diff --git a/code/vendors/zpl.h b/code/vendors/zpl.h
new file mode 100644
index 0000000..f6b54d6
--- /dev/null
+++ b/code/vendors/zpl.h
@@ -0,0 +1,17176 @@
+/**
+  ZPL - Your (almost) C99 Powerkit
+
+Usage:
+  #define ZPL_IMPLEMENTATION exactly in ONE source file right BEFORE including the library, like:
+
+  #define ZPL_IMPLEMENTATION
+  #include "zpl.h"
+
+  You can also use a freestanding version of ZPL by using ZPL_NANO, like:
+
+  #define ZPL_IMPLEMENTATION
+  #define ZPL_NANO
+  #include "zpl.h"
+
+Options:
+
+  ZPL_EDITOR - This macro should be used by the IDE's Intellisense to parse ZPL correctly. It can NEVER be used for actual compilation of the library!
+  ZPL_EXPOSE_TYPES - exposes all ZPL defined types to the global namespace. This means type such as `zpl_u32` is now available as `u32` globally.
+  ZPL_DEFINE_NULL_MACRO - to let ZPL define what NULL stands for in case it is undefined.
+  ZPL_NO_MATH_H - disables the use of math.h library and replaces it with custom routines or SIMD.
+
+Credits:
+  Read AUTHORS.md
+
+GitHub:
+  https://github.com/zpl-c/zpl
+
+Version History:
+  10.11.0 - Added zpl_file_stream_buf
+  10.10.3 - Math type-punning fixes
+  10.10.1 - Fix memory writing issue + new write-only in-situ flag
+  10.10.0 - Implement memory streaming API
+  10.9.1  - Support ARMv6, ARMv7 and ARMv8-a builds
+  10.9.0  - Improve the time API
+  10.8.3  - zpl_file_close tempfile Windows fixes
+  10.8.2  - zpl_file_temp disallow some operations
+  10.8.1  - zpl_file_temp Windows fixes
+  10.8.0  - Implemented zpl_json_write_string
+  10.7.1  - Fix zpl_file_temp platform bug
+  10.7.0  - Add zpl_file_write_contents
+  10.6.6  - Fix type mismatch in Jobs system
+  10.6.0  - Remove event system
+  10.5.8  - Remove zpl__memcpy_4byte
+  10.5.7  - zpl_file_new is now OS-agnostic constructor
+  10.5.6  - Fix coroutine creation
+  10.5.5  - Jobs system uses zpl_f32 for priority setting
+  10.5.4  - zpl_buffer_free no longer takes the 2nd argument (allocator)
+  10.5.3  - Removed crc64 and annotated some hashing methods
+  10.5.2  - Don't expose ZPL types anymore
+  10.5.1  - Fixed zpl_rdtsc for Emscripten
+  10.5.0  - Changed casts to memcopy in random methods, added embed cmd
+  10.4.1  - Jobs system now enqueues jobs with def priority of 1.0
+  10.4.0  - [META] version bump
+  10.3.0  - Pool allocator now supports zpl_free_all
+  10.2.0  - [META] version bump
+  10.1.0  - Additional math methods (thanks to funZX and msmshazan)
+  10.0.15 - WIP Emscripten fixes
+  10.0.14 - FreeBSD support
+  10.0.13 - OpenBSD support
+  10.0.12 - Cygwin fixes
+  10.0.11 - Tweak module dependencies
+  10.0.10 - Fix zero-allocation regression in filesystem module
+  10.0.9 - Fix multi-compilation unit builds
+  10.0.8 - Fix zpl_printf "%0d" format specifier
+  10.0.4 - Flush tester output to fix ordering
+  10.0.3 - Fix ZPL_STATIC_ASSERT under MSVC
+  10.0.0 - Major overhaul of the library
+
+  9.8.10 - JSON fix array-based documents with objects
+  9.8.9 - JSON document structured as array now properly recognizes the root object as array.
+  9.8.8 - Fixed an incorrect parsing of empty array nodes.
+  9.8.7 - Improve FreeBSD support
+  9.8.6 - WIP: Handle inlined methods properly
+  9.8.5 - Fix incorrect usage of EOF and opts dependency on JSON5 module's methods
+  9.8.4 - Fix MSVC ZPL_NO_MATH_H code branch using incorrect methods internally
+  9.8.3 - Fix MinGW GCC related issue with zpl_printf %lld format
+  9.8.2 - Fix VS C4190 issue
+  9.8.1 - Fix several C++ type casting quirks
+  9.8.0 - Incorporated OpenGL into ZPL core as an optional module
+  9.7.0 - Added co-routine module
+  9.6.0 - Added process module for creation and manipulation
+  9.5.2 - zpl_printf family now prints (null) on NULL string arguments
+  9.5.1 - Fixed JSON5 real number export support + indentation fixes
+  9.5.0 - Added base64 encode/decode methods
+  9.4.10- Small enum style changes
+  9.4.9 - Remove #undef for cast and hard_cast (sorry)
+  9.4.8 - Fix quote-less JSON node name resolution
+  9.4.7 - Additional change to the code
+  9.4.6 - Fix issue where zpl_json_find would have false match on substrings
+  9.4.5 - Mistakes were made, fixed compilation errors
+  9.4.3 - Fix old API shenanigans
+  9.4.2 - Fix small API typos
+  9.4.1 - Reordered JSON5 constants to integrate better with conditions
+  9.4.0 - JSON5 API changes made to zpl_json_find
+  9.3.0 - Change how zpl uses basic types internally
+  9.2.0 - Directory listing was added. Check dirlist_api.c test for more info
+  9.1.1 - Fix WIN32_LEAN_AND_MEAN redefinition properly
+  9.1.0 - get_env rework and fixes
+  9.0.3 - Small fixes and removals
+  9.0.0 - New documentation format, removed deprecated code, changed styles
+
+  8.14.1 - Fix string library
+  8.14.0 - Added zpl_re_match_all
+  8.13.0 - Update system command API
+  8.12.6 - Fix warning in CLI options parser
+  8.12.5 - Support parametric options preceding positionals
+  8.12.4 - Fixed opts positionals ordering
+  8.12.3 - Fixed incorrect handling of flags preceding positionals
+  8.12.2 - JSON parsing remark added
+  8.12.1 - Fixed a lot of important stuff
+  8.12.0 - Added helper constructors for containers
+  8.11.2 - Fix bug in opts module
+  8.11.1 - Small code improvements
+  8.11.0 - Ported regex processor from https://github.com/gingerBill/gb/ and applied fixes on top of it
+  8.10.2 - Fix zpl_strtok
+  8.10.1 - Replace zpl_strchr by zpl_char_last_occurence
+  8.10.0 - Added zpl_strchr
+  8.9.0  - API improvements for JSON5 parser
+  8.8.4  - Add support for SJSON formatting http://bitsquid.blogspot.com/2009/10/simplified-json-notation.html
+
+  6.8.3  - JSON5 exp fix
+  6.8.2  - Bugfixes applied from gb
+  6.8.1  - Performance improvements for JSON5 parser
+  6.8.0  - zpl.h is now generated by build.py
+  6.7.0  - Several fixes and added switches
+  6.6.0  - Several significant changes made to the repository
+  6.5.0  - Ported platform layer from https://github.com/gingerBill/gb/
+  6.4.1  - Use zpl_strlen in zpl_strdup
+  6.4.0  - Deprecated zpl_buffer_free and added zpl_array_end, zpl_buffer_end
+  6.3.0  - Added zpl_strdup
+  6.2.1  - Remove math redundancies
+  6.2.0  - Integrated zpl_math.h into zpl.h
+  6.1.1  - Added direct.h include for win c++ dir methods
+  6.1.0  - Added zpl_path_mkdir, zpl_path_rmdir, and few new zplFileErrors
+  6.0.4  - More MSVC(++) satisfaction by fixing warnings
+  6.0.3  - Satisfy MSVC by fixing a warning
+  6.0.2  - Fixed warnings for json5 i64 printfs
+  6.0.1  - Fixed warnings for particual win compiler in dirlist method
+  6.0.0  - New build, include/ was renamed to code/
+
+  5.8.3  - Naming fixes
+  5.8.2  - Job system now supports prioritized tasks
+  5.8.1  - Renames zpl_pad to zpl_ring
+  5.8.0  - Added instantiated scratch pad (circular buffer)
+  5.7.2  - Added Windows support for zpl_path_dirlist
+  5.7.1  - Fixed few things in job system + macOS support for zpl_path_dirlist
+  5.7.0  - Added a job system (zpl_thread_pool)
+  5.6.5  - Fixes extra error cases for zpl_opts when input is:
+         - missing a value for an option,
+         - having an extra value for a flag (e.g. --enable-log shouldn't get a value.)
+  5.6.4  - Several tweaks to the zpl_opts API
+  5.6.3  - Added support for flags without values
+  5.6.2  - Improve error handling for zpl_opts
+  5.6.1  - Added support for strings with spaces in zpl_opts
+  5.6.0  - Added zpl_opts for CLI argument parsing
+  5.5.1  - Fixed time method for win
+  5.5.0  - Integrate JSON5 writer into the core
+  5.4.0  - Improved storage support for numbers in JSON5 parser
+  5.3.0  - Integrated zpl_json into ZPL
+  5.2.0  - Added zpl_string_sprintf
+  5.1.1  - Added zpl_system_command_nores for output-less execution
+  5.1.0  - Added event handler
+  5.0.4  - Fix alias for zpl_list
+  5.0.3  - Finalizing syntax changes
+  5.0.2  - Fix segfault when using zpl_stack_memory
+  5.0.1  - Small code improvements
+  5.0.0  - Project structure changes
+
+  4.7.2  - Got rid of size arg for zpl_str_split_lines
+  4.7.1  - Added an example
+  4.7.0  - Added zpl_path_dirlist
+  4.6.1  - zpl_memcopy x86 patch from upstream
+  4.6.0  - Added few string-related functions
+  4.5.9  - Error fixes
+  4.5.8  - Warning fixes
+  4.5.7  - Fixed timer loops. zpl_time* related functions work with seconds now
+  4.5.6  - Fixed zpl_time_now() for Windows and Linux
+  4.5.5  - Small cosmetic changes
+  4.5.4  - Fixed issue when zpl_list_add would break the links
+         - when adding a new item between nodes
+  4.5.3  - Fixed malformed enum values
+  4.5.1  - Fixed some warnings
+  4.5.0  - Added zpl_array_append_at
+  4.4.0  - Added zpl_array_back, zpl_array_front
+  4.3.0  - Added zpl_list
+  4.2.0  - Added zpl_system_command_str
+  4.1.2  - GG, fixed small compilation error
+  4.1.1  - Fixed possible security issue in zpl_system_command
+  4.1.0  - Added zpl_string_make_reserve and small fixes
+  4.0.2  - Warning fix for _LARGEFILE64_SOURCE
+  4.0.1  - include stdlib.h for getenv (temp)
+  4.0.0  - ARM support, coding style changes and various improvements
+
+  3.4.1  - zpl_memcopy now uses memcpy for ARM arch-family
+  3.4.0  - Removed obsolete code
+  3.3.4  - Added Travis CI config
+  3.3.3  - Small macro formatting changes + ZPL_SYSTEM_IOS
+  3.3.2  - Fixes for android arm
+  3.3.1  - Fixed some type cast warnings
+  3.3.0  - Added Android support
+  3.1.5  - Renamed userptr to user_data in timer
+  3.1.4  - Fix for zpl_buffer not allocating correctly
+  3.1.2  - Small fix in zpl_memcompare
+  3.1.1  - Added char* conversion for data field in zpl_array_header
+  3.1.0  - Added data field to zpl_array_header
+  3.0.7  - Added timer userptr as argument to callback
+  3.0.6  - Small changes
+  3.0.5  - Fixed compilation for emscripten
+  3.0.4  - Small fixes for tiny cpp warnings
+  3.0.3  - Small fixes for various cpp warnings and errors
+  3.0.2  - Fixed linux part, and removed trailing spaces
+  3.0.1  - Small bugfix in zpl_file_open
+  3.0.0  - Added several fixes and features
+
+  2.4.0  - Added remove to hash table
+  2.3.3  - Removed redundant code
+  2.3.2  - Eliminated extra warnings
+  2.3.1  - Warning hunt
+  2.3.0  - Added the ability to copy array/buffer and fixed bug in hash table.
+  2.2.1  - Used tmpfile() for Windows
+  2.2.0  - Added zpl_file_temp
+  2.1.1  - Very small fix (forgive me)
+  2.1.0  - Added the ability to resize bitstream
+  2.0.8  - Small adjustments
+  2.0.7  - MinGW related fixes
+  2.0.0  - New NPM based version
+
+  1.2.2  - Small fix
+  1.2.1  - Macro fixes
+  1.2.0  - Added zpl_async macro
+  1.1.0  - Added timer feature
+  1.0.0  - Initial version
+
+  This Software is dual licensed under the following licenses:
+
+  Unlicense
+  This is free and unencumbered software released into the public domain.
+
+  Anyone is free to copy, modify, publish, use, compile, sell, or
+  distribute this software, either in source code form or as a compiled
+  binary, for any purpose, commercial or non-commercial, and by any
+  means.
+
+  In jurisdictions that recognize copyright laws, the author or authors
+  of this software dedicate any and all copyright interest in the
+  software to the public domain. We make this dedication for the benefit
+  of the public at large and to the detriment of our heirs and
+  successors. We intend this dedication to be an overt act of
+  relinquishment in perpetuity of all present and future rights to this
+  software under copyright law.
+
+  THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
+  EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
+  MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
+  IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR
+  OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
+  ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
+  OTHER DEALINGS IN THE SOFTWARE.
+
+  For more information, please refer to <http://unlicense.org/>
+
+  BSD 3-Clause
+
+  Copyright (c) 2016-2021 Dominik Madarász. All rights reserved.
+
+  Redistribution and use in source and binary forms, with or without
+  modification, are permitted provided that the following conditions are met:
+
+  1. Redistributions of source code must retain the above copyright notice, this
+    list of conditions and the following disclaimer.
+  2. Redistributions in binary form must reproduce the above copyright notice,
+    this list of conditions and the following disclaimer in the documentation
+    and/or other materials provided with the distribution.
+  3. Neither the name of the copyright holder nor the names of its contributors
+    may be used to endorse or promote products derived from this software without
+    specific prior written permission.
+
+  THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
+  ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
+  WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
+  DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
+  FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
+  DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
+  SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
+  CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
+  OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
+  OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
+
+
+*/
+
+#ifndef ZPL_H
+#define ZPL_H
+
+#define ZPL_VERSION_MAJOR 10
+#define ZPL_VERSION_MINOR 11
+#define ZPL_VERSION_PATCH 0
+#define ZPL_VERSION_PRE ""
+
+// file: zpl_hedley.h
+
+/* Hedley - https://nemequ.github.io/hedley
+ * Created by Evan Nemerson <evan@nemerson.com>
+ *
+ * To the extent possible under law, the author(s) have dedicated all
+ * copyright and related and neighboring rights to this software to
+ * the public domain worldwide. This software is distributed without
+ * any warranty.
+ *
+ * For details, see <http://creativecommons.org/publicdomain/zero/1.0/>.
+ * SPDX-License-Identifier: CC0-1.0
+ */
+
+#if !defined(ZPL_HEDLEY_VERSION) || (ZPL_HEDLEY_VERSION < 12)
+#if defined(ZPL_HEDLEY_VERSION)
+#  undef ZPL_HEDLEY_VERSION
+#endif
+#define ZPL_HEDLEY_VERSION 12
+
+#if defined(ZPL_STRINGIFY_EX)
+#  undef ZPL_STRINGIFY_EX
+#endif
+#define ZPL_STRINGIFY_EX(x) #x
+
+#if defined(ZPL_STRINGIFY)
+#  undef ZPL_STRINGIFY
+#endif
+#define ZPL_STRINGIFY(x) ZPL_STRINGIFY_EX(x)
+
+#if defined(ZPL_CONCAT_EX)
+#  undef ZPL_CONCAT_EX
+#endif
+#define ZPL_CONCAT_EX(a,b) a##b
+
+#if defined(ZPL_CONCAT)
+#  undef ZPL_CONCAT
+#endif
+#define ZPL_CONCAT(a,b) ZPL_CONCAT_EX(a,b)
+
+#if defined(ZPL_VERSION_ENCODE)
+#  undef ZPL_VERSION_ENCODE
+#endif
+#define ZPL_VERSION_ENCODE(major,minor,patch) (((major) * 1000000) + ((minor) * 1000) + (patch))
+
+#if defined(ZPL_VERSION_DECODE_MAJOR)
+#  undef ZPL_VERSION_DECODE_MAJOR
+#endif
+#define ZPL_VERSION_DECODE_MAJOR(version) ((version) / 1000000)
+
+#if defined(ZPL_VERSION_DECODE_MINOR)
+#  undef ZPL_VERSION_DECODE_MINOR
+#endif
+#define ZPL_VERSION_DECODE_MINOR(version) (((version) % 1000000) / 1000)
+
+#if defined(ZPL_VERSION_DECODE_PATCH)
+#  undef ZPL_VERSION_DECODE_PATCH
+#endif
+#define ZPL_VERSION_DECODE_PATCH(version) ((version) % 1000)
+
+#if defined(ZPL_GNUC_VERSION)
+#  undef ZPL_GNUC_VERSION
+#endif
+#if defined(__GNUC__) && defined(__GNUC_PATCHLEVEL__)
+#  define ZPL_GNUC_VERSION ZPL_VERSION_ENCODE(__GNUC__, __GNUC_MINOR__, __GNUC_PATCHLEVEL__)
+#elif defined(__GNUC__)
+#  define ZPL_GNUC_VERSION ZPL_VERSION_ENCODE(__GNUC__, __GNUC_MINOR__, 0)
+#endif
+
+#if defined(ZPL_GNUC_VERSION_CHECK)
+#  undef ZPL_GNUC_VERSION_CHECK
+#endif
+#if defined(ZPL_GNUC_VERSION)
+#  define ZPL_GNUC_VERSION_CHECK(major,minor,patch) (ZPL_GNUC_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_GNUC_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_MSVC_VERSION)
+#  undef ZPL_MSVC_VERSION
+#endif
+#if defined(_MSC_FULL_VER) && (_MSC_FULL_VER >= 140000000)
+#  define ZPL_MSVC_VERSION ZPL_VERSION_ENCODE(_MSC_FULL_VER / 10000000, (_MSC_FULL_VER % 10000000) / 100000, (_MSC_FULL_VER % 100000) / 100)
+#elif defined(_MSC_FULL_VER)
+#  define ZPL_MSVC_VERSION ZPL_VERSION_ENCODE(_MSC_FULL_VER / 1000000, (_MSC_FULL_VER % 1000000) / 10000, (_MSC_FULL_VER % 10000) / 10)
+#elif defined(_MSC_VER)
+#  define ZPL_MSVC_VERSION ZPL_VERSION_ENCODE(_MSC_VER / 100, _MSC_VER % 100, 0)
+#endif
+
+#if defined(ZPL_MSVC_VERSION_CHECK)
+#  undef ZPL_MSVC_VERSION_CHECK
+#endif
+#if !defined(_MSC_VER)
+#  define ZPL_MSVC_VERSION_CHECK(major,minor,patch) (0)
+#elif defined(_MSC_VER) && (_MSC_VER >= 1400)
+#  define ZPL_MSVC_VERSION_CHECK(major,minor,patch) (_MSC_FULL_VER >= ((major * 10000000) + (minor * 100000) + (patch)))
+#elif defined(_MSC_VER) && (_MSC_VER >= 1200)
+#  define ZPL_MSVC_VERSION_CHECK(major,minor,patch) (_MSC_FULL_VER >= ((major * 1000000) + (minor * 10000) + (patch)))
+#else
+#  define ZPL_MSVC_VERSION_CHECK(major,minor,patch) (_MSC_VER >= ((major * 100) + (minor)))
+#endif
+
+#if defined(ZPL_INTEL_VERSION)
+#  undef ZPL_INTEL_VERSION
+#endif
+#if defined(__INTEL_COMPILER) && defined(__INTEL_COMPILER_UPDATE)
+#  define ZPL_INTEL_VERSION ZPL_VERSION_ENCODE(__INTEL_COMPILER / 100, __INTEL_COMPILER % 100, __INTEL_COMPILER_UPDATE)
+#elif defined(__INTEL_COMPILER)
+#  define ZPL_INTEL_VERSION ZPL_VERSION_ENCODE(__INTEL_COMPILER / 100, __INTEL_COMPILER % 100, 0)
+#endif
+
+#if defined(ZPL_INTEL_VERSION_CHECK)
+#  undef ZPL_INTEL_VERSION_CHECK
+#endif
+#if defined(ZPL_INTEL_VERSION)
+#  define ZPL_INTEL_VERSION_CHECK(major,minor,patch) (ZPL_INTEL_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_INTEL_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_PGI_VERSION)
+#  undef ZPL_PGI_VERSION
+#endif
+#if defined(__PGI) && defined(__PGIC__) && defined(__PGIC_MINOR__) && defined(__PGIC_PATCHLEVEL__)
+#  define ZPL_PGI_VERSION ZPL_VERSION_ENCODE(__PGIC__, __PGIC_MINOR__, __PGIC_PATCHLEVEL__)
+#endif
+
+#if defined(ZPL_PGI_VERSION_CHECK)
+#  undef ZPL_PGI_VERSION_CHECK
+#endif
+#if defined(ZPL_PGI_VERSION)
+#  define ZPL_PGI_VERSION_CHECK(major,minor,patch) (ZPL_PGI_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_PGI_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_SUNPRO_VERSION)
+#  undef ZPL_SUNPRO_VERSION
+#endif
+#if defined(__SUNPRO_C) && (__SUNPRO_C > 0x1000)
+#  define ZPL_SUNPRO_VERSION ZPL_VERSION_ENCODE((((__SUNPRO_C >> 16) & 0xf) * 10) + ((__SUNPRO_C >> 12) & 0xf), (((__SUNPRO_C >> 8) & 0xf) * 10) + ((__SUNPRO_C >> 4) & 0xf), (__SUNPRO_C & 0xf) * 10)
+#elif defined(__SUNPRO_C)
+#  define ZPL_SUNPRO_VERSION ZPL_VERSION_ENCODE((__SUNPRO_C >> 8) & 0xf, (__SUNPRO_C >> 4) & 0xf, (__SUNPRO_C) & 0xf)
+#elif defined(__SUNPRO_CC) && (__SUNPRO_CC > 0x1000)
+#  define ZPL_SUNPRO_VERSION ZPL_VERSION_ENCODE((((__SUNPRO_CC >> 16) & 0xf) * 10) + ((__SUNPRO_CC >> 12) & 0xf), (((__SUNPRO_CC >> 8) & 0xf) * 10) + ((__SUNPRO_CC >> 4) & 0xf), (__SUNPRO_CC & 0xf) * 10)
+#elif defined(__SUNPRO_CC)
+#  define ZPL_SUNPRO_VERSION ZPL_VERSION_ENCODE((__SUNPRO_CC >> 8) & 0xf, (__SUNPRO_CC >> 4) & 0xf, (__SUNPRO_CC) & 0xf)
+#endif
+
+#if defined(ZPL_SUNPRO_VERSION_CHECK)
+#  undef ZPL_SUNPRO_VERSION_CHECK
+#endif
+#if defined(ZPL_SUNPRO_VERSION)
+#  define ZPL_SUNPRO_VERSION_CHECK(major,minor,patch) (ZPL_SUNPRO_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_SUNPRO_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_EMSCRIPTEN_VERSION)
+#  undef ZPL_EMSCRIPTEN_VERSION
+#endif
+#if defined(__EMSCRIPTEN__)
+#  define ZPL_EMSCRIPTEN_VERSION ZPL_VERSION_ENCODE(__EMSCRIPTEN_major__, __EMSCRIPTEN_minor__, __EMSCRIPTEN_tiny__)
+#endif
+
+#if defined(ZPL_EMSCRIPTEN_VERSION_CHECK)
+#  undef ZPL_EMSCRIPTEN_VERSION_CHECK
+#endif
+#if defined(ZPL_EMSCRIPTEN_VERSION)
+#  define ZPL_EMSCRIPTEN_VERSION_CHECK(major,minor,patch) (ZPL_EMSCRIPTEN_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_EMSCRIPTEN_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_ARM_VERSION)
+#  undef ZPL_ARM_VERSION
+#endif
+#if defined(__CC_ARM) && defined(__ARMCOMPILER_VERSION)
+#  define ZPL_ARM_VERSION ZPL_VERSION_ENCODE(__ARMCOMPILER_VERSION / 1000000, (__ARMCOMPILER_VERSION % 1000000) / 10000, (__ARMCOMPILER_VERSION % 10000) / 100)
+#elif defined(__CC_ARM) && defined(__ARMCC_VERSION)
+#  define ZPL_ARM_VERSION ZPL_VERSION_ENCODE(__ARMCC_VERSION / 1000000, (__ARMCC_VERSION % 1000000) / 10000, (__ARMCC_VERSION % 10000) / 100)
+#endif
+
+#if defined(ZPL_ARM_VERSION_CHECK)
+#  undef ZPL_ARM_VERSION_CHECK
+#endif
+#if defined(ZPL_ARM_VERSION)
+#  define ZPL_ARM_VERSION_CHECK(major,minor,patch) (ZPL_ARM_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_ARM_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_IBM_VERSION)
+#  undef ZPL_IBM_VERSION
+#endif
+#if defined(__ibmxl__)
+#  define ZPL_IBM_VERSION ZPL_VERSION_ENCODE(__ibmxl_version__, __ibmxl_release__, __ibmxl_modification__)
+#elif defined(__xlC__) && defined(__xlC_ver__)
+#  define ZPL_IBM_VERSION ZPL_VERSION_ENCODE(__xlC__ >> 8, __xlC__ & 0xff, (__xlC_ver__ >> 8) & 0xff)
+#elif defined(__xlC__)
+#  define ZPL_IBM_VERSION ZPL_VERSION_ENCODE(__xlC__ >> 8, __xlC__ & 0xff, 0)
+#endif
+
+#if defined(ZPL_IBM_VERSION_CHECK)
+#  undef ZPL_IBM_VERSION_CHECK
+#endif
+#if defined(ZPL_IBM_VERSION)
+#  define ZPL_IBM_VERSION_CHECK(major,minor,patch) (ZPL_IBM_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_IBM_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_TI_VERSION)
+#  undef ZPL_TI_VERSION
+#endif
+#if \
+    defined(__TI_COMPILER_VERSION__) && \
+    ( \
+      defined(__TMS470__) || defined(__TI_ARM__) || \
+      defined(__MSP430__) || \
+      defined(__TMS320C2000__) \
+    )
+#  if (__TI_COMPILER_VERSION__ >= 16000000)
+#    define ZPL_TI_VERSION ZPL_VERSION_ENCODE(__TI_COMPILER_VERSION__ / 1000000, (__TI_COMPILER_VERSION__ % 1000000) / 1000, (__TI_COMPILER_VERSION__ % 1000))
+#  endif
+#endif
+
+#if defined(ZPL_TI_VERSION_CHECK)
+#  undef ZPL_TI_VERSION_CHECK
+#endif
+#if defined(ZPL_TI_VERSION)
+#  define ZPL_TI_VERSION_CHECK(major,minor,patch) (ZPL_TI_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_TI_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_TI_CL2000_VERSION)
+#  undef ZPL_TI_CL2000_VERSION
+#endif
+#if defined(__TI_COMPILER_VERSION__) && defined(__TMS320C2000__)
+#  define ZPL_TI_CL2000_VERSION ZPL_VERSION_ENCODE(__TI_COMPILER_VERSION__ / 1000000, (__TI_COMPILER_VERSION__ % 1000000) / 1000, (__TI_COMPILER_VERSION__ % 1000))
+#endif
+
+#if defined(ZPL_TI_CL2000_VERSION_CHECK)
+#  undef ZPL_TI_CL2000_VERSION_CHECK
+#endif
+#if defined(ZPL_TI_CL2000_VERSION)
+#  define ZPL_TI_CL2000_VERSION_CHECK(major,minor,patch) (ZPL_TI_CL2000_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_TI_CL2000_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_TI_CL430_VERSION)
+#  undef ZPL_TI_CL430_VERSION
+#endif
+#if defined(__TI_COMPILER_VERSION__) && defined(__MSP430__)
+#  define ZPL_TI_CL430_VERSION ZPL_VERSION_ENCODE(__TI_COMPILER_VERSION__ / 1000000, (__TI_COMPILER_VERSION__ % 1000000) / 1000, (__TI_COMPILER_VERSION__ % 1000))
+#endif
+
+#if defined(ZPL_TI_CL430_VERSION_CHECK)
+#  undef ZPL_TI_CL430_VERSION_CHECK
+#endif
+#if defined(ZPL_TI_CL430_VERSION)
+#  define ZPL_TI_CL430_VERSION_CHECK(major,minor,patch) (ZPL_TI_CL430_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_TI_CL430_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_TI_ARMCL_VERSION)
+#  undef ZPL_TI_ARMCL_VERSION
+#endif
+#if defined(__TI_COMPILER_VERSION__) && (defined(__TMS470__) || defined(__TI_ARM__))
+#  define ZPL_TI_ARMCL_VERSION ZPL_VERSION_ENCODE(__TI_COMPILER_VERSION__ / 1000000, (__TI_COMPILER_VERSION__ % 1000000) / 1000, (__TI_COMPILER_VERSION__ % 1000))
+#endif
+
+#if defined(ZPL_TI_ARMCL_VERSION_CHECK)
+#  undef ZPL_TI_ARMCL_VERSION_CHECK
+#endif
+#if defined(ZPL_TI_ARMCL_VERSION)
+#  define ZPL_TI_ARMCL_VERSION_CHECK(major,minor,patch) (ZPL_TI_ARMCL_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_TI_ARMCL_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_TI_CL6X_VERSION)
+#  undef ZPL_TI_CL6X_VERSION
+#endif
+#if defined(__TI_COMPILER_VERSION__) && defined(__TMS320C6X__)
+#  define ZPL_TI_CL6X_VERSION ZPL_VERSION_ENCODE(__TI_COMPILER_VERSION__ / 1000000, (__TI_COMPILER_VERSION__ % 1000000) / 1000, (__TI_COMPILER_VERSION__ % 1000))
+#endif
+
+#if defined(ZPL_TI_CL6X_VERSION_CHECK)
+#  undef ZPL_TI_CL6X_VERSION_CHECK
+#endif
+#if defined(ZPL_TI_CL6X_VERSION)
+#  define ZPL_TI_CL6X_VERSION_CHECK(major,minor,patch) (ZPL_TI_CL6X_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_TI_CL6X_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_TI_CL7X_VERSION)
+#  undef ZPL_TI_CL7X_VERSION
+#endif
+#if defined(__TI_COMPILER_VERSION__) && defined(__C7000__)
+#  define ZPL_TI_CL7X_VERSION ZPL_VERSION_ENCODE(__TI_COMPILER_VERSION__ / 1000000, (__TI_COMPILER_VERSION__ % 1000000) / 1000, (__TI_COMPILER_VERSION__ % 1000))
+#endif
+
+#if defined(ZPL_TI_CL7X_VERSION_CHECK)
+#  undef ZPL_TI_CL7X_VERSION_CHECK
+#endif
+#if defined(ZPL_TI_CL7X_VERSION)
+#  define ZPL_TI_CL7X_VERSION_CHECK(major,minor,patch) (ZPL_TI_CL7X_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_TI_CL7X_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_TI_CLPRU_VERSION)
+#  undef ZPL_TI_CLPRU_VERSION
+#endif
+#if defined(__TI_COMPILER_VERSION__) && defined(__PRU__)
+#  define ZPL_TI_CLPRU_VERSION ZPL_VERSION_ENCODE(__TI_COMPILER_VERSION__ / 1000000, (__TI_COMPILER_VERSION__ % 1000000) / 1000, (__TI_COMPILER_VERSION__ % 1000))
+#endif
+
+#if defined(ZPL_TI_CLPRU_VERSION_CHECK)
+#  undef ZPL_TI_CLPRU_VERSION_CHECK
+#endif
+#if defined(ZPL_TI_CLPRU_VERSION)
+#  define ZPL_TI_CLPRU_VERSION_CHECK(major,minor,patch) (ZPL_TI_CLPRU_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_TI_CLPRU_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_CRAY_VERSION)
+#  undef ZPL_CRAY_VERSION
+#endif
+#if defined(_CRAYC)
+#  if defined(_RELEASE_PATCHLEVEL)
+#    define ZPL_CRAY_VERSION ZPL_VERSION_ENCODE(_RELEASE_MAJOR, _RELEASE_MINOR, _RELEASE_PATCHLEVEL)
+#  else
+#    define ZPL_CRAY_VERSION ZPL_VERSION_ENCODE(_RELEASE_MAJOR, _RELEASE_MINOR, 0)
+#  endif
+#endif
+
+#if defined(ZPL_CRAY_VERSION_CHECK)
+#  undef ZPL_CRAY_VERSION_CHECK
+#endif
+#if defined(ZPL_CRAY_VERSION)
+#  define ZPL_CRAY_VERSION_CHECK(major,minor,patch) (ZPL_CRAY_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_CRAY_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_IAR_VERSION)
+#  undef ZPL_IAR_VERSION
+#endif
+#if defined(__IAR_SYSTEMS_ICC__)
+#  if __VER__ > 1000
+#    define ZPL_IAR_VERSION ZPL_VERSION_ENCODE((__VER__ / 1000000), ((__VER__ / 1000) % 1000), (__VER__ % 1000))
+#  else
+#    define ZPL_IAR_VERSION ZPL_VERSION_ENCODE(VER / 100, __VER__ % 100, 0)
+#  endif
+#endif
+
+#if defined(ZPL_IAR_VERSION_CHECK)
+#  undef ZPL_IAR_VERSION_CHECK
+#endif
+#if defined(ZPL_IAR_VERSION)
+#  define ZPL_IAR_VERSION_CHECK(major,minor,patch) (ZPL_IAR_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_IAR_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_TINYC_VERSION)
+#  undef ZPL_TINYC_VERSION
+#endif
+#if defined(__TINYC__)
+#  define ZPL_TINYC_VERSION ZPL_VERSION_ENCODE(__TINYC__ / 1000, (__TINYC__ / 100) % 10, __TINYC__ % 100)
+#endif
+
+#if defined(ZPL_TINYC_VERSION_CHECK)
+#  undef ZPL_TINYC_VERSION_CHECK
+#endif
+#if defined(ZPL_TINYC_VERSION)
+#  define ZPL_TINYC_VERSION_CHECK(major,minor,patch) (ZPL_TINYC_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_TINYC_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_DMC_VERSION)
+#  undef ZPL_DMC_VERSION
+#endif
+#if defined(__DMC__)
+#  define ZPL_DMC_VERSION ZPL_VERSION_ENCODE(__DMC__ >> 8, (__DMC__ >> 4) & 0xf, __DMC__ & 0xf)
+#endif
+
+#if defined(ZPL_DMC_VERSION_CHECK)
+#  undef ZPL_DMC_VERSION_CHECK
+#endif
+#if defined(ZPL_DMC_VERSION)
+#  define ZPL_DMC_VERSION_CHECK(major,minor,patch) (ZPL_DMC_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_DMC_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_COMPCERT_VERSION)
+#  undef ZPL_COMPCERT_VERSION
+#endif
+#if defined(__COMPCERT_VERSION__)
+#  define ZPL_COMPCERT_VERSION ZPL_VERSION_ENCODE(__COMPCERT_VERSION__ / 10000, (__COMPCERT_VERSION__ / 100) % 100, __COMPCERT_VERSION__ % 100)
+#endif
+
+#if defined(ZPL_COMPCERT_VERSION_CHECK)
+#  undef ZPL_COMPCERT_VERSION_CHECK
+#endif
+#if defined(ZPL_COMPCERT_VERSION)
+#  define ZPL_COMPCERT_VERSION_CHECK(major,minor,patch) (ZPL_COMPCERT_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_COMPCERT_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_PELLES_VERSION)
+#  undef ZPL_PELLES_VERSION
+#endif
+#if defined(__POCC__)
+#  define ZPL_PELLES_VERSION ZPL_VERSION_ENCODE(__POCC__ / 100, __POCC__ % 100, 0)
+#endif
+
+#if defined(ZPL_PELLES_VERSION_CHECK)
+#  undef ZPL_PELLES_VERSION_CHECK
+#endif
+#if defined(ZPL_PELLES_VERSION)
+#  define ZPL_PELLES_VERSION_CHECK(major,minor,patch) (ZPL_PELLES_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_PELLES_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_GCC_VERSION)
+#  undef ZPL_GCC_VERSION
+#endif
+#if \
+  defined(ZPL_GNUC_VERSION) && \
+  !defined(__clang__) && \
+  !defined(ZPL_INTEL_VERSION) && \
+  !defined(ZPL_PGI_VERSION) && \
+  !defined(ZPL_ARM_VERSION) && \
+  !defined(ZPL_TI_VERSION) && \
+  !defined(ZPL_TI_ARMCL_VERSION) && \
+  !defined(ZPL_TI_CL430_VERSION) && \
+  !defined(ZPL_TI_CL2000_VERSION) && \
+  !defined(ZPL_TI_CL6X_VERSION) && \
+  !defined(ZPL_TI_CL7X_VERSION) && \
+  !defined(ZPL_TI_CLPRU_VERSION) && \
+  !defined(__COMPCERT__)
+#  define ZPL_GCC_VERSION ZPL_GNUC_VERSION
+#endif
+
+#if defined(ZPL_GCC_VERSION_CHECK)
+#  undef ZPL_GCC_VERSION_CHECK
+#endif
+#if defined(ZPL_GCC_VERSION)
+#  define ZPL_GCC_VERSION_CHECK(major,minor,patch) (ZPL_GCC_VERSION >= ZPL_VERSION_ENCODE(major, minor, patch))
+#else
+#  define ZPL_GCC_VERSION_CHECK(major,minor,patch) (0)
+#endif
+
+#if defined(ZPL_HAS_ATTRIBUTE)
+#  undef ZPL_HAS_ATTRIBUTE
+#endif
+#if defined(__has_attribute)
+#  define ZPL_HAS_ATTRIBUTE(attribute) __has_attribute(attribute)
+#else
+#  define ZPL_HAS_ATTRIBUTE(attribute) (0)
+#endif
+
+#if defined(ZPL_GNUC_HAS_ATTRIBUTE)
+#  undef ZPL_GNUC_HAS_ATTRIBUTE
+#endif
+#if defined(__has_attribute)
+#  define ZPL_GNUC_HAS_ATTRIBUTE(attribute,major,minor,patch) __has_attribute(attribute)
+#else
+#  define ZPL_GNUC_HAS_ATTRIBUTE(attribute,major,minor,patch) ZPL_GNUC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_GCC_HAS_ATTRIBUTE)
+#  undef ZPL_GCC_HAS_ATTRIBUTE
+#endif
+#if defined(__has_attribute)
+#  define ZPL_GCC_HAS_ATTRIBUTE(attribute,major,minor,patch) __has_attribute(attribute)
+#else
+#  define ZPL_GCC_HAS_ATTRIBUTE(attribute,major,minor,patch) ZPL_GCC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_HAS_CPP_ATTRIBUTE)
+#  undef ZPL_HAS_CPP_ATTRIBUTE
+#endif
+#if \
+  defined(__has_cpp_attribute) && \
+  defined(__cplusplus) && \
+  (!defined(ZPL_SUNPRO_VERSION) || ZPL_SUNPRO_VERSION_CHECK(5,15,0))
+#  define ZPL_HAS_CPP_ATTRIBUTE(attribute) __has_cpp_attribute(attribute)
+#else
+#  define ZPL_HAS_CPP_ATTRIBUTE(attribute) (0)
+#endif
+
+#if defined(ZPL_HAS_CPP_ATTRIBUTE_NS)
+#  undef ZPL_HAS_CPP_ATTRIBUTE_NS
+#endif
+#if !defined(__cplusplus) || !defined(__has_cpp_attribute)
+#  define ZPL_HAS_CPP_ATTRIBUTE_NS(ns,attribute) (0)
+#elif \
+  !defined(ZPL_PGI_VERSION) && \
+  !defined(ZPL_IAR_VERSION) && \
+  (!defined(ZPL_SUNPRO_VERSION) || ZPL_SUNPRO_VERSION_CHECK(5,15,0)) && \
+  (!defined(ZPL_MSVC_VERSION) || ZPL_MSVC_VERSION_CHECK(19,20,0))
+#  define ZPL_HAS_CPP_ATTRIBUTE_NS(ns,attribute) ZPL_HAS_CPP_ATTRIBUTE(ns::attribute)
+#else
+#  define ZPL_HAS_CPP_ATTRIBUTE_NS(ns,attribute) (0)
+#endif
+
+#if defined(ZPL_GNUC_HAS_CPP_ATTRIBUTE)
+#  undef ZPL_GNUC_HAS_CPP_ATTRIBUTE
+#endif
+#if defined(__has_cpp_attribute) && defined(__cplusplus)
+#  define ZPL_GNUC_HAS_CPP_ATTRIBUTE(attribute,major,minor,patch) __has_cpp_attribute(attribute)
+#else
+#  define ZPL_GNUC_HAS_CPP_ATTRIBUTE(attribute,major,minor,patch) ZPL_GNUC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_GCC_HAS_CPP_ATTRIBUTE)
+#  undef ZPL_GCC_HAS_CPP_ATTRIBUTE
+#endif
+#if defined(__has_cpp_attribute) && defined(__cplusplus)
+#  define ZPL_GCC_HAS_CPP_ATTRIBUTE(attribute,major,minor,patch) __has_cpp_attribute(attribute)
+#else
+#  define ZPL_GCC_HAS_CPP_ATTRIBUTE(attribute,major,minor,patch) ZPL_GCC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_HAS_BUILTIN)
+#  undef ZPL_HAS_BUILTIN
+#endif
+#if defined(__has_builtin)
+#  define ZPL_HAS_BUILTIN(builtin) __has_builtin(builtin)
+#else
+#  define ZPL_HAS_BUILTIN(builtin) (0)
+#endif
+
+#if defined(ZPL_GNUC_HAS_BUILTIN)
+#  undef ZPL_GNUC_HAS_BUILTIN
+#endif
+#if defined(__has_builtin)
+#  define ZPL_GNUC_HAS_BUILTIN(builtin,major,minor,patch) __has_builtin(builtin)
+#else
+#  define ZPL_GNUC_HAS_BUILTIN(builtin,major,minor,patch) ZPL_GNUC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_GCC_HAS_BUILTIN)
+#  undef ZPL_GCC_HAS_BUILTIN
+#endif
+#if defined(__has_builtin)
+#  define ZPL_GCC_HAS_BUILTIN(builtin,major,minor,patch) __has_builtin(builtin)
+#else
+#  define ZPL_GCC_HAS_BUILTIN(builtin,major,minor,patch) ZPL_GCC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_HAS_FEATURE)
+#  undef ZPL_HAS_FEATURE
+#endif
+#if defined(__has_feature)
+#  define ZPL_HAS_FEATURE(feature) __has_feature(feature)
+#else
+#  define ZPL_HAS_FEATURE(feature) (0)
+#endif
+
+#if defined(ZPL_GNUC_HAS_FEATURE)
+#  undef ZPL_GNUC_HAS_FEATURE
+#endif
+#if defined(__has_feature)
+#  define ZPL_GNUC_HAS_FEATURE(feature,major,minor,patch) __has_feature(feature)
+#else
+#  define ZPL_GNUC_HAS_FEATURE(feature,major,minor,patch) ZPL_GNUC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_GCC_HAS_FEATURE)
+#  undef ZPL_GCC_HAS_FEATURE
+#endif
+#if defined(__has_feature)
+#  define ZPL_GCC_HAS_FEATURE(feature,major,minor,patch) __has_feature(feature)
+#else
+#  define ZPL_GCC_HAS_FEATURE(feature,major,minor,patch) ZPL_GCC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_HAS_EXTENSION)
+#  undef ZPL_HAS_EXTENSION
+#endif
+#if defined(__has_extension)
+#  define ZPL_HAS_EXTENSION(extension) __has_extension(extension)
+#else
+#  define ZPL_HAS_EXTENSION(extension) (0)
+#endif
+
+#if defined(ZPL_GNUC_HAS_EXTENSION)
+#  undef ZPL_GNUC_HAS_EXTENSION
+#endif
+#if defined(__has_extension)
+#  define ZPL_GNUC_HAS_EXTENSION(extension,major,minor,patch) __has_extension(extension)
+#else
+#  define ZPL_GNUC_HAS_EXTENSION(extension,major,minor,patch) ZPL_GNUC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_GCC_HAS_EXTENSION)
+#  undef ZPL_GCC_HAS_EXTENSION
+#endif
+#if defined(__has_extension)
+#  define ZPL_GCC_HAS_EXTENSION(extension,major,minor,patch) __has_extension(extension)
+#else
+#  define ZPL_GCC_HAS_EXTENSION(extension,major,minor,patch) ZPL_GCC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_HAS_DECLSPEC_ATTRIBUTE)
+#  undef ZPL_HAS_DECLSPEC_ATTRIBUTE
+#endif
+#if defined(__has_declspec_attribute)
+#  define ZPL_HAS_DECLSPEC_ATTRIBUTE(attribute) __has_declspec_attribute(attribute)
+#else
+#  define ZPL_HAS_DECLSPEC_ATTRIBUTE(attribute) (0)
+#endif
+
+#if defined(ZPL_GNUC_HAS_DECLSPEC_ATTRIBUTE)
+#  undef ZPL_GNUC_HAS_DECLSPEC_ATTRIBUTE
+#endif
+#if defined(__has_declspec_attribute)
+#  define ZPL_GNUC_HAS_DECLSPEC_ATTRIBUTE(attribute,major,minor,patch) __has_declspec_attribute(attribute)
+#else
+#  define ZPL_GNUC_HAS_DECLSPEC_ATTRIBUTE(attribute,major,minor,patch) ZPL_GNUC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_GCC_HAS_DECLSPEC_ATTRIBUTE)
+#  undef ZPL_GCC_HAS_DECLSPEC_ATTRIBUTE
+#endif
+#if defined(__has_declspec_attribute)
+#  define ZPL_GCC_HAS_DECLSPEC_ATTRIBUTE(attribute,major,minor,patch) __has_declspec_attribute(attribute)
+#else
+#  define ZPL_GCC_HAS_DECLSPEC_ATTRIBUTE(attribute,major,minor,patch) ZPL_GCC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_HAS_WARNING)
+#  undef ZPL_HAS_WARNING
+#endif
+#if defined(__has_warning)
+#  define ZPL_HAS_WARNING(warning) __has_warning(warning)
+#else
+#  define ZPL_HAS_WARNING(warning) (0)
+#endif
+
+#if defined(ZPL_GNUC_HAS_WARNING)
+#  undef ZPL_GNUC_HAS_WARNING
+#endif
+#if defined(__has_warning)
+#  define ZPL_GNUC_HAS_WARNING(warning,major,minor,patch) __has_warning(warning)
+#else
+#  define ZPL_GNUC_HAS_WARNING(warning,major,minor,patch) ZPL_GNUC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_GCC_HAS_WARNING)
+#  undef ZPL_GCC_HAS_WARNING
+#endif
+#if defined(__has_warning)
+#  define ZPL_GCC_HAS_WARNING(warning,major,minor,patch) __has_warning(warning)
+#else
+#  define ZPL_GCC_HAS_WARNING(warning,major,minor,patch) ZPL_GCC_VERSION_CHECK(major,minor,patch)
+#endif
+
+/* ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_ is for
+   ZPL INTERNAL USE ONLY.  API subject to change without notice. */
+#if defined(ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_)
+#  undef ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_
+#endif
+#if defined(__cplusplus)
+#  if ZPL_HAS_WARNING("-Wc++98-compat")
+#    if ZPL_HAS_WARNING("-Wc++17-extensions")
+#      define ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_(xpr) \
+         ZPL_DIAGNOSTIC_PUSH \
+         _Pragma("clang diagnostic ignored \"-Wc++98-compat\"") \
+         _Pragma("clang diagnostic ignored \"-Wc++17-extensions\"") \
+         xpr \
+         ZPL_DIAGNOSTIC_POP
+#    else
+#      define ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_(xpr) \
+         ZPL_DIAGNOSTIC_PUSH \
+         _Pragma("clang diagnostic ignored \"-Wc++98-compat\"") \
+         xpr \
+         ZPL_DIAGNOSTIC_POP
+#    endif
+#  endif
+#endif
+#if !defined(ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_)
+#  define ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_(x) x
+#endif
+
+#if defined(ZPL_CONST_CAST)
+#  undef ZPL_CONST_CAST
+#endif
+#if defined(__cplusplus)
+#  define ZPL_CONST_CAST(T, expr) (const_cast<T>(expr))
+#elif \
+  ZPL_HAS_WARNING("-Wcast-qual") || \
+  ZPL_GCC_VERSION_CHECK(4,6,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_CONST_CAST(T, expr) (__extension__ ({ \
+      ZPL_DIAGNOSTIC_PUSH \
+      ZPL_DIAGNOSTIC_DISABLE_CAST_QUAL \
+      ((T) (expr)); \
+      ZPL_DIAGNOSTIC_POP \
+    }))
+#else
+#  define ZPL_CONST_CAST(T, expr) ((T) (expr))
+#endif
+
+#if defined(ZPL_REINTERPRET_CAST)
+#  undef ZPL_REINTERPRET_CAST
+#endif
+#if defined(__cplusplus)
+#  define ZPL_REINTERPRET_CAST(T, expr) (reinterpret_cast<T>(expr))
+#else
+#  define ZPL_REINTERPRET_CAST(T, expr) ((T) (expr))
+#endif
+
+#if defined(ZPL_STATIC_CAST)
+#  undef ZPL_STATIC_CAST
+#endif
+#if defined(__cplusplus)
+#  define ZPL_STATIC_CAST(T, expr) (static_cast<T>(expr))
+#else
+#  define ZPL_STATIC_CAST(T, expr) ((T) (expr))
+#endif
+
+#if defined(ZPL_CPP_CAST)
+#  undef ZPL_CPP_CAST
+#endif
+#if defined(__cplusplus)
+#  if ZPL_HAS_WARNING("-Wold-style-cast")
+#    define ZPL_CPP_CAST(T, expr) \
+       ZPL_DIAGNOSTIC_PUSH \
+       _Pragma("clang diagnostic ignored \"-Wold-style-cast\"") \
+       ((T) (expr)) \
+       ZPL_DIAGNOSTIC_POP
+#  elif ZPL_IAR_VERSION_CHECK(8,3,0)
+#    define ZPL_CPP_CAST(T, expr) \
+       ZPL_DIAGNOSTIC_PUSH \
+       _Pragma("diag_suppress=Pe137") \
+       ZPL_DIAGNOSTIC_POP \
+#  else
+#    define ZPL_CPP_CAST(T, expr) ((T) (expr))
+#  endif
+#else
+#  define ZPL_CPP_CAST(T, expr) (expr)
+#endif
+
+#if \
+  (defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 199901L)) || \
+  defined(__clang__) || \
+  ZPL_GCC_VERSION_CHECK(3,0,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_IAR_VERSION_CHECK(8,0,0) || \
+  ZPL_PGI_VERSION_CHECK(18,4,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(4,7,0) || \
+  ZPL_TI_CL430_VERSION_CHECK(2,0,1) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,1,0) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,0,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0) || \
+  ZPL_CRAY_VERSION_CHECK(5,0,0) || \
+  ZPL_TINYC_VERSION_CHECK(0,9,17) || \
+  ZPL_SUNPRO_VERSION_CHECK(8,0,0) || \
+  (ZPL_IBM_VERSION_CHECK(10,1,0) && defined(__C99_PRAGMA_OPERATOR))
+#  define ZPL_PRAGMA(value) _Pragma(#value)
+#elif ZPL_MSVC_VERSION_CHECK(15,0,0)
+#  define ZPL_PRAGMA(value) __pragma(value)
+#else
+#  define ZPL_PRAGMA(value)
+#endif
+
+#if defined(ZPL_DIAGNOSTIC_PUSH)
+#  undef ZPL_DIAGNOSTIC_PUSH
+#endif
+#if defined(ZPL_DIAGNOSTIC_POP)
+#  undef ZPL_DIAGNOSTIC_POP
+#endif
+#if defined(__clang__)
+#  define ZPL_DIAGNOSTIC_PUSH _Pragma("clang diagnostic push")
+#  define ZPL_DIAGNOSTIC_POP _Pragma("clang diagnostic pop")
+#elif ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_DIAGNOSTIC_PUSH _Pragma("warning(push)")
+#  define ZPL_DIAGNOSTIC_POP _Pragma("warning(pop)")
+#elif ZPL_GCC_VERSION_CHECK(4,6,0)
+#  define ZPL_DIAGNOSTIC_PUSH _Pragma("GCC diagnostic push")
+#  define ZPL_DIAGNOSTIC_POP _Pragma("GCC diagnostic pop")
+#elif ZPL_MSVC_VERSION_CHECK(15,0,0)
+#  define ZPL_DIAGNOSTIC_PUSH __pragma(warning(push))
+#  define ZPL_DIAGNOSTIC_POP __pragma(warning(pop))
+#elif ZPL_ARM_VERSION_CHECK(5,6,0)
+#  define ZPL_DIAGNOSTIC_PUSH _Pragma("push")
+#  define ZPL_DIAGNOSTIC_POP _Pragma("pop")
+#elif \
+    ZPL_TI_VERSION_CHECK(15,12,0) || \
+    ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+    ZPL_TI_CL430_VERSION_CHECK(4,4,0) || \
+    ZPL_TI_CL6X_VERSION_CHECK(8,1,0) || \
+    ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+    ZPL_TI_CLPRU_VERSION_CHECK(2,1,0)
+#  define ZPL_DIAGNOSTIC_PUSH _Pragma("diag_push")
+#  define ZPL_DIAGNOSTIC_POP _Pragma("diag_pop")
+#elif ZPL_PELLES_VERSION_CHECK(2,90,0)
+#  define ZPL_DIAGNOSTIC_PUSH _Pragma("warning(push)")
+#  define ZPL_DIAGNOSTIC_POP _Pragma("warning(pop)")
+#else
+#  define ZPL_DIAGNOSTIC_PUSH
+#  define ZPL_DIAGNOSTIC_POP
+#endif
+
+#if defined(ZPL_DIAGNOSTIC_DISABLE_DEPRECATED)
+#  undef ZPL_DIAGNOSTIC_DISABLE_DEPRECATED
+#endif
+#if ZPL_HAS_WARNING("-Wdeprecated-declarations")
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED _Pragma("clang diagnostic ignored \"-Wdeprecated-declarations\"")
+#elif ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED _Pragma("warning(disable:1478 1786)")
+#elif ZPL_PGI_VERSION_CHECK(17,10,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED _Pragma("diag_suppress 1215,1444")
+#elif ZPL_GCC_VERSION_CHECK(4,3,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED _Pragma("GCC diagnostic ignored \"-Wdeprecated-declarations\"")
+#elif ZPL_MSVC_VERSION_CHECK(15,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED __pragma(warning(disable:4996))
+#elif \
+    ZPL_TI_VERSION_CHECK(15,12,0) || \
+    (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+    ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+    (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+    ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+    (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+    ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+    (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+    ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+    ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+    ZPL_TI_CLPRU_VERSION_CHECK(2,1,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED _Pragma("diag_suppress 1291,1718")
+#elif ZPL_SUNPRO_VERSION_CHECK(5,13,0) && !defined(__cplusplus)
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED _Pragma("error_messages(off,E_DEPRECATED_ATT,E_DEPRECATED_ATT_MESS)")
+#elif ZPL_SUNPRO_VERSION_CHECK(5,13,0) && defined(__cplusplus)
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED _Pragma("error_messages(off,symdeprecated,symdeprecated2)")
+#elif ZPL_IAR_VERSION_CHECK(8,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED _Pragma("diag_suppress=Pe1444,Pe1215")
+#elif ZPL_PELLES_VERSION_CHECK(2,90,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED _Pragma("warn(disable:2241)")
+#else
+#  define ZPL_DIAGNOSTIC_DISABLE_DEPRECATED
+#endif
+
+#if defined(ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS)
+#  undef ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS
+#endif
+#if ZPL_HAS_WARNING("-Wunknown-pragmas")
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS _Pragma("clang diagnostic ignored \"-Wunknown-pragmas\"")
+#elif ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS _Pragma("warning(disable:161)")
+#elif ZPL_PGI_VERSION_CHECK(17,10,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS _Pragma("diag_suppress 1675")
+#elif ZPL_GCC_VERSION_CHECK(4,3,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS _Pragma("GCC diagnostic ignored \"-Wunknown-pragmas\"")
+#elif ZPL_MSVC_VERSION_CHECK(15,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS __pragma(warning(disable:4068))
+#elif \
+    ZPL_TI_VERSION_CHECK(16,9,0) || \
+    ZPL_TI_CL6X_VERSION_CHECK(8,0,0) || \
+    ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+    ZPL_TI_CLPRU_VERSION_CHECK(2,3,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS _Pragma("diag_suppress 163")
+#elif ZPL_TI_CL6X_VERSION_CHECK(8,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS _Pragma("diag_suppress 163")
+#elif ZPL_IAR_VERSION_CHECK(8,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS _Pragma("diag_suppress=Pe161")
+#else
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS
+#endif
+
+#if defined(ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES)
+#  undef ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES
+#endif
+#if ZPL_HAS_WARNING("-Wunknown-attributes")
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES _Pragma("clang diagnostic ignored \"-Wunknown-attributes\"")
+#elif ZPL_GCC_VERSION_CHECK(4,6,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES _Pragma("GCC diagnostic ignored \"-Wdeprecated-declarations\"")
+#elif ZPL_INTEL_VERSION_CHECK(17,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES _Pragma("warning(disable:1292)")
+#elif ZPL_MSVC_VERSION_CHECK(19,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES __pragma(warning(disable:5030))
+#elif ZPL_PGI_VERSION_CHECK(17,10,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES _Pragma("diag_suppress 1097")
+#elif ZPL_SUNPRO_VERSION_CHECK(5,14,0) && defined(__cplusplus)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES _Pragma("error_messages(off,attrskipunsup)")
+#elif \
+    ZPL_TI_VERSION_CHECK(18,1,0) || \
+    ZPL_TI_CL6X_VERSION_CHECK(8,3,0) || \
+    ZPL_TI_CL7X_VERSION_CHECK(1,2,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES _Pragma("diag_suppress 1173")
+#elif ZPL_IAR_VERSION_CHECK(8,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES _Pragma("diag_suppress=Pe1097")
+#else
+#  define ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_CPP_ATTRIBUTES
+#endif
+
+#if defined(ZPL_DIAGNOSTIC_DISABLE_CAST_QUAL)
+#  undef ZPL_DIAGNOSTIC_DISABLE_CAST_QUAL
+#endif
+#if ZPL_HAS_WARNING("-Wcast-qual")
+#  define ZPL_DIAGNOSTIC_DISABLE_CAST_QUAL _Pragma("clang diagnostic ignored \"-Wcast-qual\"")
+#elif ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_CAST_QUAL _Pragma("warning(disable:2203 2331)")
+#elif ZPL_GCC_VERSION_CHECK(3,0,0)
+#  define ZPL_DIAGNOSTIC_DISABLE_CAST_QUAL _Pragma("GCC diagnostic ignored \"-Wcast-qual\"")
+#else
+#  define ZPL_DIAGNOSTIC_DISABLE_CAST_QUAL
+#endif
+
+#if defined(ZPL_DEPRECATED)
+#  undef ZPL_DEPRECATED
+#endif
+#if defined(ZPL_DEPRECATED_FOR)
+#  undef ZPL_DEPRECATED_FOR
+#endif
+#if defined(__cplusplus) && (__cplusplus >= 201402L)
+#  define ZPL_DEPRECATED(since) ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_([[deprecated("Since " #since)]])
+#  define ZPL_DEPRECATED_FOR(since, replacement) ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_([[deprecated("Since " #since "; use " #replacement)]])
+#elif \
+  ZPL_HAS_EXTENSION(attribute_deprecated_with_message) || \
+  ZPL_GCC_VERSION_CHECK(4,5,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_ARM_VERSION_CHECK(5,6,0) || \
+  ZPL_SUNPRO_VERSION_CHECK(5,13,0) || \
+  ZPL_PGI_VERSION_CHECK(17,10,0) || \
+  ZPL_TI_VERSION_CHECK(18,1,0) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(18,1,0) || \
+  ZPL_TI_CL6X_VERSION_CHECK(8,3,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,3,0)
+#  define ZPL_DEPRECATED(since) __attribute__((__deprecated__("Since " #since)))
+#  define ZPL_DEPRECATED_FOR(since, replacement) __attribute__((__deprecated__("Since " #since "; use " #replacement)))
+#elif \
+  ZPL_HAS_ATTRIBUTE(deprecated) || \
+  ZPL_GCC_VERSION_CHECK(3,1,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+  (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+  (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0)
+#  define ZPL_DEPRECATED(since) __attribute__((__deprecated__))
+#  define ZPL_DEPRECATED_FOR(since, replacement) __attribute__((__deprecated__))
+#elif ZPL_MSVC_VERSION_CHECK(14,0,0)
+#  define ZPL_DEPRECATED(since) __declspec(deprecated("Since " # since))
+#  define ZPL_DEPRECATED_FOR(since, replacement) __declspec(deprecated("Since " #since "; use " #replacement))
+#elif \
+  ZPL_MSVC_VERSION_CHECK(13,10,0) || \
+  ZPL_PELLES_VERSION_CHECK(6,50,0)
+#  define ZPL_DEPRECATED(since) __declspec(deprecated)
+#  define ZPL_DEPRECATED_FOR(since, replacement) __declspec(deprecated)
+#elif ZPL_IAR_VERSION_CHECK(8,0,0)
+#  define ZPL_DEPRECATED(since) _Pragma("deprecated")
+#  define ZPL_DEPRECATED_FOR(since, replacement) _Pragma("deprecated")
+#else
+#  define ZPL_DEPRECATED(since)
+#  define ZPL_DEPRECATED_FOR(since, replacement)
+#endif
+
+#if defined(ZPL_UNAVAILABLE)
+#  undef ZPL_UNAVAILABLE
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(warning) || \
+  ZPL_GCC_VERSION_CHECK(4,3,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_UNAVAILABLE(available_since) __attribute__((__warning__("Not available until " #available_since)))
+#else
+#  define ZPL_UNAVAILABLE(available_since)
+#endif
+
+#if defined(ZPL_WARN_UNUSED_RESULT)
+#  undef ZPL_WARN_UNUSED_RESULT
+#endif
+#if defined(ZPL_WARN_UNUSED_RESULT_MSG)
+#  undef ZPL_WARN_UNUSED_RESULT_MSG
+#endif
+#if (ZPL_HAS_CPP_ATTRIBUTE(nodiscard) >= 201907L)
+#  define ZPL_WARN_UNUSED_RESULT ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_([[nodiscard]])
+#  define ZPL_WARN_UNUSED_RESULT_MSG(msg) ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_([[nodiscard(msg)]])
+#elif ZPL_HAS_CPP_ATTRIBUTE(nodiscard)
+#  define ZPL_WARN_UNUSED_RESULT ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_([[nodiscard]])
+#  define ZPL_WARN_UNUSED_RESULT_MSG(msg) ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_([[nodiscard]])
+#elif \
+  ZPL_HAS_ATTRIBUTE(warn_unused_result) || \
+  ZPL_GCC_VERSION_CHECK(3,4,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+  (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+  (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0) || \
+  (ZPL_SUNPRO_VERSION_CHECK(5,15,0) && defined(__cplusplus)) || \
+  ZPL_PGI_VERSION_CHECK(17,10,0)
+#  define ZPL_WARN_UNUSED_RESULT __attribute__((__warn_unused_result__))
+#  define ZPL_WARN_UNUSED_RESULT_MSG(msg) __attribute__((__warn_unused_result__))
+#elif defined(_Check_return_) /* SAL */
+#  define ZPL_WARN_UNUSED_RESULT _Check_return_
+#  define ZPL_WARN_UNUSED_RESULT_MSG(msg) _Check_return_
+#else
+#  define ZPL_WARN_UNUSED_RESULT
+#  define ZPL_WARN_UNUSED_RESULT_MSG(msg)
+#endif
+
+#if defined(ZPL_SENTINEL)
+#  undef ZPL_SENTINEL
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(sentinel) || \
+  ZPL_GCC_VERSION_CHECK(4,0,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_ARM_VERSION_CHECK(5,4,0)
+#  define ZPL_SENTINEL(position) __attribute__((__sentinel__(position)))
+#else
+#  define ZPL_SENTINEL(position)
+#endif
+
+#if defined(ZPL_NO_RETURN)
+#  undef ZPL_NO_RETURN
+#endif
+#if ZPL_IAR_VERSION_CHECK(8,0,0)
+#  define ZPL_NO_RETURN __noreturn
+#elif ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_NO_RETURN __attribute__((__noreturn__))
+#elif defined(__STDC_VERSION__) && __STDC_VERSION__ >= 201112L
+#  define ZPL_NO_RETURN _Noreturn
+#elif defined(__cplusplus) && (__cplusplus >= 201103L)
+#  define ZPL_NO_RETURN ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_([[noreturn]])
+#elif \
+  ZPL_HAS_ATTRIBUTE(noreturn) || \
+  ZPL_GCC_VERSION_CHECK(3,2,0) || \
+  ZPL_SUNPRO_VERSION_CHECK(5,11,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_IBM_VERSION_CHECK(10,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+  (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+  (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0)
+#  define ZPL_NO_RETURN __attribute__((__noreturn__))
+#elif ZPL_SUNPRO_VERSION_CHECK(5,10,0)
+#  define ZPL_NO_RETURN _Pragma("does_not_return")
+#elif ZPL_MSVC_VERSION_CHECK(13,10,0)
+#  define ZPL_NO_RETURN __declspec(noreturn)
+#elif ZPL_TI_CL6X_VERSION_CHECK(6,0,0) && defined(__cplusplus)
+#  define ZPL_NO_RETURN _Pragma("FUNC_NEVER_RETURNS;")
+#elif ZPL_COMPCERT_VERSION_CHECK(3,2,0)
+#  define ZPL_NO_RETURN __attribute((noreturn))
+#elif ZPL_PELLES_VERSION_CHECK(9,0,0)
+#  define ZPL_NO_RETURN __declspec(noreturn)
+#else
+#  define ZPL_NO_RETURN
+#endif
+
+#if defined(ZPL_NO_ESCAPE)
+#  undef ZPL_NO_ESCAPE
+#endif
+#if ZPL_HAS_ATTRIBUTE(noescape)
+#  define ZPL_NO_ESCAPE __attribute__((__noescape__))
+#else
+#  define ZPL_NO_ESCAPE
+#endif
+
+#if defined(ZPL_UNREACHABLE)
+#  undef ZPL_UNREACHABLE
+#endif
+#if defined(ZPL_UNREACHABLE_RETURN)
+#  undef ZPL_UNREACHABLE_RETURN
+#endif
+#if defined(ZPL_ASSUME)
+#  undef ZPL_ASSUME
+#endif
+#if \
+  ZPL_MSVC_VERSION_CHECK(13,10,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_ASSUME(expr) __assume(expr)
+#elif ZPL_HAS_BUILTIN(__builtin_assume)
+#  define ZPL_ASSUME(expr) __builtin_assume(expr)
+#elif \
+    ZPL_TI_CL2000_VERSION_CHECK(6,2,0) || \
+    ZPL_TI_CL6X_VERSION_CHECK(4,0,0)
+#  if defined(__cplusplus)
+#    define ZPL_ASSUME(expr) std::_nassert(expr)
+#  else
+#    define ZPL_ASSUME(expr) _nassert(expr)
+#  endif
+#endif
+#if \
+  (ZPL_HAS_BUILTIN(__builtin_unreachable) && (!defined(ZPL_ARM_VERSION))) || \
+  ZPL_GCC_VERSION_CHECK(4,5,0) || \
+  ZPL_PGI_VERSION_CHECK(18,10,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_IBM_VERSION_CHECK(13,1,5)
+#  define ZPL_UNREACHABLE() __builtin_unreachable()
+#elif defined(ZPL_ASSUME)
+#  define ZPL_UNREACHABLE() ZPL_ASSUME(0)
+#endif
+#if !defined(ZPL_ASSUME)
+#  if defined(ZPL_UNREACHABLE)
+#    define ZPL_ASSUME(expr) ZPL_STATIC_CAST(void, ((expr) ? 1 : (ZPL_UNREACHABLE(), 1)))
+#  else
+#    define ZPL_ASSUME(expr) ZPL_STATIC_CAST(void, expr)
+#  endif
+#endif
+#if defined(ZPL_UNREACHABLE)
+#  if  \
+      ZPL_TI_CL2000_VERSION_CHECK(6,2,0) || \
+      ZPL_TI_CL6X_VERSION_CHECK(4,0,0)
+#    define ZPL_UNREACHABLE_RETURN(value) return (ZPL_STATIC_CAST(void, ZPL_ASSUME(0)), (value))
+#  else
+#    define ZPL_UNREACHABLE_RETURN(value) ZPL_UNREACHABLE()
+#  endif
+#else
+#  define ZPL_UNREACHABLE_RETURN(value) return (value)
+#endif
+#if !defined(ZPL_UNREACHABLE)
+#  define ZPL_UNREACHABLE() ZPL_ASSUME(0)
+#endif
+
+ZPL_DIAGNOSTIC_PUSH
+#if ZPL_HAS_WARNING("-Wpedantic")
+#  pragma clang diagnostic ignored "-Wpedantic"
+#endif
+#if ZPL_HAS_WARNING("-Wc++98-compat-pedantic") && defined(__cplusplus)
+#  pragma clang diagnostic ignored "-Wc++98-compat-pedantic"
+#endif
+#if ZPL_GCC_HAS_WARNING("-Wvariadic-macros",4,0,0)
+#  if defined(__clang__)
+#    pragma clang diagnostic ignored "-Wvariadic-macros"
+#  elif defined(ZPL_GCC_VERSION)
+#    pragma GCC diagnostic ignored "-Wvariadic-macros"
+#  endif
+#endif
+#if defined(ZPL_NON_NULL)
+#  undef ZPL_NON_NULL
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(nonnull) || \
+  ZPL_GCC_VERSION_CHECK(3,3,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0)
+#  define ZPL_NON_NULL(...) __attribute__((__nonnull__(__VA_ARGS__)))
+#else
+#  define ZPL_NON_NULL(...)
