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sync with FWK

main
Dominik Madarász 2023-10-08 20:07:13 +02:00
parent 66867deae6
commit 97d8500237
25 changed files with 47927 additions and 131799 deletions
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BIN
engine/bind/lua
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100
engine/bind/v4k.lua
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@ -1494,6 +1494,7 @@ ffi.cdef([[
//lcpp INF [0000] vec3: macro name but used as C declaration in:API void light_dir(light_t* l, vec3 dir);
//lcpp INF [0000] vec3: macro name but used as C declaration in:STATIC void light_dir(light_t* l, vec3 dir);
//lcpp INF [0000] vec3: macro name but used as C declaration in: void light_dir(light_t* l, vec3 dir);
//lcpp INF [0000] vec2i: macro name but used as C declaration in:vec2i* entries;
//lcpp INF [0000] vec3i: macro name but used as C declaration in:typedef vec3i guid;
//lcpp INF [0000] test: macro name but used as C declaration in:API int (test)(const char *file, int line, const char *expr, bool result);
//lcpp INF [0000] test: macro name but used as C declaration in:STATIC int (test)(const char *file, int line, const char *expr, bool result);
@ -1917,6 +1918,77 @@ AUDIO_MULTIPLE_INSTANCES = 0,
AUDIO_SINGLE_INSTANCE = 512,
};
int audio_queue( const void *samples, int num_samples, int flags );
enum COMPRESS_FLAGS {
COMPRESS_RAW = 0,
COMPRESS_PPP = (1<<4),
COMPRESS_ULZ = (2<<4),
COMPRESS_LZ4 = (3<<4),
COMPRESS_CRUSH = (4<<4),
COMPRESS_DEFLATE = (5<<4),
COMPRESS_LZP1 = (6<<4),
COMPRESS_LZMA = (7<<4),
COMPRESS_BALZ = (8<<4),
COMPRESS_LZW3 = (9<<4),
COMPRESS_LZSS = (10<<4),
COMPRESS_BCM = (11<<4),
COMPRESS_ZLIB = (12<<4),
};
unsigned zbounds(unsigned inlen, unsigned flags);
unsigned zencode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
unsigned zexcess(unsigned flags);
unsigned zdecode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
unsigned cobs_bounds(unsigned len);
unsigned cobs_encode(const void *in, unsigned inlen, void *out, unsigned outlen);
unsigned cobs_decode(const void *in, unsigned inlen, void *out, unsigned outlen);
uint64_t pack754(long double f, unsigned bits, unsigned expbits);
long double unpack754(uint64_t i, unsigned bits, unsigned expbits);
int msgpack(const char *fmt, ... );
bool msgunpack(const char *fmt, ... );
int msgpack_new(uint8_t *w, size_t l);
int msgpack_nil();
int msgpack_chr(bool n);
int msgpack_uns(uint64_t n);
int msgpack_int(int64_t n);
int msgpack_str(const char *s);
int msgpack_bin(const char *s, size_t n);
int msgpack_flt(double g);
int msgpack_ext(uint8_t key, void *val, size_t n);
int msgpack_arr(uint32_t n);
int msgpack_map(uint32_t n);
int msgpack_eof();
int msgpack_err();
bool msgunpack_new( const void *opaque_or_FILE, size_t bytes );
bool msgunpack_nil();
bool msgunpack_chr(bool *chr);
bool msgunpack_uns(uint64_t *uns);
bool msgunpack_int(int64_t *sig);
bool msgunpack_str(char **str);
bool msgunpack_bin(void **bin, uint64_t *len);
bool msgunpack_flt(float *flt);
bool msgunpack_dbl(double *dbl);
bool msgunpack_ext(uint8_t *key, void **val, uint64_t *len);
bool msgunpack_arr(uint64_t *len);
bool msgunpack_map(uint64_t *len);
bool msgunpack_eof();
bool msgunpack_err();
enum {
ERR,NIL,BOL,UNS,SIG,STR,BIN,FLT,EXT,ARR,MAP
};
typedef struct variant {
union {
uint8_t chr;
uint64_t uns;
int64_t sig;
uint8_t *str;
void *bin;
double flt;
uint32_t u32;
};
uint64_t sz;
uint16_t ext;
uint16_t type;
} variant;
bool msgunpack_var(struct variant *var);
typedef struct gjk_support {
int aid, bid;
vec3 a;
@ -2049,25 +2121,6 @@ typedef union json_t { char* s; double f; int64_t i; uintptr_t p; union json_t*
char* xml_blob(char *key);
void xml_pop();
bool data_tests();
enum COMPRESS_FLAGS {
COMPRESS_RAW = 0,
COMPRESS_PPP = (1<<4),
COMPRESS_ULZ = (2<<4),
COMPRESS_LZ4 = (3<<4),
COMPRESS_CRUSH = (4<<4),
COMPRESS_DEFLATE = (5<<4),
COMPRESS_LZP1 = (6<<4),
COMPRESS_LZMA = (7<<4),
COMPRESS_BALZ = (8<<4),
COMPRESS_LZW3 = (9<<4),
COMPRESS_LZSS = (10<<4),
COMPRESS_BCM = (11<<4),
COMPRESS_ZLIB = (12<<4),
};
unsigned zbounds(unsigned inlen, unsigned flags);
unsigned zencode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
unsigned zexcess(unsigned flags);
unsigned zdecode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
void* dll(const char *filename, const char *symbol);
vec3 editor_pick(float mouse_x, float mouse_y);
char* editor_path(const char *path);
@ -2165,6 +2218,10 @@ FONT_CJK = FONT_ZH|FONT_JP|FONT_KR,
vec2 font_rect(const char *text);
void* font_colorize(const char *text, const char *comma_types, const char *comma_keywords);
vec2 font_highlight(const char *text, const void *colors);
uintptr_t id_make(void *ptr);
void * id_handle(uintptr_t id);
void id_dispose(uintptr_t id);
bool id_valid(uintptr_t id);
int input_use( int controller_id );
float input( int vk );
vec2 input2( int vk );
@ -2888,7 +2945,10 @@ int u_coefficients_sh;
uint32_t* string32( const char *utf8 );
unsigned intern( const char *string );
const char *quark( unsigned key );
typedef char* quarks_db;
typedef struct quarks_db {
char* blob;
vec2i* entries;
} quarks_db;
unsigned quark_intern( quarks_db*, const char *string );
const char *quark_string( quarks_db*, unsigned key );
uint64_t date();

29446
engine/joint/v4k.h
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27993
engine/split/3rd_miniaudio.h
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91290
engine/split/d.h
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16
engine/split/v4k.c.inl
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@ -89,18 +89,22 @@
#include "v4k.h"
#endif
#if is(win32) // hack to boost exit time. there are no critical systems that need to shutdown properly on Windows,
#define atexit(...) // however Linux needs proper atexit() to deinitialize 3rd_miniaudio.h; likely OSX as well.
#endif
#ifndef V4K_3RD
#define V4K_3RD
#include "v4k"
#endif
#define do_threadlock(mutexptr) \
for( int init_ = !!(mutexptr) || (thread_mutex_init( (mutexptr) = CALLOC(1, sizeof(thread_mutex_t)) ), 1); init_; init_ = 0) \
for( int lock_ = (thread_mutex_lock( mutexptr ), 1); lock_; lock_ = (thread_mutex_unlock( mutexptr ), 0) )
//-----------------------------------------------------------------------------
// C files
#if is(win32) // hack to boost exit time. there are no critical systems that need to shutdown properly on Windows,
#define atexit(...) // however Linux needs proper atexit() to deinitialize 3rd_miniaudio.h; likely OSX as well.
#endif
{{FILE:v4k_ds.c}}
{{FILE:v4k_string.c}}
@ -109,6 +113,8 @@
{{FILE:v4k_audio.c}}
{{FILE:v4k_buffer.c}}
{{FILE:v4k_collide.c}}
{{FILE:v4k_cooker.c}}
@ -143,6 +149,8 @@
{{FILE:v4k_system.c}}
{{FILE:v4k_id.c}}
{{FILE:v4k_ui.c}}
{{FILE:v4k_profile.c}}

4
engine/split/v4k.h.inl
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@ -108,6 +108,8 @@ extern "C" {
{{FILE:v4k_audio.h}}
{{FILE:v4k_buffer.h}}
{{FILE:v4k_collide.h}}
{{FILE:v4k_cooker.h}}
@ -122,6 +124,8 @@ extern "C" {
{{FILE:v4k_font.h}}
{{FILE:v4k_id.h}}
{{FILE:v4k_input.h}}
{{FILE:v4k_memory.h}}

4
engine/split/v4k.x.inl
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@ -113,6 +113,7 @@ errno_t fopen_s(
#undef error
#undef DEBUG
#define MA_DEBUG_OUTPUT
// #define MA_USE_AUDIO_WORKLETS
{{FILE:3rd_sts_mixer.h}}
{{FILE:3rd_miniaudio.h}}
//---
@ -148,6 +149,9 @@ errno_t fopen_s(
{{FILE:3rd_gjk.h}}
{{FILE:3rd_compress.h}}
{{FILE:3rd_archive.h}}
#if is(win32)
#include <mmsystem.h> // timeapi.h
#endif
{{FILE:3rd_thread.h}}
{{FILE:3rd_plmpeg.h}}
{{FILE:3rd_jo_mpeg.h}}

42
engine/split/v4k_audio.c
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@ -1,4 +1,4 @@
// @fixme: really shutdown audio & related threads before quitting. drwav crashes.