+#endif
+ZPL_DIAGNOSTIC_POP
+
+#if defined(ZPL_PRINTF_FORMAT)
+#  undef ZPL_PRINTF_FORMAT
+#endif
+#if defined(__MINGW32__) && ZPL_GCC_HAS_ATTRIBUTE(format,4,4,0) && !defined(__USE_MINGW_ANSI_STDIO)
+#  define ZPL_PRINTF_FORMAT(string_idx,first_to_check) __attribute__((__format__(ms_printf, string_idx, first_to_check)))
+#elif defined(__MINGW32__) && ZPL_GCC_HAS_ATTRIBUTE(format,4,4,0) && defined(__USE_MINGW_ANSI_STDIO)
+#  define ZPL_PRINTF_FORMAT(string_idx,first_to_check) __attribute__((__format__(gnu_printf, string_idx, first_to_check)))
+#elif \
+  ZPL_HAS_ATTRIBUTE(format) || \
+  ZPL_GCC_VERSION_CHECK(3,1,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_ARM_VERSION_CHECK(5,6,0) || \
+  ZPL_IBM_VERSION_CHECK(10,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+  (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+  (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0)
+#  define ZPL_PRINTF_FORMAT(string_idx,first_to_check) __attribute__((__format__(__printf__, string_idx, first_to_check)))
+#elif ZPL_PELLES_VERSION_CHECK(6,0,0)
+#  define ZPL_PRINTF_FORMAT(string_idx,first_to_check) __declspec(vaformat(printf,string_idx,first_to_check))
+#else
+#  define ZPL_PRINTF_FORMAT(string_idx,first_to_check)
+#endif
+
+#if defined(ZPL_CONSTEXPR)
+#  undef ZPL_CONSTEXPR
+#endif
+#if defined(__cplusplus)
+#  if __cplusplus >= 201103L
+#    define ZPL_CONSTEXPR ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_(constexpr)
+#  endif
+#endif
+#if !defined(ZPL_CONSTEXPR)
+#  define ZPL_CONSTEXPR
+#endif
+
+#if defined(ZPL_PREDICT)
+#  undef ZPL_PREDICT
+#endif
+#if defined(ZPL_LIKELY)
+#  undef ZPL_LIKELY
+#endif
+#if defined(ZPL_UNLIKELY)
+#  undef ZPL_UNLIKELY
+#endif
+#if defined(ZPL_UNPREDICTABLE)
+#  undef ZPL_UNPREDICTABLE
+#endif
+#if ZPL_HAS_BUILTIN(__builtin_unpredictable)
+#  define ZPL_UNPREDICTABLE(expr) __builtin_unpredictable((expr))
+#endif
+#if \
+  ZPL_HAS_BUILTIN(__builtin_expect_with_probability) || \
+  ZPL_GCC_VERSION_CHECK(9,0,0)
+#  define ZPL_PREDICT(expr, value, probability) __builtin_expect_with_probability(  (expr), (value), (probability))
+#  define ZPL_PREDICT_TRUE(expr, probability)   __builtin_expect_with_probability(!!(expr),    1   , (probability))
+#  define ZPL_PREDICT_FALSE(expr, probability)  __builtin_expect_with_probability(!!(expr),    0   , (probability))
+#  define ZPL_LIKELY(expr)                      __builtin_expect                 (!!(expr),    1                  )
+#  define ZPL_UNLIKELY(expr)                    __builtin_expect                 (!!(expr),    0                  )
+#elif \
+  ZPL_HAS_BUILTIN(__builtin_expect) || \
+  ZPL_GCC_VERSION_CHECK(3,0,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  (ZPL_SUNPRO_VERSION_CHECK(5,15,0) && defined(__cplusplus)) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_IBM_VERSION_CHECK(10,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(4,7,0) || \
+  ZPL_TI_CL430_VERSION_CHECK(3,1,0) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,1,0) || \
+  ZPL_TI_CL6X_VERSION_CHECK(6,1,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0) || \
+  ZPL_TINYC_VERSION_CHECK(0,9,27) || \
+  ZPL_CRAY_VERSION_CHECK(8,1,0)
+#  define ZPL_PREDICT(expr, expected, probability) \
+     (((probability) >= 0.9) ? __builtin_expect((expr), (expected)) : (ZPL_STATIC_CAST(void, expected), (expr)))
+#  define ZPL_PREDICT_TRUE(expr, probability) \
+     (__extension__ ({ \
+       double zpl_probability_ = (probability); \
+       ((zpl_probability_ >= 0.9) ? __builtin_expect(!!(expr), 1) : ((zpl_probability_ <= 0.1) ? __builtin_expect(!!(expr), 0) : !!(expr))); \
+     }))
+#  define ZPL_PREDICT_FALSE(expr, probability) \
+     (__extension__ ({ \
+       double zpl_probability_ = (probability); \
+       ((zpl_probability_ >= 0.9) ? __builtin_expect(!!(expr), 0) : ((zpl_probability_ <= 0.1) ? __builtin_expect(!!(expr), 1) : !!(expr))); \
+     }))
+#  define ZPL_LIKELY(expr)   __builtin_expect(!!(expr), 1)
+#  define ZPL_UNLIKELY(expr) __builtin_expect(!!(expr), 0)
+#else
+#  define ZPL_PREDICT(expr, expected, probability) (ZPL_STATIC_CAST(void, expected), (expr))
+#  define ZPL_PREDICT_TRUE(expr, probability) (!!(expr))
+#  define ZPL_PREDICT_FALSE(expr, probability) (!!(expr))
+#  define ZPL_LIKELY(expr) (!!(expr))
+#  define ZPL_UNLIKELY(expr) (!!(expr))
+#endif
+#if !defined(ZPL_UNPREDICTABLE)
+#  define ZPL_UNPREDICTABLE(expr) ZPL_PREDICT(expr, 1, 0.5)
+#endif
+
+#if defined(ZPL_MALLOC)
+#  undef ZPL_MALLOC
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(malloc) || \
+  ZPL_GCC_VERSION_CHECK(3,1,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_SUNPRO_VERSION_CHECK(5,11,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_IBM_VERSION_CHECK(12,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+  (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+  (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0)
+#  define ZPL_MALLOC __attribute__((__malloc__))
+#elif ZPL_SUNPRO_VERSION_CHECK(5,10,0)
+#  define ZPL_MALLOC _Pragma("returns_new_memory")
+#elif ZPL_MSVC_VERSION_CHECK(14, 0, 0)
+#  define ZPL_MALLOC __declspec(restrict)
+#else
+#  define ZPL_MALLOC
+#endif
+
+#if defined(ZPL_PURE)
+#  undef ZPL_PURE
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(pure) || \
+  ZPL_GCC_VERSION_CHECK(2,96,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_SUNPRO_VERSION_CHECK(5,11,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_IBM_VERSION_CHECK(10,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+  (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+  (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0) || \
+  ZPL_PGI_VERSION_CHECK(17,10,0)
+#  define ZPL_PURE __attribute__((__pure__))
+#elif ZPL_SUNPRO_VERSION_CHECK(5,10,0)
+#  define ZPL_PURE _Pragma("does_not_write_global_data")
+#elif defined(__cplusplus) && \
+    ( \
+      ZPL_TI_CL430_VERSION_CHECK(2,0,1) || \
+      ZPL_TI_CL6X_VERSION_CHECK(4,0,0) || \
+      ZPL_TI_CL7X_VERSION_CHECK(1,2,0) \
+    )
+#  define ZPL_PURE _Pragma("FUNC_IS_PURE;")
+#else
+#  define ZPL_PURE
+#endif
+
+#if defined(ZPL_CONST)
+#  undef ZPL_CONST
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(const) || \
+  ZPL_GCC_VERSION_CHECK(2,5,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_SUNPRO_VERSION_CHECK(5,11,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_IBM_VERSION_CHECK(10,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+  (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+  (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0) || \
+  ZPL_PGI_VERSION_CHECK(17,10,0)
+#  define ZPL_CONST __attribute__((__const__))
+#elif \
+  ZPL_SUNPRO_VERSION_CHECK(5,10,0)
+#  define ZPL_CONST _Pragma("no_side_effect")
+#else
+#  define ZPL_CONST ZPL_PURE
+#endif
+
+#if defined(ZPL_RESTRICT)
+#  undef ZPL_RESTRICT
+#endif
+#if defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 199901L) && !defined(__cplusplus)
+#  define ZPL_RESTRICT restrict
+#elif \
+  ZPL_GCC_VERSION_CHECK(3,1,0) || \
+  ZPL_MSVC_VERSION_CHECK(14,0,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_IBM_VERSION_CHECK(10,1,0) || \
+  ZPL_PGI_VERSION_CHECK(17,10,0) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,2,4) || \
+  ZPL_TI_CL6X_VERSION_CHECK(8,1,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  (ZPL_SUNPRO_VERSION_CHECK(5,14,0) && defined(__cplusplus)) || \
+  ZPL_IAR_VERSION_CHECK(8,0,0) || \
+  defined(__clang__)
+#  define ZPL_RESTRICT __restrict
+#elif ZPL_SUNPRO_VERSION_CHECK(5,3,0) && !defined(__cplusplus)
+#  define ZPL_RESTRICT _Restrict
+#else
+#  define ZPL_RESTRICT
+#endif
+
+#if defined(ZPL_INLINE)
+#  undef ZPL_INLINE
+#endif
+#if \
+  (defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 199901L)) || \
+  (defined(__cplusplus) && (__cplusplus >= 199711L))
+#  define ZPL_INLINE inline
+#elif \
+  defined(ZPL_GCC_VERSION) || \
+  ZPL_ARM_VERSION_CHECK(6,2,0)
+#  define ZPL_INLINE __inline__
+#elif \
+  ZPL_MSVC_VERSION_CHECK(12,0,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,1,0) || \
+  ZPL_TI_CL430_VERSION_CHECK(3,1,0) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,2,0) || \
+  ZPL_TI_CL6X_VERSION_CHECK(8,0,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0)
+#  define ZPL_INLINE __inline
+#else
+#  define ZPL_INLINE
+#endif
+
+#if defined(ZPL_ALWAYS_INLINE)
+#  undef ZPL_ALWAYS_INLINE
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(always_inline) || \
+  ZPL_GCC_VERSION_CHECK(4,0,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_SUNPRO_VERSION_CHECK(5,11,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_IBM_VERSION_CHECK(10,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+  (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+  (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0)
+#  define ZPL_ALWAYS_INLINE __attribute__((__always_inline__)) ZPL_INLINE
+#elif ZPL_MSVC_VERSION_CHECK(12,0,0)
+#  define ZPL_ALWAYS_INLINE __forceinline
+#elif defined(__cplusplus) && \
+    ( \
+      ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+      ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+      ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+      ZPL_TI_CL6X_VERSION_CHECK(6,1,0) || \
+      ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+      ZPL_TI_CLPRU_VERSION_CHECK(2,1,0) \
+    )
+#  define ZPL_ALWAYS_INLINE _Pragma("FUNC_ALWAYS_INLINE;")
+#elif ZPL_IAR_VERSION_CHECK(8,0,0)
+#  define ZPL_ALWAYS_INLINE _Pragma("inline=forced")
+#else
+#  define ZPL_ALWAYS_INLINE ZPL_INLINE
+#endif
+
+#if defined(ZPL_NEVER_INLINE)
+#  undef ZPL_NEVER_INLINE
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(noinline) || \
+  ZPL_GCC_VERSION_CHECK(4,0,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_SUNPRO_VERSION_CHECK(5,11,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_IBM_VERSION_CHECK(10,1,0) || \
+  ZPL_TI_VERSION_CHECK(15,12,0) || \
+  (ZPL_TI_ARMCL_VERSION_CHECK(4,8,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_ARMCL_VERSION_CHECK(5,2,0) || \
+  (ZPL_TI_CL2000_VERSION_CHECK(6,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL2000_VERSION_CHECK(6,4,0) || \
+  (ZPL_TI_CL430_VERSION_CHECK(4,0,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL430_VERSION_CHECK(4,3,0) || \
+  (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+  ZPL_TI_CL6X_VERSION_CHECK(7,5,0) || \
+  ZPL_TI_CL7X_VERSION_CHECK(1,2,0) || \
+  ZPL_TI_CLPRU_VERSION_CHECK(2,1,0)
+#  define ZPL_NEVER_INLINE __attribute__((__noinline__))
+#elif ZPL_MSVC_VERSION_CHECK(13,10,0)
+#  define ZPL_NEVER_INLINE __declspec(noinline)
+#elif ZPL_PGI_VERSION_CHECK(10,2,0)
+#  define ZPL_NEVER_INLINE _Pragma("noinline")
+#elif ZPL_TI_CL6X_VERSION_CHECK(6,0,0) && defined(__cplusplus)
+#  define ZPL_NEVER_INLINE _Pragma("FUNC_CANNOT_INLINE;")
+#elif ZPL_IAR_VERSION_CHECK(8,0,0)
+#  define ZPL_NEVER_INLINE _Pragma("inline=never")
+#elif ZPL_COMPCERT_VERSION_CHECK(3,2,0)
+#  define ZPL_NEVER_INLINE __attribute((noinline))
+#elif ZPL_PELLES_VERSION_CHECK(9,0,0)
+#  define ZPL_NEVER_INLINE __declspec(noinline)
+#else
+#  define ZPL_NEVER_INLINE
+#endif
+
+#if defined(ZPL_PRIVATE)
+#  undef ZPL_PRIVATE
+#endif
+#if defined(ZPL_PUBLIC)
+#  undef ZPL_PUBLIC
+#endif
+#if defined(ZPL_IMPORT)
+#  undef ZPL_IMPORT
+#endif
+#if defined(_WIN32) || defined(__CYGWIN__)
+#  define ZPL_PRIVATE
+#  define ZPL_PUBLIC   __declspec(dllexport)
+#  define ZPL_IMPORT   __declspec(dllimport)
+#else
+#  if \
+    ZPL_HAS_ATTRIBUTE(visibility) || \
+    ZPL_GCC_VERSION_CHECK(3,3,0) || \
+    ZPL_SUNPRO_VERSION_CHECK(5,11,0) || \
+    ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+    ZPL_ARM_VERSION_CHECK(4,1,0) || \
+    ZPL_IBM_VERSION_CHECK(13,1,0) || \
+    ( \
+      defined(__TI_EABI__) && \
+      ( \
+        (ZPL_TI_CL6X_VERSION_CHECK(7,2,0) && defined(__TI_GNU_ATTRIBUTE_SUPPORT__)) || \
+        ZPL_TI_CL6X_VERSION_CHECK(7,5,0) \
+      ) \
+    )
+#    define ZPL_PRIVATE __attribute__((__visibility__("hidden")))
+#    define ZPL_PUBLIC  __attribute__((__visibility__("default")))
+#  else
+#    define ZPL_PRIVATE
+#    define ZPL_PUBLIC
+#  endif
+#  define ZPL_IMPORT    extern
+#endif
+
+#if defined(ZPL_NO_THROW)
+#  undef ZPL_NO_THROW
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(nothrow) || \
+  ZPL_GCC_VERSION_CHECK(3,3,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_NO_THROW __attribute__((__nothrow__))
+#elif \
+  ZPL_MSVC_VERSION_CHECK(13,1,0) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0)
+#  define ZPL_NO_THROW __declspec(nothrow)
+#else
+#  define ZPL_NO_THROW
+#endif
+
+#if defined(ZPL_FALL_THROUGH)
+# undef ZPL_FALL_THROUGH
+#endif
+#if ZPL_GNUC_HAS_ATTRIBUTE(fallthrough,7,0,0) && !defined(ZPL_PGI_VERSION)
+#  define ZPL_FALL_THROUGH __attribute__((__fallthrough__))
+#elif ZPL_HAS_CPP_ATTRIBUTE_NS(clang,fallthrough)
+#  define ZPL_FALL_THROUGH ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_([[clang::fallthrough]])
+#elif ZPL_HAS_CPP_ATTRIBUTE(fallthrough)
+#  define ZPL_FALL_THROUGH ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_([[fallthrough]])
+#elif defined(__fallthrough) /* SAL */
+#  define ZPL_FALL_THROUGH __fallthrough
+#else
+#  define ZPL_FALL_THROUGH
+#endif
+
+#if defined(ZPL_RETURNS_NON_NULL)
+#  undef ZPL_RETURNS_NON_NULL
+#endif
+#if \
+  ZPL_HAS_ATTRIBUTE(returns_nonnull) || \
+  ZPL_GCC_VERSION_CHECK(4,9,0)
+#  define ZPL_RETURNS_NON_NULL __attribute__((__returns_nonnull__))
+#elif defined(_Ret_notnull_) /* SAL */
+#  define ZPL_RETURNS_NON_NULL _Ret_notnull_
+#else
+#  define ZPL_RETURNS_NON_NULL
+#endif
+
+#if defined(ZPL_ARRAY_PARAM)
+#  undef ZPL_ARRAY_PARAM
+#endif
+#if \
+  defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 199901L) && \
+  !defined(__STDC_NO_VLA__) && \
+  !defined(__cplusplus) && \
+  !defined(ZPL_PGI_VERSION) && \
+  !defined(ZPL_TINYC_VERSION)
+#  define ZPL_ARRAY_PARAM(name) (name)
+#else
+#  define ZPL_ARRAY_PARAM(name)
+#endif
+
+#if defined(ZPL_IS_CONSTANT)
+#  undef ZPL_IS_CONSTANT
+#endif
+#if defined(ZPL_REQUIRE_CONSTEXPR)
+#  undef ZPL_REQUIRE_CONSTEXPR
+#endif
+/* ZPL_IS_CONSTEXPR_ is for
+   ZPL INTERNAL USE ONLY.  API subject to change without notice. */
+#if defined(ZPL_IS_CONSTEXPR_)
+#  undef ZPL_IS_CONSTEXPR_
+#endif
+#if \
+  ZPL_HAS_BUILTIN(__builtin_constant_p) || \
+  ZPL_GCC_VERSION_CHECK(3,4,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+  ZPL_TINYC_VERSION_CHECK(0,9,19) || \
+  ZPL_ARM_VERSION_CHECK(4,1,0) || \
+  ZPL_IBM_VERSION_CHECK(13,1,0) || \
+  ZPL_TI_CL6X_VERSION_CHECK(6,1,0) || \
+  (ZPL_SUNPRO_VERSION_CHECK(5,10,0) && !defined(__cplusplus)) || \
+  ZPL_CRAY_VERSION_CHECK(8,1,0)
+#  define ZPL_IS_CONSTANT(expr) __builtin_constant_p(expr)
+#endif
+#if !defined(__cplusplus)
+#  if \
+       ZPL_HAS_BUILTIN(__builtin_types_compatible_p) || \
+       ZPL_GCC_VERSION_CHECK(3,4,0) || \
+       ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+       ZPL_IBM_VERSION_CHECK(13,1,0) || \
+       ZPL_CRAY_VERSION_CHECK(8,1,0) || \
+       ZPL_ARM_VERSION_CHECK(5,4,0) || \
+       ZPL_TINYC_VERSION_CHECK(0,9,24)
+#    if defined(__INTPTR_TYPE__)
+#      define ZPL_IS_CONSTEXPR_(expr) __builtin_types_compatible_p(__typeof__((1 ? (void*) ((__INTPTR_TYPE__) ((expr) * 0)) : (int*) 0)), int*)
+#    else
+#      include <stdint.h>
+#      define ZPL_IS_CONSTEXPR_(expr) __builtin_types_compatible_p(__typeof__((1 ? (void*) ((intptr_t) ((expr) * 0)) : (int*) 0)), int*)
+#    endif
+#  elif \
+       ( \
+          defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 201112L) && \
+          !defined(ZPL_SUNPRO_VERSION) && \
+          !defined(ZPL_PGI_VERSION) && \
+          !defined(ZPL_IAR_VERSION)) || \
+       ZPL_HAS_EXTENSION(c_generic_selections) || \
+       ZPL_GCC_VERSION_CHECK(4,9,0) || \
+       ZPL_INTEL_VERSION_CHECK(17,0,0) || \
+       ZPL_IBM_VERSION_CHECK(12,1,0) || \
+       ZPL_ARM_VERSION_CHECK(5,3,0)
+#    if defined(__INTPTR_TYPE__)
+#      define ZPL_IS_CONSTEXPR_(expr) _Generic((1 ? (void*) ((__INTPTR_TYPE__) ((expr) * 0)) : (int*) 0), int*: 1, void*: 0)
+#    else
+#      include <stdint.h>
+#      define ZPL_IS_CONSTEXPR_(expr) _Generic((1 ? (void*) ((intptr_t) * 0) : (int*) 0), int*: 1, void*: 0)
+#    endif
+#  elif \
+       defined(ZPL_GCC_VERSION) || \
+       defined(ZPL_INTEL_VERSION) || \
+       defined(ZPL_TINYC_VERSION) || \
+       defined(ZPL_TI_ARMCL_VERSION) || \
+       ZPL_TI_CL430_VERSION_CHECK(18,12,0) || \
+       defined(ZPL_TI_CL2000_VERSION) || \
+       defined(ZPL_TI_CL6X_VERSION) || \
+       defined(ZPL_TI_CL7X_VERSION) || \
+       defined(ZPL_TI_CLPRU_VERSION) || \
+       defined(__clang__)
+#    define ZPL_IS_CONSTEXPR_(expr) ( \
+         sizeof(void) != \
+         sizeof(*( \
+           1 ? \
+             ((void*) ((expr) * 0L) ) : \
+             ((struct { char v[sizeof(void) * 2]; } *) 1) \
+           ) \
+         ) \
+       )
+#  endif
+#endif
+#if defined(ZPL_IS_CONSTEXPR_)
+#  if !defined(ZPL_IS_CONSTANT)
+#    define ZPL_IS_CONSTANT(expr) ZPL_IS_CONSTEXPR_(expr)
+#  endif
+#  define ZPL_REQUIRE_CONSTEXPR(expr) (ZPL_IS_CONSTEXPR_(expr) ? (expr) : (-1))
+#else
+#  if !defined(ZPL_IS_CONSTANT)
+#    define ZPL_IS_CONSTANT(expr) (0)
+#  endif
+#  define ZPL_REQUIRE_CONSTEXPR(expr) (expr)
+#endif
+
+#if defined(ZPL_BEGIN_C_DECLS)
+#  undef ZPL_BEGIN_C_DECLS
+#endif
+#if defined(ZPL_END_C_DECLS)
+#  undef ZPL_END_C_DECLS
+#endif
+#if defined(ZPL_C_DECL)
+#  undef ZPL_C_DECL
+#endif
+#if defined(__cplusplus)
+#  define ZPL_BEGIN_C_DECLS extern "C" {
+#  define ZPL_END_C_DECLS }
+#  define ZPL_C_DECL extern "C"
+#else
+#  define ZPL_BEGIN_C_DECLS
+#  define ZPL_END_C_DECLS
+#  define ZPL_C_DECL
+#endif
+
+#if defined(ZPL_STATIC_ASSERT)
+#  undef ZPL_STATIC_ASSERT
+#endif
+#if \
+  !defined(__cplusplus) && ( \
+      (defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 201112L)) || \
+      ZPL_HAS_FEATURE(c_static_assert) || \
+      ZPL_GCC_VERSION_CHECK(6,0,0) || \
+      ZPL_INTEL_VERSION_CHECK(13,0,0) || \
+      defined(_Static_assert) \
+    )
+#  define ZPL_STATIC_ASSERT(expr, message) _Static_assert(expr, message)
+#elif \
+  (defined(__cplusplus) && (__cplusplus >= 201103L)) || \
+  ZPL_MSVC_VERSION_CHECK(16,0,0)
+#  define ZPL_STATIC_ASSERT(expr, message) ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_(static_assert(expr, message))
+#else
+  #define ZPL_STATIC_ASSERT3(cond, msg) typedef char static_assertion_##msg[(!!(cond)) * 2 - 1]
+  #define ZPL_STATIC_ASSERT2(cond, line) ZPL_STATIC_ASSERT3(cond, static_assertion_at_line_##line)
+  #define ZPL_STATIC_ASSERT1(cond, line) ZPL_STATIC_ASSERT2(cond, line)
+  #define ZPL_STATIC_ASSERT(cond, unused) ZPL_STATIC_ASSERT1(cond, __LINE__)
+#endif
+
+#if defined(ZPL_NULL)
+#  undef ZPL_NULL
+#endif
+#if defined(__cplusplus)
+#  if __cplusplus >= 201103L
+#    define ZPL_NULL ZPL_DIAGNOSTIC_DISABLE_CPP98_COMPAT_WRAP_(nullptr)
+#  elif defined(NULL)
+#    define ZPL_NULL NULL
+#  else
+#    define ZPL_NULL ZPL_STATIC_CAST(void*, 0)
+#  endif
+#elif defined(NULL)
+#  define ZPL_NULL NULL
+#else
+#  define ZPL_NULL ((void*) 0)
+#endif
+
+#if defined(ZPL_MESSAGE)
+#  undef ZPL_MESSAGE
+#endif
+#if ZPL_HAS_WARNING("-Wunknown-pragmas")
+#  define ZPL_MESSAGE(msg) \
+  ZPL_DIAGNOSTIC_PUSH \
+  ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS \
+  ZPL_PRAGMA(message msg) \
+  ZPL_DIAGNOSTIC_POP
+#elif \
+  ZPL_GCC_VERSION_CHECK(4,4,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_MESSAGE(msg) ZPL_PRAGMA(message msg)
+#elif ZPL_CRAY_VERSION_CHECK(5,0,0)
+#  define ZPL_MESSAGE(msg) ZPL_PRAGMA(_CRI message msg)
+#elif ZPL_IAR_VERSION_CHECK(8,0,0)
+#  define ZPL_MESSAGE(msg) ZPL_PRAGMA(message(msg))
+#elif ZPL_PELLES_VERSION_CHECK(2,0,0)
+#  define ZPL_MESSAGE(msg) ZPL_PRAGMA(message(msg))
+#else
+#  define ZPL_MESSAGE(msg)
+#endif
+
+#if defined(ZPL_WARNING)
+#  undef ZPL_WARNING
+#endif
+#if ZPL_HAS_WARNING("-Wunknown-pragmas")
+#  define ZPL_WARNING(msg) \
+  ZPL_DIAGNOSTIC_PUSH \
+  ZPL_DIAGNOSTIC_DISABLE_UNKNOWN_PRAGMAS \
+  ZPL_PRAGMA(clang warning msg) \
+  ZPL_DIAGNOSTIC_POP
+#elif \
+  ZPL_GCC_VERSION_CHECK(4,8,0) || \
+  ZPL_PGI_VERSION_CHECK(18,4,0) || \
+  ZPL_INTEL_VERSION_CHECK(13,0,0)
+#  define ZPL_WARNING(msg) ZPL_PRAGMA(GCC warning msg)
+#elif ZPL_MSVC_VERSION_CHECK(15,0,0)
+#  define ZPL_WARNING(msg) ZPL_PRAGMA(message(msg))
+#else
+#  define ZPL_WARNING(msg) ZPL_MESSAGE(msg)
+#endif
+
+#if defined(ZPL_REQUIRE)
+#  undef ZPL_REQUIRE
+#endif
+#if defined(ZPL_REQUIRE_MSG)
+#  undef ZPL_REQUIRE_MSG
+#endif
+#if ZPL_HAS_ATTRIBUTE(diagnose_if)
+#  if ZPL_HAS_WARNING("-Wgcc-compat")
+#    define ZPL_REQUIRE(expr) \
+       ZPL_DIAGNOSTIC_PUSH \
+       _Pragma("clang diagnostic ignored \"-Wgcc-compat\"") \
+       __attribute__((diagnose_if(!(expr), #expr, "error"))) \
+       ZPL_DIAGNOSTIC_POP
+#    define ZPL_REQUIRE_MSG(expr,msg) \
+       ZPL_DIAGNOSTIC_PUSH \
+       _Pragma("clang diagnostic ignored \"-Wgcc-compat\"") \
+       __attribute__((diagnose_if(!(expr), msg, "error"))) \
+       ZPL_DIAGNOSTIC_POP
+#  else
+#    define ZPL_REQUIRE(expr) __attribute__((diagnose_if(!(expr), #expr, "error")))
+#    define ZPL_REQUIRE_MSG(expr,msg) __attribute__((diagnose_if(!(expr), msg, "error")))
+#  endif
+#else
+#  define ZPL_REQUIRE(expr)
+#  define ZPL_REQUIRE_MSG(expr,msg)
+#endif
+
+#if defined(ZPL_FLAGS)
+#  undef ZPL_FLAGS
+#endif
+#if ZPL_HAS_ATTRIBUTE(flag_enum)
+#  define ZPL_FLAGS __attribute__((__flag_enum__))
+#endif
+
+#if defined(ZPL_FLAGS_CAST)
+#  undef ZPL_FLAGS_CAST
+#endif
+#if ZPL_INTEL_VERSION_CHECK(19,0,0)
+#  define ZPL_FLAGS_CAST(T, expr) (__extension__ ({ \
+  ZPL_DIAGNOSTIC_PUSH \
+      _Pragma("warning(disable:188)") \
+      ((T) (expr)); \
+      ZPL_DIAGNOSTIC_POP \
+    }))
+#else
+#  define ZPL_FLAGS_CAST(T, expr) ZPL_STATIC_CAST(T, expr)
+#endif
+
+#if defined(ZPL_EMPTY_BASES)
+#  undef ZPL_EMPTY_BASES
+#endif
+#if ZPL_MSVC_VERSION_CHECK(19,0,23918) && !ZPL_MSVC_VERSION_CHECK(20,0,0)
+#  define ZPL_EMPTY_BASES __declspec(empty_bases)
+#else
+#  define ZPL_EMPTY_BASES
+#endif
+
+/* Remaining macros are deprecated. */
+
+#if defined(ZPL_GCC_NOT_CLANG_VERSION_CHECK)
+#  undef ZPL_GCC_NOT_CLANG_VERSION_CHECK
+#endif
+#if defined(__clang__)
+#  define ZPL_GCC_NOT_CLANG_VERSION_CHECK(major,minor,patch) (0)
+#else
+#  define ZPL_GCC_NOT_CLANG_VERSION_CHECK(major,minor,patch) ZPL_GCC_VERSION_CHECK(major,minor,patch)
+#endif
+
+#if defined(ZPL_CLANG_HAS_ATTRIBUTE)
+#  undef ZPL_CLANG_HAS_ATTRIBUTE
+#endif
+#define ZPL_CLANG_HAS_ATTRIBUTE(attribute) ZPL_HAS_ATTRIBUTE(attribute)
+
+#if defined(ZPL_CLANG_HAS_CPP_ATTRIBUTE)
+#  undef ZPL_CLANG_HAS_CPP_ATTRIBUTE
+#endif
+#define ZPL_CLANG_HAS_CPP_ATTRIBUTE(attribute) ZPL_HAS_CPP_ATTRIBUTE(attribute)
+
+#if defined(ZPL_CLANG_HAS_BUILTIN)
+#  undef ZPL_CLANG_HAS_BUILTIN
+#endif
+#define ZPL_CLANG_HAS_BUILTIN(builtin) ZPL_HAS_BUILTIN(builtin)
+
+#if defined(ZPL_CLANG_HAS_FEATURE)
+#  undef ZPL_CLANG_HAS_FEATURE
+#endif
+#define ZPL_CLANG_HAS_FEATURE(feature) ZPL_HAS_FEATURE(feature)
+
+#if defined(ZPL_CLANG_HAS_EXTENSION)
+#  undef ZPL_CLANG_HAS_EXTENSION
+#endif
+#define ZPL_CLANG_HAS_EXTENSION(extension) ZPL_HAS_EXTENSION(extension)
+
+#if defined(ZPL_CLANG_HAS_DECLSPEC_DECLSPEC_ATTRIBUTE)
+#  undef ZPL_CLANG_HAS_DECLSPEC_DECLSPEC_ATTRIBUTE
+#endif
+#define ZPL_CLANG_HAS_DECLSPEC_ATTRIBUTE(attribute) ZPL_HAS_DECLSPEC_ATTRIBUTE(attribute)
+
+#if defined(ZPL_CLANG_HAS_WARNING)
+#  undef ZPL_CLANG_HAS_WARNING
+#endif
+#define ZPL_CLANG_HAS_WARNING(warning) ZPL_HAS_WARNING(warning)
+
+#endif /* !defined(ZPL_HEDLEY_VERSION) || (ZPL_HEDLEY_VERSION < X) */
+
+#define ZPL_VERSION ZPL_VERSION_ENCODE(ZPL_VERSION_MAJOR, ZPL_VERSION_MINOR, ZPL_VERSION_PATCH)
+
+#ifdef ZPL_IMPL
+    #ifndef ZPL_IMPLEMENTATION
+    #define ZPL_IMPLEMENTATION
+    #endif
+#endif
+
+#if defined(__cplusplus) && !defined(ZPL_EXTERN)
+    #define ZPL_EXTERN extern "C"
+#else
+    #define ZPL_EXTERN extern
+#endif
+
+#ifndef ZPL_DEF
+    #if defined(ZPL_SHARED_LIB)
+        #ifdef ZPL_IMPLEMENTATION
+            #define ZPL_DEF ZPL_PUBLIC
+        #else
+            #define ZPL_DEF ZPL_IMPORT
+        #endif
+    #elif defined(ZPL_STATIC_LIB)
+        #ifdef ZPL_IMPLEMENTATION
+            #define ZPL_DEF
+        #else
+            #define ZPL_DEF ZPL_EXTERN
+        #endif
+    #elif defined(ZPL_STATIC)
+        #define ZPL_DEF static
+    #else
+        #define ZPL_DEF ZPL_EXTERN
+    #endif
+#endif
+
+#ifndef ZPL_DEF_INLINE
+    #if defined(ZPL_STATIC)
+        #define ZPL_DEF_INLINE
+        #define ZPL_IMPL_INLINE
+    #else
+        #define ZPL_DEF_INLINE ZPL_ALWAYS_INLINE
+        #define ZPL_IMPL_INLINE ZPL_INLINE
+    #endif
+#endif
+
+/* Architecture-specific overrides */
+#if defined(__ARM_ARCH)
+    #define ZPL_DISABLE_THREADING
+#endif
+
+/* Distributions */
+#ifndef ZPL_CUSTOM_MODULES
+    /* default distribution */
+    #define ZPL_MODULE_CORE
+    #define ZPL_MODULE_TIMER
+    #define ZPL_MODULE_HASHING
+    #define ZPL_MODULE_REGEX
+    #define ZPL_MODULE_EVENT
+    #define ZPL_MODULE_DLL
+    #define ZPL_MODULE_OPTS
+    #define ZPL_MODULE_PROCESS
+    #define ZPL_MODULE_MATH
+    #define ZPL_MODULE_JSON
+    #define ZPL_MODULE_THREADING
+    #define ZPL_MODULE_JOBS
+    #define ZPL_MODULE_COROUTINES
+
+    /* zpl nano distribution */
+    #if defined(ZPL_NANO)
+        #undef ZPL_MODULE_TIMER
+        #undef ZPL_MODULE_HASHING
+        #undef ZPL_MODULE_REGEX
+        #undef ZPL_MODULE_EVENT
+        #undef ZPL_MODULE_DLL
+        #undef ZPL_MODULE_OPTS
+        #undef ZPL_MODULE_PROCESS
+        #undef ZPL_MODULE_MATH
+        #undef ZPL_MODULE_JSON
+        #undef ZPL_MODULE_THREADING
+        #undef ZPL_MODULE_JOBS
+        #undef ZPL_MODULE_COROUTINES
+    #endif
+
+    /* module enabling overrides */
+    #if defined(ZPL_ENABLE_CORE) && !defined(ZPL_MODULE_CORE)
+        #define ZPL_MODULE_CORE
+    #endif
+    #if defined(ZPL_ENABLE_TIMER) && !defined(ZPL_MODULE_TIMER)
+        #define ZPL_MODULE_TIMER
+    #endif
+    #if defined(ZPL_ENABLE_HASHING) && !defined(ZPL_MODULE_HASHING)
+        #define ZPL_MODULE_HASHING
+    #endif
+    #if defined(ZPL_ENABLE_REGEX) && !defined(ZPL_MODULE_REGEX)
+        #define ZPL_MODULE_REGEX
+    #endif
+    #if defined(ZPL_ENABLE_DLL) && !defined(ZPL_MODULE_DLL)
+        #define ZPL_MODULE_DLL
+    #endif
+    #if defined(ZPL_ENABLE_OPTS) && !defined(ZPL_MODULE_OPTS)
+        #define ZPL_MODULE_OPTS
+    #endif
+    #if defined(ZPL_ENABLE_PROCESS) && !defined(ZPL_MODULE_PROCESS)
+        #define ZPL_MODULE_PROCESS
+    #endif
+    #if defined(ZPL_ENABLE_MATH) && !defined(ZPL_MODULE_MATH)
+        #define ZPL_MODULE_MATH
+    #endif
+    #if defined(ZPL_ENABLE_JSON) && !defined(ZPL_MODULE_JSON)
+        #define ZPL_MODULE_JSON
+    #endif
+    #if defined(ZPL_ENABLE_THREADING) && !defined(ZPL_MODULE_THREADING)
+        #define ZPL_MODULE_THREADING
+    #endif
+    #if defined(ZPL_ENABLE_JOBS) && !defined(ZPL_MODULE_JOBS)
+        #ifndef ZPL_MODULE_THREADING
+        #define ZPL_MODULE_THREADING /* dependency */
+        #endif
+        #define ZPL_MODULE_JOBS
+    #endif
+    #if defined(ZPL_ENABLE_COROUTINES) && !defined(ZPL_MODULE_COROUTINES)
+        #ifndef ZPL_MODULE_THREADING
+        #define ZPL_MODULE_THREADING /* dependency */
+        #endif
+
+        #ifndef ZPL_MODULE_JOBS
+        #define ZPL_MODULE_JOBS /* dependency */
+        #endif
+
+        #define ZPL_MODULE_COROUTINES
+    #endif
+
+    /* module disabling overrides */
+    #if defined(ZPL_DISABLE_CORE) && defined(ZPL_MODULE_CORE)
+        #undef ZPL_MODULE_CORE
+    #endif
+    #if defined(ZPL_DISABLE_TIMER) && defined(ZPL_MODULE_TIMER)
+        #undef ZPL_MODULE_TIMER
+    #endif
+    #if defined(ZPL_DISABLE_HASHING) && defined(ZPL_MODULE_HASHING)
+        #undef ZPL_MODULE_HASHING
+    #endif
+    #if defined(ZPL_DISABLE_REGEX) && defined(ZPL_MODULE_REGEX)
+        #undef ZPL_MODULE_REGEX
+    #endif
+    #if defined(ZPL_DISABLE_DLL) && defined(ZPL_MODULE_DLL)
+        #undef ZPL_MODULE_DLL
+    #endif
+    #if defined(ZPL_DISABLE_OPTS) && defined(ZPL_MODULE_OPTS)
+        #undef ZPL_MODULE_OPTS
+    #endif
+    #if defined(ZPL_DISABLE_PROCESS) && defined(ZPL_MODULE_PROCESS)
+        #undef ZPL_MODULE_PROCESS
+    #endif
+    #if defined(ZPL_DISABLE_MATH) && defined(ZPL_MODULE_MATH)
+        #undef ZPL_MODULE_MATH
+    #endif
+    #if defined(ZPL_DISABLE_JSON) && defined(ZPL_MODULE_JSON)
+        #undef ZPL_MODULE_JSON
+    #endif
+    #if defined(ZPL_DISABLE_THREADING) && defined(ZPL_MODULE_THREADING)
+        #ifdef ZPL_MODULE_JOBS
+        #undef ZPL_MODULE_JOBS /* user */
+        #endif
+
+        #ifdef ZPL_MODULE_COROUTINES
+        #undef ZPL_MODULE_COROUTINES /* user */
+        #endif
+
+        #undef ZPL_MODULE_THREADING
+    #endif
+    #if defined(ZPL_DISABLE_JOBS) && defined(ZPL_MODULE_JOBS)
+        #ifdef ZPL_MODULE_COROUTINES
+        #undef ZPL_MODULE_COROUTINES /* user */
+        #endif
+
+        #undef ZPL_MODULE_JOBS
+    #endif
+    #if defined(ZPL_DISABLE_COROUTINES) && defined(ZPL_MODULE_COROUTINES)
+        #undef ZPL_MODULE_COROUTINES
+    #endif
+#endif
+
+#if defined(__GCC__) || defined(__GNUC__) || defined(__clang__)
+    #pragma GCC diagnostic push
+    #pragma GCC diagnostic ignored "-Wunused-function"
+    #pragma GCC diagnostic ignored "-Wmissing-field-initializers"
+    #pragma GCC diagnostic ignored "-Wimplicit-fallthrough"
+#endif
+
+#if defined(_MSC_VER)
+    #pragma warning(push)
+    #pragma warning(disable : 4201)
+    #pragma warning(disable : 4127) // Conditional expression is constant
+#endif
+
+/* general purpose includes */
+
+// file: header/core/system.h
+
+#ifdef ZPL_EDITOR
+#include <zpl.h>
+#endif
+
+ZPL_BEGIN_C_DECLS
+
+/* Platform architecture */
+
+#if defined(_WIN64) || defined(__x86_64__) || defined(_M_X64) || defined(__64BIT__) || defined(__powerpc64__) ||       \
+defined(__ppc64__) || defined(__aarch64__)
+    #ifndef ZPL_ARCH_64_BIT
+        #define ZPL_ARCH_64_BIT 1
+    #endif
+#else
+    #ifndef ZPL_ARCH_32_BIT
+        #define ZPL_ARCH_32_BIT 1
+    #endif
+#endif
+
+/* Platform endiannes */
+
+#ifndef ZPL_ENDIAN_ORDER
+    #define ZPL_ENDIAN_ORDER
+    #define ZPL_IS_BIG_ENDIAN (!*(zpl_u8 *)&(zpl_u16){ 1 })
+    #define ZPL_IS_LITTLE_ENDIAN (!ZPL_IS_BIG_ENDIAN)
+#endif
+
+/* Platform OS */
+
+#if defined(_WIN32) || defined(_WIN64)
+    #ifndef ZPL_SYSTEM_WINDOWS
+        #define ZPL_SYSTEM_WINDOWS 1
+    #endif
+#elif defined(__APPLE__) && defined(__MACH__)
+    #ifndef ZPL_SYSTEM_OSX
+        #define ZPL_SYSTEM_OSX 1
+    #endif
+    #ifndef ZPL_SYSTEM_MACOS
+        #define ZPL_SYSTEM_MACOS 1
+    #endif
+    #include <TargetConditionals.h>
+    #if TARGET_IPHONE_SIMULATOR == 1 || TARGET_OS_IPHONE == 1
+        #ifndef ZPL_SYSTEM_IOS
+            #define ZPL_SYSTEM_IOS 1
+        #endif
+    #endif
+#elif defined(__unix__)
+    #ifndef ZPL_SYSTEM_UNIX
+        #define ZPL_SYSTEM_UNIX 1
+    #endif
+    #if defined(ANDROID) || defined(__ANDROID__)
+        #ifndef ZPL_SYSTEM_ANDROID
+            #define ZPL_SYSTEM_ANDROID 1
+        #endif
+        #ifndef ZPL_SYSTEM_LINUX
+            #define ZPL_SYSTEM_LINUX 1
+        #endif
+    #elif defined(__linux__)
+    #ifndef ZPL_SYSTEM_LINUX
+        #define ZPL_SYSTEM_LINUX 1
+    #endif
+    #elif defined(__FreeBSD__) || defined(__FreeBSD_kernel__)
+        #ifndef ZPL_SYSTEM_FREEBSD
+            #define ZPL_SYSTEM_FREEBSD 1
+        #endif
+    #elif defined(__OpenBSD__)
+        #ifndef ZPL_SYSTEM_OPENBSD
+            #define ZPL_SYSTEM_OPENBSD 1
+        #endif
+    #elif defined(__EMSCRIPTEN__)
+        #ifndef ZPL_SYSTEM_EMSCRIPTEN
+            #define ZPL_SYSTEM_EMSCRIPTEN 1
+        #endif
+    #elif defined(__CYGWIN__)
+        #ifndef ZPL_SYSTEM_CYGWIN
+            #define ZPL_SYSTEM_CYGWIN 1
+        #endif
+    #else
+        #error This UNIX operating system is not supported
+    #endif
+#else
+    #error This operating system is not supported
+#endif
+
+/* Platform compiler */
+
+#if defined(_MSC_VER)
+    #define ZPL_COMPILER_MSVC 1
+#elif defined(__GNUC__)
+    #define ZPL_COMPILER_GCC 1
+#elif defined(__clang__)
+    #define ZPL_COMPILER_CLANG 1
+#elif defined(__MINGW32__)
+    #define ZPL_COMPILER_MINGW 1
+#else
+    #error Unknown compiler
+#endif
+
+/* Platform CPU */
+
+#if defined(__arm__) || defined(__aarch64__)
+    #ifndef ZPL_CPU_ARM
+        #define ZPL_CPU_ARM 1
+    #endif
+    #ifndef ZPL_CACHE_LINE_SIZE
+        #define ZPL_CACHE_LINE_SIZE 64
+    #endif
+#elif defined(_M_IX86) || defined(_M_X64) || defined(__i386__) || defined(__x86_64__) || defined(ZPL_SYSTEM_EMSCRIPTEN)
+    #ifndef ZPL_CPU_X86
+        #define ZPL_CPU_X86 1
+    #endif
+    #ifndef ZPL_CACHE_LINE_SIZE
+        #define ZPL_CACHE_LINE_SIZE 64
+    #endif
+#elif defined(_M_PPC) || defined(__powerpc__) || defined(__powerpc64__)
+    #ifndef ZPL_CPU_PPC
+        #define ZPL_CPU_PPC 1
+    #endif
+    #ifndef ZPL_CACHE_LINE_SIZE
+        #define ZPL_CACHE_LINE_SIZE 128
+    #endif
+#elif defined(__MIPSEL__) || defined(__mips_isa_rev)
+    #ifndef ZPL_CPU_MIPS
+        #define ZPL_CPU_MIPS 1
+    #endif
+    #ifndef ZPL_CACHE_LINE_SIZE
+        #define ZPL_CACHE_LINE_SIZE 64
+    #endif
+#else
+    #error Unknown CPU Type
+#endif
+
+// TODO(ZaKlaus): Find a better way to get this flag in MinGW.
+#if defined(ZPL_COMPILER_GCC) && !defined(WC_ERR_INVALID_CHARS)
+    #define WC_ERR_INVALID_CHARS 0x0080
+#endif
+
+#if defined(ZPL_COMPILER_GCC) && defined(ZPL_SYSTEM_WINDOWS)
+    #ifndef ZPL_COMPILER_MINGW
+    #define ZPL_COMPILER_MINGW // assume we use mingw as a compiler
+    #endif
+#endif
+
+#if defined(ZPL_SYSTEM_UNIX)
+    #ifndef _GNU_SOURCE
+    #define _GNU_SOURCE
+    #endif
+
+    #ifndef _LARGEFILE64_SOURCE
+    #define _LARGEFILE64_SOURCE
+    #endif
+#endif
+
+ZPL_END_C_DECLS
+
+#include <stdarg.h>
+#include <stddef.h>
+
+#if defined(ZPL_SYSTEM_WINDOWS)
+    #include <intrin.h>
+#endif
+
+// file: header/core/types.h
+
+#ifdef ZPL_EDITOR
+#include <zpl.h>
+#endif
+
+ZPL_BEGIN_C_DECLS
+
+/* Basic types */
+
+#if defined(ZPL_COMPILER_MSVC)
+    #if _MSC_VER < 1300
+        typedef unsigned char zpl_u8;
+        typedef signed char zpl_i8;
+        typedef unsigned short zpl_u16;
+        typedef signed short zpl_i16;
+        typedef unsigned int zpl_u32;
+        typedef signed int zpl_i32;
+    #else
+        typedef unsigned __int8 zpl_u8;
+        typedef signed __int8 zpl_i8;
+        typedef unsigned __int16 zpl_u16;
+        typedef signed __int16 zpl_i16;
+        typedef unsigned __int32 zpl_u32;
+        typedef signed __int32 zpl_i32;
+    #endif
+    typedef unsigned __int64 zpl_u64;
+    typedef signed __int64 zpl_i64;
+#else
+    #include <stdint.h>
+
+    typedef uint8_t zpl_u8;
+    typedef int8_t zpl_i8;
+    typedef uint16_t zpl_u16;
+    typedef int16_t zpl_i16;
+    typedef uint32_t zpl_u32;
+    typedef int32_t zpl_i32;
+    typedef uint64_t zpl_u64;
+    typedef int64_t zpl_i64;
+#endif
+
+ZPL_STATIC_ASSERT(sizeof(zpl_u8) == sizeof(zpl_i8), "sizeof(zpl_u8) != sizeof(zpl_i8)");
+ZPL_STATIC_ASSERT(sizeof(zpl_u16) == sizeof(zpl_i16), "sizeof(zpl_u16) != sizeof(zpl_i16)");
+ZPL_STATIC_ASSERT(sizeof(zpl_u32) == sizeof(zpl_i32), "sizeof(zpl_u32) != sizeof(zpl_i32)");
+ZPL_STATIC_ASSERT(sizeof(zpl_u64) == sizeof(zpl_i64), "sizeof(zpl_u64) != sizeof(zpl_i64)");
+
+ZPL_STATIC_ASSERT(sizeof(zpl_u8) == 1, "sizeof(zpl_u8) != 1");
+ZPL_STATIC_ASSERT(sizeof(zpl_u16) == 2, "sizeof(zpl_u16) != 2");
+ZPL_STATIC_ASSERT(sizeof(zpl_u32) == 4, "sizeof(zpl_u32) != 4");
+ZPL_STATIC_ASSERT(sizeof(zpl_u64) == 8, "sizeof(zpl_u64) != 8");
+
+typedef size_t zpl_usize;
+typedef ptrdiff_t zpl_isize;
+
+ZPL_STATIC_ASSERT(sizeof(zpl_usize) == sizeof(zpl_isize), "sizeof(zpl_usize) != sizeof(zpl_isize)");
+
+// NOTE: (u)zpl_intptr is only here for semantic reasons really as this library will only support 32/64 bit OSes.
+#if defined(_WIN64)
+    typedef signed __int64 zpl_intptr;
+    typedef unsigned __int64 zpl_uintptr;
+#elif defined(_WIN32)
+    // NOTE; To mark types changing their size, e.g. zpl_intptr
+    #ifndef _W64
+        #if !defined(__midl) && (defined(_X86_) || defined(_M_IX86)) && _MSC_VER >= 1300
+            #define _W64 __w64
+        #else
+            #define _W64
+        #endif
+    #endif
+    typedef _W64 signed int zpl_intptr;
+    typedef _W64 unsigned int zpl_uintptr;
+#else
+    typedef uintptr_t zpl_uintptr;
+    typedef intptr_t zpl_intptr;
+#endif
+
+ZPL_STATIC_ASSERT(sizeof(zpl_uintptr) == sizeof(zpl_intptr), "sizeof(zpl_uintptr) != sizeof(zpl_intptr)");
+
+typedef float zpl_f32;
+typedef double zpl_f64;
+
+ZPL_STATIC_ASSERT(sizeof(zpl_f32) == 4, "sizeof(zpl_f32) != 4");
+ZPL_STATIC_ASSERT(sizeof(zpl_f64) == 8, "sizeof(zpl_f64) != 8");
+
+typedef zpl_i32 zpl_rune; // NOTE: Unicode codepoint
+typedef zpl_i32 zpl_char32;
+#define ZPL_RUNE_INVALID cast(zpl_rune)(0xfffd)
+#define ZPL_RUNE_MAX cast(zpl_rune)(0x0010ffff)
+#define ZPL_RUNE_BOM cast(zpl_rune)(0xfeff)
+#define ZPL_RUNE_EOF cast(zpl_rune)(-1)
+
+typedef zpl_i8 zpl_b8;
+typedef zpl_i16 zpl_b16;
+typedef zpl_i32 zpl_b32;
+
+#if !defined(__cplusplus)
+    #if (defined(_MSC_VER) && _MSC_VER < 1800) || (!defined(_MSC_VER) && !defined(__STDC_VERSION__))
+        #ifndef true
+            #define true(0 == 0)
+        #endif
+        #ifndef false
+            #define false(0 != 0)
+        #endif
+
+        typedef zpl_b8 bool;
+    #else
+        #include <stdbool.h>
+    #endif
+#endif
+
+#if __cplusplus > 199711L
+#define register      // Deprecated in C++11.
+#endif  // #if __cplusplus > 199711L
+
+#ifndef ZPL_U8_MIN
+    #define ZPL_U8_MIN 0u
+    #define ZPL_U8_MAX 0xffu
+    #define ZPL_I8_MIN (-0x7f - 1)
+    #define ZPL_I8_MAX 0x7f
+
+    #define ZPL_U16_MIN 0u
+    #define ZPL_U16_MAX 0xffffu
+    #define ZPL_I16_MIN (-0x7fff - 1)
+    #define ZPL_I16_MAX 0x7fff
+
+    #define ZPL_U32_MIN 0u
+    #define ZPL_U32_MAX 0xffffffffu
+    #define ZPL_I32_MIN (-0x7fffffff - 1)
+    #define ZPL_I32_MAX 0x7fffffff
+
+    #define ZPL_U64_MIN 0ull
+    #define ZPL_U64_MAX 0xffffffffffffffffull
+    #define ZPL_I64_MIN (-0x7fffffffffffffffll - 1)
+    #define ZPL_I64_MAX 0x7fffffffffffffffll
+
+    #if defined(ZPL_ARCH_32_BIT)
+        #define ZPL_USIZE_MIN ZPL_U32_MIN
+        #define ZPL_USIZE_MAX ZPL_U32_MAX
+        #define ZPL_ISIZE_MIN ZPL_S32_MIN
+    #define ZPL_ISIZE_MAX ZPL_S32_MAX
+        #elif defined(ZPL_ARCH_64_BIT)
+        #define ZPL_USIZE_MIN ZPL_U64_MIN
+        #define ZPL_USIZE_MAX ZPL_U64_MAX
+        #define ZPL_ISIZE_MIN ZPL_I64_MIN
+        #define ZPL_ISIZE_MAX ZPL_I64_MAX
+    #else
+        #error Unknown architecture size. This library only supports 32 bit and 64 bit architectures.
+    #endif
+
+    #define ZPL_F32_MIN 1.17549435e-38f
+    #define ZPL_F32_MAX 3.40282347e+38f
+
+    #define ZPL_F64_MIN 2.2250738585072014e-308
+    #define ZPL_F64_MAX 1.7976931348623157e+308
+#endif
+
+#ifdef ZPL_DEFINE_NULL_MACRO
+    #ifndef NULL
+        #define NULL ZPL_NULL
+    #endif
+#endif
+
+ZPL_END_C_DECLS
+// file: header/core/helpers.h
+
+/* Various macro based helpers */
+#ifdef ZPL_EDITOR
+#include <zpl.h>
+#endif
+
+ZPL_BEGIN_C_DECLS
+
+#ifndef cast
+    #define cast(Type) (Type)
+#endif
+
+#ifndef zpl_size_of
+    #define zpl_size_of(x) (zpl_isize)(sizeof(x))
+#endif
+
+#ifndef zpl_count_of
+    #define zpl_count_of(x) ((zpl_size_of(x) / zpl_size_of(0 [x])) / ((zpl_isize)(!(zpl_size_of(x) % zpl_size_of(0 [x])))))
+#endif
+
+#ifndef zpl_offset_of
+#ifdef _MSC_VER
+    #define zpl_offset_of(Type, element) ((zpl_isize) & (((Type *)0)->element))
+#else
+    #define zpl_offset_of(Type, element) __builtin_offsetof(Type, element)
+#endif
+#endif
+
+#if defined(__cplusplus)
+    #ifndef zpl_align_of
+        #if __cplusplus >= 201103L
+            #define zpl_align_of(Type) (zpl_isize)alignof(Type)
+        #else
+            extern "C++" {
+                template <typename T> struct zpl_alignment_trick {
+                    char c;
+                    T member;
+                };
+            }
+            #define zpl_align_of(Type) zpl_offset_of(zpl_alignment_trick<Type>, member)
+        #endif
+    #endif
+#else
+    #ifndef zpl_align_of
+        #define zpl_align_of(Type) \
+        zpl_offset_of(             \
+        struct {                   \
+            char c;                \
+            Type member;           \
+        },                         \
+        member)
+    #endif
+#endif
+
+#ifndef zpl_swap
+    #define zpl_swap(Type, a, b) \
+    do {                         \
+        Type tmp = (a);          \
+        (a) = (b);               \
+        (b) = tmp;               \
+    } while (0)
+#endif
+
+
+
+#ifndef zpl_global
+    #define zpl_global static        // Global variables
+#endif
+
+#ifndef zpl_internal
+    #define zpl_internal static      // Internal linkage
+#endif
+
+#ifndef zpl_local_persist
+    #define zpl_local_persist static // Local Persisting variables
+#endif
+
+#ifndef zpl_unused
+    #if defined(_MSC_VER)
+        #define zpl_unused(x) (__pragma(warning(suppress : 4100))(x))
+    #elif defined(__GCC__)
+        #define zpl_unused(x) __attribute__((__unused__))(x)
+    #else
+        #define zpl_unused(x) ((void)(zpl_size_of(x)))
+    #endif
+#endif
+
+
+#ifndef ZPL_JOIN_MACROS
+    #define ZPL_JOIN_MACROS
+
+    #define ZPL_JOIN2 ZPL_CONCAT
+    #define ZPL_JOIN3(a, b, c) ZPL_JOIN2(ZPL_JOIN2(a, b), c)
+    #define ZPL_JOIN4(a, b, c, d) ZPL_JOIN2(ZPL_JOIN2(ZPL_JOIN2(a, b), c), d)
+#endif
+
+#ifndef ZPL_BIT
+    #define ZPL_BIT(x) (1 << (x))
+#endif
+
+#ifndef zpl_min
+    #define zpl_min(a, b) ((a) < (b) ? (a) : (b))
+#endif
+
+#ifndef zpl_max
+    #define zpl_max(a, b) ((a) > (b) ? (a) : (b))
+#endif
+
+#ifndef zpl_min3
+    #define zpl_min3(a, b, c) zpl_min(zpl_min(a, b), c)
+#endif
+
+#ifndef zpl_max3
+    #define zpl_max3(a, b, c) zpl_max(zpl_max(a, b), c)
+#endif
+
+#ifndef zpl_clamp
+    #define zpl_clamp(x, lower, upper) zpl_min(zpl_max((x), (lower)), (upper))
+#endif
+
+#ifndef zpl_clamp01
+    #define zpl_clamp01(x) zpl_clamp((x), 0, 1)
+#endif
+
+#ifndef zpl_is_between
+    #define zpl_is_between(x, lower, upper) (((lower) <= (x)) && ((x) <= (upper)))
+#endif
+
+#ifndef zpl_abs
+    #define zpl_abs(x) ((x) < 0 ? -(x) : (x))
+#endif
+
+#ifndef hard_cast
+    #define hard_cast(type) *cast(type) &
+#endif
+
+// WARN(ZaKlaus): Supported only on GCC via GNU extensions!!!
+#ifndef zpl_lambda
+    #define zpl_lambda(b_) ({ b_ _; })
+#endif
+
+#ifndef zpl_when
+    #define zpl_when(init, type, name) \
+    type name = init;                  \
+    if (name)
+#endif
+
+/* NOTE: Very useful bit setting */
+#ifndef ZPL_MASK_SET
+    #define ZPL_MASK_SET(var, set, mask) \
+    do {                                 \
+        if (set)                         \
+        (var) |= (mask);                 \
+        else                             \
+        (var) &= ~(mask);                \
+    } while (0)
+#endif
+
+// Multiline string literals in C99!
+#ifndef ZPL_MULTILINE
+    #define ZPL_MULTILINE(...) #__VA_ARGS__
+#endif
+
+ZPL_END_C_DECLS
+
+#if defined(ZPL_MODULE_CORE)
+    // file: header/core/debug.h
+
+    /* Debugging stuff */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #ifndef ZPL_DEBUG_TRAP
+        #if defined(_MSC_VER)
+            #if _MSC_VER < 1300
+                #define ZPL_DEBUG_TRAP( ) __asm int 3 /* Trap to debugger! */
+            #else
+                #define ZPL_DEBUG_TRAP( ) __debugbreak( )
+            #endif
+        #else
+            #define ZPL_DEBUG_TRAP( ) __builtin_trap( )
+        #endif
+    #endif
+
+    #ifndef ZPL_ASSERT_MSG
+        #define ZPL_ASSERT_MSG(cond, msg, ...)                                                                             \
+        do {                                                                                                               \
+            if (!(cond)) {                                                                                                 \
+                zpl_assert_handler(#cond, __FILE__, cast(zpl_i64) __LINE__, msg, ##__VA_ARGS__);                           \
+                ZPL_DEBUG_TRAP( );                                                                                         \
+            }                                                                                                              \
+        } while (0)
+    #endif
+
+    #ifndef ZPL_ASSERT
+        #define ZPL_ASSERT(cond) ZPL_ASSERT_MSG(cond, NULL)
+    #endif
+
+    #ifndef ZPL_ASSERT_NOT_NULL
+        #define ZPL_ASSERT_NOT_NULL(ptr) ZPL_ASSERT_MSG((ptr) != NULL, #ptr " must not be NULL")
+    #endif
+
+    // NOTE: Things that shouldn't happen with a message!
+    #ifndef ZPL_PANIC
+        #define ZPL_PANIC(msg, ...) ZPL_ASSERT_MSG(0, msg, ##__VA_ARGS__)
+    #endif
+
+    #ifndef ZPL_NOT_IMPLEMENTED
+        #define ZPL_NOT_IMPLEMENTED ZPL_PANIC("not implemented")
+    #endif
+
+    /* Functions */
+
+    ZPL_DEF void    zpl_assert_handler(char const *condition, char const *file, zpl_i32 line, char const *msg, ...);
+    ZPL_DEF zpl_i32 zpl_assert_crash(char const *condition);
+
+    ZPL_END_C_DECLS
+    // file: header/core/memory.h
+
+    /** @file mem.c
+    @brief Memory manipulation and helpers.
+    @defgroup memman Memory management
+
+     Consists of pointer arithmetic methods, virtual memory management and custom memory allocators.
+
+     @{
+     */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    //! Checks if value is power of 2.
+    ZPL_DEF_INLINE zpl_b32 zpl_is_power_of_two(zpl_isize x);
+
+    //! Aligns address to specified alignment.
+    ZPL_DEF_INLINE void *zpl_align_forward(void *ptr, zpl_isize alignment);
+
+    //! Moves pointer forward by bytes.
+    ZPL_DEF_INLINE void *zpl_pointer_add(void *ptr, zpl_isize bytes);
+
+    //! Moves pointer backward by bytes.
+    ZPL_DEF_INLINE void *zpl_pointer_sub(void *ptr, zpl_isize bytes);
+
+    //! Moves pointer forward by bytes.
+    ZPL_DEF_INLINE void const *zpl_pointer_add_const(void const *ptr, zpl_isize bytes);
+
+    //! Moves pointer backward by bytes.
+    ZPL_DEF_INLINE void const *zpl_pointer_sub_const(void const *ptr, zpl_isize bytes);
+
+    //! Calculates difference between two addresses.
+    ZPL_DEF_INLINE zpl_isize zpl_pointer_diff(void const *begin, void const *end);
+
+    #define zpl_ptr_add zpl_pointer_add
+    #define zpl_ptr_sub zpl_pointer_sub
+    #define zpl_ptr_add_const zpl_pointer_add_const
+    #define zpl_ptr_sub_const zpl_pointer_sub_const
+    #define zpl_ptr_diff zpl_pointer_diff
+
+    //! Clears up memory at location by specified size.
+
+    //! @param ptr Memory location to clear up.
+    //! @param size The size to clear up with.
+    ZPL_DEF_INLINE void zpl_zero_size(void *ptr, zpl_isize size);
+
+    #ifndef zpl_zero_item
+    //! Clears up an item.
+    #define zpl_zero_item(t) zpl_zero_size((t), zpl_size_of(*(t))) // NOTE: Pass pointer of struct
+
+    //! Clears up an array.
+    #define zpl_zero_array(a, count) zpl_zero_size((a), zpl_size_of(*(a)) * count)
+    #endif
+
+    //! Copy memory from source to destination.
+    ZPL_DEF_INLINE void *zpl_memmove(void *dest, void const *source, zpl_isize size);
+
+    //! Set constant value at memory location with specified size.
+    ZPL_DEF_INLINE void *zpl_memset(void *data, zpl_u8 byte_value, zpl_isize size);
+
+    //! Compare two memory locations with specified size.
+    ZPL_DEF_INLINE zpl_i32 zpl_memcompare(void const *s1, void const *s2, zpl_isize size);
+
+    //! Swap memory contents between 2 locations with size.
+    ZPL_DEF void zpl_memswap(void *i, void *j, zpl_isize size);
+
+    //! Search for a constant value within the size limit at memory location.
+    ZPL_DEF void const *zpl_memchr(void const *data, zpl_u8 byte_value, zpl_isize size);
+
+    //! Search for a constant value within the size limit at memory location in backwards.
+    ZPL_DEF void const *zpl_memrchr(void const *data, zpl_u8 byte_value, zpl_isize size);
+
+    //! Copy non-overlapping memory from source to destination.
+    ZPL_DEF void *zpl_memcopy(void *dest, void const *source, zpl_isize size);
+
+    #ifndef zpl_memcopy_array
+
+    //! Copy non-overlapping array.
+    #define zpl_memcopy_array(dst, src, count) zpl_memcopy((dst), (src), zpl_size_of(*(dst)) * (count))
+    #endif
+
+    //! Copy an array.
+    #ifndef zpl_memmove_array
+    #define zpl_memmove_array(dst, src, count) zpl_memmove((dst), (src), zpl_size_of(*(dst)) * (count))
+    #endif
+
+    #ifndef ZPL_BIT_CAST
+    #define ZPL_BIT_CAST(dest, source)                                                                                 \
+    do {                                                                                                               \
+        ZPL_STATIC_ASSERT(zpl_size_of(*(dest)) <= zpl_size_of(source), "zpl_size_of(*(dest)) !<= zpl_size_of(source)");\
+        zpl_memcopy((dest), &(source), zpl_size_of(*dest));                                                            \
+    } while (0)
+    #endif
+
+    #ifndef zpl_kilobytes
+    #define zpl_kilobytes(x) ((x)              * (zpl_i64)(1024))
+    #define zpl_megabytes(x) (zpl_kilobytes(x) * (zpl_i64)(1024))
+    #define zpl_gigabytes(x) (zpl_megabytes(x) * (zpl_i64)(1024))
+    #define zpl_terabytes(x) (zpl_gigabytes(x) * (zpl_i64)(1024))
+    #endif
+
+
+    /* inlines */
+
+    #define ZPL__ONES (cast(zpl_usize) - 1 / ZPL_U8_MAX)
+    #define ZPL__HIGHS (ZPL__ONES * (ZPL_U8_MAX / 2 + 1))
+    #define ZPL__HAS_ZERO(x) (((x)-ZPL__ONES) & ~(x)&ZPL__HIGHS)
+
+    ZPL_IMPL_INLINE void *zpl_align_forward(void *ptr, zpl_isize alignment) {
+        zpl_uintptr p;
+
+        ZPL_ASSERT(zpl_is_power_of_two(alignment));
+
+        p = cast(zpl_uintptr) ptr;
+        return cast(void *)((p + (alignment - 1)) & ~(alignment - 1));
+    }
+
+    ZPL_IMPL_INLINE void *zpl_pointer_add(void *ptr, zpl_isize bytes) { return cast(void *)(cast(zpl_u8 *) ptr + bytes); }
+    ZPL_IMPL_INLINE void *zpl_pointer_sub(void *ptr, zpl_isize bytes) { return cast(void *)(cast(zpl_u8 *) ptr - bytes); }
+    ZPL_IMPL_INLINE void const *zpl_pointer_add_const(void const *ptr, zpl_isize bytes) {
+        return cast(void const *)(cast(zpl_u8 const *) ptr + bytes);
+    }
+    ZPL_IMPL_INLINE void const *zpl_pointer_sub_const(void const *ptr, zpl_isize bytes) {
+        return cast(void const *)(cast(zpl_u8 const *) ptr - bytes);
+    }
+    ZPL_IMPL_INLINE zpl_isize zpl_pointer_diff(void const *begin, void const *end) {
+        return cast(zpl_isize)(cast(zpl_u8 const *) end - cast(zpl_u8 const *) begin);
+    }
+
+    ZPL_IMPL_INLINE void zpl_zero_size(void *ptr, zpl_isize size) { zpl_memset(ptr, 0, size); }
+
+    #if defined(_MSC_VER) && !defined(__clang__)
+    #pragma intrinsic(__movsb)
+    #endif
+
+    ZPL_IMPL_INLINE void *zpl_memmove(void *dest, void const *source, zpl_isize n) {
+        if (dest == NULL) { return NULL; }
+
+        zpl_u8 *d = cast(zpl_u8 *) dest;
+        zpl_u8 const *s = cast(zpl_u8 const *) source;
+
+        if (d == s) return d;
+        if (s + n <= d || d + n <= s) // NOTE: Non-overlapping
+            return zpl_memcopy(d, s, n);
+
+        if (d < s) {
+            if (cast(zpl_uintptr) s % zpl_size_of(zpl_isize) == cast(zpl_uintptr) d % zpl_size_of(zpl_isize)) {
+                while (cast(zpl_uintptr) d % zpl_size_of(zpl_isize)) {
+                    if (!n--) return dest;
+                    *d++ = *s++;
+                }
+                while (n >= zpl_size_of(zpl_isize)) {
+                    *cast(zpl_isize *) d = *cast(zpl_isize *) s;
+                    n -= zpl_size_of(zpl_isize);
+                    d += zpl_size_of(zpl_isize);
+                    s += zpl_size_of(zpl_isize);
+                }
+            }
+            for (; n; n--) *d++ = *s++;
+        } else {
+            if ((cast(zpl_uintptr) s % zpl_size_of(zpl_isize)) == (cast(zpl_uintptr) d % zpl_size_of(zpl_isize))) {
+                while (cast(zpl_uintptr)(d + n) % zpl_size_of(zpl_isize)) {
+                    if (!n--) return dest;
+                    d[n] = s[n];
+                }
+                while (n >= zpl_size_of(zpl_isize)) {
+                    n -= zpl_size_of(zpl_isize);
+                    *cast(zpl_isize *)(d + n) = *cast(zpl_isize *)(s + n);
+                }
+            }
+            while (n) n--, d[n] = s[n];
+        }
+
+        return dest;
+    }
+
+    ZPL_IMPL_INLINE void *zpl_memset(void *dest, zpl_u8 c, zpl_isize n) {
+        if (dest == NULL) { return NULL; }
+
+        zpl_u8 *s = cast(zpl_u8 *) dest;
+        zpl_isize k;
+        zpl_u32 c32 = ((zpl_u32)-1) / 255 * c;
+
+        if (n == 0) return dest;
+        s[0] = s[n - 1] = c;
+        if (n < 3) return dest;
+        s[1] = s[n - 2] = c;
+        s[2] = s[n - 3] = c;
+        if (n < 7) return dest;
+        s[3] = s[n - 4] = c;
+        if (n < 9) return dest;
+
+        k = -cast(zpl_intptr) s & 3;
+        s += k;
+        n -= k;
+        n &= -4;
+
+        *cast(zpl_u32 *)(s + 0) = c32;
+        *cast(zpl_u32 *)(s + n - 4) = c32;
+        if (n < 9) return dest;
+        *cast(zpl_u32 *)(s + 4) = c32;
+        *cast(zpl_u32 *)(s + 8) = c32;
+        *cast(zpl_u32 *)(s + n - 12) = c32;
+        *cast(zpl_u32 *)(s + n - 8) = c32;
+        if (n < 25) return dest;
+        *cast(zpl_u32 *)(s + 12) = c32;
+        *cast(zpl_u32 *)(s + 16) = c32;
+        *cast(zpl_u32 *)(s + 20) = c32;
+        *cast(zpl_u32 *)(s + 24) = c32;
+        *cast(zpl_u32 *)(s + n - 28) = c32;
+        *cast(zpl_u32 *)(s + n - 24) = c32;
+        *cast(zpl_u32 *)(s + n - 20) = c32;
+        *cast(zpl_u32 *)(s + n - 16) = c32;
+
+        k = 24 + (cast(zpl_uintptr) s & 4);
+        s += k;
+        n -= k;
+
+        {
+            zpl_u64 c64 = (cast(zpl_u64) c32 << 32) | c32;
+            while (n > 31) {
+                *cast(zpl_u64 *)(s + 0) = c64;
+                *cast(zpl_u64 *)(s + 8) = c64;
+                *cast(zpl_u64 *)(s + 16) = c64;
+                *cast(zpl_u64 *)(s + 24) = c64;
+
+                n -= 32;
+                s += 32;
+            }
+        }
+
+        return dest;
+    }
+
+    ZPL_IMPL_INLINE zpl_i32 zpl_memcompare(void const *s1, void const *s2, zpl_isize size) {
+        zpl_u8 const *s1p8 = cast(zpl_u8 const *) s1;
+        zpl_u8 const *s2p8 = cast(zpl_u8 const *) s2;
+
+        if (s1 == NULL || s2 == NULL) { return 0; }
+
+        while (size--) {
+            zpl_isize d;
+            if ((d = (*s1p8++ - *s2p8++)) != 0) return cast(zpl_i32) d;
+        }
+        return 0;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_is_power_of_two(zpl_isize x) {
+        if (x <= 0) return false;
+        return !(x & (x - 1));
+    }
+
+    ZPL_END_C_DECLS
+    // file: header/core/memory_virtual.h
+
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Virtual Memory
+    //
+    //
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef struct zpl_virtual_memory {
+        void *data;
+        zpl_isize size;
+    } zpl_virtual_memory;
+
+    //! Initialize virtual memory from existing data.
+    ZPL_DEF zpl_virtual_memory zpl_vm(void *data, zpl_isize size);
+
+    //! Allocate virtual memory at address with size.
+
+    //! @param addr The starting address of the region to reserve. If NULL, it lets operating system to decide where to allocate it.
+    //! @param size The size to server.
+    ZPL_DEF zpl_virtual_memory zpl_vm_alloc(void *addr, zpl_isize size);
+
+    //! Release the virtual memory.
+    ZPL_DEF zpl_b32 zpl_vm_free(zpl_virtual_memory vm);
+
+    //! Trim virtual memory.
+    ZPL_DEF zpl_virtual_memory zpl_vm_trim(zpl_virtual_memory vm, zpl_isize lead_size, zpl_isize size);
+
+    //! Purge virtual memory.
+    ZPL_DEF zpl_b32 zpl_vm_purge(zpl_virtual_memory vm);
+
+    //! Retrieve VM's page size and alignment.
+    ZPL_DEF zpl_isize zpl_virtual_memory_page_size(zpl_isize *alignment_out);
+
+    ZPL_END_C_DECLS
+    // file: header/core/memory_custom.h
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Custom Allocation
+    //
+    //
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef enum zplAllocationType {
+        ZPL_ALLOCATION_ALLOC,
+        ZPL_ALLOCATION_FREE,
+        ZPL_ALLOCATION_FREE_ALL,
+        ZPL_ALLOCATION_RESIZE,
+    } zplAllocationType;
+
+    // NOTE: This is useful so you can define an allocator of the same type and parameters
+    #define ZPL_ALLOCATOR_PROC(name)                                                                                       \
+    void *name(void *allocator_data, zplAllocationType type, zpl_isize size, zpl_isize alignment, void *old_memory,            \
+    zpl_isize old_size, zpl_u64 flags)
+    typedef ZPL_ALLOCATOR_PROC(zpl_allocator_proc);
+
+
+    typedef struct zpl_allocator {
+        zpl_allocator_proc *proc;
+        void *data;
+    } zpl_allocator;
+
+    typedef enum zplAllocatorFlag {
+        ZPL_ALLOCATOR_FLAG_CLEAR_TO_ZERO = ZPL_BIT(0),
+    } zplAllocatorFlag;
+
+    #ifndef ZPL_DEFAULT_MEMORY_ALIGNMENT
+    #define ZPL_DEFAULT_MEMORY_ALIGNMENT (2 * zpl_size_of(void *))
+    #endif
+
+    #ifndef ZPL_DEFAULT_ALLOCATOR_FLAGS
+    #define ZPL_DEFAULT_ALLOCATOR_FLAGS (ZPL_ALLOCATOR_FLAG_CLEAR_TO_ZERO)
+    #endif
+
+    //! Allocate memory with specified alignment.
+    ZPL_DEF_INLINE void *zpl_alloc_align(zpl_allocator a, zpl_isize size, zpl_isize alignment);
+
+    //! Allocate memory with default alignment.
+    ZPL_DEF_INLINE void *zpl_alloc(zpl_allocator a, zpl_isize size);
+
+    //! Free allocated memory.
+    ZPL_DEF_INLINE void zpl_free(zpl_allocator a, void *ptr);
+
+    //! Free all memory allocated by an allocator.
+    ZPL_DEF_INLINE void zpl_free_all(zpl_allocator a);
+
+    //! Resize an allocated memory.
+    ZPL_DEF_INLINE void *zpl_resize(zpl_allocator a, void *ptr, zpl_isize old_size, zpl_isize new_size);
+
+    //! Resize an allocated memory with specified alignment.
+    ZPL_DEF_INLINE void *zpl_resize_align(zpl_allocator a, void *ptr, zpl_isize old_size, zpl_isize new_size, zpl_isize alignment);
+
+    //! Allocate memory and copy data into it.
+    ZPL_DEF_INLINE void *zpl_alloc_copy(zpl_allocator a, void const *src, zpl_isize size);
+
+    //! Allocate memory with specified alignment and copy data into it.
+    ZPL_DEF_INLINE void *zpl_alloc_copy_align(zpl_allocator a, void const *src, zpl_isize size, zpl_isize alignment);
+
+    //! Allocate memory for null-terminated C-String.
+    ZPL_DEF_INLINE char *zpl_alloc_str(zpl_allocator a, char const *str);
+
+    //! Allocate memory for C-String with specified size.
+    ZPL_DEF_INLINE char *zpl_alloc_str_len(zpl_allocator a, char const *str, zpl_isize len);
+
+    #ifndef zpl_alloc_item
+
+    //! Allocate memory for an item.
+    #define zpl_alloc_item(allocator_, Type) (Type *)zpl_alloc(allocator_, zpl_size_of(Type))
+
+    //! Allocate memory for an array of items.
+    #define zpl_alloc_array(allocator_, Type, count) (Type *)zpl_alloc(allocator_, zpl_size_of(Type) * (count))
+    #endif
+
+    //! Allocate/Resize memory using default options.
+
+    //! Use this if you don't need a "fancy" resize allocation
+    ZPL_DEF_INLINE void *zpl_default_resize_align(zpl_allocator a, void *ptr, zpl_isize old_size, zpl_isize new_size, zpl_isize alignment);
+
+    //! The heap allocator backed by operating system's memory manager.
+    ZPL_DEF_INLINE zpl_allocator zpl_heap_allocator(void);
+    ZPL_DEF ZPL_ALLOCATOR_PROC(zpl_heap_allocator_proc);
+
+    #ifndef zpl_malloc
+
+    //! Helper to allocate memory using heap allocator.
+    #define zpl_malloc(sz) zpl_alloc(zpl_heap_allocator( ), sz)
+
+    //! Helper to free memory allocated by heap allocator.
+    #define zpl_mfree(ptr) zpl_free(zpl_heap_allocator( ), ptr)
+
+    //! Alias to heap allocator.
+    #define zpl_heap zpl_heap_allocator
+    #endif
+
+    //
+    // Arena Allocator
+    //
+
+    typedef struct zpl_arena {
+        zpl_allocator backing;
+        void *physical_start;
+        zpl_isize total_size;
+        zpl_isize total_allocated;
+        zpl_isize temp_count;
+    } zpl_arena;
+
+    //! Initialize memory arena from existing memory region.
+    ZPL_DEF_INLINE void zpl_arena_init_from_memory(zpl_arena *arena, void *start, zpl_isize size);
+
+    //! Initialize memory arena using existing memory allocator.
+    ZPL_DEF_INLINE void zpl_arena_init_from_allocator(zpl_arena *arena, zpl_allocator backing, zpl_isize size);
+
+    //! Initialize memory arena within an existing parent memory arena.
+    ZPL_DEF_INLINE void zpl_arena_init_sub(zpl_arena *arena, zpl_arena *parent_arena, zpl_isize size);
+
+    //! Release the memory used by memory arena.
+    ZPL_DEF_INLINE void zpl_arena_free(zpl_arena *arena);
+
+
+    //! Retrieve memory arena's aligned allocation address.
+    ZPL_DEF_INLINE zpl_isize zpl_arena_alignment_of(zpl_arena *arena, zpl_isize alignment);
+
+    //! Retrieve memory arena's remaining size.
+    ZPL_DEF_INLINE zpl_isize zpl_arena_size_remaining(zpl_arena *arena, zpl_isize alignment);
+
+    //! Check whether memory arena has any temporary snapshots.
+    ZPL_DEF_INLINE void zpl_arena_check(zpl_arena *arena);
+
+    //! Allocation Types: alloc, free_all, resize
+    ZPL_DEF_INLINE zpl_allocator zpl_arena_allocator(zpl_arena *arena);
+    ZPL_DEF ZPL_ALLOCATOR_PROC(zpl_arena_allocator_proc);
+
+
+    typedef struct zpl_temp_arena_memory {
+        zpl_arena *arena;
+        zpl_isize original_count;
+    } zpl_temp_arena_memory;
+
+    //! Capture a snapshot of used memory in a memory arena.
+    ZPL_DEF_INLINE zpl_temp_arena_memory zpl_temp_arena_memory_begin(zpl_arena *arena);
+
+    //! Reset memory arena's usage by a captured snapshot.
+    ZPL_DEF_INLINE void zpl_temp_arena_memory_end(zpl_temp_arena_memory tmp_mem);
+
+    //
+    // Pool Allocator
+    //
+
+
+    typedef struct zpl_pool {
+        zpl_allocator backing;
+        void *physical_start;
+        void *free_list;
+        zpl_isize block_size;
+        zpl_isize block_align;
+        zpl_isize total_size;
+        zpl_isize num_blocks;
+    } zpl_pool;
+
+
+    //! Initialize pool allocator.
+    ZPL_DEF_INLINE void zpl_pool_init(zpl_pool *pool, zpl_allocator backing, zpl_isize num_blocks, zpl_isize block_size);
+
+    //! Initialize pool allocator with specific block alignment.
+    ZPL_DEF void zpl_pool_init_align(zpl_pool *pool, zpl_allocator backing, zpl_isize num_blocks, zpl_isize block_size,
+                                     zpl_isize block_align);
+
+    //! Release the resources used by pool allocator.
+    ZPL_DEF_INLINE void zpl_pool_free(zpl_pool *pool);
+
+    //! Allocation Types: alloc, free
+    ZPL_DEF_INLINE zpl_allocator zpl_pool_allocator(zpl_pool *pool);
+    ZPL_DEF ZPL_ALLOCATOR_PROC(zpl_pool_allocator_proc);
+
+
+    typedef struct zpl_allocation_header_ev {
+        zpl_isize size;
+    } zpl_allocation_header_ev;
+
+    ZPL_DEF_INLINE zpl_allocation_header_ev *zpl_allocation_header(void *data);
+    ZPL_DEF_INLINE void zpl_allocation_header_fill(zpl_allocation_header_ev *header, void *data, zpl_isize size);
+
+    #if defined(ZPL_ARCH_32_BIT)
+    #define ZPL_ISIZE_HIGH_BIT 0x80000000
+    #elif defined(ZPL_ARCH_64_BIT)
+    #define ZPL_ISIZE_HIGH_BIT 0x8000000000000000ll
+    #else
+    #error
+    #endif
+
+    //
+    // Scratch Memory Allocator - Ring Buffer Based Arena
+    //
+
+
+    typedef struct zpl_scratch_memory {
+        void *physical_start;
+        zpl_isize total_size;
+        void *alloc_point;
+        void *free_point;
+    } zpl_scratch_memory;
+
+    //! Initialize ring buffer arena.
+    ZPL_DEF void zpl_scratch_memory_init(zpl_scratch_memory *s, void *start, zpl_isize size);
+
+    //! Check whether ring buffer arena is in use.
+    ZPL_DEF zpl_b32 zpl_scratch_memory_is_in_use(zpl_scratch_memory *s, void *ptr);
+
+    //! Allocation Types: alloc, free, free_all, resize
+    ZPL_DEF zpl_allocator zpl_scratch_allocator(zpl_scratch_memory *s);
+    ZPL_DEF ZPL_ALLOCATOR_PROC(zpl_scratch_allocator_proc);
+
+    //
+    // Stack Memory Allocator
+    //
+
+
+    typedef struct zpl_stack_memory {
+        zpl_allocator backing;
+
+        void *physical_start;
+        zpl_usize total_size;
+        zpl_usize allocated;
+    } zpl_stack_memory;
+
+    //! Initialize stack allocator from existing memory.
+    ZPL_DEF_INLINE void zpl_stack_memory_init_from_memory(zpl_stack_memory *s, void *start, zpl_isize size);
+
+    //! Initialize stack allocator using existing memory allocator.
+    ZPL_DEF_INLINE void zpl_stack_memory_init(zpl_stack_memory *s, zpl_allocator backing, zpl_isize size);
+
+    //! Check whether stack allocator is in use.
+    ZPL_DEF_INLINE zpl_b32 zpl_stack_memory_is_in_use(zpl_stack_memory *s, void *ptr);
+
+    //! Release the resources used by stack allocator.
+    ZPL_DEF_INLINE void zpl_stack_memory_free(zpl_stack_memory *s);
+
+    //! Allocation Types: alloc, free, free_all
+    ZPL_DEF_INLINE zpl_allocator zpl_stack_allocator(zpl_stack_memory *s);
+    ZPL_DEF ZPL_ALLOCATOR_PROC(zpl_stack_allocator_proc);
+
+    // TODO: Fixed heap allocator
+    // TODO: General heap allocator. Maybe a TCMalloc like clone?
+
+
+    /* inlines */
+
+    ZPL_IMPL_INLINE void *zpl_alloc_align(zpl_allocator a, zpl_isize size, zpl_isize alignment) {
+        return a.proc(a.data, ZPL_ALLOCATION_ALLOC, size, alignment, NULL, 0, ZPL_DEFAULT_ALLOCATOR_FLAGS);
+    }
+    ZPL_IMPL_INLINE void *zpl_alloc(zpl_allocator a, zpl_isize size) {
+        return zpl_alloc_align(a, size, ZPL_DEFAULT_MEMORY_ALIGNMENT);
+    }
+    ZPL_IMPL_INLINE void zpl_free(zpl_allocator a, void *ptr) {
+        if (ptr != NULL) a.proc(a.data, ZPL_ALLOCATION_FREE, 0, 0, ptr, 0, ZPL_DEFAULT_ALLOCATOR_FLAGS);
+    }
+    ZPL_IMPL_INLINE void zpl_free_all(zpl_allocator a) {
+        a.proc(a.data, ZPL_ALLOCATION_FREE_ALL, 0, 0, NULL, 0, ZPL_DEFAULT_ALLOCATOR_FLAGS);
+    }
+    ZPL_IMPL_INLINE void *zpl_resize(zpl_allocator a, void *ptr, zpl_isize old_size, zpl_isize new_size) {
+        return zpl_resize_align(a, ptr, old_size, new_size, ZPL_DEFAULT_MEMORY_ALIGNMENT);
+    }
+    ZPL_IMPL_INLINE void *zpl_resize_align(zpl_allocator a, void *ptr, zpl_isize old_size, zpl_isize new_size, zpl_isize alignment) {
+        return a.proc(a.data, ZPL_ALLOCATION_RESIZE, new_size, alignment, ptr, old_size, ZPL_DEFAULT_ALLOCATOR_FLAGS);
+    }
+
+    ZPL_IMPL_INLINE void *zpl_alloc_copy(zpl_allocator a, void const *src, zpl_isize size) {
+        return zpl_memcopy(zpl_alloc(a, size), src, size);
+    }
+    ZPL_IMPL_INLINE void *zpl_alloc_copy_align(zpl_allocator a, void const *src, zpl_isize size, zpl_isize alignment) {
+        return zpl_memcopy(zpl_alloc_align(a, size, alignment), src, size);
+    }
+
+    ZPL_IMPL_INLINE char *zpl_alloc_str_len(zpl_allocator a, char const *str, zpl_isize len) {
+        char *result;
+        result = cast(char *) zpl_alloc_copy(a, str, len + 1);
+        result[len] = '\0';
+        return result;
+    }
+
+    ZPL_IMPL_INLINE void *zpl_default_resize_align(zpl_allocator a, void *old_memory, zpl_isize old_size, zpl_isize new_size,
+                                              zpl_isize alignment) {
+        if (!old_memory) return zpl_alloc_align(a, new_size, alignment);
+
+        if (new_size == 0) {
+            zpl_free(a, old_memory);
+            return NULL;
+        }
+
+        if (new_size < old_size) new_size = old_size;
+
+        if (old_size == new_size) {
+            return old_memory;
+        } else {
+            void *new_memory = zpl_alloc_align(a, new_size, alignment);
+            if (!new_memory) return NULL;
+            zpl_memmove(new_memory, old_memory, zpl_min(new_size, old_size));
+            zpl_free(a, old_memory);
+            return new_memory;
+        }
+    }
+
+
+    //
+    // Heap Allocator
+    //
+
+    ZPL_IMPL_INLINE zpl_allocator zpl_heap_allocator(void) {
+        zpl_allocator a;
+        a.proc = zpl_heap_allocator_proc;
+        a.data = NULL;
+        return a;
+    }
+
+    //
+    // Arena Allocator
+    //
+
+    ZPL_IMPL_INLINE void zpl_arena_init_from_memory(zpl_arena *arena, void *start, zpl_isize size) {
+        arena->backing.proc = NULL;
+        arena->backing.data = NULL;
+        arena->physical_start = start;
+        arena->total_size = size;
+        arena->total_allocated = 0;
+        arena->temp_count = 0;
+    }
+
+    ZPL_IMPL_INLINE void zpl_arena_init_from_allocator(zpl_arena *arena, zpl_allocator backing, zpl_isize size) {
+        arena->backing = backing;
+        arena->physical_start = zpl_alloc(backing, size); // NOTE: Uses default alignment
+        arena->total_size = size;
+        arena->total_allocated = 0;
+        arena->temp_count = 0;
+    }
+
+    ZPL_IMPL_INLINE void zpl_arena_init_sub(zpl_arena *arena, zpl_arena *parent_arena, zpl_isize size) {
+        zpl_arena_init_from_allocator(arena, zpl_arena_allocator(parent_arena), size);
+    }
+
+    ZPL_IMPL_INLINE void zpl_arena_free(zpl_arena *arena) {
+        if (arena->backing.proc) {
+            zpl_free(arena->backing, arena->physical_start);
+            arena->physical_start = NULL;
+        }
+    }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_arena_alignment_of(zpl_arena *arena, zpl_isize alignment) {
+        zpl_isize alignment_offset, result_pointer, mask;
+        ZPL_ASSERT(zpl_is_power_of_two(alignment));
+
+        alignment_offset = 0;
+        result_pointer = cast(zpl_isize) arena->physical_start + arena->total_allocated;
+        mask = alignment - 1;
+        if (result_pointer & mask) alignment_offset = alignment - (result_pointer & mask);
+
+        return alignment_offset;
+    }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_arena_size_remaining(zpl_arena *arena, zpl_isize alignment) {
+        zpl_isize result = arena->total_size - (arena->total_allocated + zpl_arena_alignment_of(arena, alignment));
+        return result;
+    }
+
+    ZPL_IMPL_INLINE void zpl_arena_check(zpl_arena *arena) { ZPL_ASSERT(arena->temp_count == 0); }
+
+    ZPL_IMPL_INLINE zpl_allocator zpl_arena_allocator(zpl_arena *arena) {
+        zpl_allocator allocator;
+        allocator.proc = zpl_arena_allocator_proc;
+        allocator.data = arena;
+        return allocator;
+    }
+
+    ZPL_IMPL_INLINE zpl_temp_arena_memory zpl_temp_arena_memory_begin(zpl_arena *arena) {
+        zpl_temp_arena_memory tmp;
+        tmp.arena = arena;
+        tmp.original_count = arena->total_allocated;
+        arena->temp_count++;
+        return tmp;
+    }
+
+    ZPL_IMPL_INLINE void zpl_temp_arena_memory_end(zpl_temp_arena_memory tmp) {
+        ZPL_ASSERT(tmp.arena->total_allocated >= tmp.original_count);
+        ZPL_ASSERT(tmp.arena->temp_count > 0);
+        tmp.arena->total_allocated = tmp.original_count;
+        tmp.arena->temp_count--;
+    }
+
+    //
+    // Pool Allocator
+    //
+
+    ZPL_IMPL_INLINE void zpl_pool_init(zpl_pool *pool, zpl_allocator backing, zpl_isize num_blocks, zpl_isize block_size) {
+        zpl_pool_init_align(pool, backing, num_blocks, block_size, ZPL_DEFAULT_MEMORY_ALIGNMENT);
+    }
+
+    ZPL_IMPL_INLINE void zpl_pool_free(zpl_pool *pool) {
+        if (pool->backing.proc) { zpl_free(pool->backing, pool->physical_start); }
+    }
+
+    ZPL_IMPL_INLINE zpl_allocator zpl_pool_allocator(zpl_pool *pool) {
+        zpl_allocator allocator;
+        allocator.proc = zpl_pool_allocator_proc;
+        allocator.data = pool;
+        return allocator;
+    }
+
+    ZPL_IMPL_INLINE zpl_allocation_header_ev *zpl_allocation_header(void *data) {
+        zpl_isize *p = cast(zpl_isize *) data;
+        while (p[-1] == cast(zpl_isize)(-1)) p--;
+        return cast(zpl_allocation_header_ev *) p - 1;
+    }
+
+    ZPL_IMPL_INLINE void zpl_allocation_header_fill(zpl_allocation_header_ev *header, void *data, zpl_isize size) {
+        zpl_isize *ptr;
+        header->size = size;
+        ptr = cast(zpl_isize *)(header + 1);
+        while (cast(void *) ptr < data) *ptr++ = cast(zpl_isize)(-1);
+    }
+
+    //
+    // Stack Memory Allocator
+    //
+
+    #define ZPL_STACK_ALLOC_OFFSET sizeof(zpl_u64)
+    ZPL_STATIC_ASSERT(ZPL_STACK_ALLOC_OFFSET == 8, "ZPL_STACK_ALLOC_OFFSET != 8");
+
+    ZPL_IMPL_INLINE void zpl_stack_memory_init_from_memory(zpl_stack_memory *s, void *start, zpl_isize size) {
+        s->physical_start = start;
+        s->total_size = size;
+        s->allocated = 0;
+    }
+
+    ZPL_IMPL_INLINE void zpl_stack_memory_init(zpl_stack_memory *s, zpl_allocator backing, zpl_isize size) {
+        s->backing = backing;
+        s->physical_start = zpl_alloc(backing, size);
+        s->total_size = size;
+        s->allocated = 0;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_stack_memory_is_in_use(zpl_stack_memory *s, void *ptr) {
+        if (s->allocated == 0) return false;
+
+        if (ptr > s->physical_start && ptr < zpl_pointer_add(s->physical_start, s->total_size)) { return true; }
+
+        return false;
+    }
+
+    ZPL_IMPL_INLINE void zpl_stack_memory_free(zpl_stack_memory *s) {
+        if (s->backing.proc) {
+            zpl_free(s->backing, s->physical_start);
+            s->physical_start = NULL;
+        }
+    }
+
+    ZPL_IMPL_INLINE zpl_allocator zpl_stack_allocator(zpl_stack_memory *s) {
+        zpl_allocator a;
+        a.proc = zpl_stack_allocator_proc;
+        a.data = s;
+        return a;
+    }
+
+    ZPL_END_C_DECLS
+    // file: header/core/collections/array.h
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Dynamic Array (POD Types)
+    //
+    // zpl_array(Type) works like zpl_string or zpl_buffer where the actual type is just a pointer to the first
+    // element.
+    //
+    // Available Procedures for zpl_array(Type)
+    // zpl_array_init
+    // zpl_array_free
+    // zpl_array_set_capacity
+    // zpl_array_grow
+    // zpl_array_append
+    // zpl_array_appendv
+    // zpl_array_pop
+    // zpl_array_clear
+    // zpl_array_back
+    // zpl_array_front
+    // zpl_array_resize
+    // zpl_array_reserve
+    //
+
+    #if 0 // Example
+    void foo(void) {
+        zpl_isize i;
+        int test_values[] = {4, 2, 1, 7};
+        zpl_allocator a = zpl_heap_allocator();
+        zpl_array(int) items;
+
+        zpl_array_init(items, a);
+
+        zpl_array_append(items, 1);
+        zpl_array_append(items, 4);
+        zpl_array_append(items, 9);
+        zpl_array_append(items, 16);
+
+        items[1] = 3; // Manually set value
+        // NOTE: No array bounds checking
+
+        for (i = 0; i < items.count; i++)
+            zpl_printf("%d\n", items[i]);
+        // 1
+        // 3
+        // 9
+        // 16
+
+        zpl_array_clear(items);
+
+        zpl_array_appendv(items, test_values, zpl_count_of(test_values));
+        for (i = 0; i < items.count; i++)
+            zpl_printf("%d\n", items[i]);
+        // 4
+        // 2
+        // 1
+        // 7
+
+        zpl_array_free(items);
+    }
+    #endif
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef struct zpl_array_header {
+        char *data;
+        zpl_isize count;
+        zpl_isize capacity;
+        zpl_allocator allocator;
+    } zpl_array_header;
+
+    #define zpl_array(Type) Type *
+
+    #define zpl_array_make(Type, Name, allocator) Type *Name; zpl_array_init(Name, allocator)
+
+    #ifndef ZPL_ARRAY_GROW_FORMULA
+    #define ZPL_ARRAY_GROW_FORMULA(x) (2 * (x) + 8)
+    #endif
+
+    ZPL_STATIC_ASSERT(ZPL_ARRAY_GROW_FORMULA(0) > 0, "ZPL_ARRAY_GROW_FORMULA(0) <= 0");
+
+    #define ZPL_ARRAY_HEADER(x)    (cast(zpl_array_header *)(x) - 1)
+    #define zpl_array_allocator(x) (ZPL_ARRAY_HEADER(x)->allocator)
+    #define zpl_array_count(x)     (ZPL_ARRAY_HEADER(x)->count)
+    #define zpl_array_capacity(x)  (ZPL_ARRAY_HEADER(x)->capacity)
+    #define zpl_array_end(x)       (x + (zpl_array_count(x) - 1))
+
+    #define zpl_array_init_reserve(x, allocator_, cap)                                                                     \
+    do {                                                                                                               \
+        void **zpl__array_ = cast(void **) & (x);                                                                      \
+        zpl_array_header *zpl__ah =                                                                                    \
+        cast(zpl_array_header *) zpl_alloc(allocator_, zpl_size_of(zpl_array_header) + zpl_size_of(*(x)) * (cap)); \
+        zpl__ah->allocator = allocator_;                                                                               \
+        zpl__ah->count = 0;                                                                                            \
+        zpl__ah->data = (char *)x;                                                                                     \
+        zpl__ah->capacity = cap;                                                                                       \
+        *zpl__array_ = cast(void *)(zpl__ah + 1);                                                                      \
+    } while (0)
+
+    // NOTE: Give it an initial default capacity
+    #define zpl_array_init(x, allocator) zpl_array_init_reserve(x, allocator, ZPL_ARRAY_GROW_FORMULA(0))
+
+    #define zpl_array_free(x)                                                                                              \
+    do {                                                                                                               \
+        zpl_array_header *zpl__ah = ZPL_ARRAY_HEADER(x);                                                               \
+        zpl_free(zpl__ah->allocator, zpl__ah);                                                                         \
+    } while (0)
+
+    #define zpl_array_set_capacity(x, capacity)                                                                            \
+    do {                                                                                                               \
+        if (x) {                                                                                                       \
+            void **zpl__array_ = cast(void **) & (x);                                                                  \
+            *zpl__array_ = zpl__array_set_capacity((x), (capacity), zpl_size_of(*(x)));                                \
+        }                                                                                                              \
+    } while (0)
+
+    // NOTE: Do not use the thing below directly, use the macro
+    ZPL_DEF void *zpl__array_set_capacity(void *array, zpl_isize capacity, zpl_isize element_size);
+
+    #define zpl_array_grow(x, min_capacity)                                                                                \
+    do {                                                                                                               \
+        zpl_isize new_capacity = ZPL_ARRAY_GROW_FORMULA(zpl_array_capacity(x));                                            \
+        if (new_capacity < (min_capacity)) new_capacity = (min_capacity);                                              \
+        zpl_array_set_capacity(x, new_capacity);                                                                       \
+    } while (0)
+
+    #define zpl_array_append(x, item)                                                                                      \
+    do {                                                                                                               \
+        if (zpl_array_capacity(x) < zpl_array_count(x) + 1) zpl_array_grow(x, 0);                                      \
+        (x)[zpl_array_count(x)++] = (item);                                                                            \
+    } while (0)
+
+    #define zpl_array_append_at(x, item, ind)                                                                              \
+    do {                                                                                                               \
+        zpl_array_header *zpl__ah = ZPL_ARRAY_HEADER(x);                                                               \
+        if (ind == zpl__ah->count) { zpl_array_append(x, item); break; }                                               \
+        if (zpl_array_capacity(x) < zpl_array_count(x) + 1) zpl_array_grow(x, 0);                                      \
+        zpl_memmove(&(x)[ind + 1], (x + ind), zpl_size_of(x[0]) * (zpl__ah->count - ind));                             \
+        x[ind] = item;                                                                                                 \
+        zpl__ah->count++;                                                                                              \
+    } while (0)
+
+    #define zpl_array_appendv(x, items, item_count)                                                                        \
+    do {                                                                                                               \
+        zpl_array_header *zpl__ah = ZPL_ARRAY_HEADER(x);                                                               \
+        ZPL_ASSERT(zpl_size_of((items)[0]) == zpl_size_of((x)[0]));                                                    \
+        if (zpl__ah->capacity < zpl__ah->count + (item_count)) zpl_array_grow(x, zpl__ah->count + (item_count));       \
+        zpl_memcopy(&(x)[zpl__ah->count], (items), zpl_size_of((x)[0]) * (item_count));                                \
+        zpl__ah->count += (item_count);                                                                                \
+    } while (0)
+
+    #define zpl_array_remove_at(x, index)                                                                                  \
+    do {                                                                                                               \
+        zpl_array_header *zpl__ah = ZPL_ARRAY_HEADER(x);                                                               \
+        ZPL_ASSERT(index < zpl__ah->count);                                                                            \
+        zpl_memmove(x + index, x + index + 1, zpl_size_of(x[0]) * (zpl__ah->count - index));                           \
+        --zpl__ah->count;                                                                                              \
+    } while (0)
+
+    #define zpl_array_copy_init(y, x)                                                                                      \
+    do {                                                                                                               \
+        zpl_array_init_reserve(y, zpl_array_allocator(x), zpl_array_capacity(x));                                      \
+        zpl_memcopy(y, x, zpl_array_capacity(x) * zpl_size_of(*x));                                                    \
+        zpl_array_count(y) = zpl_array_count(x);                                                                       \
+    } while (0)
+
+    #define zpl_array_pop(x)                                                                                               \
+    do {                                                                                                               \
+        ZPL_ASSERT(ZPL_ARRAY_HEADER(x)->count > 0);                                                                    \
+        ZPL_ARRAY_HEADER(x)->count--;                                                                                  \
+    } while (0)
+    #define zpl_array_back(x) x[ZPL_ARRAY_HEADER(x)->count - 1]
+    #define zpl_array_front(x) x[0]
+    #define zpl_array_clear(x)                                                                                             \
+    do { ZPL_ARRAY_HEADER(x)->count = 0; } while (0)
+
+    #define zpl_array_resize(x, new_count)                                                                                 \
+    do {                                                                                                               \
+        if (ZPL_ARRAY_HEADER(x)->capacity < (new_count)) zpl_array_grow(x, (new_count));                               \
+        ZPL_ARRAY_HEADER(x)->count = (new_count);                                                                      \
+    } while (0)
+
+    #define zpl_array_reserve(x, new_capacity)                                                                             \
+    do {                                                                                                               \
+        if (ZPL_ARRAY_HEADER(x)->capacity < (new_capacity)) zpl_array_set_capacity(x, new_capacity);                   \
+    } while (0)
+
+    ZPL_END_C_DECLS
+    // file: header/core/collections/buffer.h
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Fixed Capacity Buffer (POD Types)
+    //
+    //
+    // zpl_buffer(Type) works like zpl_string or zpl_array where the actual type is just a pointer to the first
+    // element.
+    //
+    // Available Procedures for zpl_buffer(Type)
+    // zpl_buffer_init
+    // zpl_buffer_free
+    // zpl_buffer_append
+    // zpl_buffer_appendv
+    // zpl_buffer_pop
+    // zpl_buffer_clear
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef struct zpl_buffer_header {
+        zpl_allocator backing;
+        zpl_isize count;
+        zpl_isize capacity;
+    } zpl_buffer_header;
+
+    #define zpl_buffer(Type) Type *
+
+    #define zpl_buffer_make(Type, Name, allocator, cap) Type *Name; zpl_buffer_init(Name, allocator, cap)
+
+    #define ZPL_BUFFER_HEADER(x)   (cast(zpl_buffer_header *)(x) - 1)
+    #define zpl_buffer_count(x)    (ZPL_BUFFER_HEADER(x)->count)
+    #define zpl_buffer_capacity(x) (ZPL_BUFFER_HEADER(x)->capacity)
+    #define zpl_buffer_end(x) (x + (zpl_buffer_count(x) - 1))
+
+    #define zpl_buffer_init(x, allocator, cap)                                                                             \
+    do {                                                                                                               \
+        void **nx = cast(void **) & (x);                                                                               \
+        zpl_buffer_header *zpl__bh =                                                                                   \
+        cast(zpl_buffer_header *) zpl_alloc((allocator), sizeof(zpl_buffer_header) + (cap)*zpl_size_of(*(x)));     \
+        zpl__bh->backing = allocator;                                                                                  \
+        zpl__bh->count = 0;                                                                                            \
+        zpl__bh->capacity = cap;                                                                                       \
+        *nx = cast(void *)(zpl__bh + 1);                                                                               \
+    } while (0)
+
+    #define zpl_buffer_free(x) (zpl_free(ZPL_BUFFER_HEADER(x)->backing, ZPL_BUFFER_HEADER(x)))
+
+    #define zpl_buffer_append(x, item)                                                                                     \
+    do { (x)[zpl_buffer_count(x)++] = (item); } while (0)
+
+    #define zpl_buffer_appendv(x, items, item_count)                                                                       \
+    do {                                                                                                               \
+        ZPL_ASSERT(zpl_size_of(*(items)) == zpl_size_of(*(x)));                                                        \
+        ZPL_ASSERT(zpl_buffer_count(x) + item_count <= zpl_buffer_capacity(x));                                        \
+        zpl_memcopy(&(x)[zpl_buffer_count(x)], (items), zpl_size_of(*(x)) * (item_count));                             \
+        zpl_buffer_count(x) += (item_count);                                                                           \
+    } while (0)
+
+    #define zpl_buffer_copy_init(y, x)                                                                                     \
+    do {                                                                                                               \
+        zpl_buffer_init_reserve(y, zpl_buffer_allocator(x), zpl_buffer_capacity(x));                                   \
+        zpl_memcopy(y, x, zpl_buffer_capacity(x) * zpl_size_of(*x));                                                   \
+        zpl_buffer_count(y) = zpl_buffer_count(x);                                                                     \
+    } while (0)
+
+    #define zpl_buffer_pop(x)                                                                                              \
+    do {                                                                                                               \
+        ZPL_ASSERT(zpl_buffer_count(x) > 0);                                                                           \
+        zpl_buffer_count(x)--;                                                                                         \
+    } while (0)
+    #define zpl_buffer_clear(x)                                                                                            \
+    do { zpl_buffer_count(x) = 0; } while (0)
+
+    ZPL_END_C_DECLS
+    // file: header/core/collections/list.h
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Linked List
+    //
+    // zpl_list encapsulates pointer to data and points to the next and the previous element in the list.
+    //
+    // Available Procedures for zpl_list
+    // zpl_list_init
+    // zpl_list_add
+    // zpl_list_remove
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #if 0
+    #define ZPL_IMPLEMENTATION
+    #include "zpl.h"
+    int main(void)
+    {
+        zpl_list s, *head, *cursor;
+        zpl_list_init(&s, "it is optional to call init: ");
+        head = cursor = &s;
+
+        // since we can construct an element implicitly this way
+        // the second field gets overwritten once we add it to a list.
+        zpl_list a = {"hello"};
+        cursor = zpl_list_add(cursor, &a);
+
+        zpl_list b = {"world"};
+        cursor = zpl_list_add(cursor, &b);
+
+        zpl_list c = {"!!! OK"};
+        cursor = zpl_list_add(cursor, &c);
+
+        for (zpl_list *l=head; l; l=l->next) {
+            zpl_printf("%s ", cast(char *)l->ptr);
+        }
+        zpl_printf("\n");
+
+        return 0;
+    }
+    #endif
+
+
+    typedef struct zpl__list {
+        void const *ptr;
+        struct zpl__list *next, *prev;
+    } zpl_list;
+
+    ZPL_DEF_INLINE void      zpl_list_init(zpl_list *list, void const *ptr);
+    ZPL_DEF_INLINE zpl_list *zpl_list_add(zpl_list *list, zpl_list *item);
+
+    // NOTE(zaklaus): Returns a pointer to the next node (or NULL if the removed node has no trailing node.)