// @fixme: really shutdown audio & related threads before quitting. ma_dr_wav crashes.
#if is(win32) && !is(gcc)
@ -54,15 +54,15 @@ void midi_send(unsigned midi_msg) {
#endif
}
// encapsulate drwav,drmp3,stbvorbis and some buffer with the sts_mixer_stream_t
// encapsulate ma_dr_wav,ma_dr_mp3,stbvorbis and some buffer with the sts_mixer_stream_t
enum { UNK, WAV, OGG, MP1, MP3 };
typedef struct {
int type;
union {
drwav wav;
ma_dr_wav wav;
stb_vorbis *ogg;
void *opaque;
drmp3 mp3_;
ma_dr_mp3 mp3_;
};
sts_mixer_stream_t stream; // mixer stream
union {
@ -100,16 +100,16 @@ static void refill_stream(sts_mixer_sample_t* sample, void* userdata) {
default:
break; case WAV: {
int sl = sample->length / 2; /*sample->channels*/;
if( stream->rewind ) stream->rewind = 0, drwav_seek_to_pcm_frame(&stream->wav, 0);
if (drwav_read_pcm_frames_s16(&stream->wav, sl, (short*)stream->data) < sl) {
drwav_seek_to_pcm_frame(&stream->wav, 0);
if( stream->rewind ) stream->rewind = 0, ma_dr_wav_seek_to_pcm_frame(&stream->wav, 0);
if (ma_dr_wav_read_pcm_frames_s16(&stream->wav, sl, (short*)stream->data) < sl) {
ma_dr_wav_seek_to_pcm_frame(&stream->wav, 0);
}
}
break; case MP3: {
int sl = sample->length / 2; /*sample->channels*/;
if( stream->rewind ) stream->rewind = 0, drmp3_seek_to_pcm_frame(&stream->mp3_, 0);
if (drmp3_read_pcm_frames_f32(&stream->mp3_, sl, stream->dataf) < sl) {
drmp3_seek_to_pcm_frame(&stream->mp3_, 0);
if( stream->rewind ) stream->rewind = 0, ma_dr_mp3_seek_to_pcm_frame(&stream->mp3_, 0);
if (ma_dr_mp3_read_pcm_frames_f32(&stream->mp3_, sl, stream->dataf) < sl) {
ma_dr_mp3_seek_to_pcm_frame(&stream->mp3_, 0);
}
}
break; case OGG: {
@ -140,14 +140,14 @@ static bool load_stream(mystream_t* stream, const char *filename) {
stream->stream.sample.frequency = info.sample_rate;
stream->stream.sample.audio_format = STS_MIXER_SAMPLE_FORMAT_16;
}
if( stream->type == UNK && drwav_init_memory(&stream->wav, data, datalen, NULL)) {
if( stream->type == UNK && ma_dr_wav_init_memory(&stream->wav, data, datalen, NULL)) {
if( stream->wav.channels != 2 ) { puts("cannot stream wav file. stereo required."); goto end; } // @fixme: upsample
stream->type = WAV;
stream->stream.sample.frequency = stream->wav.sampleRate;
stream->stream.sample.audio_format = STS_MIXER_SAMPLE_FORMAT_16;
}
drmp3_config mp3_cfg = { 2, HZ };
if( stream->type == UNK && (drmp3_init_memory(&stream->mp3_, data, datalen, NULL/*&mp3_cfg*/) != 0) ) {
ma_dr_mp3_config mp3_cfg = { 2, HZ };
if( stream->type == UNK && (ma_dr_mp3_init_memory(&stream->mp3_, data, datalen, NULL/*&mp3_cfg*/) != 0) ) {
stream->type = MP3;
stream->stream.sample.frequency = stream->mp3_.sampleRate;
stream->stream.sample.audio_format = STS_MIXER_SAMPLE_FORMAT_FLOAT;
@ -175,14 +175,14 @@ static bool load_sample(sts_mixer_sample_t* sample, const char *filename) {
int error;
int channels = 0;
if( !channels ) for( drwav w = {0}, *wav = &w; wav && drwav_init_memory(wav, data, datalen, NULL); wav = 0 ) {
if( !channels ) for( ma_dr_wav w = {0}, *wav = &w; wav && ma_dr_wav_init_memory(wav, data, datalen, NULL); wav = 0 ) {
channels = wav->channels;
sample->frequency = wav->sampleRate;
sample->audio_format = STS_MIXER_SAMPLE_FORMAT_16;
sample->length = wav->totalPCMFrameCount;
sample->data = REALLOC(0, sample->length * sizeof(short) * channels);
drwav_read_pcm_frames_s16(wav, sample->length, (short*)sample->data);
drwav_uninit(wav);
ma_dr_wav_read_pcm_frames_s16(wav, sample->length, (short*)sample->data);
ma_dr_wav_uninit(wav);
}
if( !channels ) for( stb_vorbis *ogg = stb_vorbis_open_memory((const unsigned char *)data, datalen, &error, NULL); ogg; ogg = 0 ) {
stb_vorbis_info info = stb_vorbis_get_info(ogg);
@ -197,9 +197,9 @@ static bool load_sample(sts_mixer_sample_t* sample, const char *filename) {
stb_vorbis_decode_memory((const unsigned char *)data, datalen, &channels, &sample_rate, (short **)&buffer);
sample->data = buffer;
}
drmp3_config mp3_cfg = { 2, 44100 };
drmp3_uint64 mp3_fc;
if( !channels ) for( short *fbuf = drmp3_open_memory_and_read_pcm_frames_s16(data, datalen, &mp3_cfg, &mp3_fc, NULL); fbuf ; fbuf = 0 ) {
ma_dr_mp3_config mp3_cfg = { 2, 44100 };
ma_uint64 mp3_fc;
if( !channels ) for( short *fbuf = ma_dr_mp3_open_memory_and_read_pcm_frames_s16(data, datalen, &mp3_cfg, &mp3_fc, NULL); fbuf ; fbuf = 0 ) {
channels = mp3_cfg.channels;
sample->frequency = mp3_cfg.sampleRate;
sample->audio_format = STS_MIXER_SAMPLE_FORMAT_16;
@ -281,8 +281,8 @@ int audio_init( int flags ) {
ma_backend_oss,
ma_backend_jack,
ma_backend_opensl,
ma_backend_webaudio,
//ma_backend_openal,
// ma_backend_webaudio,
// ma_backend_openal,
//ma_backend_sdl,
ma_backend_null // Lowest priority.
#else

915
engine/split/v4k_buffer.c 100644
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@ -0,0 +1,915 @@
// ----------------------------------------------------------------------------
// compression api
static struct zcompressor {
// id of compressor
unsigned enumerator;
// name of compressor
const char name1, *name4, *name;
// returns worst case compression estimation for selected flags
unsigned (*bounds)(unsigned bytes, unsigned flags);
// returns number of bytes written. 0 if error.
unsigned (*encode)(const void *in, unsigned inlen, void *out, unsigned outcap, unsigned flags);
// returns number of excess bytes that will be overwritten when decoding.
unsigned (*excess)(unsigned flags);
// returns number of bytes written. 0 if error.
unsigned (*decode)(const void *in, unsigned inlen, void *out, unsigned outcap);
} zlist[] = {
{ COMPRESS_RAW, '0', "raw", "raw", raw_bounds, raw_encode, raw_excess, raw_decode },
{ COMPRESS_PPP, 'p', "ppp", "ppp", ppp_bounds, ppp_encode, ppp_excess, ppp_decode },
{ COMPRESS_ULZ, 'u', "ulz", "ulz", ulz_bounds, ulz_encode, ulz_excess, ulz_decode },
{ COMPRESS_LZ4, '4', "lz4x", "lz4x", lz4x_bounds, lz4x_encode, lz4x_excess, lz4x_decode },
{ COMPRESS_CRUSH, 'c', "crsh", "crush", crush_bounds, crush_encode, crush_excess, crush_decode },
{ COMPRESS_DEFLATE, 'd', "defl", "deflate", deflate_bounds, deflate_encode, deflate_excess, deflate_decode },
{ COMPRESS_LZP1, '1', "lzp1", "lzp1", lzp1_bounds, lzp1_encode, lzp1_excess, lzp1_decode },
{ COMPRESS_LZMA, 'm', "lzma", "lzma", lzma_bounds, lzma_encode, lzma_excess, lzma_decode },
{ COMPRESS_BALZ, 'b', "balz", "balz", balz_bounds, balz_encode, balz_excess, balz_decode },
{ COMPRESS_LZW3, 'w', "lzw3", "lzrw3a", lzrw3a_bounds, lzrw3a_encode, lzrw3a_excess, lzrw3a_decode },
{ COMPRESS_LZSS, 's', "lzss", "lzss", lzss_bounds, lzss_encode, lzss_excess, lzss_decode },
{ COMPRESS_BCM, 'B', "bcm", "bcm", bcm_bounds, bcm_encode, bcm_excess, bcm_decode },
{ COMPRESS_ZLIB, 'z', "zlib", "zlib", deflate_bounds, deflatez_encode, deflate_excess, deflatez_decode },
};
enum { COMPRESS_NUM = 14 };
static char *znameof(unsigned flags) {
static __thread char buf[16];
snprintf(buf, 16, "%4s.%c", zlist[(flags>>4)&0x0F].name4, "0123456789ABCDEF"[flags&0xF]);
return buf;
}
unsigned zencode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].encode(in, inlen, (uint8_t*)out, outlen, flags & 0x0F);
}
unsigned zdecode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].decode((uint8_t*)in, inlen, out, outlen);
}
unsigned zbounds(unsigned inlen, unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].bounds(inlen, flags & 0x0F);
}
unsigned zexcess(unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].excess(flags & 0x0F);
}
// ----------------------------------------------------------------------------
// cobs en/decoding
//
// Based on code by Jacques Fortier.