+    ZPL_DEF_INLINE zpl_list *zpl_list_remove(zpl_list *list);
+
+
+    ZPL_IMPL_INLINE void zpl_list_init(zpl_list *list, void const *ptr) {
+        zpl_list list_ = { 0 };
+        *list = list_;
+        list->ptr = ptr;
+    }
+
+    ZPL_IMPL_INLINE zpl_list *zpl_list_add(zpl_list *list, zpl_list *item) {
+        item->next = NULL;
+
+        if (list->next) { item->next = list->next; }
+
+        list->next = item;
+        item->prev = list;
+        return item;
+    }
+
+    ZPL_IMPL_INLINE zpl_list *zpl_list_remove(zpl_list *list) {
+        if (list->prev) { list->prev->next = list->next; }
+
+        return list->next;
+    }
+
+    ZPL_END_C_DECLS
+    // file: header/core/collections/ring.h
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Instantiated Circular buffer
+    //
+    /*
+    int main()
+    {
+        zpl_ring_zpl_u32 pad={0};
+        zpl_ring_zpl_u32_init(&pad, zpl_heap(), 3);
+        zpl_ring_zpl_u32_append(&pad, 1);
+        zpl_ring_zpl_u32_append(&pad, 2);
+        zpl_ring_zpl_u32_append(&pad, 3);
+
+        while (!zpl_ring_zpl_u32_empty(&pad)) {
+            zpl_printf("Result is %d\n", *zpl_ring_zpl_u32_get(&pad));
+        }
+
+        zpl_ring_zpl_u32_free(&pad);
+
+        return 0;
+    }
+    */
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #define ZPL_RING_DECLARE(type)                                                                                         \
+    typedef struct {                                                                                                   \
+        zpl_allocator backing;                                                                                         \
+        zpl_buffer(type) buf;                                                                                          \
+        zpl_usize head, tail;                                                                                              \
+        zpl_usize capacity;                                                                                                \
+    } ZPL_JOIN2(zpl_ring_, type);                                                                                      \
+    \
+    ZPL_DEF void ZPL_JOIN3(zpl_ring_, type, _init)(ZPL_JOIN2(zpl_ring_, type) * pad, zpl_allocator a, zpl_isize max_size); \
+    ZPL_DEF void ZPL_JOIN3(zpl_ring_, type, _free)(ZPL_JOIN2(zpl_ring_, type) * pad);                                  \
+    ZPL_DEF zpl_b32 ZPL_JOIN3(zpl_ring_, type, _full)(ZPL_JOIN2(zpl_ring_, type) * pad);                                   \
+    ZPL_DEF zpl_b32 ZPL_JOIN3(zpl_ring_, type, _empty)(ZPL_JOIN2(zpl_ring_, type) * pad);                                  \
+    ZPL_DEF void ZPL_JOIN3(zpl_ring_, type, _append)(ZPL_JOIN2(zpl_ring_, type) * pad, type data);                     \
+    ZPL_DEF void ZPL_JOIN3(zpl_ring_, type, _append_array)(ZPL_JOIN2(zpl_ring_, type) * pad, zpl_array(type) data);    \
+    ZPL_DEF type *ZPL_JOIN3(zpl_ring_, type, _get)(ZPL_JOIN2(zpl_ring_, type) * pad);                                  \
+    ZPL_DEF zpl_array(type)                                                                                            \
+    ZPL_JOIN3(zpl_ring_, type, _get_array)(ZPL_JOIN2(zpl_ring_, type) * pad, zpl_usize max_size, zpl_allocator a);
+
+    #define ZPL_RING_DEFINE(type)                                                                                          \
+    void ZPL_JOIN3(zpl_ring_, type, _init)(ZPL_JOIN2(zpl_ring_, type) * pad, zpl_allocator a, zpl_isize max_size) {        \
+        ZPL_JOIN2(zpl_ring_, type) pad_ = { 0 };                                                                       \
+        *pad = pad_;                                                                                                   \
+        \
+        pad->backing = a;                                                                                              \
+        zpl_buffer_init(pad->buf, a, max_size + 1);                                                                    \
+        pad->capacity = max_size + 1;                                                                                  \
+        pad->head = pad->tail = 0;                                                                                     \
+    }                                                                                                                  \
+    void ZPL_JOIN3(zpl_ring_, type, _free)(ZPL_JOIN2(zpl_ring_, type) * pad) {                                         \
+        zpl_buffer_free(pad->buf);                                                                       \
+    }                                                                                                                  \
+    \
+    zpl_b32 ZPL_JOIN3(zpl_ring_, type, _full)(ZPL_JOIN2(zpl_ring_, type) * pad) {                                          \
+        return ((pad->head + 1) % pad->capacity) == pad->tail;                                                         \
+    }                                                                                                                  \
+    \
+    zpl_b32 ZPL_JOIN3(zpl_ring_, type, _empty)(ZPL_JOIN2(zpl_ring_, type) * pad) { return pad->head == pad->tail; }        \
+    \
+    void ZPL_JOIN3(zpl_ring_, type, _append)(ZPL_JOIN2(zpl_ring_, type) * pad, type data) {                            \
+        pad->buf[pad->head] = data;                                                                                    \
+        pad->head = (pad->head + 1) % pad->capacity;                                                                   \
+        \
+        if (pad->head == pad->tail) { pad->tail = (pad->tail + 1) % pad->capacity; }                                   \
+    }                                                                                                                  \
+    \
+    void ZPL_JOIN3(zpl_ring_, type, _append_array)(ZPL_JOIN2(zpl_ring_, type) * pad, zpl_array(type) data) {           \
+        zpl_usize c = zpl_array_count(data);                                                                               \
+        for (zpl_usize i = 0; i < c; ++i) { ZPL_JOIN3(zpl_ring_, type, _append)(pad, data[i]); }                           \
+    }                                                                                                                  \
+    \
+    type *ZPL_JOIN3(zpl_ring_, type, _get)(ZPL_JOIN2(zpl_ring_, type) * pad) {                                         \
+        if (ZPL_JOIN3(zpl_ring_, type, _empty)(pad)) { return NULL; }                                                  \
+        \
+        type *data = &pad->buf[pad->tail];                                                                             \
+        pad->tail = (pad->tail + 1) % pad->capacity;                                                                   \
+        \
+        return data;                                                                                                   \
+    }                                                                                                                  \
+    \
+    zpl_array(type)                                                                                                    \
+    ZPL_JOIN3(zpl_ring_, type, _get_array)(ZPL_JOIN2(zpl_ring_, type) * pad, zpl_usize max_size, zpl_allocator a) {    \
+        zpl_array(type) vals = 0;                                                                                          \
+        zpl_array_init(vals, a);                                                                                       \
+        while (--max_size && !ZPL_JOIN3(zpl_ring_, type, _empty)(pad)) {                                               \
+            zpl_array_append(vals, *ZPL_JOIN3(zpl_ring_, type, _get)(pad));                                            \
+        }                                                                                                              \
+        return vals;                                                                                                   \
+    }
+
+    ZPL_END_C_DECLS
+    // file: header/core/collections/hashtable.h
+
+    /** @file hashtable.c
+    @brief Instantiated hash table
+    @defgroup hashtable Instantiated hash table
+
+    @n
+    @n This is an attempt to implement a templated hash table
+    @n NOTE: The key is always a zpl_u64 for simplicity and you will _probably_ _never_ need anything bigger.
+    @n
+    @n Hash table type and function declaration, call: ZPL_TABLE_DECLARE(PREFIX, NAME, N, VALUE)
+    @n Hash table function definitions, call: ZPL_TABLE_DEFINE(NAME, N, VALUE)
+    @n
+    @n     PREFIX  - a prefix for function prototypes e.g. extern, static, etc.
+    @n     NAME    - Name of the Hash Table
+    @n     FUNC    - the name will prefix function names
+    @n     VALUE   - the type of the value to be stored
+    @n
+    @n tablename_init(NAME * h, zpl_allocator a);
+    @n tablename_destroy(NAME * h);
+    @n tablename_get(NAME * h, zpl_u64 key);
+    @n tablename_set(NAME * h, zpl_u64 key, VALUE value);
+    @n tablename_grow(NAME * h);
+    @n tablename_rehash(NAME * h, zpl_isize new_count);
+    @n tablename_remove(NAME * h, zpl_u64 key);
+
+     @{
+    */
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef struct zpl_hash_table_find_result {
+        zpl_isize hash_index;
+        zpl_isize entry_prev;
+        zpl_isize entry_index;
+    } zpl_hash_table_find_result;
+
+    #define ZPL_TABLE(PREFIX, NAME, FUNC, VALUE)                                                                           \
+    ZPL_TABLE_DECLARE(PREFIX, NAME, FUNC, VALUE);                                                                      \
+    ZPL_TABLE_DEFINE(NAME, FUNC, VALUE);
+
+    #define ZPL_TABLE_DECLARE(PREFIX, NAME, FUNC, VALUE)                                                                   \
+    typedef struct ZPL_JOIN2(NAME, Entry) {                                                                            \
+        zpl_u64 key;                                                                                                       \
+        zpl_isize next;                                                                                                    \
+        VALUE value;                                                                                                   \
+    } ZPL_JOIN2(NAME, Entry);                                                                                          \
+    \
+    typedef struct NAME {                                                                                              \
+        zpl_array(zpl_isize) hashes;                                                                                       \
+        zpl_array(ZPL_JOIN2(NAME, Entry)) entries;                                                                     \
+    } NAME;                                                                                                            \
+    \
+    PREFIX void ZPL_JOIN2(FUNC, init)(NAME * h, zpl_allocator a);                                                      \
+    PREFIX void ZPL_JOIN2(FUNC, destroy)(NAME * h);                                                                    \
+    PREFIX VALUE *ZPL_JOIN2(FUNC, get)(NAME * h, zpl_u64 key);                                                             \
+    PREFIX void ZPL_JOIN2(FUNC, set)(NAME * h, zpl_u64 key, VALUE value);                                                  \
+    PREFIX void ZPL_JOIN2(FUNC, grow)(NAME * h);                                                                       \
+    PREFIX void ZPL_JOIN2(FUNC, rehash)(NAME * h, zpl_isize new_count);                                                    \
+    PREFIX void ZPL_JOIN2(FUNC, remove)(NAME * h, zpl_u64 key);
+
+    #define ZPL_TABLE_DEFINE(NAME, FUNC, VALUE)                                                                            \
+    void ZPL_JOIN2(FUNC, init)(NAME * h, zpl_allocator a) {                                                            \
+        zpl_array_init(h->hashes, a);                                                                                  \
+        zpl_array_init(h->entries, a);                                                                                 \
+    }                                                                                                                  \
+    \
+    void ZPL_JOIN2(FUNC, destroy)(NAME * h) {                                                                          \
+        if (h->entries) zpl_array_free(h->entries);                                                                    \
+        if (h->hashes) zpl_array_free(h->hashes);                                                                      \
+    }                                                                                                                  \
+    \
+    zpl_internal zpl_isize ZPL_JOIN2(FUNC, _add_entry)(NAME * h, zpl_u64 key) {                                                \
+        zpl_isize index;                                                                                                   \
+        ZPL_JOIN2(NAME, Entry) e = { 0 };                                                                              \
+        e.key = key;                                                                                                   \
+        e.next = -1;                                                                                                   \
+        index = zpl_array_count(h->entries);                                                                           \
+        zpl_array_append(h->entries, e);                                                                               \
+        return index;                                                                                                  \
+    }                                                                                                                  \
+    \
+    zpl_internal zpl_hash_table_find_result ZPL_JOIN2(FUNC, _find)(NAME * h, zpl_u64 key) {                                \
+        zpl_hash_table_find_result r = { -1, -1, -1 };                                                                 \
+        if (zpl_array_count(h->hashes) > 0) {                                                                          \
+            r.hash_index = key % zpl_array_count(h->hashes);                                                           \
+            r.entry_index = h->hashes[r.hash_index];                                                                   \
+            while (r.entry_index >= 0) {                                                                               \
+                if (h->entries[r.entry_index].key == key) return r;                                                    \
+                r.entry_prev = r.entry_index;                                                                          \
+                r.entry_index = h->entries[r.entry_index].next;                                                        \
+            }                                                                                                          \
+        }                                                                                                              \
+        return r;                                                                                                      \
+    }                                                                                                                  \
+    \
+    zpl_internal zpl_b32 ZPL_JOIN2(FUNC, _full)(NAME * h) {                                                                \
+        return 0.75f * zpl_array_count(h->hashes) < zpl_array_count(h->entries);                                       \
+    }                                                                                                                  \
+    \
+    void ZPL_JOIN2(FUNC, grow)(NAME * h) {                                                                             \
+        zpl_isize new_count = ZPL_ARRAY_GROW_FORMULA(zpl_array_count(h->entries));                                         \
+        ZPL_JOIN2(FUNC, rehash)(h, new_count);                                                                         \
+    }                                                                                                                  \
+    \
+    void ZPL_JOIN2(FUNC, rehash)(NAME * h, zpl_isize new_count) {                                                          \
+        zpl_isize i, j;                                                                                                    \
+        NAME nh = { 0 };                                                                                               \
+        ZPL_JOIN2(FUNC, init)(&nh, zpl_array_allocator(h->hashes));                                                    \
+        zpl_array_resize(nh.hashes, new_count);                                                                        \
+        zpl_array_reserve(nh.entries, zpl_array_count(h->entries));                                                    \
+        for (i = 0; i < new_count; i++) nh.hashes[i] = -1;                                                             \
+        for (i = 0; i < zpl_array_count(h->entries); i++) {                                                            \
+            ZPL_JOIN2(NAME, Entry) * e;                                                                                \
+            zpl_hash_table_find_result fr;                                                                             \
+            if (zpl_array_count(nh.hashes) == 0) ZPL_JOIN2(FUNC, grow)(&nh);                                           \
+            e = &h->entries[i];                                                                                        \
+            fr = ZPL_JOIN2(FUNC, _find)(&nh, e->key);                                                                  \
+            j = ZPL_JOIN2(FUNC, _add_entry)(&nh, e->key);                                                              \
+            if (fr.entry_prev < 0)                                                                                     \
+            nh.hashes[fr.hash_index] = j;                                                                          \
+            else                                                                                                       \
+            nh.entries[fr.entry_prev].next = j;                                                                    \
+            nh.entries[j].next = fr.entry_index;                                                                       \
+            nh.entries[j].value = e->value;                                                                            \
+        }                                                                                                              \
+        ZPL_JOIN2(FUNC, destroy)(h);                                                                                   \
+        h->hashes = nh.hashes;                                                                                         \
+        h->entries = nh.entries;                                                                                       \
+    }                                                                                                                  \
+    \
+    VALUE *ZPL_JOIN2(FUNC, get)(NAME * h, zpl_u64 key) {                                                                   \
+        zpl_isize index = ZPL_JOIN2(FUNC, _find)(h, key).entry_index;                                                      \
+        if (index >= 0) return &h->entries[index].value;                                                               \
+        return NULL;                                                                                                   \
+    }                                                                                                                  \
+    \
+    void ZPL_JOIN2(FUNC, remove)(NAME * h, zpl_u64 key) {                                                                  \
+        zpl_hash_table_find_result fr = ZPL_JOIN2(FUNC, _find)(h, key);                                                \
+        if (fr.entry_index >= 0) {                                                                                     \
+            if (fr.entry_prev >= 0) {                                                                                  \
+                h->entries[fr.entry_prev].next = h->entries[fr.entry_index].next;                                      \
+            } else {                                                                                                   \
+                h->hashes[fr.hash_index] = fr.entry_index;                                                             \
+            }                                                                                                          \
+            zpl_array_remove_at(h->entries, fr.entry_index);                                                           \
+        }                                                                                                              \
+        ZPL_JOIN2(FUNC, rehash)(h, zpl_array_count(h->entries));                                                       \
+    }                                                                                                                  \
+    \
+    void ZPL_JOIN2(FUNC, set)(NAME * h, zpl_u64 key, VALUE value) {                                                        \
+        zpl_isize index;                                                                                                   \
+        zpl_hash_table_find_result fr;                                                                                 \
+        if (zpl_array_count(h->hashes) == 0) ZPL_JOIN2(FUNC, grow)(h);                                                 \
+        fr = ZPL_JOIN2(FUNC, _find)(h, key);                                                                           \
+        if (fr.entry_index >= 0) {                                                                                     \
+            index = fr.entry_index;                                                                                    \
+        } else {                                                                                                       \
+            index = ZPL_JOIN2(FUNC, _add_entry)(h, key);                                                               \
+            if (fr.entry_prev >= 0) {                                                                                  \
+                h->entries[fr.entry_prev].next = index;                                                                \
+            } else {                                                                                                   \
+                h->hashes[fr.hash_index] = index;                                                                      \
+            }                                                                                                          \
+        }                                                                                                              \
+        h->entries[index].value = value;                                                                               \
+        if (ZPL_JOIN2(FUNC, _full)(h)) ZPL_JOIN2(FUNC, grow)(h);                                                       \
+    }\
+
+    //! @}
+
+    ZPL_END_C_DECLS
+    // file: header/core/string.h
+
+    /** @file string.c
+    @brief String operations and library
+    @defgroup string String library
+
+    Offers methods for c-string manipulation, but also a string library based on gb_string, which is c-string friendly.
+
+    @{
+    */
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Char Functions
+    //
+    //
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    ZPL_DEF_INLINE char    zpl_char_to_lower(char c);
+    ZPL_DEF_INLINE char    zpl_char_to_upper(char c);
+    ZPL_DEF_INLINE zpl_b32 zpl_char_is_space(char c);
+    ZPL_DEF_INLINE zpl_b32 zpl_char_is_digit(char c);
+    ZPL_DEF_INLINE zpl_b32 zpl_char_is_hex_digit(char c);
+    ZPL_DEF_INLINE zpl_b32 zpl_char_is_alpha(char c);
+    ZPL_DEF_INLINE zpl_b32 zpl_char_is_alphanumeric(char c);
+    ZPL_DEF_INLINE zpl_i32 zpl_digit_to_int(char c);
+    ZPL_DEF_INLINE zpl_i32 zpl_hex_digit_to_int(char c);
+    ZPL_DEF_INLINE zpl_u8  zpl_char_to_hex_digit(char c);
+    ZPL_DEF_INLINE zpl_b32 zpl_char_is_control(char c);
+
+    // NOTE: ASCII only
+    ZPL_DEF_INLINE void zpl_str_to_lower(char *str);
+    ZPL_DEF_INLINE void zpl_str_to_upper(char *str);
+
+    ZPL_DEF_INLINE char *zpl_str_trim(char *str, zpl_b32 skip_newline);
+    ZPL_DEF_INLINE char *zpl_str_skip(char *str, char c);
+    ZPL_DEF_INLINE char *zpl_str_control_skip(char *str, char c);
+
+    ZPL_DEF_INLINE zpl_isize   zpl_strlen(const char *str);
+    ZPL_DEF_INLINE zpl_isize   zpl_strnlen(const char *str, zpl_isize max_len);
+    ZPL_DEF_INLINE zpl_i32     zpl_strcmp(const char *s1, const char *s2);
+    ZPL_DEF_INLINE zpl_i32     zpl_strncmp(const char *s1, const char *s2, zpl_isize len);
+    ZPL_DEF_INLINE char       *zpl_strcpy(char *dest, const char *source);
+    ZPL_DEF_INLINE char       *zpl_strncpy(char *dest, const char *source, zpl_isize len);
+    ZPL_DEF_INLINE zpl_isize   zpl_strlcpy(char *dest, const char *source, zpl_isize len);
+    ZPL_DEF_INLINE char       *zpl_strrev(char *str); // NOTE: ASCII only
+    ZPL_DEF_INLINE const char *zpl_strtok(char *output, const char *src, const char *delimit);
+
+    ZPL_DEF_INLINE char   *zpl_strdup(zpl_allocator a, char *src, zpl_isize max_len);
+    ZPL_DEF_INLINE char  **zpl_str_split_lines(zpl_allocator alloc, char *source, zpl_b32 strip_whitespace);
+
+    #define zpl_str_expand(str) str, zpl_strlen(str)
+
+    ZPL_DEF_INLINE zpl_b32 zpl_str_has_prefix(const char *str, const char *prefix);
+    ZPL_DEF_INLINE zpl_b32 zpl_str_has_suffix(const char *str, const char *suffix);
+
+    ZPL_DEF_INLINE const char *zpl_char_first_occurence(const char *str, char c);
+    ZPL_DEF_INLINE const char *zpl_char_last_occurence(const char *str, char c);
+    #define zpl_strchr zpl_char_first_occurence
+
+    ZPL_DEF_INLINE void zpl_str_concat(char *dest, zpl_isize dest_len, const char *src_a, zpl_isize src_a_len, const char *src_b, zpl_isize src_b_len);
+
+    ZPL_DEF zpl_u64 zpl_str_to_u64(const char *str, char **end_ptr, zpl_i32 base); // TODO: Support more than just decimal and hexadecimal
+    ZPL_DEF zpl_i64 zpl_str_to_i64(const char *str, char **end_ptr, zpl_i32 base); // TODO: Support more than just decimal and hexadecimal
+    ZPL_DEF zpl_f64 zpl_str_to_f64(const char *str, char **end_ptr);
+    ZPL_DEF void    zpl_i64_to_str(zpl_i64 value, char *string, zpl_i32 base);
+    ZPL_DEF void    zpl_u64_to_str(zpl_u64 value, char *string, zpl_i32 base);
+
+    ZPL_DEF_INLINE zpl_f32 zpl_str_to_f32(const char *str, char **end_ptr);
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // UTF-8 Handling
+    //
+    //
+
+    // NOTE: Does not check if utf-8 string is valid
+    ZPL_IMPL_INLINE zpl_isize zpl_utf8_strlen(zpl_u8 const *str);
+    ZPL_IMPL_INLINE zpl_isize zpl_utf8_strnlen(zpl_u8 const *str, zpl_isize max_len);
+
+    // NOTE: Windows doesn't handle 8 bit filenames well
+    ZPL_DEF zpl_u16 *zpl_utf8_to_ucs2(zpl_u16 *buffer, zpl_isize len, zpl_u8 const *str);
+    ZPL_DEF zpl_u8  *zpl_ucs2_to_utf8(zpl_u8 *buffer, zpl_isize len, zpl_u16 const *str);
+    ZPL_DEF zpl_u16 *zpl_utf8_to_ucs2_buf(zpl_u8 const *str); // NOTE: Uses locally persisting buffer
+    ZPL_DEF zpl_u8  *zpl_ucs2_to_utf8_buf(zpl_u16 const *str); // NOTE: Uses locally persisting buffer
+
+    // NOTE: Returns size of codepoint in bytes
+    ZPL_DEF zpl_isize zpl_utf8_decode(zpl_u8 const *str, zpl_isize str_len, zpl_rune *codepoint);
+    ZPL_DEF zpl_isize zpl_utf8_codepoint_size(zpl_u8 const *str, zpl_isize str_len);
+    ZPL_DEF zpl_isize zpl_utf8_encode_rune(zpl_u8 buf[4], zpl_rune r);
+
+    /* inlines */
+
+    ZPL_IMPL_INLINE char zpl_char_to_lower(char c) {
+        if (c >= 'A' && c <= 'Z') return 'a' + (c - 'A');
+        return c;
+    }
+
+    ZPL_IMPL_INLINE char zpl_char_to_upper(char c) {
+        if (c >= 'a' && c <= 'z') return 'A' + (c - 'a');
+        return c;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_char_is_space(char c) {
+        if (c == ' ' || c == '\t' || c == '\n' || c == '\r' || c == '\f' || c == '\v') return true;
+        return false;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_char_is_digit(char c) {
+        if (c >= '0' && c <= '9') return true;
+        return false;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_char_is_hex_digit(char c) {
+        if (zpl_char_is_digit(c) || (c >= 'a' && c <= 'f') || (c >= 'A' && c <= 'F')) return true;
+        return false;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_char_is_alpha(char c) {
+        if ((c >= 'A' && c <= 'Z') || (c >= 'a' && c <= 'z')) return true;
+        return false;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_char_is_alphanumeric(char c) { return zpl_char_is_alpha(c) || zpl_char_is_digit(c); }
+
+    ZPL_IMPL_INLINE zpl_i32 zpl_digit_to_int(char c) { return zpl_char_is_digit(c) ? c - '0' : c - 'W'; }
+
+    ZPL_IMPL_INLINE zpl_i32 zpl_hex_digit_to_int(char c) {
+        if (zpl_char_is_digit(c))
+            return zpl_digit_to_int(c);
+        else if (zpl_is_between(c, 'a', 'f'))
+            return c - 'a' + 10;
+        else if (zpl_is_between(c, 'A', 'F'))
+            return c - 'A' + 10;
+        return -1;
+    }
+
+    ZPL_IMPL_INLINE zpl_u8 zpl_char_to_hex_digit(char c) {
+        if (c >= '0' && c <= '9')
+            return (zpl_u8)(c - '0');
+        if (c >= 'a' && c <= 'f')
+            return (zpl_u8)(c - 'a');
+        if (c >= 'A' && c <= 'F')
+            return (zpl_u8)(c - 'A');
+        return 0;
+    }
+
+
+    ZPL_IMPL_INLINE void zpl_str_to_lower(char *str) {
+        if (!str) return;
+        while (*str) {
+            *str = zpl_char_to_lower(*str);
+            str++;
+        }
+    }
+
+    ZPL_IMPL_INLINE void zpl_str_to_upper(char *str) {
+        if (!str) return;
+        while (*str) {
+            *str = zpl_char_to_upper(*str);
+            str++;
+        }
+    }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_strlen(const char *str) {
+        if (str == NULL) { return 0; }
+
+        const char *begin = str;
+        zpl_isize const *w;
+        while (cast(zpl_uintptr) str % sizeof(zpl_usize)) {
+            if (!*str) return str - begin;
+            str++;
+        }
+        w = cast(zpl_isize const *) str;
+        while (!ZPL__HAS_ZERO(*w)) w++;
+        str = cast(const char *) w;
+        while (*str) str++;
+        return str - begin;
+    }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_strnlen(const char *str, zpl_isize max_len) {
+        const char *end = cast(const char *) zpl_memchr(str, 0, max_len);
+        if (end) return end - str;
+        return max_len;
+    }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_utf8_strlen(zpl_u8 const *str) {
+        zpl_isize count = 0;
+        for (; *str; count++) {
+            zpl_u8 c = *str;
+            zpl_isize inc = 0;
+            if (c < 0x80)
+                inc = 1;
+            else if ((c & 0xe0) == 0xc0)
+                inc = 2;
+            else if ((c & 0xf0) == 0xe0)
+                inc = 3;
+            else if ((c & 0xf8) == 0xf0)
+                inc = 4;
+            else
+                return -1;
+
+            str += inc;
+        }
+        return count;
+    }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_utf8_strnlen(zpl_u8 const *str, zpl_isize max_len) {
+        zpl_isize count = 0;
+        for (; *str && max_len > 0; count++) {
+            zpl_u8 c = *str;
+            zpl_isize inc = 0;
+            if (c < 0x80)
+                inc = 1;
+            else if ((c & 0xe0) == 0xc0)
+                inc = 2;
+            else if ((c & 0xf0) == 0xe0)
+                inc = 3;
+            else if ((c & 0xf8) == 0xf0)
+                inc = 4;
+            else
+                return -1;
+
+            str += inc;
+            max_len -= inc;
+        }
+        return count;
+    }
+
+    ZPL_IMPL_INLINE zpl_i32 zpl_strcmp(const char *s1, const char *s2) {
+        while (*s1 && (*s1 == *s2)) { s1++, s2++; }
+        return *(zpl_u8 *)s1 - *(zpl_u8 *)s2;
+    }
+
+    ZPL_IMPL_INLINE char *zpl_strcpy(char *dest, const char *source) {
+        ZPL_ASSERT_NOT_NULL(dest);
+        if (source) {
+            char *str = dest;
+            while (*source) *str++ = *source++;
+        }
+        return dest;
+    }
+
+    ZPL_IMPL_INLINE char *zpl_strncpy(char *dest, const char *source, zpl_isize len) {
+        ZPL_ASSERT_NOT_NULL(dest);
+        if (source) {
+            char *str = dest;
+            while (len > 0 && *source) {
+                *str++ = *source++;
+                len--;
+            }
+            while (len > 0) {
+                *str++ = '\0';
+                len--;
+            }
+        }
+        return dest;
+    }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_strlcpy(char *dest, const char *source, zpl_isize len) {
+        zpl_isize result = 0;
+        ZPL_ASSERT_NOT_NULL(dest);
+        if (source) {
+            const char *source_start = source;
+            char *str = dest;
+            while (len > 0 && *source) {
+                *str++ = *source++;
+                len--;
+            }
+            while (len > 0) {
+                *str++ = '\0';
+                len--;
+            }
+
+            result = source - source_start;
+        }
+        return result;
+    }
+
+    ZPL_IMPL_INLINE char *zpl_strrev(char *str) {
+        zpl_isize len = zpl_strlen(str);
+        char *a = str + 0;
+        char *b = str + len - 1;
+        len /= 2;
+        while (len--) {
+            zpl_swap(char, *a, *b);
+            a++, b--;
+        }
+        return str;
+    }
+
+    ZPL_IMPL_INLINE zpl_i32 zpl_strncmp(const char *s1, const char *s2, zpl_isize len) {
+        for (; len > 0; s1++, s2++, len--) {
+            if (*s1 != *s2)
+                return ((s1 < s2) ? -1 : +1);
+            else if (*s1 == '\0')
+                return 0;
+        }
+        return 0;
+    }
+
+    ZPL_IMPL_INLINE const char *zpl_strtok(char *output, const char *src, const char *delimit) {
+        while (*src && zpl_char_first_occurence(delimit, *src) == NULL) *output++ = *src++;
+
+        *output = 0;
+        return *src ? src + 1 : src;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_char_is_control(char c) {
+        return !!zpl_strchr("\"\\/bfnrt", c);
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl__is_special_char(char c) { return !!zpl_strchr("<>:/", c); }
+    ZPL_IMPL_INLINE zpl_b32 zpl__is_assign_char(char c) { return !!zpl_strchr(":=|", c); }
+    ZPL_IMPL_INLINE zpl_b32 zpl__is_delim_char(char c) { return !!zpl_strchr(",|\n", c); }
+
+
+    ZPL_IMPL_INLINE char *zpl_str_control_skip(char *str, char c) {
+        while ((*str && *str != c) || (*(str - 1) == '\\' && *str == c && zpl_char_is_control(c))) { ++str; }
+
+        return str;
+    }
+
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_str_has_prefix(const char *str, const char *prefix) {
+        while (*prefix) {
+            if (*str++ != *prefix++) return false;
+        }
+        return true;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_str_has_suffix(const char *str, const char *suffix) {
+        zpl_isize i = zpl_strlen(str);
+        zpl_isize j = zpl_strlen(suffix);
+        if (j <= i) return zpl_strcmp(str + i - j, suffix) == 0;
+        return false;
+    }
+
+    ZPL_IMPL_INLINE const char *zpl_char_first_occurence(const char *s, char c) {
+        char ch = c;
+        for (; *s != ch; s++) {
+            if (*s == '\0') return NULL;
+        }
+        return s;
+    }
+
+    ZPL_IMPL_INLINE const char *zpl_char_last_occurence(const char *s, char c) {
+        char *result = (char*)NULL;
+        do {
+            if (*s == c) result = (char *)s;
+        } while (*s++);
+
+        return result;
+    }
+
+    ZPL_IMPL_INLINE char *zpl_str_trim(char *str, zpl_b32 skip_newline)
+    {
+        while (*str && zpl_char_is_space(*str) && (!skip_newline || (skip_newline && *str != '\n'))) { ++str; }
+        return str;
+    }
+
+    ZPL_IMPL_INLINE char *zpl_str_skip(char *str, char c) {
+        while (*str && *str != c) { ++str; }
+        return str;
+    }
+
+    ZPL_IMPL_INLINE void zpl_str_concat(char *dest, zpl_isize dest_len, const char *src_a, zpl_isize src_a_len, const char *src_b,
+                                   zpl_isize src_b_len) {
+        ZPL_ASSERT(dest_len >= src_a_len + src_b_len + 1);
+        if (dest) {
+            zpl_memcopy(dest, src_a, src_a_len);
+            zpl_memcopy(dest + src_a_len, src_b, src_b_len);
+            dest[src_a_len + src_b_len] = '\0';
+        }
+    }
+
+    ZPL_IMPL_INLINE zpl_f32 zpl_str_to_f32(const char *str, char **end_ptr) {
+        zpl_f64 f = zpl_str_to_f64(str, end_ptr);
+        zpl_f32 r = cast(zpl_f32) f;
+        return r;
+    }
+
+    ZPL_IMPL_INLINE char *zpl_strdup(zpl_allocator a, char *src, zpl_isize max_len) {
+        ZPL_ASSERT_NOT_NULL(src);
+        zpl_isize len = zpl_strlen(src);
+        char *dest = cast(char *) zpl_alloc(a, max_len);
+        zpl_memset(dest + len, 0, max_len - len);
+        zpl_strncpy(dest, src, max_len);
+
+        return dest;
+    }
+
+    ZPL_IMPL_INLINE char **zpl_str_split_lines(zpl_allocator alloc, char *source, zpl_b32 strip_whitespace) {
+        char **lines = NULL, *p = source, *pd = p;
+        zpl_array_init(lines, alloc);
+
+        while (*p) {
+            if (*pd == '\n') {
+                *pd = 0;
+                if (*(pd - 1) == '\r') *(pd - 1) = 0;
+                if (strip_whitespace && (pd - p) == 0) {
+                    p = pd + 1;
+                    continue;
+                }
+                zpl_array_append(lines, p);
+                p = pd + 1;
+            }
+            ++pd;
+        }
+        return lines;
+    }
+
+    ZPL_END_C_DECLS
+    // file: header/core/stringlib.h
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef char *zpl_string;
+
+    typedef struct zpl_string_header {
+        zpl_allocator allocator;
+        zpl_isize length;
+        zpl_isize capacity;
+    } zpl_string_header;
+
+    #define ZPL_STRING_HEADER(str) (cast(zpl_string_header *)(str) - 1)
+
+    ZPL_DEF zpl_string zpl_string_make_reserve(zpl_allocator a, zpl_isize capacity);
+    ZPL_DEF zpl_string zpl_string_make_length(zpl_allocator a, void const *str, zpl_isize num_bytes);
+    ZPL_DEF zpl_string zpl_string_sprintf(zpl_allocator a, char *buf, zpl_isize num_bytes, const char *fmt, ...);
+    ZPL_DEF zpl_string zpl_string_sprintf_buf(zpl_allocator a, const char *fmt, ...); // NOTE: Uses locally persistent buffer
+    ZPL_DEF zpl_string zpl_string_append_length(zpl_string str, void const *other, zpl_isize num_bytes);
+    ZPL_DEF zpl_string zpl_string_appendc(zpl_string str, const char *other);
+    ZPL_DEF zpl_string zpl_string_join(zpl_allocator a, const char **parts, zpl_isize count, const char *glue);
+    ZPL_DEF zpl_string zpl_string_set(zpl_string str, const char *cstr);
+    ZPL_DEF zpl_string zpl_string_make_space_for(zpl_string str, zpl_isize add_len);
+    ZPL_DEF zpl_isize  zpl_string_allocation_size(zpl_string const str);
+    ZPL_DEF zpl_b32    zpl_string_are_equal(zpl_string const lhs, zpl_string const rhs);
+    ZPL_DEF zpl_string zpl_string_trim(zpl_string str, const char *cut_set);
+    ZPL_DEF zpl_string zpl_string_append_rune(zpl_string str, zpl_rune r);
+    ZPL_DEF zpl_string zpl_string_append_fmt(zpl_string str, const char *fmt, ...);
+
+    ZPL_DEF_INLINE zpl_string zpl_string_make(zpl_allocator a, const char *str);
+    ZPL_DEF_INLINE void       zpl_string_free(zpl_string str);
+    ZPL_DEF_INLINE void       zpl_string_clear(zpl_string str);
+    ZPL_DEF_INLINE zpl_string zpl_string_duplicate(zpl_allocator a, zpl_string const str);
+    ZPL_DEF_INLINE zpl_isize  zpl_string_length(zpl_string const str);
+    ZPL_DEF_INLINE zpl_isize  zpl_string_capacity(zpl_string const str);
+    ZPL_DEF_INLINE zpl_isize  zpl_string_available_space(zpl_string const str);
+    ZPL_DEF_INLINE zpl_string zpl_string_append(zpl_string str, zpl_string const other);
+    ZPL_DEF_INLINE zpl_string zpl_string_trim_space(zpl_string str); // Whitespace ` \t\r\n\v\f`
+    ZPL_DEF_INLINE void       zpl__set_string_length(zpl_string str, zpl_isize len);
+    ZPL_DEF_INLINE void       zpl__set_string_capacity(zpl_string str, zpl_isize cap);
+
+    ZPL_IMPL_INLINE void zpl__set_string_length(zpl_string str, zpl_isize len) { ZPL_STRING_HEADER(str)->length = len; }
+    ZPL_IMPL_INLINE void zpl__set_string_capacity(zpl_string str, zpl_isize cap) { ZPL_STRING_HEADER(str)->capacity = cap; }
+    ZPL_IMPL_INLINE zpl_string zpl_string_make(zpl_allocator a, const char *str) {
+        zpl_isize len = str ? zpl_strlen(str) : 0;
+        return zpl_string_make_length(a, str, len);
+    }
+
+    ZPL_IMPL_INLINE void zpl_string_free(zpl_string str) {
+        if (str) {
+            zpl_string_header *header = ZPL_STRING_HEADER(str);
+            zpl_free(header->allocator, header);
+        }
+    }
+
+    ZPL_IMPL_INLINE zpl_string zpl_string_duplicate(zpl_allocator a, zpl_string const str) {
+        return zpl_string_make_length(a, str, zpl_string_length(str));
+    }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_string_length(zpl_string const str) { return ZPL_STRING_HEADER(str)->length; }
+    ZPL_IMPL_INLINE zpl_isize zpl_string_capacity(zpl_string const str) { return ZPL_STRING_HEADER(str)->capacity; }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_string_available_space(zpl_string const str) {
+        zpl_string_header *h = ZPL_STRING_HEADER(str);
+        if (h->capacity > h->length) return h->capacity - h->length;
+        return 0;
+    }
+
+    ZPL_IMPL_INLINE void zpl_string_clear(zpl_string str) {
+        zpl__set_string_length(str, 0);
+        str[0] = '\0';
+    }
+
+    ZPL_IMPL_INLINE zpl_string zpl_string_append(zpl_string str, zpl_string const other) {
+        return zpl_string_append_length(str, other, zpl_string_length(other));
+    }
+
+    ZPL_IMPL_INLINE zpl_string zpl_string_trim_space(zpl_string str) { return zpl_string_trim(str, " \t\r\n\v\f"); }
+
+
+    ZPL_END_C_DECLS
+    // file: header/core/file.h
+
+    /** @file file.c
+    @brief File handling
+    @defgroup fileio File handling
+
+    File I/O operations as well as path and folder structure manipulation methods. With threading enabled, it also offers async read/write methods.
+
+    @{
+    */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef zpl_u32 zpl_file_mode;
+
+    typedef enum zpl_file_mode_flag {
+        ZPL_FILE_MODE_READ   = ZPL_BIT(0),
+        ZPL_FILE_MODE_WRITE  = ZPL_BIT(1),
+        ZPL_FILE_MODE_APPEND = ZPL_BIT(2),
+        ZPL_FILE_MODE_RW     = ZPL_BIT(3),
+        ZPL_FILE_MODES       = ZPL_FILE_MODE_READ | ZPL_FILE_MODE_WRITE | ZPL_FILE_MODE_APPEND | ZPL_FILE_MODE_RW,
+    } zpl_file_mode_flag;
+
+    // NOTE: Only used internally and for the file operations
+    typedef enum zpl_seek_whence_type {
+        ZPL_SEEK_WHENCE_BEGIN   = 0,
+        ZPL_SEEK_WHENCE_CURRENT = 1,
+        ZPL_SEEK_WHENCE_END     = 2,
+    } zpl_seek_whence_type;
+
+    typedef enum zpl_file_error {
+        ZPL_FILE_ERROR_NONE,
+        ZPL_FILE_ERROR_INVALID,
+        ZPL_FILE_ERROR_INVALID_FILENAME,
+        ZPL_FILE_ERROR_EXISTS,
+        ZPL_FILE_ERROR_NOT_EXISTS,
+        ZPL_FILE_ERROR_PERMISSION,
+        ZPL_FILE_ERROR_TRUNCATION_FAILURE,
+        ZPL_FILE_ERROR_NOT_EMPTY,
+        ZPL_FILE_ERROR_NAME_TOO_LONG,
+        ZPL_FILE_ERROR_UNKNOWN,
+    } zpl_file_error;
+
+    typedef union zpl_file_descriptor {
+        void *p;
+        zpl_intptr i;
+        zpl_uintptr u;
+    } zpl_file_descriptor;
+
+    typedef struct zpl_file_operations zpl_file_operations;
+
+    #define ZPL_FILE_OPEN_PROC(name) zpl_file_error name(zpl_file_descriptor *fd, zpl_file_operations *ops, zpl_file_mode mode, char const *filename)
+    #define ZPL_FILE_READ_AT_PROC(name) zpl_b32 name(zpl_file_descriptor fd, void *buffer, zpl_isize size, zpl_i64 offset, zpl_isize *bytes_read, zpl_b32 stop_at_newline)
+    #define ZPL_FILE_WRITE_AT_PROC(name) zpl_b32 name(zpl_file_descriptor fd, void const *buffer, zpl_isize size, zpl_i64 offset, zpl_isize *bytes_written)
+    #define ZPL_FILE_SEEK_PROC(name) zpl_b32 name(zpl_file_descriptor fd, zpl_i64 offset, zpl_seek_whence_type whence, zpl_i64 *new_offset)
+    #define ZPL_FILE_CLOSE_PROC(name) void name(zpl_file_descriptor fd)
+
+    typedef ZPL_FILE_OPEN_PROC(zpl_file_open_proc);
+    typedef ZPL_FILE_READ_AT_PROC(zpl_file_read_proc);
+    typedef ZPL_FILE_WRITE_AT_PROC(zpl_file_write_proc);
+    typedef ZPL_FILE_SEEK_PROC(zpl_file_seek_proc);
+    typedef ZPL_FILE_CLOSE_PROC(zpl_file_close_proc);
+
+    struct zpl_file_operations {
+        zpl_file_read_proc  *read_at;
+        zpl_file_write_proc *write_at;
+        zpl_file_seek_proc  *seek;
+        zpl_file_close_proc *close;
+    };
+
+    extern zpl_file_operations const zpl_default_file_operations;
+
+    typedef zpl_u64 zpl_file_time;
+    typedef enum zpl_dir_type {
+        ZPL_DIR_TYPE_FILE,
+        ZPL_DIR_TYPE_FOLDER,
+        ZPL_DIR_TYPE_UNKNOWN,
+    } zpl_dir_type;
+
+    struct zpl_dir_info;
+
+    typedef struct zpl_dir_entry {
+        char const *filename;
+        struct zpl_dir_info *dir_info;
+        zpl_u8 type;
+    } zpl_dir_entry;
+
+    typedef struct zpl_dir_info {
+        char const    *fullpath;
+        zpl_dir_entry *entries; // zpl_array
+
+        // Internals
+        char **filenames; // zpl_array
+        zpl_string buf;
+    } zpl_dir_info;
+
+    typedef struct zpl_file {
+        zpl_file_operations ops;
+        zpl_file_descriptor fd;
+        zpl_b32 is_temp;
+
+        char const    *filename;
+        zpl_file_time last_write_time;
+        zpl_dir_entry *dir;
+    } zpl_file;
+
+    typedef enum zpl_file_standard_type {
+        ZPL_FILE_STANDARD_INPUT,
+        ZPL_FILE_STANDARD_OUTPUT,
+        ZPL_FILE_STANDARD_ERROR,
+
+        ZPL_FILE_STANDARD_COUNT,
+    } zpl_file_standard_type;
+
+    /**
+     * Get standard file I/O.
+     * @param  std Check zpl_file_standard_type
+     * @return     File handle to standard I/O
+     */
+    ZPL_DEF zpl_file      *zpl_file_get_standard(zpl_file_standard_type std);
+
+    /**
+     * Connects a system handle to a ZPL file.
+     * @param  file   Pointer to ZPL file
+     * @param  handle Low-level OS handle to connect
+     */
+    ZPL_DEF void           zpl_file_connect_handle(zpl_file *file, void *handle);
+
+    /**
+     * Creates a new file
+     * @param  file
+     * @param  filename
+     */
+    ZPL_DEF zpl_file_error zpl_file_create(zpl_file *file, char const *filename);
+
+    /**
+     * Opens a file
+     * @param  file
+     * @param  filename
+     */
+    ZPL_DEF zpl_file_error zpl_file_open(zpl_file *file, char const *filename);
+
+    /**
+     * Opens a file using a specified mode
+     * @param  file
+     * @param  mode     Access mode to use
+     * @param  filename
+     */
+    ZPL_DEF zpl_file_error zpl_file_open_mode(zpl_file *file, zpl_file_mode mode, char const *filename);
+
+    /**
+     * Constructs a new file from data
+     * @param  file
+     * @param  fd       Low-level file descriptor to use
+     * @param  ops      File operations to rely upon
+     * @param  filename
+     */
+    ZPL_DEF zpl_file_error zpl_file_new(zpl_file *file, zpl_file_descriptor fd, zpl_file_operations ops, char const *filename);
+
+    /**
+     * Returns a size of the file
+     * @param  file
+     * @return      File size
+     */
+    ZPL_DEF zpl_i64        zpl_file_size(zpl_file *file);
+
+    /**
+     * Returns the currently opened file's name
+     * @param  file
+     */
+    ZPL_DEF char const    *zpl_file_name(zpl_file *file);
+
+    /**
+     * Truncates the file by a specified size
+     * @param  file
+     * @param  size Size to truncate
+     */
+    ZPL_DEF zpl_file_error zpl_file_truncate(zpl_file *file, zpl_i64 size);
+
+    /**
+     * Checks whether a file's been changed since the last check
+     * @param  file
+     */
+    ZPL_DEF zpl_b32 zpl_file_has_changed(zpl_file *file);
+
+    /**
+     * Retrieves a directory listing relative to the file
+     * @param file
+     */
+    ZPL_DEF void zpl_file_dirinfo_refresh(zpl_file *file);
+
+    /**
+     * Creates a temporary file
+     * @param  file
+     */
+    zpl_file_error zpl_file_temp(zpl_file *file);
+
+    /**
+     * Closes the file
+     * @param  file
+     */
+    ZPL_DEF zpl_file_error zpl_file_close(zpl_file *file);
+
+    /**
+     * Reads file safely
+     * @param  file
+     * @param  buffer     Buffer to read to
+     * @param  size       Size to read
+     * @param  offset     Offset to read from
+     * @param  bytes_read How much data we've actually read
+     */
+    ZPL_DEF_INLINE zpl_b32 zpl_file_read_at_check(zpl_file *file, void *buffer, zpl_isize size, zpl_i64 offset, zpl_isize *bytes_read);
+
+    /**
+     * Writes to file safely
+     * @param  file
+     * @param  buffer        Buffer to read from
+     * @param  size          Size to write
+     * @param  offset        Offset to write to
+     * @param  bytes_written How much data we've actually written
+     */
+    ZPL_DEF_INLINE zpl_b32 zpl_file_write_at_check(zpl_file *file, void const *buffer, zpl_isize size, zpl_i64 offset, zpl_isize *bytes_written);
+
+
+    /**
+     * Reads file at a specific offset
+     * @param  file
+     * @param  buffer     Buffer to read to
+     * @param  size       Size to read
+     * @param  offset     Offset to read from
+     * @param  bytes_read How much data we've actually read
+     */
+    ZPL_DEF_INLINE zpl_b32 zpl_file_read_at(zpl_file *file, void *buffer, zpl_isize size, zpl_i64 offset);
+
+    /**
+     * Writes to file at a specific offset
+     * @param  file
+     * @param  buffer        Buffer to read from
+     * @param  size          Size to write
+     * @param  offset        Offset to write to
+     * @param  bytes_written How much data we've actually written
+     */
+    ZPL_DEF_INLINE zpl_b32 zpl_file_write_at(zpl_file *file, void const *buffer, zpl_isize size, zpl_i64 offset);
+
+    /**
+     * Seeks the file cursor from the beginning of file to a specific position
+     * @param  file
+     * @param  offset Offset to seek to
+     */
+    ZPL_DEF_INLINE zpl_i64 zpl_file_seek(zpl_file *file, zpl_i64 offset);
+
+    /**
+     * Seeks the file cursor to the end of the file
+     * @param  file
+     */
+    ZPL_DEF_INLINE zpl_i64 zpl_file_seek_to_end(zpl_file *file);
+
+    /**
+     * Skips N bytes at the current position
+     * @param  file
+     * @param  bytes Bytes to skip
+     */
+    ZPL_DEF_INLINE zpl_i64 zpl_file_skip(zpl_file *file, zpl_i64 bytes); // NOTE: Skips a certain amount of bytes
+
+    /**
+     * Returns the length from the beginning of the file we've read so far
+     * @param  file
+     * @return      Our current position in file
+     */
+    ZPL_DEF_INLINE zpl_i64 zpl_file_tell(zpl_file *file);
+
+    /**
+     * Reads from a file
+     * @param  file
+     * @param  buffer Buffer to read to
+     * @param  size   Size to read
+     */
+    ZPL_DEF_INLINE zpl_b32 zpl_file_read(zpl_file *file, void *buffer, zpl_isize size);
+
+    /**
+     * Writes to a file
+     * @param  file
+     * @param  buffer Buffer to read from
+     * @param  size   Size to read
+     */
+    ZPL_DEF_INLINE zpl_b32 zpl_file_write(zpl_file *file, void const *buffer, zpl_isize size);
+
+
+    typedef struct zpl_file_contents {
+        zpl_allocator allocator;
+        void *data;
+        zpl_isize size;
+    } zpl_file_contents;
+
+    /**
+     * Reads the whole file contents
+     * @param  a              Allocator to use
+     * @param  zero_terminate End the read data with null terminator
+     * @param  filepath       Path to the file
+     * @return                File contents data
+     */
+    ZPL_DEF zpl_file_contents zpl_file_read_contents(zpl_allocator a, zpl_b32 zero_terminate, char const *filepath);
+
+    /**
+     * Frees the file content data previously read
+     * @param  fc
+     */
+    ZPL_DEF void              zpl_file_free_contents(zpl_file_contents *fc);
+
+    /**
+     * Writes content to a file
+     */
+    ZPL_DEF zpl_b32           zpl_file_write_contents(char const* filepath, void const* buffer, zpl_isize size, zpl_file_error* err);
+
+    /**
+     * Reads the file as array of lines
+     *
+     * Make sure you free both the returned buffer and the lines (zpl_array)
+     * @param  alloc            Allocator to use
+     * @param  lines            Reference to zpl_array container we store lines to
+     * @param  filename         Path to the file
+     * @param  strip_whitespace Strip whitespace when we split to lines?
+     * @return                  File content we've read itself
+     */
+    ZPL_DEF char *zpl_file_read_lines(zpl_allocator alloc, zpl_array(char *)*lines, char const *filename, zpl_b32 strip_whitespace);
+
+    //! @}
+
+    /* inlines */
+
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_file_read_at_check(zpl_file *f, void *buffer, zpl_isize size, zpl_i64 offset, zpl_isize *bytes_read) {
+        if (!f->ops.read_at) f->ops = zpl_default_file_operations;
+        return f->ops.read_at(f->fd, buffer, size, offset, bytes_read, false);
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_file_write_at_check(zpl_file *f, void const *buffer, zpl_isize size, zpl_i64 offset, zpl_isize *bytes_written) {
+        if (!f->ops.read_at) f->ops = zpl_default_file_operations;
+        return f->ops.write_at(f->fd, buffer, size, offset, bytes_written);
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_file_read_at(zpl_file *f, void *buffer, zpl_isize size, zpl_i64 offset) {
+        return zpl_file_read_at_check(f, buffer, size, offset, NULL);
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_file_write_at(zpl_file *f, void const *buffer, zpl_isize size, zpl_i64 offset) {
+        return zpl_file_write_at_check(f, buffer, size, offset, NULL);
+    }
+
+    ZPL_IMPL_INLINE zpl_i64 zpl_file_seek(zpl_file *f, zpl_i64 offset) {
+        zpl_i64 new_offset = 0;
+        if (!f->ops.read_at) f->ops = zpl_default_file_operations;
+        f->ops.seek(f->fd, offset, ZPL_SEEK_WHENCE_BEGIN, &new_offset);
+        return new_offset;
+    }
+
+    ZPL_IMPL_INLINE zpl_i64 zpl_file_seek_to_end(zpl_file *f) {
+        zpl_i64 new_offset = 0;
+        if (!f->ops.read_at) f->ops = zpl_default_file_operations;
+        f->ops.seek(f->fd, 0, ZPL_SEEK_WHENCE_END, &new_offset);
+        return new_offset;
+    }
+
+    // NOTE: Skips a certain amount of bytes
+    ZPL_IMPL_INLINE zpl_i64 zpl_file_skip(zpl_file *f, zpl_i64 bytes) {
+        zpl_i64 new_offset = 0;
+        if (!f->ops.read_at) f->ops = zpl_default_file_operations;
+        f->ops.seek(f->fd, bytes, ZPL_SEEK_WHENCE_CURRENT, &new_offset);
+        return new_offset;
+    }
+
+    ZPL_IMPL_INLINE zpl_i64 zpl_file_tell(zpl_file *f) {
+        zpl_i64 new_offset = 0;
+        if (!f->ops.read_at) f->ops = zpl_default_file_operations;
+        f->ops.seek(f->fd, 0, ZPL_SEEK_WHENCE_CURRENT, &new_offset);
+        return new_offset;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_file_read(zpl_file *f, void *buffer, zpl_isize size) {
+        zpl_i64 cur_offset = zpl_file_tell(f);
+        zpl_b32 result = zpl_file_read_at(f, buffer, size, zpl_file_tell(f));
+        zpl_file_seek(f, cur_offset + size);
+        return result;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_file_write(zpl_file *f, void const *buffer, zpl_isize size) {
+        zpl_i64 cur_offset = zpl_file_tell(f);
+        zpl_b32 result = zpl_file_write_at(f, buffer, size, zpl_file_tell(f));
+        zpl_file_seek(f, cur_offset + size);
+        return result;
+    }
+
+    ZPL_END_C_DECLS
+    // file: header/core/file_stream.h
+
+    /** @file file_stream.c
+    @brief File stream
+    @defgroup fileio File stream
+
+    File streaming operations on memory.
+
+    @{
+    */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef enum {
+        /* Allows us to write to the buffer directly. Beware: you can not append a new data! */
+        ZPL_FILE_STREAM_WRITABLE = ZPL_BIT(0),
+
+        /* Clones the input buffer so you can write (zpl_file_write*) data into it. */
+        /* Since we work with a clone, the buffer size can dynamically grow as well. */
+        ZPL_FILE_STREAM_CLONE_WRITABLE = ZPL_BIT(1),
+    } zpl_file_stream_flags;
+
+    /**
+     * Opens a new memory stream
+     * @param file
+     * @param allocator
+     */
+    ZPL_DEF void zpl_file_stream_new(zpl_file* file, zpl_allocator allocator);
+
+    /**
+     * Opens a memory stream over an existing buffer
+     * @param  file
+     * @param  allocator
+     * @param  buffer   Memory to create stream from
+     * @param  size     Buffer's size
+     * @param  flags
+     */
+    ZPL_DEF void zpl_file_stream_open(zpl_file* file, zpl_allocator allocator, zpl_u8 *buffer, zpl_isize size, zpl_file_stream_flags flags);
+
+    /**
+     * Retrieves the stream's underlying buffer and buffer size.
+     * @param file memory stream
+     * @param size (Optional) buffer size
+     */
+    ZPL_DEF zpl_u8 *zpl_file_stream_buf(zpl_file* file, zpl_isize *size);
+
+    extern zpl_file_operations const zpl_memory_file_operations;
+
+    //! @}
+
+    ZPL_END_C_DECLS
+    // file: header/core/file_misc.h
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #ifndef ZPL_PATH_SEPARATOR
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            #define ZPL_PATH_SEPARATOR '\\'
+        #else
+            #define ZPL_PATH_SEPARATOR '/'
+        #endif
+    #endif
+
+    /**
+     * Checks if file/directory exists
+     * @param  filepath
+     */
+    ZPL_DEF zpl_b32       zpl_fs_exists(char const *filepath);
+
+    /**
+     * Retrieves node's type (file, folder, ...)
+     * @param  path
+     */
+    ZPL_DEF zpl_u8        zpl_fs_get_type(char const *path);
+
+    /**
+     * Retrieves file's last write time
+     * @param  filepath
+     */
+    ZPL_DEF zpl_file_time zpl_fs_last_write_time(char const *filepath);
+
+    /**
+     * Copies the file to a directory
+     * @param  existing_filename
+     * @param  new_filename
+     * @param  fail_if_exists
+     */
+    ZPL_DEF zpl_b32       zpl_fs_copy(char const *existing_filename, char const *new_filename, zpl_b32 fail_if_exists);
+
+    /**
+     * Moves the file to a directory
+     * @param  existing_filename
+     * @param  new_filename
+     */
+    ZPL_DEF zpl_b32       zpl_fs_move(char const *existing_filename, char const *new_filename);
+
+    /**
+     * Removes a file from a directory
+     * @param  filename
+     */
+    ZPL_DEF zpl_b32       zpl_fs_remove(char const *filename);
+
+    ZPL_DEF_INLINE zpl_b32 zpl_path_is_absolute(char const *path);
+    ZPL_DEF_INLINE zpl_b32 zpl_path_is_relative(char const *path);
+    ZPL_DEF_INLINE zpl_b32 zpl_path_is_root(char const *path);
+
+    ZPL_DEF_INLINE char const *zpl_path_base_name(char const *path);
+    ZPL_DEF_INLINE char const *zpl_path_extension(char const *path);
+
+    ZPL_DEF void    zpl_path_fix_slashes(char *path);
+
+    ZPL_DEF zpl_file_error zpl_path_mkdir(char const *path, zpl_i32 mode);
+    ZPL_DEF zpl_file_error zpl_path_rmdir(char const *path);
+
+    ZPL_DEF char       *zpl_path_get_full_name(zpl_allocator a, char const *path);
+
+    /**
+     * Returns file paths terminated by newline (\n)
+     * @param  alloc   [description]
+     * @param  dirname [description]
+     * @param  recurse [description]
+     * @return         [description]
+     */
+    ZPL_DEF /*zpl_string*/char * zpl_path_dirlist(zpl_allocator alloc, char const *dirname, zpl_b32 recurse);
+
+    /**
+     * Initialize dirinfo from specified path
+     * @param dir  [description]
+     * @param path [description]
+     */
+    ZPL_DEF void zpl_dirinfo_init(zpl_dir_info *dir, char const *path);
+    ZPL_DEF void zpl_dirinfo_free(zpl_dir_info *dir);
+
+    /**
+     * Analyze the entry's dirinfo
+     * @param dir_entry [description]
+     */
+    ZPL_DEF void zpl_dirinfo_step(zpl_dir_entry *dir_entry);
+
+
+    /* inlines */
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_path_is_absolute(char const *path) {
+        zpl_b32 result = false;
+        ZPL_ASSERT_NOT_NULL(path);
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        result = (zpl_strlen(path) > 2) && zpl_char_is_alpha(path[0]) && (path[1] == ':' && path[2] == ZPL_PATH_SEPARATOR);
+    #else
+        result = (zpl_strlen(path) > 0 && path[0] == ZPL_PATH_SEPARATOR);
+    #endif
+        return result;
+    }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_path_is_relative(char const *path) { return !zpl_path_is_absolute(path); }
+
+    ZPL_IMPL_INLINE zpl_b32 zpl_path_is_root(char const *path) {
+        zpl_b32 result = false;
+        ZPL_ASSERT_NOT_NULL(path);
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        result = zpl_path_is_absolute(path) && (zpl_strlen(path) == 3);
+    #else
+        result = zpl_path_is_absolute(path) && (zpl_strlen(path) == 1);
+    #endif
+        return result;
+    }
+
+    ZPL_IMPL_INLINE char const *zpl_path_base_name(char const *path) {
+        char const *ls;
+        ZPL_ASSERT_NOT_NULL(path);
+        zpl_path_fix_slashes((char *)path);
+        ls = zpl_char_last_occurence(path, ZPL_PATH_SEPARATOR);
+        return (ls == NULL) ? path : ls + 1;
+    }
+
+    ZPL_IMPL_INLINE char const *zpl_path_extension(char const *path) {
+        char const *ld;
+        ZPL_ASSERT_NOT_NULL(path);
+        ld = zpl_char_last_occurence(path, '.');
+        return (ld == NULL) ? NULL : ld + 1;
+    }
+
+    ZPL_END_C_DECLS
+    // file: header/core/print.h
+
+    /** @file print.c
+    @brief Printing methods
+    @defgroup print Printing methods
+
+    Various printing methods.
+    @{
+    */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    ZPL_DEF zpl_isize zpl_printf(char const *fmt, ...);
+    ZPL_DEF zpl_isize zpl_printf_va(char const *fmt, va_list va);
+    ZPL_DEF zpl_isize zpl_printf_err(char const *fmt, ...);
+    ZPL_DEF zpl_isize zpl_printf_err_va(char const *fmt, va_list va);
+    ZPL_DEF zpl_isize zpl_fprintf(zpl_file *f, char const *fmt, ...);
+    ZPL_DEF zpl_isize zpl_fprintf_va(zpl_file *f, char const *fmt, va_list va);
+
+    // NOTE: A locally persisting buffer is used internally
+    ZPL_DEF char *zpl_bprintf(char const *fmt, ...);
+
+    // NOTE: A locally persisting buffer is used internally
+    ZPL_DEF char *zpl_bprintf_va(char const *fmt, va_list va);
+
+    ZPL_DEF zpl_isize zpl_snprintf(char *str, zpl_isize n, char const *fmt, ...);
+    ZPL_DEF zpl_isize zpl_snprintf_va(char *str, zpl_isize n, char const *fmt, va_list va);
+
+    ZPL_END_C_DECLS
+    // file: header/core/time.h
+
+    /** @file time.c
+    @brief Time helper methods.
+    @defgroup time Time helpers
+
+     Helper methods for retrieving the current time in many forms under different precisions. It also offers a simple to use timer library.
+
+     @{
+     */
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    //! Return CPU timestamp.
+    ZPL_DEF zpl_u64 zpl_rdtsc(void);
+
+    //! Return relative time (in seconds) since the application start.
+    ZPL_DEF zpl_f64 zpl_time_rel(void);
+
+    //! Return relative time since the application start.
+    ZPL_DEF zpl_u64 zpl_time_rel_ms(void);
+
+    //! Return time (in seconds) since 1601-01-01 UTC.
+    ZPL_DEF zpl_f64 zpl_time_utc(void);
+
+    //! Return time since 1601-01-01 UTC.
+    ZPL_DEF zpl_u64 zpl_time_utc_ms(void);
+
+    //! Return local system time since 1601-01-01
+    ZPL_DEF zpl_u64 zpl_time_tz_ms(void);
+
+    //! Return local system time in seconds since 1601-01-01
+    ZPL_DEF zpl_f64 zpl_time_tz(void);
+
+    //! Convert Win32 epoch (1601-01-01 UTC) to UNIX (1970-01-01 UTC)
+    ZPL_DEF_INLINE zpl_u64 zpl_time_win32_to_unix(zpl_u64 ms);
+
+    //! Convert UNIX (1970-01-01 UTC) to Win32 epoch (1601-01-01 UTC)
+    ZPL_DEF_INLINE zpl_u64 zpl_time_unix_to_win32(zpl_u64 ms);
+
+    //! Sleep for specified number of milliseconds.
+    ZPL_DEF void zpl_sleep_ms(zpl_u32 ms);
+
+    //! Sleep for specified number of seconds.
+    ZPL_DEF_INLINE void zpl_sleep(zpl_f32 s);
+
+    // Deprecated methods
+    ZPL_DEPRECATED_FOR(10.9.0, zpl_time_rel)
+    ZPL_DEF_INLINE zpl_f64 zpl_time_now(void);
+
+    ZPL_DEPRECATED_FOR(10.9.0, zpl_time_utc)
+    ZPL_DEF_INLINE zpl_f64 zpl_utc_time_now(void);
+
+
+    #ifndef ZPL__UNIX_TO_WIN32_EPOCH
+    #define ZPL__UNIX_TO_WIN32_EPOCH 11644473600000ull
+    #endif
+
+    ZPL_IMPL_INLINE zpl_u64 zpl_time_win32_to_unix(zpl_u64 ms) {
+        return ms - ZPL__UNIX_TO_WIN32_EPOCH;
+    }
+
+    ZPL_IMPL_INLINE zpl_u64 zpl_time_unix_to_win32(zpl_u64 ms) {
+        return ms + ZPL__UNIX_TO_WIN32_EPOCH;
+    }
+
+    ZPL_IMPL_INLINE void zpl_sleep(zpl_f32 s) {
+        zpl_sleep_ms((zpl_u32)(s * 1000));
+    }
+
+    ZPL_IMPL_INLINE zpl_f64 zpl_time_now() {
+        return zpl_time_rel();
+    }
+
+    ZPL_IMPL_INLINE zpl_f64 zpl_utc_time_now() {
+        return zpl_time_utc();
+    }
+
+    ZPL_END_C_DECLS
+    // file: header/core/random.h
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef struct zpl_random {
+        zpl_u32 offsets[8];
+        zpl_u32 value;
+    } zpl_random;
+
+    // NOTE: Generates from numerous sources to produce a decent pseudo-random seed
+    ZPL_DEF void      zpl_random_init(zpl_random *r);
+    ZPL_DEF zpl_u32   zpl_random_gen_u32(zpl_random *r);
+    ZPL_DEF zpl_u32   zpl_random_gen_u32_unique(zpl_random *r);
+    ZPL_DEF zpl_u64   zpl_random_gen_u64(zpl_random *r); // NOTE: (zpl_random_gen_u32() << 32) | zpl_random_gen_u32()
+    ZPL_DEF zpl_isize zpl_random_gen_isize(zpl_random *r);
+    ZPL_DEF zpl_i64   zpl_random_range_i64(zpl_random *r, zpl_i64 lower_inc, zpl_i64 higher_inc);
+    ZPL_DEF zpl_isize zpl_random_range_isize(zpl_random *r, zpl_isize lower_inc, zpl_isize higher_inc);
+    ZPL_DEF zpl_f64   zpl_random_range_f64(zpl_random *r, zpl_f64 lower_inc, zpl_f64 higher_inc);
+
+    ZPL_END_C_DECLS
+    // file: header/core/misc.h
+
+    /** @file misc.c
+    @brief Various other stuff
+    @defgroup misc Various other stuff
+
+     Methods that don't belong anywhere but are still very useful in many occasions.
+
+     @{
+     */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    ZPL_DEF void zpl_exit(zpl_u32 code);
+    ZPL_DEF void zpl_yield(void);
+
+    //! Returns allocated buffer
+    ZPL_DEF const char *zpl_get_env(const char *name);
+    ZPL_DEF const char *zpl_get_env_buf(const char *name);
+    ZPL_DEF zpl_string  zpl_get_env_str(const char *name);
+    ZPL_DEF void        zpl_set_env(const char *name, const char *value);
+    ZPL_DEF void        zpl_unset_env(const char *name);
+
+    ZPL_DEF zpl_u32    zpl_system_command(const char *command, zpl_usize buffer_len, char *buffer);
+    ZPL_DEF zpl_string zpl_system_command_str(const char *command, zpl_allocator backing);
+
+    ZPL_DEF_INLINE zpl_u16 zpl_endian_swap16(zpl_u16 i);
+    ZPL_DEF_INLINE zpl_u32 zpl_endian_swap32(zpl_u32 i);
+    ZPL_DEF_INLINE zpl_u64 zpl_endian_swap64(zpl_u64 i);
+
+    ZPL_DEF_INLINE zpl_isize zpl_count_set_bits(zpl_u64 mask);
+
+    //! @}
+    //$$
+
+    ZPL_IMPL_INLINE zpl_u16 zpl_endian_swap16(zpl_u16 i) {
+        return (i>>8) | (i<<8);
+    }
+
+    ZPL_IMPL_INLINE zpl_u32 zpl_endian_swap32(zpl_u32 i) {
+        return (i>>24) |(i<<24) |
+            ((i&0x00ff0000u)>>8)  | ((i&0x0000ff00u)<<8);
+    }
+
+    ZPL_IMPL_INLINE zpl_u64 zpl_endian_swap64(zpl_u64 i) {
+        return (i>>56) | (i<<56) |
+            ((i&0x00ff000000000000ull)>>40) | ((i&0x000000000000ff00ull)<<40) |
+            ((i&0x0000ff0000000000ull)>>24) | ((i&0x0000000000ff0000ull)<<24) |
+            ((i&0x000000ff00000000ull)>>8)  | ((i&0x00000000ff000000ull)<<8);
+    }
+
+    ZPL_IMPL_INLINE zpl_i32 zpl_next_pow2(zpl_i32 x) {
+        x--;
+        x |= x >> 1;
+        x |= x >> 2;
+        x |= x >> 4;
+        x |= x >> 8;
+        x |= x >> 16;
+        return x + 1;
+    }
+
+    ZPL_IMPL_INLINE void zpl_bit_set(zpl_u32* x, zpl_u32 bit) { *x = *x | (1 << bit); }
+    ZPL_IMPL_INLINE zpl_b8 zpl_bit_get(zpl_u32 x, zpl_u32 bit) { return (x & (1 << bit)); }
+    ZPL_IMPL_INLINE void zpl_bit_reset(zpl_u32* x, zpl_u32 bit) { *x = *x & ~(1 << bit); }
+
+    ZPL_IMPL_INLINE zpl_isize zpl_count_set_bits(zpl_u64 mask) {
+        zpl_isize count = 0;
+        while (mask) {
+            count += (mask & 1);
+            mask >>= 1;
+        }
+        return count;
+    }
+
+    ZPL_END_C_DECLS
+    // file: header/core/sort.h
+
+    /** @file sort.c
+    @brief Sorting and searching methods.
+    @defgroup sort Sorting and searching
+
+    Methods for sorting arrays using either Quick/Merge-sort combo or Radix sort. It also contains simple implementation of binary search, as well as an easy to use API to define your own comparators.
+
+    @{
+    */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #define ZPL_COMPARE_PROC(name) int name(void const *a, void const *b)
+    typedef ZPL_COMPARE_PROC(zpl_compare_proc);
+
+    #define ZPL_COMPARE_PROC_PTR(def) ZPL_COMPARE_PROC((*def))
+
+    // Procedure pointers
+    // NOTE: The offset parameter specifies the offset in the structure
+    // e.g. zpl_i32_cmp(zpl_offset_of(Thing, value))
+    // Use 0 if it's just the type instead.
+
+    ZPL_DEF ZPL_COMPARE_PROC_PTR(i16_cmp(zpl_isize offset));
+    ZPL_DEF ZPL_COMPARE_PROC_PTR(u8_cmp(zpl_isize offset));
+    ZPL_DEF ZPL_COMPARE_PROC_PTR(i32_cmp(zpl_isize offset));
+    ZPL_DEF ZPL_COMPARE_PROC_PTR(i64_cmp(zpl_isize offset));
+    ZPL_DEF ZPL_COMPARE_PROC_PTR(isize_cmp(zpl_isize offset));
+    ZPL_DEF ZPL_COMPARE_PROC_PTR(str_cmp(zpl_isize offset));
+    ZPL_DEF ZPL_COMPARE_PROC_PTR(f32_cmp(zpl_isize offset));
+    ZPL_DEF ZPL_COMPARE_PROC_PTR(f64_cmp(zpl_isize offset));
+
+    // TODO: Better sorting algorithms
+
+    //! Sorts an array.
+
+    //! Uses quick sort for large arrays but insertion sort for small ones.
+    #define zpl_sort_array(array, count, compare_proc) zpl_sort(array, count, zpl_size_of(*(array)), compare_proc)
+
+    //! Perform sorting operation on a memory location with a specified item count and size.
+    ZPL_DEF void zpl_sort(void *base, zpl_isize count, zpl_isize size, zpl_compare_proc compare_proc);
+
+    // NOTE: the count of temp == count of items
+    #define zpl_radix_sort(Type) zpl_radix_sort_##Type
+    #define ZPL_RADIX_SORT_PROC(Type) void zpl_radix_sort(Type)(zpl_##Type * items, zpl_##Type * temp, zpl_isize count)
+
+    ZPL_DEF ZPL_RADIX_SORT_PROC(u8);
+    ZPL_DEF ZPL_RADIX_SORT_PROC(u16);
+    ZPL_DEF ZPL_RADIX_SORT_PROC(u32);
+    ZPL_DEF ZPL_RADIX_SORT_PROC(u64);
+
+    //! Performs binary search on an array.
+
+    //! Returns index or -1 if not found
+    #define zpl_binary_search_array(array, count, key, compare_proc)                                                       \
+    zpl_binary_search(array, count, zpl_size_of(*(array)), key, compare_proc)
+
+    //! Performs binary search on a memory location with specified item count and size.
+    ZPL_DEF_INLINE zpl_isize zpl_binary_search(void const *base, zpl_isize count, zpl_isize size, void const *key,
+                                    zpl_compare_proc compare_proc);
+
+    #define zpl_shuffle_array(array, count) zpl_shuffle(array, count, zpl_size_of(*(array)))
+
+    //! Shuffles a memory.
+    ZPL_DEF void zpl_shuffle(void *base, zpl_isize count, zpl_isize size);
+
+    #define zpl_reverse_array(array, count) zpl_reverse(array, count, zpl_size_of(*(array)))
+
+    //! Reverses memory's contents
+    ZPL_DEF void zpl_reverse(void *base, zpl_isize count, zpl_isize size);
+
+    //! @}
+
+
+    ZPL_IMPL_INLINE zpl_isize zpl_binary_search(void const *base, zpl_isize count, zpl_isize size, void const *key,
+                                       zpl_compare_proc compare_proc) {
+        zpl_isize start = 0;
+        zpl_isize end = count;
+
+        while (start < end) {
+            zpl_isize mid = start + (end - start) / 2;
+            zpl_isize result = compare_proc(key, cast(zpl_u8 *) base + mid * size);
+            if (result < 0)
+                end = mid;
+            else if (result > 0)
+                start = mid + 1;
+            else
+                return mid;
+        }
+
+        return -1;
+    }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_TIMER)
+    // file: header/timer.h
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef void (*zpl_timer_cb)(void *data);
+
+    //! Timer data structure
+    typedef struct zpl_timer {
+        zpl_timer_cb callback;
+        zpl_b32 enabled;
+        zpl_i32 remaining_calls;
+        zpl_i32 initial_calls;
+        zpl_f64 next_call_ts;
+        zpl_f64 duration;
+        void *user_data;
+    } zpl_timer;
+
+    typedef zpl_timer *zpl_timer_pool; ///< zpl_array
+
+    //! Initialize timer pool.
+    #define zpl_timer_init(pool, allocator) zpl_array_init(pool, allocator)
+
+    //! Add new timer to pool and return it.
+    ZPL_DEF zpl_timer *zpl_timer_add(zpl_timer_pool pool);
+
+    //! Perform timer pool update.
+
+    //! Traverse over all timers and update them accordingly. Should be called by Main Thread in a tight loop.
+    ZPL_DEF void zpl_timer_update(zpl_timer_pool pool);
+
+    //! Set up timer.
+
+    //! Set up timer with specific options.
+    //! @param timer
+    //! @param duration How long/often to fire a timer.
+    //! @param count How many times we fire a timer. Use -1 for infinity.
+    //! @param callback A method to execute once a timer triggers.
+    ZPL_DEF void zpl_timer_set(zpl_timer *timer, zpl_f64 /* microseconds */ duration, zpl_i32 /* -1 for INFINITY */ count,
+                               zpl_timer_cb callback);
+
+    //! Start timer with specified delay.
+    ZPL_DEF void zpl_timer_start(zpl_timer *timer, zpl_f64 delay_start);
+
+    //! Stop timer and prevent it from triggering.
+    ZPL_DEF void zpl_timer_stop(zpl_timer *timer);
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_HASHING)
+    // file: header/hashing.h
+
+    /** @file hashing.c
+    @brief Hashing and Checksum Functions
+    @defgroup hashing Hashing and Checksum Functions
+
+    Several hashing methods used by ZPL internally but possibly useful outside of it. Contains: adler32, crc32/64, fnv32/64/a and murmur32/64
+
+    @{
+    */
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    ZPL_DEF zpl_u32 zpl_adler32(void const *data, zpl_isize len);
+
+    ZPL_DEF zpl_u32 zpl_crc32(void const *data, zpl_isize len);
+
+    // These use FNV-1 algorithm
+    ZPL_DEF zpl_u32 zpl_fnv32(void const *data, zpl_isize len);
+    ZPL_DEF zpl_u64 zpl_fnv64(void const *data, zpl_isize len);
+    ZPL_DEF zpl_u32 zpl_fnv32a(void const *data, zpl_isize len);
+    ZPL_DEF zpl_u64 zpl_fnv64a(void const *data, zpl_isize len);
+
+    ZPL_DEF zpl_u8 *zpl_base64_encode(zpl_allocator a, void const *data, zpl_isize len);
+    ZPL_DEF zpl_u8 *zpl_base64_decode(zpl_allocator a, void const *data, zpl_isize len);
+
+    //! Based on MurmurHash3
+    ZPL_DEF zpl_u32 zpl_murmur32_seed(void const *data, zpl_isize len, zpl_u32 seed);
+
+    //! Based on MurmurHash2
+    ZPL_DEF zpl_u64 zpl_murmur64_seed(void const *data, zpl_isize len, zpl_u64 seed);
+
+    //! Default seed of 0x9747b28c
+    ZPL_DEF_INLINE zpl_u32 zpl_murmur32(void const *data, zpl_isize len);
+
+    //! Default seed of 0x9747b28c
+    ZPL_DEF_INLINE zpl_u64 zpl_murmur64(void const *data, zpl_isize len);
+
+    //! @}
+
+    ZPL_IMPL_INLINE zpl_u32 zpl_murmur32(void const *data, zpl_isize len) { return zpl_murmur32_seed(data, len, 0x9747b28c); }
+    ZPL_IMPL_INLINE zpl_u64 zpl_murmur64(void const *data, zpl_isize len) { return zpl_murmur64_seed(data, len, 0x9747b28c); }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_REGEX)
+    // file: header/regex.h
+
+    /** @file regex.c
+    @brief Regular expressions parser.
+    @defgroup regex Regex processor
+
+    Port of gb_regex with several bugfixes applied. This is a simple regex library and is fast to perform.
+
+    Supported Matching:
+        @n ^       - Beginning of string
+        @n $       - End of string
+        @n .       - Match one (anything)
+        @n |       - Branch (or)
+        @n ()      - Capturing group
+        @n []      - Any character included in set
+        @n [^]     - Any character excluded from set
+        @n +       - One or more  (greedy)
+        @n +?      - One or more  (non-greedy)
+        @n *       - Zero or more (greedy)
+        @n *?      - Zero or more (non-greedy)
+        @n ?       - Zero or once
+        @n [BACKSLASH]XX     - Hex decimal digit (must be 2 digits)
+        @n [BACKSLASH]meta   - Meta character
+        @n [BACKSLASH]s      - Whitespace
+        @n [BACKSLASH]S      - Not whitespace
+        @n [BACKSLASH]d      - Digit
+        @n [BACKSLASH]D      - Not digit
+        @n [BACKSLASH]a      - Alphabetic character
+        @n [BACKSLASH]l      - Lower case letter
+        @n [BACKSLASH]u      - Upper case letter
+        @n [BACKSLASH]w      - Word
+        @n [BACKSLASH]W      - Not word
+        @n [BACKSLASH]x      - Hex Digit
+        @n [BACKSLASH]p      - Printable ASCII character
+        @n --Whitespace--
+        @n [BACKSLASH]t      - Tab
+        @n [BACKSLASH]n      - New line
+        @n [BACKSLASH]r      - Return carriage
+        @n [BACKSLASH]v      - Vertical Tab
+        @n [BACKSLASH]f      - Form feed
+
+        @{
+    */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef struct zpl_re {
+        zpl_allocator backing;
+        zpl_isize capture_count;
+        char *buf;
+        zpl_isize buf_len, buf_cap;
+        zpl_b32 can_realloc;
+    } zpl_re;
+
+    typedef struct zpl_re_capture {
+        char const *str;
+        zpl_isize len;
+    } zpl_re_capture;
+
+    #define zplRegexError zpl_regex_error
+    typedef enum zpl_regex_error {
+        ZPL_RE_ERROR_NONE,
+        ZPL_RE_ERROR_NO_MATCH,
+        ZPL_RE_ERROR_TOO_LONG,
+        ZPL_RE_ERROR_MISMATCHED_CAPTURES,
+        ZPL_RE_ERROR_MISMATCHED_BLOCKS,
+        ZPL_RE_ERROR_BRANCH_FAILURE,
+        ZPL_RE_ERROR_INVALID_QUANTIFIER,
+        ZPL_RE_ERROR_INTERNAL_FAILURE,
+    } zpl_regex_error;
+
+    //! Compile regex pattern.
+    ZPL_DEF zpl_regex_error zpl_re_compile(zpl_re *re, zpl_allocator backing, char const *pattern, zpl_isize pattern_len);
+
+    //! Compile regex pattern using a buffer.
+    ZPL_DEF zpl_regex_error zpl_re_compile_from_buffer(zpl_re *re, char const *pattern, zpl_isize pattern_len, void *buffer, zpl_isize buffer_len);
+
+    //! Destroy regex object.
+    ZPL_DEF void            zpl_re_destroy(zpl_re *re);
+
+    //! Retrieve number of retrievable captures.
+    ZPL_DEF zpl_isize       zpl_re_capture_count(zpl_re *re);
+
+    //! Match input string and output captures of the occurence.
+    ZPL_DEF zpl_b32         zpl_re_match(zpl_re *re, char const *str, zpl_isize str_len, zpl_re_capture *captures, zpl_isize max_capture_count, zpl_isize *offset);
+
+    //! Match all occurences in an input string and output them into captures. Array of captures is allocated on the heap and needs to be freed afterwards.
+    ZPL_DEF zpl_b32         zpl_re_match_all(zpl_re *re, char const *str, zpl_isize str_len, zpl_isize max_capture_count, zpl_re_capture **out_captures);
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_DLL)
+    // file: header/dll.h
+
+    /** @file dll.c
+    @brief DLL Handling
+    @defgroup dll DLL handling
+
+    @{
+    */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef void *zpl_dll_handle;
+    typedef void (*zpl_dll_proc)(void);
+
+    ZPL_DEF zpl_dll_handle zpl_dll_load(char const *filepath);
+    ZPL_DEF void           zpl_dll_unload(zpl_dll_handle dll);
+    ZPL_DEF zpl_dll_proc   zpl_dll_proc_address(zpl_dll_handle dll, char const *proc_name);
+
+    //! @}
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_OPTS)
+    // file: header/opts.h
+
+    /** @file opts.c
+    @brief CLI options processor
+    @defgroup cli CLI options processor
+
+     Opts is a CLI options parser, it can parse flags, switches and arguments from command line
+     and offers an easy way to express input errors as well as the ability to display help screen.
+
+    @{
+     */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef enum {
+        ZPL_OPTS_STRING,
+        ZPL_OPTS_FLOAT,
+        ZPL_OPTS_FLAG,
+        ZPL_OPTS_INT,
+    } zpl_opts_types;
+
+    typedef struct {
+        char const *name, *lname, *desc;
+        zpl_u8 type;
+        zpl_b32 met, pos;
+
+        //! values
+        union {
+            zpl_string text;
+            zpl_i64 integer;
+            zpl_f64 real;
+        };
+    } zpl_opts_entry;
+
+    typedef enum {
+        ZPL_OPTS_ERR_VALUE,
+        ZPL_OPTS_ERR_OPTION,
+        ZPL_OPTS_ERR_EXTRA_VALUE,
+        ZPL_OPTS_ERR_MISSING_VALUE,
+    } zpl_opts_err_type;
+
+    typedef struct {
+        char *val;
+        zpl_u8 type;
+    } zpl_opts_err;
+
+    typedef struct {
+        zpl_allocator    alloc;
+        zpl_opts_entry  *entries;   ///< zpl_array
+        zpl_opts_err    *errors;    ///< zpl_array
+        zpl_opts_entry **positioned; ///< zpl_array
+        char const      *appname;
+    } zpl_opts;
+
+    //! Initializes options parser.
+
+    //! Initializes CLI options parser using specified memory allocator and provided application name.
+    //! @param opts Options parser to initialize.
+    //! @param allocator Memory allocator to use. (ex. zpl_heap())
+    //! @param app Application name displayed in help screen.
+    ZPL_DEF void zpl_opts_init(zpl_opts *opts, zpl_allocator allocator, char const *app);
+
+    //! Releases the resources used by options parser.
+    ZPL_DEF void zpl_opts_free(zpl_opts *opts);
+
+    //! Registers an option.
+
+    //! Registers an option with its short and long name, specifies option's type and its description.
+    //! @param opts Options parser to add to.
+    //! @param lname Shorter name of option. (ex. "f")
+    //! @param name Full name of option. (ex. "foo") Note that rest of the module uses longer names to manipulate opts.
+    //! @param desc Description shown in the help screen.
+    //! @param type Option's type (see zpl_opts_types)
+    //! @see zpl_opts_types
+    ZPL_DEF void zpl_opts_add(zpl_opts *opts, char const *name, char const *lname, const char *desc, zpl_u8 type);
+
+    //! Registers option as positional.
+
+    //! Registers added option as positional, so that we can pass it anonymously. Arguments are expected on the command input in the same order they were registered as.
+    //! @param opts
+    //! @param name Name of already registered option.
+    ZPL_DEF void zpl_opts_positional_add(zpl_opts *opts, char const *name);
+
+    //! Compiles CLI arguments.
+
+    // This method takes CLI arguments as input and processes them based on rules that were set up.
+    //! @param opts
+    //! @param argc Argument count in an array.
+    //! @param argv Array of arguments.
+    ZPL_DEF zpl_b32 zpl_opts_compile(zpl_opts *opts, int argc, char **argv);
+
+    //! Prints out help screen.
+
+    //! Prints out help screen with example usage of application as well as with all the flags available.
+    ZPL_DEF void zpl_opts_print_help(zpl_opts *opts);
+
+    //! Prints out parsing errors.
+
+    //! Prints out possible errors caused by CLI input.
+    ZPL_DEF void zpl_opts_print_errors(zpl_opts *opts);
+
+    //! Fetches a string from an option.
+
+    //! @param opts
+    //! @param name Name of an option.
+    //! @param fallback Fallback string we return if option wasn't found.
+    ZPL_DEF zpl_string zpl_opts_string(zpl_opts *opts, char const *name, char const *fallback);
+
+    //! Fetches a real number from an option.
+
+    //! @param opts
+    //! @param name Name of an option.
+    //! @param fallback Fallback real number we return if option was not found.
+    ZPL_DEF zpl_f64 zpl_opts_real(zpl_opts *opts, char const *name, zpl_f64 fallback);
+
+    //! Fetches an integer number from an option.
+
+    //! @param opts
+    //! @param name Name of an option.
+    //! @param fallback Fallback integer number we return if option was not found.
+    ZPL_DEF zpl_i64 zpl_opts_integer(zpl_opts *opts, char const *name, zpl_i64 fallback);
+
+    //! Checks whether an option was used.
+
+    //! @param opts
+    //! @param name Name of an option.
+    ZPL_DEF zpl_b32 zpl_opts_has_arg(zpl_opts *opts, char const *name);
+
+    //! Checks whether all positionals have been passed in.
+    ZPL_DEF zpl_b32 zpl_opts_positionals_filled(zpl_opts *opts);
+
+    //! @}
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_PROCESS)
+    // file: header/process.h
+
+    /** @file process.c
+    @brief Process creation and manipulation methods
+    @defgroup process Process creation and manipulation methods
+
+    Gives you the ability to create a new process, wait for it to end or terminate it.
+    It also exposes standard I/O with configurable options.
+
+    @{
+    */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+    // TODO(zaklaus): Add Linux support
+
+    typedef enum {
+        ZPL_PR_OPTS_COMBINE_STD_OUTPUT  = ZPL_BIT(1),
+        ZPL_PR_OPTS_INHERIT_ENV         = ZPL_BIT(2),
+        ZPL_PR_OPTS_CUSTOM_ENV          = ZPL_BIT(3),
+    } zpl_pr_opts;
+
+    typedef struct {
+        zpl_file in, out, err;
+        void *f_stdin, *f_stdout, *f_stderr;
+    #ifdef ZPL_SYSTEM_WINDOWS
+        void *win32_handle;
+    #else
+        // todo
+    #endif
+    } zpl_pr;
+
+    typedef struct {
+        char *con_title;
+        char *workdir;
+
+        zpl_isize env_count;
+        char **env; // format: "var=name"
+
+        zpl_u32 posx, posy;
+        zpl_u32 resx, resy;
+        zpl_u32 bufx, bufy;
+        zpl_u32 fill_attr;
+        zpl_u32 flags;
+        zpl_b32 show_window;
+    } zpl_pr_si;
+
+    ZPL_DEF zpl_i32 zpl_pr_create(zpl_pr *process, const char **args, zpl_isize argc, zpl_pr_si si, zpl_pr_opts options);
+    ZPL_DEF void    zpl_pr_destroy(zpl_pr *process);
+    ZPL_DEF void    zpl_pr_terminate(zpl_pr *process, zpl_i32 err_code);
+    ZPL_DEF zpl_i32 zpl_pr_join(zpl_pr *process);
+
+    //! @}
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_MATH)
+    // file: header/math.h
+
+    /** @file math.c
+    @brief Math operations
+    @defgroup math Math operations
+
+    OpenGL gamedev friendly library for math.
+
+    @{
+    */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef union zpl_vec2 {
+        struct {
+            zpl_f32 x, y;
+        };
+        struct {
+            zpl_f32 s, t;
+        };
+        zpl_f32 e[2];
+    } zpl_vec2;
+
+    typedef union zpl_vec3 {
+        struct {
+            zpl_f32 x, y, z;
+        };
+        struct {
+            zpl_f32 r, g, b;
+        };
+        struct {
+            zpl_f32 s, t, p;
+        };
+
+        zpl_vec2 xy;
+        zpl_vec2 st;
+        zpl_f32 e[3];
+    } zpl_vec3;
+
+    typedef union zpl_vec4 {
+        struct {
+            zpl_f32 x, y, z, w;
+        };
+        struct {
+            zpl_f32 r, g, b, a;
+        };
+        struct {
+            zpl_f32 s, t, p, q;
+        };
+        struct {
+            zpl_vec2 xy, zw;
+        };
+        struct {
+            zpl_vec2 st, pq;
+        };
+        zpl_vec3 xyz;
+        zpl_vec3 rgb;
+        zpl_f32 e[4];
+    } zpl_vec4;
+
+    typedef union zpl_mat2 {
+        struct {
+            zpl_vec2 x, y;
+        };
+        zpl_vec2 col[2];
+        zpl_f32 e[4];
+    } zpl_mat2;
+
+    typedef union zpl_mat3 {
+        struct {
+            zpl_vec3 x, y, z;
+        };
+        zpl_vec3 col[3];
+        zpl_f32 e[9];
+    } zpl_mat3;
+
+    typedef union zpl_mat4 {
+        struct {
+            zpl_vec4 x, y, z, w;
+        };
+        zpl_vec4 col[4];
+        zpl_f32 e[16];
+    } zpl_mat4;
+
+    typedef union zpl_quat {
+        struct {
+            zpl_f32 x, y, z, w;
+        };
+        zpl_vec4 xyzw;
+        zpl_vec3 xyz;
+        zpl_f32 e[4];
+    } zpl_quat;
+
+    typedef union zpl_plane {
+        struct {
+            zpl_f32 a, b, c, d;
+        };
+        zpl_vec4 xyzw;
+        zpl_vec3 n;
+        zpl_f32 e[4];
+    } zpl_plane;
+
+    typedef struct zpl_frustum {
+        zpl_plane x1;
+        zpl_plane x2;
+        zpl_plane y1;
+        zpl_plane y2;
+        zpl_plane z1;
+        zpl_plane z2;
+    } zpl_frustum;
+
+    typedef zpl_f32 zpl_float2[2];
+    typedef zpl_f32 zpl_float3[3];
+    typedef zpl_f32 zpl_float4[4];
+
+    typedef struct zpl_rect2 {
+        zpl_vec2 pos, dim;
+    } zpl_rect2;
+    typedef struct zpl_rect3 {
+        zpl_vec3 pos, dim;
+    } zpl_rect3;
+
+    typedef struct zpl_aabb2 {
+        zpl_vec2 centre, half_size;
+    } zpl_aabb2;
+    typedef struct zpl_aabb3 {
+        zpl_vec3 centre, half_size;
+    } zpl_aabb3;
+
+    typedef short zpl_half;
+
+    #ifndef ZPL_CONSTANTS
+    #define ZPL_CONSTANTS
+    #define ZPL_EPSILON    1.19209290e-7f
+    #define ZPL_ZERO       0.0f
+    #define ZPL_ONE        1.0f
+    #define ZPL_TWO_THIRDS 0.666666666666666666666666666666666666667f
+
+    #define ZPL_TAU          6.28318530717958647692528676655900576f
+    #define ZPL_PI           3.14159265358979323846264338327950288f
+    #define ZPL_ONE_OVER_TAU 0.636619772367581343075535053490057448f
+    #define ZPL_ONE_OVER_PI  0.159154943091895335768883763372514362f
+
+    #define ZPL_TAU_OVER_2 3.14159265358979323846264338327950288f
+    #define ZPL_TAU_OVER_4 1.570796326794896619231321691639751442f
+    #define ZPL_TAU_OVER_8 0.785398163397448309615660845819875721f
+
+    #define ZPL_E          2.71828182845904523536f
+    #define ZPL_SQRT_TWO   1.41421356237309504880168872420969808f
+    #define ZPL_SQRT_THREE 1.73205080756887729352744634150587236f
+    #define ZPL_SQRT_FIVE  2.23606797749978969640917366873127623f
+
+    #define ZPL_LOG_TWO 0.693147180559945309417232121458176568f
+    #define ZPL_LOG_TEN 2.30258509299404568401799145468436421f
+    #endif // ZPL_CONSTANTS
+
+    #ifndef zpl_square
+    #define zpl_square(x) ((x) * (x))
+    #endif
+
+    #ifndef zpl_cube
+    #define zpl_cube(x) ((x) * (x) * (x))
+    #endif
+
+    #ifndef zpl_sign
+    #define zpl_sign(x) ((x) >= 0 ? 1 : -1)
+    #endif
+
+    ZPL_DEF zpl_f32 zpl_to_radians(zpl_f32 degrees);
+    ZPL_DEF zpl_f32 zpl_to_degrees(zpl_f32 radians);
+
+    /* NOTE: Because to interpolate angles */
+    ZPL_DEF zpl_f32 zpl_angle_diff(zpl_f32 radians_a, zpl_f32 radians_b);
+
+    ZPL_DEF zpl_f32 zpl_copy_sign(zpl_f32 x, zpl_f32 y);
+    ZPL_DEF zpl_f32 zpl_remainder(zpl_f32 x, zpl_f32 y);
+    ZPL_DEF zpl_f32 zpl_mod(zpl_f32 x, zpl_f32 y);
+    ZPL_DEF zpl_f64 zpl_copy_sign64(zpl_f64 x, zpl_f64 y);
+    ZPL_DEF zpl_f64 zpl_floor64(zpl_f64 x);
+    ZPL_DEF zpl_f64 zpl_ceil64(zpl_f64 x);
+    ZPL_DEF zpl_f64 zpl_round64(zpl_f64 x);
+    ZPL_DEF zpl_f64 zpl_remainder64(zpl_f64 x, zpl_f64 y);
+    ZPL_DEF zpl_f64 zpl_abs64(zpl_f64 x);
+    ZPL_DEF zpl_f64 zpl_sign64(zpl_f64 x);
+    ZPL_DEF zpl_f64 zpl_mod64(zpl_f64 x, zpl_f64 y);
+    ZPL_DEF zpl_f32 zpl_sqrt(zpl_f32 a);
+    ZPL_DEF zpl_f32 zpl_rsqrt(zpl_f32 a);
+    ZPL_DEF zpl_f32 zpl_quake_rsqrt(zpl_f32 a); /* NOTE: It's probably better to use 1.0f/zpl_sqrt(a)
+                                         * And for simd, there is usually isqrt functions too!
+                                         */
+    ZPL_DEF zpl_f32 zpl_sin(zpl_f32 radians);
+    ZPL_DEF zpl_f32 zpl_cos(zpl_f32 radians);
+    ZPL_DEF zpl_f32 zpl_tan(zpl_f32 radians);
+    ZPL_DEF zpl_f32 zpl_arcsin(zpl_f32 a);
+    ZPL_DEF zpl_f32 zpl_arccos(zpl_f32 a);
+    ZPL_DEF zpl_f32 zpl_arctan(zpl_f32 a);
+    ZPL_DEF zpl_f32 zpl_arctan2(zpl_f32 y, zpl_f32 x);
+
+    ZPL_DEF zpl_f32 zpl_exp(zpl_f32 x);
+    ZPL_DEF zpl_f32 zpl_exp2(zpl_f32 x);
+    ZPL_DEF zpl_f32 zpl_log(zpl_f32 x);
+    ZPL_DEF zpl_f32 zpl_log2(zpl_f32 x);
+    ZPL_DEF zpl_f32 zpl_fast_exp(zpl_f32 x);   /* NOTE: Only valid from -1 <= x <= +1 */
+    ZPL_DEF zpl_f32 zpl_fast_exp2(zpl_f32 x);  /* NOTE: Only valid from -1 <= x <= +1 */
+    ZPL_DEF zpl_f32 zpl_pow(zpl_f32 x, zpl_f32 y); /* x^y */
+
+    ZPL_DEF zpl_f32 zpl_round(zpl_f32 x);
+    ZPL_DEF zpl_f32 zpl_floor(zpl_f32 x);
+    ZPL_DEF zpl_f32 zpl_ceil(zpl_f32 x);
+
+    ZPL_DEF zpl_f32  zpl_half_to_float(zpl_half value);
+    ZPL_DEF zpl_half zpl_float_to_half(zpl_f32 value);
+
+    ZPL_DEF zpl_vec2 zpl_vec2f_zero(void);
+    ZPL_DEF zpl_vec2 zpl_vec2f(zpl_f32 x, zpl_f32 y);
+    ZPL_DEF zpl_vec2 zpl_vec2fv(zpl_f32 x[2]);
+
+    ZPL_DEF zpl_vec3 zpl_vec3f_zero(void);
+    ZPL_DEF zpl_vec3 zpl_vec3f(zpl_f32 x, zpl_f32 y, zpl_f32 z);
+    ZPL_DEF zpl_vec3 zpl_vec3fv(zpl_f32 x[3]);
+
+    ZPL_DEF zpl_vec4 zpl_vec4f_zero(void);
+    ZPL_DEF zpl_vec4 zpl_vec4f(zpl_f32 x, zpl_f32 y, zpl_f32 z, zpl_f32 w);
+    ZPL_DEF zpl_vec4 zpl_vec4fv(zpl_f32 x[4]);
+
+    ZPL_DEF zpl_f32 zpl_vec2_max(zpl_vec2 v);
+    ZPL_DEF zpl_f32 zpl_vec2_side(zpl_vec2 p, zpl_vec2 q, zpl_vec2 r);
+    ZPL_DEF void zpl_vec2_add(zpl_vec2 *d, zpl_vec2 v0, zpl_vec2 v1);
+    ZPL_DEF void zpl_vec2_sub(zpl_vec2 *d, zpl_vec2 v0, zpl_vec2 v1);
+    ZPL_DEF void zpl_vec2_mul(zpl_vec2 *d, zpl_vec2 v, zpl_f32 s);
+    ZPL_DEF void zpl_vec2_div(zpl_vec2 *d, zpl_vec2 v, zpl_f32 s);
+
+    ZPL_DEF zpl_f32 zpl_vec3_max(zpl_vec3 v);
+    ZPL_DEF void zpl_vec3_add(zpl_vec3 *d, zpl_vec3 v0, zpl_vec3 v1);
+    ZPL_DEF void zpl_vec3_sub(zpl_vec3 *d, zpl_vec3 v0, zpl_vec3 v1);
+    ZPL_DEF void zpl_vec3_mul(zpl_vec3 *d, zpl_vec3 v, zpl_f32 s);
+    ZPL_DEF void zpl_vec3_div(zpl_vec3 *d, zpl_vec3 v, zpl_f32 s);
+
+    ZPL_DEF void zpl_vec4_add(zpl_vec4 *d, zpl_vec4 v0, zpl_vec4 v1);
+    ZPL_DEF void zpl_vec4_sub(zpl_vec4 *d, zpl_vec4 v0, zpl_vec4 v1);
+    ZPL_DEF void zpl_vec4_mul(zpl_vec4 *d, zpl_vec4 v, zpl_f32 s);
+    ZPL_DEF void zpl_vec4_div(zpl_vec4 *d, zpl_vec4 v, zpl_f32 s);
+
+    ZPL_DEF void zpl_vec2_addeq(zpl_vec2 *d, zpl_vec2 v);
+    ZPL_DEF void zpl_vec2_subeq(zpl_vec2 *d, zpl_vec2 v);
+    ZPL_DEF void zpl_vec2_muleq(zpl_vec2 *d, zpl_f32 s);
+    ZPL_DEF void zpl_vec2_diveq(zpl_vec2 *d, zpl_f32 s);
+
+    ZPL_DEF void zpl_vec3_addeq(zpl_vec3 *d, zpl_vec3 v);
+    ZPL_DEF void zpl_vec3_subeq(zpl_vec3 *d, zpl_vec3 v);
+    ZPL_DEF void zpl_vec3_muleq(zpl_vec3 *d, zpl_f32 s);
+    ZPL_DEF void zpl_vec3_diveq(zpl_vec3 *d, zpl_f32 s);
+
+    ZPL_DEF void zpl_vec4_addeq(zpl_vec4 *d, zpl_vec4 v);
+    ZPL_DEF void zpl_vec4_subeq(zpl_vec4 *d, zpl_vec4 v);
+    ZPL_DEF void zpl_vec4_muleq(zpl_vec4 *d, zpl_f32 s);
+    ZPL_DEF void zpl_vec4_diveq(zpl_vec4 *d, zpl_f32 s);
+
+    ZPL_DEF zpl_f32 zpl_vec2_dot(zpl_vec2 v0, zpl_vec2 v1);
+    ZPL_DEF zpl_f32 zpl_vec3_dot(zpl_vec3 v0, zpl_vec3 v1);
+    ZPL_DEF zpl_f32 zpl_vec4_dot(zpl_vec4 v0, zpl_vec4 v1);
+
+    ZPL_DEF void zpl_vec2_cross(zpl_f32 *d, zpl_vec2 v0, zpl_vec2 v1);
+    ZPL_DEF void zpl_vec3_cross(zpl_vec3 *d, zpl_vec3 v0, zpl_vec3 v1);
+
+    ZPL_DEF zpl_f32 zpl_vec2_mag2(zpl_vec2 v);
+    ZPL_DEF zpl_f32 zpl_vec3_mag2(zpl_vec3 v);
+    ZPL_DEF zpl_f32 zpl_vec4_mag2(zpl_vec4 v);
+
+    ZPL_DEF zpl_f32 zpl_vec2_mag(zpl_vec2 v);
+    ZPL_DEF zpl_f32 zpl_vec3_mag(zpl_vec3 v);
+    ZPL_DEF zpl_f32 zpl_vec4_mag(zpl_vec4 v);
+
+    ZPL_DEF void zpl_vec2_norm(zpl_vec2 *d, zpl_vec2 v);
+    ZPL_DEF void zpl_vec3_norm(zpl_vec3 *d, zpl_vec3 v);
+    ZPL_DEF void zpl_vec4_norm(zpl_vec4 *d, zpl_vec4 v);
+
+    ZPL_DEF void zpl_vec2_norm0(zpl_vec2 *d, zpl_vec2 v);
+    ZPL_DEF void zpl_vec3_norm0(zpl_vec3 *d, zpl_vec3 v);
+    ZPL_DEF void zpl_vec4_norm0(zpl_vec4 *d, zpl_vec4 v);
+
+    ZPL_DEF void zpl_vec2_reflect(zpl_vec2 *d, zpl_vec2 i, zpl_vec2 n);
+    ZPL_DEF void zpl_vec3_reflect(zpl_vec3 *d, zpl_vec3 i, zpl_vec3 n);
+    ZPL_DEF void zpl_vec2_refract(zpl_vec2 *d, zpl_vec2 i, zpl_vec2 n, zpl_f32 eta);
+    ZPL_DEF void zpl_vec3_refract(zpl_vec3 *d, zpl_vec3 i, zpl_vec3 n, zpl_f32 eta);
+
+    ZPL_DEF zpl_f32 zpl_vec2_aspect_ratio(zpl_vec2 v);
+
+    ZPL_DEF void zpl_mat2_identity(zpl_mat2 *m);
+    ZPL_DEF void zpl_float22_identity(zpl_f32 m[2][2]);
+
+    ZPL_DEF void    zpl_mat2_transpose(zpl_mat2 *m);
+    ZPL_DEF void    zpl_mat2_mul(zpl_mat2 *out, zpl_mat2 *m1, zpl_mat2 *m2);
+    ZPL_DEF void    zpl_mat2_mul_vec2(zpl_vec2 *out, zpl_mat2 *m, zpl_vec2 in);
+    ZPL_DEF void    zpl_mat2_inverse(zpl_mat2 *out, zpl_mat2 *in);
+    ZPL_DEF zpl_f32 zpl_mat2_determinate(zpl_mat2 *m);
+
+    ZPL_DEF zpl_mat2   *zpl_mat2_v(zpl_vec2 m[2]);
+    ZPL_DEF zpl_mat2   *zpl_mat2_f(zpl_f32 m[2][2]);
+    ZPL_DEF zpl_float2 *zpl_float22_m(zpl_mat2 *m);
+    ZPL_DEF zpl_float2 *zpl_float22_v(zpl_vec2 m[2]);
+    ZPL_DEF zpl_float2 *zpl_float22_4(zpl_f32 m[4]);
+
+    ZPL_DEF void zpl_float22_transpose(zpl_f32 (*vec)[2]);
+    ZPL_DEF void zpl_float22_mul(zpl_f32 (*out)[2], zpl_f32 (*mat1)[2], zpl_f32 (*mat2)[2]);
+    ZPL_DEF void zpl_float22_mul_vec2(zpl_vec2 *out, zpl_f32 m[2][2], zpl_vec2 in);
+
+    ZPL_DEF void zpl_mat3_identity(zpl_mat3 *m);
+    ZPL_DEF void zpl_float33_identity(zpl_f32 m[3][3]);
+
+    ZPL_DEF void    zpl_mat3_transpose(zpl_mat3 *m);
+    ZPL_DEF void    zpl_mat3_mul(zpl_mat3 *out, zpl_mat3 *m1, zpl_mat3 *m2);
+    ZPL_DEF void    zpl_mat3_mul_vec3(zpl_vec3 *out, zpl_mat3 *m, zpl_vec3 in);
+    ZPL_DEF void    zpl_mat3_inverse(zpl_mat3 *out, zpl_mat3 *in);
+    ZPL_DEF zpl_f32 zpl_mat3_determinate(zpl_mat3 *m);
+
+    ZPL_DEF zpl_mat3   *zpl_mat3_v(zpl_vec3 m[3]);
+    ZPL_DEF zpl_mat3   *zpl_mat3_f(zpl_f32 m[3][3]);
+
+    ZPL_DEF zpl_float3 *zpl_float33_m(zpl_mat3 *m);
+    ZPL_DEF zpl_float3 *zpl_float33_v(zpl_vec3 m[3]);
+    ZPL_DEF zpl_float3 *zpl_float33_9(zpl_f32 m[9]);
+
+    ZPL_DEF void zpl_float33_transpose(zpl_f32 (*vec)[3]);
+    ZPL_DEF void zpl_float33_mul(zpl_f32 (*out)[3], zpl_f32 (*mat1)[3], zpl_f32 (*mat2)[3]);
+    ZPL_DEF void zpl_float33_mul_vec3(zpl_vec3 *out, zpl_f32 m[3][3], zpl_vec3 in);
+
+    ZPL_DEF void zpl_mat4_identity(zpl_mat4 *m);
+    ZPL_DEF void zpl_float44_identity(zpl_f32 m[4][4]);
+    ZPL_DEF void zpl_mat4_copy(zpl_mat4* out, zpl_mat4* m);
+
+    ZPL_DEF void zpl_mat4_transpose(zpl_mat4 *m);
+    ZPL_DEF void zpl_mat4_mul(zpl_mat4 *out, zpl_mat4 *m1, zpl_mat4 *m2);
+    ZPL_DEF void zpl_mat4_mul_vec4(zpl_vec4 *out, zpl_mat4 *m, zpl_vec4 in);
+    ZPL_DEF void zpl_mat4_inverse(zpl_mat4 *out, zpl_mat4 *in);
+
+    ZPL_DEF zpl_mat4 *zpl_mat4_v(zpl_vec4 m[4]);
+    ZPL_DEF zpl_mat4 *zpl_mat4_f(zpl_f32 m[4][4]);
+
+    ZPL_DEF zpl_float4 *zpl_float44_m(zpl_mat4 *m);
+    ZPL_DEF zpl_float4 *zpl_float44_v(zpl_vec4 m[4]);
+    ZPL_DEF zpl_float4 *zpl_float44_16(zpl_f32 m[16]);
+
+    ZPL_DEF void zpl_float44_transpose(zpl_f32 (*vec)[4]);
+    ZPL_DEF void zpl_float44_mul(zpl_f32 (*out)[4], zpl_f32 (*mat1)[4], zpl_f32 (*mat2)[4]);
+    ZPL_DEF void zpl_float44_mul_vec4(zpl_vec4 *out, zpl_f32 m[4][4], zpl_vec4 in);
+
+    ZPL_DEF void zpl_mat4_translate(zpl_mat4 *out, zpl_vec3 v);
+    ZPL_DEF void zpl_mat4_rotate(zpl_mat4 *out, zpl_vec3 v, zpl_f32 angle_radians);
+    ZPL_DEF void zpl_mat4_scale(zpl_mat4 *out, zpl_vec3 v);
+    ZPL_DEF void zpl_mat4_scalef(zpl_mat4 *out, zpl_f32 s);
+    ZPL_DEF void zpl_mat4_ortho2d(zpl_mat4 *out, zpl_f32 left, zpl_f32 right, zpl_f32 bottom, zpl_f32 top);
+    ZPL_DEF void zpl_mat4_ortho3d(zpl_mat4 *out, zpl_f32 left, zpl_f32 right, zpl_f32 bottom, zpl_f32 top, zpl_f32 z_near, zpl_f32 z_far);
+    ZPL_DEF void zpl_mat4_perspective(zpl_mat4 *out, zpl_f32 fovy, zpl_f32 aspect, zpl_f32 z_near, zpl_f32 z_far);
+    ZPL_DEF void zpl_mat4_infinite_perspective(zpl_mat4 *out, zpl_f32 fovy, zpl_f32 aspect, zpl_f32 z_near);
+
+    ZPL_DEF void zpl_mat4_ortho2d_dx(zpl_mat4 *out, zpl_f32 left, zpl_f32 right, zpl_f32 bottom, zpl_f32 top);
+    ZPL_DEF void zpl_mat4_ortho3d_dx(zpl_mat4 *out, zpl_f32 left, zpl_f32 right, zpl_f32 bottom, zpl_f32 top, zpl_f32 z_near, zpl_f32 z_far);
+    ZPL_DEF void zpl_mat4_perspective_dx(zpl_mat4 *out, zpl_f32 fovy, zpl_f32 aspect, zpl_f32 z_near, zpl_f32 z_far);
+    ZPL_DEF void zpl_mat4_infinite_perspective_dx(zpl_mat4 *out, zpl_f32 fovy, zpl_f32 aspect, zpl_f32 z_near);
+
+    ZPL_DEF void zpl_mat4_look_at(zpl_mat4 *out, zpl_vec3 eye, zpl_vec3 centre, zpl_vec3 up);
+
+    ZPL_DEF void zpl_mat4_look_at_lh(zpl_mat4 *out, zpl_vec3 eye, zpl_vec3 centre, zpl_vec3 up);
+
+    ZPL_DEF zpl_quat zpl_quatf(zpl_f32 x, zpl_f32 y, zpl_f32 z, zpl_f32 w);
+    ZPL_DEF zpl_quat zpl_quatfv(zpl_f32 e[4]);
+    ZPL_DEF zpl_quat zpl_quat_axis_angle(zpl_vec3 axis, zpl_f32 angle_radians);
+    ZPL_DEF zpl_quat zpl_quat_euler_angles(zpl_f32 pitch, zpl_f32 yaw, zpl_f32 roll);
+    ZPL_DEF zpl_quat zpl_quat_identity(void);
+
+    ZPL_DEF void zpl_quat_add(zpl_quat *d, zpl_quat q0, zpl_quat q1);
+    ZPL_DEF void zpl_quat_sub(zpl_quat *d, zpl_quat q0, zpl_quat q1);
+    ZPL_DEF void zpl_quat_mul(zpl_quat *d, zpl_quat q0, zpl_quat q1);
+    ZPL_DEF void zpl_quat_div(zpl_quat *d, zpl_quat q0, zpl_quat q1);
+
+    ZPL_DEF void zpl_quat_mulf(zpl_quat *d, zpl_quat q, zpl_f32 s);
+    ZPL_DEF void zpl_quat_divf(zpl_quat *d, zpl_quat q, zpl_f32 s);
+
+    ZPL_DEF void zpl_quat_addeq(zpl_quat *d, zpl_quat q);
+    ZPL_DEF void zpl_quat_subeq(zpl_quat *d, zpl_quat q);
+    ZPL_DEF void zpl_quat_muleq(zpl_quat *d, zpl_quat q);
+    ZPL_DEF void zpl_quat_diveq(zpl_quat *d, zpl_quat q);
+
+    ZPL_DEF void zpl_quat_muleqf(zpl_quat *d, zpl_f32 s);
+    ZPL_DEF void zpl_quat_diveqf(zpl_quat *d, zpl_f32 s);
+
+    ZPL_DEF zpl_f32 zpl_quat_dot(zpl_quat q0, zpl_quat q1);
+    ZPL_DEF zpl_f32 zpl_quat_mag(zpl_quat q);
+
+    ZPL_DEF void zpl_quat_norm(zpl_quat *d, zpl_quat q);
+    ZPL_DEF void zpl_quat_conj(zpl_quat *d, zpl_quat q);
+    ZPL_DEF void zpl_quat_inverse(zpl_quat *d, zpl_quat q);
+
+    ZPL_DEF void    zpl_quat_axis(zpl_vec3 *axis, zpl_quat q);
+    ZPL_DEF zpl_f32 zpl_quat_angle(zpl_quat q);
+
+    ZPL_DEF zpl_f32 zpl_quat_pitch(zpl_quat q);
+    ZPL_DEF zpl_f32 zpl_quat_yaw(zpl_quat q);
+    ZPL_DEF zpl_f32 zpl_quat_roll(zpl_quat q);
+
+    /* NOTE: Rotate v by q */
+    ZPL_DEF void zpl_quat_rotate_vec3(zpl_vec3 *d, zpl_quat q, zpl_vec3 v);
+    ZPL_DEF void zpl_mat4_from_quat(zpl_mat4 *out, zpl_quat q);
+    ZPL_DEF void zpl_quat_from_mat4(zpl_quat *out, zpl_mat4 *m);
+
+    /* Plane math. */
+    ZPL_DEF zpl_f32 zpl_plane_distance(zpl_plane* p, zpl_vec3 v);
+
+    /* Frustum culling. */
+    ZPL_DEF void zpl_frustum_create(zpl_frustum* out, zpl_mat4* camera, zpl_mat4* proj);
+    ZPL_DEF zpl_b8 zpl_frustum_sphere_inside(zpl_frustum* frustum, zpl_vec3 center, zpl_f32 radius);
+    ZPL_DEF zpl_b8 zpl_frustum_point_inside(zpl_frustum* frustum, zpl_vec3 point);
+    ZPL_DEF zpl_b8 zpl_frustum_box_inside(zpl_frustum* frustum, zpl_aabb3 box);
+
+    /* Interpolations */
+    ZPL_DEF zpl_f32 zpl_lerp(zpl_f32 a, zpl_f32 b, zpl_f32 t);
+    ZPL_DEF zpl_f32 zpl_unlerp(zpl_f32 t, zpl_f32 a, zpl_f32 b);
+    ZPL_DEF zpl_f32 zpl_smooth_step(zpl_f32 a, zpl_f32 b, zpl_f32 t);
+    ZPL_DEF zpl_f32 zpl_smoother_step(zpl_f32 a, zpl_f32 b, zpl_f32 t);
+
+    ZPL_DEF void zpl_vec2_lerp(zpl_vec2 *d, zpl_vec2 a, zpl_vec2 b, zpl_f32 t);
+    ZPL_DEF void zpl_vec3_lerp(zpl_vec3 *d, zpl_vec3 a, zpl_vec3 b, zpl_f32 t);
+    ZPL_DEF void zpl_vec4_lerp(zpl_vec4 *d, zpl_vec4 a, zpl_vec4 b, zpl_f32 t);
+
+    ZPL_DEF void zpl_vec2_cslerp(zpl_vec2 *d, zpl_vec2 a, zpl_vec2 v0, zpl_vec2 b, zpl_vec2 v1, zpl_f32 t);
+    ZPL_DEF void zpl_vec3_cslerp(zpl_vec3 *d, zpl_vec3 a, zpl_vec3 v0, zpl_vec3 b, zpl_vec3 v1, zpl_f32 t);
+    ZPL_DEF void zpl_vec2_dcslerp(zpl_vec2 *d, zpl_vec2 a, zpl_vec2 v0, zpl_vec2 b, zpl_vec2 v1, zpl_f32 t);
+    ZPL_DEF void zpl_vec3_dcslerp(zpl_vec3 *d, zpl_vec3 a, zpl_vec3 v0, zpl_vec3 b, zpl_vec3 v1, zpl_f32 t);
+
+    ZPL_DEF void zpl_quat_lerp(zpl_quat *d, zpl_quat a, zpl_quat b, zpl_f32 t);
+    ZPL_DEF void zpl_quat_nlerp(zpl_quat *d, zpl_quat a, zpl_quat b, zpl_f32 t);
+    ZPL_DEF void zpl_quat_slerp(zpl_quat *d, zpl_quat a, zpl_quat b, zpl_f32 t);
+    ZPL_DEF void zpl_quat_nquad(zpl_quat *d, zpl_quat p, zpl_quat a, zpl_quat b, zpl_quat q, zpl_f32 t);
+    ZPL_DEF void zpl_quat_squad(zpl_quat *d, zpl_quat p, zpl_quat a, zpl_quat b, zpl_quat q, zpl_f32 t);
+    ZPL_DEF void zpl_quat_slerp_approx(zpl_quat *d, zpl_quat a, zpl_quat b, zpl_f32 t);
+    ZPL_DEF void zpl_quat_squad_approx(zpl_quat *d, zpl_quat p, zpl_quat a, zpl_quat b, zpl_quat q, zpl_f32 t);
+
+    /* Rects */
+    ZPL_DEF zpl_rect2 zpl_rect2f(zpl_vec2 pos, zpl_vec2 dim);
+    ZPL_DEF zpl_rect3 zpl_rect3f(zpl_vec3 pos, zpl_vec3 dim);
+
+    ZPL_DEF int zpl_rect2_contains(zpl_rect2 a, zpl_f32 x, zpl_f32 y);
+    ZPL_DEF int zpl_rect2_contains_vec2(zpl_rect2 a, zpl_vec2 p);
+    ZPL_DEF int zpl_rect2_intersects(zpl_rect2 a, zpl_rect2 b);
+    ZPL_DEF int zpl_rect2_intersection_result(zpl_rect2 a, zpl_rect2 b, zpl_rect2 *intersection);
+
+    //! @}
+    ZPL_END_C_DECLS
+    #if defined(__cplusplus)
+        ZPL_INLINE bool operator==(zpl_vec2 a, zpl_vec2 b) { return (a.x == b.x) && (a.y == b.y); }
+        ZPL_INLINE bool operator!=(zpl_vec2 a, zpl_vec2 b) { return !operator==(a, b); }
+
+        ZPL_INLINE zpl_vec2 operator+(zpl_vec2 a) { return a; }
+        ZPL_INLINE zpl_vec2 operator-(zpl_vec2 a) { zpl_vec2 r = {-a.x, -a.y}; return r; }
+
+        ZPL_INLINE zpl_vec2 operator+(zpl_vec2 a, zpl_vec2 b) { zpl_vec2 r; zpl_vec2_add(&r, a, b); return r; }
+        ZPL_INLINE zpl_vec2 operator-(zpl_vec2 a, zpl_vec2 b) { zpl_vec2 r; zpl_vec2_sub(&r, a, b); return r; }
+
+        ZPL_INLINE zpl_vec2 operator*(zpl_vec2 a, float scalar) { zpl_vec2 r; zpl_vec2_mul(&r, a, scalar); return r; }
+        ZPL_INLINE zpl_vec2 operator*(float scalar, zpl_vec2 a) { return operator*(a, scalar); }
+
+        ZPL_INLINE zpl_vec2 operator/(zpl_vec2 a, float scalar) { return operator*(a, 1.0f/scalar); }
+
+        /* Hadamard Product */
+        ZPL_INLINE zpl_vec2 operator*(zpl_vec2 a, zpl_vec2 b) { zpl_vec2 r = {a.x*b.x, a.y*b.y}; return r; }
+        ZPL_INLINE zpl_vec2 operator/(zpl_vec2 a, zpl_vec2 b) { zpl_vec2 r = {a.x/b.x, a.y/b.y}; return r; }
+
+        ZPL_INLINE zpl_vec2 &operator+=(zpl_vec2 &a, zpl_vec2 b)       { return (a = a + b); }
+        ZPL_INLINE zpl_vec2 &operator-=(zpl_vec2 &a, zpl_vec2 b)       { return (a = a - b); }
+        ZPL_INLINE zpl_vec2 &operator*=(zpl_vec2 &a, float scalar) { return (a = a * scalar); }
+        ZPL_INLINE zpl_vec2 &operator/=(zpl_vec2 &a, float scalar) { return (a = a / scalar); }
+
+
+        ZPL_INLINE bool operator==(zpl_vec3 a, zpl_vec3 b) { return (a.x == b.x) && (a.y == b.y) && (a.z == b.z); }
+        ZPL_INLINE bool operator!=(zpl_vec3 a, zpl_vec3 b) { return !operator==(a, b); }
+
+        ZPL_INLINE zpl_vec3 operator+(zpl_vec3 a) { return a; }
+        ZPL_INLINE zpl_vec3 operator-(zpl_vec3 a) { zpl_vec3 r = {-a.x, -a.y, -a.z}; return r; }
+
+        ZPL_INLINE zpl_vec3 operator+(zpl_vec3 a, zpl_vec3 b) { zpl_vec3 r; zpl_vec3_add(&r, a, b); return r; }
+        ZPL_INLINE zpl_vec3 operator-(zpl_vec3 a, zpl_vec3 b) { zpl_vec3 r; zpl_vec3_sub(&r, a, b); return r; }
+
+        ZPL_INLINE zpl_vec3 operator*(zpl_vec3 a, float scalar) { zpl_vec3 r; zpl_vec3_mul(&r, a, scalar); return r; }
+        ZPL_INLINE zpl_vec3 operator*(float scalar, zpl_vec3 a) { return operator*(a, scalar); }
+
+        ZPL_INLINE zpl_vec3 operator/(zpl_vec3 a, float scalar) { return operator*(a, 1.0f/scalar); }
+
+        /* Hadamard Product */
+        ZPL_INLINE zpl_vec3 operator*(zpl_vec3 a, zpl_vec3 b) { zpl_vec3 r = {a.x*b.x, a.y*b.y, a.z*b.z}; return r; }
+        ZPL_INLINE zpl_vec3 operator/(zpl_vec3 a, zpl_vec3 b) { zpl_vec3 r = {a.x/b.x, a.y/b.y, a.z/b.z}; return r; }
+
+        ZPL_INLINE zpl_vec3 &operator+=(zpl_vec3 &a, zpl_vec3 b)       { return (a = a + b); }
+        ZPL_INLINE zpl_vec3 &operator-=(zpl_vec3 &a, zpl_vec3 b)       { return (a = a - b); }
+        ZPL_INLINE zpl_vec3 &operator*=(zpl_vec3 &a, float scalar) { return (a = a * scalar); }
+        ZPL_INLINE zpl_vec3 &operator/=(zpl_vec3 &a, float scalar) { return (a = a / scalar); }
+
+
+        ZPL_INLINE bool operator==(zpl_vec4 a, zpl_vec4 b) { return (a.x == b.x) && (a.y == b.y) && (a.z == b.z) && (a.w == b.w); }
+        ZPL_INLINE bool operator!=(zpl_vec4 a, zpl_vec4 b) { return !operator==(a, b); }
+
+        ZPL_INLINE zpl_vec4 operator+(zpl_vec4 a) { return a; }
+        ZPL_INLINE zpl_vec4 operator-(zpl_vec4 a) { zpl_vec4 r = {-a.x, -a.y, -a.z, -a.w}; return r; }
+
+        ZPL_INLINE zpl_vec4 operator+(zpl_vec4 a, zpl_vec4 b) { zpl_vec4 r; zpl_vec4_add(&r, a, b); return r; }
+        ZPL_INLINE zpl_vec4 operator-(zpl_vec4 a, zpl_vec4 b) { zpl_vec4 r; zpl_vec4_sub(&r, a, b); return r; }
+
+        ZPL_INLINE zpl_vec4 operator*(zpl_vec4 a, float scalar) { zpl_vec4 r; zpl_vec4_mul(&r, a, scalar); return r; }
+        ZPL_INLINE zpl_vec4 operator*(float scalar, zpl_vec4 a) { return operator*(a, scalar); }
+
+        ZPL_INLINE zpl_vec4 operator/(zpl_vec4 a, float scalar) { return operator*(a, 1.0f/scalar); }
+
+        /* Hadamard Product */
+        ZPL_INLINE zpl_vec4 operator*(zpl_vec4 a, zpl_vec4 b) { zpl_vec4 r = {a.x*b.x, a.y*b.y, a.z*b.z, a.w*b.w}; return r; }
+        ZPL_INLINE zpl_vec4 operator/(zpl_vec4 a, zpl_vec4 b) { zpl_vec4 r = {a.x/b.x, a.y/b.y, a.z/b.z, a.w/b.w}; return r; }
+
+        ZPL_INLINE zpl_vec4 &operator+=(zpl_vec4 &a, zpl_vec4 b)       { return (a = a + b); }
+        ZPL_INLINE zpl_vec4 &operator-=(zpl_vec4 &a, zpl_vec4 b)       { return (a = a - b); }
+        ZPL_INLINE zpl_vec4 &operator*=(zpl_vec4 &a, float scalar) { return (a = a * scalar); }
+        ZPL_INLINE zpl_vec4 &operator/=(zpl_vec4 &a, float scalar) { return (a = a / scalar); }
+
+
+        ZPL_INLINE zpl_mat2 operator+(zpl_mat2 const &a, zpl_mat2 const &b) {
+            int i, j;
+            zpl_mat2 r = {0};
+            for (j = 0; j < 2; j++) {
+                for (i = 0; i < 2; i++)
+                    r.e[2*j+i] = a.e[2*j+i] + b.e[2*j+i];
+            }
+            return r;
+        }
+
+        ZPL_INLINE zpl_mat2 operator-(zpl_mat2 const &a, zpl_mat2 const &b) {
+            int i, j;
+            zpl_mat2 r = {0};
+            for (j = 0; j < 2; j++) {
+                for (i = 0; i < 2; i++)
+                    r.e[2*j+i] = a.e[2*j+i] - b.e[2*j+i];
+            }
+            return r;
+        }
+
+        ZPL_INLINE zpl_mat2 operator*(zpl_mat2 const &a, zpl_mat2 const &b) { zpl_mat2 r; zpl_mat2_mul(&r, (zpl_mat2 *)&a, (zpl_mat2 *)&b); return r; }
+        ZPL_INLINE zpl_vec2 operator*(zpl_mat2 const &a, zpl_vec2 v) { zpl_vec2 r; zpl_mat2_mul_vec2(&r, (zpl_mat2 *)&a, v); return r; }
+        ZPL_INLINE zpl_mat2 operator*(zpl_mat2 const &a, float scalar) {
+            zpl_mat2 r = {0};
+            int i;
+            for (i = 0; i < 2*2; i++) r.e[i] = a.e[i] * scalar;
+            return r;
+        }
+        ZPL_INLINE zpl_mat2 operator*(float scalar, zpl_mat2 const &a) { return operator*(a, scalar); }
+        ZPL_INLINE zpl_mat2 operator/(zpl_mat2 const &a, float scalar) { return operator*(a, 1.0f/scalar); }
+
+        ZPL_INLINE zpl_mat2& operator+=(zpl_mat2& a, zpl_mat2 const &b) { return (a = a + b); }
+        ZPL_INLINE zpl_mat2& operator-=(zpl_mat2& a, zpl_mat2 const &b) { return (a = a - b); }
+        ZPL_INLINE zpl_mat2& operator*=(zpl_mat2& a, zpl_mat2 const &b) { return (a = a * b); }
+
+
+
+        ZPL_INLINE zpl_mat3 operator+(zpl_mat3 const &a, zpl_mat3 const &b) {
+            int i, j;
+            zpl_mat3 r = {0};
+            for (j = 0; j < 3; j++) {
+                for (i = 0; i < 3; i++)
+                    r.e[3*j+i] = a.e[3*j+i] + b.e[3*j+i];
+            }
+            return r;
+        }
+
+        ZPL_INLINE zpl_mat3 operator-(zpl_mat3 const &a, zpl_mat3 const &b) {
+            int i, j;
+            zpl_mat3 r = {0};
+            for (j = 0; j < 3; j++) {
+                for (i = 0; i < 3; i++)
+                    r.e[3*j+i] = a.e[3*j+i] - b.e[3*j+i];
+            }
+            return r;
+        }
+
+        ZPL_INLINE zpl_mat3 operator*(zpl_mat3 const &a, zpl_mat3 const &b) { zpl_mat3 r; zpl_mat3_mul(&r, (zpl_mat3 *)&a, (zpl_mat3 *)&b); return r; }
+        ZPL_INLINE zpl_vec3 operator*(zpl_mat3 const &a, zpl_vec3 v) { zpl_vec3 r; zpl_mat3_mul_vec3(&r, (zpl_mat3 *)&a, v); return r; }
+        ZPL_INLINE zpl_mat3 operator*(zpl_mat3 const &a, float scalar) {
+            zpl_mat3 r = {0};
+            int i;
+            for (i = 0; i < 3*3; i++) r.e[i] = a.e[i] * scalar;
+            return r;
+        }
+        ZPL_INLINE zpl_mat3 operator*(float scalar, zpl_mat3 const &a) { return operator*(a, scalar); }
+        ZPL_INLINE zpl_mat3 operator/(zpl_mat3 const &a, float scalar) { return operator*(a, 1.0f/scalar); }
+
+        ZPL_INLINE zpl_mat3& operator+=(zpl_mat3& a, zpl_mat3 const &b) { return (a = a + b); }
+        ZPL_INLINE zpl_mat3& operator-=(zpl_mat3& a, zpl_mat3 const &b) { return (a = a - b); }
+        ZPL_INLINE zpl_mat3& operator*=(zpl_mat3& a, zpl_mat3 const &b) { return (a = a * b); }
+
+
+
+        ZPL_INLINE zpl_mat4 operator+(zpl_mat4 const &a, zpl_mat4 const &b) {
+            int i, j;
+            zpl_mat4 r = {0};
+            for (j = 0; j < 4; j++) {
+                for (i = 0; i < 4; i++)
+                    r.e[4*j+i] = a.e[4*j+i] + b.e[4*j+i];
+            }
+            return r;
+        }
+
+        ZPL_INLINE zpl_mat4 operator-(zpl_mat4 const &a, zpl_mat4 const &b) {
+            int i, j;
+            zpl_mat4 r = {0};
+            for (j = 0; j < 4; j++) {
+                for (i = 0; i < 4; i++)
+                    r.e[4*j+i] = a.e[4*j+i] - b.e[4*j+i];
+            }
+            return r;
+        }
+
+        ZPL_INLINE zpl_mat4 operator*(zpl_mat4 const &a, zpl_mat4 const &b) { zpl_mat4 r; zpl_mat4_mul(&r, (zpl_mat4 *)&a, (zpl_mat4 *)&b); return r; }
+        ZPL_INLINE zpl_vec4 operator*(zpl_mat4 const &a, zpl_vec4 v) { zpl_vec4 r; zpl_mat4_mul_vec4(&r, (zpl_mat4 *)&a, v); return r; }
+        ZPL_INLINE zpl_mat4 operator*(zpl_mat4 const &a, float scalar) {
+            zpl_mat4 r = {0};
+            int i;
+            for (i = 0; i < 4*4; i++) r.e[i] = a.e[i] * scalar;
+            return r;
+        }
+        ZPL_INLINE zpl_mat4 operator*(float scalar, zpl_mat4 const &a) { return operator*(a, scalar); }
+        ZPL_INLINE zpl_mat4 operator/(zpl_mat4 const &a, float scalar) { return operator*(a, 1.0f/scalar); }
+
+        ZPL_INLINE zpl_mat4& operator+=(zpl_mat4 &a, zpl_mat4 const &b) { return (a = a + b); }
+        ZPL_INLINE zpl_mat4& operator-=(zpl_mat4 &a, zpl_mat4 const &b) { return (a = a - b); }
+        ZPL_INLINE zpl_mat4& operator*=(zpl_mat4 &a, zpl_mat4 const &b) { return (a = a * b); }
+
+
+
+        ZPL_INLINE bool operator==(zpl_quat a, zpl_quat b) { return a.xyzw == b.xyzw; }
+        ZPL_INLINE bool operator!=(zpl_quat a, zpl_quat b) { return !operator==(a, b); }
+
+        ZPL_INLINE zpl_quat operator+(zpl_quat q) { return q; }
+        ZPL_INLINE zpl_quat operator-(zpl_quat q) { return zpl_quatf(-q.x, -q.y, -q.z, -q.w); }
+
+        ZPL_INLINE zpl_quat operator+(zpl_quat a, zpl_quat b) { zpl_quat r; zpl_quat_add(&r, a, b); return r; }
+        ZPL_INLINE zpl_quat operator-(zpl_quat a, zpl_quat b) { zpl_quat r; zpl_quat_sub(&r, a, b); return r; }
+
+        ZPL_INLINE zpl_quat operator*(zpl_quat a, zpl_quat b)  { zpl_quat r; zpl_quat_mul(&r, a, b); return r; }
+        ZPL_INLINE zpl_quat operator*(zpl_quat q, float s) { zpl_quat r; zpl_quat_mulf(&r, q, s); return r; }
+        ZPL_INLINE zpl_quat operator*(float s, zpl_quat q) { return operator*(q, s); }
+        ZPL_INLINE zpl_quat operator/(zpl_quat q, float s) { zpl_quat r; zpl_quat_divf(&r, q, s); return r; }
+
+        ZPL_INLINE zpl_quat &operator+=(zpl_quat &a, zpl_quat b) { zpl_quat_addeq(&a, b); return a; }
+        ZPL_INLINE zpl_quat &operator-=(zpl_quat &a, zpl_quat b) { zpl_quat_subeq(&a, b); return a; }
+        ZPL_INLINE zpl_quat &operator*=(zpl_quat &a, zpl_quat b) { zpl_quat_muleq(&a, b); return a; }
+        ZPL_INLINE zpl_quat &operator/=(zpl_quat &a, zpl_quat b) { zpl_quat_diveq(&a, b); return a; }
+
+        ZPL_INLINE zpl_quat &operator*=(zpl_quat &a, float b) { zpl_quat_muleqf(&a, b); return a; }
+        ZPL_INLINE zpl_quat &operator/=(zpl_quat &a, float b) { zpl_quat_diveqf(&a, b); return a; }
+
+        /* Rotate v by a */
+        ZPL_INLINE zpl_vec3 operator*(zpl_quat q, zpl_vec3 v) { zpl_vec3 r; zpl_quat_rotate_vec3(&r, q, v); return r; }
+    #endif
+#endif
+
+#if defined(ZPL_MODULE_JSON)
+    // file: header/json.h
+
+    /** @file json.c
+    @brief JSON5 Parser/Writer
+    @defgroup json JSON5 parser/writer
+
+    Easy to use and very fast JSON5 parser that can easily load 50 megabytes of JSON content under half a second. It also contains simple JSON5 writer and acts as a good library for handling config files. The parser also supports the **Simplified JSON (SJSON)** format.
+
+    We can parse JSON5 files in two different modes:
+        @n 1) Fast way (useful for raw data), which can not handle comments and might cause parsing failure if comment is present.
+        @n 2) Slower way (useful for config files), which handles comments perfectly but **might** have performance impact
+            on bigger JSON files. (+50MiB)
+    @{
+    */
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    //! Debug mode
+
+    #ifdef ZPL_JSON_DEBUG
+    #define ZPL_JSON_ASSERT ZPL_ASSERT(0)
+    #else
+    #define ZPL_JSON_ASSERT
+    #endif
+
+    //! JSON object types
+    typedef enum zpl_json_type {
+        ZPL_JSON_TYPE_OBJECT,
+        ZPL_JSON_TYPE_STRING,
+        ZPL_JSON_TYPE_MULTISTRING,
+        ZPL_JSON_TYPE_ARRAY,
+        ZPL_JSON_TYPE_INTEGER,
+        ZPL_JSON_TYPE_REAL,
+        ZPL_JSON_TYPE_CONSTANT
+    } zpl_json_type;
+
+    //! Field value properties
+    typedef enum zpl_json_props {
+        ZPL_JSON_PROPS_NONE         = 0,
+        ZPL_JSON_PROPS_NAN          = 1,
+        ZPL_JSON_PROPS_NAN_NEG      = 2,
+        ZPL_JSON_PROPS_INFINITY     = 3,
+        ZPL_JSON_PROPS_INFINITY_NEG = 4,
+        ZPL_JSON_PROPS_IS_EXP       = 5,
+        ZPL_JSON_PROPS_IS_HEX       = 6,
+
+        // Used internally so that people can fill in real numbers for JSON files they plan to write.
+        ZPL_JSON_PROPS_IS_PARSED_REAL = 7,
+    } zpl_json_props;
+
+    //! Value constants
+    typedef enum zpl_json_const {
+        ZPL_JSON_CONST_FALSE,
+        ZPL_JSON_CONST_TRUE,
+        ZPL_JSON_CONST_NULL,
+    } zpl_json_const;
+
+    // TODO(ZaKlaus): Error handling
+    //! Parser error types
+    typedef enum zpl_json_error {
+        ZPL_JSON_ERROR_NONE,
+        ZPL_JSON_ERROR_INVALID_NAME,
+        ZPL_JSON_ERROR_INVALID_VALUE,
+        ZPL_JSON_ERROR_OBJECT_OR_SOURCE_WAS_NULL,
+    } zpl_json_error;
+
+    //! Field name decoration style
+    typedef enum zpl_json_naming_style {
+        ZPL_JSON_NAME_STYLE_DOUBLE_QUOTE,
+        ZPL_JSON_NAME_STYLE_SINGLE_QUOTE,
+        ZPL_JSON_NAME_STYLE_NO_QUOTES,
+    } zpl_json_naming_style;
+
+    //! Field value assign style
+    typedef enum zpl_json_assign_style {
+        ZPL_JSON_ASSIGN_STYLE_COLON,
+        ZPL_JSON_ASSIGN_STYLE_EQUALS,
+        ZPL_JSON_ASSIGN_STYLE_LINE,
+    } zpl_json_assign_style;
+
+    //! Field delimiter style
+    typedef enum zpl_json_delim_style {
+        ZPL_JSON_DELIM_STYLE_COMMA,
+        ZPL_JSON_DELIM_STYLE_LINE,
+        ZPL_JSON_DELIM_STYLE_NEWLINE,
+    } zpl_json_delim_style;
+
+    #define zpl_json_object zpl_json_object
+
+    //! JSON object definition.
+    typedef struct zpl_json_object {
+        zpl_allocator backing;
+        char *name;
+        zpl_u8 type        :6;
+        zpl_u8 name_style  :2;
+        zpl_u8 props       :7;
+        zpl_u8 cfg_mode    :1;
+        zpl_u8 assign_style:4;
+        zpl_u8 delim_style :4;
+        zpl_u8 delim_line_width;
+
+        union {
+            struct zpl_json_object *nodes;  ///< zpl_array
+            zpl_i64 integer;
+            char *string;
+
+            struct {
+                zpl_f64 real;
+                zpl_i32 base;
+                zpl_i32 base2;
+                zpl_i32 base2_offset;
+                zpl_i32 exp;
+                zpl_u8 exp_neg   :1;
+                zpl_u8 lead_digit:1;
+            };
+            zpl_u8 constant;
+        };
+    } zpl_json_object;
+
+    //! Parses JSON5/SJSON text.
+
+    //! This method takes text form of JSON document as a source and parses its contents into JSON object structure we can work with. It also optionally handles comments that usually appear in documents used for configuration.
+    //! @param root JSON object we store data to.
+    //! @param len Text length. (reserved)
+    //! @param source Text to be processed. This string will be modified during the process!
+    //! @param allocator Memory allocator to use. (ex. zpl_heap())
+    //! @param handle_comments Whether to handle possible comments or not. Note that if we won't handle comments in a document containing them, the parser will error out. See remark in source code.
+    //! @param err_code Variable we will store error code in.
+    ZPL_DEF void zpl_json_parse(zpl_json_object *root, zpl_usize len, char *source, zpl_allocator allocator, zpl_b32 handle_comments,
+                                zpl_u8 *err_code);
+
+    //! Exports JSON5 document into text form and outputs it into a file.
+
+    //! This method takes JSON object tree and exports it into valid JSON5 form with the support of various styles that were preserved during import or set up programatically.
+    //! @param file File we write text to.
+    //! @param obj JSON object we export data from.
+    //! @param indent Text indentation used during export. Use 0 for root objects.
+    ZPL_DEF void zpl_json_write(zpl_file *file, zpl_json_object *obj, zpl_isize indent);
+
+    //! Exports JSON5 document into text form and returns a zpl_string
+
+    //! This method takes JSON object tree and exports it into valid JSON5 form with the support of various styles that were preserved during import or set up programatically.
+    //! @param obj JSON object we export data from.
+    //! @param indent Text indentation used during export. Use 0 for root objects.
+    //! @return zpl_string
+    ZPL_DEF zpl_string zpl_json_write_string(zpl_allocator a, zpl_json_object *obj, zpl_isize indent);
+
+    //! Releases used resources by a JSON object.
+
+    //! @param obj JSON object to free.
+    ZPL_DEF void zpl_json_free(zpl_json_object *obj);
+
+    //! Searches for a JSON node within a document by its name.
+
+    //! @param obj JSON object to search in.
+    //! @param name JSON node's name to search for.
+    //! @param deep_search Perform the search recursively.
+    ZPL_DEF zpl_json_object *zpl_json_find(zpl_json_object *obj, char const *name, zpl_b32 deep_search);
+
+    //! Initializes a JSON node.
+
+    //! @param obj JSON node to initialize.
+    //! @param backing Memory allocator to use (ex. zpl_heap())
+    //! @param name JSON node's name.
+    //! @param type JSON node's type. (See zpl_json_type)
+    //! @see zpl_json_type
+    ZPL_DEF void zpl_json_init_node(zpl_json_object *obj, zpl_allocator backing, char const *name, zpl_u8 type);
+
+    //! Adds object into JSON document at a specific index.
+
+    //! Initializes and adds a JSON object into a JSON document at a specific index.
+    //! @param obj Root node to add to.
+    //! @param index Index to store at.
+    //! @param name JSON node's name.
+    //! @param type JSON node's type. (See zpl_json_type)
+    //! @see zpl_json_type
+    ZPL_DEF zpl_json_object *zpl_json_add_at(zpl_json_object *obj, zpl_isize index, char const *name, zpl_u8 type);
+
+    //! Appends object into JSON document.
+
+    //! Initializes and appends a JSON object into a JSON document.
+    //! @param obj Root node to add to.
+    //! @param name JSON node's name.
+    //! @param type JSON node's type. (See zpl_json_type)
+    //! @see zpl_json_type
+    ZPL_DEF zpl_json_object *zpl_json_add(zpl_json_object *obj, char const *name, zpl_u8 type);
+
+    //! @}
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_THREADING)
+    #if defined(ZPL_SYSTEM_UNIX) || defined(ZPL_SYSTEM_MACOS)
+        #include <pthread.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        #if !defined(ZPL_NO_WINDOWS_H)
+            #ifndef WIN32_LEAN_AND_MEAN
+                #define NOMINMAX
+                #define WIN32_LEAN_AND_MEAN
+                #define WIN32_MEAN_AND_LEAN
+                #define VC_EXTRALEAN
+            #endif
+            #include <windows.h>
+            #undef NOMINMAX
+            #undef WIN32_LEAN_AND_MEAN
+            #undef WIN32_MEAN_AND_LEAN
+            #undef VC_EXTRALEAN
+
+            /* prevent it from including later */
+            #define ZPL_NO_WINDOWS_H
+        #endif
+
+        // include errno.h for MinGW
+        #if defined(ZPL_COMPILER_GCC)
+            #include <errno.h>
+        #endif
+    #endif
+
+    #if !defined(zpl_thread_local)
+        #if defined(_MSC_VER) && _MSC_VER >= 1300
+            #define zpl_thread_local __declspec(thread)
+        #elif defined(__GNUC__)
+            #define zpl_thread_local __thread
+        #else
+            #define zpl_thread_local thread_local
+        #endif
+    #endif
+
+    // file: header/threading/atomic.h
+
+    // Atomics
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    // TODO: Be specific with memory order?
+    // e.g. relaxed, acquire, release, acquire_release
+
+    #if !defined(__cplusplus) && !defined(ZPL_COMPILER_MSVC)
+    # include <stdatomic.h>
+    # define zpl_atomic(X) volatile _Atomic(X)
+    #else
+    // TODO: Fix once C++ guys bother to add C atomics to std.
+    //# include <atomic>
+    # define zpl_atomic(X) volatile X /*std::atomic<X>*/
+    #endif
+
+    #define zpl_atomicarg(X) volatile X
+
+    ZPL_BEGIN_C_DECLS
+
+    #if defined(ZPL_COMPILER_MSVC)
+        typedef struct zpl_atomic32  { zpl_atomic(zpl_i32) value; } zpl_atomic32;
+        typedef struct zpl_atomic64  { zpl_atomic(zpl_i64) value; } zpl_atomic64;
+        typedef struct zpl_atomic_ptr { zpl_atomic(void*) value; } zpl_atomic_ptr;
+    #else
+        #if defined(ZPL_ARCH_32_BIT)
+            #define ZPL_ATOMIC_PTR_ALIGNMENT 4
+        #elif defined(ZPL_ARCH_64_BIT)
+            #define ZPL_ATOMIC_PTR_ALIGNMENT 8
+        #else
+            #error Unknown architecture
+        #endif
+
+        typedef struct zpl_atomic32   { zpl_atomic(zpl_i32) value; } __attribute__ ((aligned(4))) zpl_atomic32;
+        typedef struct zpl_atomic64   { zpl_atomic(zpl_i64) value; } __attribute__ ((aligned(8))) zpl_atomic64;
+        typedef struct zpl_atomic_ptr { zpl_atomic(void*) value; }     __attribute__ ((aligned(ZPL_ATOMIC_PTR_ALIGNMENT))) zpl_atomic_ptr;
+    #endif
+
+    ZPL_DEF zpl_i32  zpl_atomic32_load            (zpl_atomic32 const *a);
+    ZPL_DEF void     zpl_atomic32_store           (zpl_atomic32 *a, zpl_atomicarg(zpl_i32) value);
+    ZPL_DEF zpl_i32  zpl_atomic32_compare_exchange(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) expected, zpl_atomicarg(zpl_i32) desired);
+    ZPL_DEF zpl_i32  zpl_atomic32_exchange        (zpl_atomic32 *a, zpl_atomicarg(zpl_i32) desired);
+    ZPL_DEF zpl_i32  zpl_atomic32_fetch_add       (zpl_atomic32 *a, zpl_atomicarg(zpl_i32) operand);
+    ZPL_DEF zpl_i32  zpl_atomic32_fetch_and       (zpl_atomic32 *a, zpl_atomicarg(zpl_i32) operand);
+    ZPL_DEF zpl_i32  zpl_atomic32_fetch_or        (zpl_atomic32 *a, zpl_atomicarg(zpl_i32) operand);
+    ZPL_DEF zpl_b32  zpl_atomic32_spin_lock       (zpl_atomic32 *a, zpl_isize time_out); // NOTE: time_out = -1 as default
+    ZPL_DEF void     zpl_atomic32_spin_unlock     (zpl_atomic32 *a);
+    ZPL_DEF zpl_b32  zpl_atomic32_try_acquire_lock(zpl_atomic32 *a);
+
+
+    ZPL_DEF zpl_i64  zpl_atomic64_load            (zpl_atomic64 const *a);
+    ZPL_DEF void     zpl_atomic64_store           (zpl_atomic64 *a, zpl_atomicarg(zpl_i64) value);
+    ZPL_DEF zpl_i64  zpl_atomic64_compare_exchange(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) expected, zpl_atomicarg(zpl_i64) desired);
+    ZPL_DEF zpl_i64  zpl_atomic64_exchange        (zpl_atomic64 *a, zpl_atomicarg(zpl_i64) desired);
+    ZPL_DEF zpl_i64  zpl_atomic64_fetch_add       (zpl_atomic64 *a, zpl_atomicarg(zpl_i64) operand);
+    ZPL_DEF zpl_i64  zpl_atomic64_fetch_and       (zpl_atomic64 *a, zpl_atomicarg(zpl_i64) operand);
+    ZPL_DEF zpl_i64  zpl_atomic64_fetch_or        (zpl_atomic64 *a, zpl_atomicarg(zpl_i64) operand);
+    ZPL_DEF zpl_b32  zpl_atomic64_spin_lock       (zpl_atomic64 *a, zpl_isize time_out); // NOTE: time_out = -1 as default
+    ZPL_DEF void     zpl_atomic64_spin_unlock     (zpl_atomic64 *a);
+    ZPL_DEF zpl_b32  zpl_atomic64_try_acquire_lock(zpl_atomic64 *a);
+
+
+    ZPL_DEF void *zpl_atomic_ptr_load            (zpl_atomic_ptr const *a);
+    ZPL_DEF void      zpl_atomic_ptr_store           (zpl_atomic_ptr *a, zpl_atomicarg(void *)value);
+    ZPL_DEF void *zpl_atomic_ptr_compare_exchange(zpl_atomic_ptr *a, zpl_atomicarg(void *)expected, zpl_atomicarg(void *)desired);
+    ZPL_DEF void *zpl_atomic_ptr_exchange        (zpl_atomic_ptr *a, zpl_atomicarg(void *)desired);
+    ZPL_DEF void *zpl_atomic_ptr_fetch_add       (zpl_atomic_ptr *a, zpl_atomicarg(void *)operand);
+    ZPL_DEF void *zpl_atomic_ptr_fetch_and       (zpl_atomic_ptr *a, zpl_atomicarg(void *)operand);
+    ZPL_DEF void *zpl_atomic_ptr_fetch_or        (zpl_atomic_ptr *a, zpl_atomicarg(void *)operand);
+    ZPL_DEF zpl_b32   zpl_atomic_ptr_spin_lock       (zpl_atomic_ptr *a, zpl_isize time_out); // NOTE: time_out = -1 as default
+    ZPL_DEF void      zpl_atomic_ptr_spin_unlock     (zpl_atomic_ptr *a);
+    ZPL_DEF zpl_b32   zpl_atomic_ptr_try_acquire_lock(zpl_atomic_ptr *a);
+
+    ZPL_END_C_DECLS
+    // file: header/threading/fence.h
+
+    // Fences
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    ZPL_DEF void zpl_yield_thread(void);
+    ZPL_DEF void zpl_mfence      (void);
+    ZPL_DEF void zpl_sfence      (void);
+    ZPL_DEF void zpl_lfence      (void);
+
+    ZPL_END_C_DECLS
+    // file: header/threading/sem.h
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #if defined(ZPL_SYSTEM_MACOS)
+        #include <mach/thread_act.h>
+    #elif defined(ZPL_SYSTEM_UNIX)
+        #include <semaphore.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        typedef struct zpl_semaphore { void *win32_handle; }     zpl_semaphore;
+    #elif defined(ZPL_SYSTEM_MACOS)
+        typedef struct zpl_semaphore { semaphore_t osx_handle; } zpl_semaphore;
+    #elif defined(ZPL_SYSTEM_UNIX)
+        typedef struct zpl_semaphore { sem_t unix_handle; }      zpl_semaphore;
+    #else
+        #error
+    #endif
+
+    ZPL_DEF void zpl_semaphore_init   (zpl_semaphore *s);
+    ZPL_DEF void zpl_semaphore_destroy(zpl_semaphore *s);
+    ZPL_DEF void zpl_semaphore_post   (zpl_semaphore *s, zpl_i32 count);
+    ZPL_DEF void zpl_semaphore_release(zpl_semaphore *s); // NOTE: zpl_semaphore_post(s, 1)
+    ZPL_DEF void zpl_semaphore_wait   (zpl_semaphore *s);
+
+    ZPL_END_C_DECLS
+    // file: header/threading/mutex.h
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef struct zpl_mutex {
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        CRITICAL_SECTION win32_critical_section;
+    #else
+        pthread_mutex_t pthread_mutex;
+    #endif
+    } zpl_mutex;
+
+    ZPL_DEF void     zpl_mutex_init    (zpl_mutex *m);
+    ZPL_DEF void     zpl_mutex_destroy (zpl_mutex *m);
+    ZPL_DEF void     zpl_mutex_lock    (zpl_mutex *m);
+    ZPL_DEF zpl_b32  zpl_mutex_try_lock(zpl_mutex *m);
+    ZPL_DEF void     zpl_mutex_unlock  (zpl_mutex *m);
+
+    ZPL_END_C_DECLS
+    // file: header/threading/thread.h
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #else
+    struct zpl_thread;
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef zpl_isize (*zpl_thread_proc)(struct zpl_thread *thread);
+
+    typedef struct zpl_thread {
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        void *        win32_handle;
+    #else
+        pthread_t     posix_handle;
+    #endif
+
+        zpl_thread_proc  proc;
+        void *           user_data;
+        zpl_isize        user_index;
+        zpl_isize        return_value;
+
+        zpl_semaphore    semaphore;
+        zpl_isize        stack_size;
+        zpl_b32          is_running;
+    } zpl_thread;
+
+    ZPL_DEF void     zpl_thread_init            (zpl_thread *t);
+    ZPL_DEF void     zpl_thread_destroy         (zpl_thread *t);
+    ZPL_DEF void     zpl_thread_start           (zpl_thread *t, zpl_thread_proc proc, void *data);
+    ZPL_DEF void     zpl_thread_start_with_stack(zpl_thread *t, zpl_thread_proc proc, void *data, zpl_isize stack_size);
+    ZPL_DEF void     zpl_thread_join            (zpl_thread *t);
+    ZPL_DEF zpl_b32  zpl_thread_is_running      (zpl_thread const *t);
+    ZPL_DEF zpl_u32  zpl_thread_current_id      (void);
+    ZPL_DEF void     zpl_thread_set_name        (zpl_thread *t, char const *name);
+
+    ZPL_END_C_DECLS
+    // file: header/threading/sync.h
+
+    // NOTE: Thread Merge Operation
+    // Based on Sean Barrett's stb_sync
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef struct zpl_sync {
+        zpl_i32 target;  // Target Number of threads
+        zpl_i32 current; // Threads to hit
+        zpl_i32 waiting; // Threads waiting
+
+        zpl_mutex start;
+        zpl_mutex mutex;
+        zpl_semaphore release;
+    } zpl_sync;
+
+    ZPL_DEF void     zpl_sync_init          (zpl_sync *s);
+    ZPL_DEF void     zpl_sync_destroy       (zpl_sync *s);
+    ZPL_DEF void     zpl_sync_set_target    (zpl_sync *s, zpl_i32 count);
+    ZPL_DEF void     zpl_sync_release       (zpl_sync *s);
+    ZPL_DEF zpl_i32  zpl_sync_reach         (zpl_sync *s);
+    ZPL_DEF void     zpl_sync_reach_and_wait(zpl_sync *s);
+
+    ZPL_END_C_DECLS
+    // file: header/threading/affinity.h
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #if defined(ZPL_SYSTEM_WINDOWS) || defined (ZPL_SYSTEM_CYGWIN)
+
+        typedef struct zpl_affinity {
+            zpl_b32   is_accurate;
+            zpl_isize core_count;
+            zpl_isize thread_count;
+
+        #define ZPL_WIN32_MAX_THREADS (8 * zpl_size_of(zpl_usize))
+            zpl_usize core_masks[ZPL_WIN32_MAX_THREADS];
+        } zpl_affinity;
+
+    #elif defined(ZPL_SYSTEM_OSX)
+
+        typedef struct zpl_affinity {
+            zpl_b32   is_accurate;
+            zpl_isize core_count;
+            zpl_isize thread_count;
+            zpl_isize threads_per_core;
+        } zpl_affinity;
+
+    #elif defined(ZPL_SYSTEM_LINUX) || defined(ZPL_SYSTEM_FREEBSD) || defined(ZPL_SYSTEM_EMSCRIPTEN) || defined(ZPL_SYSTEM_OPENBSD)
+
+        typedef struct zpl_affinity {
+            zpl_b32   is_accurate;
+            zpl_isize core_count;
+            zpl_isize thread_count;
+            zpl_isize threads_per_core;
+        } zpl_affinity;
+
+    #else
+        #error TODO: Unknown system
+    #endif
+
+    ZPL_DEF void      zpl_affinity_init   (zpl_affinity *a);
+    ZPL_DEF void      zpl_affinity_destroy(zpl_affinity *a);
+    ZPL_DEF zpl_b32   zpl_affinity_set    (zpl_affinity *a, zpl_isize core, zpl_isize thread);
+    ZPL_DEF zpl_isize zpl_affinity_thread_count_for_core(zpl_affinity *a, zpl_isize core);
+
+    ZPL_END_C_DECLS
+
+    #if defined(ZPL_MODULE_JOBS)
+        // file: header/jobs.h
+
+        /** @file threadpool.c
+        @brief Job system
+        @defgroup jobs Job system
+
+         This job system follows thread pool pattern to minimize the costs of thread initialization.
+         It reuses fixed number of threads to process variable number of jobs.
+
+         @{
+         */
+        #ifdef ZPL_EDITOR
+        #include <zpl.h>
+        #endif
+
+        ZPL_BEGIN_C_DECLS
+
+        typedef void (*zpl_jobs_proc)(void *data);
+
+        #define ZPL_INVALID_JOB ZPL_U32_MAX
+
+        typedef enum {
+            ZPL_JOBS_STATUS_READY,
+            ZPL_JOBS_STATUS_BUSY,
+            ZPL_JOBS_STATUS_WAITING,
+            ZPL_JOBS_STATUS_TERM,
+        } zpl_jobs_status;
+
+        typedef struct {
+            zpl_jobs_proc proc;
+            void *data;
+
+            zpl_f32 priority;
+        } zpl_thread_job;
+
+        typedef struct {
+            zpl_thread thread;
+            zpl_atomic32 status;
+            zpl_u32 jobid;
+            void *pool;
+        } zpl_thread_worker;
+
+        typedef struct {
+            zpl_allocator alloc;
+            zpl_u32 max_threads;
+            zpl_f32 job_spawn_treshold;
+            zpl_mutex access;
+            zpl_thread_worker *workers; ///< zpl_buffer
+            zpl_thread_job *jobs; ///< zpl_array
+            zpl_u32 *queue; ///< zpl_array
+            zpl_u32 *available; ///< zpl_array
+        } zpl_thread_pool;
+
+        //! Initialize thread pool with specified amount of fixed threads.
+        ZPL_DEF void    zpl_jobs_init(zpl_thread_pool *pool, zpl_allocator a, zpl_u32 max_threads);
+
+        //! Release the resources use by thread pool.
+        ZPL_DEF void    zpl_jobs_free(zpl_thread_pool *pool);
+
+        //! Enqueue a job with specified data.
+        ZPL_DEF void    zpl_jobs_enqueue(zpl_thread_pool *pool, zpl_jobs_proc proc, void *data);
+
+        //! Enqueue a job with specific priority with specified data.
+        ZPL_DEF void    zpl_jobs_enqueue_with_priority(zpl_thread_pool *pool, zpl_jobs_proc proc, void *data, zpl_f32 priority);
+
+        //! Process all jobs and check all threads. Should be called by Main Thread in a tight loop.
+        ZPL_DEF zpl_b32 zpl_jobs_process(zpl_thread_pool *pool);
+
+        ZPL_END_C_DECLS
+    #endif
+
+    #if defined(ZPL_MODULE_COROUTINES)
+        // file: header/coroutines.h
+
+        /** @file coroutines.c
+        @brief Coroutines module
+        @defgroup misc Coroutines module
+
+         This module implements co-routines feature for C99.
+
+         @{
+         */
+        /*
+           See test/coroutines.c for an example usage
+         */
+        #ifdef ZPL_EDITOR
+        #include <zpl.h>
+        #endif
+
+        ZPL_BEGIN_C_DECLS
+
+        #ifndef ZPL_CO_ARG_STACK_CAPACITY
+        #define ZPL_CO_ARG_STACK_CAPACITY 128
+        #endif
+
+        typedef enum {
+            ZPL_CO_READY,
+            ZPL_CO_ENQUEUED,
+            ZPL_CO_RUNNING,
+            ZPL_CO_WAITING,
+            ZPL_CO_DEAD,
+        } zpl_co_status;
+
+        struct zpl_co;
+
+        typedef void (*zpl_co_proc)(struct zpl_co *co);
+
+        typedef struct zpl_co {
+            zpl_atomic32  status;
+            zpl_co_proc   f;
+            void         *data; // overwritten internally, use inside of co-routines
+            void         *data_stack[ZPL_CO_ARG_STACK_CAPACITY];
+            zpl_i32       data_read_idx, data_write_idx;
+            zpl_atomic32  resume, push_arg;
+        } zpl_co;
+
+        // These methods are used to initialize the co-routine subsystem
+
+        /**
+         * Initializes the coroutines subsystem
+         * @param  a           Memory allocator to be used
+         * @param  max_threads Maximum amount of threads to use for coroutines execution
+         */
+        ZPL_DEF void   zpl_co_init(zpl_allocator a, zpl_u32 max_threads);
+
+        /**
+         * Destroys the coroutines subsystem
+         *
+         * IMPORTANT: This is a blocking method that waits until all the coroutines are finished.
+         * Please, make sure your coroutines are correctly designed, so that you
+         * won't end up in an infinite loop.
+         */
+        ZPL_DEF void   zpl_co_destroy(void);
+
+        // These methods are used by the host to create and run/resume co-routines
+        // Make sure the co-routine subsystem is initialized first!
+
+        /**
+         * Create a paused coroutine
+         * @param  co Coroutine reference
+         * @param  f  Coroutine method
+         */
+        ZPL_DEF void zpl_co_make(zpl_co *co, zpl_co_proc f);
+
+        /**
+         * Starts/Resumes a coroutine execution.
+         *
+         * IMPORTANT: Data you pass is stored in a stack of up to ZPL_CO_ARG_STACK_CAPACITY.
+         * This means that you can cause stack corruption if you
+         * call 'zpl_co_resume' with data passed (ZPL_CO_ARG_STACK_CAPACITY+1) times.
+         * Raise the number by defining ZPL_CO_ARG_STACK_CAPACITY if required.
+         *
+         * @param  co   Coroutine
+         * @param  data Data we want to pass (or NULL)
+         */
+        ZPL_DEF void    zpl_co_resume(zpl_co *co, void *data);
+
+        /**
+         * Is a coroutine running at the moment?
+         * @param  co Coroutine
+         * @return
+         */
+        ZPL_DEF_INLINE zpl_b32 zpl_co_running(zpl_co *co);
+
+        /**
+         * Is a coroutine already finished?
+         * @param  co Coroutine
+         * @return
+         */
+        ZPL_DEF_INLINE zpl_b32 zpl_co_finished(zpl_co *co);
+
+        /**
+         * Is coroutine waiting? (in yield state)
+         * @param  co Coroutine
+         * @return
+         */
+        ZPL_DEF_INLINE zpl_b32 zpl_co_waiting(zpl_co *co);
+
+        // This method is used by the co-routine to await execution
+        //
+
+        /**
+         * Yield the coroutine.
+         *
+         * IMPORTANT: Only to be used by the coroutine!!
+         * @param  co Coroutine
+         */
+        ZPL_DEF void   zpl_co_yield(zpl_co *co);
+
+        //! @}
+
+        ZPL_IMPL_INLINE zpl_b32 zpl_co_running(zpl_co *co) {
+            return zpl_atomic32_load(&co->status) == ZPL_CO_RUNNING;
+        }
+
+        ZPL_IMPL_INLINE zpl_b32 zpl_co_finished(zpl_co *co) {
+            return zpl_atomic32_load(&co->status) == ZPL_CO_DEAD;
+        }
+
+        ZPL_IMPL_INLINE zpl_b32 zpl_co_waiting(zpl_co *co) {
+            return zpl_atomic32_load(&co->resume) == 0;
+        }
+
+        ZPL_END_C_DECLS
+    #endif
+#endif
+
+#if defined(ZPL_COMPILER_MSVC)
+    #pragma warning(pop)
+#endif
+
+#if defined(__GCC__) || defined(__GNUC__) || defined(__clang__)
+    #pragma GCC diagnostic pop
+#endif
+
+#if defined(ZPL_IMPLEMENTATION) && !defined(ZPL_IMPLEMENTATION_DONE)
+#define ZPL_IMPLEMENTATION_DONE
+
+#if defined(__GCC__) || defined(__GNUC__) || defined(__clang__)
+    #pragma GCC diagnostic push
+    #pragma GCC diagnostic ignored "-Wattributes"
+    #pragma GCC diagnostic ignored "-Wunused-value"
+    #pragma GCC diagnostic ignored "-Wunused-function"
+    #pragma GCC diagnostic ignored "-Wwrite-strings"
+    #pragma GCC diagnostic ignored "-Wunused-parameter"
+    #pragma GCC diagnostic ignored "-Wdeprecated-declarations"
+    #pragma GCC diagnostic ignored "-Wmissing-braces"
+    #pragma GCC diagnostic ignored "-Wmissing-field-initializers"
+    #pragma GCC diagnostic ignored "-Wimplicit-fallthrough"
+#endif
+
+#if defined(_MSC_VER)
+    #pragma warning(push)
+    #pragma warning(disable : 4201)
+    #pragma warning(disable : 4996) // Disable deprecated POSIX functions warning
+    #pragma warning(disable : 4127) // Conditional expression is constant
+#endif
+
+/* general purpose includes */
+
+#include <stdio.h>
+
+#if defined(ZPL_SYSTEM_UNIX) || defined(ZPL_SYSTEM_MACOS)
+    #include <unistd.h>
+    #include <errno.h>
+#elif defined(ZPL_SYSTEM_WINDOWS)
+    #if !defined(ZPL_NO_WINDOWS_H)
+        #ifndef WIN32_LEAN_AND_MEAN
+            #ifndef NOMINMAX
+            #define NOMINMAX
+            #endif
+
+            #define WIN32_LEAN_AND_MEAN
+            #define WIN32_MEAN_AND_LEAN
+            #define VC_EXTRALEAN
+        #endif
+        #include <windows.h>
+        #undef NOMINMAX
+        #undef WIN32_LEAN_AND_MEAN
+        #undef WIN32_MEAN_AND_LEAN
+        #undef VC_EXTRALEAN
+    #endif
+#endif
+
+#if defined(ZPL_MODULE_CORE)
+    // file: source/core/debug.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    void zpl_assert_handler(char const *condition, char const *file, zpl_i32 line, char const *msg, ...) {
+        zpl_printf_err("%s:(%d): Assert Failure: ", file, line);
+
+        if (condition) zpl_printf_err("`%s` ", condition);
+
+        if (msg) {
+            va_list va;
+            va_start(va, msg);
+            zpl_printf_err_va(msg, va);
+            va_end(va);
+        }
+
+        zpl_printf_err("\n");
+    }
+
+    zpl_i32 zpl_assert_crash(char const *condition) {
+        ZPL_PANIC(condition);
+        return 0;
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/memory.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    #include <string.h>
+
+    ZPL_BEGIN_C_DECLS
+
+
+    void zpl_memswap(void *i, void *j, zpl_isize size) {
+        if (i == j) return;
+
+        if (size == 4) {
+            zpl_swap(zpl_u32, *cast(zpl_u32 *) i, *cast(zpl_u32 *) j);
+        } else if (size == 8) {
+            zpl_swap(zpl_u64, *cast(zpl_u64 *) i, *cast(zpl_u64 *) j);
+        } else if (size < 8) {
+            zpl_u8 *a = cast(zpl_u8 *) i;
+            zpl_u8 *b = cast(zpl_u8 *) j;
+            if (a != b) {
+                while (size--) { zpl_swap(zpl_u8, *a++, *b++); }
+            }
+        } else {
+            char buffer[256];
+
+            while (size > zpl_size_of(buffer)) {
+                zpl_memswap(i, j, zpl_size_of(buffer));
+                i = zpl_pointer_add(i, zpl_size_of(buffer));
+                j = zpl_pointer_add(j, zpl_size_of(buffer));
+                size -= zpl_size_of(buffer);
+            }
+
+            zpl_memcopy(buffer, i, size);
+            zpl_memcopy(i, j, size);
+            zpl_memcopy(j, buffer, size);
+        }
+    }
+
+    void const *zpl_memchr(void const *data, zpl_u8 c, zpl_isize n) {
+        zpl_u8 const *s = cast(zpl_u8 const *) data;
+        while ((cast(zpl_uintptr) s & (sizeof(zpl_usize) - 1)) && n && *s != c) {
+            s++;
+            n--;
+        }
+        if (n && *s != c) {
+            zpl_isize const *w;
+            zpl_isize k = ZPL__ONES * c;
+            w = cast(zpl_isize const *) s;
+            while (n >= zpl_size_of(zpl_isize) && !ZPL__HAS_ZERO(*w ^ k)) {
+                w++;
+                n -= zpl_size_of(zpl_isize);
+            }
+            s = cast(zpl_u8 const *) w;
+            while (n && *s != c) {
+                s++;
+                n--;
+            }
+        }
+
+        return n ? cast(void const *) s : NULL;
+    }
+
+    void const *zpl_memrchr(void const *data, zpl_u8 c, zpl_isize n) {
+        zpl_u8 const *s = cast(zpl_u8 const *) data;
+        while (n--) {
+            if (s[n] == c) return cast(void const *)(s + n);
+        }
+        return NULL;
+    }
+
+    void *zpl_memcopy(void *dest, void const *source, zpl_isize n) {
+        if (dest == NULL) { return NULL; }
+
+        return memcpy(dest, source, n);
+
+        // TODO: Re-work the whole method
+    #if 0
+    #if defined(_MSC_VER)
+        __movsb(cast(zpl_u8 *) dest, cast(zpl_u8 *) source, n);
+    #elif defined(ZPL_CPU_X86) && !defined(ZPL_SYSTEM_EMSCRIPTEN)
+        zpl_u8 *__dest8 = cast(zpl_u8 *) dest;
+        zpl_u8 *__source8 = cast(zpl_u8 *) source;
+        __asm__ __volatile__("rep movsb" : "+D"(__dest8), "+S"(__source8), "+c"(n) : : "memory");
+    #elif defined(ZPL_CPU_ARM)
+        return memcpy(dest, source, n);
+    #else
+        zpl_u8 *d = cast(zpl_u8 *) dest;
+        zpl_u8 const *s = cast(zpl_u8 const *) source;
+        zpl_u32 w, x;
+
+        for (; cast(zpl_uintptr) s % 4 && n; n--) *d++ = *s++;
+
+        if (cast(zpl_uintptr) d % 4 == 0) {
+            for (; n >= 16; s += 16, d += 16, n -= 16) {
+                *cast(zpl_u32 *)(d + 0) = *cast(zpl_u32 *)(s + 0);
+                *cast(zpl_u32 *)(d + 4) = *cast(zpl_u32 *)(s + 4);
+                *cast(zpl_u32 *)(d + 8) = *cast(zpl_u32 *)(s + 8);
+                *cast(zpl_u32 *)(d + 12) = *cast(zpl_u32 *)(s + 12);
+            }
+            if (n & 8) {
+                *cast(zpl_u32 *)(d + 0) = *cast(zpl_u32 *)(s + 0);
+                *cast(zpl_u32 *)(d + 4) = *cast(zpl_u32 *)(s + 4);
+                d += 8;
+                s += 8;
+            }
+            if (n & 4) {
+                *cast(zpl_u32 *)(d + 0) = *cast(zpl_u32 *)(s + 0);
+                d += 4;
+                s += 4;
+            }
+            if (n & 2) {
+                *d++ = *s++;
+                *d++ = *s++;
+            }
+            if (n & 1) { *d = *s; }
+            return dest;
+        }
+
+        if (n >= 32) {
+    #if __BYTE_ORDER == __BIG_ENDIAN
+    #define LS <<
+    #define RS >>
+    #else
+    #define LS >>
+    #define RS <<
+    #endif
+            switch (cast(zpl_uintptr) d % 4) {
+                case 1: {
+                    w = *cast(zpl_u32 *) s;
+                    *d++ = *s++;
+                    *d++ = *s++;
+                    *d++ = *s++;
+                    n -= 3;
+                    while (n > 16) {
+                        x = *cast(zpl_u32 *)(s + 1);
+                        *cast(zpl_u32 *)(d + 0) = (w LS 24) | (x RS 8);
+                        w = *cast(zpl_u32 *)(s + 5);
+                        *cast(zpl_u32 *)(d + 4) = (x LS 24) | (w RS 8);
+                        x = *cast(zpl_u32 *)(s + 9);
+                        *cast(zpl_u32 *)(d + 8) = (w LS 24) | (x RS 8);
+                        w = *cast(zpl_u32 *)(s + 13);
+                        *cast(zpl_u32 *)(d + 12) = (x LS 24) | (w RS 8);
+
+                        s += 16;
+                        d += 16;
+                        n -= 16;
+                    }
+                } break;
+                case 2: {
+                    w = *cast(zpl_u32 *) s;
+                    *d++ = *s++;
+                    *d++ = *s++;
+                    n -= 2;
+                    while (n > 17) {
+                        x = *cast(zpl_u32 *)(s + 2);
+                        *cast(zpl_u32 *)(d + 0) = (w LS 16) | (x RS 16);
+                        w = *cast(zpl_u32 *)(s + 6);
+                        *cast(zpl_u32 *)(d + 4) = (x LS 16) | (w RS 16);
+                        x = *cast(zpl_u32 *)(s + 10);
+                        *cast(zpl_u32 *)(d + 8) = (w LS 16) | (x RS 16);
+                        w = *cast(zpl_u32 *)(s + 14);
+                        *cast(zpl_u32 *)(d + 12) = (x LS 16) | (w RS 16);
+
+                        s += 16;
+                        d += 16;
+                        n -= 16;
+                    }
+                } break;
+                case 3: {
+                    w = *cast(zpl_u32 *) s;
+                    *d++ = *s++;
+                    n -= 1;
+                    while (n > 18) {
+                        x = *cast(zpl_u32 *)(s + 3);
+                        *cast(zpl_u32 *)(d + 0) = (w LS 8) | (x RS 24);
+                        w = *cast(zpl_u32 *)(s + 7);
+                        *cast(zpl_u32 *)(d + 4) = (x LS 8) | (w RS 24);
+                        x = *cast(zpl_u32 *)(s + 11);
+                        *cast(zpl_u32 *)(d + 8) = (w LS 8) | (x RS 24);
+                        w = *cast(zpl_u32 *)(s + 15);
+                        *cast(zpl_u32 *)(d + 12) = (x LS 8) | (w RS 24);
+
+                        s += 16;
+                        d += 16;
+                        n -= 16;
+                    }
+                } break;
+                default: break; // NOTE: Do nowt!
+            }
+    #undef LS
+    #undef RS
+            if (n & 16) {
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+            }
+            if (n & 8) {
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+            }
+            if (n & 4) {
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+                *d++ = *s++;
+            }
+            if (n & 2) {
+                *d++ = *s++;
+                *d++ = *s++;
+            }
+            if (n & 1) { *d = *s; }
+        }
+
+    #endif
+    #endif
+
+        return dest;
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/memory_virtual.c
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Virtual Memory
+    //
+    //
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    zpl_virtual_memory zpl_vm(void *data, zpl_isize size) {
+        zpl_virtual_memory vm;
+        vm.data = data;
+        vm.size = size;
+        return vm;
+    }
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        zpl_virtual_memory zpl_vm_alloc(void *addr, zpl_isize size) {
+            zpl_virtual_memory vm;
+            ZPL_ASSERT(size > 0);
+            vm.data = VirtualAlloc(addr, size, MEM_COMMIT | MEM_RESERVE, PAGE_READWRITE);
+            vm.size = size;
+            return vm;
+        }
+
+        zpl_b32 zpl_vm_free(zpl_virtual_memory vm) {
+            MEMORY_BASIC_INFORMATION info;
+            while (vm.size > 0) {
+                if (VirtualQuery(vm.data, &info, zpl_size_of(info)) == 0) return false;
+                if (info.BaseAddress != vm.data || info.AllocationBase != vm.data || info.State != MEM_COMMIT ||
+                    info.RegionSize > cast(zpl_usize) vm.size) {
+                    return false;
+                }
+                if (VirtualFree(vm.data, 0, MEM_RELEASE) == 0) return false;
+                vm.data = zpl_pointer_add(vm.data, info.RegionSize);
+                vm.size -= info.RegionSize;
+            }
+            return true;
+        }
+
+        zpl_virtual_memory zpl_vm_trim(zpl_virtual_memory vm, zpl_isize lead_size, zpl_isize size) {
+            zpl_virtual_memory new_vm = { 0 };
+            void *ptr;
+            ZPL_ASSERT(vm.size >= lead_size + size);
+
+            ptr = zpl_pointer_add(vm.data, lead_size);
+
+            zpl_vm_free(vm);
+            new_vm = zpl_vm_alloc(ptr, size);
+            if (new_vm.data == ptr) return new_vm;
+            if (new_vm.data) zpl_vm_free(new_vm);
+            return new_vm;
+        }
+
+        zpl_b32 zpl_vm_purge(zpl_virtual_memory vm) {
+            VirtualAlloc(vm.data, vm.size, MEM_RESET, PAGE_READWRITE);
+            // NOTE: Can this really fail?
+            return true;
+        }
+
+        zpl_isize zpl_virtual_memory_page_size(zpl_isize *alignment_out) {
+            SYSTEM_INFO info;
+            GetSystemInfo(&info);
+            if (alignment_out) *alignment_out = info.dwAllocationGranularity;
+            return info.dwPageSize;
+        }
+
+    #else
+        #include <sys/mman.h>
+
+        #ifndef MAP_ANONYMOUS
+            #define MAP_ANONYMOUS MAP_ANON
+        #endif
+
+        zpl_virtual_memory zpl_vm_alloc(void *addr, zpl_isize size) {
+            zpl_virtual_memory vm;
+            ZPL_ASSERT(size > 0);
+            vm.data = mmap(addr, size, PROT_READ | PROT_WRITE, MAP_ANONYMOUS | MAP_PRIVATE, -1, 0);
+            vm.size = size;
+            return vm;
+        }
+
+        zpl_b32 zpl_vm_free(zpl_virtual_memory vm) {
+            munmap(vm.data, vm.size);
+            return true;
+        }
+
+        zpl_virtual_memory zpl_vm_trim(zpl_virtual_memory vm, zpl_isize lead_size, zpl_isize size) {
+            void *ptr;
+            zpl_isize trail_size;
+            ZPL_ASSERT(vm.size >= lead_size + size);
+
+            ptr = zpl_pointer_add(vm.data, lead_size);
+            trail_size = vm.size - lead_size - size;
+
+            if (lead_size != 0) zpl_vm_free(zpl_vm(vm.data, lead_size));
+            if (trail_size != 0) zpl_vm_free(zpl_vm(ptr, trail_size));
+            return zpl_vm(ptr, size);
+        }
+
+        zpl_b32 zpl_vm_purge(zpl_virtual_memory vm) {
+            int err = madvise(vm.data, vm.size, MADV_DONTNEED);
+            return err != 0;
+        }
+
+        zpl_isize zpl_virtual_memory_page_size(zpl_isize *alignment_out) {
+            // TODO: Is this always true?
+            zpl_isize result = cast(zpl_isize) sysconf(_SC_PAGE_SIZE);
+            if (alignment_out) *alignment_out = result;
+            return result;
+        }
+
+    #endif
+
+    ZPL_END_C_DECLS
+    // file: source/core/memory_custom.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    #ifndef _IOSC11_SOURCE
+    #define _IOSC11_SOURCE
+    #endif
+
+    #include <stdlib.h>
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        #include <malloc.h>
+    #endif
+
+    #if defined(ZPL_COMPILER_MINGW)
+        #ifdef __MINGW32__
+        #define _aligned_malloc __mingw_aligned_malloc
+        #define _aligned_free  __mingw_aligned_free
+        #endif //MINGW
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    char *zpl_alloc_str(zpl_allocator a, char const *str) {
+        return zpl_alloc_str_len(a, str, zpl_strlen(str));
+    }
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Custom Allocation
+    //
+    //
+
+    //
+    // Heap Allocator
+    //
+
+    ZPL_ALLOCATOR_PROC(zpl_heap_allocator_proc) {
+        void *ptr = NULL;
+        zpl_unused(allocator_data);
+        zpl_unused(old_size);
+        // TODO: Throughly test!