// "Redistribution and use in source and binary forms are permitted, with or without modification."
//
// Consistent Overhead Byte Stuffing is an encoding that removes all 0 bytes from arbitrary binary data.
// The encoded data consists only of bytes with values from 0x01 to 0xFF. This is useful for preparing data for
// transmission over a serial link (RS-232 or RS-485 for example), as the 0 byte can be used to unambiguously indicate
// packet boundaries. COBS also has the advantage of adding very little overhead (at least 1 byte, plus up to an
// additional byte per 254 bytes of data). For messages smaller than 254 bytes, the overhead is constant.
//
// This implementation is designed to be both efficient and robust.
// The decoder is designed to detect malformed input data and report an error upon detection.
unsigned cobs_bounds( unsigned len ) {
return len + ceil(len / 254.0) + 1;
}
unsigned cobs_encode(const void *in, unsigned inlen, void *out, unsigned outlen) {
const uint8_t *src = (const uint8_t *)in;
uint8_t *dst = (uint8_t*)out;
size_t srclen = inlen;
uint8_t code = 1;
size_t read_index = 0, write_index = 1, code_index = 0;
while( read_index < srclen ) {
if( src[ read_index ] == 0) {
dst[ code_index ] = code;
code = 1;
code_index = write_index++;
read_index++;
} else {
dst[ write_index++ ] = src[ read_index++ ];
code++;
if( code == 0xFF ) {
dst[ code_index ] = code;
code = 1;
code_index = write_index++;
}
}
}
dst[ code_index ] = code;
return write_index;
}
unsigned cobs_decode(const void *in, unsigned inlen, void *out, unsigned outlen) {
const uint8_t *src = (const uint8_t *)in;
uint8_t *dst = (uint8_t*)out;
size_t srclen = inlen;
uint8_t code, i;
size_t read_index = 0, write_index = 0;
while( read_index < srclen ) {
code = src[ read_index ];
if( ((read_index + code) > srclen) && (code != 1) ) {
return 0;
}
read_index++;
for( i = 1; i < code; i++ ) {
dst[ write_index++ ] = src[ read_index++ ];
}
if( (code != 0xFF) && (read_index != srclen) ) {
dst[ write_index++ ] = '\0';
}
}
return write_index;
}
#if 0
static
void cobs_test( const char *buffer, int buflen ) {
char enc[4096];
int enclen = cobs_encode( buffer, buflen, enc, 4096 );
char dec[4096];
int declen = cobs_decode( enc, enclen, dec, 4096 );
test( enclen >= buflen );
test( declen == buflen );
test( memcmp(dec, buffer, buflen) == 0 );
printf("%d->%d->%d (+%d extra bytes)\n", declen, enclen, declen, enclen - declen);
}
AUTORUN {
const char *null = 0;
cobs_test( null, 0 );
const char empty[] = "";
cobs_test( empty, sizeof(empty) );
const char text[] = "hello world\n";
cobs_test( text, sizeof(text) );
const char bintext[] = "hello\0\0\0world\n";
cobs_test( bintext, sizeof(bintext) );
const char blank[512] = {0};
cobs_test( blank, sizeof(blank) );
char longbintext[1024];
for( int i = 0; i < 1024; ++i ) longbintext[i] = (unsigned char)i;
cobs_test( longbintext, sizeof(longbintext) );
assert(~puts("Ok"));
}
#endif
// ----------------------------------------------------------------------------
// float un/packing: 8 (micro), 16 (half), 32 (float), 64 (double) types
// - rlyeh, public domain. original code by Beej.us (PD).