+        switch (type) {
+    #if defined(ZPL_COMPILER_MSVC) || (defined(ZPL_COMPILER_GCC) && defined(ZPL_SYSTEM_WINDOWS))
+            case ZPL_ALLOCATION_ALLOC:
+            ptr = _aligned_malloc(size, alignment);
+            if (flags & ZPL_ALLOCATOR_FLAG_CLEAR_TO_ZERO) zpl_zero_size(ptr, size);
+            break;
+            case ZPL_ALLOCATION_FREE: _aligned_free(old_memory); break;
+            case ZPL_ALLOCATION_RESIZE: ptr = _aligned_realloc(old_memory, size, alignment); break;
+
+    #elif defined(ZPL_SYSTEM_LINUX) && !defined(ZPL_CPU_ARM)
+            case ZPL_ALLOCATION_ALLOC: {
+                ptr = aligned_alloc(alignment, size);
+
+                if (flags & ZPL_ALLOCATOR_FLAG_CLEAR_TO_ZERO) { zpl_zero_size(ptr, size); }
+            } break;
+
+            case ZPL_ALLOCATION_FREE: {
+                free(old_memory);
+            } break;
+
+            case ZPL_ALLOCATION_RESIZE: {
+                zpl_allocator a = zpl_heap_allocator( );
+                ptr = zpl_default_resize_align(a, old_memory, old_size, size, alignment);
+            } break;
+    #else
+            case ZPL_ALLOCATION_ALLOC: {
+                posix_memalign(&ptr, alignment, size);
+
+                if (flags & ZPL_ALLOCATOR_FLAG_CLEAR_TO_ZERO) { zpl_zero_size(ptr, size); }
+            } break;
+
+            case ZPL_ALLOCATION_FREE: {
+                free(old_memory);
+            } break;
+
+            case ZPL_ALLOCATION_RESIZE: {
+                zpl_allocator a = zpl_heap_allocator( );
+                ptr = zpl_default_resize_align(a, old_memory, old_size, size, alignment);
+            } break;
+    #endif
+
+            case ZPL_ALLOCATION_FREE_ALL: break;
+        }
+
+        return ptr;
+    }
+
+    //
+    // Arena Allocator
+    //
+
+    ZPL_ALLOCATOR_PROC(zpl_arena_allocator_proc) {
+        zpl_arena *arena = cast(zpl_arena *) allocator_data;
+        void *ptr = NULL;
+
+        zpl_unused(old_size);
+
+        switch (type) {
+            case ZPL_ALLOCATION_ALLOC: {
+                void *end = zpl_pointer_add(arena->physical_start, arena->total_allocated);
+                zpl_isize total_size = size + alignment;
+
+                // NOTE: Out of memory
+                if (arena->total_allocated + total_size > cast(zpl_isize) arena->total_size) {
+                    zpl_printf_err("Arena out of memory\n");
+                    return NULL;
+                }
+
+                ptr = zpl_align_forward(end, alignment);
+                arena->total_allocated += total_size;
+                if (flags & ZPL_ALLOCATOR_FLAG_CLEAR_TO_ZERO) zpl_zero_size(ptr, size);
+            } break;
+
+            case ZPL_ALLOCATION_FREE:
+            // NOTE: Free all at once
+            // Use Temp_Arena_Memory if you want to free a block
+            break;
+
+            case ZPL_ALLOCATION_FREE_ALL: arena->total_allocated = 0; break;
+
+            case ZPL_ALLOCATION_RESIZE: {
+                // TODO: Check if ptr is on top of stack and just extend
+                zpl_allocator a = zpl_arena_allocator(arena);
+                ptr = zpl_default_resize_align(a, old_memory, old_size, size, alignment);
+            } break;
+        }
+        return ptr;
+    }
+
+    //
+    // Pool Allocator
+    //
+
+    void zpl_pool_init_align(zpl_pool *pool, zpl_allocator backing, zpl_isize num_blocks, zpl_isize block_size, zpl_isize block_align) {
+        zpl_isize actual_block_size, pool_size, block_index;
+        void *data, *curr;
+        zpl_uintptr *end;
+
+        zpl_zero_item(pool);
+
+        pool->backing = backing;
+        pool->block_size = block_size;
+        pool->block_align = block_align;
+        pool->num_blocks = num_blocks;
+
+        actual_block_size = block_size + block_align;
+        pool_size = num_blocks * actual_block_size;
+
+        data = zpl_alloc_align(backing, pool_size, block_align);
+
+        // NOTE: Init intrusive freelist
+        curr = data;
+        for (block_index = 0; block_index < num_blocks - 1; block_index++) {
+            zpl_uintptr *next = cast(zpl_uintptr *) curr;
+            *next = cast(zpl_uintptr) curr + actual_block_size;
+            curr = zpl_pointer_add(curr, actual_block_size);
+        }
+
+        end = cast(zpl_uintptr *) curr;
+        *end = cast(zpl_uintptr) NULL;
+
+        pool->physical_start = data;
+        pool->free_list = data;
+    }
+
+    ZPL_ALLOCATOR_PROC(zpl_pool_allocator_proc) {
+        zpl_pool *pool = cast(zpl_pool *) allocator_data;
+        void *ptr = NULL;
+
+        zpl_unused(old_size);
+
+        switch (type) {
+            case ZPL_ALLOCATION_ALLOC: {
+                zpl_uintptr next_free;
+                ZPL_ASSERT(size == pool->block_size);
+                ZPL_ASSERT(alignment == pool->block_align);
+                ZPL_ASSERT(pool->free_list != NULL);
+
+                next_free = *cast(zpl_uintptr *) pool->free_list;
+                ptr = pool->free_list;
+                pool->free_list = cast(void *) next_free;
+                pool->total_size += pool->block_size;
+                if (flags & ZPL_ALLOCATOR_FLAG_CLEAR_TO_ZERO) zpl_zero_size(ptr, size);
+            } break;
+
+            case ZPL_ALLOCATION_FREE: {
+                zpl_uintptr *next;
+                if (old_memory == NULL) return NULL;
+
+                next = cast(zpl_uintptr *) old_memory;
+                *next = cast(zpl_uintptr) pool->free_list;
+                pool->free_list = old_memory;
+                pool->total_size -= pool->block_size;
+            } break;
+
+            case ZPL_ALLOCATION_FREE_ALL: {
+                zpl_isize actual_block_size, block_index;
+                void *curr;
+                zpl_uintptr *end;
+
+                actual_block_size = pool->block_size + pool->block_align;
+                pool->total_size = 0;
+
+                // NOTE: Init intrusive freelist
+                curr = pool->physical_start;
+                for (block_index = 0; block_index < pool->num_blocks - 1; block_index++) {
+                    zpl_uintptr *next = cast(zpl_uintptr *) curr;
+                    *next = cast(zpl_uintptr) curr + actual_block_size;
+                    curr = zpl_pointer_add(curr, actual_block_size);
+                }
+
+                end = cast(zpl_uintptr *) curr;
+                *end = cast(zpl_uintptr) NULL;
+                pool->free_list = pool->physical_start;
+            } break;
+
+            case ZPL_ALLOCATION_RESIZE:
+            // NOTE: Cannot resize
+            ZPL_PANIC("You cannot resize something allocated by with a pool.");
+            break;
+        }
+
+        return ptr;
+    }
+
+
+    //
+    // Scratch Memory Allocator
+    //
+
+    void zpl_scratch_memory_init(zpl_scratch_memory *s, void *start, zpl_isize size) {
+        s->physical_start = start;
+        s->total_size = size;
+        s->alloc_point = start;
+        s->free_point = start;
+    }
+
+    zpl_b32 zpl_scratch_memory_is_in_use(zpl_scratch_memory *s, void *ptr) {
+        if (s->free_point == s->alloc_point) return false;
+        if (s->alloc_point > s->free_point) return ptr >= s->free_point && ptr < s->alloc_point;
+        return ptr >= s->free_point || ptr < s->alloc_point;
+    }
+
+    zpl_allocator zpl_scratch_allocator(zpl_scratch_memory *s) {
+        zpl_allocator a;
+        a.proc = zpl_scratch_allocator_proc;
+        a.data = s;
+        return a;
+    }
+
+    ZPL_ALLOCATOR_PROC(zpl_scratch_allocator_proc) {
+        zpl_scratch_memory *s = cast(zpl_scratch_memory *) allocator_data;
+        void *ptr = NULL;
+        ZPL_ASSERT_NOT_NULL(s);
+
+        switch (type) {
+            case ZPL_ALLOCATION_ALLOC: {
+                void *pt = s->alloc_point;
+                zpl_allocation_header_ev *header = cast(zpl_allocation_header_ev *) pt;
+                void *data = zpl_align_forward(header + 1, alignment);
+                void *end = zpl_pointer_add(s->physical_start, s->total_size);
+
+                ZPL_ASSERT(alignment % 4 == 0);
+                size = ((size + 3) / 4) * 4;
+                pt = zpl_pointer_add(pt, size);
+
+                // NOTE: Wrap around
+                if (pt > end) {
+                    header->size = zpl_pointer_diff(header, end) | ZPL_ISIZE_HIGH_BIT;
+                    pt = s->physical_start;
+                    header = cast(zpl_allocation_header_ev *) pt;
+                    data = zpl_align_forward(header + 1, alignment);
+                    pt = zpl_pointer_add(pt, size);
+                }
+
+                if (!zpl_scratch_memory_is_in_use(s, pt)) {
+                    zpl_allocation_header_fill(header, pt, zpl_pointer_diff(header, pt));
+                    s->alloc_point = cast(zpl_u8 *) pt;
+                    ptr = data;
+                }
+
+                if (flags & ZPL_ALLOCATOR_FLAG_CLEAR_TO_ZERO) zpl_zero_size(ptr, size);
+            } break;
+
+            case ZPL_ALLOCATION_FREE: {
+                if (old_memory) {
+                    void *end = zpl_pointer_add(s->physical_start, s->total_size);
+                    if (old_memory < s->physical_start || old_memory >= end) {
+                        ZPL_ASSERT(false);
+                    } else {
+                        // NOTE: Mark as free
+                        zpl_allocation_header_ev *h = zpl_allocation_header(old_memory);
+                        ZPL_ASSERT((h->size & ZPL_ISIZE_HIGH_BIT) == 0);
+                        h->size = h->size | ZPL_ISIZE_HIGH_BIT;
+
+                        while (s->free_point != s->alloc_point) {
+                            zpl_allocation_header_ev *header = cast(zpl_allocation_header_ev *) s->free_point;
+                            if ((header->size & ZPL_ISIZE_HIGH_BIT) == 0) break;
+
+                            s->free_point = zpl_pointer_add(s->free_point, h->size & (~ZPL_ISIZE_HIGH_BIT));
+                            if (s->free_point == end) s->free_point = s->physical_start;
+                        }
+                    }
+                }
+            } break;
+
+            case ZPL_ALLOCATION_FREE_ALL:
+            s->alloc_point = s->physical_start;
+            s->free_point = s->physical_start;
+            break;
+
+            case ZPL_ALLOCATION_RESIZE:
+            ptr = zpl_default_resize_align(zpl_scratch_allocator(s), old_memory, old_size, size, alignment);
+            break;
+        }
+
+        return ptr;
+    }
+
+    //
+    // Stack Memory Allocator
+    //
+    ZPL_ALLOCATOR_PROC(zpl_stack_allocator_proc) {
+        zpl_stack_memory *s = cast(zpl_stack_memory *) allocator_data;
+        void *ptr = NULL;
+        ZPL_ASSERT_NOT_NULL(s);
+        zpl_unused(old_size);
+        zpl_unused(flags);
+
+        switch (type) {
+            case ZPL_ALLOCATION_ALLOC: {
+                size += ZPL_STACK_ALLOC_OFFSET;
+                zpl_u64 alloc_offset = s->allocated;
+
+                void *curr =
+                    cast(zpl_u64 *) zpl_align_forward(cast(zpl_u64 *) zpl_pointer_add(s->physical_start, s->allocated), alignment);
+
+                if (cast(zpl_u64 *) zpl_pointer_add(curr, size) > cast(zpl_u64 *) zpl_pointer_add(s->physical_start, s->total_size)) {
+                    if (s->backing.proc) {
+                        void *old_start = s->physical_start;
+                        s->physical_start =
+                            zpl_resize_align(s->backing, s->physical_start, s->total_size, s->total_size + size, alignment);
+                        curr = cast(zpl_u64 *)
+                            zpl_align_forward(cast(zpl_u64 *) zpl_pointer_add(s->physical_start, s->allocated), alignment);
+                        s->total_size = zpl_pointer_diff(old_start, s->physical_start);
+                    } else {
+                        ZPL_PANIC("Can not resize stack's memory! Allocator not defined!");
+                    }
+                }
+
+                s->allocated = zpl_pointer_diff(s->physical_start, curr) + size;
+
+                *(zpl_u64 *)curr = alloc_offset;
+                curr = zpl_pointer_add(curr, ZPL_STACK_ALLOC_OFFSET);
+
+                ptr = curr;
+            } break;
+
+            case ZPL_ALLOCATION_FREE: {
+                if (old_memory) {
+                    void *curr = old_memory;
+                    curr = zpl_pointer_sub(curr, ZPL_STACK_ALLOC_OFFSET);
+
+                    zpl_u64 alloc_offset = *(zpl_u64 *)curr;
+                    s->allocated = (zpl_usize)alloc_offset;
+                }
+            } break;
+
+            case ZPL_ALLOCATION_FREE_ALL: {
+                s->allocated = 0;
+            } break;
+
+            case ZPL_ALLOCATION_RESIZE: {
+                ZPL_PANIC("You cannot resize something allocated by a stack.");
+            } break;
+        }
+        return ptr;
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/array.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    ZPL_NEVER_INLINE void *zpl__array_set_capacity(void *array, zpl_isize capacity, zpl_isize element_size) {
+        zpl_array_header *h = ZPL_ARRAY_HEADER(array);
+
+        ZPL_ASSERT(element_size > 0);
+
+        if (capacity == h->capacity) return array;
+
+        if (capacity < h->count) {
+            if (h->capacity < capacity) {
+                zpl_isize new_capacity = ZPL_ARRAY_GROW_FORMULA(h->capacity);
+                if (new_capacity < capacity) new_capacity = capacity;
+                zpl__array_set_capacity(array, new_capacity, element_size);
+            }
+            h->count = capacity;
+        }
+
+        {
+            zpl_isize size = zpl_size_of(zpl_array_header) + element_size * capacity;
+            zpl_array_header *nh = cast(zpl_array_header *) zpl_alloc(h->allocator, size);
+            zpl_memmove(nh, h, zpl_size_of(zpl_array_header) + element_size * h->count);
+            nh->allocator = h->allocator;
+            nh->count = h->count;
+            nh->data = (char *)nh + 1;
+            nh->capacity = capacity;
+            zpl_free(h->allocator, h);
+            return nh + 1;
+        }
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/string.c
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Char things
+    //
+    //
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    zpl_internal zpl_isize zpl__scan_zpl_i64(const char *text, zpl_i32 base, zpl_i64 *value) {
+        const char *text_begin = text;
+        zpl_i64 result = 0;
+        zpl_b32 negative = false;
+
+        if (*text == '-') {
+            negative = true;
+            text++;
+        }
+
+        if (base == 16 && zpl_strncmp(text, "0x", 2) == 0) text += 2;
+
+        for (;;) {
+            zpl_i64 v;
+            if (zpl_char_is_digit(*text))
+                v = *text - '0';
+            else if (base == 16 && zpl_char_is_hex_digit(*text))
+                v = zpl_hex_digit_to_int(*text);
+            else
+                break;
+
+            result *= base;
+            result += v;
+            text++;
+        }
+
+        if (value) {
+            if (negative) result = -result;
+            *value = result;
+        }
+
+        return (text - text_begin);
+    }
+
+    zpl_internal zpl_isize zpl__scan_zpl_u64(const char *text, zpl_i32 base, zpl_u64 *value) {
+        const char *text_begin = text;
+        zpl_u64 result = 0;
+
+        if (base == 16 && zpl_strncmp(text, "0x", 2) == 0) text += 2;
+
+        for (;;) {
+            zpl_u64 v;
+            if (zpl_char_is_digit(*text))
+                v = *text - '0';
+            else if (base == 16 && zpl_char_is_hex_digit(*text))
+                v = zpl_hex_digit_to_int(*text);
+            else {
+                break;
+            }
+
+            result *= base;
+            result += v;
+            text++;
+        }
+
+        if (value) *value = result;
+
+        return (text - text_begin);
+    }
+
+    // TODO: Make better
+    zpl_u64 zpl_str_to_u64(const char *str, char **end_ptr, zpl_i32 base) {
+        zpl_isize len;
+        zpl_u64 value = 0;
+
+        if (!base) {
+            if ((zpl_strlen(str) > 2) && (zpl_strncmp(str, "0x", 2) == 0))
+                base = 16;
+            else
+                base = 10;
+        }
+
+        len = zpl__scan_zpl_u64(str, base, &value);
+        if (end_ptr) *end_ptr = (char *)str + len;
+        return value;
+    }
+
+    zpl_i64 zpl_str_to_i64(const char *str, char **end_ptr, zpl_i32 base) {
+        zpl_isize len;
+        zpl_i64 value;
+
+        if (!base) {
+            if ((zpl_strlen(str) > 2) && (zpl_strncmp(str, "0x", 2) == 0))
+                base = 16;
+            else
+                base = 10;
+        }
+
+        len = zpl__scan_zpl_i64(str, base, &value);
+        if (end_ptr) *end_ptr = (char *)str + len;
+        return value;
+    }
+
+    // TODO: Are these good enough for characters?
+    zpl_global const char zpl__num_to_char_table[] = "0123456789"
+    "ABCDEFGHIJKLMNOPQRSTUVWXYZ"
+    "abcdefghijklmnopqrstuvwxyz"
+    "@$";
+
+    void zpl_i64_to_str(zpl_i64 value, char *string, zpl_i32 base) {
+        char *buf = string;
+        zpl_b32 negative = false;
+        zpl_u64 v;
+
+        if (value < 0) {
+            negative = true;
+            value = -value;
+        }
+
+        v = cast(zpl_u64) value;
+        if (v != 0) {
+            while (v > 0) {
+                *buf++ = zpl__num_to_char_table[v % base];
+                v /= base;
+            }
+        } else {
+            *buf++ = '0';
+        }
+        if (negative) *buf++ = '-';
+        *buf = '\0';
+        zpl_strrev(string);
+    }
+
+    void zpl_u64_to_str(zpl_u64 value, char *string, zpl_i32 base) {
+        char *buf = string;
+
+        if (value) {
+            while (value > 0) {
+                *buf++ = zpl__num_to_char_table[value % base];
+                value /= base;
+            }
+        } else {
+            *buf++ = '0';
+        }
+        *buf = '\0';
+
+        zpl_strrev(string);
+    }
+
+    zpl_f64 zpl_str_to_f64(const char *str, char **end_ptr) {
+        zpl_f64 result, value, sign, scale;
+        zpl_i32 frac;
+
+        while (zpl_char_is_space(*str)) { str++; }
+
+        sign = 1.0;
+        if (*str == '-') {
+            sign = -1.0;
+            str++;
+        } else if (*str == '+') {
+            str++;
+        }
+
+        for (value = 0.0; zpl_char_is_digit(*str); str++) { value = value * 10.0 + (*str - '0'); }
+
+        if (*str == '.') {
+            zpl_f64 pow10 = 10.0;
+            str++;
+            while (zpl_char_is_digit(*str)) {
+                value += (*str - '0') / pow10;
+                pow10 *= 10.0;
+                str++;
+            }
+        }
+
+        frac = 0;
+        scale = 1.0;
+        if ((*str == 'e') || (*str == 'E')) {
+            zpl_u32 exp;
+
+            str++;
+            if (*str == '-') {
+                frac = 1;
+                str++;
+            } else if (*str == '+') {
+                str++;
+            }
+
+            for (exp = 0; zpl_char_is_digit(*str); str++) { exp = exp * 10 + (*str - '0'); }
+            if (exp > 308) exp = 308;
+
+            while (exp >= 50) {
+                scale *= 1e50;
+                exp -= 50;
+            }
+            while (exp >= 8) {
+                scale *= 1e8;
+                exp -= 8;
+            }
+            while (exp > 0) {
+                scale *= 10.0;
+                exp -= 1;
+            }
+        }
+
+        result = sign * (frac ? (value / scale) : (value * scale));
+
+        if (end_ptr) *end_ptr = cast(char *) str;
+
+        return result;
+    }
+
+
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Windows UTF-8 Handling
+    //
+    //
+
+    zpl_u16 *zpl_utf8_to_ucs2(zpl_u16 *buffer, zpl_isize len, zpl_u8 const *str) {
+        zpl_rune c;
+        zpl_isize i = 0;
+        len--;
+        while (*str) {
+            if (i >= len) return NULL;
+            if (!(*str & 0x80)) {
+                buffer[i++] = *str++;
+            } else if ((*str & 0xe0) == 0xc0) {
+                if (*str < 0xc2) return NULL;
+                c = (*str++ & 0x1f) << 6;
+                if ((*str & 0xc0) != 0x80) return NULL;
+                buffer[i++] = cast(zpl_u16)(c + (*str++ & 0x3f));
+            } else if ((*str & 0xf0) == 0xe0) {
+                if (*str == 0xe0 && (str[1] < 0xa0 || str[1] > 0xbf)) return NULL;
+                if (*str == 0xed && str[1] > 0x9f) // str[1] < 0x80 is checked below
+                    return NULL;
+                c = (*str++ & 0x0f) << 12;
+                if ((*str & 0xc0) != 0x80) return NULL;
+                c += (*str++ & 0x3f) << 6;
+                if ((*str & 0xc0) != 0x80) return NULL;
+                buffer[i++] = cast(zpl_u16)(c + (*str++ & 0x3f));
+            } else if ((*str & 0xf8) == 0xf0) {
+                if (*str > 0xf4) return NULL;
+                if (*str == 0xf0 && (str[1] < 0x90 || str[1] > 0xbf)) return NULL;
+                if (*str == 0xf4 && str[1] > 0x8f) // str[1] < 0x80 is checked below
+                    return NULL;
+                c = (*str++ & 0x07) << 18;
+                if ((*str & 0xc0) != 0x80) return NULL;
+                c += (*str++ & 0x3f) << 12;
+                if ((*str & 0xc0) != 0x80) return NULL;
+                c += (*str++ & 0x3f) << 6;
+                if ((*str & 0xc0) != 0x80) return NULL;
+                c += (*str++ & 0x3f);
+                // UTF-8 encodings of values used in surrogate pairs are invalid
+                if ((c & 0xfffff800) == 0xd800) return NULL;
+                if (c >= 0x10000) {
+                    c -= 0x10000;
+                    if (i + 2 > len) return NULL;
+                    buffer[i++] = 0xd800 | (0x3ff & (c >> 10));
+                    buffer[i++] = 0xdc00 | (0x3ff & (c));
+                }
+            } else {
+                return NULL;
+            }
+        }
+        buffer[i] = 0;
+        return buffer;
+    }
+
+    zpl_u8 *zpl_ucs2_to_utf8(zpl_u8 *buffer, zpl_isize len, zpl_u16 const *str) {
+        zpl_isize i = 0;
+        len--;
+        while (*str) {
+            if (*str < 0x80) {
+                if (i + 1 > len) return NULL;
+                buffer[i++] = (char)*str++;
+            } else if (*str < 0x800) {
+                if (i + 2 > len) return NULL;
+                buffer[i++] = cast(char)(0xc0 + (*str >> 6));
+                buffer[i++] = cast(char)(0x80 + (*str & 0x3f));
+                str += 1;
+            } else if (*str >= 0xd800 && *str < 0xdc00) {
+                zpl_rune c;
+                if (i + 4 > len) return NULL;
+                c = ((str[0] - 0xd800) << 10) + ((str[1]) - 0xdc00) + 0x10000;
+                buffer[i++] = cast(char)(0xf0 + (c >> 18));
+                buffer[i++] = cast(char)(0x80 + ((c >> 12) & 0x3f));
+                buffer[i++] = cast(char)(0x80 + ((c >> 6) & 0x3f));
+                buffer[i++] = cast(char)(0x80 + ((c)&0x3f));
+                str += 2;
+            } else if (*str >= 0xdc00 && *str < 0xe000) {
+                return NULL;
+            } else {
+                if (i + 3 > len) return NULL;
+                buffer[i++] = 0xe0 + (*str >> 12);
+                buffer[i++] = 0x80 + ((*str >> 6) & 0x3f);
+                buffer[i++] = 0x80 + ((*str) & 0x3f);
+                str += 1;
+            }
+        }
+        buffer[i] = 0;
+        return buffer;
+    }
+
+    zpl_u16 *zpl_utf8_to_ucs2_buf(zpl_u8 const *str) { // NOTE: Uses locally persisting buffer
+        zpl_local_persist zpl_u16 buf[4096];
+        return zpl_utf8_to_ucs2(buf, zpl_count_of(buf), str);
+    }
+
+    zpl_u8 *zpl_ucs2_to_utf8_buf(zpl_u16 const *str) { // NOTE: Uses locally persisting buffer
+        zpl_local_persist zpl_u8 buf[4096];
+        return zpl_ucs2_to_utf8(buf, zpl_count_of(buf), str);
+    }
+
+    zpl_global zpl_u8 const zpl__utf8_first[256] = {
+        0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, // 0x00-0x0F
+        0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, // 0x10-0x1F
+        0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, // 0x20-0x2F
+        0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, // 0x30-0x3F
+        0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, // 0x40-0x4F
+        0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, // 0x50-0x5F
+        0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, // 0x60-0x6F
+        0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, 0xf0, // 0x70-0x7F
+        0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, // 0x80-0x8F
+        0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, // 0x90-0x9F
+        0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, // 0xA0-0xAF
+        0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, // 0xB0-0xBF
+        0xf1, 0xf1, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, // 0xC0-0xCF
+        0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, // 0xD0-0xDF
+        0x13, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x23, 0x03, 0x03, // 0xE0-0xEF
+        0x34, 0x04, 0x04, 0x04, 0x44, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, 0xf1, // 0xF0-0xFF
+    };
+
+
+    typedef struct zpl_utf8_accept_range {
+        zpl_u8 lo, hi;
+    } zpl_utf8_accept_range;
+
+    zpl_global zpl_utf8_accept_range const zpl__utf8_accept_ranges[] = {
+        { 0x80, 0xbf }, { 0xa0, 0xbf }, { 0x80, 0x9f }, { 0x90, 0xbf }, { 0x80, 0x8f },
+    };
+
+    zpl_isize zpl_utf8_decode(zpl_u8 const *str, zpl_isize str_len, zpl_rune *codepoint_out) {
+
+        zpl_isize width = 0;
+        zpl_rune codepoint = ZPL_RUNE_INVALID;
+
+        if (str_len > 0) {
+            zpl_u8 s0 = str[0];
+            zpl_u8 x = zpl__utf8_first[s0], sz;
+            zpl_u8 b1, b2, b3;
+            zpl_utf8_accept_range accept;
+            if (x >= 0xf0) {
+                zpl_rune mask = (cast(zpl_rune) x << 31) >> 31;
+                codepoint = (cast(zpl_rune) s0 & (~mask)) | (ZPL_RUNE_INVALID & mask);
+                width = 1;
+                goto end;
+            }
+            if (s0 < 0x80) {
+                codepoint = s0;
+                width = 1;
+                goto end;
+            }
+
+            sz = x & 7;
+            accept = zpl__utf8_accept_ranges[x >> 4];
+            if (str_len < zpl_size_of(sz)) goto invalid_codepoint;
+
+            b1 = str[1];
+            if (b1 < accept.lo || accept.hi < b1) goto invalid_codepoint;
+
+            if (sz == 2) {
+                codepoint = (cast(zpl_rune) s0 & 0x1f) << 6 | (cast(zpl_rune) b1 & 0x3f);
+                width = 2;
+                goto end;
+            }
+
+            b2 = str[2];
+            if (!zpl_is_between(b2, 0x80, 0xbf)) goto invalid_codepoint;
+
+            if (sz == 3) {
+                codepoint = (cast(zpl_rune) s0 & 0x1f) << 12 | (cast(zpl_rune) b1 & 0x3f) << 6 | (cast(zpl_rune) b2 & 0x3f);
+                width = 3;
+                goto end;
+            }
+
+            b3 = str[3];
+            if (!zpl_is_between(b3, 0x80, 0xbf)) goto invalid_codepoint;
+
+            codepoint = (cast(zpl_rune) s0 & 0x07) << 18 | (cast(zpl_rune) b1 & 0x3f) << 12 | (cast(zpl_rune) b2 & 0x3f) << 6 |
+                (cast(zpl_rune) b3 & 0x3f);
+            width = 4;
+            goto end;
+
+            invalid_codepoint:
+            codepoint = ZPL_RUNE_INVALID;
+            width = 1;
+        }
+
+        end:
+        if (codepoint_out) *codepoint_out = codepoint;
+        return width;
+    }
+
+    zpl_isize zpl_utf8_codepoint_size(zpl_u8 const *str, zpl_isize str_len) {
+        zpl_isize i = 0;
+        for (; i < str_len && str[i]; i++) {
+            if ((str[i] & 0xc0) != 0x80) break;
+        }
+        return i + 1;
+    }
+
+    zpl_isize zpl_utf8_encode_rune(zpl_u8 buf[4], zpl_rune r) {
+        zpl_u32 i = cast(zpl_u32) r;
+        zpl_u8 mask = 0x3f;
+        if (i <= (1 << 7) - 1) {
+            buf[0] = cast(zpl_u8) r;
+            return 1;
+        }
+        if (i <= (1 << 11) - 1) {
+            buf[0] = 0xc0 | cast(zpl_u8)(r >> 6);
+            buf[1] = 0x80 | (cast(zpl_u8)(r) & mask);
+            return 2;
+        }
+
+        // Invalid or Surrogate range
+        if (i > ZPL_RUNE_MAX || zpl_is_between(i, 0xd800, 0xdfff)) {
+            r = ZPL_RUNE_INVALID;
+
+            buf[0] = 0xe0 | cast(zpl_u8)(r >> 12);
+            buf[1] = 0x80 | (cast(zpl_u8)(r >> 6) & mask);
+            buf[2] = 0x80 | (cast(zpl_u8)(r) & mask);
+            return 3;
+        }
+
+        if (i <= (1 << 16) - 1) {
+            buf[0] = 0xe0 | cast(zpl_u8)(r >> 12);
+            buf[1] = 0x80 | (cast(zpl_u8)(r >> 6) & mask);
+            buf[2] = 0x80 | (cast(zpl_u8)(r) & mask);
+            return 3;
+        }
+
+        buf[0] = 0xf0 | cast(zpl_u8)(r >> 18);
+        buf[1] = 0x80 | (cast(zpl_u8)(r >> 12) & mask);
+        buf[2] = 0x80 | (cast(zpl_u8)(r >> 6) & mask);
+        buf[3] = 0x80 | (cast(zpl_u8)(r) & mask);
+        return 4;
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/stringlib.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    zpl_string zpl_string_make_reserve(zpl_allocator a, zpl_isize capacity) {
+        zpl_isize header_size = zpl_size_of(zpl_string_header);
+        void *ptr = zpl_alloc(a, header_size + capacity + 1);
+
+        zpl_string str;
+        zpl_string_header *header;
+
+        if (ptr == NULL) return NULL;
+        zpl_zero_size(ptr, header_size + capacity + 1);
+
+        str = cast(char *) ptr + header_size;
+        header = ZPL_STRING_HEADER(str);
+        header->allocator = a;
+        header->length = 0;
+        header->capacity = capacity;
+        str[capacity] = '\0';
+
+        return str;
+    }
+
+
+    zpl_string zpl_string_make_length(zpl_allocator a, void const *init_str, zpl_isize num_bytes) {
+        zpl_isize header_size = zpl_size_of(zpl_string_header);
+        void *ptr = zpl_alloc(a, header_size + num_bytes + 1);
+
+        zpl_string str;
+        zpl_string_header *header;
+
+        if (ptr == NULL) return NULL;
+        if (!init_str) zpl_zero_size(ptr, header_size + num_bytes + 1);
+
+        str = cast(char *) ptr + header_size;
+        header = ZPL_STRING_HEADER(str);
+        header->allocator = a;
+        header->length = num_bytes;
+        header->capacity = num_bytes;
+        if (num_bytes && init_str) zpl_memcopy(str, init_str, num_bytes);
+        str[num_bytes] = '\0';
+
+        return str;
+    }
+
+    zpl_string zpl_string_sprintf_buf(zpl_allocator a, const char *fmt, ...) {
+        zpl_local_persist char buf[4096] = { 0 };
+        va_list va;
+        va_start(va, fmt);
+        zpl_snprintf_va(buf, 4096, fmt, va);
+        va_end(va);
+
+        return zpl_string_make(a, buf);
+    }
+
+    zpl_string zpl_string_sprintf(zpl_allocator a, char *buf, zpl_isize num_bytes, const char *fmt, ...) {
+        va_list va;
+        va_start(va, fmt);
+        zpl_snprintf_va(buf, num_bytes, fmt, va);
+        va_end(va);
+
+        return zpl_string_make(a, buf);
+    }
+
+    zpl_string zpl_string_append_length(zpl_string str, void const *other, zpl_isize other_len) {
+        if (other_len > 0) {
+            zpl_isize curr_len = zpl_string_length(str);
+
+            str = zpl_string_make_space_for(str, other_len);
+            if (str == NULL) return NULL;
+
+            zpl_memcopy(str + curr_len, other, other_len);
+            str[curr_len + other_len] = '\0';
+            zpl__set_string_length(str, curr_len + other_len);
+        }
+        return str;
+    }
+
+    ZPL_ALWAYS_INLINE zpl_string zpl_string_appendc(zpl_string str, const char *other) {
+        return zpl_string_append_length(str, other, zpl_strlen(other));
+    }
+
+    ZPL_ALWAYS_INLINE zpl_string zpl_string_join(zpl_allocator a, const char **parts, zpl_isize count, const char *glue) {
+        zpl_string ret;
+        zpl_isize i;
+
+        ret = zpl_string_make(a, NULL);
+
+        for (i=0; i<count; ++i) {
+            ret = zpl_string_appendc(ret, parts[i]);
+
+            if ((i+1) < count) {
+                ret = zpl_string_appendc(ret, glue);
+            }
+        }
+
+        return ret;
+    }
+
+    zpl_string zpl_string_set(zpl_string str, const char *cstr) {
+        zpl_isize len = zpl_strlen(cstr);
+        if (zpl_string_capacity(str) < len) {
+            str = zpl_string_make_space_for(str, len - zpl_string_length(str));
+            if (str == NULL) return NULL;
+        }
+
+        zpl_memcopy(str, cstr, len);
+        str[len] = '\0';
+        zpl__set_string_length(str, len);
+
+        return str;
+    }
+
+    zpl_string zpl_string_make_space_for(zpl_string str, zpl_isize add_len) {
+        zpl_isize available = zpl_string_available_space(str);
+
+        // NOTE: Return if there is enough space left
+        if (available >= add_len) {
+            return str;
+        } else {
+            zpl_isize new_len, old_size, new_size;
+            void *ptr, *new_ptr;
+            zpl_allocator a = ZPL_STRING_HEADER(str)->allocator;
+            zpl_string_header *header;
+
+            new_len = zpl_string_length(str) + add_len;
+            ptr = ZPL_STRING_HEADER(str);
+            old_size = zpl_size_of(zpl_string_header) + zpl_string_length(str) + 1;
+            new_size = zpl_size_of(zpl_string_header) + new_len + 1;
+
+            new_ptr = zpl_resize(a, ptr, old_size, new_size);
+            if (new_ptr == NULL) return NULL;
+
+            header = cast(zpl_string_header *) new_ptr;
+            header->allocator = a;
+
+            str = cast(zpl_string)(header + 1);
+            zpl__set_string_capacity(str, new_len);
+
+            return str;
+        }
+    }
+
+    zpl_isize zpl_string_allocation_size(zpl_string const str) {
+        zpl_isize cap = zpl_string_capacity(str);
+        return zpl_size_of(zpl_string_header) + cap;
+    }
+
+    zpl_b32 zpl_string_are_equal(zpl_string const lhs, zpl_string const rhs) {
+        zpl_isize lhs_len, rhs_len, i;
+        lhs_len = zpl_string_length(lhs);
+        rhs_len = zpl_string_length(rhs);
+        if (lhs_len != rhs_len) return false;
+
+        for (i = 0; i < lhs_len; i++) {
+            if (lhs[i] != rhs[i]) return false;
+        }
+
+        return true;
+    }
+
+    zpl_string zpl_string_trim(zpl_string str, const char *cut_set) {
+        char *start, *end, *start_pos, *end_pos;
+        zpl_isize len;
+
+        start_pos = start = str;
+        end_pos = end = str + zpl_string_length(str) - 1;
+
+        while (start_pos <= end && zpl_char_first_occurence(cut_set, *start_pos)) start_pos++;
+        while (end_pos > start_pos && zpl_char_first_occurence(cut_set, *end_pos)) end_pos--;
+
+        len = cast(zpl_isize)((start_pos > end_pos) ? 0 : ((end_pos - start_pos) + 1));
+
+        if (str != start_pos) zpl_memmove(str, start_pos, len);
+        str[len] = '\0';
+
+        zpl__set_string_length(str, len);
+
+        return str;
+    }
+
+    zpl_string zpl_string_append_rune(zpl_string str, zpl_rune r) {
+        if (r >= 0) {
+            zpl_u8 buf[8] = { 0 };
+            zpl_isize len = zpl_utf8_encode_rune(buf, r);
+            return zpl_string_append_length(str, buf, len);
+        }
+
+        return str;
+    }
+
+    zpl_string zpl_string_append_fmt(zpl_string str, const char *fmt, ...) {
+        zpl_isize res;
+        char buf[4096] = { 0 };
+        va_list va;
+        va_start(va, fmt);
+        res = zpl_snprintf_va(buf, zpl_count_of(buf) - 1, fmt, va) - 1;
+        va_end(va);
+        return zpl_string_append_length(str, buf, res);
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/file.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // File Handling
+    //
+    //
+    #include <sys/stat.h>
+
+    #ifdef ZPL_SYSTEM_MACOS
+        #include <copyfile.h>
+    #endif
+
+    #ifdef ZPL_SYSTEM_CYGWIN
+    #   include <windows.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_WINDOWS) && !defined(ZPL_COMPILER_GCC)
+    #include <io.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #if defined(ZPL_SYSTEM_WINDOWS) || defined (ZPL_SYSTEM_CYGWIN)
+
+        zpl_internal wchar_t *zpl__alloc_utf8_to_ucs2(zpl_allocator a, char const *text, zpl_isize *w_len_) {
+            wchar_t *w_text = NULL;
+            zpl_isize len = 0, w_len = 0, w_len1 = 0;
+            if (text == NULL) {
+                if (w_len_) *w_len_ = w_len;
+                return NULL;
+            }
+            len = zpl_strlen(text);
+            if (len == 0) {
+                if (w_len_) *w_len_ = w_len;
+                return NULL;
+            }
+            w_len = MultiByteToWideChar(CP_UTF8, MB_ERR_INVALID_CHARS, text, cast(int) len, NULL, 0);
+            if (w_len == 0) {
+                if (w_len_) *w_len_ = w_len;
+                return NULL;
+            }
+            w_text = zpl_alloc_array(a, wchar_t, w_len + 1);
+            w_len1 = MultiByteToWideChar(CP_UTF8, MB_ERR_INVALID_CHARS, text, cast(int) len, w_text, cast(int) w_len);
+            if (w_len1 == 0) {
+                zpl_free(a, w_text);
+                if (w_len_) *w_len_ = 0;
+                return NULL;
+            }
+            w_text[w_len] = 0;
+            if (w_len_) *w_len_ = w_len;
+            return w_text;
+        }
+
+        zpl_internal ZPL_FILE_SEEK_PROC(zpl__win32_file_seek) {
+            LARGE_INTEGER li_offset;
+            li_offset.QuadPart = offset;
+            if (!SetFilePointerEx(fd.p, li_offset, &li_offset, whence)) { return false; }
+
+            if (new_offset) *new_offset = li_offset.QuadPart;
+            return true;
+        }
+
+        zpl_internal ZPL_FILE_READ_AT_PROC(zpl__win32_file_read) {
+            zpl_unused(stop_at_newline);
+            zpl_b32 result = false;
+            zpl__win32_file_seek(fd, offset, ZPL_SEEK_WHENCE_BEGIN, NULL);
+            DWORD size_ = cast(DWORD)(size > ZPL_I32_MAX ? ZPL_I32_MAX : size);
+            DWORD bytes_read_;
+            if (ReadFile(fd.p, buffer, size_, &bytes_read_, NULL)) {
+                if (bytes_read) *bytes_read = bytes_read_;
+                result = true;
+            }
+
+            return result;
+        }
+
+        zpl_internal ZPL_FILE_WRITE_AT_PROC(zpl__win32_file_write) {
+            DWORD size_ = cast(DWORD)(size > ZPL_I32_MAX ? ZPL_I32_MAX : size);
+            DWORD bytes_written_;
+            zpl__win32_file_seek(fd, offset, ZPL_SEEK_WHENCE_BEGIN, NULL);
+            if (WriteFile(fd.p, buffer, size_, &bytes_written_, NULL)) {
+                if (bytes_written) *bytes_written = bytes_written_;
+                return true;
+            }
+            return false;
+        }
+
+        zpl_internal ZPL_FILE_CLOSE_PROC(zpl__win32_file_close) { CloseHandle(fd.p); }
+
+        zpl_file_operations const zpl_default_file_operations = { zpl__win32_file_read, zpl__win32_file_write,
+            zpl__win32_file_seek, zpl__win32_file_close };
+
+        ZPL_NEVER_INLINE ZPL_FILE_OPEN_PROC(zpl__win32_file_open) {
+            DWORD desired_access;
+            DWORD creation_disposition;
+            void *handle;
+            wchar_t *w_text;
+
+            switch (mode & ZPL_FILE_MODES) {
+                case ZPL_FILE_MODE_READ:
+                    desired_access = GENERIC_READ;
+                    creation_disposition = OPEN_EXISTING;
+                    break;
+                case ZPL_FILE_MODE_WRITE:
+                    desired_access = GENERIC_WRITE;
+                    creation_disposition = CREATE_ALWAYS;
+                    break;
+                case ZPL_FILE_MODE_APPEND:
+                    desired_access = GENERIC_WRITE;
+                    creation_disposition = OPEN_ALWAYS;
+                    break;
+                case ZPL_FILE_MODE_READ | ZPL_FILE_MODE_RW:
+                    desired_access = GENERIC_READ | GENERIC_WRITE;
+                    creation_disposition = OPEN_EXISTING;
+                break;
+                case ZPL_FILE_MODE_WRITE | ZPL_FILE_MODE_RW:
+                    desired_access = GENERIC_READ | GENERIC_WRITE;
+                    creation_disposition = CREATE_ALWAYS;
+                    break;
+                case ZPL_FILE_MODE_APPEND | ZPL_FILE_MODE_RW:
+                    desired_access = GENERIC_READ | GENERIC_WRITE;
+                    creation_disposition = OPEN_ALWAYS;
+                    break;
+                default: ZPL_PANIC("Invalid file mode"); return ZPL_FILE_ERROR_INVALID;
+            }
+
+            w_text = zpl__alloc_utf8_to_ucs2(zpl_heap_allocator( ), filename, NULL);
+            handle = CreateFileW(w_text, desired_access, FILE_SHARE_READ | FILE_SHARE_DELETE, NULL, creation_disposition,
+                                 FILE_ATTRIBUTE_NORMAL, NULL);
+
+            zpl_free(zpl_heap_allocator( ), w_text);
+
+            if (handle == INVALID_HANDLE_VALUE) {
+                DWORD err = GetLastError( );
+                switch (err) {
+                    case ERROR_FILE_NOT_FOUND: return ZPL_FILE_ERROR_NOT_EXISTS;
+                    case ERROR_FILE_EXISTS: return ZPL_FILE_ERROR_EXISTS;
+                    case ERROR_ALREADY_EXISTS: return ZPL_FILE_ERROR_EXISTS;
+                    case ERROR_ACCESS_DENIED: return ZPL_FILE_ERROR_PERMISSION;
+                }
+                return ZPL_FILE_ERROR_INVALID;
+            }
+
+            if (mode & ZPL_FILE_MODE_APPEND) {
+                LARGE_INTEGER offset = { 0 };
+                if (!SetFilePointerEx(handle, offset, NULL, ZPL_SEEK_WHENCE_END)) {
+                    CloseHandle(handle);
+                    return ZPL_FILE_ERROR_INVALID;
+                }
+            }
+
+            fd->p = handle;
+            *ops = zpl_default_file_operations;
+            return ZPL_FILE_ERROR_NONE;
+        }
+
+    #else // POSIX
+        #include <fcntl.h>
+
+        zpl_internal ZPL_FILE_SEEK_PROC(zpl__posix_file_seek) {
+        #if defined(ZPL_SYSTEM_OSX)
+            zpl_i64 res = lseek(fd.i, offset, whence);
+        #else // TODO(ZaKlaus): @fixme lseek64
+            zpl_i64 res = lseek(fd.i, offset, whence);
+        #endif
+            if (res < 0) return false;
+            if (new_offset) *new_offset = res;
+            return true;
+        }
+
+        zpl_internal ZPL_FILE_READ_AT_PROC(zpl__posix_file_read) {
+            zpl_unused(stop_at_newline);
+            zpl_isize res = pread(fd.i, buffer, size, offset);
+            if (res < 0) return false;
+            if (bytes_read) *bytes_read = res;
+            return true;
+        }
+
+        zpl_internal ZPL_FILE_WRITE_AT_PROC(zpl__posix_file_write) {
+            zpl_isize res;
+            zpl_i64 curr_offset = 0;
+            zpl__posix_file_seek(fd, 0, ZPL_SEEK_WHENCE_CURRENT, &curr_offset);
+            if (curr_offset == offset) {
+                // NOTE: Writing to stdout et al. doesn't like pwrite for numerous reasons
+                res = write(cast(int) fd.i, buffer, size);
+            } else {
+                res = pwrite(cast(int) fd.i, buffer, size, offset);
+            }
+            if (res < 0) return false;
+            if (bytes_written) *bytes_written = res;
+            return true;
+        }
+
+        zpl_internal ZPL_FILE_CLOSE_PROC(zpl__posix_file_close) { close(fd.i); }
+
+        zpl_file_operations const zpl_default_file_operations = { zpl__posix_file_read, zpl__posix_file_write,
+            zpl__posix_file_seek, zpl__posix_file_close };
+
+        ZPL_NEVER_INLINE ZPL_FILE_OPEN_PROC(zpl__posix_file_open) {
+            zpl_i32 os_mode;
+            switch (mode & ZPL_FILE_MODES) {
+                case ZPL_FILE_MODE_READ: os_mode = O_RDONLY; break;
+                case ZPL_FILE_MODE_WRITE: os_mode = O_WRONLY | O_CREAT | O_TRUNC; break;
+                case ZPL_FILE_MODE_APPEND: os_mode = O_WRONLY | O_APPEND | O_CREAT; break;
+                case ZPL_FILE_MODE_READ | ZPL_FILE_MODE_RW: os_mode = O_RDWR; break;
+                case ZPL_FILE_MODE_WRITE | ZPL_FILE_MODE_RW: os_mode = O_RDWR | O_CREAT | O_TRUNC; break;
+                case ZPL_FILE_MODE_APPEND | ZPL_FILE_MODE_RW: os_mode = O_RDWR | O_APPEND | O_CREAT; break;
+                default: ZPL_PANIC("Invalid file mode"); return ZPL_FILE_ERROR_INVALID;
+            }
+
+            fd->i = open(filename, os_mode, S_IRUSR | S_IWUSR | S_IRGRP | S_IWGRP | S_IROTH | S_IWOTH);
+            if (fd->i < 0) {
+                // TODO: More file errors
+                return ZPL_FILE_ERROR_INVALID;
+            }
+
+            *ops = zpl_default_file_operations;
+            return ZPL_FILE_ERROR_NONE;
+        }
+
+    #endif
+
+    zpl_file_error zpl_file_new(zpl_file *f, zpl_file_descriptor fd, zpl_file_operations ops, char const *filename) {
+        zpl_file_error err = ZPL_FILE_ERROR_NONE;
+        zpl_isize len = zpl_strlen(filename);
+
+        f->ops = ops;
+        f->fd = fd;
+        f->dir = NULL;
+        f->last_write_time = 0;
+        f->filename = zpl_alloc_array(zpl_heap_allocator( ), char, len + 1);
+        zpl_memcopy(cast(char *) f->filename, cast(char *) filename, len + 1);
+
+        return err;
+    }
+
+    zpl_file_error zpl_file_open_mode(zpl_file *f, zpl_file_mode mode, char const *filename) {
+        zpl_file file_ = {0};
+        *f = file_;
+        zpl_file_error err;
+    #if defined(ZPL_SYSTEM_WINDOWS) || defined(ZPL_SYSTEM_CYGWIN)
+        err = zpl__win32_file_open(&f->fd, &f->ops, mode, filename);
+    #else
+        err = zpl__posix_file_open(&f->fd, &f->ops, mode, filename);
+    #endif
+        if (err == ZPL_FILE_ERROR_NONE) return zpl_file_new(f, f->fd, f->ops, filename);
+        return err;
+    }
+
+    zpl_internal void zpl__dirinfo_free_entry(zpl_dir_entry *entry);
+
+    zpl_file_error zpl_file_close(zpl_file *f) {
+        if (!f) return ZPL_FILE_ERROR_INVALID;
+
+        if (f->filename) zpl_free(zpl_heap_allocator( ), cast(char *) f->filename);
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        if (f->fd.p == INVALID_HANDLE_VALUE) return ZPL_FILE_ERROR_INVALID;
+    #else
+        if (f->fd.i < 0) return ZPL_FILE_ERROR_INVALID;
+    #endif
+        
+        if (f->is_temp)
+        {
+            f->ops.close(f->fd);
+            return ZPL_FILE_ERROR_NONE;
+        }
+
+        if (!f->ops.read_at) f->ops = zpl_default_file_operations;
+        f->ops.close(f->fd);
+
+        if (f->dir) {
+            zpl__dirinfo_free_entry(f->dir);
+            zpl_mfree(f->dir);
+            f->dir = NULL;
+        }
+
+        return ZPL_FILE_ERROR_NONE;
+    }
+
+
+    zpl_file_error zpl_file_create(zpl_file *f, char const *filename) {
+        return zpl_file_open_mode(f, ZPL_FILE_MODE_WRITE | ZPL_FILE_MODE_RW, filename);
+    }
+
+    zpl_file_error zpl_file_open(zpl_file *f, char const *filename) {
+        return zpl_file_open_mode(f, ZPL_FILE_MODE_READ, filename);
+    }
+
+    char const *zpl_file_name(zpl_file *f) { return f->filename ? f->filename : ""; }
+
+    zpl_b32 zpl_file_has_changed(zpl_file *f) {
+        if (f->is_temp)
+            return false;
+        zpl_b32 result = false;
+        zpl_file_time last_write_time = zpl_fs_last_write_time(f->filename);
+        if (f->last_write_time != last_write_time) {
+            result = true;
+            f->last_write_time = last_write_time;
+        }
+        return result;
+    }
+
+    // TODO: Is this a bad idea?
+    zpl_global zpl_b32 zpl__std_file_set = false;
+    zpl_global zpl_file zpl__std_files[ZPL_FILE_STANDARD_COUNT] = { { 0 } };
+
+    #if defined(ZPL_SYSTEM_WINDOWS) || defined(ZPL_SYSTEM_CYGWIN)
+
+    zpl_file *zpl_file_get_standard(zpl_file_standard_type std) {
+        if (!zpl__std_file_set) {
+    #define ZPL__SET_STD_FILE(type, v)                                                                                     \
+            zpl__std_files[type].fd.p = v;                                                                                     \
+            zpl__std_files[type].ops = zpl_default_file_operations
+            ZPL__SET_STD_FILE(ZPL_FILE_STANDARD_INPUT, GetStdHandle(STD_INPUT_HANDLE));
+            ZPL__SET_STD_FILE(ZPL_FILE_STANDARD_OUTPUT, GetStdHandle(STD_OUTPUT_HANDLE));
+            ZPL__SET_STD_FILE(ZPL_FILE_STANDARD_ERROR, GetStdHandle(STD_ERROR_HANDLE));
+    #undef ZPL__SET_STD_FILE
+            zpl__std_file_set = true;
+        }
+        return &zpl__std_files[std];
+    }
+
+    void zpl_file_connect_handle(zpl_file *file, void *handle) {
+        ZPL_ASSERT_NOT_NULL(file);
+        ZPL_ASSERT_NOT_NULL(handle);
+
+        if (file->is_temp)
+            return;
+
+        zpl_zero_item(file);
+
+        file->fd.p = handle;
+        file->ops = zpl_default_file_operations;
+    }
+
+    zpl_file_error zpl_file_truncate(zpl_file *f, zpl_i64 size) {
+        zpl_file_error err = ZPL_FILE_ERROR_NONE;
+        zpl_i64 prev_offset = zpl_file_tell(f);
+        zpl_file_seek(f, size);
+        if (!SetEndOfFile(f)) err = ZPL_FILE_ERROR_TRUNCATION_FAILURE;
+        zpl_file_seek(f, prev_offset);
+        return err;
+    }
+
+    zpl_b32 zpl_fs_exists(char const *name) {
+        WIN32_FIND_DATAW data;
+        wchar_t *w_text;
+        void *handle;
+        zpl_b32 found = false;
+        zpl_allocator a = zpl_heap_allocator( );
+
+        w_text = zpl__alloc_utf8_to_ucs2(a, name, NULL);
+        if (w_text == NULL) { return false; }
+        handle = FindFirstFileW(w_text, &data);
+        zpl_free(a, w_text);
+        found = handle != INVALID_HANDLE_VALUE;
+        if (found) FindClose(handle);
+        return found;
+    }
+
+    #else // POSIX
+
+    zpl_file *zpl_file_get_standard(zpl_file_standard_type std) {
+        if (!zpl__std_file_set) {
+    #define ZPL__SET_STD_FILE(type, v)                                                                                     \
+            zpl__std_files[type].fd.i = v;                                                                                     \
+            zpl__std_files[type].ops = zpl_default_file_operations
+            ZPL__SET_STD_FILE(ZPL_FILE_STANDARD_INPUT, 0);
+            ZPL__SET_STD_FILE(ZPL_FILE_STANDARD_OUTPUT, 1);
+            ZPL__SET_STD_FILE(ZPL_FILE_STANDARD_ERROR, 2);
+    #undef ZPL__SET_STD_FILE
+            zpl__std_file_set = true;
+        }
+        return &zpl__std_files[std];
+    }
+
+    zpl_file_error zpl_file_truncate(zpl_file *f, zpl_i64 size) {
+        zpl_file_error err = ZPL_FILE_ERROR_NONE;
+        int i = ftruncate(f->fd.i, size);
+        if (i != 0) err = ZPL_FILE_ERROR_TRUNCATION_FAILURE;
+        return err;
+    }
+
+    zpl_b32 zpl_fs_exists(char const *name) { return access(name, F_OK) != -1; }
+
+    #endif
+
+    zpl_i64 zpl_file_size(zpl_file *f) {
+        zpl_i64 size = 0;
+        zpl_i64 prev_offset = zpl_file_tell(f);
+        zpl_file_seek_to_end(f);
+        size = zpl_file_tell(f);
+        zpl_file_seek(f, prev_offset);
+        return size;
+    }
+
+    zpl_file_error zpl_file_temp(zpl_file *file) {
+        zpl_zero_item(file);
+        FILE *fd = NULL;
+
+    #if defined(ZPL_SYSTEM_WINDOWS) && !defined(ZPL_COMPILER_GCC)
+        errno_t errcode = tmpfile_s(&fd);
+
+        if (errcode != 0) {
+            fd = NULL;
+        }
+    #else
+        fd = tmpfile();
+    #endif
+
+        if (fd == NULL) { return ZPL_FILE_ERROR_INVALID; }
+
+    #if defined(ZPL_SYSTEM_WINDOWS) && !defined(ZPL_COMPILER_GCC)
+        file->fd.i = _get_osfhandle(_fileno(fd));
+    #else 
+        file->fd.i = fileno(fd);
+    #endif
+        file->ops = zpl_default_file_operations;
+        file->is_temp = true;
+        return ZPL_FILE_ERROR_NONE;
+    }
+
+    zpl_file_contents zpl_file_read_contents(zpl_allocator a, zpl_b32 zero_terminate, char const *filepath) {
+        zpl_file_contents result = { 0 };
+        zpl_file file = { 0 };
+
+        result.allocator = a;
+
+        if (zpl_file_open(&file, filepath) == ZPL_FILE_ERROR_NONE) {
+            zpl_isize file_size = cast(zpl_isize) zpl_file_size(&file);
+            if (file_size > 0) {
+                result.data = zpl_alloc(a, zero_terminate ? file_size + 1 : file_size);
+                result.size = file_size;
+                zpl_file_read_at(&file, result.data, result.size, 0);
+                if (zero_terminate) {
+                    zpl_u8 *str = cast(zpl_u8 *) result.data;
+                    str[file_size] = '\0';
+                }
+            }
+            zpl_file_close(&file);
+        }
+
+        return result;
+    }
+
+    void zpl_file_free_contents(zpl_file_contents *fc) {
+        ZPL_ASSERT_NOT_NULL(fc->data);
+        zpl_free(fc->allocator, fc->data);
+        fc->data = NULL;
+        fc->size = 0;
+    }
+
+    zpl_b32 zpl_file_write_contents(char const* filepath, void const* buffer, zpl_isize size, zpl_file_error* err) {
+        zpl_file f = { 0 };
+        zpl_file_error open_err;
+        zpl_b32 write_ok;
+        open_err = zpl_file_open_mode(&f, ZPL_FILE_MODE_WRITE, filepath);
+
+        if (open_err != ZPL_FILE_ERROR_NONE)
+        {
+            if (err)
+                *err = open_err;
+
+            return false;
+        }
+
+        write_ok = zpl_file_write(&f, buffer, size);
+        zpl_file_close(&f);
+        return write_ok;
+    }
+
+    char *zpl_file_read_lines(zpl_allocator alloc, zpl_array(char *)*lines, char const *filename, zpl_b32 strip_whitespace) {
+        zpl_file f = { 0 };
+        zpl_file_open(&f, filename);
+        zpl_isize fsize = (zpl_isize)zpl_file_size(&f);
+
+        char *contents = (char *)zpl_alloc(alloc, fsize + 1);
+        zpl_file_read(&f, contents, fsize);
+        contents[fsize] = 0;
+        *lines = zpl_str_split_lines(alloc, contents, strip_whitespace);
+        zpl_file_close(&f);
+
+        return contents;
+    }
+
+    #if !defined(_WINDOWS_) && defined(ZPL_SYSTEM_WINDOWS)
+        ZPL_IMPORT DWORD WINAPI GetFullPathNameA(char const *lpFileName, DWORD nBufferLength, char *lpBuffer, char **lpFilePart);
+        ZPL_IMPORT DWORD WINAPI GetFullPathNameW(wchar_t const *lpFileName, DWORD nBufferLength, wchar_t *lpBuffer, wchar_t **lpFilePart);
+    #endif
+
+    ZPL_END_C_DECLS
+    // file: source/core/file_stream.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Memory streaming
+    //
+    //
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef struct {
+        zpl_u8 magic;
+        zpl_u8 *buf; //< zpl_array OR plain buffer if we can't write
+        zpl_isize cursor;
+        zpl_allocator alloc;
+
+        zpl_file_stream_flags flags;
+        zpl_isize cap;
+    } zpl__memory_fd;
+
+    #define ZPL__FILE_STREAM_FD_MAGIC 37
+
+    ZPL_ALWAYS_INLINE zpl_file_descriptor zpl__file_stream_fd_make(zpl__memory_fd* d) {
+        zpl_file_descriptor fd = {0};
+        fd.p = (void*)d;
+        return fd;
+    }
+
+    ZPL_ALWAYS_INLINE zpl__memory_fd *zpl__file_stream_from_fd(zpl_file_descriptor fd) {
+        zpl__memory_fd *d = (zpl__memory_fd*)fd.p;
+        ZPL_ASSERT(d->magic == ZPL__FILE_STREAM_FD_MAGIC);
+        return d;
+    }
+
+    void zpl_file_stream_new(zpl_file* file, zpl_allocator allocator) {
+        ZPL_ASSERT_NOT_NULL(file);
+        zpl__memory_fd *d = (zpl__memory_fd*)zpl_alloc(allocator, zpl_size_of(zpl__memory_fd));
+        zpl_zero_item(file);
+        d->magic = ZPL__FILE_STREAM_FD_MAGIC;
+        d->alloc = allocator;
+        d->flags = ZPL_FILE_STREAM_CLONE_WRITABLE;
+        d->cap = 0;
+        zpl_array_init(d->buf, allocator);
+        file->ops = zpl_memory_file_operations;
+        file->fd = zpl__file_stream_fd_make(d);
+        file->dir = NULL;
+        file->last_write_time = 0;
+        file->filename = NULL;
+        file->is_temp = true;
+    }
+    void zpl_file_stream_open(zpl_file* file, zpl_allocator allocator, zpl_u8 *buffer, zpl_isize size, zpl_file_stream_flags flags) {
+        ZPL_ASSERT_NOT_NULL(file);
+        zpl__memory_fd *d = (zpl__memory_fd*)zpl_alloc(allocator, zpl_size_of(zpl__memory_fd));
+        zpl_zero_item(file);
+        d->magic = ZPL__FILE_STREAM_FD_MAGIC;
+        d->alloc = allocator;
+        d->flags = flags;
+        if (d->flags & ZPL_FILE_STREAM_CLONE_WRITABLE) {
+            zpl_array_init_reserve(d->buf, allocator, size);
+            zpl_memcopy(d->buf, buffer, size);
+            d->cap = zpl_array_count(d->buf) = size;
+        } else {
+            d->buf = buffer;
+            d->cap = size;
+        }
+        file->ops = zpl_memory_file_operations;
+        file->fd = zpl__file_stream_fd_make(d);
+        file->dir = NULL;
+        file->last_write_time = 0;
+        file->filename = NULL;
+        file->is_temp = true;
+    }
+
+    zpl_u8 *zpl_file_stream_buf(zpl_file* file, zpl_isize *size) {
+        ZPL_ASSERT_NOT_NULL(file);
+        zpl__memory_fd *d = zpl__file_stream_from_fd(file->fd);
+        if (size) *size = d->cap;
+        return d->buf;
+    }
+
+    zpl_internal ZPL_FILE_SEEK_PROC(zpl__memory_file_seek) {
+        zpl__memory_fd *d = zpl__file_stream_from_fd(fd);
+        zpl_isize buflen = d->cap;
+
+        if (whence == ZPL_SEEK_WHENCE_BEGIN)
+            d->cursor = 0;
+        else if (whence == ZPL_SEEK_WHENCE_END)
+            d->cursor = buflen;
+
+        d->cursor = zpl_max(0, zpl_clamp(d->cursor + offset, 0, buflen));
+        if (new_offset) *new_offset = d->cursor;
+        return true;
+    }
+
+    zpl_internal ZPL_FILE_READ_AT_PROC(zpl__memory_file_read) {
+        zpl_unused(stop_at_newline);
+        zpl__memory_fd *d = zpl__file_stream_from_fd(fd);
+        zpl_memcopy(buffer, d->buf + offset, size);
+        if (bytes_read) *bytes_read = size;
+        return true;
+    }
+
+    zpl_internal ZPL_FILE_WRITE_AT_PROC(zpl__memory_file_write) {
+        zpl__memory_fd *d = zpl__file_stream_from_fd(fd);
+        if (!(d->flags & (ZPL_FILE_STREAM_CLONE_WRITABLE|ZPL_FILE_STREAM_WRITABLE)))
+            return false;
+        zpl_isize buflen = d->cap;
+        zpl_isize extralen = zpl_max(0, size-(buflen-offset));
+        zpl_isize rwlen = size-extralen;
+        zpl_isize new_cap = buflen+extralen;
+        if (d->flags & ZPL_FILE_STREAM_CLONE_WRITABLE) {
+            if(zpl_array_capacity(d->buf) < new_cap) {
+                zpl_array_grow(d->buf, (zpl_i64)(new_cap));
+            }
+        }
+        zpl_memcopy(d->buf + offset, buffer, rwlen);
+
+        if ((d->flags & ZPL_FILE_STREAM_CLONE_WRITABLE) && extralen > 0) {
+            zpl_memcopy(d->buf + offset + rwlen, zpl_ptr_add_const(buffer, rwlen), extralen);
+            d->cap = zpl_array_count(d->buf) = new_cap;
+        } else {
+            extralen = 0;
+        }
+
+        if (bytes_written) *bytes_written = (rwlen+extralen);
+        return true;
+    }
+
+    zpl_internal ZPL_FILE_CLOSE_PROC(zpl__memory_file_close) {
+        zpl__memory_fd *d = zpl__file_stream_from_fd(fd);
+        zpl_allocator alloc = d->alloc;
+        if (d->flags & ZPL_FILE_STREAM_CLONE_WRITABLE)
+            zpl_array_free(d->buf);
+        zpl_free(alloc, d);
+    }
+
+    zpl_file_operations const zpl_memory_file_operations = { zpl__memory_file_read, zpl__memory_file_write,
+        zpl__memory_file_seek, zpl__memory_file_close };
+
+    ZPL_END_C_DECLS
+    // file: source/core/file_misc.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_UNIX) || defined(ZPL_SYSTEM_MACOS)
+        #include <dirent.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_UNIX) && !defined(ZPL_SYSTEM_FREEBSD) && !defined(ZPL_SYSTEM_OPENBSD) && !defined(ZPL_SYSTEM_CYGWIN)
+        #include <sys/sendfile.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+    #   include <io.h>
+    #   include <direct.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_CYGWIN)
+    #   include <io.h>
+    #   include <dirent.h>
+    #   include <windows.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+
+    #if defined(ZPL_SYSTEM_WINDOWS) || defined(ZPL_SYSTEM_CYGWIN)
+        zpl_file_time zpl_fs_last_write_time(char const *filepath) {
+            ULARGE_INTEGER li = { 0 };
+            FILETIME last_write_time = { 0 };
+            WIN32_FILE_ATTRIBUTE_DATA data = { 0 };
+            zpl_allocator a = zpl_heap_allocator( );
+
+            wchar_t *w_text = zpl__alloc_utf8_to_ucs2(a, filepath, NULL);
+            if (w_text == NULL) { return 0; }
+            if (GetFileAttributesExW(w_text, GetFileExInfoStandard, &data)) last_write_time = data.ftLastWriteTime;
+
+            zpl_free(a, w_text);
+
+            li.LowPart = last_write_time.dwLowDateTime;
+            li.HighPart = last_write_time.dwHighDateTime;
+            return cast(zpl_file_time) li.QuadPart;
+        }
+
+        zpl_b32 zpl_fs_copy(char const *existing_filename, char const *new_filename, zpl_b32 fail_if_exists) {
+            zpl_b32 result = false;
+            zpl_allocator a = zpl_heap_allocator( );
+
+            wchar_t *w_old = zpl__alloc_utf8_to_ucs2(a, existing_filename, NULL);
+            if (w_old == NULL) { return false; }
+
+            wchar_t *w_new = zpl__alloc_utf8_to_ucs2(a, new_filename, NULL);
+            if (w_new != NULL) { result = CopyFileW(w_old, w_new, fail_if_exists); }
+
+            zpl_free(a, w_old);
+            zpl_free(a, w_new);
+            return result;
+        }
+
+        zpl_b32 zpl_fs_move(char const *existing_filename, char const *new_filename) {
+            zpl_b32 result = false;
+            zpl_allocator a = zpl_heap_allocator( );
+
+            wchar_t *w_old = zpl__alloc_utf8_to_ucs2(a, existing_filename, NULL);
+            if (w_old == NULL) { return false; }
+
+            wchar_t *w_new = zpl__alloc_utf8_to_ucs2(a, new_filename, NULL);
+            if (w_new != NULL) { result = MoveFileW(w_old, w_new); }
+
+            zpl_free(a, w_old);
+            zpl_free(a, w_new);
+            return result;
+        }
+
+        zpl_b32 zpl_fs_remove(char const *filename) {
+            zpl_b32 result = false;
+            zpl_allocator a = zpl_heap_allocator( );
+
+            wchar_t *w_filename = zpl__alloc_utf8_to_ucs2(a, filename, NULL);
+            if (w_filename == NULL) { return false; }
+
+            result = DeleteFileW(w_filename);
+
+            zpl_free(a, w_filename);
+            return result;
+        }
+
+    #else
+
+        zpl_file_time zpl_fs_last_write_time(char const *filepath) {
+            time_t result = 0;
+            struct stat file_stat;
+
+            if (stat(filepath, &file_stat)) result = file_stat.st_mtime;
+
+            return cast(zpl_file_time) result;
+        }
+
+        #if defined(ZPL_SYSTEM_FREEBSD)
+            #include <sys/types.h>
+            #include <sys/socket.h>
+            #include <sys/uio.h>
+        #endif
+
+
+        zpl_b32 zpl_fs_copy(char const *existing_filename, char const *new_filename, zpl_b32 fail_if_exists) {
+            zpl_unused(fail_if_exists);
+        #if defined(ZPL_SYSTEM_OSX)
+            return copyfile(existing_filename, new_filename, NULL, COPYFILE_DATA) == 0;
+        #elif defined(ZPL_SYSTEM_OPENBSD)
+            ZPL_NOT_IMPLEMENTED;
+            return 0;
+        #else
+            zpl_isize size;
+            int existing_fd = open(existing_filename, O_RDONLY, 0);
+            int new_fd = open(new_filename, O_WRONLY | O_CREAT, 0666);
+
+            struct stat stat_existing;
+            fstat(existing_fd, &stat_existing);
+
+        #if defined(ZPL_SYSTEM_FREEBSD)
+            size = sendfile(new_fd, existing_fd, 0, stat_existing.st_size, NULL, 0, 0);
+        #else
+            size = sendfile(new_fd, existing_fd, 0, stat_existing.st_size);
+        #endif
+
+            close(new_fd);
+            close(existing_fd);
+
+            return size == stat_existing.st_size;
+        #endif
+        }
+
+        zpl_b32 zpl_fs_move(char const *existing_filename, char const *new_filename) {
+            if (link(existing_filename, new_filename) == 0) { return (unlink(existing_filename) != -1); }
+            return false;
+        }
+
+        zpl_b32 zpl_fs_remove(char const *filename) {
+        #if defined(ZPL_SYSTEM_OSX) || defined(ZPL_SYSTEM_EMSCRIPTEN)
+            return (unlink(filename) != -1);
+        #else
+            return (remove(filename) == 0);
+        #endif
+        }
+
+    #endif
+
+    char *zpl_path_get_full_name(zpl_allocator a, char const *path) {
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        wchar_t *w_path = NULL;
+        wchar_t *w_fullpath = NULL;
+        zpl_isize w_len = 0;
+        zpl_isize new_len = 0;
+        zpl_isize new_len1 = 0;
+        char *new_path = 0;
+
+        w_path = zpl__alloc_utf8_to_ucs2(zpl_heap_allocator( ), path, NULL);
+        if (w_path == NULL) { return NULL; }
+
+        w_len = GetFullPathNameW(w_path, 0, NULL, NULL);
+        if (w_len == 0) { return NULL; }
+
+        w_fullpath = zpl_alloc_array(zpl_heap_allocator( ), wchar_t, w_len + 1);
+        GetFullPathNameW(w_path, cast(int) w_len, w_fullpath, NULL);
+        w_fullpath[w_len] = 0;
+
+        zpl_free(zpl_heap_allocator( ), w_path);
+
+        new_len = WideCharToMultiByte(CP_UTF8, WC_ERR_INVALID_CHARS, w_fullpath, cast(int) w_len, NULL, 0, NULL, NULL);
+
+        if (new_len == 0) {
+            zpl_free(zpl_heap_allocator( ), w_fullpath);
+            return NULL;
+        }
+
+        new_path = zpl_alloc_array(a, char, new_len);
+        new_len1 = WideCharToMultiByte(CP_UTF8, WC_ERR_INVALID_CHARS, w_fullpath, cast(int) w_len, new_path,
+                                       cast(int) new_len, NULL, NULL);
+
+        if (new_len1 == 0) {
+            zpl_free(zpl_heap_allocator( ), w_fullpath);
+            zpl_free(a, new_path);
+            return NULL;
+        }
+
+        new_path[new_len] = 0;
+        return new_path;
+    #else
+        char *p, *result, *fullpath = NULL;
+        zpl_isize len;
+        p = realpath(path, NULL);
+        fullpath = p;
+        if (p == NULL) {
+            // NOTE(bill): File does not exist
+            fullpath = cast(char *) path;
+        }
+
+        len = zpl_strlen(fullpath);
+
+        result = zpl_alloc_array(a, char, len + 1);
+        zpl_memmove(result, fullpath, len);
+        result[len] = 0;
+        zpl_free(a, p);
+
+        return result;
+    #endif
+    }
+
+    zpl_file_error zpl_path_mkdir(char const *path, zpl_i32 mode) {
+        zpl_i32 error = 0;
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        error = _wmkdir((const wchar_t *)zpl_utf8_to_ucs2_buf((const zpl_u8 *)path));
+    #else
+        error = mkdir(path, (mode_t)mode);
+    #endif
+
+        if (error == 0) { return ZPL_FILE_ERROR_NONE; }
+
+        switch (errno) {
+            case EPERM:
+            case EACCES: return ZPL_FILE_ERROR_PERMISSION;
+            case EEXIST: return ZPL_FILE_ERROR_EXISTS;
+            case ENAMETOOLONG: return ZPL_FILE_ERROR_NAME_TOO_LONG;
+        }
+
+        return ZPL_FILE_ERROR_UNKNOWN;
+    }
+
+    zpl_file_error zpl_path_rmdir(char const *path) {
+        zpl_i32 error = 0;
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        error = _wrmdir((const wchar_t *)zpl_utf8_to_ucs2_buf((const zpl_u8 *)path));
+    #else
+        error = rmdir(path);
+    #endif
+
+        if (error == 0) { return ZPL_FILE_ERROR_NONE; }
+
+        switch (errno) {
+            case EPERM:
+            case EACCES: return ZPL_FILE_ERROR_PERMISSION;
+            case ENOENT: return ZPL_FILE_ERROR_NOT_EXISTS;
+            case ENOTEMPTY: return ZPL_FILE_ERROR_NOT_EMPTY;
+            case ENAMETOOLONG: return ZPL_FILE_ERROR_NAME_TOO_LONG;
+        }
+
+        return ZPL_FILE_ERROR_UNKNOWN;
+    }
+
+    void zpl__file_direntry(zpl_allocator alloc, char const *dirname, zpl_string *output, zpl_b32 recurse) {
+    #if defined(ZPL_SYSTEM_UNIX) || defined(ZPL_SYSTEM_OSX)
+        DIR *d, *cd;
+        struct dirent *dir;
+        d = opendir(dirname);
+
+        if (d) {
+            while ((dir = readdir(d))) {
+                if (!zpl_strncmp(dir->d_name, "..", 2)) continue;
+                if (dir->d_name[0] == '.' && dir->d_name[1] == 0) continue;
+
+                zpl_string dirpath = zpl_string_make(alloc, dirname);
+                dirpath = zpl_string_appendc(dirpath, "/");
+                dirpath = zpl_string_appendc(dirpath, dir->d_name);
+
+                *output = zpl_string_appendc(*output, dirpath);
+                *output = zpl_string_appendc(*output, "\n");
+
+                if (recurse && (cd = opendir(dirpath)) != NULL) { zpl__file_direntry(alloc, dirpath, output, recurse); }
+                zpl_string_free(dirpath);
+            }
+        }
+    #elif defined(ZPL_SYSTEM_WINDOWS)
+        zpl_usize length = zpl_strlen(dirname);
+        struct _wfinddata_t data;
+        zpl_intptr findhandle;
+
+        char directory[MAX_PATH] = { 0 };
+        zpl_strncpy(directory, dirname, length);
+
+        // keeping it native
+        for (zpl_usize i = 0; i < length; i++) {
+            if (directory[i] == '/') directory[i] = '\\';
+        }
+
+        // remove trailing slashses
+        if (directory[length - 1] == '\\') { directory[length - 1] = '\0'; }
+
+        // attach search pattern
+        zpl_string findpath = zpl_string_make(alloc, directory);
+        findpath = zpl_string_appendc(findpath, "\\");
+        findpath = zpl_string_appendc(findpath, "*");
+
+        findhandle = _wfindfirst((const wchar_t *)zpl_utf8_to_ucs2_buf((const zpl_u8 *)findpath), &data);
+        zpl_string_free(findpath);
+
+        if (findhandle != -1) {
+            do {
+                char *filename = (char *)zpl_ucs2_to_utf8_buf((const zpl_u16 *)data.name);
+                if (!zpl_strncmp(filename, "..", 2)) continue;
+                if (filename[0] == '.' && filename[1] == 0) continue;
+
+                zpl_string dirpath = zpl_string_make(alloc, directory);
+                dirpath = zpl_string_appendc(dirpath, "\\");
+                dirpath = zpl_string_appendc(dirpath, filename);
+
+                *output = zpl_string_appendc(*output, dirpath);
+                *output = zpl_string_appendc(*output, "\n");
+
+                if (recurse && (data.attrib & _A_SUBDIR)) { zpl__file_direntry(alloc, dirpath, output, recurse); }
+
+                zpl_string_free(dirpath);
+            } while (_wfindnext(findhandle, &data) != -1);
+            _findclose(findhandle);
+        }
+    #else
+        // TODO: Implement other OSes
+    #endif
+    }
+
+    zpl_string zpl_path_dirlist(zpl_allocator alloc, char const *dirname, zpl_b32 recurse) {
+        zpl_string buf = zpl_string_make_reserve(alloc, 4);
+        zpl__file_direntry(alloc, dirname, &buf, recurse);
+        return buf;
+    }
+
+    void zpl_dirinfo_init(zpl_dir_info *dir, char const *path) {
+        ZPL_ASSERT_NOT_NULL(dir);
+
+        zpl_dir_info dir_ = {0};
+        *dir = dir_;
+        dir->fullpath = (char const*)zpl_malloc(zpl_strlen(path));
+        zpl_strcpy((char *)dir->fullpath, path);
+
+
+        zpl_string dirlist = zpl_path_dirlist(zpl_heap(), path, false);
+        char **files=zpl_str_split_lines(zpl_heap(), dirlist, false);
+        dir->filenames = files;
+        dir->buf = dirlist;
+
+        zpl_array_init(dir->entries, zpl_heap());
+
+        for (zpl_i32 i=0; i<zpl_array_count(files); ++i) {
+            zpl_dir_entry entry = {0};
+            entry.filename = files[i];
+            entry.type = zpl_fs_get_type(entry.filename);
+
+            zpl_array_append(dir->entries, entry);
+        }
+    }
+
+    zpl_internal void zpl__dirinfo_free_entry(zpl_dir_entry *entry) {
+        if (entry->dir_info) {
+            zpl_dirinfo_free(entry->dir_info);
+            zpl_mfree(entry->dir_info);
+            entry->dir_info = NULL;
+        }
+    }
+
+    void zpl_dirinfo_free(zpl_dir_info *dir) {
+        ZPL_ASSERT_NOT_NULL(dir);
+
+        for (zpl_isize i = 0; i < zpl_array_count(dir->entries); ++i) {
+            zpl__dirinfo_free_entry(dir->entries + i);
+        }
+
+        zpl_array_free(dir->entries);
+        zpl_array_free(dir->filenames);
+        zpl_string_free(dir->buf);
+        zpl_mfree((void *)dir->fullpath);
+    }
+
+
+    zpl_u8 zpl_fs_get_type(char const *path) {
+    #ifdef ZPL_SYSTEM_WINDOWS
+        DWORD attrs = GetFileAttributesW((const wchar_t *)zpl_utf8_to_ucs2_buf((const zpl_u8 *)path));
+
+        if (attrs == INVALID_FILE_ATTRIBUTES) {
+            return ZPL_DIR_TYPE_UNKNOWN;
+        }
+
+        if (attrs & FILE_ATTRIBUTE_DIRECTORY) {
+            return ZPL_DIR_TYPE_FOLDER;
+        }
+        else {
+            return ZPL_DIR_TYPE_FILE;
+        }
+
+    #else
+        struct stat s;
+        if( stat(path,&s) == 0 )
+        {
+            if( s.st_mode & S_IFDIR )
+            {
+                return ZPL_DIR_TYPE_FOLDER;
+            }
+            else
+            {
+                return ZPL_DIR_TYPE_FILE;
+            }
+        }
+    #endif
+
+        return ZPL_DIR_TYPE_UNKNOWN;
+    }
+
+    void zpl_dirinfo_step(zpl_dir_entry *entry) {
+        if (entry->dir_info) {
+            zpl__dirinfo_free_entry(entry);
+        }
+
+        entry->dir_info = (zpl_dir_info *)zpl_malloc(sizeof(zpl_dir_info));
+        zpl_dir_info dir_ = {0};
+        *entry->dir_info = dir_;
+
+        zpl_local_persist char buf[128] = {0};
+        char const *path = entry->filename;
+
+        if (entry->type != ZPL_DIR_TYPE_FOLDER) {
+            zpl_path_fix_slashes((char *)path);
+            char const* slash = zpl_char_last_occurence(path, ZPL_PATH_SEPARATOR);
+            zpl_strncpy(buf, path, slash-path);
+            path = buf;
+        }
+
+        zpl_dirinfo_init(entry->dir_info, path);
+    }
+
+    void zpl_file_dirinfo_refresh(zpl_file *file) {
+        if (file->is_temp)
+            return;
+
+        if (file->dir) {
+            zpl__dirinfo_free_entry(file->dir);
+            zpl_mfree(file->dir);
+            file->dir = NULL;
+        }
+
+        file->dir = (zpl_dir_entry *)zpl_malloc(sizeof(zpl_dir_entry));
+        zpl_dir_entry dir_ = {0};
+        *file->dir = dir_;
+        file->dir->filename = file->filename;
+        file->dir->type = ZPL_DIR_TYPE_FILE;
+
+        zpl_dirinfo_step(file->dir);
+    }
+
+    void zpl_path_fix_slashes(char *path) {
+    #ifdef ZPL_SYSTEM_WINDOWS
+        char *p = path;
+
+        while (*p != '\0') {
+            if (*p == '/')
+                *p = '\\';
+
+            ++p;
+        }
+    #endif
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/print.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    zpl_isize zpl_printf_va(char const *fmt, va_list va) {
+        return zpl_fprintf_va(zpl_file_get_standard(ZPL_FILE_STANDARD_OUTPUT), fmt, va);
+    }
+
+    zpl_isize zpl_printf_err_va(char const *fmt, va_list va) {
+        return zpl_fprintf_va(zpl_file_get_standard(ZPL_FILE_STANDARD_ERROR), fmt, va);
+    }
+
+    zpl_isize zpl_fprintf_va(struct zpl_file *f, char const *fmt, va_list va) {
+        zpl_local_persist char buf[4096];
+        zpl_isize len = zpl_snprintf_va(buf, zpl_size_of(buf), fmt, va);
+        zpl_file_write(f, buf, len - 1); // NOTE: prevent extra whitespace
+        return len;
+    }
+
+    char *zpl_bprintf_va(char const *fmt, va_list va) {
+        zpl_local_persist char buffer[4096];
+        zpl_snprintf_va(buffer, zpl_size_of(buffer), fmt, va);
+        return buffer;
+    }
+
+    zpl_isize zpl_printf(char const *fmt, ...) {
+        zpl_isize res;
+        va_list va;
+        va_start(va, fmt);
+        res = zpl_printf_va(fmt, va);
+        va_end(va);
+        return res;
+    }
+
+    zpl_isize zpl_printf_err(char const *fmt, ...) {
+        zpl_isize res;
+        va_list va;
+        va_start(va, fmt);
+        res = zpl_printf_err_va(fmt, va);
+        va_end(va);
+        return res;
+    }
+
+    zpl_isize zpl_fprintf(struct zpl_file *f, char const *fmt, ...) {
+        zpl_isize res;
+        va_list va;
+        va_start(va, fmt);
+        res = zpl_fprintf_va(f, fmt, va);
+        va_end(va);
+        return res;
+    }
+
+    char *zpl_bprintf(char const *fmt, ...) {
+        va_list va;
+        char *str;
+        va_start(va, fmt);
+        str = zpl_bprintf_va(fmt, va);
+        va_end(va);
+        return str;
+    }
+
+    zpl_isize zpl_snprintf(char *str, zpl_isize n, char const *fmt, ...) {
+        zpl_isize res;
+        va_list va;
+        va_start(va, fmt);
+        res = zpl_snprintf_va(str, n, fmt, va);
+        va_end(va);
+        return res;
+    }
+
+
+    enum {
+        ZPL_FMT_MINUS = ZPL_BIT(0),
+        ZPL_FMT_PLUS  = ZPL_BIT(1),
+        ZPL_FMT_ALT   = ZPL_BIT(2),
+        ZPL_FMT_SPACE = ZPL_BIT(3),
+        ZPL_FMT_ZERO  = ZPL_BIT(4),
+
+        ZPL_FMT_CHAR   = ZPL_BIT(5),
+        ZPL_FMT_SHORT  = ZPL_BIT(6),
+        ZPL_FMT_INT    = ZPL_BIT(7),
+        ZPL_FMT_LONG   = ZPL_BIT(8),
+        ZPL_FMT_LLONG  = ZPL_BIT(9),
+        ZPL_FMT_SIZE   = ZPL_BIT(10),
+        ZPL_FMT_INTPTR = ZPL_BIT(11),
+
+        ZPL_FMT_UNSIGNED = ZPL_BIT(12),
+        ZPL_FMT_LOWER    = ZPL_BIT(13),
+        ZPL_FMT_UPPER    = ZPL_BIT(14),
+        ZPL_FMT_WIDTH    = ZPL_BIT(15),
+
+        ZPL_FMT_DONE = ZPL_BIT(30),
+
+        ZPL_FMT_INTS =
+            ZPL_FMT_CHAR | ZPL_FMT_SHORT | ZPL_FMT_INT  |
+            ZPL_FMT_LONG | ZPL_FMT_LLONG | ZPL_FMT_SIZE | ZPL_FMT_INTPTR
+    };
+
+    typedef struct {
+        zpl_i32 base;
+        zpl_i32 flags;
+        zpl_i32 width;
+        zpl_i32 precision;
+    } zpl__format_info;
+
+    zpl_internal zpl_isize zpl__print_string(char *text, zpl_isize max_len, zpl__format_info *info, char const *str) {
+        zpl_isize res = 0, len = 0;
+        zpl_isize remaining = max_len;
+
+        if (str == NULL && max_len >= 4) {
+            res += zpl_strlcpy(text, "(null)", 6);
+            return res;
+        }
+
+        if (info && info->precision >= 0)
+            len = zpl_strnlen(str, info->precision);
+        else
+            len = zpl_strlen(str);
+
+        if (info && (info->width == 0 && info->flags & ZPL_FMT_WIDTH)) {
+            return res;
+        }
+
+        if (info && (info->width == 0 || info->flags & ZPL_FMT_MINUS)) {
+            if (info->precision > 0) len = info->precision < len ? info->precision : len;
+
+            res += zpl_strlcpy(text, str, len);
+
+            if (info->width > res) {
+                zpl_isize padding = info->width - len;
+                char pad = (info->flags & ZPL_FMT_ZERO) ? '0' : ' ';
+                while (padding-- > 0 && remaining-- > 0) *text++ = pad, res++;
+            }
+        } else {
+            if (info && (info->width > res)) {
+                zpl_isize padding = info->width - len;
+                char pad = (info->flags & ZPL_FMT_ZERO) ? '0' : ' ';
+                while (padding-- > 0 && remaining-- > 0) *text++ = pad, res++;
+            }
+
+            res += zpl_strlcpy(text, str, len);
+        }
+
+        if (info) {
+            if (info->flags & ZPL_FMT_UPPER)
+                zpl_str_to_upper(text);
+            else if (info->flags & ZPL_FMT_LOWER)
+                zpl_str_to_lower(text);
+        }
+
+        return res;
+    }
+
+    zpl_internal zpl_isize zpl__print_char(char *text, zpl_isize max_len, zpl__format_info *info, char arg) {
+        char str[2] = "";
+        str[0] = arg;
+        return zpl__print_string(text, max_len, info, str);
+    }
+
+    zpl_internal zpl_isize zpl__print_i64(char *text, zpl_isize max_len, zpl__format_info *info, zpl_i64 value) {
+        char num[130];
+        zpl_i64_to_str(value, num, info ? info->base : 10);
+        return zpl__print_string(text, max_len, info, num);
+    }
+
+    zpl_internal zpl_isize zpl__print_u64(char *text, zpl_isize max_len, zpl__format_info *info, zpl_u64 value) {
+        char num[130];
+        zpl_u64_to_str(value, num, info ? info->base : 10);
+        return zpl__print_string(text, max_len, info, num);
+    }
+
+    zpl_internal zpl_isize zpl__print_f64(char *text, zpl_isize max_len, zpl__format_info *info, zpl_f64 arg) {
+        // TODO: Handle exponent notation
+        zpl_isize width, len, remaining = max_len;
+        char *text_begin = text;
+
+        if (arg) {
+            zpl_u64 value;
+            if (arg < 0) {
+                if (remaining > 1) *text = '-', remaining--;
+                text++;
+                arg = -arg;
+            } else if (info->flags & ZPL_FMT_MINUS) {
+                if (remaining > 1) *text = '+', remaining--;
+                text++;
+            }
+
+            value = cast(zpl_u64) arg;
+            len = zpl__print_u64(text, remaining, NULL, value);
+            text += len;
+
+            if (len >= remaining)
+                remaining = zpl_min(remaining, 1);
+            else
+                remaining -= len;
+            arg -= value;
+
+            if (info->precision < 0) info->precision = 6;
+
+            if ((info->flags & ZPL_FMT_ALT) || info->precision > 0) {
+                zpl_i64 mult = 10;
+                if (remaining > 1) *text = '.', remaining--;
+                text++;
+                while (info->precision-- > 0) {
+                    value = cast(zpl_u64)(arg * mult);
+                    len = zpl__print_u64(text, remaining, NULL, value);
+                    text += len;
+                    if (len >= remaining)
+                        remaining = zpl_min(remaining, 1);
+                    else
+                        remaining -= len;
+                    arg -= cast(zpl_f64) value / mult;
+                    mult *= 10;
+                }
+            }
+        } else {
+            if (remaining > 1) *text = '0', remaining--;
+            text++;
+            if (info->flags & ZPL_FMT_ALT) {
+                if (remaining > 1) *text = '.', remaining--;
+                text++;
+            }
+        }
+
+        width = info->width - (text - text_begin);
+        if (width > 0) {
+            char fill = (info->flags & ZPL_FMT_ZERO) ? '0' : ' ';
+            char *end = text + remaining - 1;
+            len = (text - text_begin);
+
+            for (len = (text - text_begin); len--;) {
+                if ((text_begin + len + width) < end) *(text_begin + len + width) = *(text_begin + len);
+            }
+
+            len = width;
+            text += len;
+            if (len >= remaining)
+                remaining = zpl_min(remaining, 1);
+            else
+                remaining -= len;
+
+            while (len--) {
+                if (text_begin + len < end) text_begin[len] = fill;
+            }
+        }
+
+        return (text - text_begin);
+    }
+
+    ZPL_NEVER_INLINE zpl_isize zpl_snprintf_va(char *text, zpl_isize max_len, char const *fmt, va_list va) {
+        char const *text_begin = text;
+        zpl_isize remaining = max_len, res;
+
+        while (*fmt) {
+            zpl__format_info info = { 0 };
+            zpl_isize len = 0;
+            info.precision = -1;
+
+            while (*fmt && *fmt != '%' && remaining) *text++ = *fmt++;
+
+            if (*fmt == '%') {
+                do {
+                    switch (*++fmt) {
+                    case '-': {info.flags |= ZPL_FMT_MINUS; break;}
+                    case '+': {info.flags |= ZPL_FMT_PLUS; break;}
+                    case '#': {info.flags |= ZPL_FMT_ALT; break;}
+                    case ' ': {info.flags |= ZPL_FMT_SPACE; break;}
+                    case '0': {info.flags |= (ZPL_FMT_ZERO|ZPL_FMT_WIDTH); break;}
+                    default: {info.flags |= ZPL_FMT_DONE; break;}
+                    }
+                } while (!(info.flags & ZPL_FMT_DONE));
+            }
+
+            // NOTE: Optional Width
+            if (*fmt == '*') {
+                int width = va_arg(va, int);
+                if (width < 0) {
+                    info.flags |= ZPL_FMT_MINUS;
+                    info.width = -width;
+                } else {
+                    info.width = width;
+                }
+                info.flags |= ZPL_FMT_WIDTH;
+                fmt++;
+            } else {
+                info.width = cast(zpl_i32) zpl_str_to_i64(fmt, cast(char **) & fmt, 10);
+                if (info.width != 0) {
+                    info.flags |= ZPL_FMT_WIDTH;
+                }
+            }
+
+            // NOTE: Optional Precision
+            if (*fmt == '.') {
+                fmt++;
+                if (*fmt == '*') {
+                    info.precision = va_arg(va, int);
+                    fmt++;
+                } else {
+                    info.precision = cast(zpl_i32) zpl_str_to_i64(fmt, cast(char **) & fmt, 10);
+                }
+                info.flags &= ~ZPL_FMT_ZERO;
+            }
+
+            switch (*fmt++) {
+                case 'h':
+                if (*fmt == 'h') { // hh => char
+                    info.flags |= ZPL_FMT_CHAR;
+                    fmt++;
+                } else { // h => short
+                    info.flags |= ZPL_FMT_SHORT;
+                }
+                break;
+
+                case 'l':
+                if (*fmt == 'l') { // ll => long long
+                    info.flags |= ZPL_FMT_LLONG;
+                    fmt++;
+                } else { // l => long
+                    info.flags |= ZPL_FMT_LONG;
+                }
+                break;
+
+                break;
+
+                case 'z': // NOTE: zpl_usize
+                    info.flags |= ZPL_FMT_UNSIGNED;
+                    // fallthrough
+                case 't': // NOTE: zpl_isize
+                    info.flags |= ZPL_FMT_SIZE;
+                    break;
+
+                default: fmt--; break;
+            }
+
+            switch (*fmt) {
+                case 'u':
+                    info.flags |= ZPL_FMT_UNSIGNED;
+                    // fallthrough
+                case 'd':
+                case 'i': info.base = 10; break;
+
+                case 'o': info.base = 8; break;
+
+                case 'x':
+                    info.base = 16;
+                    info.flags |= (ZPL_FMT_UNSIGNED | ZPL_FMT_LOWER);
+                    break;
+
+                case 'X':
+                    info.base = 16;
+                    info.flags |= (ZPL_FMT_UNSIGNED | ZPL_FMT_UPPER);
+                    break;
+
+                case 'f':
+                case 'F':
+                case 'g':
+                case 'G': len = zpl__print_f64(text, remaining, &info, va_arg(va, zpl_f64)); break;
+
+                case 'a':
+                case 'A':
+                    // TODO:
+                    break;
+
+                case 'c': len = zpl__print_char(text, remaining, &info, cast(char) va_arg(va, int)); break;
+
+                case 's': len = zpl__print_string(text, remaining, &info, va_arg(va, char *)); break;
+
+                case 'p':
+                    info.base = 16;
+                    info.flags |= (ZPL_FMT_LOWER | ZPL_FMT_UNSIGNED | ZPL_FMT_ALT | ZPL_FMT_INTPTR);
+                    break;
+
+                case '%': len = zpl__print_char(text, remaining, &info, '%'); break;
+
+                default: fmt--; break;
+            }
+
+            fmt++;
+
+            if (info.base != 0) {
+                if (info.flags & ZPL_FMT_UNSIGNED) {
+                    zpl_u64 value = 0;
+                    switch (info.flags & ZPL_FMT_INTS) {
+                        case ZPL_FMT_CHAR:   value = cast(zpl_u64) cast(zpl_u8) va_arg(va, int); break;
+                        case ZPL_FMT_SHORT:  value = cast(zpl_u64) cast(zpl_u16) va_arg(va, int); break;
+                        case ZPL_FMT_LONG:   value = cast(zpl_u64) va_arg(va, unsigned long); break;
+                        case ZPL_FMT_LLONG:  value = cast(zpl_u64) va_arg(va, unsigned long long); break;
+                        case ZPL_FMT_SIZE:   value = cast(zpl_u64) va_arg(va, zpl_usize); break;
+                        case ZPL_FMT_INTPTR: value = cast(zpl_u64) va_arg(va, zpl_uintptr); break;
+                        default: value             = cast(zpl_u64) va_arg(va, unsigned int); break;
+                    }
+
+                    len = zpl__print_u64(text, remaining, &info, value);
+
+                } else {
+                    zpl_i64 value = 0;
+                    switch (info.flags & ZPL_FMT_INTS) {
+                        case ZPL_FMT_CHAR:   value = cast(zpl_i64) cast(zpl_i8) va_arg(va, int); break;
+                        case ZPL_FMT_SHORT:  value = cast(zpl_i64) cast(zpl_i16) va_arg(va, int); break;
+                        case ZPL_FMT_LONG:   value = cast(zpl_i64) va_arg(va, long); break;
+                        case ZPL_FMT_LLONG:  value = cast(zpl_i64) va_arg(va, long long); break;
+                        case ZPL_FMT_SIZE:   value = cast(zpl_i64) va_arg(va, zpl_usize); break;
+                        case ZPL_FMT_INTPTR: value = cast(zpl_i64) va_arg(va, zpl_uintptr); break;
+                        default: value             = cast(zpl_i64) va_arg(va, int); break;
+                    }
+
+                    len = zpl__print_i64(text, remaining, &info, value);
+                }
+            }
+
+            text += len;
+            if (len >= remaining)
+                remaining = zpl_min(remaining, 1);
+            else
+                remaining -= len;
+        }
+
+        *text++ = '\0';
+        res = (text - text_begin);
+        return (res >= max_len || res < 0) ? -1 : res;
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/time.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_MACOS) || ZPL_SYSTEM_UNIX
+        #include <time.h>
+        #include <sys/time.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_MACOS)
+        #include <mach/mach.h>
+        #include <mach/mach_time.h>
+        #include <mach/clock.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_EMSCRIPTEN)
+        #include <emscripten.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        #include <timezoneapi.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    //! @}
+    //$$
+    ////////////////////////////////////////////////////////////////
+    //
+    // Time
+    //
+    //
+
+    #if defined(ZPL_COMPILER_MSVC) && !defined(__clang__)
+        zpl_u64 zpl_rdtsc(void) { return __rdtsc( ); }
+    #elif defined(__i386__)
+        zpl_u64 zpl_rdtsc(void) {
+            zpl_u64 x;
+            __asm__ volatile(".byte 0x0f, 0x31" : "=A"(x));
+            return x;
+        }
+    #elif defined(__x86_64__)
+        zpl_u64 zpl_rdtsc(void) {
+            zpl_u32 hi, lo;
+            __asm__ __volatile__("rdtsc" : "=a"(lo), "=d"(hi));
+            return (cast(zpl_u64) lo) | ((cast(zpl_u64) hi) << 32);
+        }
+    #elif defined(__powerpc__)
+        zpl_u64 zpl_rdtsc(void) {
+            zpl_u64 result = 0;
+            zpl_u32 upper, lower, tmp;
+            __asm__ volatile("0:                   \n"
+                             "\tmftbu   %0         \n"
+                             "\tmftb    %1         \n"
+                             "\tmftbu   %2         \n"
+                             "\tcmpw    %2,%0      \n"
+                             "\tbne     0b         \n"
+                             : "=r"(upper), "=r"(lower), "=r"(tmp));
+            result = upper;
+            result = result << 32;
+            result = result | lower;
+
+            return result;
+        }
+    #elif defined(ZPL_SYSTEM_EMSCRIPTEN)
+        zpl_u64 zpl_rdtsc(void) {
+            return (zpl_u64)(emscripten_get_now() * 1e+6);
+        }
+    #elif defined(ZPL_CPU_ARM)
+        zpl_u64 zpl_rdtsc(void) {
+            #if defined(__aarch64__)
+                int64_t r = 0;
+                asm volatile("mrs %0, cntvct_el0" : "=r"(r));
+            #elif (__ARM_ARCH >= 6)
+                uint32_t r = 0;
+                uint32_t pmccntr;
+                uint32_t pmuseren;
+                uint32_t pmcntenset;
+
+                // Read the user mode perf monitor counter access permissions.
+                asm volatile("mrc p15, 0, %0, c9, c14, 0" : "=r"(pmuseren));
+                if (pmuseren & 1) { // Allows reading perfmon counters for user mode code.
+                    asm volatile("mrc p15, 0, %0, c9, c12, 1" : "=r"(pmcntenset));
+                    if (pmcntenset & 0x80000000ul) { // Is it counting?
+                        asm volatile("mrc p15, 0, %0, c9, c13, 0" : "=r"(pmccntr));
+                        // The counter is set up to count every 64th cycle
+                        return ((int64_t)pmccntr) * 64; // Should optimize to << 6
+                    }
+                }
+            #else
+                #error "No suitable method for zpl_rdtsc for this cpu type"
+            #endif
+
+            return r;
+        }
+    #endif
+
+    #if defined(ZPL_SYSTEM_WINDOWS) || defined(ZPL_SYSTEM_CYGWIN)
+
+        zpl_u64 zpl_time_rel_ms(void) {
+            zpl_local_persist LARGE_INTEGER win32_perf_count_freq = { 0 };
+            zpl_u64 result;
+            LARGE_INTEGER counter;
+            zpl_local_persist LARGE_INTEGER win32_perf_counter = { 0 };
+            if (!win32_perf_count_freq.QuadPart) {
+                QueryPerformanceFrequency(&win32_perf_count_freq);
+                ZPL_ASSERT(win32_perf_count_freq.QuadPart != 0);
+                QueryPerformanceCounter(&win32_perf_counter);
+            }
+
+            QueryPerformanceCounter(&counter);
+
+            result = (counter.QuadPart - win32_perf_counter.QuadPart) * 1000 / (win32_perf_count_freq.QuadPart);
+            return result;
+        }
+
+        zpl_u64 zpl_time_utc_ms(void) {
+            FILETIME ft;
+            ULARGE_INTEGER li;
+
+            GetSystemTimeAsFileTime(&ft);
+            li.LowPart = ft.dwLowDateTime;
+            li.HighPart = ft.dwHighDateTime;
+
+            return li.QuadPart / 1000;
+        }
+
+        zpl_u64 zpl_time_tz_ms(void) {
+            FILETIME ft;
+            SYSTEMTIME st, lst;
+            ULARGE_INTEGER li;
+
+            GetSystemTime(&st);
+            SystemTimeToTzSpecificLocalTime(NULL, &st, &lst);
+            SystemTimeToFileTime(&lst, &ft);
+            li.LowPart = ft.dwLowDateTime;
+            li.HighPart = ft.dwHighDateTime;
+
+            return li.QuadPart / 1000;
+        }
+
+        void zpl_sleep_ms(zpl_u32 ms) { Sleep(ms); }
+
+    #else
+
+        #if defined(ZPL_SYSTEM_LINUX) || defined(ZPL_SYSTEM_FREEBSD) || defined(ZPL_SYSTEM_OPENBSD) || defined(ZPL_SYSTEM_EMSCRIPTEN)
+            zpl_u64 zpl__unix_gettime(void) {
+                struct timespec t;
+                zpl_u64 result;
+
+                clock_gettime(1 /*CLOCK_MONOTONIC*/, &t);
+                result = 1000 * t.tv_sec + 1.0e-6 * t.tv_nsec;
+                return result;
+            }
+        #endif
+
+        zpl_u64 zpl_time_rel_ms(void) {
+        #if defined(ZPL_SYSTEM_OSX)
+            zpl_u64 result;
+
+            zpl_local_persist zpl_u64 timebase = 0;
+            zpl_local_persist zpl_u64 timestart = 0;
+
+            if (!timestart) {
+                mach_timebase_info_data_t tb = { 0 };
+                mach_timebase_info(&tb);
+                timebase = tb.numer;
+                timebase /= tb.denom;
+                timestart = mach_absolute_time();
+            }
+
+            // NOTE: mach_absolute_time() returns things in nanoseconds
+            result = 1.0e-6 * (mach_absolute_time() - timestart) * timebase;
+            return result;
+        #else
+            zpl_local_persist zpl_u64 unix_timestart = 0.0;
+
+            if (!unix_timestart) { unix_timestart = zpl__unix_gettime( ); }
+
+            zpl_u64 now = zpl__unix_gettime( );
+
+            return (now - unix_timestart);
+        #endif
+        }
+
+        zpl_u64 zpl_time_utc_ms(void) {
+            struct timespec t;
+        #if defined(ZPL_SYSTEM_OSX)
+            clock_serv_t cclock;
+            mach_timespec_t mts;
+            host_get_clock_service(mach_host_self( ), CALENDAR_CLOCK, &cclock);
+            clock_get_time(cclock, &mts);
+            mach_port_deallocate(mach_task_self( ), cclock);
+            t.tv_sec = mts.tv_sec;
+            t.tv_nsec = mts.tv_nsec;
+        #else
+            clock_gettime(0 /*CLOCK_REALTIME*/, &t);
+        #endif
+            return (t.tv_sec * 1000 + t.tv_nsec * 1e-6 + ZPL__UNIX_TO_WIN32_EPOCH);
+        }
+
+        void zpl_sleep_ms(zpl_u32 ms) {
+            struct timespec req = { cast(time_t)(ms * 1e-3), cast(long)((ms % 1000) * 1e6) };
+            struct timespec rem = { 0, 0 };
+            nanosleep(&req, &rem);
+        }
+
+        zpl_u64 zpl_time_tz_ms(void) {
+            struct tm t;
+            zpl_u64 result = zpl_time_utc_ms() - ZPL__UNIX_TO_WIN32_EPOCH;
+            zpl_u16 ms = result % 1000;
+            result *= 1e-3;
+            localtime_r((const time_t*)&result, &t);
+            result = (zpl_u64)mktime(&t);
+            return (result - timezone + t.tm_isdst * 3600) * 1000 + ms + ZPL__UNIX_TO_WIN32_EPOCH;
+        }
+    #endif
+
+    zpl_f64 zpl_time_rel(void) {
+        return (zpl_f64)(zpl_time_rel_ms() * 1e-3);
+    }
+
+    zpl_f64 zpl_time_utc(void) {
+        return (zpl_f64)(zpl_time_utc_ms() * 1e-3);
+    }
+
+    zpl_f64 zpl_time_tz(void) {
+        return (zpl_f64)(zpl_time_tz_ms() * 1e-3);
+    }
+
+
+
+    ZPL_END_C_DECLS
+    // file: source/core/random.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #if defined(ZPL_MODULE_THREADING)
+        zpl_global zpl_atomic32 zpl__random_shared_counter = {0};
+    #else
+        zpl_global zpl_i32 zpl__random_shared_counter = 0;
+    #endif
+
+    zpl_internal zpl_u32 zpl__get_noise_from_time(void) {
+        zpl_u32 accum = 0;
+        zpl_f64 start, remaining, end, curr = 0;
+        zpl_u64 interval = 100000ll;
+
+        start     = zpl_time_rel();
+        remaining = (interval - cast(zpl_u64)(interval*start)%interval) / cast(zpl_f64)interval;
+        end       = start + remaining;
+
+        do {
+            curr = zpl_time_rel();
+            accum += cast(zpl_u32)curr;
+        } while (curr >= end);
+        return accum;
+    }
+
+    // NOTE: Partly from http://preshing.com/20121224/how-to-generate-a-sequence-of-unique-random-integers/
+    // But the generation is even more random-er-est
+
+    zpl_internal ZPL_ALWAYS_INLINE zpl_u32 zpl__permute_qpr(zpl_u32 x) {
+        zpl_local_persist zpl_u32 const prime = 4294967291; // 2^32 - 5
+        if (x >= prime) {
+            return x;
+        } else {
+            zpl_u32 residue = cast(zpl_u32)(cast(zpl_u64) x * x) % prime;
+            if (x <= prime / 2)
+                return residue;
+            else
+                return prime - residue;
+        }
+    }
+
+    zpl_internal ZPL_ALWAYS_INLINE zpl_u32 zpl__permute_with_offset(zpl_u32 x, zpl_u32 offset) {
+        return (zpl__permute_qpr(x) + offset) ^ 0x5bf03635;
+    }
+
+
+    void zpl_random_init(zpl_random *r) {
+        zpl_u64 time, tick;
+        zpl_isize i, j;
+        zpl_u32 x = 0;
+        r->value = 0;
+
+        r->offsets[0] = zpl__get_noise_from_time();
+    #ifdef ZPL_MODULE_THREADING
+        r->offsets[1] = zpl_atomic32_fetch_add(&zpl__random_shared_counter, 1);
+        r->offsets[2] = zpl_thread_current_id();
+        r->offsets[3] = zpl_thread_current_id() * 3 + 1;
+    #else
+        r->offsets[1] = zpl__random_shared_counter++;
+        r->offsets[2] = 0;
+        r->offsets[3] = 1;
+    #endif
+        time = zpl_time_tz_ms();
+        r->offsets[4] = cast(zpl_u32)(time >> 32);
+        r->offsets[5] = cast(zpl_u32)time;
+        r->offsets[6] = zpl__get_noise_from_time();
+        tick = zpl_rdtsc();
+        r->offsets[7] = cast(zpl_u32)(tick ^ (tick >> 32));
+
+        for (j = 0; j < 4; j++) {
+            for (i = 0; i < zpl_count_of(r->offsets); i++) {
+                r->offsets[i] = x = zpl__permute_with_offset(x, r->offsets[i]);
+            }
+        }
+    }
+
+    zpl_u32 zpl_random_gen_u32(zpl_random *r) {
+        zpl_u32 x = r->value;
+        zpl_u32 carry = 1;
+        zpl_isize i;
+        for (i = 0; i < zpl_count_of(r->offsets); i++) {
+            x = zpl__permute_with_offset(x, r->offsets[i]);
+            if (carry > 0) {
+                carry = ++r->offsets[i] ? 0 : 1;
+            }
+        }
+
+        r->value = x;
+        return x;
+    }
+
+    zpl_u32 zpl_random_gen_u32_unique(zpl_random *r) {
+        zpl_u32 x = r->value;
+        zpl_isize i;
+        r->value++;
+        for (i = 0; i < zpl_count_of(r->offsets); i++) {
+            x = zpl__permute_with_offset(x, r->offsets[i]);
+        }
+
+        return x;
+    }
+
+    zpl_u64 zpl_random_gen_u64(zpl_random *r) {
+        return ((cast(zpl_u64)zpl_random_gen_u32(r)) << 32) | zpl_random_gen_u32(r);
+    }
+
+
+    zpl_isize zpl_random_gen_isize(zpl_random *r) {
+        zpl_u64 u = zpl_random_gen_u64(r);
+        return *cast(zpl_isize *)&u;
+    }
+
+
+    zpl_i64 zpl_random_range_i64(zpl_random *r, zpl_i64 lower_inc, zpl_i64 higher_inc) {
+        zpl_u64 u = zpl_random_gen_u64(r);
+        zpl_i64 i = *cast(zpl_i64 *)&u;
+        zpl_i64 diff = higher_inc-lower_inc+1;
+        i %= diff;
+        i += lower_inc;
+        return i;
+    }
+
+    zpl_isize zpl_random_range_isize(zpl_random *r, zpl_isize lower_inc, zpl_isize higher_inc) {
+        zpl_u64 u = zpl_random_gen_u64(r);
+        zpl_isize i = *cast(zpl_isize *)&u;
+        zpl_isize diff = higher_inc-lower_inc+1;
+        i %= diff;
+        i += lower_inc;
+        return i;
+    }
+
+    ZPL_ALWAYS_INLINE zpl_f64 zpl__random_copy_sign64(zpl_f64 x, zpl_f64 y) {
+        zpl_i64 ix=0, iy=0;
+        zpl_memcopy(&ix, &x, zpl_size_of(zpl_i64));
+        zpl_memcopy(&iy, &y, zpl_size_of(zpl_i64));
+
+        ix &= 0x7fffffffffffffff;
+        ix |= iy & 0x8000000000000000;
+
+        zpl_f64 r = 0.0;
+        zpl_memcopy(&r, &ix, zpl_size_of(zpl_f64));
+        return r;
+    }
+
+    ZPL_ALWAYS_INLINE zpl_f64 zpl__random_floor64    (zpl_f64 x)        { return cast(zpl_f64)((x >= 0.0) ? cast(zpl_i64)x : cast(zpl_i64)(x-0.9999999999999999)); }
+    ZPL_ALWAYS_INLINE zpl_f64 zpl__random_ceil64     (zpl_f64 x)        { return cast(zpl_f64)((x < 0) ? cast(zpl_i64)x : (cast(zpl_i64)x)+1); }
+    ZPL_ALWAYS_INLINE zpl_f64 zpl__random_round64    (zpl_f64 x)        { return cast(zpl_f64)((x >= 0.0) ? zpl__random_floor64(x + 0.5) : zpl__random_ceil64(x - 0.5)); }
+    ZPL_ALWAYS_INLINE zpl_f64 zpl__random_remainder64(zpl_f64 x, zpl_f64 y) { return x - (zpl__random_round64(x/y)*y); }
+    ZPL_ALWAYS_INLINE zpl_f64 zpl__random_abs64      (zpl_f64 x)        { return x < 0 ? -x : x; }
+    ZPL_ALWAYS_INLINE zpl_f64 zpl__random_sign64     (zpl_f64 x)        { return x < 0 ? -1.0 : +1.0; }
+
+    ZPL_ALWAYS_INLINE zpl_f64 zpl__random_mod64(zpl_f64 x, zpl_f64 y) {
+        zpl_f64 result;
+        y = zpl__random_abs64(y);
+        result = zpl__random_remainder64(zpl__random_abs64(x), y);
+        if (zpl__random_sign64(result)) result += y;
+        return zpl__random_copy_sign64(result, x);
+    }
+
+    zpl_f64 zpl_random_range_f64(zpl_random *r, zpl_f64 lower_inc, zpl_f64 higher_inc) {
+        zpl_u64 u = zpl_random_gen_u64(r);
+        zpl_f64 f = 0;
+        zpl_memcopy(&f, &u, zpl_size_of(zpl_f64));
+        zpl_f64 diff = higher_inc-lower_inc+1.0;
+        f = zpl__random_mod64(f, diff);
+        f += lower_inc;
+        return f;
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/misc.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #if defined(ZPL_SYSTEM_UNIX) || defined(ZPL_SYSTEM_MACOS)
+        #include <sched.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        void zpl_exit(zpl_u32 code) { ExitProcess(code); }
+    #else
+        void zpl_exit(zpl_u32 code) { exit(code); }
+    #endif
+
+    void zpl_yield(void) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            Sleep(0);
+        #else
+            sched_yield();
+        #endif
+    }
+
+    const char *zpl_get_env(const char *name) {
+        char *buffer = NULL;
+        const char *ptr = zpl_get_env_buf(name);
+
+        if (ptr == NULL) {
+            return NULL;
+        }
+
+        zpl_isize ptr_size = zpl_strlen(ptr);
+        buffer = (char *)zpl_malloc(ptr_size * sizeof(char)+1);
+        zpl_memcopy((char *)buffer, ptr, ptr_size+1);
+        return buffer;
+    }
+
+    const char *zpl_get_env_buf(const char *name) {
+        #ifdef ZPL_SYSTEM_WINDOWS
+            zpl_local_persist wchar_t wbuffer[32767] = {0};
+            zpl_local_persist char buffer[32767] = {0};
+
+            if (!GetEnvironmentVariableW(
+                    cast(LPCWSTR)zpl_utf8_to_ucs2_buf(cast(const zpl_u8 *)name),
+                    cast(LPWSTR)wbuffer, 32767)) {
+                return NULL;
+            }
+
+            zpl_ucs2_to_utf8(cast(zpl_u8*)buffer, 32767, cast(const zpl_u16*)wbuffer);
+
+            return (const char *)buffer;
+        #else
+            return (const char *)getenv(name);
+        #endif
+    }
+
+    zpl_string zpl_get_env_str(const char *name) {
+        const char *buf = zpl_get_env_buf(name);
+
+        if (buf == NULL) {
+            return NULL;
+        }
+
+        zpl_string str = zpl_string_make(zpl_heap(), buf);
+        return str;
+    }
+
+    void zpl_set_env(const char *name, const char *value) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            SetEnvironmentVariableA(name, value);
+        #else
+            setenv(name, value, 1);
+        #endif
+    }
+
+    void zpl_unset_env(const char *name) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            SetEnvironmentVariableA(name, NULL);
+        #else
+            unsetenv(name);
+        #endif
+    }
+
+    #if !defined(ZPL_SYSTEM_WINDOWS)
+        extern char **environ;
+    #endif
+
+    zpl_u32 zpl_system_command(const char *command, zpl_usize buffer_len, char *buffer) {
+        #if defined(ZPL_SYSTEM_EMSCRIPTEN)
+            ZPL_PANIC("zpl_system_command not supported");
+        #else
+
+            #if defined(ZPL_SYSTEM_WINDOWS)
+                FILE *handle = _popen(command, "r");
+            #else
+                FILE *handle =  popen(command, "r");
+            #endif
+
+            if(!handle) return 0;
+
+            int c;
+            zpl_usize i=0;
+            while ((c = getc(handle)) != EOF && i++ < buffer_len) {
+                *buffer++ = c;
+            }
+
+            #if defined(ZPL_SYSTEM_WINDOWS)
+                _pclose(handle);
+            #else
+                pclose(handle);
+            #endif
+
+        #endif
+
+        return 1;
+    }
+
+    zpl_string zpl_system_command_str(const char *command, zpl_allocator backing) {
+        #if defined(ZPL_SYSTEM_EMSCRIPTEN)
+            ZPL_PANIC("zpl_system_command not supported");
+        #else
+
+            #if defined(ZPL_SYSTEM_WINDOWS)
+                FILE *handle = _popen(command, "r");
+            #else
+                FILE *handle =  popen(command, "r");
+            #endif
+
+            if(!handle) return NULL;
+
+            zpl_string output = zpl_string_make_reserve(backing, 4);
+
+            int c;
+            while ((c = getc(handle)) != EOF) {
+                char ins[2] = {(char)c,0};
+                output = zpl_string_appendc(output, ins);
+            }
+
+            #if defined(ZPL_SYSTEM_WINDOWS)
+                _pclose(handle);
+            #else
+                pclose(handle);
+            #endif
+            return output;
+        #endif
+        return NULL;
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/core/sort.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #define ZPL__COMPARE_PROC(Type)                                                                                        \
+    zpl_global zpl_isize Type##__cmp_offset;                                                                         \
+    ZPL_COMPARE_PROC(Type##__cmp) {                                                                              \
+        Type const p = *cast(Type const *) zpl_pointer_add_const(a, Type##__cmp_offset);                         \
+        Type const q = *cast(Type const *) zpl_pointer_add_const(b, Type##__cmp_offset);                         \
+        return p < q ? -1 : p > q;                                                                                     \
+    }                                                                                                                  \
+    ZPL_COMPARE_PROC_PTR(Type##_cmp(zpl_isize offset)) {                                                             \
+        Type##__cmp_offset = offset;                                                                             \
+        return &Type##__cmp;                                                                                     \
+    }
+
+    ZPL__COMPARE_PROC(zpl_u8);
+    ZPL__COMPARE_PROC(zpl_i16);
+    ZPL__COMPARE_PROC(zpl_i32);
+    ZPL__COMPARE_PROC(zpl_i64);
+    ZPL__COMPARE_PROC(zpl_isize);
+    ZPL__COMPARE_PROC(zpl_f32);
+    ZPL__COMPARE_PROC(zpl_f64);
+
+    // NOTE: str_cmp is special as it requires a funny type and funny comparison
+    zpl_global zpl_isize zpl__str_cmp_offset;
+    ZPL_COMPARE_PROC(zpl__str_cmp) {
+        char const *p = *cast(char const **) zpl_pointer_add_const(a, zpl__str_cmp_offset);
+        char const *q = *cast(char const **) zpl_pointer_add_const(b, zpl__str_cmp_offset);
+        return zpl_strcmp(p, q);
+    }
+    ZPL_COMPARE_PROC_PTR(zpl_str_cmp(zpl_isize offset)) {
+        zpl__str_cmp_offset = offset;
+        return &zpl__str_cmp;
+    }
+
+    #undef ZPL__COMPARE_PROC
+
+    // TODO: Make user definable?
+    #define ZPL__SORT_STACK_SIZE 64
+    #define zpl__SORT_INSERT_SORT_TRESHOLD 8
+
+    #define ZPL__SORT_PUSH(_base, _limit)                                                                                  \
+    do {                                                                                                               \
+        stack_ptr[0] = (_base);                                                                                        \
+        stack_ptr[1] = (_limit);                                                                                       \
+        stack_ptr += 2;                                                                                                \
+    } while (0)
+
+    #define ZPL__SORT_POP(_base, _limit)                                                                                   \
+    do {                                                                                                               \
+        stack_ptr -= 2;                                                                                                \
+        (_base) = stack_ptr[0];                                                                                        \
+        (_limit) = stack_ptr[1];                                                                                       \
+    } while (0)
+
+    void zpl_sort(void *base_, zpl_isize count, zpl_isize size, zpl_compare_proc cmp) {
+        zpl_u8 *i, *j;
+        zpl_u8 *base = cast(zpl_u8 *) base_;
+        zpl_u8 *limit = base + count * size;
+        zpl_isize threshold = zpl__SORT_INSERT_SORT_TRESHOLD * size;
+
+        // NOTE: Prepare the stack
+        zpl_u8 *stack[ZPL__SORT_STACK_SIZE] = { 0 };
+        zpl_u8 **stack_ptr = stack;
+
+        for (;;) {
+            if ((limit - base) > threshold) {
+                // NOTE: Quick sort
+                i = base + size;
+                j = limit - size;
+
+                zpl_memswap(((limit - base) / size / 2) * size + base, base, size);
+                if (cmp(i, j) > 0) zpl_memswap(i, j, size);
+                if (cmp(base, j) > 0) zpl_memswap(base, j, size);
+                if (cmp(i, base) > 0) zpl_memswap(i, base, size);
+
+                for (;;) {
+                    do
+                        i += size;
+                    while (cmp(i, base) < 0);
+                    do
+                        j -= size;
+                    while (cmp(j, base) > 0);
+                    if (i > j) break;
+                    zpl_memswap(i, j, size);
+                }
+
+                zpl_memswap(base, j, size);
+
+                if (j - base > limit - i) {
+                    ZPL__SORT_PUSH(base, j);
+                    base = i;
+                } else {
+                    ZPL__SORT_PUSH(i, limit);
+                    limit = j;
+                }
+            } else {
+                // NOTE: Insertion sort
+                for (j = base, i = j + size; i < limit; j = i, i += size) {
+                    for (; cmp(j, j + size) > 0; j -= size) {
+                        zpl_memswap(j, j + size, size);
+                        if (j == base) break;
+                    }
+                }
+
+                if (stack_ptr == stack) break; // NOTE: Sorting is done!
+                ZPL__SORT_POP(base, limit);
+            }
+        }
+    }
+
+    #undef ZPL__SORT_PUSH
+    #undef ZPL__SORT_POP
+
+    #define ZPL_RADIX_SORT_PROC_GEN(Type)                                                                                  \
+    ZPL_RADIX_SORT_PROC(Type) {                                                                                        \
+        zpl_##Type *source = items;                                                                                          \
+        zpl_##Type *dest = temp;                                                                                             \
+        zpl_isize byte_index, i, byte_max = 8 * zpl_size_of(zpl_##Type);                                                         \
+        for (byte_index = 0; byte_index < byte_max; byte_index += 8) {                                                 \
+            zpl_isize offsets[256] = { 0 };                                                                                \
+            zpl_isize total = 0;                                                                                           \
+            /* NOTE: First pass - count how many of each key */                                                        \
+            for (i = 0; i < count; i++) {                                                                              \
+                zpl_##Type radix_value = source[i];                                                                          \
+                zpl_##Type radix_piece = (radix_value >> byte_index) & 0xff;                                                 \
+                offsets[radix_piece]++;                                                                                \
+            }                                                                                                          \
+            /* NOTE: Change counts to offsets */                                                                       \
+            for (i = 0; i < zpl_count_of(offsets); i++) {                                                              \
+                zpl_isize skcount = offsets[i];                                                                            \
+                offsets[i] = total;                                                                                    \
+                total += skcount;                                                                                      \
+            }                                                                                                          \
+            /* NOTE: Second pass - place elements into the right location */                                           \
+            for (i = 0; i < count; i++) {                                                                              \
+                zpl_##Type radix_value = source[i];                                                                          \
+                zpl_##Type radix_piece = (radix_value >> byte_index) & 0xff;                                                 \
+                dest[offsets[radix_piece]++] = source[i];                                                              \
+            }                                                                                                          \
+            zpl_swap(zpl_##Type *, source, dest);                                                                            \
+        }                                                                                                              \
+    }
+
+    ZPL_RADIX_SORT_PROC_GEN(u8);
+    ZPL_RADIX_SORT_PROC_GEN(u16);
+    ZPL_RADIX_SORT_PROC_GEN(u32);
+    ZPL_RADIX_SORT_PROC_GEN(u64);
+
+    void zpl_shuffle(void *base, zpl_isize count, zpl_isize size) {
+        zpl_u8 *a;
+        zpl_isize i, j;
+        zpl_random random;
+        zpl_random_init(&random);
+
+        a = cast(zpl_u8 *) base + (count - 1) * size;
+        for (i = count; i > 1; i--) {
+            j = zpl_random_gen_isize(&random) % i;
+            zpl_memswap(a, cast(zpl_u8 *) base + j * size, size);
+            a -= size;
+        }
+    }
+
+    void zpl_reverse(void *base, zpl_isize count, zpl_isize size) {
+        zpl_isize i, j = count - 1;
+        for (i = 0; i < j; i++, j++) zpl_memswap(cast(zpl_u8 *) base + i * size, cast(zpl_u8 *) base + j * size, size);
+    }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_TIMER)
+    // file: source/timer.c
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Timer
+    //
+    //
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    zpl_timer *zpl_timer_add(zpl_timer_pool pool) {
+        ZPL_ASSERT(pool);
+
+        zpl_timer t = { 0 };
+        zpl_array_append(pool, t);
+        return pool + (zpl_array_count(pool) - 1);
+    }
+
+    void zpl_timer_set(zpl_timer *t, zpl_f64 duration, zpl_i32 count, zpl_timer_cb cb) {
+        ZPL_ASSERT(t);
+
+        t->duration = duration;
+        t->remaining_calls = t->initial_calls = count;
+        t->callback = cb;
+        t->enabled = false;
+    }
+
+    void zpl_timer_start(zpl_timer *t, zpl_f64 delay_start) {
+        ZPL_ASSERT(t && !t->enabled);
+
+        t->enabled = true;
+        t->remaining_calls = t->initial_calls;
+        t->next_call_ts = zpl_time_rel( ) + delay_start;
+    }
+
+    void zpl_timer_stop(zpl_timer *t) {
+        ZPL_ASSERT(t && t->enabled);
+
+        t->enabled = false;
+    }
+
+    void zpl_timer_update(zpl_timer_pool pool) {
+        ZPL_ASSERT(pool);
+
+        zpl_f64 now = zpl_time_rel( );
+
+        for (zpl_isize i = 0; i < zpl_array_count(pool); ++i) {
+            zpl_timer *t = pool + i;
+
+            if (t->enabled) {
+                if (t->remaining_calls > 0 || t->initial_calls == -1) {
+                    if (t->next_call_ts <= now) {
+                        if (t->initial_calls != -1) { --t->remaining_calls; }
+
+                        if (t->remaining_calls == 0) {
+                            t->enabled = false;
+                        } else {
+                            t->next_call_ts = now + t->duration;
+                        }
+
+                        t->callback(t->user_data);
+                    }
+                }
+            }
+        }
+    }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_HASHING)
+    // file: source/hashing.c
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Hashing functions
+    //
+    //
+
+    #ifdef ZPL_EDITOR
+    #include "../zpl.h"
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    zpl_u32 zpl_adler32(void const *data, zpl_isize len) {
+        zpl_u32 const MOD_ALDER = 65521;
+        zpl_u32 a = 1, b = 0;
+        zpl_isize i, block_len;
+        zpl_u8 const *bytes = cast(zpl_u8 const *) data;
+
+        block_len = len % 5552;
+
+        while (len) {
+            for (i = 0; i + 7 < block_len; i += 8) {
+                a += bytes[0], b += a;
+                a += bytes[1], b += a;
+                a += bytes[2], b += a;
+                a += bytes[3], b += a;
+                a += bytes[4], b += a;
+                a += bytes[5], b += a;
+                a += bytes[6], b += a;
+                a += bytes[7], b += a;
+
+                bytes += 8;
+            }
+            for (; i < block_len; i++) a += *bytes++, b += a;
+
+            a %= MOD_ALDER, b %= MOD_ALDER;
+            len -= block_len;
+            block_len = 5552;
+        }
+
+        return (b << 16) | a;
+    }
+
+    zpl_global zpl_u32 const ZPL__CRC32_TABLE[256] = {
+        0x00000000, 0x77073096, 0xee0e612c, 0x990951ba, 0x076dc419, 0x706af48f, 0xe963a535, 0x9e6495a3, 0x0edb8832,
+        0x79dcb8a4, 0xe0d5e91e, 0x97d2d988, 0x09b64c2b, 0x7eb17cbd, 0xe7b82d07, 0x90bf1d91, 0x1db71064, 0x6ab020f2,
+        0xf3b97148, 0x84be41de, 0x1adad47d, 0x6ddde4eb, 0xf4d4b551, 0x83d385c7, 0x136c9856, 0x646ba8c0, 0xfd62f97a,
+        0x8a65c9ec, 0x14015c4f, 0x63066cd9, 0xfa0f3d63, 0x8d080df5, 0x3b6e20c8, 0x4c69105e, 0xd56041e4, 0xa2677172,
+        0x3c03e4d1, 0x4b04d447, 0xd20d85fd, 0xa50ab56b, 0x35b5a8fa, 0x42b2986c, 0xdbbbc9d6, 0xacbcf940, 0x32d86ce3,
+        0x45df5c75, 0xdcd60dcf, 0xabd13d59, 0x26d930ac, 0x51de003a, 0xc8d75180, 0xbfd06116, 0x21b4f4b5, 0x56b3c423,
+        0xcfba9599, 0xb8bda50f, 0x2802b89e, 0x5f058808, 0xc60cd9b2, 0xb10be924, 0x2f6f7c87, 0x58684c11, 0xc1611dab,
+        0xb6662d3d, 0x76dc4190, 0x01db7106, 0x98d220bc, 0xefd5102a, 0x71b18589, 0x06b6b51f, 0x9fbfe4a5, 0xe8b8d433,
+        0x7807c9a2, 0x0f00f934, 0x9609a88e, 0xe10e9818, 0x7f6a0dbb, 0x086d3d2d, 0x91646c97, 0xe6635c01, 0x6b6b51f4,
+        0x1c6c6162, 0x856530d8, 0xf262004e, 0x6c0695ed, 0x1b01a57b, 0x8208f4c1, 0xf50fc457, 0x65b0d9c6, 0x12b7e950,
+        0x8bbeb8ea, 0xfcb9887c, 0x62dd1ddf, 0x15da2d49, 0x8cd37cf3, 0xfbd44c65, 0x4db26158, 0x3ab551ce, 0xa3bc0074,
+        0xd4bb30e2, 0x4adfa541, 0x3dd895d7, 0xa4d1c46d, 0xd3d6f4fb, 0x4369e96a, 0x346ed9fc, 0xad678846, 0xda60b8d0,
+        0x44042d73, 0x33031de5, 0xaa0a4c5f, 0xdd0d7cc9, 0x5005713c, 0x270241aa, 0xbe0b1010, 0xc90c2086, 0x5768b525,
+        0x206f85b3, 0xb966d409, 0xce61e49f, 0x5edef90e, 0x29d9c998, 0xb0d09822, 0xc7d7a8b4, 0x59b33d17, 0x2eb40d81,
+        0xb7bd5c3b, 0xc0ba6cad, 0xedb88320, 0x9abfb3b6, 0x03b6e20c, 0x74b1d29a, 0xead54739, 0x9dd277af, 0x04db2615,
+        0x73dc1683, 0xe3630b12, 0x94643b84, 0x0d6d6a3e, 0x7a6a5aa8, 0xe40ecf0b, 0x9309ff9d, 0x0a00ae27, 0x7d079eb1,
+        0xf00f9344, 0x8708a3d2, 0x1e01f268, 0x6906c2fe, 0xf762575d, 0x806567cb, 0x196c3671, 0x6e6b06e7, 0xfed41b76,
+        0x89d32be0, 0x10da7a5a, 0x67dd4acc, 0xf9b9df6f, 0x8ebeeff9, 0x17b7be43, 0x60b08ed5, 0xd6d6a3e8, 0xa1d1937e,
+        0x38d8c2c4, 0x4fdff252, 0xd1bb67f1, 0xa6bc5767, 0x3fb506dd, 0x48b2364b, 0xd80d2bda, 0xaf0a1b4c, 0x36034af6,
+        0x41047a60, 0xdf60efc3, 0xa867df55, 0x316e8eef, 0x4669be79, 0xcb61b38c, 0xbc66831a, 0x256fd2a0, 0x5268e236,
+        0xcc0c7795, 0xbb0b4703, 0x220216b9, 0x5505262f, 0xc5ba3bbe, 0xb2bd0b28, 0x2bb45a92, 0x5cb36a04, 0xc2d7ffa7,
+        0xb5d0cf31, 0x2cd99e8b, 0x5bdeae1d, 0x9b64c2b0, 0xec63f226, 0x756aa39c, 0x026d930a, 0x9c0906a9, 0xeb0e363f,
+        0x72076785, 0x05005713, 0x95bf4a82, 0xe2b87a14, 0x7bb12bae, 0x0cb61b38, 0x92d28e9b, 0xe5d5be0d, 0x7cdcefb7,
+        0x0bdbdf21, 0x86d3d2d4, 0xf1d4e242, 0x68ddb3f8, 0x1fda836e, 0x81be16cd, 0xf6b9265b, 0x6fb077e1, 0x18b74777,
+        0x88085ae6, 0xff0f6a70, 0x66063bca, 0x11010b5c, 0x8f659eff, 0xf862ae69, 0x616bffd3, 0x166ccf45, 0xa00ae278,
+        0xd70dd2ee, 0x4e048354, 0x3903b3c2, 0xa7672661, 0xd06016f7, 0x4969474d, 0x3e6e77db, 0xaed16a4a, 0xd9d65adc,
+        0x40df0b66, 0x37d83bf0, 0xa9bcae53, 0xdebb9ec5, 0x47b2cf7f, 0x30b5ffe9, 0xbdbdf21c, 0xcabac28a, 0x53b39330,
+        0x24b4a3a6, 0xbad03605, 0xcdd70693, 0x54de5729, 0x23d967bf, 0xb3667a2e, 0xc4614ab8, 0x5d681b02, 0x2a6f2b94,
+        0xb40bbe37, 0xc30c8ea1, 0x5a05df1b, 0x2d02ef8d,
+    };
+
+    zpl_u32 zpl_crc32(void const *data, zpl_isize len) {
+        zpl_isize remaining;
+        zpl_u32 result = ~(cast(zpl_u32) 0);
+        zpl_u8 const *c = cast(zpl_u8 const *) data;
+        for (remaining = len; remaining--; c++) result = (result >> 8) ^ (ZPL__CRC32_TABLE[(result ^ *c) & 0xff]);
+        return ~result;
+    }
+
+    zpl_u32 zpl_fnv32(void const *data, zpl_isize len) {
+        zpl_isize i;
+        zpl_u32 h = 0x811c9dc5;
+        zpl_u8 const *c = cast(zpl_u8 const *) data;
+
+        for (i = 0; i < len; i++) h = (h * 0x01000193) ^ c[i];
+
+        return h;
+    }
+
+    zpl_u64 zpl_fnv64(void const *data, zpl_isize len) {
+        zpl_isize i;
+        zpl_u64 h = 0xcbf29ce484222325ull;
+        zpl_u8 const *c = cast(zpl_u8 const *) data;
+
+        for (i = 0; i < len; i++) h = (h * 0x100000001b3ll) ^ c[i];
+
+        return h;
+    }
+
+    zpl_u32 zpl_fnv32a(void const *data, zpl_isize len) {
+        zpl_isize i;
+        zpl_u32 h = 0x811c9dc5;
+        zpl_u8 const *c = cast(zpl_u8 const *) data;
+
+        for (i = 0; i < len; i++) h = (h ^ c[i]) * 0x01000193;
+
+        return h;
+    }
+
+    zpl_u64 zpl_fnv64a(void const *data, zpl_isize len) {
+        zpl_isize i;
+        zpl_u64 h = 0xcbf29ce484222325ull;
+        zpl_u8 const *c = cast(zpl_u8 const *) data;
+
+        for (i = 0; i < len; i++) h = (h ^ c[i]) * 0x100000001b3ll;
+
+        return h;
+    }
+
+    // base64 implementation based on https://nachtimwald.com/2017/11/18/base64-encode-and-decode-in-c/
+    //
+    zpl_global zpl_u8 zpl__base64_chars[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/";
+
+
+    /* generated table based on: */
+    #if 0
+    void zpl__base64_decode_table() {
+        zpl_i32 inv[80];
+        zpl_isize i;
+
+        zpl_memset(inv, -1, zpl_size_of(inv));
+
+        for (i=0; i < zpl_size_of(zpl__base64_chars)-1; i++) {
+            inv[zpl__base64_chars[i]-43] = i;
+        }
+    }
+    #endif
+    /* === */
+    zpl_global zpl_i32 zpl__base64_dec_table[] = {
+        62, -1, -1, -1, 63, 52, 53, 54, 55, 56, 57, 58,
+        59, 60, 61, -1, -1, -1, -1, -1, -1, -1, 0, 1, 2, 3, 4, 5,
+        6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20,
+        21, 22, 23, 24, 25, -1, -1, -1, -1, -1, -1, 26, 27, 28,
+        29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42,
+        43, 44, 45, 46, 47, 48, 49, 50, 51 };
+
+    zpl_isize zpl__base64_encoded_size(zpl_isize len) {
+        zpl_isize ret = len;
+
+        if (len % 3 != 0) {
+            ret += 3 - (len % 3);
+        }
+
+        ret /= 3;
+        ret *= 4;
+
+        return ret;
+    }
+
+    zpl_isize zpl__base64_decoded_size(void const *data) {
+        zpl_isize len, ret, i;
+        const zpl_u8 *s = cast(const zpl_u8 *)data;
+
+        if (s == NULL) {
+            return 0;
+        }
+
+        len = zpl_strlen(cast(const char*)s);
+        ret = len / 4 * 3;
+
+        for (i=len; i-- > 0;) {
+            if (s[i] == '=') {
+                ret--;
+            } else {
+                break;
+            }
+        }
+
+        return ret;
+    }
+
+    zpl_b32 zpl__base64_valid_char(zpl_u8 c) {
+        if (c >= '0' && c <= '9')
+            return true;
+        if (c >= 'A' && c <= 'Z')
+            return true;
+        if (c >= 'a' && c <= 'z')
+            return true;
+        if (c == '+' || c == '/' || c == '=')
+            return true;
+
+        return false;
+    }
+
+    zpl_u8 *zpl_base64_encode(zpl_allocator a, void const *data, zpl_isize len) {
+        const zpl_u8 *s = cast(const zpl_u8*)data;
+        zpl_u8 *ret = NULL;
+        zpl_isize enc_len, i, j, v;
+
+        if (data == NULL || len == 0) {
+            return NULL;
+        }
+
+        enc_len = zpl__base64_encoded_size(len);
+        ret = cast(zpl_u8 *)zpl_alloc(a, enc_len+1);
+        ret[enc_len] = 0;
+
+        for (i=0, j=0; i < len; i+=3, j+=4) {
+            v = s[i];
+            v = (i+1 < len) ? (v << 8 | s[i+1]) : (v << 8);
+            v = (i+2 < len) ? (v << 8 | s[i+2]) : (v << 8);
+
+            ret[j] = zpl__base64_chars[(v >> 18) & 0x3F];
+            ret[j+1] = zpl__base64_chars[(v >> 12) & 0x3F];
+
+            if (i+1 < len)
+                ret[j+2] = zpl__base64_chars[(v >> 6) & 0x3F];
+
+            else ret[j+2] = '=';
+
+            if (i+2 < len)
+                ret[j+3] = zpl__base64_chars[v & 0x3F];
+
+            else ret[j+3] = '=';
+
+        }
+
+        return ret;
+    }
+
+    zpl_u8 *zpl_base64_decode(zpl_allocator a, void const *data, zpl_isize len) {
+        const zpl_u8 *s = cast(const zpl_u8*)data;
+        zpl_u8 *ret = NULL;
+        zpl_isize alen, i, j, v;
+
+        if (data == NULL) {
+            return NULL;
+        }
+
+        alen = zpl__base64_decoded_size(s);
+        ret = cast(zpl_u8 *)zpl_alloc(a, alen+1);
+
+        ZPL_ASSERT_NOT_NULL(ret);
+
+        ret[alen] = 0;
+
+        for (i=0; i<len; i++) {
+            if (!zpl__base64_valid_char(s[i]))
+                return NULL;
+        }
+
+        for (i=0, j=0; i<len; i+=4, j+=3) {
+            v = zpl__base64_dec_table[s[i]-43];
+            v = (v << 6) | zpl__base64_dec_table[s[i+1]-43];
+            v = (s[i+2] == '=') ? (v << 6) : ((v << 6) | zpl__base64_dec_table[s[i+2]-43]);
+            v = (s[i+3] == '=') ? (v << 6) : ((v << 6) | zpl__base64_dec_table[s[i+3]-43]);
+
+            ret[j] = (v >> 16) & 0xFF;
+
+            if (s[i+2] != '=')
+                ret[j+1] = (v >> 8) & 0xFF;
+
+            if (s[i+3] != '=')
+                ret[j+2] = v & 0xFF;
+        }
+
+        return ret;
+    }
+
+    zpl_u32 zpl_murmur32_seed(void const *data, zpl_isize len, zpl_u32 seed) {
+        zpl_u32 const c1 = 0xcc9e2d51;
+        zpl_u32 const c2 = 0x1b873593;
+        zpl_u32 const r1 = 15;
+        zpl_u32 const r2 = 13;
+        zpl_u32 const m = 5;
+        zpl_u32 const n = 0xe6546b64;
+
+        zpl_isize i, nblocks = len / 4;
+        zpl_u32 hash = seed, k1 = 0;
+        zpl_u32 const *blocks = cast(zpl_u32 const *) data;
+        zpl_u8 const *tail = cast(zpl_u8 const *)(data) + nblocks * 4;
+
+        for (i = 0; i < nblocks; i++) {
+            zpl_u32 k = blocks[i];
+            k *= c1;
+            k = (k << r1) | (k >> (32 - r1));
+            k *= c2;
+
+            hash ^= k;
+            hash = ((hash << r2) | (hash >> (32 - r2))) * m + n;
+        }
+
+        switch (len & 3) {
+            case 3: k1 ^= tail[2] << 16;
+            case 2: k1 ^= tail[1] << 8;
+            case 1:
+            k1 ^= tail[0];
+
+            k1 *= c1;
+            k1 = (k1 << r1) | (k1 >> (32 - r1));
+            k1 *= c2;
+            hash ^= k1;
+        }
+
+        hash ^= len;
+        hash ^= (hash >> 16);
+        hash *= 0x85ebca6b;
+        hash ^= (hash >> 13);
+        hash *= 0xc2b2ae35;
+        hash ^= (hash >> 16);
+
+        return hash;
+    }
+
+    zpl_u64 zpl_murmur64_seed(void const *data_, zpl_isize len, zpl_u64 seed) {
+    #if defined(ZPL_ARCH_64_BIT)
+        zpl_u64 const m = 0xc6a4a7935bd1e995ULL;
+        zpl_i32 const r = 47;
+
+        zpl_u64 h = seed ^ (len * m);
+
+        zpl_u64 const *data = cast(zpl_u64 const *) data_;
+        zpl_u8 const *data2 = cast(zpl_u8 const *) data_;
+        zpl_u64 const *end = data + (len / 8);
+
+        while (data != end) {
+            zpl_u64 k = *data++;
+
+            k *= m;
+            k ^= k >> r;
+            k *= m;
+
+            h ^= k;
+            h *= m;
+        }
+
+        switch (len & 7) {
+            case 7: h ^= cast(zpl_u64)(data2[6]) << 48;
+            case 6: h ^= cast(zpl_u64)(data2[5]) << 40;
+            case 5: h ^= cast(zpl_u64)(data2[4]) << 32;
+            case 4: h ^= cast(zpl_u64)(data2[3]) << 24;
+            case 3: h ^= cast(zpl_u64)(data2[2]) << 16;
+            case 2: h ^= cast(zpl_u64)(data2[1]) << 8;
+            case 1: h ^= cast(zpl_u64)(data2[0]); 
+                    h *= m;
+        };
+
+        h ^= h >> r;
+        h *= m;
+        h ^= h >> r;
+
+        return h;
+    #else
+        zpl_u64 h;
+        zpl_u32 const m = 0x5bd1e995;
+        zpl_i32 const r = 24;
+
+        zpl_u32 h1 = cast(zpl_u32)(seed) ^ cast(zpl_u32)(len);
+        zpl_u32 h2 = cast(zpl_u32)(seed >> 32);
+
+        zpl_u32 const *data = cast(zpl_u32 const *) data_;
+
+        while (len >= 8) {
+            zpl_u32 k1, k2;
+            k1 = *data++;
+            k1 *= m;
+            k1 ^= k1 >> r;
+            k1 *= m;
+            h1 *= m;
+            h1 ^= k1;
+            len -= 4;
+
+            k2 = *data++;
+            k2 *= m;
+            k2 ^= k2 >> r;
+            k2 *= m;
+            h2 *= m;
+            h2 ^= k2;
+            len -= 4;
+        }
+
+        if (len >= 4) {
+            zpl_u32 k1 = *data++;
+            k1 *= m;
+            k1 ^= k1 >> r;
+            k1 *= m;
+            h1 *= m;
+            h1 ^= k1;
+            len -= 4;
+        }
+
+        switch (len) {
+            case 3: h2 ^= (cast(zpl_u8 const *) data)[2] << 16;
+            case 2: h2 ^= (cast(zpl_u8 const *) data)[1] << 8;
+            case 1: h2 ^= (cast(zpl_u8 const *) data)[0] << 0; h2 *= m;
+        };
+
+        h1 ^= h2 >> 18;
+        h1 *= m;
+        h2 ^= h1 >> 22;
+        h2 *= m;
+        h1 ^= h2 >> 17;
+        h1 *= m;
+        h2 ^= h1 >> 19;
+        h2 *= m;
+
+        h = h1;
+        h = (h << 32) | h2;
+
+        return h;
+    #endif
+    }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_REGEX)
+    // file: source/regex.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    typedef enum zplreOp {
+        ZPL_RE_OP_BEGIN_CAPTURE,
+        ZPL_RE_OP_END_CAPTURE,
+
+        ZPL_RE_OP_BEGINNING_OF_LINE,
+        ZPL_RE_OP_END_OF_LINE,
+
+        ZPL_RE_OP_EXACT_MATCH,
+        ZPL_RE_OP_META_MATCH,
+
+        ZPL_RE_OP_ANY,
+        ZPL_RE_OP_ANY_OF,
+        ZPL_RE_OP_ANY_BUT,
+
+        ZPL_RE_OP_ZERO_OR_MORE,
+        ZPL_RE_OP_ONE_OR_MORE,
+        ZPL_RE_OP_ZERO_OR_MORE_SHORTEST,
+        ZPL_RE_OP_ONE_OR_MORE_SHORTEST,
+        ZPL_RE_OP_ZERO_OR_ONE,
+
+        ZPL_RE_OP_BRANCH_START,
+        ZPL_RE_OP_BRANCH_END
+    } zplreOp;
+
+    typedef enum zplreCode {
+        ZPL_RE_CODE_NULL              = 0x0000,
+        ZPL_RE_CODE_WHITESPACE        = 0x0100,
+        ZPL_RE_CODE_NOT_WHITESPACE    = 0x0200,
+        ZPL_RE_CODE_DIGIT             = 0x0300,
+        ZPL_RE_CODE_NOT_DIGIT         = 0x0400,
+        ZPL_RE_CODE_ALPHA             = 0x0500,
+        ZPL_RE_CODE_LOWER             = 0x0600,
+        ZPL_RE_CODE_UPPER             = 0x0700,
+        ZPL_RE_CODE_WORD              = 0x0800,
+        ZPL_RE_CODE_NOT_WORD          = 0x0900,
+
+        ZPL_RE_CODE_XDIGIT            = 0x0a00,
+        ZPL_RE_CODE_PRINTABLE         = 0x0b00,
+    } zplreCode;
+
+    typedef struct {
+        zpl_isize op, offset;
+    } zpl_re_ctx;
+
+    enum {
+        ZPL_RE__NO_MATCH = -1,
+        ZPL_RE__INTERNAL_FAILURE = -2,
+    };
+
+    static char const ZPL_RE__META_CHARS[] = "^$()[].*+?|\\";
+    static char const ZPL_RE__WHITESPACE[] = " \r\t\n\v\f";
+    #define ZPL_RE__LITERAL(str) (str), zpl_size_of(str)-1
+
+    static zpl_re_ctx zpl_re__exec_single(zpl_re *re, zpl_isize op, char const *str, zpl_isize str_len, zpl_isize offset, zpl_re_capture *captures, zpl_isize max_capture_count);
+    static zpl_re_ctx zpl_re__exec(zpl_re *re, zpl_isize op, char const *str, zpl_isize str_len, zpl_isize offset, zpl_re_capture *captures, zpl_isize max_capture_count);
+
+    static zpl_re_ctx zpl_re__ctx_no_match(zpl_isize op) {
+        zpl_re_ctx c;
+        c.op = op;
+        c.offset = ZPL_RE__NO_MATCH;
+        return c;
+    }
+
+    static zpl_re_ctx zpl_re__ctx_internal_failure(zpl_isize op) {
+        zpl_re_ctx c;
+        c.op = op;
+        c.offset = ZPL_RE__INTERNAL_FAILURE;
+        return c;
+    }
+
+    static zpl_u8 zpl_re__hex(char const *s) {
+        return ((zpl_char_to_hex_digit(*s) << 4) & 0xf0) | (zpl_char_to_hex_digit(*(s+1)) & 0x0f);
+    }
+
+    static zpl_isize zpl_re__strfind(char const *s, zpl_isize len, char c, zpl_isize offset) {
+        if (offset < len) {
+            char const *found = (char const *)zpl_memchr(s+offset, c, len-offset);
+            if (found)
+                return found - s;
+        }
+
+        return -1;
+    }
+
+    static zpl_b32 zpl_re__match_escape(char c, int code) {
+        switch (code) {
+            case ZPL_RE_CODE_NULL:           return c == 0;
+            case ZPL_RE_CODE_WHITESPACE:     return zpl_re__strfind(ZPL_RE__LITERAL(ZPL_RE__WHITESPACE), c, 0) >= 0;
+            case ZPL_RE_CODE_NOT_WHITESPACE: return zpl_re__strfind(ZPL_RE__LITERAL(ZPL_RE__WHITESPACE), c, 0) < 0;
+            case ZPL_RE_CODE_DIGIT:          return (c >= '0' && c <= '9');
+            case ZPL_RE_CODE_NOT_DIGIT:      return !(c >= '0' && c <= '9');
+            case ZPL_RE_CODE_ALPHA:          return (c >= 'A' && c <= 'Z') || (c >= 'a' && c <= 'z');
+            case ZPL_RE_CODE_LOWER:          return (c >= 'a' && c <= 'z');
+            case ZPL_RE_CODE_UPPER:          return (c >= 'A' && c <= 'Z');
+
+            /* TODO(bill): Make better? */
+            case ZPL_RE_CODE_WORD:           return (c >= 'A' && c <= 'Z') || (c >= 'a' && c <= 'z') || (c >= '0' && c <= '9') || c == '_';
+            case ZPL_RE_CODE_NOT_WORD:       return !((c >= 'A' && c <= 'Z') || (c >= 'a' && c <= 'z') || (c >= '0' && c <= '9') || c == '_');
+
+            /* TODO(bill): Maybe replace with between tests? */
+            case ZPL_RE_CODE_XDIGIT:         return zpl_re__strfind(ZPL_RE__LITERAL("0123456789ABCDEFabcdef"), c, 0) >= 0;
+            case ZPL_RE_CODE_PRINTABLE:      return c >= 0x20 && c <= 0x7e;
+            default: break;
+        }
+
+        return 0;
+    }
+
+    static zpl_re_ctx zpl_re__consume(zpl_re *re, zpl_isize op, char const *str, zpl_isize str_len, zpl_isize offset, zpl_re_capture *captures, zpl_isize max_capture_count, zpl_b32 is_greedy)
+    {
+        zpl_re_ctx c, best_c, next_c;
+
+        c.op = op;
+        c.offset = offset;
+
+        best_c.op = ZPL_RE__NO_MATCH;
+        best_c.offset = offset;
+
+        for (;;) {
+            c = zpl_re__exec_single(re, op, str, str_len, c.offset, 0, 0);
+            if (c.offset > str_len || c.offset == -1) break;
+            if (c.op >= re->buf_len) return c;
+
+            next_c = zpl_re__exec(re, c.op, str, str_len, c.offset, captures, max_capture_count);
+            if (next_c.offset <= str_len) {
+                if (captures)
+                    zpl_re__exec(re, c.op, str, str_len, c.offset, captures, max_capture_count);
+
+                best_c = next_c;
+                if (!is_greedy) break;
+            }
+
+            if (best_c.op > re->buf_len)
+                best_c.op = c.op;
+
+        }
+
+        return best_c;
+    }
+
+    static zpl_re_ctx zpl_re__exec_single(zpl_re *re, zpl_isize op, char const *str, zpl_isize str_len, zpl_isize offset, zpl_re_capture *captures, zpl_isize max_capture_count) {
+        zpl_re_ctx ctx;
+        zpl_isize buffer_len;
+        zpl_isize match_len;
+        zpl_isize next_op;
+        zpl_isize skip;
+
+        switch (re->buf[op++]) {
+            case ZPL_RE_OP_BEGIN_CAPTURE: {
+                zpl_u8 capture = re->buf[op++];
+                if (captures && (capture < max_capture_count))
+                    captures[capture].str = str + offset;
+            } break;
+
+            case ZPL_RE_OP_END_CAPTURE: {
+                zpl_u8 capture = re->buf[op++];
+                if (captures && (capture < max_capture_count))
+                    captures[capture].len = (str + offset) - captures[capture].str;
+            } break;
+
+            case ZPL_RE_OP_BEGINNING_OF_LINE: {
+                if (offset != 0)
+                    return zpl_re__ctx_no_match(op);
+            } break;
+
+            case ZPL_RE_OP_END_OF_LINE: {
+                if (offset != str_len)
+                    return zpl_re__ctx_no_match(op);
+            } break;
+
+            case ZPL_RE_OP_BRANCH_START: {
+                skip = re->buf[op++];
+                ctx = zpl_re__exec(re, op, str, str_len, offset, captures, max_capture_count);
+                if (ctx.offset <= str_len) {
+                    offset = ctx.offset;
+                    op = ctx.op;
+                } else {
+                    ctx = zpl_re__exec(re, op + skip, str, str_len, offset, captures, max_capture_count);
+                    offset = ctx.offset;
+                    op = ctx.op;
+                }
+            } break;
+
+            case ZPL_RE_OP_BRANCH_END: {
+                skip = re->buf[op++];
+                op += skip;
+            } break;
+
+            case ZPL_RE_OP_ANY: {
+                if (offset < str_len) {
+                    offset++;
+                    break;
+                }
+                return zpl_re__ctx_no_match(op);
+            } break;
+
+            case ZPL_RE_OP_ANY_OF: {
+                zpl_isize i;
+                char cin = str[offset];
+                buffer_len = re->buf[op++];
+
+                if (offset >= str_len)
+                    return zpl_re__ctx_no_match(op + buffer_len);
+
+                for (i = 0; i < buffer_len; i++) {
+                    char cmatch = (char)re->buf[op+i];
+                    if (!cmatch) {
+                        i++;
+                        if (zpl_re__match_escape(cin, re->buf[op+i] << 8))
+                            break;
+                    } else if (cin == cmatch) {
+                        break;
+                    }
+                }
+
+                if (i == buffer_len)
+                    return zpl_re__ctx_no_match(op + buffer_len);
+
+                offset++;
+                op += buffer_len;
+            } break;
+
+            case ZPL_RE_OP_ANY_BUT: {
+                zpl_isize i;
+                char cin = str[offset];
+                buffer_len = re->buf[op++];
+
+                if (offset >= str_len)
+                    return zpl_re__ctx_no_match(op + buffer_len);
+
+                for (i = 0; i < buffer_len; i++) {
+                    char cmatch = (char)re->buf[op + i];
+                    if (!cmatch) {
+                        i++;
+                        if (zpl_re__match_escape(cin, re->buf[op+i] << 8))
+                            return zpl_re__ctx_no_match(op + buffer_len);
+                    } else if (cin == cmatch) {
+                        return zpl_re__ctx_no_match(op + buffer_len);
+                    }
+                }
+
+                offset++;
+                op += buffer_len;
+            } break;
+
+            case ZPL_RE_OP_EXACT_MATCH: {
+                match_len = re->buf[op++];
+
+                if ((match_len > (str_len - offset)) ||
+                    zpl_strncmp(str+offset, (const char*)re->buf + op, match_len) != 0)
+                    return zpl_re__ctx_no_match(op + match_len);
+
+                op += match_len;
+                offset += match_len;
+            } break;
+
+            case ZPL_RE_OP_META_MATCH: {
+                char cin = (char)re->buf[op++];
+                char cmatch = str[offset++];
+
+                if (!cin) {
+                    if (zpl_re__match_escape(cmatch, re->buf[op++] << 8))
+                        break;
+                }
+                else if (cin == cmatch) break;
+
+                return zpl_re__ctx_no_match(op);
+            } break;
+
+            case ZPL_RE_OP_ZERO_OR_MORE: {
+                ctx = zpl_re__consume(re, op, str, str_len, offset, captures, max_capture_count, 1);
+                offset = ctx.offset;
+                op = ctx.op;
+            } break;
+
+            case ZPL_RE_OP_ONE_OR_MORE: {
+                ctx = zpl_re__exec_single(re, op, str, str_len, offset, captures, max_capture_count);
+
+                if (ctx.offset > str_len)
+                    return ctx;
+
+                ctx = zpl_re__consume(re, op, str, str_len, offset, captures, max_capture_count, 1);
+                offset = ctx.offset;
+                op = ctx.op;
+            } break;
+
+            case ZPL_RE_OP_ZERO_OR_MORE_SHORTEST: {
+                ctx = zpl_re__consume(re, op, str, str_len, offset, captures, max_capture_count, 0);
+                offset = ctx.offset;
+                op = ctx.op;
+            } break;
+
+            case ZPL_RE_OP_ONE_OR_MORE_SHORTEST: {
+                ctx = zpl_re__exec_single(re, op, str, str_len, offset, captures, max_capture_count);
+
+                if (ctx.offset > str_len)
+                    return ctx;
+
+                ctx = zpl_re__consume(re, op, str, str_len, offset, captures, max_capture_count, 0);
+                offset = ctx.offset;
+                op = ctx.op;
+            } break;
+
+            case ZPL_RE_OP_ZERO_OR_ONE: {
+                ctx = zpl_re__exec_single(re, op, str, str_len, offset, captures, max_capture_count);
+
+                if (ctx.offset <= str_len) {
+                    zpl_re_ctx possible_ctx = zpl_re__exec(re, ctx.op, str, str_len, ctx.offset, captures, max_capture_count);
+
+                    if (possible_ctx.offset <= str_len) {
+                        op = possible_ctx.op;
+                        offset = possible_ctx.offset;
+                        break;
+                    }
+                }
+
+                next_op = ctx.op;
+                ctx = zpl_re__exec(re, next_op, str, str_len, offset, captures, max_capture_count);
+
+                if (ctx.offset <= str_len) {
+                    op = ctx.op;
+                    offset = ctx.offset;
+                    break;
+                }
+                return zpl_re__ctx_no_match(op);
+            } break;
+
+            default: {
+                return zpl_re__ctx_internal_failure(op);
+            } break;
+        }
+
+        ctx.op = op;
+        ctx.offset = offset;
+
+        return ctx;
+    }
+
+    static zpl_re_ctx zpl_re__exec(zpl_re *re, zpl_isize op, char const *str, zpl_isize str_len, zpl_isize offset, zpl_re_capture *captures, zpl_isize max_capture_count) {
+        zpl_re_ctx c;
+        c.op = op;
+        c.offset = offset;
+
+        while (c.op < re->buf_len) {
+            c = zpl_re__exec_single(re, c.op, str, str_len, c.offset, captures, max_capture_count);
+
+            if (c.offset > str_len || c.offset == -1)
+                break;
+        }
+
+        return c;
+    }
+
+    static zpl_regex_error zpl_re__emit_ops(zpl_re *re, zpl_isize op_count, ...) {
+        va_list va;
+
+        if (re->buf_len + op_count > re->buf_cap) {
+            if (!re->can_realloc) {
+                return ZPL_RE_ERROR_TOO_LONG;
+            }
+            else {
+                zpl_isize new_cap = (re->buf_cap*2) + op_count;
+                re->buf = (char *)zpl_resize(re->backing, re->buf, re->buf_cap, new_cap);
+                re->buf_cap = new_cap;
+            }
+        }
+
+        va_start(va, op_count);
+        for (zpl_isize i = 0; i < op_count; i++)
+        {
+            zpl_i32 v = va_arg(va, zpl_i32);
+            if (v > 256)
+                return ZPL_RE_ERROR_TOO_LONG;
+            re->buf[re->buf_len++] = (char)v;
+        }
+        va_end(va);
+
+        return ZPL_RE_ERROR_NONE;
+    }
+
+    static zpl_regex_error zpl_re__emit_ops_buffer(zpl_re *re, zpl_isize op_count, char const *buffer) {
+        if (re->buf_len + op_count > re->buf_cap) {
+            if (!re->can_realloc) {
+                return ZPL_RE_ERROR_TOO_LONG;
+            }
+            else {
+                zpl_isize new_cap = (re->buf_cap*2) + op_count;
+                re->buf = (char *)zpl_resize(re->backing, re->buf, re->buf_cap, new_cap);
+                re->buf_cap = new_cap;
+            }
+        }
+
+        for (zpl_isize i = 0; i < op_count; i++)
+        {
+            re->buf[re->buf_len++] = buffer[i];
+        }
+
+        return ZPL_RE_ERROR_NONE;
+    }
+
+    static int zpl_re__encode_escape(char code) {
+        switch (code) {
+            default:   break; /* NOTE(bill): It's a normal character */
+
+            /* TODO(bill): Are there anymore? */
+            case 't':  return '\t';
+            case 'n':  return '\n';
+            case 'r':  return '\r';
+            case 'f':  return '\f';
+            case 'v':  return '\v';
+
+            case '0':  return ZPL_RE_CODE_NULL;
+
+            case 's':  return ZPL_RE_CODE_WHITESPACE;
+            case 'S':  return ZPL_RE_CODE_NOT_WHITESPACE;
+
+            case 'd':  return ZPL_RE_CODE_DIGIT;
+            case 'D':  return ZPL_RE_CODE_NOT_DIGIT;
+
+            case 'a':  return ZPL_RE_CODE_ALPHA;
+            case 'l':  return ZPL_RE_CODE_LOWER;
+            case 'u':  return ZPL_RE_CODE_UPPER;
+
+            case 'w':  return ZPL_RE_CODE_WORD;
+            case 'W':  return ZPL_RE_CODE_NOT_WORD;
+
+            case 'x':  return ZPL_RE_CODE_XDIGIT;
+            case 'p':  return ZPL_RE_CODE_PRINTABLE;
+        }
+        return code;
+    }
+
+    static zpl_regex_error zpl_re__parse_group(zpl_re *re, char const *pattern, zpl_isize len, zpl_isize offset, zpl_isize *new_offset) {
+        zpl_regex_error err = ZPL_RE_ERROR_NONE;
+        char buffer[256] = {0};
+        zpl_isize buffer_len = 0, buffer_cap = zpl_size_of(buffer);
+        zpl_b32 closed = 0;
+        zplreOp op = ZPL_RE_OP_ANY_OF;
+
+        if (pattern[offset] == '^') {
+            offset++;
+            op = ZPL_RE_OP_ANY_BUT;
+        }
+
+        while(!closed &&
+              err == ZPL_RE_ERROR_NONE &&
+              offset < len)
+        {
+            if (pattern[offset] == ']') {
+                err = zpl_re__emit_ops(re, 2, (zpl_i32)op, (zpl_i32)buffer_len);
+                if (err) break;
+
+                err = zpl_re__emit_ops_buffer(re, buffer_len, (const char*)buffer);
+                if (err) break;
+                offset++;
+                closed = 1;
+                break;
+            }
+
+            if (buffer_len >= buffer_cap)
+                return ZPL_RE_ERROR_TOO_LONG;
+
+            if (pattern[offset] == '\\') {
+                offset++;
+
+                if ((offset + 1 < len) && zpl_char_is_hex_digit(*(pattern+offset))) {
+                    buffer[buffer_len++] = zpl_re__hex((pattern+offset));
+                    offset++;
+                }
+                else if (offset < len) {
+                    zpl_i32 code = zpl_re__encode_escape(pattern[offset]);
+
+                    if (!code || code > 0xff) {
+                        buffer[buffer_len++] = 0;
+
+                        if (buffer_len >= buffer_cap)
+                            return ZPL_RE_ERROR_TOO_LONG;
+
+                        buffer[buffer_len++] = (code >> 8) & 0xff;
+                    }
+                    else {
+                        buffer[buffer_len++] = code & 0xff;
+                    }
+                }
+            }
+            else {
+                buffer[buffer_len++] = (unsigned char)pattern[offset];
+            }
+
+            offset++;
+        }
+
+        if (err) return err;
+        if (!closed) return ZPL_RE_ERROR_MISMATCHED_BLOCKS;
+        if (new_offset) *new_offset = offset;
+        return ZPL_RE_ERROR_NONE;
+    }
+
+    static zpl_regex_error zpl_re__compile_quantifier(zpl_re *re, zpl_isize last_buf_len, unsigned char quantifier) {
+        zpl_regex_error err;
+        zpl_isize move_size;
+
+        if ((re->buf[last_buf_len] == ZPL_RE_OP_EXACT_MATCH) &&
+            (re->buf[last_buf_len+1] > 1))
+        {
+            unsigned char last_char = re->buf[re->buf_len-1];
+
+            re->buf[last_buf_len+1]--;
+            re->buf_len--;
+            err = zpl_re__emit_ops(re, 4, (zpl_i32)quantifier, (zpl_i32)ZPL_RE_OP_EXACT_MATCH, 1, (zpl_i32)last_char);
+            if (err) return err;
+            return ZPL_RE_ERROR_NONE;
+        }
+
+        move_size = re->buf_len - last_buf_len + 1;
+
+        err = zpl_re__emit_ops(re, 1, 0);
+        if (err) return err;
+
+        zpl_memmove(re->buf+last_buf_len+1, re->buf+last_buf_len, move_size);
+        re->buf[last_buf_len] = quantifier;
+
+        return ZPL_RE_ERROR_NONE;
+    }
+
+    static zpl_regex_error zpl_re__parse(zpl_re *re, char const *pattern, zpl_isize len, zpl_isize offset, zpl_isize level, zpl_isize *new_offset) {
+        zpl_regex_error err = ZPL_RE_ERROR_NONE;
+        zpl_isize last_buf_len = re->buf_len;
+        zpl_isize branch_begin = re->buf_len;
+        zpl_isize branch_op = -1;
+
+        while (offset < len) {
+            switch (pattern[offset++]) {
+                case '^': {
+                    err = zpl_re__emit_ops(re, 1, ZPL_RE_OP_BEGINNING_OF_LINE);
+                    if (err) return err;
+                } break;
+
+                case '$': {
+                    err = zpl_re__emit_ops(re, 1, ZPL_RE_OP_END_OF_LINE);
+                    if (err) return err;
+                } break;
+
+                case '(': {
+                    zpl_isize capture = re->capture_count++;
+                    last_buf_len = re->buf_len;
+                    err = zpl_re__emit_ops(re, 2, ZPL_RE_OP_BEGIN_CAPTURE, (zpl_i32)capture);
+                    if (err) return err;
+
+                    err = zpl_re__parse(re, pattern, len, offset, level+1, &offset);
+
+                    if ((offset > len) || (pattern[offset-1] != ')'))
+                        return ZPL_RE_ERROR_MISMATCHED_CAPTURES;
+
+                    err = zpl_re__emit_ops(re, 2, ZPL_RE_OP_END_CAPTURE, (zpl_i32)capture);
+                    if (err) return err;
+                } break;
+
+                case ')': {
+                    if (branch_op != -1)
+                        re->buf[branch_op + 1] = (unsigned char)(re->buf_len - (branch_op+2));
+
+                    if (level == 0)
+                        return ZPL_RE_ERROR_MISMATCHED_CAPTURES;
+
+                    if (new_offset) *new_offset = offset;
+                    return ZPL_RE_ERROR_NONE;
+                } break;
+
+                case '[': {
+                    last_buf_len = re->buf_len;
+                    err = zpl_re__parse_group(re, pattern, len, offset, &offset);
+                    if (offset > len)
+                        return err;
+                } break;
+
+                /* NOTE(bill): Branching magic! */
+                case '|': {
+                    if (branch_begin >= re->buf_len) {
+                        return ZPL_RE_ERROR_BRANCH_FAILURE;
+                    } else {
+                        zpl_isize size = re->buf_len - branch_begin;
+                        err = zpl_re__emit_ops(re, 4, 0, 0, ZPL_RE_OP_BRANCH_END, 0);
+                        if (err) return err;
+
+                        zpl_memmove(re->buf + branch_begin + 2, re->buf + branch_begin, size);
+                        re->buf[branch_begin] = ZPL_RE_OP_BRANCH_START;
+                        re->buf[branch_begin+1] = (size+2) & 0xff;
+                        branch_op = re->buf_len-2;
+                    }
+                } break;
+
+                case '.': {
+                    last_buf_len = re->buf_len;
+                    err = zpl_re__emit_ops(re, 1, ZPL_RE_OP_ANY);
+                    if (err) return err;
+                } break;
+
+                case '*':
+                case '+':
+                {
+                    unsigned char quantifier = ZPL_RE_OP_ONE_OR_MORE;
+                    if (pattern[offset-1] == '*')
+                        quantifier = ZPL_RE_OP_ZERO_OR_MORE;
+
+                    if (last_buf_len >= re->buf_len)
+                        return ZPL_RE_ERROR_INVALID_QUANTIFIER;
+                    if ((re->buf[last_buf_len] < ZPL_RE_OP_EXACT_MATCH) ||
+                        (re->buf[last_buf_len] > ZPL_RE_OP_ANY_BUT))
+                        return ZPL_RE_ERROR_INVALID_QUANTIFIER;
+
+                    if ((offset < len) && (pattern[offset] == '?')) {
+                        quantifier = ZPL_RE_OP_ONE_OR_MORE_SHORTEST;
+                        if (quantifier == ZPL_RE_OP_ZERO_OR_MORE)
+                            quantifier = ZPL_RE_OP_ZERO_OR_MORE_SHORTEST;
+                        offset++;
+                    }
+
+                    err = zpl_re__compile_quantifier(re, last_buf_len, quantifier);
+                    if (err) return err;
+                } break;
+
+                case '?': {
+                    if (last_buf_len >= re->buf_len)
+                        return ZPL_RE_ERROR_INVALID_QUANTIFIER;
+                    if ((re->buf[last_buf_len] < ZPL_RE_OP_EXACT_MATCH) ||
+                        (re->buf[last_buf_len] > ZPL_RE_OP_ANY_BUT))
+                        return ZPL_RE_ERROR_INVALID_QUANTIFIER;
+
+                    err = zpl_re__compile_quantifier(re, last_buf_len,
+                                                     (unsigned char)ZPL_RE_OP_ZERO_OR_ONE);
+                    if (err) return err;
+                } break;
+
+                case '\\': {
+                    last_buf_len = re->buf_len;
+                    if ((offset+1 < len) && zpl_char_is_hex_digit(*(pattern+offset))) {
+                        unsigned char hex_value = zpl_re__hex((pattern+offset));
+                        offset += 2;
+                        err = zpl_re__emit_ops(re, 2, ZPL_RE_OP_META_MATCH, (int)hex_value);
+                        if (err) return err;
+                    } else if (offset < len) {
+                        int code = zpl_re__encode_escape(pattern[offset++]);
+                        if (!code || (code > 0xff)) {
+                            err = zpl_re__emit_ops(re, 3, ZPL_RE_OP_META_MATCH, 0, (int)((code >> 8) & 0xff));
+                            if (err) return err;
+                        } else {
+                            err = zpl_re__emit_ops(re, 2, ZPL_RE_OP_META_MATCH, (int)code);
+                            if (err) return err;
+                        }
+                    }
+                } break;
+
+                /* NOTE(bill): Exact match */
+                default: {
+                    char const *match_start;
+                    zpl_isize size = 0;
+                    offset--;
+                    match_start = pattern+offset;
+                    while ((offset < len) &&
+                           (zpl_re__strfind(ZPL_RE__LITERAL(ZPL_RE__META_CHARS), pattern[offset], 0) < 0)) {
+                        size++, offset++;
+                    }
+
+                    last_buf_len = re->buf_len;
+                    err = zpl_re__emit_ops(re, 2, ZPL_RE_OP_EXACT_MATCH, (int)size);
+                    if (err) return err;
+                    err = zpl_re__emit_ops_buffer(re, size, (char const *)match_start);
+                    if (err) return err;
+                } break;
+            }
+        }
+
+        if (new_offset) *new_offset = offset;
+        return ZPL_RE_ERROR_NONE;
+    }
+
+    zpl_regex_error zpl_re_compile_from_buffer(zpl_re *re, char const *pattern, zpl_isize pattern_len, void *buffer, zpl_isize buffer_len) {
+        zpl_regex_error err;
+        re->capture_count = 0;
+        re->buf = (char *)buffer;
+        re->buf_len = 0;
+        re->buf_cap = re->buf_len;
+        re->can_realloc = 0;
+
+        err = zpl_re__parse(re, pattern, pattern_len, 0, 0, 0);
+        return err;
+    }
+
+    zpl_regex_error zpl_re_compile(zpl_re *re, zpl_allocator backing, char const *pattern, zpl_isize pattern_len) {
+        zpl_regex_error err;
+        zpl_isize cap = pattern_len+128;
+        zpl_isize offset = 0;
+
+        re->backing = backing;
+        re->capture_count = 0;
+        re->buf = (char *)zpl_alloc(backing, cap);
+        re->buf_len = 0;
+        re->buf_cap = cap;
+        re->can_realloc = 1;
+
+        err = zpl_re__parse(re, pattern, pattern_len, 0, 0, &offset);
+
+        if (offset != pattern_len)
+            zpl_free(backing, re->buf);
+
+        return err;
+    }
+
+    zpl_isize zpl_re_capture_count(zpl_re *re) { return re->capture_count; }
+
+    zpl_b32 zpl_re_match(zpl_re *re, char const *str, zpl_isize len, zpl_re_capture *captures, zpl_isize max_capture_count, zpl_isize *offset) {
+        if (re && re->buf_len > 0) {
+            if (re->buf[0] == ZPL_RE_OP_BEGINNING_OF_LINE) {
+                zpl_re_ctx c = zpl_re__exec(re, 0, str, len, 0, captures, max_capture_count);
+                if (c.offset >= 0 && c.offset <= len) { if (offset) *offset = c.offset; return 1; };
+                if (c.offset == ZPL_RE__INTERNAL_FAILURE) return 0;
+            } else {
+                zpl_isize i;
+                for (i = 0; i < len; i++) {
+                    zpl_re_ctx c = zpl_re__exec(re, 0, str, len, i, captures, max_capture_count);
+                    if (c.offset >= 0 && c.offset <= len) { if (offset) *offset = c.offset; return 1; };
+                    if (c.offset == ZPL_RE__INTERNAL_FAILURE) return 0;
+                }
+            }
+            return 0;
+        }
+        return 1;
+    }
+
+
+    zpl_b32 zpl_re_match_all(zpl_re *re, char const *str, zpl_isize str_len, zpl_isize max_capture_count,
+                         zpl_re_capture **out_captures)
+    {
+        char *end = (char *)str + str_len;
+        char *p = (char *)str;
+
+        zpl_buffer_make(zpl_re_capture, cps, zpl_heap(), max_capture_count);
+
+        zpl_isize offset = 0;
+
+        while (p < end)
+        {
+            zpl_b32 ok = zpl_re_match(re, p, end - p, cps, max_capture_count, &offset);
+            if (!ok) {
+                zpl_buffer_free(cps);
+                return false;
+            }
+
+            p += offset;
+
+            for (zpl_isize i = 0; i < max_capture_count; i++) {
+                zpl_array_append(*out_captures, cps[i]);
+            }
+        }
+
+        zpl_buffer_free(cps);
+
+        return true;
+    }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_DLL)
+    // file: source/dll.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_UNIX) || defined(ZPL_SYSTEM_MACOS)
+        #include <dlfcn.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // DLL Handling
+    //
+    //
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        zpl_dll_handle zpl_dll_load(char const *filepath) {
+            return cast(zpl_dll_handle) LoadLibraryA(filepath);
+        }
+
+        void zpl_dll_unload(zpl_dll_handle dll) {
+            FreeLibrary(cast(HMODULE) dll);
+        }
+
+        zpl_dll_proc zpl_dll_proc_address(zpl_dll_handle dll, char const *proc_name) {
+            return cast(zpl_dll_proc) GetProcAddress(cast(HMODULE) dll, proc_name);
+        }
+
+    #else // POSIX
+
+        zpl_dll_handle zpl_dll_load(char const *filepath) {
+            return cast(zpl_dll_handle) dlopen(filepath, RTLD_LAZY | RTLD_GLOBAL);
+        }
+
+        void zpl_dll_unload(zpl_dll_handle dll) {
+            dlclose(dll);
+        }
+
+        zpl_dll_proc zpl_dll_proc_address(zpl_dll_handle dll, char const *proc_name) {
+            return cast(zpl_dll_proc) dlsym(dll, proc_name);
+        }
+
+    #endif
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_OPTS)
+    // file: source/opts.c
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // CLI Options
+    //
+    //
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    void zpl_opts_init(zpl_opts *opts, zpl_allocator a, char const *app) {
+        zpl_opts opts_ = { 0 };
+        *opts = opts_;
+        opts->alloc = a;
+        opts->appname = app;
+
+        zpl_array_init(opts->entries, a);
+        zpl_array_init(opts->positioned, a);
+        zpl_array_init(opts->errors, a);
+    }
+
+    void zpl_opts_free(zpl_opts *opts) {
+        for (zpl_i32 i = 0; i < zpl_array_count(opts->entries); ++i) {
+            zpl_opts_entry *e = opts->entries + i;
+            if (e->type == ZPL_OPTS_STRING) {
+                zpl_string_free(e->text);
+            }
+        }
+
+        zpl_array_free(opts->entries);
+        zpl_array_free(opts->positioned);
+        zpl_array_free(opts->errors);
+    }
+
+    void zpl_opts_add(zpl_opts *opts, char const *name, char const *lname, const char *desc, zpl_u8 type) {
+        zpl_opts_entry e = { 0 };
+
+        e.name = name;
+        e.lname = lname;
+        e.desc = desc;
+        e.type = type;
+        e.met = false;
+        e.pos = false;
+
+        zpl_array_append(opts->entries, e);
+    }
+
+    zpl_opts_entry *zpl__opts_find(zpl_opts *opts, char const *name, zpl_usize len, zpl_b32 longname) {
+        zpl_opts_entry *e = 0;
+
+        for (int i = 0; i < zpl_array_count(opts->entries); ++i) {
+            e = opts->entries + i;
+            char const *n = (longname ? e->lname : e->name);
+
+            if (zpl_strnlen(name, len) == zpl_strlen(n) && !zpl_strncmp(n, name, len)) { return e; }
+        }
+
+        return NULL;
+    }
+
+    void zpl_opts_positional_add(zpl_opts *opts, char const *name) {
+        zpl_opts_entry *e = zpl__opts_find(opts, name, zpl_strlen(name), true);
+
+        if (e) {
+            e->pos = true;
+            zpl_array_append_at(opts->positioned, e, 0);
+        }
+    }
+
+    zpl_b32 zpl_opts_positionals_filled(zpl_opts *opts) { return zpl_array_count(opts->positioned) == 0; }
+
+    zpl_string zpl_opts_string(zpl_opts *opts, char const *name, char const *fallback) {
+        zpl_opts_entry *e = zpl__opts_find(opts, name, zpl_strlen(name), true);
+
+        return (char *)((e && e->met) ? e->text : fallback);
+    }
+
+    zpl_f64 zpl_opts_real(zpl_opts *opts, char const *name, zpl_f64 fallback) {
+        zpl_opts_entry *e = zpl__opts_find(opts, name, zpl_strlen(name), true);
+
+        return (e && e->met) ? e->real : fallback;
+    }
+
+    zpl_i64 zpl_opts_integer(zpl_opts *opts, char const *name, zpl_i64 fallback) {
+        zpl_opts_entry *e = zpl__opts_find(opts, name, zpl_strlen(name), true);
+
+        return (e && e->met) ? e->integer : fallback;
+    }
+
+    void zpl__opts_set_value(zpl_opts *opts, zpl_opts_entry *t, char *b) {
+        t->met = true;
+
+        switch (t->type) {
+            case ZPL_OPTS_STRING: {
+                t->text = zpl_string_make(opts->alloc, b);
+            } break;
+
+            case ZPL_OPTS_FLOAT: {
+                t->real = zpl_str_to_f64(b, NULL);
+            } break;
+
+            case ZPL_OPTS_INT: {
+                t->integer = zpl_str_to_i64(b, NULL, 10);
+            } break;
+        }
+
+        for (zpl_isize i=0; i < zpl_array_count(opts->positioned); i++) {
+            if (!zpl_strcmp(opts->positioned[i]->lname, t->lname)) {
+                zpl_array_remove_at(opts->positioned, i);
+                break;
+            }
+        }
+    }
+
+    zpl_b32 zpl_opts_has_arg(zpl_opts *opts, char const *name) {
+        zpl_opts_entry *e = zpl__opts_find(opts, name, zpl_strlen(name), true);
+
+        if (e) { return e->met; }
+
+        return false;
+    }
+
+    void zpl_opts_print_help(zpl_opts *opts) {
+        zpl_printf("USAGE: %s", opts->appname);
+
+        for (zpl_isize i = zpl_array_count(opts->entries); i >= 0; --i) {
+            zpl_opts_entry *e = opts->entries + i;
+
+            if (e->pos == (zpl_b32) true) { zpl_printf(" [%s]", e->lname); }
+        }
+
+        zpl_printf("\nOPTIONS:\n");
+
+        for (zpl_isize i = 0; i < zpl_array_count(opts->entries); ++i) {
+            zpl_opts_entry *e = opts->entries + i;
+
+            zpl_printf("\t-%s, --%s: %s\n", e->name, e->lname, e->desc);
+        }
+    }
+
+    void zpl_opts_print_errors(zpl_opts *opts) {
+        for (int i = 0; i < zpl_array_count(opts->errors); ++i) {
+            zpl_opts_err *err = (opts->errors + i);
+
+            zpl_printf("ERROR: ");
+
+            switch (err->type) {
+                case ZPL_OPTS_ERR_OPTION: zpl_printf("Invalid option \"%s\"", err->val); break;
+
+                case ZPL_OPTS_ERR_VALUE: zpl_printf("Invalid value \"%s\"", err->val); break;
+
+                case ZPL_OPTS_ERR_MISSING_VALUE: zpl_printf("Missing value for option \"%s\"", err->val); break;
+
+                case ZPL_OPTS_ERR_EXTRA_VALUE: zpl_printf("Extra value for option \"%s\"", err->val); break;
+            }
+
+            zpl_printf("\n");
+        }
+    }
+
+    void zpl__opts_push_error(zpl_opts *opts, char *b, zpl_u8 errtype) {
+        zpl_opts_err err = { 0 };
+        err.val = b;
+        err.type = errtype;
+        zpl_array_append(opts->errors, err);
+    }
+
+    zpl_b32 zpl_opts_compile(zpl_opts *opts, int argc, char **argv) {
+        zpl_b32 had_errors = false;
+        for (int i = 1; i < argc; ++i) {
+            char *p = argv[i];
+
+            if (*p) {
+                p = zpl_str_trim(p, false);
+                if (*p == '-') {
+                    zpl_opts_entry *t = 0;
+                    zpl_b32 checkln = false;
+                    if (*(p + 1) == '-') {
+                        checkln = true;
+                        ++p;
+                    }
+
+                    char *b = p + 1, *e = b;
+
+                    while (zpl_char_is_alphanumeric(*e)) { ++e; }
+
+                    t = zpl__opts_find(opts, b, (e - b), checkln);
+
+                    if (t) {
+                        char *ob = b;
+                        b = e;
+
+                        /**/ if (*e == '=') {
+                            if (t->type == ZPL_OPTS_FLAG) {
+                                *e = '\0';
+                                zpl__opts_push_error(opts, ob, ZPL_OPTS_ERR_EXTRA_VALUE);
+                                had_errors = true;
+                                continue;
+                            }
+
+                            b = e = e + 1;
+                        } else if (*e == '\0') {
+                            char *sp = argv[i+1];
+
+                            if (sp && *sp != '-' && (zpl_array_count(opts->positioned) < 1  || t->type != ZPL_OPTS_FLAG)) {
+                                if (t->type == ZPL_OPTS_FLAG) {
+                                    zpl__opts_push_error(opts, b, ZPL_OPTS_ERR_EXTRA_VALUE);
+                                    had_errors = true;
+                                    continue;
+                                }
+
+                                p = sp;
+                                b = e = sp;
+                                ++i;
+                            } else {
+                                if (t->type != ZPL_OPTS_FLAG) {
+                                    zpl__opts_push_error(opts, ob, ZPL_OPTS_ERR_MISSING_VALUE);
+                                    had_errors = true;
+                                    continue;
+                                }
+                                t->met = true;
+                                continue;
+                            }
+                        }
+
+                        e = zpl_str_control_skip(e, '\0');
+                        zpl__opts_set_value(opts, t, b);
+                    } else {
+                        zpl__opts_push_error(opts, b, ZPL_OPTS_ERR_OPTION);
+                        had_errors = true;
+                    }
+                } else if (zpl_array_count(opts->positioned)) {
+                    zpl_opts_entry *l = zpl_array_back(opts->positioned);
+                    zpl_array_pop(opts->positioned);
+                    zpl__opts_set_value(opts, l, p);
+                } else {
+                    zpl__opts_push_error(opts, p, ZPL_OPTS_ERR_VALUE);
+                    had_errors = true;
+                }
+            }
+        }
+        return !had_errors;
+    }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_PROCESS)
+    // file: source/process.c
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Process creation and manipulation methods
+    //
+    //
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    static ZPL_ALWAYS_INLINE void zpl__pr_close_file_handle(zpl_file *f) {
+        ZPL_ASSERT_NOT_NULL(f);
+        f->fd.p  = NULL;
+    }
+
+    static ZPL_ALWAYS_INLINE void zpl__pr_close_file_handles(zpl_pr *process) {
+        ZPL_ASSERT_NOT_NULL(process);
+
+        zpl__pr_close_file_handle(&process->in);
+        zpl__pr_close_file_handle(&process->out);
+        zpl__pr_close_file_handle(&process->err);
+
+        process->f_stdin = process->f_stdout = process->f_stderr = NULL;
+
+    #ifdef ZPL_SYSTEM_WINDOWS
+        process->win32_handle = NULL;
+    #else
+        ZPL_NOT_IMPLEMENTED;
+    #endif
+    }
+
+    enum {
+        ZPL_PR_HANDLE_MODE_READ,
+        ZPL_PR_HANDLE_MODE_WRITE,
+        ZPL_PR_HANDLE_MODES,
+    };
+
+    void *zpl__pr_open_handle(zpl_u8 type, const char *mode, void **handle) {
+    #ifdef ZPL_SYSTEM_WINDOWS
+        void *pipes[ZPL_PR_HANDLE_MODES];
+        zpl_i32 fd;
+
+        const zpl_u32 flag_inherit      = 0x00000001;
+        SECURITY_ATTRIBUTES sa         = {zpl_size_of(sa), 0, 1};
+
+        if (!CreatePipe(&pipes[0], &pipes[1], cast(LPSECURITY_ATTRIBUTES)&sa, 0)) {
+            return NULL;
+        }
+
+        if (!SetHandleInformation(pipes[type], flag_inherit, 0)) {
+            return NULL;
+        }
+
+        fd = _open_osfhandle(cast(zpl_intptr)pipes[type], 0);
+
+        if (fd != -1) {
+            *handle = pipes[1-type];
+            return _fdopen(fd, mode);
+        }
+
+        return NULL;
+    #else
+        ZPL_NOT_IMPLEMENTED;
+        return NULL;
+    #endif
+    }
+
+    zpl_i32 zpl_pr_create(zpl_pr *process, const char **args, zpl_isize argc, zpl_pr_si si, zpl_pr_opts options) {
+        ZPL_ASSERT_NOT_NULL(process);
+        zpl_zero_item(process);
+
+    #ifdef ZPL_SYSTEM_WINDOWS
+        zpl_string cli, env;
+        zpl_b32 c_env=false;
+        STARTUPINFOW psi = {0};
+        PROCESS_INFORMATION pi = {0};
+        zpl_i32 err_code = 0;
+        zpl_allocator a = zpl_heap();
+        const zpl_u32 use_std_handles   = 0x00000100;
+
+        psi.cb = zpl_size_of(psi);
+        psi.dwFlags = use_std_handles | si.flags;
+
+        if (options & ZPL_PR_OPTS_CUSTOM_ENV) {
+            env = zpl_string_join(zpl_heap(), cast(const char**)si.env, si.env_count, "\0\0");
+            env = zpl_string_appendc(env, "\0");
+            c_env = true;
+        }
+        else if (!(options & ZPL_PR_OPTS_INHERIT_ENV)) {
+            env = (zpl_string)"\0\0\0\0";
+        } else {
+            env = (zpl_string)NULL;
+        }
+
+        process->f_stdin  = zpl__pr_open_handle(ZPL_PR_HANDLE_MODE_WRITE, "wb", &psi.hStdInput);
+        process->f_stdout = zpl__pr_open_handle(ZPL_PR_HANDLE_MODE_READ, "rb", &psi.hStdOutput);
+
+        if (options & ZPL_PR_OPTS_COMBINE_STD_OUTPUT) {
+            process->f_stderr = process->f_stdout;
+            psi.hStdError = psi.hStdOutput;
+        } else {
+            process->f_stderr = zpl__pr_open_handle(ZPL_PR_HANDLE_MODE_READ, "rb", &psi.hStdError);
+        }
+
+        cli = zpl_string_join(zpl_heap(), args, argc, " ");
+
+        psi.dwX = si.posx;
+        psi.dwY = si.posy;
+        psi.dwXSize = si.resx;
+        psi.dwYSize = si.resy;
+        psi.dwXCountChars = si.bufx;
+        psi.dwYCountChars = si.bufy;
+        psi.dwFillAttribute = si.fill_attr;
+        psi.wShowWindow = si.show_window;
+
+        wchar_t *w_cli = zpl__alloc_utf8_to_ucs2(a, cli, NULL);
+        wchar_t *w_workdir = zpl__alloc_utf8_to_ucs2(a, si.workdir, NULL);
+
+        if (!CreateProcessW(
+            NULL,
+            w_cli,
+            NULL,
+            NULL,
+            1,
+            0,
+            env,
+            w_workdir,
+            cast(LPSTARTUPINFOW)&psi,
+            cast(LPPROCESS_INFORMATION)&pi
+        )) {
+            err_code = -1;
+            goto pr_free_data;
+        }
+
+        process->win32_handle = pi.hProcess;
+        CloseHandle(pi.hThread);
+
+        zpl_file_connect_handle(&process->in, process->f_stdin);
+        zpl_file_connect_handle(&process->out, process->f_stdout);
+        zpl_file_connect_handle(&process->err, process->f_stderr);
+
+    pr_free_data:
+        zpl_string_free(cli);
+        zpl_free(a, w_cli);
+        zpl_free(a, w_workdir);
+
+        if (c_env)
+                zpl_string_free(env);
+
+        return err_code;
+
+    #else
+        ZPL_NOT_IMPLEMENTED;
+        return -1;
+    #endif
+    }
+
+
+    zpl_i32 zpl_pr_join(zpl_pr *process) {
+        zpl_i32 ret_code;
+
+        ZPL_ASSERT_NOT_NULL(process);
+
+    #ifdef ZPL_SYSTEM_WINDOWS
+        if (process->f_stdin) {
+            fclose(cast(FILE *)process->f_stdin);
+        }
+
+        WaitForSingleObject(process->win32_handle, INFINITE);
+
+        if (!GetExitCodeProcess(process->win32_handle, cast(LPDWORD)&ret_code)) {
+            zpl_pr_destroy(process);
+            return -1;
+        }
+
+        zpl_pr_destroy(process);
+
+        return ret_code;
+    #else
+        ZPL_NOT_IMPLEMENTED;
+        ret_code = -1;
+        return ret_code;
+    #endif
+    }
+
+    void zpl_pr_destroy(zpl_pr *process) {
+        ZPL_ASSERT_NOT_NULL(process);
+
+    #ifdef ZPL_SYSTEM_WINDOWS
+        if (process->f_stdin) {
+            fclose(cast(FILE *)process->f_stdin);
+        }
+
+        fclose(cast(FILE *)process->f_stdout);
+
+        if (process->f_stderr != process->f_stdout) {
+            fclose(cast(FILE *)process->f_stderr);
+        }
+
+        CloseHandle(process->win32_handle);
+
+        zpl__pr_close_file_handles(process);
+    #else
+        ZPL_NOT_IMPLEMENTED;
+    #endif
+    }
+
+    void zpl_pr_terminate(zpl_pr *process, zpl_i32 err_code) {
+        ZPL_ASSERT_NOT_NULL(process);
+
+    #ifdef ZPL_SYSTEM_WINDOWS
+        TerminateProcess(process->win32_handle, cast(UINT)err_code);
+        zpl_pr_destroy(process);
+    #else
+        ZPL_NOT_IMPLEMENTED;
+    #endif
+    }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_MATH)
+    // file: source/math.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+
+    #if !defined(ZPL_NO_MATH_H)
+        #include <math.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Math
+    //
+
+    zpl_f32 zpl_to_radians(zpl_f32 degrees) { return degrees * ZPL_TAU / 360.0f; }
+    zpl_f32 zpl_to_degrees(zpl_f32 radians) { return radians * 360.0f / ZPL_TAU; }
+
+    zpl_f32 zpl_angle_diff(zpl_f32 radians_a, zpl_f32 radians_b) {
+        zpl_f32 delta = zpl_mod(radians_b - radians_a, ZPL_TAU);
+        delta = zpl_mod(delta + 1.5f * ZPL_TAU, ZPL_TAU);
+        delta -= 0.5f * ZPL_TAU;
+        return delta;
+    }
+
+    zpl_f32 zpl_copy_sign(zpl_f32 x, zpl_f32 y) {
+        zpl_i32 ix, iy;
+        zpl_f32 r;
+        zpl_memcopy(&ix, &x, zpl_size_of(x));
+        zpl_memcopy(&iy, &y, zpl_size_of(y));
+
+        ix &= 0x7fffffff;
+        ix |= iy & 0x80000000;
+        zpl_memcopy(&r, &ix, zpl_size_of(ix));
+        return r;
+    }
+
+    zpl_f32 zpl_remainder(zpl_f32 x, zpl_f32 y) { return x - (zpl_round(x / y) * y); }
+
+    zpl_f32 zpl_mod(zpl_f32 x, zpl_f32 y) {
+        zpl_f32 result;
+        y = zpl_abs(y);
+        result = zpl_remainder(zpl_abs(x), y);
+        if (zpl_sign(result)) result += y;
+        return zpl_copy_sign(result, x);
+    }
+
+    zpl_f64 zpl_copy_sign64(zpl_f64 x, zpl_f64 y) {
+        zpl_i64 ix, iy;
+        zpl_f64 r;
+        zpl_memcopy(&ix, &x, zpl_size_of(x));
+        zpl_memcopy(&iy, &y, zpl_size_of(y));
+
+        ix &= 0x7fffffffffffffff;
+        ix |= iy & 0x8000000000000000;
+        zpl_memcopy(&r, &ix, zpl_size_of(ix));
+        return r;
+    }
+
+    zpl_f64 zpl_floor64(zpl_f64 x)                { return cast(zpl_f64)((x >= 0.0) ? cast(zpl_i64) x : cast(zpl_i64)(x - 0.9999999999999999)); }
+    zpl_f64 zpl_ceil64(zpl_f64 x)                 { return cast(zpl_f64)((x < 0) ? cast(zpl_i64) x : (cast(zpl_i64) x) + 1); }
+    zpl_f64 zpl_round64(zpl_f64 x)                { return cast(zpl_f64)((x >= 0.0) ? zpl_floor64(x + 0.5) : zpl_ceil64(x - 0.5)); }
+    zpl_f64 zpl_remainder64(zpl_f64 x, zpl_f64 y) { return x - (zpl_round64(x / y) * y); }
+    zpl_f64 zpl_abs64(zpl_f64 x)                  { return x < 0 ? -x : x; }
+    zpl_f64 zpl_sign64(zpl_f64 x)                 { return x < 0 ? -1.0 : +1.0; }
+
+    zpl_f64 zpl_mod64(zpl_f64 x, zpl_f64 y) {
+        zpl_f64 result;
+        y = zpl_abs64(y);
+        result = zpl_remainder64(zpl_abs64(x), y);
+        if (zpl_sign64(result)) result += y;
+        return zpl_copy_sign64(result, x);
+    }
+
+    zpl_f32 zpl_quake_rsqrt(zpl_f32 a) {
+        union {
+            int i;
+            zpl_f32 f;
+        } t;
+        zpl_f32 x2;
+        zpl_f32 const three_halfs = 1.5f;
+
+        x2 = a * 0.5f;
+        t.f = a;
+        t.i = 0x5f375a86 - (t.i >> 1);                /* What the fuck? */
+        t.f = t.f * (three_halfs - (x2 * t.f * t.f)); /* 1st iteration */
+        t.f = t.f * (three_halfs - (x2 * t.f * t.f)); /* 2nd iteration, this can be removed */
+
+        return t.f;
+    }
+
+    #if defined(ZPL_NO_MATH_H)
+        #if defined(_MSC_VER)
+
+            zpl_f32 zpl_rsqrt(zpl_f32 a) { return _mm_cvtss_f32(_mm_rsqrt_ss(_mm_set_ss(a))); }
+            zpl_f32 zpl_sqrt(zpl_f32 a)  { return _mm_cvtss_f32(_mm_sqrt_ss(_mm_set_ss(a))); };
+
+            zpl_f32 zpl_sin(zpl_f32 a) {
+                static zpl_f32 const a0 = +1.91059300966915117e-31f;
+                static zpl_f32 const a1 = +1.00086760103908896f;
+                static zpl_f32 const a2 = -1.21276126894734565e-2f;
+                static zpl_f32 const a3 = -1.38078780785773762e-1f;
+                static zpl_f32 const a4 = -2.67353392911981221e-2f;
+                static zpl_f32 const a5 = +2.08026600266304389e-2f;
+                static zpl_f32 const a6 = -3.03996055049204407e-3f;
+                static zpl_f32 const a7 = +1.38235642404333740e-4f;
+                return a0 + a * (a1 + a * (a2 + a * (a3 + a * (a4 + a * (a5 + a * (a6 + a * a7))))));
+            }
+
+            zpl_f32 zpl_cos(zpl_f32 a) {
+                static zpl_f32 const a0 = +1.00238601909309722f;
+                static zpl_f32 const a1 = -3.81919947353040024e-2f;
+                static zpl_f32 const a2 = -3.94382342128062756e-1f;
+                static zpl_f32 const a3 = -1.18134036025221444e-1f;
+                static zpl_f32 const a4 = +1.07123798512170878e-1f;
+                static zpl_f32 const a5 = -1.86637164165180873e-2f;
+                static zpl_f32 const a6 = +9.90140908664079833e-4f;
+                static zpl_f32 const a7 = -5.23022132118824778e-14f;
+                return a0 + a * (a1 + a * (a2 + a * (a3 + a * (a4 + a * (a5 + a * (a6 + a * a7))))));
+            }
+
+            zpl_f32 zpl_tan(zpl_f32 radians) {
+                zpl_f32 rr = radians * radians;
+                zpl_f32 a = 9.5168091e-03f;
+                a *= rr;
+                a += 2.900525e-03f;
+                a *= rr;
+                a += 2.45650893e-02f;
+                a *= rr;
+                a += 5.33740603e-02f;
+                a *= rr;
+                a += 1.333923995e-01f;
+                a *= rr;
+                a += 3.333314036e-01f;
+                a *= rr;
+                a += 1.0f;
+                a *= radians;
+                return a;
+            }
+
+            zpl_f32 zpl_arcsin(zpl_f32 a) { return zpl_arctan2(a, zpl_sqrt((1.0f + a) * (1.0f - a))); }
+            zpl_f32 zpl_arccos(zpl_f32 a) { return zpl_arctan2(zpl_sqrt((1.0f + a) * (1.0f - a)), a); }
+
+            zpl_f32 zpl_arctan(zpl_f32 a) {
+                zpl_f32 u = a * a;
+                zpl_f32 u2 = u * u;
+                zpl_f32 u3 = u2 * u;
+                zpl_f32 u4 = u3 * u;
+                zpl_f32 f = 1.0f + 0.33288950512027f * u - 0.08467922817644f * u2 + 0.03252232640125f * u3 - 0.00749305860992f * u4;
+                return a / f;
+            }
+
+            zpl_f32 zpl_arctan2(zpl_f32 y, zpl_f32 x) {
+                if (zpl_abs(x) > zpl_abs(y)) {
+                    zpl_f32 a = zpl_arctan(y / x);
+                    if (x > 0.0f)
+                        return a;
+                    else
+                        return y > 0.0f ? a + ZPL_TAU_OVER_2 : a - ZPL_TAU_OVER_2;
+                } else {
+                    zpl_f32 a = zpl_arctan(x / y);
+                    if (x > 0.0f)
+                        return y > 0.0f ? ZPL_TAU_OVER_4 - a : -ZPL_TAU_OVER_4 - a;
+                    else
+                        return y > 0.0f ? ZPL_TAU_OVER_4 + a : -ZPL_TAU_OVER_4 + a;
+                }
+            }
+
+            zpl_f32 zpl_exp(zpl_f32 a) {
+                union {
+                    zpl_f32 f;
+                    int i;
+                } u, v;
+                u.i = (int)(6051102 * a + 1056478197);
+                v.i = (int)(1056478197 - 6051102 * a);
+                return u.f / v.f;
+            }
+
+            zpl_f32 zpl_log(zpl_f32 a) {
+                union {
+                    zpl_f32 f;
+                    int i;
+                } u = { a };
+                return (u.i - 1064866805) * 8.262958405176314e-8f; /* 1 / 12102203.0; */
+            }
+
+            zpl_f32 zpl_pow(zpl_f32 a, zpl_f32 b) {
+                int flipped = 0, e;
+                zpl_f32 f, r = 1.0f;
+                if (b < 0) {
+                    flipped = 1;
+                    b = -b;
+                }
+
+                e = (int)b;
+                f = zpl_exp(b - e);
+
+                while (e) {
+                    if (e & 1) r *= a;
+                    a *= a;
+                    e >>= 1;
+                }
+
+                r *= f;
+                return flipped ? 1.0f / r : r;
+            }
+
+        #else
+
+            zpl_f32 zpl_rsqrt(zpl_f32 a)              { return 1.0f / __builtin_sqrt(a); }
+            zpl_f32 zpl_sqrt(zpl_f32 a)               { return __builtin_sqrt(a); }
+            zpl_f32 zpl_sin(zpl_f32 radians)          { return __builtin_sinf(radians); }
+            zpl_f32 zpl_cos(zpl_f32 radians)          { return __builtin_cosf(radians); }
+            zpl_f32 zpl_tan(zpl_f32 radians)          { return __builtin_tanf(radians); }
+            zpl_f32 zpl_arcsin(zpl_f32 a)             { return __builtin_asinf(a); }
+            zpl_f32 zpl_arccos(zpl_f32 a)             { return __builtin_acosf(a); }
+            zpl_f32 zpl_arctan(zpl_f32 a)             { return __builtin_atanf(a); }
+            zpl_f32 zpl_arctan2(zpl_f32 y, zpl_f32 x) { return __builtin_atan2f(y, x); }
+
+            zpl_f32 zpl_exp(zpl_f32 x) { return __builtin_expf(x); }
+            zpl_f32 zpl_log(zpl_f32 x) { return __builtin_logf(x); }
+
+            // TODO: Should this be zpl_exp(y * zpl_log(x)) ???