//
// [src] http://beej.us/guide/bgnet/output/html/multipage/advanced.html#serialization
// Modified to encode NaN and Infinity as well.
//
// [1] http://www.mrob.com/pub/math/floatformats.html#minifloat
// [2] microfloat: [0.002 to 240] range.
// [3] half float: can approximate any 16-bit unsigned integer or its reciprocal to 3 decimal places.
uint64_t pack754(long double f, unsigned bits, unsigned expbits) {
long double fnorm;
int shift;
long long sign, exp, significand;
unsigned significandbits = bits - expbits - 1; // -1 for sign bit
if (f == 0.0) return 0; // get this special case out of the way
//< @r-lyeh beware! works for 32/64 only
else if (f == INFINITY) return 0x7f800000ULL << (bits - 32); // 0111 1111 1000
else if (f == -INFINITY) return 0xff800000ULL << (bits - 32);
else if (f != f) return 0x7fc00000ULL << (bits - 32); // 0111 1111 1100 NaN
//< @r-lyeh
// check sign and begin normalization
if (f < 0) { sign = 1; fnorm = -f; }
else { sign = 0; fnorm = f; }
// get the normalized form of f and track the exponent
shift = 0;
while(fnorm >= 2.0) { fnorm /= 2.0; shift++; }
while(fnorm < 1.0) { fnorm *= 2.0; shift--; }
fnorm = fnorm - 1.0;
// calculate the binary form (non-float) of the significand data
significand = fnorm * ((1LL<<significandbits) + 0.5f);
// get the biased exponent
exp = shift + ((1<<(expbits-1)) - 1); // shift + bias
// return the final answer
return (sign<<(bits-1)) | (exp<<(bits-expbits-1)) | significand;
}
long double unpack754(uint64_t i, unsigned bits, unsigned expbits) {
long double result;
long long shift;
unsigned bias;
unsigned significandbits = bits - expbits - 1; // -1 for sign bit
if (i == 0) return 0.0;
//< @r-lyeh beware! works for 32 only
else if (i == 0x7fc00000ULL) return NAN; // NaN
else if (i == 0x7f800000ULL) return INFINITY; // +Inf
else if (i == 0xff800000ULL) return -INFINITY; // -Inf
//< @r-lyeh
// pull the significand
result = (i&((1LL<<significandbits)-1)); // mask
result /= (1LL<<significandbits); // convert back to float
result += 1.0f; // add the one back on
// deal with the exponent
bias = (1<<(expbits-1)) - 1;
shift = ((i>>significandbits)&((1LL<<expbits)-1)) - bias;
while(shift > 0) { result *= 2.0; shift--; }
while(shift < 0) { result /= 2.0; shift++; }
// sign it
result *= (i>>(bits-1))&1? -1.0: 1.0;
return result;
}
// ----------------------------------------------------------------------------
// msgpack v5, schema based struct/buffer bitpacking
// - rlyeh, public domain.
//
// [ref] https://github.com/msgpack/msgpack/blob/master/spec.md
//
// @todo: finish msgunpack()
// @todo: alt api v3
// return number of bytes written; 0 if not space enough.
// int msgpack( uint8_t *buf, const char *fmt, ... ); // if !buf, bulk size; else pack.
// return number of processed bytes; 0 if parse error.
// int msgunpack( const uint8_t *buf, const char *fmt, ... ); // if !buf, test message; else unpack.
struct writer {
uint8_t *w; // Write pointer into buffer
size_t len; // Written bytes up to date
size_t cap; // Buffer capacity
};
struct reader {
FILE *fp;
const void *membuf;
size_t memsize, offset;
struct variant v; // tmp
};
static __thread struct writer out;
static __thread struct reader in;
static void wrbe(uint64_t n, uint8_t *b) {
#ifndef BIG_ENDIAN
n = ntoh64(n);
#endif
memcpy(b, &n, sizeof(uint64_t));
}
static int wr(int len, uint8_t opcode, uint64_t value) {
uint8_t b[8];
assert((out.len + (len+1) < out.cap) && "buffer overflow!");
*out.w++ = (opcode);
/**/ if(len == 1) *out.w++ = (uint8_t)(value);
else if(len == 2) wrbe(value, b), memcpy(out.w, &b[6], 2), out.w += 2;
else if(len == 4) wrbe(value, b), memcpy(out.w, &b[4], 4), out.w += 4;
else if(len == 8) wrbe(value, b), memcpy(out.w, &b[0], 8), out.w += 8;
out.len += len+1;
return len+1;
}
static bool rd(void *buf, size_t len, size_t swap) { // return false any error and/or eof
bool ret;
if( in.fp ) {
assert( !ferror(in.fp) && "invalid file handle (reader)" );
ret = len == fread((char*)buf, 1, len, in.fp);
} else {
assert( in.membuf && "invalid memory buffer (reader)");
assert( (in.offset + len <= in.memsize) && "memory overflow! (reader)");
ret = !!memcpy(buf, (char*)in.membuf + in.offset, len);
}
#ifndef BIG_ENDIAN
/**/ if( swap && len == 2 ) *((uint16_t*)buf) = ntoh16(*((uint16_t*)buf));
else if( swap && len == 4 ) *((uint32_t*)buf) = ntoh32(*((uint32_t*)buf));
else if( swap && len == 8 ) *((uint64_t*)buf) = ntoh64(*((uint64_t*)buf));
#endif
return in.offset += len, ret;
}
static bool rdbuf(char **buf, size_t len) { // return false on error or out of memory
char *ptr = REALLOC(*buf, len+1);
if( ptr && rd(ptr, len, 0) ) {
(*buf = ptr)[len] = 0;
} else {
FREE(ptr), ptr = 0;
}
return !!ptr;
}
int msgpack_new(uint8_t *w, size_t l) {
out.w = w;
out.len = 0;
out.cap = l;
return w != 0 && l != 0;
}
int msgpack_nil() {
return wr(0, 0xC0, 0);
}
int msgpack_chr(bool c) {
return wr(0, c ? 0xC3 : 0xC2, 0);
}
int msgpack_uns(uint64_t n) {
/**/ if (n < 0x80) return wr(0, n, 0);
else if (n < 0x100) return wr(1, 0xCC, n);
else if (n < 0x10000) return wr(2, 0xCD, n);
else if (n < 0x100000000) return wr(4, 0xCE, n);
else return wr(8, 0xCF, n);
}
int msgpack_int(int64_t n) {
/**/ if (n >= 0) return msgpack_uns(n);
else if (n >= -32) return wr(0, n, 0); //wr(0, 0xE0 | n, 0);
else if (n >= -128) return wr(1, 0xD0, n + 0xff + 1);
else if (n >= -32768) return wr(2, 0xD1, n + 0xffff + 1);
else if (n >= -2147483648LL) return wr(4, 0xD2, n + 0xffffffffull + 1);
else return wr(8, 0xD3, n + 0xffffffffffffffffull + 1);
}
int msgpack_flt(double g) {
float f = (float)g;
double h = f;
/**/ if(g == h) return wr(4, 0xCA, pack754_32(f));
else return wr(8, 0xCB, pack754_64(g));
}
int msgpack_str(const char *s) {
size_t n = strlen(s), c = n;
/**/ if (n < 0x20) c += wr(0, 0xA0 | n, 0);
else if (n < 0x100) c += wr(1, 0xD9, n);
else if (n < 0x10000) c += wr(2, 0xDA, n);
else c += wr(4, 0xDB, n);
memcpy(out.w, s, n);
out.w += n;
out.len += n;
return c;
}
int msgpack_bin(const char *s, size_t n) {
size_t c = n;
/**/ if (n < 0x100) c += wr(1, 0xC4, n);
else if (n < 0x10000) c += wr(2, 0xC5, n);
else c += wr(4, 0xC6, n);
memcpy(out.w, s, n);
out.w += n;
out.len += n;
return c;
}
int msgpack_arr(uint32_t numitems) {
uint32_t n = numitems;
/**/ if (n < 0x10) return wr(0, 0x90 | n, 0);
else if (n < 0x10000) return wr(2, 0xDC, n);