+            zpl_f32 zpl_pow(zpl_f32 x, zpl_f32 y) { return __builtin_powf(x, y); }
+
+        #endif
+    #else
+        zpl_f32 zpl_rsqrt(zpl_f32 a)                { return 1.0f / sqrtf(a); }
+        zpl_f32 zpl_sqrt(zpl_f32 a)                 { return sqrtf(a); };
+        zpl_f32 zpl_sin(zpl_f32 radians)            { return sinf(radians); };
+        zpl_f32 zpl_cos(zpl_f32 radians)            { return cosf(radians); };
+        zpl_f32 zpl_tan(zpl_f32 radians)            { return tanf(radians); };
+        zpl_f32 zpl_arcsin(zpl_f32 a)               { return asinf(a); };
+        zpl_f32 zpl_arccos(zpl_f32 a)               { return acosf(a); };
+        zpl_f32 zpl_arctan(zpl_f32 a)               { return atanf(a); };
+        zpl_f32 zpl_arctan2(zpl_f32 y, zpl_f32 x)   { return atan2f(y, x); };
+
+        zpl_f32 zpl_exp(zpl_f32 x)            { return expf(x); }
+        zpl_f32 zpl_log(zpl_f32 x)            { return logf(x); }
+        zpl_f32 zpl_pow(zpl_f32 x, zpl_f32 y) { return powf(x, y); }
+    #endif
+
+    zpl_f32 zpl_exp2(zpl_f32 x) { return zpl_exp(ZPL_LOG_TWO * x); }
+    zpl_f32 zpl_log2(zpl_f32 x) { return zpl_log(x) / ZPL_LOG_TWO; }
+
+    zpl_f32 zpl_fast_exp(zpl_f32 x) {
+        /* NOTE: Only works in the range -1 <= x <= +1 */
+        zpl_f32 e = 1.0f + x * (1.0f + x * 0.5f * (1.0f + x * 0.3333333333f * (1.0f + x * 0.25f * (1.0f + x * 0.2f))));
+        return e;
+    }
+
+    zpl_f32 zpl_fast_exp2(zpl_f32 x) { return zpl_fast_exp(ZPL_LOG_TWO * x); }
+
+    zpl_f32 zpl_round(zpl_f32 x) { return (float)((x >= 0.0f) ? zpl_floor(x + 0.5f) : zpl_ceil(x - 0.5f)); }
+    zpl_f32 zpl_floor(zpl_f32 x) { return (float)((x >= 0.0f) ? (int)x              : (int)(x - 0.9999999999999999f)); }
+    zpl_f32 zpl_ceil(zpl_f32 x)  { return (float)((x <  0.0f) ? (int)x              : ((int)x) + 1); }
+
+    zpl_f32 zpl_half_to_float(zpl_half value) {
+        union {
+            unsigned int i;
+            zpl_f32 f;
+        } result;
+        int s = (value >> 15) & 0x001;
+        int e = (value >> 10) & 0x01f;
+        int m = value & 0x3ff;
+
+        if (e == 0) {
+            if (m == 0) {
+                /* Plus or minus zero */
+                result.i = (unsigned int)(s << 31);
+                return result.f;
+            } else {
+                /* Denormalized number */
+                while (!(m & 0x00000400)) {
+                    m <<= 1;
+                    e -= 1;
+                }
+
+                e += 1;
+                m &= ~0x00000400;
+            }
+        } else if (e == 31) {
+            if (m == 0) {
+                /* Positive or negative infinity */
+                result.i = (unsigned int)((s << 31) | 0x7f800000);
+                return result.f;
+            } else {
+                /* Nan */
+                result.i = (unsigned int)((s << 31) | 0x7f800000 | (m << 13));
+                return result.f;
+            }
+        }
+
+        e = e + (127 - 15);
+        m = m << 13;
+
+        result.i = (unsigned int)((s << 31) | (e << 23) | m);
+        return result.f;
+    }
+
+    zpl_half zpl_float_to_half(zpl_f32 value) {
+        union {
+            unsigned int i;
+            zpl_f32 f;
+        } v;
+        int i, s, e, m;
+
+        v.f = value;
+        i = (int)v.i;
+
+        s = (i >> 16) & 0x00008000;
+        e = ((i >> 23) & 0x000000ff) - (127 - 15);
+        m = i & 0x007fffff;
+
+        if (e <= 0) {
+            if (e < -10) return (zpl_half)s;
+            m = (m | 0x00800000) >> (1 - e);
+
+            if (m & 0x00001000) m += 0x00002000;
+
+            return (zpl_half)(s | (m >> 13));
+        } else if (e == 0xff - (127 - 15)) {
+            if (m == 0) {
+                return (zpl_half)(s | 0x7c00); /* NOTE: infinity */
+            } else {
+                /* NOTE: NAN */
+                m >>= 13;
+                return (zpl_half)(s | 0x7c00 | m | (m == 0));
+            }
+        } else {
+            if (m & 0x00001000) {
+                m += 0x00002000;
+                if (m & 0x00800000) {
+                    m = 0;
+                    e += 1;
+                }
+            }
+
+            if (e > 30) {
+                zpl_f32 volatile f = 1e12f;
+                int j;
+                for (j = 0; j < 10; j++) f *= f; /* NOTE: Cause overflow */
+
+                return (zpl_half)(s | 0x7c00);
+            }
+
+            return (zpl_half)(s | (e << 10) | (m >> 13));
+        }
+    }
+
+    #define ZPL_VEC2_2OP(a, c, post) \
+        a->x = c.x post;             \
+        a->y = c.y post;
+
+    #define ZPL_VEC2_3OP(a, b, op, c, post) \
+        a->x = b.x op c.x post;             \
+        a->y = b.y op c.y post;
+
+    #define ZPL_VEC3_2OP(a, c, post) \
+        a->x = c.x post;             \
+        a->y = c.y post;             \
+        a->z = c.z post;
+
+    #define ZPL_VEC3_3OP(a, b, op, c, post) \
+        a->x = b.x op c.x post;             \
+        a->y = b.y op c.y post;             \
+        a->z = b.z op c.z post;
+
+    #define ZPL_VEC4_2OP(a, c, post) \
+        a->x = c.x post;             \
+        a->y = c.y post;             \
+        a->z = c.z post;             \
+        a->w = c.w post;
+
+    #define ZPL_VEC4_3OP(a, b, op, c, post) \
+        a->x = b.x op c.x post;             \
+        a->y = b.y op c.y post;             \
+        a->z = b.z op c.z post;             \
+        a->w = b.w op c.w post;
+
+    zpl_vec2 zpl_vec2f_zero(void) {
+        zpl_vec2 v = { 0, 0 };
+        return v;
+    }
+    zpl_vec2 zpl_vec2f(zpl_f32 x, zpl_f32 y) {
+        zpl_vec2 v;
+        v.x = x;
+        v.y = y;
+        return v;
+    }
+    zpl_vec2 zpl_vec2fv(zpl_f32 x[2]) {
+        zpl_vec2 v;
+        v.x = x[0];
+        v.y = x[1];
+        return v;
+    }
+
+    zpl_vec3 zpl_vec3f_zero(void) {
+        zpl_vec3 v = { 0, 0, 0 };
+        return v;
+    }
+    zpl_vec3 zpl_vec3f(zpl_f32 x, zpl_f32 y, zpl_f32 z) {
+        zpl_vec3 v;
+        v.x = x;
+        v.y = y;
+        v.z = z;
+        return v;
+    }
+    zpl_vec3 zpl_vec3fv(zpl_f32 x[3]) {
+        zpl_vec3 v;
+        v.x = x[0];
+        v.y = x[1];
+        v.z = x[2];
+        return v;
+    }
+
+    zpl_vec4 zpl_vec4f_zero(void) {
+        zpl_vec4 v = { 0, 0, 0, 0 };
+        return v;
+    }
+    zpl_vec4 zpl_vec4f(zpl_f32 x, zpl_f32 y, zpl_f32 z, zpl_f32 w) {
+        zpl_vec4 v;
+        v.x = x;
+        v.y = y;
+        v.z = z;
+        v.w = w;
+        return v;
+    }
+    zpl_vec4 zpl_vec4fv(zpl_f32 x[4]) {
+        zpl_vec4 v;
+        v.x = x[0];
+        v.y = x[1];
+        v.z = x[2];
+        v.w = x[3];
+        return v;
+    }
+
+    zpl_f32 zpl_vec2_max(zpl_vec2 v) { return zpl_max(v.x, v.y); }
+    zpl_f32 zpl_vec2_side(zpl_vec2 p, zpl_vec2 q, zpl_vec2 r) { return ((q.x - p.x) * (r.y - p.y) - (r.x - p.x) * (q.y - p.y)); }
+
+    void zpl_vec2_add(zpl_vec2 *d, zpl_vec2 v0, zpl_vec2 v1) { ZPL_VEC2_3OP(d, v0, +, v1, +0); }
+    void zpl_vec2_sub(zpl_vec2 *d, zpl_vec2 v0, zpl_vec2 v1) { ZPL_VEC2_3OP(d, v0, -, v1, +0); }
+    void zpl_vec2_mul(zpl_vec2 *d, zpl_vec2 v, zpl_f32 s)    { ZPL_VEC2_2OP(d, v, *s); }
+    void zpl_vec2_div(zpl_vec2 *d, zpl_vec2 v, zpl_f32 s)    { ZPL_VEC2_2OP(d, v, / s); }
+
+    zpl_f32 zpl_vec3_max(zpl_vec3 v) { return zpl_max3(v.x, v.y, v.z); }
+
+    void zpl_vec3_add(zpl_vec3 *d, zpl_vec3 v0, zpl_vec3 v1) { ZPL_VEC3_3OP(d, v0, +, v1, +0); }
+    void zpl_vec3_sub(zpl_vec3 *d, zpl_vec3 v0, zpl_vec3 v1) { ZPL_VEC3_3OP(d, v0, -, v1, +0); }
+    void zpl_vec3_mul(zpl_vec3 *d, zpl_vec3 v, zpl_f32 s)    { ZPL_VEC3_2OP(d, v, *s); }
+    void zpl_vec3_div(zpl_vec3 *d, zpl_vec3 v, zpl_f32 s)    { ZPL_VEC3_2OP(d, v, / s); }
+
+    void zpl_vec4_add(zpl_vec4 *d, zpl_vec4 v0, zpl_vec4 v1) { ZPL_VEC4_3OP(d, v0, +, v1, +0); }
+    void zpl_vec4_sub(zpl_vec4 *d, zpl_vec4 v0, zpl_vec4 v1) { ZPL_VEC4_3OP(d, v0, -, v1, +0); }
+    void zpl_vec4_mul(zpl_vec4 *d, zpl_vec4 v, zpl_f32 s)    { ZPL_VEC4_2OP(d, v, *s); }
+    void zpl_vec4_div(zpl_vec4 *d, zpl_vec4 v, zpl_f32 s)    { ZPL_VEC4_2OP(d, v, / s); }
+
+    void zpl_vec2_addeq(zpl_vec2 *d, zpl_vec2 v) { ZPL_VEC2_3OP(d, (*d), +, v, +0); }
+    void zpl_vec2_subeq(zpl_vec2 *d, zpl_vec2 v) { ZPL_VEC2_3OP(d, (*d), -, v, +0); }
+    void zpl_vec2_muleq(zpl_vec2 *d, zpl_f32 s)  { ZPL_VEC2_2OP(d, (*d), *s); }
+    void zpl_vec2_diveq(zpl_vec2 *d, zpl_f32 s)  { ZPL_VEC2_2OP(d, (*d), / s); }
+
+    void zpl_vec3_addeq(zpl_vec3 *d, zpl_vec3 v) { ZPL_VEC3_3OP(d, (*d), +, v, +0); }
+    void zpl_vec3_subeq(zpl_vec3 *d, zpl_vec3 v) { ZPL_VEC3_3OP(d, (*d), -, v, +0); }
+    void zpl_vec3_muleq(zpl_vec3 *d, zpl_f32 s)  { ZPL_VEC3_2OP(d, (*d), *s); }
+    void zpl_vec3_diveq(zpl_vec3 *d, zpl_f32 s)  { ZPL_VEC3_2OP(d, (*d), / s); }
+
+    void zpl_vec4_addeq(zpl_vec4 *d, zpl_vec4 v) { ZPL_VEC4_3OP(d, (*d), +, v, +0); }
+    void zpl_vec4_subeq(zpl_vec4 *d, zpl_vec4 v) { ZPL_VEC4_3OP(d, (*d), -, v, +0); }
+    void zpl_vec4_muleq(zpl_vec4 *d, zpl_f32 s)  { ZPL_VEC4_2OP(d, (*d), *s); }
+    void zpl_vec4_diveq(zpl_vec4 *d, zpl_f32 s)  { ZPL_VEC4_2OP(d, (*d), / s); }
+
+    #undef ZPL_VEC2_2OP
+    #undef ZPL_VEC2_3OP
+    #undef ZPL_VEC3_3OP
+    #undef ZPL_VEC3_2OP
+    #undef ZPL_VEC4_2OP
+    #undef ZPL_VEC4_3OP
+
+    zpl_f32 zpl_vec2_dot(zpl_vec2 v0, zpl_vec2 v1) { return v0.x * v1.x + v0.y * v1.y; }
+    zpl_f32 zpl_vec3_dot(zpl_vec3 v0, zpl_vec3 v1) { return v0.x * v1.x + v0.y * v1.y + v0.z * v1.z; }
+    zpl_f32 zpl_vec4_dot(zpl_vec4 v0, zpl_vec4 v1) { return v0.x * v1.x + v0.y * v1.y + v0.z * v1.z + v0.w * v1.w; }
+
+    void zpl_vec2_cross(zpl_f32 *d, zpl_vec2 v0, zpl_vec2 v1) { *d = v0.x * v1.y - v1.x * v0.y; }
+    void zpl_vec3_cross(zpl_vec3 *d, zpl_vec3 v0, zpl_vec3 v1) {
+        d->x = v0.y * v1.z - v0.z * v1.y;
+        d->y = v0.z * v1.x - v0.x * v1.z;
+        d->z = v0.x * v1.y - v0.y * v1.x;
+    }
+
+    zpl_f32 zpl_vec2_mag2(zpl_vec2 v) { return zpl_vec2_dot(v, v); }
+    zpl_f32 zpl_vec3_mag2(zpl_vec3 v) { return zpl_vec3_dot(v, v); }
+    zpl_f32 zpl_vec4_mag2(zpl_vec4 v) { return zpl_vec4_dot(v, v); }
+
+    /* TODO: Create custom sqrt function */
+    zpl_f32 zpl_vec2_mag(zpl_vec2 v) { return zpl_sqrt(zpl_vec2_dot(v, v)); }
+    zpl_f32 zpl_vec3_mag(zpl_vec3 v) { return zpl_sqrt(zpl_vec3_dot(v, v)); }
+    zpl_f32 zpl_vec4_mag(zpl_vec4 v) { return zpl_sqrt(zpl_vec4_dot(v, v)); }
+
+    void zpl_vec2_norm(zpl_vec2 *d, zpl_vec2 v) {
+        zpl_f32 inv_mag = zpl_rsqrt(zpl_vec2_dot(v, v));
+        zpl_vec2_mul(d, v, inv_mag);
+    }
+    void zpl_vec3_norm(zpl_vec3 *d, zpl_vec3 v) {
+        zpl_f32 mag = zpl_vec3_mag(v);
+        zpl_vec3_div(d, v, mag);
+    }
+    void zpl_vec4_norm(zpl_vec4 *d, zpl_vec4 v) {
+        zpl_f32 mag = zpl_vec4_mag(v);
+        zpl_vec4_div(d, v, mag);
+    }
+
+    void zpl_vec2_norm0(zpl_vec2 *d, zpl_vec2 v) {
+        zpl_f32 mag = zpl_vec2_mag(v);
+        if (mag > 0)
+            zpl_vec2_div(d, v, mag);
+        else
+            *d = zpl_vec2f_zero( );
+    }
+    void zpl_vec3_norm0(zpl_vec3 *d, zpl_vec3 v) {
+        zpl_f32 mag = zpl_vec3_mag(v);
+        if (mag > 0)
+            zpl_vec3_div(d, v, mag);
+        else
+            *d = zpl_vec3f_zero( );
+    }
+    void zpl_vec4_norm0(zpl_vec4 *d, zpl_vec4 v) {
+        zpl_f32 mag = zpl_vec4_mag(v);
+        if (mag > 0)
+            zpl_vec4_div(d, v, mag);
+        else
+            *d = zpl_vec4f_zero( );
+    }
+
+    void zpl_vec2_reflect(zpl_vec2 *d, zpl_vec2 i, zpl_vec2 n) {
+        zpl_vec2 b = n;
+        zpl_vec2_muleq(&b, 2.0f * zpl_vec2_dot(n, i));
+        zpl_vec2_sub(d, i, b);
+    }
+
+    void zpl_vec3_reflect(zpl_vec3 *d, zpl_vec3 i, zpl_vec3 n) {
+        zpl_vec3 b = n;
+        zpl_vec3_muleq(&b, 2.0f * zpl_vec3_dot(n, i));
+        zpl_vec3_sub(d, i, b);
+    }
+
+    void zpl_vec2_refract(zpl_vec2 *d, zpl_vec2 i, zpl_vec2 n, zpl_f32 eta) {
+        zpl_vec2 a, b;
+        zpl_f32 dv, k;
+
+        dv = zpl_vec2_dot(n, i);
+        k = 1.0f - eta * eta * (1.0f - dv * dv);
+        zpl_vec2_mul(&a, i, eta);
+        zpl_vec2_mul(&b, n, eta * dv * zpl_sqrt(k));
+        zpl_vec2_sub(d, a, b);
+        zpl_vec2_muleq(d, (float)(k >= 0.0f));
+    }
+
+    void zpl_vec3_refract(zpl_vec3 *d, zpl_vec3 i, zpl_vec3 n, zpl_f32 eta) {
+        zpl_vec3 a, b;
+        zpl_f32 dv, k;
+
+        dv = zpl_vec3_dot(n, i);
+        k = 1.0f - eta * eta * (1.0f - dv * dv);
+        zpl_vec3_mul(&a, i, eta);
+        zpl_vec3_mul(&b, n, eta * dv * zpl_sqrt(k));
+        zpl_vec3_sub(d, a, b);
+        zpl_vec3_muleq(d, (float)(k >= 0.0f));
+    }
+
+    zpl_f32 zpl_vec2_aspect_ratio(zpl_vec2 v) { return (v.y < 0.0001f) ? 0.0f : v.x / v.y; }
+
+    void zpl_mat2_transpose(zpl_mat2 *m) { zpl_float22_transpose(zpl_float22_m(m)); }
+    void zpl_mat2_identity(zpl_mat2 *m) { zpl_float22_identity(zpl_float22_m(m)); }
+    void zpl_mat2_mul(zpl_mat2 *out, zpl_mat2 *m1, zpl_mat2 *m2) {
+        zpl_float22_mul(zpl_float22_m(out), zpl_float22_m(m1), zpl_float22_m(m2));
+    }
+
+    void zpl_float22_identity(zpl_f32 m[2][2]) {
+        m[0][0] = 1;
+        m[0][1] = 0;
+        m[1][0] = 0;
+        m[1][1] = 1;
+    }
+
+    void zpl_mat2_copy(zpl_mat2* out, zpl_mat2* m) {
+        zpl_memcopy(out, m, sizeof(zpl_mat3));
+    }
+
+    void zpl_mat2_mul_vec2(zpl_vec2 *out, zpl_mat2 *m, zpl_vec2 in) { zpl_float22_mul_vec2(out, zpl_float22_m(m), in); }
+
+    zpl_mat2 *zpl_mat2_v(zpl_vec2 m[2])   { return (zpl_mat2 *)m; }
+    zpl_mat2 *zpl_mat2_f(zpl_f32 m[2][2]) { return (zpl_mat2 *)m; }
+
+    zpl_float2 *zpl_float22_m(zpl_mat2 *m)   { return (zpl_float2 *)m; }
+    zpl_float2 *zpl_float22_v(zpl_vec2 m[2]) { return (zpl_float2 *)m; }
+    zpl_float2 *zpl_float22_4(zpl_f32 m[4])  { return (zpl_float2 *)m; }
+
+    void zpl_float22_transpose(zpl_f32 (*vec)[2]) {
+        int i, j;
+        for (j = 0; j < 2; j++) {
+            for (i = j + 1; i < 2; i++) {
+                zpl_f32 t = vec[i][j];
+                vec[i][j] = vec[j][i];
+                vec[j][i] = t;
+            }
+        }
+    }
+
+    void zpl_float22_mul(zpl_f32 (*out)[2], zpl_f32 (*mat1)[2], zpl_f32 (*mat2)[2]) {
+        int i, j;
+        zpl_f32 temp1[2][2], temp2[2][2];
+        if (mat1 == out) {
+            zpl_memcopy(temp1, mat1, sizeof(temp1));
+            mat1 = temp1;
+        }
+        if (mat2 == out) {
+            zpl_memcopy(temp2, mat2, sizeof(temp2));
+            mat2 = temp2;
+        }
+        for (j = 0; j < 2; j++) {
+            for (i = 0; i < 2; i++) { out[j][i] = mat1[0][i] * mat2[j][0] + mat1[1][i] * mat2[j][1]; }
+        }
+    }
+
+    void zpl_float22_mul_vec2(zpl_vec2 *out, zpl_f32 m[2][2], zpl_vec2 v) {
+        out->x = m[0][0] * v.x + m[0][1] * v.y;
+        out->y = m[1][0] * v.x + m[1][1] * v.y;
+    }
+
+    zpl_f32 zpl_mat2_determinate(zpl_mat2 *m) {
+        zpl_float2 *e = zpl_float22_m(m);
+        return e[0][0] * e[1][1] - e[1][0] * e[0][1];
+    }
+
+    void zpl_mat2_inverse(zpl_mat2 *out, zpl_mat2 *in) {
+        zpl_float2 *o = zpl_float22_m(out);
+        zpl_float2 *i = zpl_float22_m(in);
+
+        zpl_f32 ood = 1.0f / zpl_mat2_determinate(in);
+
+        o[0][0] = +i[1][1] * ood;
+        o[0][1] = -i[0][1] * ood;
+        o[1][0] = -i[1][0] * ood;
+        o[1][1] = +i[0][0] * ood;
+    }
+
+    void zpl_mat3_transpose(zpl_mat3 *m) { zpl_float33_transpose(zpl_float33_m(m)); }
+    void zpl_mat3_identity(zpl_mat3 *m)  { zpl_float33_identity(zpl_float33_m(m)); }
+
+    void zpl_mat3_copy(zpl_mat3* out, zpl_mat3* m) {
+        zpl_memcopy(out, m, sizeof(zpl_mat3));
+    }
+
+    void zpl_mat3_mul(zpl_mat3 *out, zpl_mat3 *m1, zpl_mat3 *m2) {
+        zpl_float33_mul(zpl_float33_m(out), zpl_float33_m(m1), zpl_float33_m(m2));
+    }
+
+    void zpl_float33_identity(zpl_f32 m[3][3]) {
+        m[0][0] = 1;
+        m[0][1] = 0;
+        m[0][2] = 0;
+        m[1][0] = 0;
+        m[1][1] = 1;
+        m[1][2] = 0;
+        m[2][0] = 0;
+        m[2][1] = 0;
+        m[2][2] = 1;
+    }
+
+    void zpl_mat3_mul_vec3(zpl_vec3 *out, zpl_mat3 *m, zpl_vec3 in) { zpl_float33_mul_vec3(out, zpl_float33_m(m), in); }
+
+    zpl_mat3 *zpl_mat3_v(zpl_vec3 m[3])   { return (zpl_mat3 *)m; }
+    zpl_mat3 *zpl_mat3_f(zpl_f32 m[3][3]) { return (zpl_mat3 *)m; }
+
+    zpl_float3 *zpl_float33_m(zpl_mat3 *m)   { return (zpl_float3 *)m; }
+    zpl_float3 *zpl_float33_v(zpl_vec3 m[3]) { return (zpl_float3 *)m; }
+    zpl_float3 *zpl_float33_9(zpl_f32 m[9])  { return (zpl_float3 *)m; }
+
+    void zpl_float33_transpose(zpl_f32 (*vec)[3]) {
+        int i, j;
+        for (j = 0; j < 3; j++) {
+            for (i = j + 1; i < 3; i++) {
+                zpl_f32 t = vec[i][j];
+                vec[i][j] = vec[j][i];
+                vec[j][i] = t;
+            }
+        }
+    }
+
+    void zpl_float33_mul(zpl_f32 (*out)[3], zpl_f32 (*mat1)[3], zpl_f32 (*mat2)[3]) {
+        int i, j;
+        zpl_f32 temp1[3][3], temp2[3][3];
+        if (mat1 == out) {
+            zpl_memcopy(temp1, mat1, sizeof(temp1));
+            mat1 = temp1;
+        }
+        if (mat2 == out) {
+            zpl_memcopy(temp2, mat2, sizeof(temp2));
+            mat2 = temp2;
+        }
+        for (j = 0; j < 3; j++) {
+            for (i = 0; i < 3; i++) {
+                out[j][i] = mat1[0][i] * mat2[j][0] + mat1[1][i] * mat2[j][1] + mat1[2][i] * mat2[j][2];
+            }
+        }
+    }
+
+    void zpl_float33_mul_vec3(zpl_vec3 *out, zpl_f32 m[3][3], zpl_vec3 v) {
+        out->x = m[0][0] * v.x + m[0][1] * v.y + m[0][2] * v.z;
+        out->y = m[1][0] * v.x + m[1][1] * v.y + m[1][2] * v.z;
+        out->z = m[2][0] * v.x + m[2][1] * v.y + m[2][2] * v.z;
+    }
+
+    zpl_f32 zpl_mat3_determinate(zpl_mat3 *m) {
+        zpl_float3 *e = zpl_float33_m(m);
+        zpl_f32 d =
+            +e[0][0] * (e[1][1] * e[2][2] - e[1][2] * e[2][1])
+            -e[0][1] * (e[1][0] * e[2][2] - e[1][2] * e[2][0])
+            +e[0][2] * (e[1][0] * e[2][1] - e[1][1] * e[2][0]);
+        return d;
+    }
+
+    void zpl_mat3_inverse(zpl_mat3 *out, zpl_mat3 *in) {
+        zpl_float3 *o = zpl_float33_m(out);
+        zpl_float3 *i = zpl_float33_m(in);
+
+        zpl_f32 ood = 1.0f / zpl_mat3_determinate(in);
+
+        o[0][0] = +(i[1][1] * i[2][2] - i[2][1] * i[1][2]) * ood;
+        o[0][1] = -(i[1][0] * i[2][2] - i[2][0] * i[1][2]) * ood;
+        o[0][2] = +(i[1][0] * i[2][1] - i[2][0] * i[1][1]) * ood;
+        o[1][0] = -(i[0][1] * i[2][2] - i[2][1] * i[0][2]) * ood;
+        o[1][1] = +(i[0][0] * i[2][2] - i[2][0] * i[0][2]) * ood;
+        o[1][2] = -(i[0][0] * i[2][1] - i[2][0] * i[0][1]) * ood;
+        o[2][0] = +(i[0][1] * i[1][2] - i[1][1] * i[0][2]) * ood;
+        o[2][1] = -(i[0][0] * i[1][2] - i[1][0] * i[0][2]) * ood;
+        o[2][2] = +(i[0][0] * i[1][1] - i[1][0] * i[0][1]) * ood;
+    }
+
+    void zpl_mat4_transpose(zpl_mat4 *m) { zpl_float44_transpose(zpl_float44_m(m)); }
+    void zpl_mat4_identity(zpl_mat4 *m)  { zpl_float44_identity(zpl_float44_m(m)); }
+
+    void zpl_mat4_copy(zpl_mat4* out, zpl_mat4* m) {
+        zpl_memcopy(out, m, sizeof(zpl_mat4));
+    }
+
+
+    void zpl_mat4_mul(zpl_mat4 *out, zpl_mat4 *m1, zpl_mat4 *m2) {
+        zpl_float44_mul(zpl_float44_m(out), zpl_float44_m(m1), zpl_float44_m(m2));
+    }
+
+    void zpl_float44_identity(zpl_f32 m[4][4]) {
+        m[0][0] = 1;
+        m[0][1] = 0;
+        m[0][2] = 0;
+        m[0][3] = 0;
+        m[1][0] = 0;
+        m[1][1] = 1;
+        m[1][2] = 0;
+        m[1][3] = 0;
+        m[2][0] = 0;
+        m[2][1] = 0;
+        m[2][2] = 1;
+        m[2][3] = 0;
+        m[3][0] = 0;
+        m[3][1] = 0;
+        m[3][2] = 0;
+        m[3][3] = 1;
+    }
+
+    void zpl_mat4_mul_vec4(zpl_vec4 *out, zpl_mat4 *m, zpl_vec4 in) { zpl_float44_mul_vec4(out, zpl_float44_m(m), in); }
+
+    zpl_mat4 *zpl_mat4_v(zpl_vec4 m[4])   { return (zpl_mat4 *)m; }
+    zpl_mat4 *zpl_mat4_f(zpl_f32 m[4][4]) { return (zpl_mat4 *)m; }
+
+    zpl_float4 *zpl_float44_m(zpl_mat4 *m)    { return (zpl_float4 *)m; }
+    zpl_float4 *zpl_float44_v(zpl_vec4 m[4])  { return (zpl_float4 *)m; }
+    zpl_float4 *zpl_float44_16(zpl_f32 m[16]) { return (zpl_float4 *)m; }
+
+    void zpl_float44_transpose(zpl_f32 (*vec)[4]) {
+        zpl_f32 tmp;
+        tmp = vec[1][0];
+        vec[1][0] = vec[0][1];
+        vec[0][1] = tmp;
+        tmp = vec[2][0];
+        vec[2][0] = vec[0][2];
+        vec[0][2] = tmp;
+        tmp = vec[3][0];
+        vec[3][0] = vec[0][3];
+        vec[0][3] = tmp;
+        tmp = vec[2][1];
+        vec[2][1] = vec[1][2];
+        vec[1][2] = tmp;
+        tmp = vec[3][1];
+        vec[3][1] = vec[1][3];
+        vec[1][3] = tmp;
+        tmp = vec[3][2];
+        vec[3][2] = vec[2][3];
+        vec[2][3] = tmp;
+    }
+
+    void zpl_float44_mul(zpl_f32 (*out)[4], zpl_f32 (*mat1)[4], zpl_f32 (*mat2)[4]) {
+        int i, j;
+        zpl_f32 temp1[4][4], temp2[4][4];
+        if (mat1 == out) {
+            zpl_memcopy(temp1, mat1, sizeof(temp1));
+            mat1 = temp1;
+        }
+        if (mat2 == out) {
+            zpl_memcopy(temp2, mat2, sizeof(temp2));
+            mat2 = temp2;
+        }
+        for (j = 0; j < 4; j++) {
+            for (i = 0; i < 4; i++) {
+                out[j][i] =
+                    mat1[0][i] * mat2[j][0] + mat1[1][i] * mat2[j][1]
+                   +mat1[2][i] * mat2[j][2] + mat1[3][i] * mat2[j][3];
+            }
+        }
+    }
+
+    void zpl_float44_mul_vec4(zpl_vec4 *out, zpl_f32 m[4][4], zpl_vec4 v) {
+        out->x = m[0][0] * v.x + m[1][0] * v.y + m[2][0] * v.z + m[3][0] * v.w;
+        out->y = m[0][1] * v.x + m[1][1] * v.y + m[2][1] * v.z + m[3][1] * v.w;
+        out->z = m[0][2] * v.x + m[1][2] * v.y + m[2][2] * v.z + m[3][2] * v.w;
+        out->w = m[0][3] * v.x + m[1][3] * v.y + m[2][3] * v.z + m[3][3] * v.w;
+    }
+
+    void zpl_mat4_inverse(zpl_mat4 *out, zpl_mat4 *in) {
+        zpl_float4 *o = zpl_float44_m(out);
+        zpl_float4 *m = zpl_float44_m(in);
+
+        zpl_f32 ood;
+
+        zpl_f32 sf00 = m[2][2] * m[3][3] - m[3][2] * m[2][3];
+        zpl_f32 sf01 = m[2][1] * m[3][3] - m[3][1] * m[2][3];
+        zpl_f32 sf02 = m[2][1] * m[3][2] - m[3][1] * m[2][2];
+        zpl_f32 sf03 = m[2][0] * m[3][3] - m[3][0] * m[2][3];
+        zpl_f32 sf04 = m[2][0] * m[3][2] - m[3][0] * m[2][2];
+        zpl_f32 sf05 = m[2][0] * m[3][1] - m[3][0] * m[2][1];
+        zpl_f32 sf06 = m[1][2] * m[3][3] - m[3][2] * m[1][3];
+        zpl_f32 sf07 = m[1][1] * m[3][3] - m[3][1] * m[1][3];
+        zpl_f32 sf08 = m[1][1] * m[3][2] - m[3][1] * m[1][2];
+        zpl_f32 sf09 = m[1][0] * m[3][3] - m[3][0] * m[1][3];
+        zpl_f32 sf10 = m[1][0] * m[3][2] - m[3][0] * m[1][2];
+        zpl_f32 sf11 = m[1][1] * m[3][3] - m[3][1] * m[1][3];
+        zpl_f32 sf12 = m[1][0] * m[3][1] - m[3][0] * m[1][1];
+        zpl_f32 sf13 = m[1][2] * m[2][3] - m[2][2] * m[1][3];
+        zpl_f32 sf14 = m[1][1] * m[2][3] - m[2][1] * m[1][3];
+        zpl_f32 sf15 = m[1][1] * m[2][2] - m[2][1] * m[1][2];
+        zpl_f32 sf16 = m[1][0] * m[2][3] - m[2][0] * m[1][3];
+        zpl_f32 sf17 = m[1][0] * m[2][2] - m[2][0] * m[1][2];
+        zpl_f32 sf18 = m[1][0] * m[2][1] - m[2][0] * m[1][1];
+
+        o[0][0] = +(m[1][1] * sf00 - m[1][2] * sf01 + m[1][3] * sf02);
+        o[1][0] = -(m[1][0] * sf00 - m[1][2] * sf03 + m[1][3] * sf04);
+        o[2][0] = +(m[1][0] * sf01 - m[1][1] * sf03 + m[1][3] * sf05);
+        o[3][0] = -(m[1][0] * sf02 - m[1][1] * sf04 + m[1][2] * sf05);
+
+        o[0][1] = -(m[0][1] * sf00 - m[0][2] * sf01 + m[0][3] * sf02);
+        o[1][1] = +(m[0][0] * sf00 - m[0][2] * sf03 + m[0][3] * sf04);
+        o[2][1] = -(m[0][0] * sf01 - m[0][1] * sf03 + m[0][3] * sf05);
+        o[3][1] = +(m[0][0] * sf02 - m[0][1] * sf04 + m[0][2] * sf05);
+
+        o[0][2] = +(m[0][1] * sf06 - m[0][2] * sf07 + m[0][3] * sf08);
+        o[1][2] = -(m[0][0] * sf06 - m[0][2] * sf09 + m[0][3] * sf10);
+        o[2][2] = +(m[0][0] * sf11 - m[0][1] * sf09 + m[0][3] * sf12);
+        o[3][2] = -(m[0][0] * sf08 - m[0][1] * sf10 + m[0][2] * sf12);
+
+        o[0][3] = -(m[0][1] * sf13 - m[0][2] * sf14 + m[0][3] * sf15);
+        o[1][3] = +(m[0][0] * sf13 - m[0][2] * sf16 + m[0][3] * sf17);
+        o[2][3] = -(m[0][0] * sf14 - m[0][1] * sf16 + m[0][3] * sf18);
+        o[3][3] = +(m[0][0] * sf15 - m[0][1] * sf17 + m[0][2] * sf18);
+
+        ood = 1.0f / (m[0][0] * o[0][0] + m[0][1] * o[1][0] + m[0][2] * o[2][0] + m[0][3] * o[3][0]);
+
+        o[0][0] *= ood; o[1][0] *= ood; o[2][0] *= ood; o[3][0] *= ood;
+        o[0][1] *= ood; o[1][1] *= ood; o[2][1] *= ood; o[3][1] *= ood;
+        o[0][2] *= ood; o[1][2] *= ood; o[2][2] *= ood; o[3][2] *= ood;
+        o[0][3] *= ood; o[1][3] *= ood; o[2][3] *= ood; o[3][3] *= ood;
+    }
+
+    void zpl_mat4_translate(zpl_mat4 *out, zpl_vec3 v) {
+        zpl_mat4_identity(out);
+        out->col[3].xyz = v;
+        out->col[3].w = 1;
+    }
+
+    void zpl_mat4_rotate(zpl_mat4 *out, zpl_vec3 v, zpl_f32 angle_radians) {
+        zpl_f32 c, s;
+        zpl_vec3 axis, t;
+        zpl_float4 *rot;
+
+        c = zpl_cos(angle_radians);
+        s = zpl_sin(angle_radians);
+
+        zpl_vec3_norm(&axis, v);
+        zpl_vec3_mul(&t, axis, 1.0f - c);
+
+        zpl_mat4_identity(out);
+        rot = zpl_float44_m(out);
+
+        rot[0][0] = c + t.x * axis.x;
+        rot[0][1] = 0 + t.x * axis.y + s * axis.z;
+        rot[0][2] = 0 + t.x * axis.z - s * axis.y;
+        rot[0][3] = 0;
+
+        rot[1][0] = 0 + t.y * axis.x - s * axis.z;
+        rot[1][1] = c + t.y * axis.y;
+        rot[1][2] = 0 + t.y * axis.z + s * axis.x;
+        rot[1][3] = 0;
+
+        rot[2][0] = 0 + t.z * axis.x + s * axis.y;
+        rot[2][1] = 0 + t.z * axis.y - s * axis.x;
+        rot[2][2] = c + t.z * axis.z;
+        rot[2][3] = 0;
+    }
+
+    void zpl_mat4_scale(zpl_mat4 *out, zpl_vec3 v) {
+        zpl_mat4_identity(out);
+        out->e[0]  = v.x;
+        out->e[5]  = v.y;
+        out->e[10] = v.z;
+    }
+
+    void zpl_mat4_scalef(zpl_mat4 *out, zpl_f32 s) {
+        zpl_mat4_identity(out);
+        out->e[0]  = s;
+        out->e[5]  = s;
+        out->e[10] = s;
+    }
+
+    void zpl_mat4_ortho2d(zpl_mat4 *out, zpl_f32 left, zpl_f32 right, zpl_f32 bottom, zpl_f32 top) {
+        zpl_float4 *m;
+        zpl_mat4_identity(out);
+        m = zpl_float44_m(out);
+
+        m[0][0] = 2.0f / (right - left);
+        m[1][1] = 2.0f / (top - bottom);
+        m[2][2] = -1.0f;
+        m[3][0] = -(right + left) / (right - left);
+        m[3][1] = -(top + bottom) / (top - bottom);
+    }
+
+    void zpl_mat4_ortho3d(zpl_mat4 *out, zpl_f32 left, zpl_f32 right, zpl_f32 bottom, zpl_f32 top, zpl_f32 z_near, zpl_f32 z_far) {
+        zpl_float4 *m;
+        zpl_mat4_identity(out);
+        m = zpl_float44_m(out);
+
+        m[0][0] = +2.0f / (right - left);
+        m[1][1] = +2.0f / (top - bottom);
+        m[2][2] = -2.0f / (z_far - z_near);
+        m[3][0] = -(right + left) / (right - left);
+        m[3][1] = -(top + bottom) / (top - bottom);
+        m[3][2] = -(z_far + z_near) / (z_far - z_near);
+    }
+
+    void zpl_mat4_perspective(zpl_mat4 *out, zpl_f32 fovy, zpl_f32 aspect, zpl_f32 z_near, zpl_f32 z_far) {
+        zpl_f32 tan_half_fovy = zpl_tan(0.5f * fovy);
+        zpl_mat4 zero_mat = { 0 };
+        zpl_float4 *m = zpl_float44_m(out);
+        *out = zero_mat;
+
+        m[0][0] = 1.0f / (aspect * tan_half_fovy);
+        m[1][1] = 1.0f / (tan_half_fovy);
+        m[2][2] = -(z_far + z_near) / (z_far - z_near);
+        m[2][3] = -1.0f;
+        m[3][2] = -2.0f * z_far * z_near / (z_far - z_near);
+    }
+
+    void zpl_mat4_infinite_perspective(zpl_mat4 *out, zpl_f32 fovy, zpl_f32 aspect, zpl_f32 z_near) {
+        zpl_f32 range = zpl_tan(0.5f * fovy) * z_near;
+        zpl_f32 left = -range * aspect;
+        zpl_f32 right = range * aspect;
+        zpl_f32 bottom = -range;
+        zpl_f32 top = range;
+        zpl_mat4 zero_mat = { 0 };
+        zpl_float4 *m = zpl_float44_m(out);
+        *out = zero_mat;
+
+        m[0][0] = (2.0f * z_near) / (right - left);
+        m[1][1] = (2.0f * z_near) / (top - bottom);
+        m[2][2] = -1.0f;
+        m[2][3] = -1.0f;
+        m[3][2] = -2.0f * z_near;
+    }
+
+    void zpl_mat4_ortho2d_dx(zpl_mat4 *out, zpl_f32 left, zpl_f32 right, zpl_f32 bottom, zpl_f32 top) {
+        zpl_float4 *m;
+        zpl_mat4_identity(out);
+        m = zpl_float44_m(out);
+
+        m[0][0] = 2.0f / (right - left);
+        m[1][1] = 2.0f / (top - bottom);
+        m[2][2] = -1.0f;
+        m[3][0] = -(right + left) / (right - left);
+        m[3][1] = -(top + bottom) / (top - bottom);
+    }
+
+    void zpl_mat4_ortho3d_dx(zpl_mat4 *out, zpl_f32 left, zpl_f32 right, zpl_f32 bottom, zpl_f32 top, zpl_f32 z_near, zpl_f32 z_far) {
+        zpl_float4 *m;
+        zpl_mat4_identity(out);
+        m = zpl_float44_m(out);
+
+        m[0][0] = +2.0f / (right - left);
+        m[1][1] = +2.0f / (top - bottom);
+        m[2][2] = -1.0f / (z_far - z_near);
+        m[3][0] = -(right + left) / (right - left);
+        m[3][1] = -(top + bottom) / (top - bottom);
+        m[3][2] = -( z_near) / (z_far - z_near);
+    }
+
+    void zpl_mat4_perspective_dx(zpl_mat4 *out, zpl_f32 fovy, zpl_f32 aspect, zpl_f32 z_near, zpl_f32 z_far) {
+        zpl_f32 tan_half_fovy = zpl_tan(0.5f * fovy);
+        zpl_mat4 zero_mat = { 0 };
+        zpl_float4 *m = zpl_float44_m(out);
+        *out = zero_mat;
+
+        m[0][0] = 1.0f / (aspect * tan_half_fovy);
+        m[1][1] = 1.0f / (tan_half_fovy);
+        m[2][2] = -(z_far ) / (z_far - z_near);
+        m[2][3] = -1.0f;
+        m[3][2] = - z_near / (z_far - z_near);
+    }
+
+    void zpl_mat4_infinite_perspective_dx(zpl_mat4 *out, zpl_f32 fovy, zpl_f32 aspect, zpl_f32 z_near) {
+         zpl_f32 tan_half_fovy = zpl_tan(0.5f * fovy);
+        zpl_mat4 zero_mat = { 0 };
+        zpl_float4 *m = zpl_float44_m(out);
+        *out = zero_mat;
+
+        m[0][0] = 1.0f / (aspect * tan_half_fovy);
+        m[1][1] = 1.0f / (tan_half_fovy);
+        m[2][2] = -1.0f;
+        m[2][3] = -1.0f;
+        m[3][2] = - z_near;
+    }
+
+
+
+    void zpl_mat4_look_at(zpl_mat4 *out, zpl_vec3 eye, zpl_vec3 centre, zpl_vec3 up) {
+        zpl_vec3 f, s, u;
+        zpl_float4 *m;
+
+        zpl_vec3_sub(&f, centre, eye);
+        zpl_vec3_norm(&f, f);
+
+        zpl_vec3_cross(&s, f, up);
+        zpl_vec3_norm(&s, s);
+
+        zpl_vec3_cross(&u, s, f);
+
+        zpl_mat4_identity(out);
+        m = zpl_float44_m(out);
+
+        m[0][0] = +s.x;
+        m[1][0] = +s.y;
+        m[2][0] = +s.z;
+
+        m[0][1] = +u.x;
+        m[1][1] = +u.y;
+        m[2][1] = +u.z;
+
+        m[0][2] = -f.x;
+        m[1][2] = -f.y;
+        m[2][2] = -f.z;
+
+        m[3][0] = -zpl_vec3_dot(s, eye);
+        m[3][1] = -zpl_vec3_dot(u, eye);
+        m[3][2] = +zpl_vec3_dot(f, eye);
+    }
+
+    void zpl_mat4_look_at_lh(zpl_mat4 *out, zpl_vec3 eye, zpl_vec3 centre, zpl_vec3 up) {
+        zpl_vec3 f, s, u;
+        zpl_float4 *m;
+
+        zpl_vec3_sub(&f, centre, eye);
+        zpl_vec3_norm(&f, f);
+
+        zpl_vec3_cross(&s, up, f);
+        zpl_vec3_norm(&s, s);
+
+        zpl_vec3_cross(&u, f, s);
+
+        zpl_mat4_identity(out);
+        m = zpl_float44_m(out);
+
+        m[0][0] = +s.x;
+        m[1][0] = +s.y;
+        m[2][0] = +s.z;
+
+        m[0][1] = +u.x;
+        m[1][1] = +u.y;
+        m[2][1] = +u.z;
+
+        m[0][2] = +f.x;
+        m[1][2] = +f.y;
+        m[2][2] = +f.z;
+
+        m[3][0] = -zpl_vec3_dot(s, eye);
+        m[3][1] = -zpl_vec3_dot(u, eye);
+        m[3][2] = -zpl_vec3_dot(f, eye);
+    }
+
+    zpl_quat zpl_quatf(zpl_f32 x, zpl_f32 y, zpl_f32 z, zpl_f32 w) {
+        zpl_quat q;
+        q.x = x;
+        q.y = y;
+        q.z = z;
+        q.w = w;
+        return q;
+    }
+    zpl_quat zpl_quatfv(zpl_f32 e[4]) {
+        zpl_quat q;
+        q.x = e[0];
+        q.y = e[1];
+        q.z = e[2];
+        q.w = e[3];
+        return q;
+    }
+
+    zpl_quat zpl_quat_axis_angle(zpl_vec3 axis, zpl_f32 angle_radians) {
+        zpl_quat q;
+        zpl_vec3_norm(&q.xyz, axis);
+        zpl_vec3_muleq(&q.xyz, zpl_sin(0.5f * angle_radians));
+        q.w = zpl_cos(0.5f * angle_radians);
+        return q;
+    }
+
+    zpl_quat zpl_quat_euler_angles(zpl_f32 pitch, zpl_f32 yaw, zpl_f32 roll) {
+        /* TODO: Do without multiplication, i.e. make it faster */
+        zpl_quat q, p, y, r;
+        p = zpl_quat_axis_angle(zpl_vec3f(1, 0, 0), pitch);
+        y = zpl_quat_axis_angle(zpl_vec3f(0, 1, 0), yaw);
+        r = zpl_quat_axis_angle(zpl_vec3f(0, 0, 1), roll);
+
+        zpl_quat_mul(&q, y, p);
+        zpl_quat_muleq(&q, r);
+
+        return q;
+    }
+
+    zpl_quat zpl_quat_identity(void) {
+        zpl_quat q = { 0, 0, 0, 1 };
+        return q;
+    }
+
+    void zpl_quat_add(zpl_quat *d, zpl_quat q0, zpl_quat q1) { zpl_vec4_add(&d->xyzw, q0.xyzw, q1.xyzw); }
+    void zpl_quat_sub(zpl_quat *d, zpl_quat q0, zpl_quat q1) { zpl_vec4_sub(&d->xyzw, q0.xyzw, q1.xyzw); }
+
+    void zpl_quat_mul(zpl_quat *d, zpl_quat q0, zpl_quat q1) {
+        d->x = q0.w * q1.x + q0.x * q1.w + q0.y * q1.z - q0.z * q1.y;
+        d->y = q0.w * q1.y - q0.x * q1.z + q0.y * q1.w + q0.z * q1.x;
+        d->z = q0.w * q1.z + q0.x * q1.y - q0.y * q1.x + q0.z * q1.w;
+        d->w = q0.w * q1.w - q0.x * q1.x - q0.y * q1.y - q0.z * q1.z;
+    }
+
+    void zpl_quat_div(zpl_quat *d, zpl_quat q0, zpl_quat q1) {
+        zpl_quat iq1;
+        zpl_quat_inverse(&iq1, q1);
+        zpl_quat_mul(d, q0, iq1);
+    }
+
+    void zpl_quat_mulf(zpl_quat *d, zpl_quat q0, zpl_f32 s) { zpl_vec4_mul(&d->xyzw, q0.xyzw, s); }
+    void zpl_quat_divf(zpl_quat *d, zpl_quat q0, zpl_f32 s) { zpl_vec4_div(&d->xyzw, q0.xyzw, s); }
+
+    void zpl_quat_addeq(zpl_quat *d, zpl_quat q) { zpl_vec4_addeq(&d->xyzw, q.xyzw); }
+    void zpl_quat_subeq(zpl_quat *d, zpl_quat q) { zpl_vec4_subeq(&d->xyzw, q.xyzw); }
+    void zpl_quat_muleq(zpl_quat *d, zpl_quat q) { zpl_quat_mul(d, *d, q); }
+    void zpl_quat_diveq(zpl_quat *d, zpl_quat q) { zpl_quat_div(d, *d, q); }
+
+    void zpl_quat_muleqf(zpl_quat *d, zpl_f32 s) { zpl_vec4_muleq(&d->xyzw, s); }
+    void zpl_quat_diveqf(zpl_quat *d, zpl_f32 s) { zpl_vec4_diveq(&d->xyzw, s); }
+
+    zpl_f32 zpl_quat_dot(zpl_quat q0, zpl_quat q1) {
+        zpl_f32 r = zpl_vec3_dot(q0.xyz, q1.xyz) + q0.w * q1.w;
+        return r;
+    }
+    zpl_f32 zpl_quat_mag(zpl_quat q) {
+        zpl_f32 r = zpl_sqrt(zpl_quat_dot(q, q));
+        return r;
+    }
+
+    void zpl_quat_norm(zpl_quat *d, zpl_quat q) { zpl_quat_divf(d, q, zpl_quat_mag(q)); }
+
+    void zpl_quat_conj(zpl_quat *d, zpl_quat q) {
+        d->xyz = zpl_vec3f(-q.x, -q.y, -q.z);
+        d->w = q.w;
+    }
+    void zpl_quat_inverse(zpl_quat *d, zpl_quat q) {
+        zpl_quat_conj(d, q);
+        zpl_quat_diveqf(d, zpl_quat_dot(q, q));
+    }
+
+    void zpl_quat_axis(zpl_vec3 *axis, zpl_quat q) {
+        zpl_quat n;
+        zpl_quat_norm(&n, q);
+        zpl_vec3_div(axis, n.xyz, zpl_sin(zpl_arccos(q.w)));
+    }
+
+    zpl_f32 zpl_quat_angle(zpl_quat q) {
+        zpl_f32 mag   = zpl_quat_mag(q);
+        zpl_f32 c     = q.w * (1.0f / mag);
+        zpl_f32 angle = 2.0f * zpl_arccos(c);
+        return angle;
+    }
+
+    zpl_f32 zpl_quat_roll(zpl_quat q) {
+        return zpl_arctan2(2.0f * q.x * q.y + q.z * q.w, q.x * q.x + q.w * q.w - q.y * q.y - q.z * q.z);
+    }
+    zpl_f32 zpl_quat_pitch(zpl_quat q) {
+        return zpl_arctan2(2.0f * q.y * q.z + q.w * q.x, q.w * q.w - q.x * q.x - q.y * q.y + q.z * q.z);
+    }
+    zpl_f32 zpl_quat_yaw(zpl_quat q) { return zpl_arcsin(-2.0f * (q.x * q.z - q.w * q.y)); }
+
+    void zpl_quat_rotate_vec3(zpl_vec3 *d, zpl_quat q, zpl_vec3 v) {
+        /* zpl_vec3 t = 2.0f * cross(q.xyz, v);
+         * *d = q.w*t + v + cross(q.xyz, t);
+         */
+        zpl_vec3 t, p;
+        zpl_vec3_cross(&t, q.xyz, v);
+        zpl_vec3_muleq(&t, 2.0f);
+
+        zpl_vec3_cross(&p, q.xyz, t);
+
+        zpl_vec3_mul(d, t, q.w);
+        zpl_vec3_addeq(d, v);
+        zpl_vec3_addeq(d, p);
+    }
+
+    void zpl_mat4_from_quat(zpl_mat4 *out, zpl_quat q) {
+        zpl_float4 *m;
+        zpl_quat a;
+        zpl_f32 xx, yy, zz, xy, xz, yz, wx, wy, wz;
+
+        zpl_quat_norm(&a, q);
+        xx = a.x * a.x;
+        yy = a.y * a.y;
+        zz = a.z * a.z;
+        xy = a.x * a.y;
+        xz = a.x * a.z;
+        yz = a.y * a.z;
+        wx = a.w * a.x;
+        wy = a.w * a.y;
+        wz = a.w * a.z;
+
+        zpl_mat4_identity(out);
+        m = zpl_float44_m(out);
+
+        m[0][0] = 1.0f - 2.0f * (yy + zz);
+        m[0][1] = 2.0f * (xy + wz);
+        m[0][2] = 2.0f * (xz - wy);
+
+        m[1][0] = 2.0f * (xy - wz);
+        m[1][1] = 1.0f - 2.0f * (xx + zz);
+        m[1][2] = 2.0f * (yz + wx);
+
+        m[2][0] = 2.0f * (xz + wy);
+        m[2][1] = 2.0f * (yz - wx);
+        m[2][2] = 1.0f - 2.0f * (xx + yy);
+    }
+
+    void zpl_quat_from_mat4(zpl_quat *out, zpl_mat4 *mat) {
+        zpl_float4 *m;
+        zpl_f32 four_x_squared_minus_1, four_y_squared_minus_1, four_z_squared_minus_1, four_w_squared_minus_1,
+        four_biggest_squared_minus_1;
+        int biggest_index = 0;
+        zpl_f32 biggest_value, mult;
+
+        m = zpl_float44_m(mat);
+
+        four_x_squared_minus_1 = m[0][0] - m[1][1] - m[2][2];
+        four_y_squared_minus_1 = m[1][1] - m[0][0] - m[2][2];
+        four_z_squared_minus_1 = m[2][2] - m[0][0] - m[1][1];
+        four_w_squared_minus_1 = m[0][0] + m[1][1] + m[2][2];
+
+        four_biggest_squared_minus_1 = four_w_squared_minus_1;
+        if (four_x_squared_minus_1 > four_biggest_squared_minus_1) {
+            four_biggest_squared_minus_1 = four_x_squared_minus_1;
+            biggest_index = 1;
+        }
+        if (four_y_squared_minus_1 > four_biggest_squared_minus_1) {
+            four_biggest_squared_minus_1 = four_y_squared_minus_1;
+            biggest_index = 2;
+        }
+        if (four_z_squared_minus_1 > four_biggest_squared_minus_1) {
+            four_biggest_squared_minus_1 = four_z_squared_minus_1;
+            biggest_index = 3;
+        }
+
+        biggest_value = zpl_sqrt(four_biggest_squared_minus_1 + 1.0f) * 0.5f;
+        mult = 0.25f / biggest_value;
+
+        switch (biggest_index) {
+            case 0:
+                out->w = biggest_value;
+                out->x = (m[1][2] - m[2][1]) * mult;
+                out->y = (m[2][0] - m[0][2]) * mult;
+                out->z = (m[0][1] - m[1][0]) * mult;
+                break;
+            case 1:
+                out->w = (m[1][2] - m[2][1]) * mult;
+                out->x = biggest_value;
+                out->y = (m[0][1] + m[1][0]) * mult;
+                out->z = (m[2][0] + m[0][2]) * mult;
+                break;
+            case 2:
+                out->w = (m[2][0] - m[0][2]) * mult;
+                out->x = (m[0][1] + m[1][0]) * mult;
+                out->y = biggest_value;
+                out->z = (m[1][2] + m[2][1]) * mult;
+                break;
+            case 3:
+                out->w = (m[0][1] - m[1][0]) * mult;
+                out->x = (m[2][0] + m[0][2]) * mult;
+                out->y = (m[1][2] + m[2][1]) * mult;
+                out->z = biggest_value;
+                break;
+        }
+    }
+
+    zpl_f32 zpl_plane_distance(zpl_plane* p, zpl_vec3 v) {
+        return (p->a * v.x + p->b * v.y + p->c * v.z + p->d);
+    }
+
+    void zpl_frustum_create(zpl_frustum* out, zpl_mat4* camera, zpl_mat4* proj) {
+        zpl_mat4 pv;
+
+        zpl_mat4_mul(&pv, camera, proj);
+
+        register zpl_plane* fp = 0;
+        zpl_f32 rmag;
+
+        fp = &out->x1;
+        fp->a = pv.x.w + pv.x.x;
+        fp->b = pv.y.w + pv.x.y;
+        fp->c = pv.z.w + pv.x.z;
+        fp->d = pv.w.w + pv.x.w;
+
+        rmag = zpl_rsqrt(zpl_square(fp->a) + zpl_square(fp->b) + zpl_square(fp->c));
+
+        fp->a *= rmag;
+        fp->b *= rmag;
+        fp->c *= rmag;
+        fp->d *= rmag;
+
+        fp = &out->x2;
+
+        fp->a = pv.x.w - pv.x.x;
+        fp->b = pv.y.w - pv.x.y;
+        fp->c = pv.z.w - pv.x.z;
+        fp->d = pv.w.w - pv.x.w;
+
+        rmag = zpl_rsqrt(zpl_square(fp->a) + zpl_square(fp->b) + zpl_square(fp->c));
+
+        fp->a *= rmag;
+        fp->b *= rmag;
+        fp->c *= rmag;
+        fp->d *= rmag;
+
+        fp = &out->y1;
+
+        fp->a = pv.x.w - pv.y.x;
+        fp->b = pv.y.w - pv.y.y;
+        fp->c = pv.z.w - pv.y.w;
+        fp->d = pv.w.w - pv.y.z;
+
+        rmag = zpl_rsqrt(zpl_square(fp->a) + zpl_square(fp->b) + zpl_square(fp->c));
+
+        fp->a *= rmag;
+        fp->b *= rmag;
+        fp->c *= rmag;
+        fp->d *= rmag;
+
+        fp = &out->y2;
+
+        fp->a = pv.x.w + pv.y.x;
+        fp->b = pv.y.w + pv.y.y;
+        fp->c = pv.z.w + pv.y.z;
+        fp->d = pv.w.w + pv.y.w;
+
+        rmag = zpl_rsqrt(zpl_square(fp->a) + zpl_square(fp->b) + zpl_square(fp->c));
+
+        fp->a *= rmag;
+        fp->b *= rmag;
+        fp->c *= rmag;
+        fp->d *= rmag;;
+
+        fp = &out->z1;
+
+        fp->a = pv.x.w + pv.z.x;
+        fp->b = pv.y.w + pv.z.y;
+        fp->c = pv.z.w + pv.z.z;
+        fp->d = pv.w.w + pv.z.w;
+
+        rmag = zpl_rsqrt(zpl_square(fp->a) + zpl_square(fp->b) + zpl_square(fp->c));
+
+        fp->a *= rmag;
+        fp->b *= rmag;
+        fp->c *= rmag;
+        fp->d *= rmag;
+
+        fp = &out->z2;
+
+        fp->a = pv.x.w - pv.z.x;
+        fp->b = pv.y.w - pv.z.y;
+        fp->c = pv.z.w - pv.z.z;
+        fp->d = pv.w.w - pv.z.w;
+
+        rmag = zpl_rsqrt(zpl_square(fp->a) + zpl_square(fp->b) + zpl_square(fp->c));
+
+        fp->a *= rmag;
+        fp->b *= rmag;
+        fp->c *= rmag;
+        fp->d *= rmag;
+    }
+
+    zpl_b8 zpl_frustum_sphere_inside(zpl_frustum* frustum, zpl_vec3 center, zpl_f32 radius) {
+        if (zpl_plane_distance(&frustum->x1, center) <= -radius) return 0;
+        if (zpl_plane_distance(&frustum->x2, center) <= -radius) return 0;
+        if (zpl_plane_distance(&frustum->y1, center) <= -radius) return 0;
+        if (zpl_plane_distance(&frustum->y2, center) <= -radius) return 0;
+        if (zpl_plane_distance(&frustum->z1, center) <= -radius) return 0;
+        if (zpl_plane_distance(&frustum->z2, center) <= -radius) return 0;
+
+        return 1;
+    }
+
+    zpl_b8 zpl_frustum_point_inside(zpl_frustum* frustum, zpl_vec3 point) {
+        return zpl_frustum_sphere_inside(frustum, point, 0.0f);
+    }
+
+    zpl_b8 zpl_frustum_box_inside(zpl_frustum* frustum, zpl_aabb3 aabb) {
+        
+        zpl_vec3 box = aabb.half_size;
+        zpl_vec3 v, b;
+
+        b = zpl_vec3f(-box.x, -box.y, -box.z);
+        zpl_vec3_add(&v, b, aabb.centre);
+
+        if (zpl_frustum_point_inside(frustum, v)) return 1;
+
+        b = zpl_vec3f(+box.x, -box.y, -box.z);
+        zpl_vec3_add(&v, b, aabb.centre);
+
+        if (zpl_frustum_point_inside(frustum, v)) return 1;
+
+        b = zpl_vec3f(-box.x, +box.y, -box.z);
+        zpl_vec3_add(&v, b, aabb.centre);
+
+        if (zpl_frustum_point_inside(frustum, v)) return 1;
+
+        b = zpl_vec3f(+box.x, +box.y, -box.z);
+        zpl_vec3_add(&v, b, aabb.centre);
+
+        if (zpl_frustum_point_inside(frustum, v)) return 1;
+
+        b = zpl_vec3f(+box.x, +box.y, +box.z);
+        zpl_vec3_add(&v, b, aabb.centre);
+
+        if (zpl_frustum_point_inside(frustum, v)) return 1;
+
+        b = zpl_vec3f(-box.x, +box.y, +box.z);
+        zpl_vec3_add(&v, b, aabb.centre);
+
+        if (zpl_frustum_point_inside(frustum, v)) return 1;
+
+        b = zpl_vec3f(-box.x, -box.y, +box.z);
+        zpl_vec3_add(&v, b, aabb.centre);
+
+        if (zpl_frustum_point_inside(frustum, v)) return 1;
+
+        b = zpl_vec3f(+box.x, -box.y, +box.z);
+        zpl_vec3_add(&v, b, aabb.centre);
+
+        if (zpl_frustum_point_inside(frustum, v)) return 1;
+
+        return 0;
+    }
+
+    zpl_f32 zpl_lerp(zpl_f32 a, zpl_f32 b, zpl_f32 t) { return a * (1.0f - t) + b * t; }
+    zpl_f32 zpl_unlerp(zpl_f32 t, zpl_f32 a, zpl_f32 b) { return (t - a) / (b - a); }
+    zpl_f32 zpl_smooth_step(zpl_f32 a, zpl_f32 b, zpl_f32 t) {
+        zpl_f32 x = (t - a) / (b - a);
+        return x * x * (3.0f - 2.0f * x);
+    }
+    zpl_f32 zpl_smoother_step(zpl_f32 a, zpl_f32 b, zpl_f32 t) {
+        zpl_f32 x = (t - a) / (b - a);
+        return x * x * x * (x * (6.0f * x - 15.0f) + 10.0f);
+    }
+
+    #define ZPL_VEC_LERPN(N, d, a, b, t)     \
+        zpl_vec##N db;                       \
+        zpl_vec##N##_sub(&db, b, a);         \
+        zpl_vec##N##_muleq(&db, t);          \
+        zpl_vec##N##_add(d, a, db)
+
+    void zpl_vec2_lerp(zpl_vec2 *d, zpl_vec2 a, zpl_vec2 b, zpl_f32 t) { ZPL_VEC_LERPN(2, d, a, b, t); }
+    void zpl_vec3_lerp(zpl_vec3 *d, zpl_vec3 a, zpl_vec3 b, zpl_f32 t) { ZPL_VEC_LERPN(3, d, a, b, t); }
+    void zpl_vec4_lerp(zpl_vec4 *d, zpl_vec4 a, zpl_vec4 b, zpl_f32 t) { ZPL_VEC_LERPN(4, d, a, b, t); }
+
+    #undef ZPL_VEC_LERPN
+
+    void zpl_vec2_cslerp(zpl_vec2 *d, zpl_vec2 a, zpl_vec2 v0, zpl_vec2 b, zpl_vec2 v1, zpl_f32 t) {
+        zpl_f32 t2 = t * t;
+        zpl_f32 ti = (t - 1);
+        zpl_f32 ti2 = ti * ti;
+
+        zpl_f32 h00 = (1 + 2 * t) * ti2;
+        zpl_f32 h10 = t * ti2;
+        zpl_f32 h01 = t2 * (3 - 2 * t);
+        zpl_f32 h11 = t2 * ti;
+
+        d->x = h00 * a.x + h10 * v0.x + h01 * b.x + h11 * v1.x;
+        d->y = h00 * a.y + h10 * v0.y + h01 * b.y + h11 * v1.y;
+    }
+
+    void zpl_vec3_cslerp(zpl_vec3 *d, zpl_vec3 a, zpl_vec3 v0, zpl_vec3 b, zpl_vec3 v1, zpl_f32 t) {
+        zpl_f32 t2 = t * t;
+        zpl_f32 ti = (t - 1);
+        zpl_f32 ti2 = ti * ti;
+
+        zpl_f32 h00 = (1 + 2 * t) * ti2;
+        zpl_f32 h10 = t * ti2;
+        zpl_f32 h01 = t2 * (3 - 2 * t);
+        zpl_f32 h11 = t2 * ti;
+
+        d->x = h00 * a.x + h10 * v0.x + h01 * b.x + h11 * v1.x;
+        d->y = h00 * a.y + h10 * v0.y + h01 * b.y + h11 * v1.y;
+        d->z = h00 * a.z + h10 * v0.z + h01 * b.z + h11 * v1.z;
+    }
+
+    void zpl_vec2_dcslerp(zpl_vec2 *d, zpl_vec2 a, zpl_vec2 v0, zpl_vec2 b, zpl_vec2 v1, zpl_f32 t) {
+        zpl_f32 t2 = t * t;
+
+        zpl_f32 dh00 = 6 * t2 - 6 * t;
+        zpl_f32 dh10 = 3 * t2 - 4 * t + 1;
+        zpl_f32 dh01 = -6 * t2 + 6 * t;
+        zpl_f32 dh11 = 3 * t2 - 2 * t;
+
+        d->x = dh00 * a.x + dh10 * v0.x + dh01 * b.x + dh11 * v1.x;
+        d->y = dh00 * a.y + dh10 * v0.y + dh01 * b.y + dh11 * v1.y;
+    }
+
+    void zpl_vec3_dcslerp(zpl_vec3 *d, zpl_vec3 a, zpl_vec3 v0, zpl_vec3 b, zpl_vec3 v1, zpl_f32 t) {
+        zpl_f32 t2 = t * t;
+
+        zpl_f32 dh00 = 6 * t2 - 6 * t;
+        zpl_f32 dh10 = 3 * t2 - 4 * t + 1;
+        zpl_f32 dh01 = -6 * t2 + 6 * t;
+        zpl_f32 dh11 = 3 * t2 - 2 * t;
+
+        d->x = dh00 * a.x + dh10 * v0.x + dh01 * b.x + dh11 * v1.x;
+        d->y = dh00 * a.y + dh10 * v0.y + dh01 * b.y + dh11 * v1.y;
+        d->z = dh00 * a.z + dh10 * v0.z + dh01 * b.z + dh11 * v1.z;
+    }
+
+    void zpl_quat_lerp(zpl_quat *d, zpl_quat a, zpl_quat b, zpl_f32 t) { zpl_vec4_lerp(&d->xyzw, a.xyzw, b.xyzw, t); }
+    void zpl_quat_nlerp(zpl_quat *d, zpl_quat a, zpl_quat b, zpl_f32 t) {
+        zpl_quat_lerp(d, a, b, t);
+        zpl_quat_norm(d, *d);
+    }
+
+    void zpl_quat_slerp(zpl_quat *d, zpl_quat a, zpl_quat b, zpl_f32 t) {
+        zpl_quat x, y, z;
+        zpl_f32 cos_theta, angle;
+        zpl_f32 s1, s0, is;
+
+        z = b;
+        cos_theta = zpl_quat_dot(a, b);
+
+        if (cos_theta < 0.0f) {
+            z = zpl_quatf(-b.x, -b.y, -b.z, -b.w);
+            cos_theta = -cos_theta;
+        }
+
+        if (cos_theta > 1.0f) {
+            /* NOTE: Use lerp not nlerp as it's not a real angle or they are not normalized */
+            zpl_quat_lerp(d, a, b, t);
+        }
+
+        angle = zpl_arccos(cos_theta);
+
+        s1 = zpl_sin((1.0f - t) * angle);
+        s0 = zpl_sin(t * angle);
+        is = 1.0f / zpl_sin(angle);
+        zpl_quat_mulf(&x, a, s1);
+        zpl_quat_mulf(&y, z, s0);
+        zpl_quat_add(d, x, y);
+        zpl_quat_muleqf(d, is);
+    }
+
+    void zpl_quat_slerp_approx(zpl_quat *d, zpl_quat a, zpl_quat b, zpl_f32 t) {
+        /* NOTE: Derived by taylor expanding the geometric interpolation equation
+         *             Even works okay for nearly anti-parallel versors!!!
+         */
+        /* NOTE: Extra interations cannot be used as they require angle^4 which is not worth it to approximate */
+        zpl_f32 tp = t + (1.0f - zpl_quat_dot(a, b)) / 3.0f * t * (-2.0f * t * t + 3.0f * t - 1.0f);
+        zpl_quat_nlerp(d, a, b, tp);
+    }
+
+    void zpl_quat_nquad(zpl_quat *d, zpl_quat p, zpl_quat a, zpl_quat b, zpl_quat q, zpl_f32 t) {
+        zpl_quat x, y;
+        zpl_quat_nlerp(&x, p, q, t);
+        zpl_quat_nlerp(&y, a, b, t);
+        zpl_quat_nlerp(d, x, y, 2.0f * t * (1.0f - t));
+    }
+
+    void zpl_quat_squad(zpl_quat *d, zpl_quat p, zpl_quat a, zpl_quat b, zpl_quat q, zpl_f32 t) {
+        zpl_quat x, y;
+        zpl_quat_slerp(&x, p, q, t);
+        zpl_quat_slerp(&y, a, b, t);
+        zpl_quat_slerp(d, x, y, 2.0f * t * (1.0f - t));
+    }
+
+    void zpl_quat_squad_approx(zpl_quat *d, zpl_quat p, zpl_quat a, zpl_quat b, zpl_quat q, zpl_f32 t) {
+        zpl_quat x, y;
+        zpl_quat_slerp_approx(&x, p, q, t);
+        zpl_quat_slerp_approx(&y, a, b, t);
+        zpl_quat_slerp_approx(d, x, y, 2.0f * t * (1.0f - t));
+    }
+
+    zpl_rect2 zpl_rect2f(zpl_vec2 pos, zpl_vec2 dim) {
+        zpl_rect2 r;
+        r.pos = pos;
+        r.dim = dim;
+        return r;
+    }
+
+    zpl_rect3 zpl_rect3f(zpl_vec3 pos, zpl_vec3 dim) {
+        zpl_rect3 r;
+        r.pos = pos;
+        r.dim = dim;
+        return r;
+    }
+
+    int zpl_rect2_contains(zpl_rect2 a, zpl_f32 x, zpl_f32 y) {
+        zpl_f32 min_x = zpl_min(a.pos.x, a.pos.x + a.dim.x);
+        zpl_f32 max_x = zpl_max(a.pos.x, a.pos.x + a.dim.x);
+        zpl_f32 min_y = zpl_min(a.pos.y, a.pos.y + a.dim.y);
+        zpl_f32 max_y = zpl_max(a.pos.y, a.pos.y + a.dim.y);
+        int result    =        (x >= min_x) & (x < max_x) & (y >= min_y) & (y < max_y);
+        return result;
+    }
+
+    int zpl_rect2_contains_vec2(zpl_rect2 a, zpl_vec2 p) { return zpl_rect2_contains(a, p.x, p.y); }
+
+    int zpl_rect2_intersects(zpl_rect2 a, zpl_rect2 b) {
+        zpl_rect2 r = { 0 };
+        return zpl_rect2_intersection_result(a, b, &r);
+    }
+
+    int zpl_rect2_intersection_result(zpl_rect2 a, zpl_rect2 b, zpl_rect2 *intersection) {
+        zpl_f32 a_min_x = zpl_min(a.pos.x, a.pos.x + a.dim.x);
+        zpl_f32 a_max_x = zpl_max(a.pos.x, a.pos.x + a.dim.x);
+        zpl_f32 a_min_y = zpl_min(a.pos.y, a.pos.y + a.dim.y);
+        zpl_f32 a_max_y = zpl_max(a.pos.y, a.pos.y + a.dim.y);
+
+        zpl_f32 b_min_x = zpl_min(b.pos.x, b.pos.x + b.dim.x);
+        zpl_f32 b_max_x = zpl_max(b.pos.x, b.pos.x + b.dim.x);
+        zpl_f32 b_min_y = zpl_min(b.pos.y, b.pos.y + b.dim.y);
+        zpl_f32 b_max_y = zpl_max(b.pos.y, b.pos.y + b.dim.y);
+
+        zpl_f32 x0 = zpl_max(a_min_x, b_min_x);
+        zpl_f32 y0 = zpl_max(a_min_y, b_min_y);
+        zpl_f32 x1 = zpl_min(a_max_x, b_max_x);
+        zpl_f32 y1 = zpl_min(a_max_y, b_max_y);
+
+        if ((x0 < x1) && (y0 < y1)) {
+            zpl_rect2 r = zpl_rect2f(zpl_vec2f(x0, y0), zpl_vec2f(x1 - x0, y1 - y0));
+            *intersection = r;
+            return 1;
+        } else {
+            zpl_rect2 r = { 0 };
+            *intersection = r;
+            return 0;
+        }
+    }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_JSON)
+    // file: source/json.c
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // JSON5 Parser
+    //
+    //
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    #include <math.h> /* needed for INFINITY and NAN */
+
+    ZPL_BEGIN_C_DECLS
+
+    static ZPL_ALWAYS_INLINE zpl_b32 zpl__json_is_special_char(char c) { return !!zpl_strchr("<>:/", c); }
+    static ZPL_ALWAYS_INLINE zpl_b32 zpl__json_is_assign_char(char c) { return !!zpl_strchr(":=|", c); }
+    static ZPL_ALWAYS_INLINE zpl_b32 zpl__json_is_delim_char(char c) { return !!zpl_strchr(",|\n", c); }
+
+    char *zpl__json_parse_object(zpl_json_object *obj, char *base, zpl_allocator a, zpl_u8 *err_code);
+    char *zpl__json_parse_array(zpl_json_object *obj, char *base, zpl_allocator a, zpl_u8 *err_code);
+    char *zpl__json_parse_value(zpl_json_object *obj, char *base, zpl_allocator a, zpl_u8 *err_code);
+
+    #define jx(x) !zpl_char_is_hex_digit(str[x])
+    ZPL_ALWAYS_INLINE zpl_b32 zpl__json_validate_name(char *str, char *err) {
+        while (*str) {
+            if ((str[0] == '\\' && !zpl_char_is_control(str[1])) &&
+                (str[0] == '\\' && jx(1) && jx(2) && jx(3) && jx(4))) {
+                *err = *str;
+                return false;
+            }
+
+            ++str;
+        }
+
+        return true;
+    }
+    #undef jx
+
+
+    void zpl_json_parse(zpl_json_object *root, zpl_usize len, char *source, zpl_allocator a, zpl_b32 handle_comments,
+                        zpl_u8 *err_code) {
+
+        if (!root || !source)
+        {
+            ZPL_JSON_ASSERT;
+            if (err_code) *err_code = ZPL_JSON_ERROR_OBJECT_OR_SOURCE_WAS_NULL;
+            return;
+        }
+
+        zpl_unused(len);
+
+        char *dest = (char *)source;
+
+        if (handle_comments) {
+            zpl_b32 is_lit = false;
+            char lit_c = '\0';
+            char *p = dest;
+            char *b = dest;
+            zpl_isize l = 0;
+
+            while (*p) {
+                if (!is_lit) {
+                    if ((*p == '"' || *p == '\'')) {
+                        lit_c = *p;
+                        is_lit = true;
+                        ++p;
+                        continue;
+                    }
+                } else {
+                    if (*p == '\\' && *(p + 1) && *(p + 1) == lit_c) {
+                        p += 2;
+                        continue;
+                    } else if (*p == lit_c) {
+                        is_lit = false;
+                        ++p;
+                        continue;
+                    }
+                }
+
+                if (!is_lit) {
+                    // NOTE(ZaKlaus): block comment
+                    if (p[0] == '/' && p[1] == '*') {
+                        b = p;
+                        l = 2;
+                        p += 2;
+
+                        while (p[0] != '*' && p[1] != '/') {
+                            ++p;
+                            ++l;
+                        }
+                        p += 2;
+                        l += 2;
+                        zpl_memset(b, ' ', l);
+                    }
+
+                    // NOTE(ZaKlaus): inline comment
+                    if (p[0] == '/' && p[1] == '/') {
+                        b = p;
+                        l = 2;
+                        p += 2;
+
+                        while (p[0] != '\n') {
+                            ++p;
+                            ++l;
+                        }
+                        ++l;
+                        zpl_memset(b, ' ', l);
+                    }
+                }
+
+                ++p;
+            }
+        }
+
+        if (err_code) *err_code = ZPL_JSON_ERROR_NONE;
+        zpl_json_object root_ = { 0 };
+
+        dest = zpl_str_trim(dest, false);
+
+        zpl_b32 starts_with_bracket = false;
+
+        if (*dest != '{' && *dest != '[') { root_.cfg_mode = true; }
+        if (*dest == '[') { starts_with_bracket = true; }
+
+        char *endp = NULL;
+
+        if (!starts_with_bracket)
+            endp = zpl__json_parse_object(&root_, dest, a, err_code);
+        else
+            endp = zpl__json_parse_array(&root_, (dest+1), a, err_code);
+
+        if (!root_.cfg_mode && endp == NULL) {
+            if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_VALUE;
+        }
+
+        // Replace root node with its child if the JSON document is an array.
+        if (starts_with_bracket && root_.type != ZPL_JSON_TYPE_ARRAY) {
+            zpl_json_object *replace = &root_;
+            *replace = root_.nodes[0];
+        }
+
+        *root = root_;
+    }
+
+    #define zpl___ind(x)                                                                                                   \
+    for (int i = 0; i < x; ++i) zpl_fprintf(f, " ");
+
+    void zpl__json_write_value(zpl_file *f, zpl_json_object *o, zpl_json_object *t, zpl_isize indent, zpl_b32 is_inline, zpl_b32 is_last);
+
+    void zpl_json_write(zpl_file *f, zpl_json_object *o, zpl_isize indent) {
+        if (!o)
+            return;
+
+        zpl___ind(indent - 4);
+        if (!o->cfg_mode)
+            zpl_fprintf(f, "{\n");
+        else {
+            indent -= 4;
+        }
+
+        if (o->nodes)
+        {
+            zpl_isize cnt = zpl_array_count(o->nodes);
+
+            for (int i = 0; i < cnt; ++i) {
+                if (i < cnt - 1) {
+                    zpl__json_write_value(f, o->nodes + i, o, indent, false, false);
+                } else {
+                    zpl__json_write_value(f, o->nodes + i, o, indent, false, true);
+                }
+            }
+        }
+
+        zpl___ind(indent);
+
+        if (indent > 0) {
+            zpl_fprintf(f, "}");
+        } else {
+            if (!o->cfg_mode) zpl_fprintf(f, "}\n");
+        }
+    }
+
+    zpl_string zpl_json_write_string(zpl_allocator a, zpl_json_object *obj, zpl_isize indent) {
+        zpl_file tmp;
+        zpl_file_stream_new(&tmp, a);
+        zpl_json_write(&tmp, obj, indent);
+        zpl_file_seek(&tmp, 0);
+        zpl_i64 fsize = zpl_file_size(&tmp)-1;
+        zpl_string output = zpl_string_make_reserve(a, fsize+1);
+        zpl_file_read(&tmp, output, fsize);
+        zpl_file_close(&tmp);
+        return output;
+    }
+
+    void zpl__json_write_value(zpl_file *f, zpl_json_object *o, zpl_json_object *t, zpl_isize indent, zpl_b32 is_inline, zpl_b32 is_last) {
+        zpl_json_object *node = o;
+        indent += 4;
+
+        if (!is_inline) {
+            zpl___ind(indent);
+            switch (node->name_style) {
+                case ZPL_JSON_NAME_STYLE_DOUBLE_QUOTE: {
+                    zpl_fprintf(f, "\"%s\"", node->name);
+                } break;
+
+                case ZPL_JSON_NAME_STYLE_SINGLE_QUOTE: {
+                    zpl_fprintf(f, "\'%s\'", node->name);
+                } break;
+
+                case ZPL_JSON_NAME_STYLE_NO_QUOTES: {
+                    zpl_fprintf(f, "%s", node->name);
+                } break;
+            }
+
+            if (o->assign_style == ZPL_JSON_ASSIGN_STYLE_COLON)
+                zpl_fprintf(f, ": ");
+            else {
+                if (o->name_style != ZPL_JSON_NAME_STYLE_NO_QUOTES)
+                    zpl___ind(1);
+
+                if (o->assign_style == ZPL_JSON_ASSIGN_STYLE_EQUALS)
+                    zpl_fprintf(f, "= ");
+                else if (o->assign_style == ZPL_JSON_ASSIGN_STYLE_LINE)
+                    zpl_fprintf(f, "| ");
+            }
+
+        }
+
+        switch (node->type) {
+            case ZPL_JSON_TYPE_STRING: {
+                zpl_fprintf(f, "\"%s\"", node->string);
+            } break;
+
+            case ZPL_JSON_TYPE_MULTISTRING: {
+                zpl_fprintf(f, "`%s`", node->string);
+            } break;
+
+            case ZPL_JSON_TYPE_ARRAY: {
+                zpl_fprintf(f, "[");
+                zpl_isize elemn = zpl_array_count(node->nodes);
+                for (int j = 0; j < elemn; ++j) {
+                    if ((node->nodes + j)->type == ZPL_JSON_TYPE_OBJECT || (node->nodes + j)->type == ZPL_JSON_TYPE_ARRAY) {
+                        zpl__json_write_value(f, node->nodes + j, o, 0, true, true);
+                    } else {
+                        zpl__json_write_value(f, node->nodes + j, o, -4, true, true);
+                    }
+
+                    if (j < elemn - 1) { zpl_fprintf(f, ", "); }
+                }
+                zpl_fprintf(f, "]");
+            } break;
+
+            case ZPL_JSON_TYPE_INTEGER: {
+                if (node->props == ZPL_JSON_PROPS_IS_HEX) {
+                    zpl_fprintf(f, "0x%llx", (long long)node->integer);
+                } else {
+                    zpl_fprintf(f, "%lld", (long long)node->integer);
+                }
+            } break;
+
+            case ZPL_JSON_TYPE_REAL: {
+                if (node->props == ZPL_JSON_PROPS_NAN) {
+                    zpl_fprintf(f, "NaN");
+                } else if (node->props == ZPL_JSON_PROPS_NAN_NEG) {
+                    zpl_fprintf(f, "-NaN");
+                } else if (node->props == ZPL_JSON_PROPS_INFINITY) {
+                    zpl_fprintf(f, "Infinity");
+                } else if (node->props == ZPL_JSON_PROPS_INFINITY_NEG) {
+                    zpl_fprintf(f, "-Infinity");
+                } else if (node->props == ZPL_JSON_PROPS_IS_EXP) {
+                    zpl_fprintf(f, "%lld.%0*d%llde%c%lld", (long long)node->base, node->base2_offset, 0, (long long)node->base2, node->exp_neg ? '-' : '+',
+                                (long long)node->exp);
+                } else if (node->props == ZPL_JSON_PROPS_IS_PARSED_REAL) {
+                    if (!node->lead_digit)
+                        zpl_fprintf(f, ".%0*d%lld", node->base2_offset, 0, (long long)node->base2);
+                    else
+                        zpl_fprintf(f, "%lld.%0*d%lld", (long long int)node->base2_offset, 0, (int)node->base, (long long)node->base2);
+                } else {
+                    zpl_fprintf(f, "%f", node->real);
+                }
+            } break;
+
+            case ZPL_JSON_TYPE_OBJECT: {
+                zpl_json_write(f, node, indent);
+            } break;
+
+            case ZPL_JSON_TYPE_CONSTANT: {
+                if (node->constant == ZPL_JSON_CONST_TRUE) {
+                    zpl_fprintf(f, "true");
+                } else if (node->constant == ZPL_JSON_CONST_FALSE) {
+                    zpl_fprintf(f, "false");
+                } else if (node->constant == ZPL_JSON_CONST_NULL) {
+                    zpl_fprintf(f, "null");
+                }
+            } break;
+        }
+
+        if (!is_inline) {
+
+            if (o->delim_style != ZPL_JSON_DELIM_STYLE_COMMA)
+            {
+                if (o->delim_style == ZPL_JSON_DELIM_STYLE_NEWLINE)
+                    zpl_fprintf(f, "\n");
+                else if (o->delim_style == ZPL_JSON_DELIM_STYLE_LINE)
+                {
+                    zpl___ind(o->delim_line_width);
+                    zpl_fprintf(f, "|\n");
+                }
+            }
+            else
+            {
+                if (!is_last) {
+                    zpl_fprintf(f, ",\n");
+                } else {
+                    zpl_fprintf(f, "\n");
+                }
+            }
+        }
+    }
+    #undef zpl___ind
+
+    void zpl_json_free(zpl_json_object *obj) {
+        if ((obj->type == ZPL_JSON_TYPE_OBJECT || obj->type == ZPL_JSON_TYPE_ARRAY) && obj->nodes) {
+            for (zpl_isize i = 0; i < zpl_array_count(obj->nodes); ++i) { zpl_json_free(obj->nodes + i); }
+
+            zpl_array_free(obj->nodes);
+        }
+    }
+
+    char *zpl__json_parse_array(zpl_json_object *obj, char *base, zpl_allocator a, zpl_u8 *err_code) {
+        ZPL_ASSERT(obj && base);
+        char *p = base;
+
+        obj->type = ZPL_JSON_TYPE_ARRAY;
+        zpl_array_init(obj->nodes, a);
+        obj->backing = a;
+
+        while (*p) {
+            p = zpl_str_trim(p, false);
+
+            if (p && *p == ']') {
+                return p;
+            }
+
+            zpl_json_object elem = { 0 };
+            elem.backing = a;
+            p = zpl__json_parse_value(&elem, p, a, err_code);
+
+            if (err_code && *err_code != ZPL_JSON_ERROR_NONE) { return NULL; }
+
+            zpl_array_append(obj->nodes, elem);
+
+            p = zpl_str_trim(p, false);
+
+            if (*p == ',') {
+                ++p;
+                continue;
+            } else {
+                if (*p != ']') {
+                    if (err_code) { *err_code = ZPL_JSON_ERROR_INVALID_VALUE; }
+                }
+                return p;
+            }
+        }
+
+        if (err_code) { *err_code = ZPL_JSON_ERROR_INVALID_VALUE; }
+        return p;
+    }
+
+    char *zpl__json_parse_value(zpl_json_object *obj, char *base, zpl_allocator a, zpl_u8 *err_code) {
+        ZPL_ASSERT(obj && base);
+        char *p = base;
+        char *b = base;
+        char *e = base;
+
+        if (*p == '"' || *p == '\'') {
+            char c = *p;
+            obj->type = ZPL_JSON_TYPE_STRING;
+            b = p + 1;
+            e = b;
+            obj->string = b;
+
+            while (*e) {
+                if (*e == '\\' && *(e + 1) == c) {
+                    e += 2;
+                    continue;
+                } else if (*e == '\\' && (*(e + 1) == '\r' || *(e + 1) == '\n')) {
+                    *e = ' ';
+                    e++;
+                    continue;
+                } else if (*e == c) {
+                    break;
+                }
+                ++e;
+            }
+
+            *e = '\0';
+            p = e + 1;
+        } else if (*p == '`') {
+            obj->type = ZPL_JSON_TYPE_MULTISTRING;
+            b = p + 1;
+            e = b;
+            obj->string = b;
+
+            while (*e) {
+                if (*e == '\\' && *(e + 1) == '`') {
+                    e += 2;
+                    continue;
+                } else if (*e == '`') {
+                    break;
+                }
+                ++e;
+            }
+
+            *e = '\0';
+            p = e + 1;
+        } else if (zpl_char_is_alpha(*p) || (*p == '-' && !zpl_char_is_digit(*(p + 1)))) {
+            obj->type = ZPL_JSON_TYPE_CONSTANT;
+
+            if (!zpl_strncmp(p, "true", 4)) {
+                obj->constant = ZPL_JSON_CONST_TRUE;
+                p += 4;
+            } else if (!zpl_strncmp(p, "false", 5)) {
+                obj->constant = ZPL_JSON_CONST_FALSE;
+                p += 5;
+            } else if (!zpl_strncmp(p, "null", 4)) {
+                obj->constant = ZPL_JSON_CONST_NULL;
+                p += 4;
+            } else if (!zpl_strncmp(p, "Infinity", 8)) {
+                obj->type = ZPL_JSON_TYPE_REAL;
+                obj->real = INFINITY;
+                obj->props = ZPL_JSON_PROPS_INFINITY;
+                p += 8;
+            } else if (!zpl_strncmp(p, "-Infinity", 9)) {
+                obj->type = ZPL_JSON_TYPE_REAL;
+                obj->real = -INFINITY;
+                obj->props = ZPL_JSON_PROPS_INFINITY_NEG;
+                p += 9;
+            } else if (!zpl_strncmp(p, "NaN", 3)) {
+                obj->type = ZPL_JSON_TYPE_REAL;
+                obj->real = NAN;
+                obj->props = ZPL_JSON_PROPS_NAN;
+                p += 3;
+            } else if (!zpl_strncmp(p, "-NaN", 4)) {
+                obj->type = ZPL_JSON_TYPE_REAL;
+                obj->real = -NAN;
+                obj->props = ZPL_JSON_PROPS_NAN_NEG;
+                p += 4;
+            } else {
+                ZPL_JSON_ASSERT;
+                if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_VALUE;
+                return NULL;
+            }
+        } else if (zpl_char_is_digit(*p) || *p == '+' || *p == '-' || *p == '.') {
+            obj->type = ZPL_JSON_TYPE_INTEGER;
+
+            b = p;
+            e = b;
+
+            zpl_isize ib = 0;
+            char buf[48] = { 0 };
+
+            if (*e == '+')
+                ++e;
+            else if (*e == '-') {
+                buf[ib++] = *e++;
+            }
+
+            if (*e == '.') {
+                obj->type = ZPL_JSON_TYPE_REAL;
+                obj->props = ZPL_JSON_PROPS_IS_PARSED_REAL;
+                buf[ib++] = '0';
+                obj->lead_digit = false;
+
+                do {
+                    buf[ib++] = *e;
+                } while (zpl_char_is_digit(*++e));
+            } else {
+                if (*e == '0' && (*(e + 1) == 'x' || *(e + 1) == 'X')) { obj->props = ZPL_JSON_PROPS_IS_HEX; }
+                while (zpl_char_is_hex_digit(*e) || *e == 'x' || *e == 'X') { buf[ib++] = *e++; }
+
+                if (*e == '.') {
+                    obj->type = ZPL_JSON_TYPE_REAL;
+                    obj->lead_digit = true;
+                    zpl_u32 step = 0;
+
+                    do {
+                        buf[ib++] = *e;
+                        ++step;
+                    } while (zpl_char_is_digit(*++e));
+
+                    if (step < 2) { buf[ib++] = '0'; }
+                }
+            }
+
+            zpl_i32 exp = 0;
+            zpl_f32 eb = 10;
+            char expbuf[6] = { 0 };
+            zpl_isize expi = 0;
+
+            if (*e == 'e' || *e == 'E') {
+                ++e;
+                if (*e == '+' || *e == '-' || zpl_char_is_digit(*e)) {
+                    if (*e == '-') { eb = 0.1f; }
+
+                    if (!zpl_char_is_digit(*e)) { ++e; }
+
+                    while (zpl_char_is_digit(*e)) { expbuf[expi++] = *e++; }
+                }
+
+                exp = (zpl_i32)zpl_str_to_i64(expbuf, NULL, 10);
+            }
+
+            if (obj->type == ZPL_JSON_TYPE_INTEGER) {
+                obj->integer = zpl_str_to_i64(buf, 0, 0);
+
+                while (exp-- > 0) { obj->integer *= (zpl_i64)eb; }
+            } else {
+                obj->real = zpl_str_to_f64(buf, 0);
+
+                char *q = buf, *qp = q, *qp2 = q;
+                while (*qp != '.') ++qp;
+                *qp = '\0';
+                qp2 = qp + 1;
+                char *qpOff = qp2;
+                while (*qpOff++ == '0') obj->base2_offset++;
+
+                obj->base = (zpl_i32)zpl_str_to_i64(q, 0, 0);
+                obj->base2 = (zpl_i32)zpl_str_to_i64(qp2, 0, 0);
+
+                if (exp) {
+                    obj->exp = exp;
+                    obj->exp_neg = !(eb == 10.f);
+                    obj->props = ZPL_JSON_PROPS_IS_EXP;
+                }
+
+                while (exp-- > 0) { obj->real *= eb; }
+            }
+            p = e;
+        } else if (*p == '[') {
+            p = zpl_str_trim(p + 1, false);
+            obj->type = ZPL_JSON_TYPE_ARRAY;
+            if (*p == ']') return (p+1);
+            p = zpl__json_parse_array(obj, p, a, err_code);
+            if (err_code && *err_code != ZPL_JSON_ERROR_NONE) { return NULL; }
+
+            ++p;
+        } else if (*p == '{') {
+            p = zpl_str_trim(p + 1, false);
+            obj->type = ZPL_JSON_TYPE_OBJECT;
+            if (*p == '}') return (p+1);
+            p = zpl__json_parse_object(obj, p, a, err_code);
+
+            if (err_code && *err_code != ZPL_JSON_ERROR_NONE) { return NULL; }
+
+            ++p;
+        }
+
+        return p;
+    }
+
+    char *zpl__json_parse_object(zpl_json_object *obj, char *base, zpl_allocator a, zpl_u8 *err_code) {
+        ZPL_ASSERT(obj && base);
+        char *p = base;
+        char *b = base;
+        char *e = base;
+
+        zpl_array_init(obj->nodes, a);
+        obj->backing = a;
+
+        p = zpl_str_trim(p, false);
+        zpl_b32 starts_with_brace = false;
+        zpl_b32 starts_with_bracket = false;
+        /**/ if (*p == '{') { ++p; starts_with_brace = true; obj->type = ZPL_JSON_TYPE_OBJECT; }
+        else if (*p == '[') { ++p; starts_with_bracket = true; obj->type = ZPL_JSON_TYPE_ARRAY; }
+
+        while (*p) {
+            zpl_json_object node = { 0 };
+            p = zpl_str_trim(p, false);
+            if (*p == '}' && starts_with_brace) return p;
+            if (*p == ']' && starts_with_bracket) return p;
+
+            if (*p == ']' && starts_with_brace)     { if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_VALUE; return p; }
+            if (*p == '}' && starts_with_bracket)   { if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_VALUE; return p; }
+
+            if (*p == '"' || *p == '\'') {
+                if (*p == '"') {
+                    node.name_style = ZPL_JSON_NAME_STYLE_DOUBLE_QUOTE;
+                } else {
+                    node.name_style = ZPL_JSON_NAME_STYLE_SINGLE_QUOTE;
+                }
+
+                char c = *p;
+                b = ++p;
+                e = zpl_str_control_skip(b, c);
+                node.name = b;
+                *e = '\0';
+                p = ++e;
+                p = zpl_str_trim(p, false);
+                if (!zpl__json_is_assign_char(*p)) {
+                    ZPL_JSON_ASSERT;
+                    if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_NAME;
+                    return NULL;
+                }
+            }
+            else {
+                if (*p == '[') {
+                    starts_with_bracket = true;
+                    if (node.name) *node.name = '\0';
+                    p = zpl__json_parse_value(&node, p, a, err_code);
+                    goto l_parsed;
+                }
+                else if (zpl_char_is_alpha(*p) || *p == '_' || *p == '$') {
+                    b = p;
+                    e = b;
+
+                    do {
+                        ++e;
+                    } while (*e && (zpl_char_is_alphanumeric(*e) || *e == '_') && !zpl_char_is_space(*e) && !zpl__json_is_assign_char(*e));
+
+                    if (zpl_char_is_space(*e)) {
+                        // NOTE(zaklaus): We know this is where the node name ends, cut it here
+                        *e = '\0';
+                        ++e;
+                    }
+
+                    if (zpl__json_is_assign_char(*e)) {
+                        p = e;
+
+                        if (*e == '=')
+                            node.assign_style = ZPL_JSON_ASSIGN_STYLE_EQUALS;
+                        else if (*e == '|')
+                            node.assign_style = ZPL_JSON_ASSIGN_STYLE_LINE;
+                    }
+                    else {
+                        while (*e) {
+                            if (*e && (!zpl_char_is_space(*e) || zpl__json_is_assign_char(*e)))
+                            {
+                                if (*e == '=')
+                                    node.assign_style = ZPL_JSON_ASSIGN_STYLE_EQUALS;
+                                else if (*e == '|')
+                                    node.assign_style = ZPL_JSON_ASSIGN_STYLE_LINE;
+
+                                break;
+                            }
+                            ++e;
+                        }
+
+                        e = zpl_str_trim(e, false);
+                        p = e;
+
+                        if (*p && !zpl__json_is_assign_char(*p)) {
+                            ZPL_JSON_ASSERT;
+                            if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_NAME;
+                            return NULL;
+                        }
+                        else
+                        {
+                            if (*p == '=')
+                                node.assign_style = ZPL_JSON_ASSIGN_STYLE_EQUALS;
+                            else if (*p == '|')
+                                node.assign_style = ZPL_JSON_ASSIGN_STYLE_LINE;
+                        }
+                    }
+
+                    *e = '\0';
+                    node.name = b;
+                    node.name_style = ZPL_JSON_NAME_STYLE_NO_QUOTES;
+                }
+            }
+
+            char errc;
+            if (node.name && !zpl__json_validate_name(node.name, &errc)) {
+                ZPL_JSON_ASSERT;
+                if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_NAME;
+                return NULL;
+            }
+
+            p = zpl_str_trim(p + 1, false);
+            p = zpl__json_parse_value(&node, p, a, err_code);
+            node.backing = obj->backing;
+
+            if (err_code && *err_code != ZPL_JSON_ERROR_NONE) { return NULL; }
+
+            l_parsed:
+
+            if (err_code && *err_code != ZPL_JSON_ERROR_NONE) { return NULL; }
+
+            zpl_array_append(obj->nodes, node);
+
+            char *wp = p;
+            p = zpl_str_trim(p, true);
+            zpl_u8 wl = cast(zpl_u8)(p-wp);
+
+            if (zpl__json_is_delim_char(*p) || *p == '\0') {
+                zpl_json_object *n = zpl_array_end(obj->nodes);
+
+                if (*p == '\n')
+                    n->delim_style = ZPL_JSON_DELIM_STYLE_NEWLINE;
+                else if (*p == '|') {
+                    n->delim_style = ZPL_JSON_DELIM_STYLE_LINE;
+                    n->delim_line_width = wl;
+                }
+                else if (*p == '\0') {
+                    return p;
+                }
+
+                p = zpl_str_trim(p + 1, false);
+                if (*p == '\0' || *p == '}' || *p == ']')
+                    return p;
+                else
+                    continue;
+            } else if (*p == '\0' || *p == '}' || *p == ']') {
+                if (starts_with_brace && *p != '}')
+                {
+                    if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_VALUE;
+                    return NULL;
+                }
+
+                if (starts_with_bracket && *p != ']')
+                {
+                    if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_VALUE;
+                    return NULL;
+                }
+
+                return p;
+            } else {
+                ZPL_JSON_ASSERT;
+                if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_VALUE;
+                return NULL;
+            }
+        }
+        if (err_code) *err_code = ZPL_JSON_ERROR_INVALID_VALUE;
+        return p;
+    }
+
+    zpl_json_object *zpl_json_find(zpl_json_object *obj, char const *name, zpl_b32 deep_search)
+    {
+        if (obj->type != ZPL_JSON_TYPE_OBJECT)
+        {
+            return NULL;
+        }
+
+        for (zpl_isize i = 0; i < zpl_array_count(obj->nodes); i++)
+        {
+            if (!zpl_strcmp(obj->nodes[i].name, name))
+            {
+                return (obj->nodes + i);
+            }
+        }
+
+        if (deep_search)
+        {
+            for (zpl_isize i = 0; i < zpl_array_count(obj->nodes); i++)
+            {
+                zpl_json_object *res = zpl_json_find(obj->nodes + i, name, deep_search);
+
+                if (res != NULL)
+                    return res;
+            }
+        }
+
+        return NULL;
+    }
+
+    void zpl_json_init_node(zpl_json_object *obj, zpl_allocator backing, char const *name, zpl_u8 type)
+    {
+        obj->name = (char *)name;
+        obj->type = type;
+        obj->backing = backing;
+
+        if (type == ZPL_JSON_TYPE_ARRAY || type == ZPL_JSON_TYPE_OBJECT)
+        {
+            zpl_array_init(obj->nodes, backing);
+        }
+    }
+
+    zpl_json_object *zpl_json_add_at(zpl_json_object *obj, zpl_isize index, char const *name, zpl_u8 type)
+    {
+        if (!obj || (obj->type != ZPL_JSON_TYPE_OBJECT && obj->type != ZPL_JSON_TYPE_ARRAY))
+        {
+            return NULL;
+        }
+
+        if (!obj->nodes)
+            return NULL;
+
+        if (index < 0 || index > zpl_array_count(obj->nodes))
+            return NULL;
+
+        zpl_json_object o = {0};
+        zpl_json_init_node(&o, obj->backing, name, type);
+
+        zpl_array_append_at(obj->nodes, o, index);
+
+        return obj->nodes + index;
+    }
+
+    zpl_json_object *zpl_json_add(zpl_json_object *obj, char const *name, zpl_u8 type)
+    {
+        if (!obj || (obj->type != ZPL_JSON_TYPE_OBJECT && obj->type != ZPL_JSON_TYPE_ARRAY))
+        {
+            return NULL;
+        }
+
+        if (!obj->nodes)
+            return NULL;
+
+        return zpl_json_add_at(obj, zpl_array_count(obj->nodes), name, type);
+    }
+
+    ZPL_END_C_DECLS
+#endif
+
+#if defined(ZPL_MODULE_THREADING)
+    // file: source/threading/atomic.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    ////////////////////////////////////////////////////////////////
+    //
+    // Concurrency
+    //
+    //
+    // IMPORTANT TODO: Use compiler intrinsics for the atomics
+
+    #if defined(ZPL_COMPILER_MSVC) && !defined(ZPL_COMPILER_CLANG)
+        zpl_i32 zpl_atomic32_load (zpl_atomic32 const *a)      { return a->value;  }
+        void     zpl_atomic32_store(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) value) { a->value = value; }
+
+        zpl_i32 zpl_atomic32_compare_exchange(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) expected, zpl_atomicarg(zpl_i32) desired) {
+            return _InterlockedCompareExchange(cast(long *)a, desired, expected);
+        }
+        zpl_i32 zpl_atomic32_exchange(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) desired) {
+            return _InterlockedExchange(cast(long *)a, desired);
+        }
+        zpl_i32 zpl_atomic32_fetch_add(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) operand) {
+            return _InterlockedExchangeAdd(cast(long *)a, operand);
+        }
+        zpl_i32 zpl_atomic32_fetch_and(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) operand) {
+            return _InterlockedAnd(cast(long *)a, operand);
+        }
+        zpl_i32 zpl_atomic32_fetch_or(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) operand) {
+            return _InterlockedOr(cast(long *)a, operand);
+        }
+
+        zpl_i64 zpl_atomic64_load(zpl_atomic64 const *a) {
+            #if defined(ZPL_ARCH_64_BIT)
+                return a->value;
+            #elif ZPL_CPU_X86
+                // NOTE: The most compatible way to get an atomic 64-bit load on x86 is with cmpxchg8b
+                zpl_atomicarg(zpl_i64) result;
+                __asm {
+                    mov esi, a;
+                    mov ebx, eax;
+                    mov ecx, edx;
+                    lock cmpxchg8b [esi];
+                    mov dword ptr result, eax;
+                    mov dword ptr result[4], edx;
+                }
+                return result;
+            #else
+                #error TODO: atomics for this CPU
+            #endif
+        }
+
+        void zpl_atomic64_store(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) value) {
+            #if defined(ZPL_ARCH_64_BIT)
+                a->value = value;
+            #elif ZPL_CPU_X86
+                // NOTE: The most compatible way to get an atomic 64-bit store on x86 is with cmpxchg8b
+                __asm {
+                    mov esi, a;
+                    mov ebx, dword ptr value;
+                    mov ecx, dword ptr value[4];
+                    retry:
+                    cmpxchg8b [esi];
+                    jne retry;
+                }
+            #else
+                #error TODO: atomics for this CPU
+            #endif
+        }
+
+        zpl_i64 zpl_atomic64_compare_exchange(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) expected, zpl_atomicarg(zpl_i64) desired) {
+            return _InterlockedCompareExchange64(cast(zpl_atomicarg(zpl_i64) *)a, desired, expected);
+        }
+
+        zpl_i64 zpl_atomic64_exchange(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) desired) {
+            #if defined(ZPL_ARCH_64_BIT)
+                return _InterlockedExchange64(cast(zpl_atomicarg(zpl_i64) *)a, desired);
+            #elif ZPL_CPU_X86
+                zpl_atomicarg(zpl_i64) expected = a->value;
+                for (;;) {
+                    zpl_atomicarg(zpl_i64) original = _InterlockedCompareExchange64(cast(zpl_atomicarg(zpl_i64) *)a, desired, expected);
+                    if (original == expected)
+                        return original;
+                    expected = original;
+                }
+            #else
+                #error TODO: atomics for this CPU
+            #endif
+        }
+
+        zpl_i64 zpl_atomic64_fetch_add(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) operand) {
+            #if defined(ZPL_ARCH_64_BIT)
+                return _InterlockedExchangeAdd64(cast(zpl_atomicarg(zpl_i64) *)a, operand);
+            #elif ZPL_CPU_X86
+                zpl_atomicarg(zpl_i64) expected = a->value;
+                for (;;) {
+                    zpl_atomicarg(zpl_i64) original = _InterlockedCompareExchange64(cast(zpl_atomicarg(zpl_i64) *)a, expected + operand, expected);
+                    if (original == expected)
+                        return original;
+                    expected = original;
+                }
+            #else
+                #error TODO: atomics for this CPU
+            #endif
+        }
+
+        zpl_i64 zpl_atomic64_fetch_and(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) operand) {
+            #if defined(ZPL_ARCH_64_BIT)
+                return _InterlockedAnd64(cast(zpl_atomicarg(zpl_i64) *)a, operand);
+            #elif ZPL_CPU_X86
+                zpl_atomicarg(zpl_i64) expected = a->value;
+                for (;;) {
+                    zpl_atomicarg(zpl_i64) original = _InterlockedCompareExchange64(cast(zpl_atomicarg(zpl_i64) *)a, expected & operand, expected);
+                    if (original == expected)
+                        return original;
+                    expected = original;
+                }
+            #else
+                #error TODO: atomics for this CPU
+            #endif
+        }
+
+        zpl_i64 zpl_atomic64_fetch_or(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) operand) {
+            #if defined(ZPL_ARCH_64_BIT)
+                return _InterlockedOr64(cast(zpl_atomicarg(zpl_i64) *)a, operand);
+            #elif ZPL_CPU_X86
+                zpl_atomicarg(zpl_i64) expected = a->value;
+                for (;;) {
+                    zpl_atomicarg(zpl_i64) original = _InterlockedCompareExchange64(cast(zpl_atomicarg(zpl_i64) *)a, expected | operand, expected);
+                    if (original == expected)
+                        return original;
+                    expected = original;
+                }
+            #else
+                #error TODO: atomics for this CPU
+            #endif
+        }
+
+    #elif defined(ZPL_CPU_X86)
+
+        zpl_i32 zpl_atomic32_load (zpl_atomic32 const *a)      { return a->value;  }
+        void zpl_atomic32_store(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) value) { a->value = value; }
+
+        zpl_i32 zpl_atomic32_compare_exchange(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) expected, zpl_atomicarg(zpl_i32) desired) {
+            zpl_atomicarg(zpl_i32) original;
+            __asm__(
+                "lock; cmpxchgl %2, %1"
+                : "=a"(original), "+m"(a->value)
+                : "q"(desired), "0"(expected)
+                );
+            return original;
+        }
+
+        zpl_i32 zpl_atomic32_exchange(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) desired) {
+            // NOTE: No lock prefix is necessary for xchgl
+            zpl_atomicarg(zpl_i32) original;
+            __asm__(
+                "xchgl %0, %1"
+                : "=r"(original), "+m"(a->value)
+                : "0"(desired)
+                );
+            return original;
+        }
+
+        zpl_i32 zpl_atomic32_fetch_add(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) operand) {
+            zpl_atomicarg(zpl_i32) original;
+            __asm__(
+                "lock; xaddl %0, %1"
+                : "=r"(original), "+m"(a->value)
+                : "0"(operand)
+                );
+            return original;
+        }
+
+        zpl_i32 zpl_atomic32_fetch_and(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) operand) {
+            zpl_atomicarg(zpl_i32) original;
+            zpl_atomicarg(zpl_i32) tmp;
+            __asm__(
+                "1:     movl    %1, %0\n"
+                "       movl    %0, %2\n"
+                "       andl    %3, %2\n"
+                "       lock; cmpxchgl %2, %1\n"
+                "       jne     1b"
+                : "=&a"(original), "+m"(a->value), "=&r"(tmp)
+                : "r"(operand)
+                );
+            return original;
+        }
+
+        zpl_i32 zpl_atomic32_fetch_or(zpl_atomic32 *a, zpl_atomicarg(zpl_i32) operand) {
+            zpl_atomicarg(zpl_i32) original;
+            zpl_atomicarg(zpl_i32) temp;
+            __asm__(
+                "1:     movl    %1, %0\n"
+                "       movl    %0, %2\n"
+                "       orl     %3, %2\n"
+                "       lock; cmpxchgl %2, %1\n"
+                "       jne     1b"
+                : "=&a"(original), "+m"(a->value), "=&r"(temp)
+                : "r"(operand)
+                );
+            return original;
+        }
+
+
+        zpl_i64 zpl_atomic64_load(zpl_atomic64 const *a) {
+            #if defined(ZPL_ARCH_64_BIT)
+                return a->value;
+            #else
+                zpl_atomicarg(zpl_i64) original;
+                __asm__(
+                    "movl %%ebx, %%eax\n"
+                    "movl %%ecx, %%edx\n"
+                    "lock; cmpxchg8b %1"
+                    : "=&A"(original)
+                    : "m"(a->value)
+                    );
+                return original;
+            #endif
+        }
+
+        void zpl_atomic64_store(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) value) {
+            #if defined(ZPL_ARCH_64_BIT)
+                a->value = value;
+            #else
+                zpl_atomicarg(zpl_i64) expected = a->value;
+                __asm__(
+                    "1:    cmpxchg8b %0\n"
+                    "      jne 1b"
+                    : "=m"(a->value)
+                    : "b"((zpl_atomicarg(zpl_i32))value), "c"((zpl_atomicarg(zpl_i32))(value >> 32)), "A"(expected)
+                    );
+            #endif
+        }
+
+        zpl_i64 zpl_atomic64_compare_exchange(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) expected, zpl_atomicarg(zpl_i64) desired) {
+            #if defined(ZPL_ARCH_64_BIT)
+                zpl_atomicarg(zpl_i64) original;
+                __asm__(
+                    "lock; cmpxchgq %2, %1"
+                    : "=a"(original), "+m"(a->value)
+                    : "q"(desired), "0"(expected)
+                    );
+                return original;
+            #else
+                zpl_atomicarg(zpl_i64) original;
+                __asm__(
+                    "lock; cmpxchg8b %1"
+                    : "=A"(original), "+m"(a->value)
+                    : "b"((zpl_atomicarg(zpl_i32))desired), "c"((zpl_atomicarg(zpl_i32))(desired >> 32)), "0"(expected)
+                    );
+                return original;
+            #endif
+        }
+
+        zpl_i64 zpl_atomic64_exchange(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) desired) {
+            #if defined(ZPL_ARCH_64_BIT)
+                zpl_atomicarg(zpl_i64) original;
+                __asm__(
+                    "xchgq %0, %1"
+                    : "=r"(original), "+m"(a->value)
+                    : "0"(desired)
+                    );
+                return original;
+            #else
+                zpl_atomicarg(zpl_i64) original = a->value;
+                for (;;) {
+                    zpl_atomicarg(zpl_i64) previous = zpl_atomic64_compare_exchange(a, original, desired);
+                    if (original == previous)
+                        return original;
+                    original = previous;
+                }
+            #endif
+        }
+
+        zpl_i64 zpl_atomic64_fetch_add(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) operand) {
+            #if defined(ZPL_ARCH_64_BIT)
+                zpl_atomicarg(zpl_i64) original;
+                __asm__(
+                    "lock; xaddq %0, %1"
+                    : "=r"(original), "+m"(a->value)
+                    : "0"(operand)
+                    );
+                return original;
+            #else
+                for (;;) {
+                    zpl_atomicarg(zpl_i64) original = a->value;
+                    if (zpl_atomic64_compare_exchange(a, original, original + operand) == original)
+                        return original;
+                }
+            #endif
+        }
+
+        zpl_i64 zpl_atomic64_fetch_and(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) operand) {
+            #if defined(ZPL_ARCH_64_BIT)
+                zpl_atomicarg(zpl_i64) original;
+                zpl_atomicarg(zpl_i64) tmp;
+                __asm__(
+                    "1:     movq    %1, %0\n"
+                    "       movq    %0, %2\n"
+                    "       andq    %3, %2\n"
+                    "       lock; cmpxchgq %2, %1\n"
+                    "       jne     1b"
+                    : "=&a"(original), "+m"(a->value), "=&r"(tmp)
+                    : "r"(operand)
+                    );
+                return original;
+            #else
+                for (;;) {
+                    zpl_atomicarg(zpl_i64) original = a->value;
+                    if (zpl_atomic64_compare_exchange(a, original, original & operand) == original)
+                        return original;
+                }
+            #endif
+        }
+
+        zpl_i64 zpl_atomic64_fetch_or(zpl_atomic64 *a, zpl_atomicarg(zpl_i64) operand) {
+            #if defined(ZPL_ARCH_64_BIT)
+                zpl_atomicarg(zpl_i64) original;
+                zpl_atomicarg(zpl_i64) temp;
+                __asm__(
+                    "1:     movq    %1, %0\n"
+                    "       movq    %0, %2\n"
+                    "       orq     %3, %2\n"
+                    "       lock; cmpxchgq %2, %1\n"
+                    "       jne     1b"
+                    : "=&a"(original), "+m"(a->value), "=&r"(temp)
+                    : "r"(operand)
+                    );
+                return original;
+            #else
+                for (;;) {
+                    zpl_atomicarg(zpl_i64) original = a->value;
+                    if (zpl_atomic64_compare_exchange(a, original, original | operand) == original)
+                        return original;
+                }
+            #endif
+        }
+
+    #else
+        #error TODO: Implement Atomics for this CPU
+    #endif
+
+
+
+    zpl_b32 zpl_atomic32_spin_lock(zpl_atomic32 *a, zpl_isize time_out) {
+        zpl_atomicarg(zpl_i32) old_value = zpl_atomic32_compare_exchange(a, 1, 0);
+        zpl_i32 counter = 0;
+        while (old_value != 0 && (time_out < 0 || counter++ < time_out)) {
+            zpl_yield_thread();
+            old_value = zpl_atomic32_compare_exchange(a, 1, 0);
+            zpl_mfence();
+        }
+        return old_value == 0;
+    }
+
+    void zpl_atomic32_spin_unlock(zpl_atomic32 *a) {
+        zpl_atomic32_store(a, 0);
+        zpl_mfence();
+    }
+
+    zpl_b32 zpl_atomic64_spin_lock(zpl_atomic64 *a, zpl_isize time_out) {
+        zpl_atomicarg(zpl_i64) old_value = zpl_atomic64_compare_exchange(a, 1, 0);
+        zpl_atomicarg(zpl_i64) counter = 0;
+        while (old_value != 0 && (time_out < 0 || counter++ < time_out)) {
+            zpl_yield_thread();
+            old_value = zpl_atomic64_compare_exchange(a, 1, 0);
+            zpl_mfence();
+        }
+        return old_value == 0;
+    }
+
+    void zpl_atomic64_spin_unlock(zpl_atomic64 *a) {
+        zpl_atomic64_store(a, 0);
+        zpl_mfence();
+    }
+
+    zpl_b32 zpl_atomic32_try_acquire_lock(zpl_atomic32 *a) {
+        zpl_atomicarg(zpl_i32) old_value;
+        zpl_yield_thread();
+        old_value = zpl_atomic32_compare_exchange(a, 1, 0);
+        zpl_mfence();
+        return old_value == 0;
+    }
+
+    zpl_b32 zpl_atomic64_try_acquire_lock(zpl_atomic64 *a) {
+        zpl_atomicarg(zpl_i64) old_value;
+        zpl_yield_thread();
+        old_value = zpl_atomic64_compare_exchange(a, 1, 0);
+        zpl_mfence();
+        return old_value == 0;
+    }
+
+
+
+    #if defined(ZPL_ARCH_32_BIT)
+
+        void* zpl_atomic_ptr_load(zpl_atomic_ptr const *a) {
+            return (void *)cast(zpl_intptr)zpl_atomic32_load(cast(zpl_atomic32 const *)a);
+        }
+        void zpl_atomic_ptr_store(zpl_atomic_ptr *a, zpl_atomicarg(void *)value) {
+            zpl_atomic32_store(cast(zpl_atomic32 *)a, cast(zpl_atomicarg(zpl_i32))cast(zpl_intptr)value);
+        }
+        void* zpl_atomic_ptr_compare_exchange(zpl_atomic_ptr *a, zpl_atomicarg(void *)expected, zpl_atomicarg(void *)desired) {
+            return (void *)cast(zpl_intptr)zpl_atomic32_compare_exchange(cast(zpl_atomic32 *)a, cast(zpl_atomicarg(zpl_i32))cast(zpl_intptr)expected, cast(zpl_atomicarg(zpl_i32))cast(zpl_intptr)desired);
+        }
+        void* zpl_atomic_ptr_exchange(zpl_atomic_ptr *a, zpl_atomicarg(void *)desired) {
+            return (void *)cast(zpl_intptr)zpl_atomic32_exchange(cast(zpl_atomic32 *)a, cast(zpl_atomicarg(zpl_i32))cast(zpl_intptr)desired);
+        }
+        void* zpl_atomic_ptr_fetch_add(zpl_atomic_ptr *a, zpl_atomicarg(void *)operand) {
+            return (void *)cast(zpl_intptr)zpl_atomic32_fetch_add(cast(zpl_atomic32 *)a, cast(zpl_atomicarg(zpl_i32))cast(zpl_intptr)operand);
+        }
+        void* zpl_atomic_ptr_fetch_and(zpl_atomic_ptr *a, zpl_atomicarg(void *)operand) {
+            return (void *)cast(zpl_intptr)zpl_atomic32_fetch_and(cast(zpl_atomic32 *)a, cast(zpl_atomicarg(zpl_i32))cast(zpl_intptr)operand);
+        }
+        void* zpl_atomic_ptr_fetch_or(zpl_atomic_ptr *a, zpl_atomicarg(void *)operand) {
+            return (void *)cast(zpl_intptr)zpl_atomic32_fetch_or(cast(zpl_atomic32 *)a, cast(zpl_atomicarg(zpl_i32))cast(zpl_intptr)operand);
+        }
+        zpl_b32 zpl_atomic_ptr_spin_lock(zpl_atomic_ptr *a, zpl_isize time_out) {
+            return zpl_atomic32_spin_lock(cast(zpl_atomic32 *)a, time_out);
+        }
+        void zpl_atomic_ptr_spin_unlock(zpl_atomic_ptr *a) {
+            zpl_atomic32_spin_unlock(cast(zpl_atomic32 *)a);
+        }
+        zpl_b32 zpl_atomic_ptr_try_acquire_lock(zpl_atomic_ptr *a) {
+            return zpl_atomic32_try_acquire_lock(cast(zpl_atomic32 *)a);
+        }
+
+    #elif defined(ZPL_ARCH_64_BIT)
+
+        void* zpl_atomic_ptr_load(zpl_atomic_ptr const *a) {
+            return (void *)cast(zpl_intptr)zpl_atomic64_load(cast(zpl_atomic64 const *)a);
+        }
+        void zpl_atomic_ptr_store(zpl_atomic_ptr *a, zpl_atomicarg(void *)value) {
+            zpl_atomic64_store(cast(zpl_atomic64 *)a, cast(zpl_i64)cast(zpl_intptr)value);
+        }
+        void* zpl_atomic_ptr_compare_exchange(zpl_atomic_ptr *a, zpl_atomicarg(void *)expected, zpl_atomicarg(void *)desired) {
+            return (void *)cast(zpl_intptr)zpl_atomic64_compare_exchange(cast(zpl_atomic64 *)a, cast(zpl_i64)cast(zpl_intptr)expected, cast(zpl_i64)cast(zpl_intptr)desired);
+        }
+        void* zpl_atomic_ptr_exchange(zpl_atomic_ptr *a, zpl_atomicarg(void *)desired) {
+            return (void *)cast(zpl_intptr)zpl_atomic64_exchange(cast(zpl_atomic64 *)a, cast(zpl_i64)cast(zpl_intptr)desired);
+        }
+        void* zpl_atomic_ptr_fetch_add(zpl_atomic_ptr *a, zpl_atomicarg(void *)operand) {
+            return (void *)cast(zpl_intptr)zpl_atomic64_fetch_add(cast(zpl_atomic64 *)a, cast(zpl_i64)cast(zpl_intptr)operand);
+        }
+        void* zpl_atomic_ptr_fetch_and(zpl_atomic_ptr *a, zpl_atomicarg(void *)operand) {
+            return (void *)cast(zpl_intptr)zpl_atomic64_fetch_and(cast(zpl_atomic64 *)a, cast(zpl_i64)cast(zpl_intptr)operand);
+        }
+        void* zpl_atomic_ptr_fetch_or(zpl_atomic_ptr *a, zpl_atomicarg(void *)operand) {
+            return (void *)cast(zpl_intptr)zpl_atomic64_fetch_or(cast(zpl_atomic64 *)a, cast(zpl_i64)cast(zpl_intptr)operand);
+        }
+        zpl_b32 zpl_atomic_ptr_spin_lock(zpl_atomic_ptr *a, zpl_isize time_out) {
+            return zpl_atomic64_spin_lock(cast(zpl_atomic64 *)a, time_out);
+        }
+        void zpl_atomic_ptr_spin_unlock(zpl_atomic_ptr *a) {
+            zpl_atomic64_spin_unlock(cast(zpl_atomic64 *)a);
+        }
+        zpl_b32 zpl_atomic_ptr_try_acquire_lock(zpl_atomic_ptr *a) {
+            return zpl_atomic64_try_acquire_lock(cast(zpl_atomic64 *)a);
+        }
+
+    #endif
+
+    ZPL_END_C_DECLS
+    // file: source/threading/fence.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #if defined(_MSC_VER)
+         /* Microsoft C/C++-compatible compiler */
+         #include <intrin.h>
+    #elif defined(__GNUC__) && (defined(__x86_64__) || defined(__i386__))
+         /* GCC-compatible compiler, targeting x86/x86-64 */
+         #include <x86intrin.h>
+    #elif defined(__GNUC__) && defined(__ARM_NEON__)
+         /* GCC-compatible compiler, targeting ARM with NEON */
+         #include <arm_neon.h>
+    #elif defined(__GNUC__) && defined(__IWMMXT__)
+         /* GCC-compatible compiler, targeting ARM with WMMX */
+         #include <mmintrin.h>
+    #elif (defined(__GNUC__) || defined(__xlC__)) && (defined(__VEC__) || defined(__ALTIVEC__))
+         /* XLC or GCC-compatible compiler, targeting PowerPC with VMX/VSX */
+         #include <altivec.h>
+    #elif defined(__GNUC__) && defined(__SPE__)
+         /* GCC-compatible compiler, targeting PowerPC with SPE */
+         #include <spe.h>
+    #endif
+
+    void zpl_yield_thread(void) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            _mm_pause();
+        #elif defined(ZPL_SYSTEM_OSX)
+            __asm__ volatile ("" : : : "memory");
+        #elif defined(ZPL_CPU_X86)
+            _mm_pause();
+        #else
+            #error Unknown architecture
+        #endif
+    }
+
+    void zpl_mfence(void) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            _ReadWriteBarrier();
+        #elif defined(ZPL_SYSTEM_OSX)
+            __sync_synchronize();
+        #elif defined(ZPL_CPU_X86)
+            _mm_mfence();
+        #else
+            #error Unknown architecture
+        #endif
+    }
+
+    void zpl_sfence(void) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            _WriteBarrier();
+        #elif defined(ZPL_SYSTEM_OSX)
+            __asm__ volatile ("" : : : "memory");
+        #elif defined(ZPL_CPU_X86)
+            _mm_sfence();
+        #else
+            #error Unknown architecture
+        #endif
+    }
+
+    void zpl_lfence(void) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            _ReadBarrier();
+        #elif defined(ZPL_SYSTEM_OSX)
+            __asm__ volatile ("" : : : "memory");
+        #elif defined(ZPL_CPU_X86)
+            _mm_lfence();
+        #else
+            #error Unknown architecture
+        #endif
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/threading/sem.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    void zpl_semaphore_release(zpl_semaphore *s) { zpl_semaphore_post(s, 1); }
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+
+        void zpl_semaphore_init   (zpl_semaphore *s)            { s->win32_handle = CreateSemaphoreA(NULL, 0, ZPL_I32_MAX, NULL); }
+        void zpl_semaphore_destroy(zpl_semaphore *s)            { CloseHandle(s->win32_handle); }
+        void zpl_semaphore_post   (zpl_semaphore *s, zpl_i32 count) { ReleaseSemaphore(s->win32_handle, count, NULL); }
+        void zpl_semaphore_wait   (zpl_semaphore *s)            { WaitForSingleObject(s->win32_handle, INFINITE); }
+
+    #elif defined(ZPL_SYSTEM_OSX)
+
+        void zpl_semaphore_init   (zpl_semaphore *s)            { semaphore_create(mach_task_self(), &s->osx_handle, SYNC_POLICY_FIFO, 0); }
+        void zpl_semaphore_destroy(zpl_semaphore *s)            { semaphore_destroy(mach_task_self(), s->osx_handle); }
+        void zpl_semaphore_post   (zpl_semaphore *s, zpl_i32 count) { while (count --> 0) semaphore_signal(s->osx_handle); }
+        void zpl_semaphore_wait   (zpl_semaphore *s)            { semaphore_wait(s->osx_handle); }
+
+    #elif defined(ZPL_SYSTEM_UNIX)
+
+        void zpl_semaphore_init   (zpl_semaphore *s)            { sem_init(&s->unix_handle, 0, 0); }
+        void zpl_semaphore_destroy(zpl_semaphore *s)            { sem_destroy(&s->unix_handle); }
+        void zpl_semaphore_post   (zpl_semaphore *s, zpl_i32 count) { while (count --> 0) sem_post(&s->unix_handle); }
+        void zpl_semaphore_wait   (zpl_semaphore *s)            { int i; do { i = sem_wait(&s->unix_handle); } while (i == -1 && errno == EINTR); }
+
+    #else
+        #error Semaphores for this OS are not implemented
+    #endif
+
+    ZPL_END_C_DECLS
+    // file: source/threading/mutex.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    void zpl_mutex_init(zpl_mutex *m) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            InitializeCriticalSection(&m->win32_critical_section);
+        #else
+            pthread_mutex_init(&m->pthread_mutex, NULL);
+        #endif
+    }
+
+    void zpl_mutex_destroy(zpl_mutex *m) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            DeleteCriticalSection(&m->win32_critical_section);
+        #else
+            pthread_mutex_destroy(&m->pthread_mutex);
+        #endif
+    }
+
+    void zpl_mutex_lock(zpl_mutex *m) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            EnterCriticalSection(&m->win32_critical_section);
+        #else
+            pthread_mutex_lock(&m->pthread_mutex);
+        #endif
+    }
+
+    zpl_b32 zpl_mutex_try_lock(zpl_mutex *m) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            return TryEnterCriticalSection(&m->win32_critical_section);
+        #else
+            return pthread_mutex_trylock(&m->pthread_mutex);
+        #endif
+    }
+
+    void zpl_mutex_unlock(zpl_mutex *m) {
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            LeaveCriticalSection(&m->win32_critical_section);
+        #else
+            pthread_mutex_unlock(&m->pthread_mutex);
+        #endif
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/threading/thread.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    zpl_b32 zpl_thread_is_running(zpl_thread const *t) { return t->is_running != 0; }
+
+    void zpl_thread_init(zpl_thread *t) {
+        zpl_zero_item(t);
+
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            t->win32_handle = INVALID_HANDLE_VALUE;
+        #else
+            t->posix_handle = 0;
+        #endif
+
+        zpl_semaphore_init(&t->semaphore);
+    }
+
+    void zpl_thread_destroy(zpl_thread *t) {
+        if (t->is_running) zpl_thread_join(t);
+        zpl_semaphore_destroy(&t->semaphore);
+    }
+
+    void zpl__thread_run(zpl_thread *t) {
+        zpl_semaphore_release(&t->semaphore);
+        t->return_value = t->proc(t);
+    }
+
+    #if defined(ZPL_SYSTEM_WINDOWS)
+        DWORD __stdcall zpl__thread_proc(void *arg) {
+            zpl_thread *t = cast(zpl_thread *)arg;
+            zpl__thread_run(t);
+            t->is_running = false;
+            return 0;
+        }
+    #else
+        void *zpl__thread_proc(void *arg) {
+            zpl_thread *t = cast(zpl_thread *)arg;
+            zpl__thread_run(t);
+            t->is_running = false;
+            return NULL;
+        }
+    #endif
+
+    void zpl_thread_start(zpl_thread *t, zpl_thread_proc proc, void *user_data) {
+        zpl_thread_start_with_stack(t, proc, user_data, 0);
+    }
+
+    void zpl_thread_start_with_stack(zpl_thread *t, zpl_thread_proc proc, void *user_data, zpl_isize stack_size) {
+        ZPL_ASSERT(!t->is_running);
+        ZPL_ASSERT(proc != NULL);
+        t->proc = proc;
+        t->user_data = user_data;
+        t->stack_size = stack_size;
+
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            t->win32_handle = CreateThread(NULL, stack_size, zpl__thread_proc, t, 0, NULL);
+            ZPL_ASSERT_MSG(t->win32_handle != NULL, "CreateThread: GetLastError");
+        #else
+            {
+                pthread_attr_t attr;
+                pthread_attr_init(&attr);
+                pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE);
+                if (stack_size != 0)
+                    pthread_attr_setstacksize(&attr, stack_size);
+                pthread_create(&t->posix_handle, &attr, zpl__thread_proc, t);
+                pthread_attr_destroy(&attr);
+            }
+        #endif
+
+        t->is_running = true;
+        zpl_semaphore_wait(&t->semaphore);
+    }
+
+    void zpl_thread_join(zpl_thread *t) {
+        if (!t->is_running) return;
+
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            WaitForSingleObject(t->win32_handle, INFINITE);
+            CloseHandle(t->win32_handle);
+            t->win32_handle = INVALID_HANDLE_VALUE;
+        #else
+            pthread_join(t->posix_handle, NULL);
+            t->posix_handle = 0;
+        #endif
+            t->is_running = false;
+        }
+
+        zpl_u32 zpl_thread_current_id(void) {
+            zpl_u32 thread_id;
+        #if defined(ZPL_SYSTEM_WINDOWS)
+            #if defined(ZPL_ARCH_32_BIT) && defined(ZPL_CPU_X86)
+                thread_id = (cast(zpl_u32 *)__readfsdword(24))[9];
+            #elif defined(ZPL_ARCH_64_BIT) && defined(ZPL_CPU_X86)
+                thread_id = (cast(zpl_u32 *)__readgsqword(48))[18];
+            #else
+                thread_id = GetCurrentThreadId();
+            #endif
+
+        #elif defined(ZPL_SYSTEM_OSX) && defined(ZPL_ARCH_64_BIT)
+            thread_id = pthread_mach_thread_np(pthread_self());
+        #elif defined(ZPL_ARCH_32_BIT) && defined(ZPL_CPU_X86)
+            __asm__("mov %%gs:0x08,%0" : "=r"(thread_id));
+        #elif defined(ZPL_ARCH_64_BIT) && defined(ZPL_CPU_X86)
+            __asm__("mov %%fs:0x10,%0" : "=r"(thread_id));
+        #else
+            #error Unsupported architecture for zpl_thread_current_id()
+        #endif
+
+        return thread_id;
+    }
+
+    void zpl_thread_set_name(zpl_thread *t, char const *name) {
+        #if defined(ZPL_COMPILER_MSVC)
+            #pragma pack(push, 8)
+                typedef struct {
+                    DWORD       type;
+                    char const *name;
+                    DWORD       id;
+                    DWORD       flags;
+                } zplprivThreadName;
+            #pragma pack(pop)
+
+            zplprivThreadName tn;
+            tn.type  = 0x1000;
+            tn.name  = name;
+            tn.id    = GetThreadId(cast(HANDLE)t->win32_handle);
+            tn.flags = 0;
+
+            __try {
+                RaiseException(0x406d1388, 0, zpl_size_of(tn)/4, cast(ULONG_PTR *)&tn);
+            } __except(1 /*EXCEPTION_EXECUTE_HANDLER*/) {
+            }
+
+        #elif defined(ZPL_SYSTEM_WINDOWS) && !defined(ZPL_COMPILER_MSVC)
+            zpl_unused(t);
+            zpl_unused(name);
+            // IMPORTANT TODO: Set thread name for GCC/Clang on windows
+            return;
+        #elif defined(ZPL_SYSTEM_OSX)
+            // TODO: Test if this works
+            pthread_setname_np(name);
+        #else
+            zpl_unused(t);
+            zpl_unused(name);
+            // TODO: Test if this works
+            //        pthread_set_name_np(t->posix_handle, name);
+        #endif
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/threading/sync.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    void zpl_sync_init(zpl_sync *s) {
+        zpl_zero_item(s);
+        zpl_mutex_init(&s->mutex);
+        zpl_mutex_init(&s->start);
+        zpl_semaphore_init(&s->release);
+    }
+
+    void zpl_sync_destroy(zpl_sync *s) {
+        if (s->waiting) {
+            ZPL_PANIC("Cannot destroy while threads are waiting!");
+        }
+
+        zpl_mutex_destroy(&s->mutex);
+        zpl_mutex_destroy(&s->start);
+        zpl_semaphore_destroy(&s->release);
+    }
+
+    void zpl_sync_set_target(zpl_sync *s, zpl_i32 count) {
+        zpl_mutex_lock(&s->start);
+
+        zpl_mutex_lock(&s->mutex);
+        ZPL_ASSERT(s->target == 0);
+        s->target = count;
+        s->current = 0;
+        s->waiting = 0;
+        zpl_mutex_unlock(&s->mutex);
+    }
+
+    void zpl_sync_release(zpl_sync *s) {
+        if (s->waiting) {
+            zpl_semaphore_release(&s->release);
+        } else {
+            s->target = 0;
+            zpl_mutex_unlock(&s->start);
+        }
+    }
+
+    zpl_i32 zpl_sync_reach(zpl_sync *s) {
+        zpl_i32 n;
+        zpl_mutex_lock(&s->mutex);
+        ZPL_ASSERT(s->current < s->target);
+        n = ++s->current; // NOTE: Record this value to avoid possible race if `return s->current` was done
+        if (s->current == s->target)
+            zpl_sync_release(s);
+        zpl_mutex_unlock(&s->mutex);
+        return n;
+    }
+
+    void zpl_sync_reach_and_wait(zpl_sync *s) {
+        zpl_mutex_lock(&s->mutex);
+        ZPL_ASSERT(s->current < s->target);
+        s->current++;
+        if (s->current == s->target) {
+            zpl_sync_release(s);
+            zpl_mutex_unlock(&s->mutex);
+        } else {
+            s->waiting++;                   // NOTE: Waiting, so one more waiter
+            zpl_mutex_unlock(&s->mutex);     // NOTE: Release the mutex to other threads
+            zpl_semaphore_wait(&s->release); // NOTE: Wait for merge completion
+            zpl_mutex_lock(&s->mutex);       // NOTE: On merge completion, lock mutex
+            s->waiting--;                   // NOTE: Done waiting
+            zpl_sync_release(s);             // NOTE: Restart the next waiter
+            zpl_mutex_unlock(&s->mutex);
+        }
+    }
+
+    ZPL_END_C_DECLS
+    // file: source/threading/affinity.c
+
+    #ifdef ZPL_EDITOR
+    #include <zpl.h>
+    #endif
+
+    #if defined(ZPL_SYSTEM_MACOS)
+        #include <sys/sysctl.h>
+    #endif
+
+    ZPL_BEGIN_C_DECLS
+
+    #if defined(ZPL_SYSTEM_WINDOWS) || defined(ZPL_SYSTEM_CYGWIN)
+
+        void zpl_affinity_init(zpl_affinity *a) {
+            SYSTEM_LOGICAL_PROCESSOR_INFORMATION *start_processor_info = NULL;
+            DWORD length = 0;
+            zpl_b32 result  = GetLogicalProcessorInformation(NULL, &length);
+
+            zpl_zero_item(a);
+
+            if (!result && GetLastError() == 122l /*ERROR_INSUFFICIENT_BUFFER*/ && length > 0) {
+                start_processor_info = cast(SYSTEM_LOGICAL_PROCESSOR_INFORMATION *)zpl_alloc(zpl_heap_allocator(), length);
+                result = GetLogicalProcessorInformation(start_processor_info, &length);
+                if (result) {
+                    SYSTEM_LOGICAL_PROCESSOR_INFORMATION *end_processor_info, *processor_info;
+
+                    a->is_accurate  = true;
+                    a->core_count   = 0;
+                    a->thread_count = 0;
+                    end_processor_info = cast(SYSTEM_LOGICAL_PROCESSOR_INFORMATION *)zpl_pointer_add(start_processor_info, length);
+
+                    for (processor_info = start_processor_info;
+                         processor_info < end_processor_info;
+                         processor_info++) {
+                        if (processor_info->Relationship == RelationProcessorCore) {
+                            zpl_isize thread = zpl_count_set_bits(processor_info->ProcessorMask);
+                            if (thread == 0) {
+                                a->is_accurate = false;
+                            } else if (a->thread_count + thread > ZPL_WIN32_MAX_THREADS) {
+                                a->is_accurate = false;
+                            } else {
+                                ZPL_ASSERT(a->core_count <= a->thread_count &&
+                                           a->thread_count < ZPL_WIN32_MAX_THREADS);
+                                a->core_masks[a->core_count++] = processor_info->ProcessorMask;
+                                a->thread_count += thread;
+                            }
+                        }
+                    }
+                }
+
+                zpl_free(zpl_heap_allocator(), start_processor_info);
+            }
+
+            ZPL_ASSERT(a->core_count <= a->thread_count);
+            if (a->thread_count == 0) {
+                a->is_accurate   = false;
+                a->core_count    = 1;
+                a->thread_count  = 1;
+                a->core_masks[0] = 1;
+            }
+
+        }
+
+        void zpl_affinity_destroy(zpl_affinity *a) {
+            zpl_unused(a);
+        }
+
+        zpl_b32 zpl_affinity_set(zpl_affinity *a, zpl_isize core, zpl_isize thread) {
+            zpl_usize available_mask, check_mask = 1;
+            ZPL_ASSERT(thread < zpl_affinity_thread_count_for_core(a, core));
+
+            available_mask = a->core_masks[core];
+            for (;;) {
+                if ((available_mask & check_mask) != 0) {
+                    if (thread-- == 0) {
+                        zpl_usize result = SetThreadAffinityMask(GetCurrentThread(), check_mask);
+                        return result != 0;
+                    }
+                }
+                check_mask <<= 1; // NOTE: Onto the next bit
+            }
+        }
+
+        zpl_isize zpl_affinity_thread_count_for_core(zpl_affinity *a, zpl_isize core) {
+            ZPL_ASSERT(core >= 0 && core < a->core_count);
+            return zpl_count_set_bits(a->core_masks[core]);
+        }
+
+    #elif defined(ZPL_SYSTEM_MACOS)
+        void zpl_affinity_init(zpl_affinity *a) {
+            zpl_usize count, count_size = zpl_size_of(count);
+
+            a->is_accurate      = false;
+            a->thread_count     = 1;
+            a->core_count       = 1;
+            a->threads_per_core = 1;
+
+            if (sysctlbyname("hw.logicalcpu", &count, &count_size, NULL, 0) == 0) {
+                if (count > 0) {
+                    a->thread_count = count;
+                    // Get # of physical cores
+                    if (sysctlbyname("hw.physicalcpu", &count, &count_size, NULL, 0) == 0) {
+                        if (count > 0) {
+                            a->core_count = count;
+                            a->threads_per_core = a->thread_count / count;
+                            if (a->threads_per_core < 1)
+                                a->threads_per_core = 1;
+                            else
+                                a->is_accurate = true;
+                        }
+                    }
+                }
+            }
+
+        }
+
+        void zpl_affinity_destroy(zpl_affinity *a) {
+            zpl_unused(a);
+        }
+
+        zpl_b32 zpl_affinity_set(zpl_affinity *a, zpl_isize core, zpl_isize thread_index) {
+            zpl_isize index;
+            thread_t thread;
+            thread_affinity_policy_data_t info;
+            kern_return_t result;
+
+            ZPL_ASSERT(core < a->core_count);
+            ZPL_ASSERT(thread_index < a->threads_per_core);
+
+            index = core * a->threads_per_core + thread_index;
+            thread = mach_thread_self();
+            info.affinity_tag = cast(integer_t)index;
+            result = thread_policy_set(thread, THREAD_AFFINITY_POLICY, cast(thread_policy_t)&info, THREAD_AFFINITY_POLICY_COUNT);
+            return result == KERN_SUCCESS;
+        }
+
+        zpl_isize zpl_affinity_thread_count_for_core(zpl_affinity *a, zpl_isize core) {
+            ZPL_ASSERT(core >= 0 && core < a->core_count);
+            return a->threads_per_core;
+        }
+
+    #elif defined(ZPL_SYSTEM_LINUX) || defined(ZPL_SYSTEM_FREEBSD) || defined(ZPL_SYSTEM_OPENBSD)
+
+        // IMPORTANT TODO: This zpl_affinity stuff for linux needs be improved a lot!
+        // NOTE(zangent): I have to read /proc/cpuinfo to get the number of threads per core.
+
+        void zpl_affinity_init(zpl_affinity *a) {
+            zpl_b32   accurate = true;
+            zpl_isize threads = 0;
+
+            a->thread_count     = 1;
+            a->core_count       = sysconf(_SC_NPROCESSORS_ONLN);
+            a->threads_per_core = 1;
+
+
+            if(a->core_count <= 0) {
+                a->core_count = 1;
+                accurate = false;
+            }
+
+            // Parsing /proc/cpuinfo to get the number of threads per core.
+            // NOTE(zangent): This calls the CPU's threads "cores", although the wording
+            // is kind of weird. This should be right, though.
+            FILE *cpu_info = fopen("/proc/cpuinfo", "r");
+            if (cpu_info != NULL) {
+                for (;;) {
+                    // The 'temporary char'. Everything goes into this char,
+                    // so that we can check against EOF at the end of this loop.
+                    int c;
+
+        #define AF__CHECK(letter) ((c = getc(cpu_info)) == letter)
+                    if (AF__CHECK('c') && AF__CHECK('p') && AF__CHECK('u') && AF__CHECK(' ') &&
+                        AF__CHECK('c') && AF__CHECK('o') && AF__CHECK('r') && AF__CHECK('e') && AF__CHECK('s')) {
+                        // We're on a CPU info line.
+                        while (!AF__CHECK(EOF)) {
+                            if (c == '\n') {
+                                break;
+                            } else if (c < '0' || '9' > c) {
+                                continue;
+                            }
+                            threads = threads * 10 + (c - '0');
+                        }
+                        break;
+                    } else {
+                        while (!AF__CHECK('\n')) {
+                            if (c==EOF) {
+                                break;
+                            }
+                        }
+                    }
+                    if (c == EOF) {
+                        break;
+                    }
+        #undef AF__CHECK
+                }
+
+                fclose(cpu_info);
+            }
+
+            if (threads == 0) {
+                threads  = 1;
+                accurate = false;
+            }
+
+            a->threads_per_core = threads;
+            a->thread_count = a->threads_per_core * a->core_count;
+            a->is_accurate = accurate;
+
+        }
+
+        void zpl_affinity_destroy(zpl_affinity *a) {
+            zpl_unused(a);
+        }
+
+        zpl_b32 zpl_affinity_set(zpl_affinity * a, zpl_isize core, zpl_isize thread_index) {
+            zpl_unused(a);
+            zpl_unused(core);
+            zpl_unused(thread_index);
+            return true;
+        }
+
+        zpl_isize zpl_affinity_thread_count_for_core(zpl_affinity *a, zpl_isize core) {
+            ZPL_ASSERT(0 <= core && core < a->core_count);
+            return a->threads_per_core;
+        }
+
+    #elif defined(ZPL_SYSTEM_EMSCRIPTEN)
+        #error No affinity implementation for Emscripten
+    #else
+        #error TODO: Unknown system
+    #endif
+
+    ZPL_END_C_DECLS
+
+    #if defined(ZPL_MODULE_JOBS)
+        // file: source/jobs.c
+
+        ///////////////////////////////////////////////////////////////
+        //
+        // Thread Pool
+        //
+        #ifdef ZPL_EDITOR
+        #include <zpl.h>
+        #endif
+
+        ZPL_BEGIN_C_DECLS
+
+        zpl_isize zpl__jobs_entry(struct zpl_thread *thread) {
+            zpl_thread_worker *tw = (zpl_thread_worker *)thread->user_data;
+            zpl_thread_pool *pool = (zpl_thread_pool *)tw->pool;
+
+            for (;;) {
+                zpl_u32 status = zpl_atomic32_load(&tw->status);
+
+                switch (status) {
+                    case ZPL_JOBS_STATUS_READY: {
+                        zpl_atomic32_store(&tw->status, ZPL_JOBS_STATUS_BUSY);
+
+                        zpl_mutex_lock(&pool->access);
+                        zpl_thread_job *job = pool->jobs + tw->jobid;
+                        zpl_mutex_unlock(&pool->access);
+
+                        job->proc(job->data);
+
+                        zpl_atomic32_store(&tw->status, ZPL_JOBS_STATUS_WAITING);
+                    } break;
+
+                    case ZPL_JOBS_STATUS_WAITING: {
+                        zpl_yield( );
+                    } break;
+
+                    case ZPL_JOBS_STATUS_TERM: {
+                        return 0;
+                    } break;
+                }
+            }
+
+            return 0;
+        }
+
+        void zpl_jobs_init(zpl_thread_pool *pool, zpl_allocator a, zpl_u32 max_threads) {
+            zpl_thread_pool pool_ = { 0 };
+            *pool = pool_;
+            zpl_mutex_init(&pool->access);
+
+            pool->alloc = a;
+            pool->max_threads = max_threads;
+
+            // NOTE: Spawn a new job slot when number of available slots is below 25%
+            // compared to the total number of slots.
+            pool->job_spawn_treshold = 0.25;
+
+            zpl_buffer_init(pool->workers, a, max_threads);
+            zpl_array_init(pool->jobs, a);
+            zpl_array_init(pool->queue, a);
+            zpl_array_init(pool->available, a);
+
+            for (zpl_usize i = 0; i < max_threads; ++i) {
+                zpl_thread_worker worker_ = { 0 };
+                zpl_thread_worker *tw = pool->workers + i;
+                *tw = worker_;
+
+                zpl_thread_init(&tw->thread);
+                zpl_atomic32_store(&tw->status, ZPL_JOBS_STATUS_WAITING);
+                tw->pool = pool;
+                tw->jobid = ZPL_INVALID_JOB;
+                zpl_thread_start(&tw->thread, zpl__jobs_entry, (void *)tw);
+            }
+        }
+
+        void zpl_jobs_free(zpl_thread_pool *pool) {
+            for (zpl_usize i = 0; i < pool->max_threads; ++i) {
+                zpl_thread_worker *tw = pool->workers + i;
+
+                zpl_atomic32_store(&tw->status, ZPL_JOBS_STATUS_TERM);
+                zpl_thread_destroy(&tw->thread);
+            }
+
+            zpl_buffer_free(pool->workers);
+            zpl_array_free(pool->jobs);
+            zpl_array_free(pool->queue);
+            zpl_array_free(pool->available);
+        }
+
+        void zpl_jobs_enqueue_with_priority(zpl_thread_pool *pool, zpl_jobs_proc proc, void *data, zpl_f32 priority) {
+            ZPL_ASSERT_NOT_NULL(proc);
+            zpl_f32 treshold = 0.0f;
+
+            if (zpl_array_count(pool->queue) > 0) {
+                treshold = (zpl_array_count(pool->available) / (zpl_f32)zpl_array_count(pool->jobs));
+            }
+
+            if (treshold <= pool->job_spawn_treshold) {
+                zpl_thread_job job = { 0 };
+                job.proc = proc;
+                job.data = data;
+                job.priority = priority;
+
+                zpl_array_append(pool->jobs, job);
+                zpl_u32 jobid = (zpl_u32)zpl_array_count(pool->jobs) - 1;
+                zpl_array_append(pool->queue, jobid);
+            } else {
+                zpl_u32 jobid = zpl_array_back(pool->available);
+                zpl_thread_job *jp = pool->jobs + jobid;
+                zpl_array_pop(pool->available);
+
+                jp->proc = proc;
+                jp->data = data;
+                jp->priority = priority;
+
+                zpl_array_append(pool->queue, jobid);
+            }
+        }
+
+        void zpl_jobs_enqueue(zpl_thread_pool *pool, zpl_jobs_proc proc, void *data) {
+            ZPL_ASSERT_NOT_NULL(proc);
+            zpl_jobs_enqueue_with_priority(pool, proc, data, 1.0f);
+        }
+
+        zpl_thread_local zpl_thread_pool *zpl__thread_pool;
+
+        ZPL_COMPARE_PROC(zpl___jobs_cmp) {
+            zpl_thread_job *p = (zpl_thread_job *)(zpl__thread_pool->jobs + *(zpl_u32 *)a);
+            zpl_thread_job *q = (zpl_thread_job *)(zpl__thread_pool->jobs + *(zpl_u32 *)b);
+            return cast(zpl_i32)(p->priority < q->priority ? 1.0f : p->priority > q->priority);
+        }
+
+        ZPL_COMPARE_PROC_PTR(zpl__jobs_cmp(zpl_thread_pool *pool)) {
+            zpl__thread_pool = pool;
+            return &zpl___jobs_cmp;
+        }
+
+        zpl_b32 zpl_jobs_process(zpl_thread_pool *pool) {
+            // NOTE: Sort the queue based on the job priority
+            if (zpl_array_count(pool->queue)) {
+                zpl_sort_array(pool->queue, zpl_array_count(pool->queue), zpl__jobs_cmp(pool));
+            }
+
+            // NOTE: Process the jobs
+            for (zpl_usize i = 0; i < pool->max_threads; ++i) {
+                zpl_thread_worker *tw = pool->workers + i;
+                if (zpl_array_count(pool->queue) == 0) return false;
+
+                zpl_u32 status = zpl_atomic32_load(&tw->status);
+
+                if (status == ZPL_JOBS_STATUS_WAITING) {
+                    if (tw->jobid != ZPL_INVALID_JOB) { zpl_array_append(pool->available, tw->jobid); }
+
+                    zpl_u32 jobid = *pool->queue;
+                    zpl_array_remove_at(pool->queue, 0);
+                    tw->jobid = jobid;
+                    zpl_atomic32_store(&tw->status, ZPL_JOBS_STATUS_READY);
+                }
+            }
+
+            return true;
+        }
+
+        ZPL_END_C_DECLS
+    #endif
+
+    #if defined(ZPL_MODULE_COROUTINES)
+        // file: source/coroutines.c
+
+        ////////////////////////////////////////////////////////////////
+        //
+        // Coroutines
+        //
+        //
+        #ifdef ZPL_EDITOR
+        #include <zpl.h>
+        #endif
+
+        ZPL_BEGIN_C_DECLS
+
+        struct {
+            zpl_b32 is_ready;
+            zpl_thread_pool coroutines;
+            zpl_thread runner;
+            zpl_atomic32 request_term;
+            zpl_mutex is_processing;
+        } zpl__co_internals;
+
+        zpl_thread_local zpl_u8 zpl__co_yield_barrier;
+
+        zpl_isize zpl__co_runner(struct zpl_thread *t) {
+            do {
+                if (zpl_atomic32_load(&zpl__co_internals.request_term))
+                    break;
+
+                zpl_b32 lock = zpl_mutex_try_lock(&zpl__co_internals.is_processing);
+
+                while (!lock) {
+                    zpl_yield_thread();
+                    lock = zpl_mutex_try_lock(&zpl__co_internals.is_processing);
+
+                    if (zpl_atomic32_load(&zpl__co_internals.request_term))
+                        break;
+
+                    zpl_mfence();
+                }
+
+                zpl_jobs_process(&zpl__co_internals.coroutines);
+                zpl_mutex_unlock(&zpl__co_internals.is_processing);
+            } while (1);
+
+            return 0;
+        }
+
+        void zpl__co_job(void *data) {
+            zpl_co *co = cast(zpl_co *)data;
+
+            zpl_atomic32_store(&co->status, ZPL_CO_RUNNING);
+            co->f(co);
+            zpl_atomic32_store(&co->status, ZPL_CO_DEAD);
+        }
+
+        void zpl_co_init(zpl_allocator a, zpl_u32 max_threads) {
+            if (!zpl__co_internals.is_ready) {
+                zpl_zero_item(&zpl__co_internals);
+                zpl_mutex_init(&zpl__co_internals.is_processing);
+                zpl_jobs_init(&zpl__co_internals.coroutines, a, max_threads);
+                zpl_thread_init(&zpl__co_internals.runner);
+                zpl_thread_start(&zpl__co_internals.runner, zpl__co_runner, NULL);
+                zpl_atomic32_store(&zpl__co_internals.request_term, 0);
+                zpl__co_internals.is_ready = 1;
+
+                // Set up a barrier so that we won't let user call zpl_co_yield in a main thread.
+                zpl__co_yield_barrier = 1;
+            }
+        }
+
+        void zpl_co_destroy(void) {
+            zpl_atomic32_exchange(&zpl__co_internals.request_term, 1);
+            zpl_thread_destroy(&zpl__co_internals.runner);
+            zpl_mutex_destroy(&zpl__co_internals.is_processing);
+            zpl_jobs_free(&zpl__co_internals.coroutines);
+            zpl__co_internals.is_ready = 0;
+            zpl_mfence();
+        }
+
+        void zpl_co_make(zpl_co *co, zpl_co_proc f) {
+            ZPL_ASSERT_MSG(zpl__co_internals.is_ready, "Coroutines module is not initialized. Call zpl_co_init first!");
+            ZPL_ASSERT_NOT_NULL(co);
+
+            zpl_zero_item(co);
+            co->f = f;
+            zpl_atomic32_store(&co->status, ZPL_CO_READY);
+            zpl_atomic32_store(&co->resume, 0);
+        }
+
+        void zpl_co_resume(zpl_co *co, void *data) {
+            ZPL_ASSERT_NOT_NULL(co);
+
+            if (data != NULL) {
+                zpl_atomic32_store(&co->push_arg, 1);
+                co->data_stack[co->data_write_idx++] = data;
+                zpl_atomic32_spin_unlock(&co->push_arg);
+                zpl_mfence();
+            }
+
+            zpl_i32 status = zpl_atomic32_load(&co->status);
+
+            // Initialize a job
+            if (status == ZPL_CO_READY) {
+
+                if (data)
+                    co->data = co->data_stack[co->data_read_idx++];
+
+                zpl_atomic32_store(&co->status, ZPL_CO_ENQUEUED);
+                zpl_mfence();
+
+                zpl_mutex_lock(&zpl__co_internals.is_processing);
+                zpl_jobs_enqueue(&zpl__co_internals.coroutines, zpl__co_job, cast(void *)co);
+                zpl_mutex_unlock(&zpl__co_internals.is_processing);
+            }
+            else {
+                zpl_atomic32_fetch_add(&co->resume, 1);
+                zpl_mfence();
+            }
+        }
+
+        void zpl_co_yield(zpl_co *co) {
+            zpl_i32 value;
+            ZPL_ASSERT_NOT_NULL(co);
+            ZPL_ASSERT_MSG((!zpl__co_yield_barrier), "zpl_co_yield can only be called inside of coroutines!");
+
+            zpl_atomic32_store(&co->status, ZPL_CO_WAITING);
+
+            value = zpl_atomic32_load(&co->resume);
+
+            while (value == 0) {
+                zpl_yield_thread();
+                value = zpl_atomic32_load(&co->resume);
+                zpl_mfence();
+            }
+
+            zpl_atomic32_spin_lock(&co->push_arg, -1);
+            co->data = co->data_stack[co->data_read_idx++];
+
+            // null pointer is present, no arg is found, so return back by 1 index
+            if (co->data == NULL) {
+                co->data_read_idx--;
+            }
+
+            zpl_atomic32_spin_unlock(&co->push_arg);
+
+            zpl_atomic32_store(&co->status, ZPL_CO_RUNNING);
+            zpl_atomic32_fetch_add(&co->resume, -1);
+        }
+
+        ZPL_END_C_DECLS
+    #endif
+#endif
+
+
+#if defined(ZPL_COMPILER_MSVC)
+    #pragma warning(pop)
+#endif
+
+#if defined(__GCC__) || defined(__GNUC__) || defined(__clang__)
+    #pragma GCC diagnostic pop
+#endif
+
+#endif // ZPL_IMPLEMENTATION
+
+#if defined(ZPL_EXPOSE_TYPES)
+    typedef zpl_u8 u8;
+    typedef zpl_i8 i8;
+    typedef zpl_u16 u16;
+    typedef zpl_i16 i16;
+    typedef zpl_u32 u32;
+    typedef zpl_i32 i32;
+    typedef zpl_u64 u64;
+    typedef zpl_i64 i64;
+    typedef zpl_b8 b8;
+    typedef zpl_b16 b16;
+    typedef zpl_b32 b32;
+    typedef zpl_f32 f32;
+    typedef zpl_f64 f64;
+    typedef zpl_rune rune;
+    typedef zpl_usize usize;
+    typedef zpl_isize isize;
+    typedef zpl_uintptr uintptr;
+    typedef zpl_intptr intptr;
+#endif // ZPL_EXPOSE_TYPES
+
+#endif // ZPL_H
+
+// TOC:
+// zpl.h
+// zpl_hedley.h
+// header/core/system.h
+// header/core/types.h
+// header/core/helpers.h
+// header/core/debug.h
+// header/core/memory.h
+// header/core/memory_virtual.h
+// header/core/memory_custom.h
+// header/core/collections/array.h
+// header/core/collections/buffer.h
+// header/core/collections/list.h
+// header/core/collections/ring.h
+// header/core/collections/hashtable.h
+// header/core/string.h
+// header/core/stringlib.h
+// header/core/file.h
+// header/core/file_stream.h
+// header/core/file_misc.h
+// header/core/print.h
+// header/core/time.h
+// header/core/random.h
+// header/core/misc.h
+// header/core/sort.h
+// header/timer.h
+// header/hashing.h
+// header/regex.h
+// header/event.h
+// header/dll.h
+// header/opts.h
+// header/process.h
+// header/math.h
+// header/json.h
+// header/threading/atomic.h
+// header/threading/fence.h
+// header/threading/sem.h
+// header/threading/mutex.h
+// header/threading/thread.h
+// header/threading/sync.h
+// header/threading/affinity.h
+// header/jobs.h
+// header/coroutines.h
+// source/core/debug.c
+// source/core/memory.c
+// source/core/memory_virtual.c
+// source/core/memory_custom.c
+// source/core/array.c
+// source/core/string.c
+// source/core/stringlib.c
+// source/core/file.c
+// source/core/file_stream.c
+// source/core/file_misc.c
+// source/core/print.c
+// source/core/time.c
+// source/core/random.c
+// source/core/misc.c
+// source/core/sort.c
+// source/timer.c
+// source/hashing.c
+// source/regex.c
+// source/event.c
+// source/dll.c
+// source/opts.c
+// source/process.c
+// source/math.c
+// source/json.c
+// source/threading/atomic.c
+// source/threading/fence.c
+// source/threading/sem.c
+// source/threading/mutex.c
+// source/threading/thread.c
+// source/threading/sync.c
+// source/threading/affinity.c
+// source/jobs.c
+// source/coroutines.c