else return wr(4, 0xDD, n);
}
int msgpack_map(uint32_t numpairs) {
uint32_t n = numpairs;
/**/ if (n < 0x10) return wr(0, 0x80 | n, 0);
else if (n < 0x10000) return wr(2, 0xDE, n);
else return wr(4, 0xDF, n);
}
int msgpack_ext(uint8_t key, void *val, size_t n) {
uint32_t c = n;
/**/ if (n == 1) c += wr(1, 0xD4, key);
else if (n == 2) c += wr(1, 0xD5, key);
else if (n == 4) c += wr(1, 0xD6, key);
else if (n == 8) c += wr(1, 0xD7, key);
else if (n == 16) c += wr(1, 0xD8, key);
else if (n < 0x100) c += wr(1, 0xC7, n), c += wr(0, key, 0);
else if (n < 0x10000) c += wr(2, 0xC8, n), c += wr(0, key, 0);
else c += wr(4, 0xC9, n), c += wr(0, key, 0);
memcpy(out.w, val, n);
out.w += n;
out.len += n;
return c;
}
bool msgunpack_new( const void *opaque_or_FILE, size_t bytes ) {
return !!((memset(&in, 0, sizeof(in)), in.memsize = bytes) ? (in.membuf = opaque_or_FILE) : (in.fp = (FILE*)opaque_or_FILE));
}
bool msgunpack_eof() {
return in.fp ? !!feof(in.fp) : (in.offset > in.memsize);
}
bool msgunpack_err() {
return in.fp ? !!ferror(in.fp) : !in.memsize;
}
bool msgunpack_var(struct variant *w) {
uint8_t tag;
struct variant v = {0};
if( rd(&tag, 1, 0) )
switch(tag) {
default:
/**/ if((tag & 0x80) == 0x00) { v.type = UNS; v.sz = 1; v.uns = tag; }
else if((tag & 0xe0) == 0xe0) { v.type = SIG; v.sz = 1; v.sig = (int8_t)tag; }
else if((tag & 0xe0) == 0xa0) { v.type = rdbuf(&v.str, v.sz = tag & 0x1f) ? STR : ERR; }
else if((tag & 0xf0) == 0x90) { v.type = ARR; v.sz = tag & 0x0f; }
else if((tag & 0xf0) == 0x80) { v.type = MAP; v.sz = tag & 0x0f; }
break; case 0xc0: v.type = NIL; v.sz = 0;
break; case 0xc2: v.type = BOL; v.sz = 1; v.chr = 0;
break; case 0xc3: v.type = BOL; v.sz = 1; v.chr = 1;
break; case 0xcc: v.type = rd(&v.uns, v.sz = 1, 0) ? UNS : ERR;
break; case 0xcd: v.type = rd(&v.uns, v.sz = 2, 1) ? UNS : ERR;
break; case 0xce: v.type = rd(&v.uns, v.sz = 4, 1) ? UNS : ERR;
break; case 0xcf: v.type = rd(&v.uns, v.sz = 8, 1) ? UNS : ERR;
break; case 0xd0: v.type = rd(&v.uns, v.sz = 1, 0) ? (v.sig -= 0xff + 1, SIG) : ERR;
break; case 0xd1: v.type = rd(&v.uns, v.sz = 2, 1) ? (v.sig -= 0xffff + 1, SIG) : ERR;
break; case 0xd2: v.type = rd(&v.uns, v.sz = 4, 1) ? (v.sig -= 0xffffffffull + 1, SIG) : ERR;
break; case 0xd3: v.type = rd(&v.uns, v.sz = 8, 1) ? (v.sig -= 0xffffffffffffffffull + 1, SIG) : ERR;
break; case 0xca: v.type = rd(&v.u32, v.sz = 4, 1) ? (v.flt = unpack754_32(v.u32), FLT) : ERR;
break; case 0xcb: v.type = rd(&v.uns, v.sz = 8, 1) ? (v.flt = unpack754_64(v.uns), FLT) : ERR;
break; case 0xd9: v.type = rd(&v.sz, 1, 0) && rdbuf(&v.str, v.sz) ? STR : ERR;
break; case 0xda: v.type = rd(&v.sz, 2, 1) && rdbuf(&v.str, v.sz) ? STR : ERR;
break; case 0xdb: v.type = rd(&v.sz, 4, 1) && rdbuf(&v.str, v.sz) ? STR : ERR;
break; case 0xc4: v.type = rd(&v.sz, 1, 0) && rdbuf(&v.str, v.sz) ? BIN : ERR;
break; case 0xc5: v.type = rd(&v.sz, 2, 1) && rdbuf(&v.str, v.sz) ? BIN : ERR;
break; case 0xc6: v.type = rd(&v.sz, 4, 1) && rdbuf(&v.str, v.sz) ? BIN : ERR;
break; case 0xdc: v.type = rd(&v.sz, 2, 1) ? ARR : ERR;
break; case 0xdd: v.type = rd(&v.sz, 4, 1) ? ARR : ERR;
break; case 0xde: v.type = rd(&v.sz, 2, 1) ? MAP : ERR;
break; case 0xdf: v.type = rd(&v.sz, 4, 1) ? MAP : ERR;
break; case 0xd4: v.type = rd(&v.ext, 1, 0) && rd(&v.uns, 1, 0) && rdbuf(&v.str, v.sz = v.uns) ? EXT : ERR;
break; case 0xd5: v.type = rd(&v.ext, 1, 0) && rd(&v.uns, 2, 1) && rdbuf(&v.str, v.sz = v.uns) ? EXT : ERR;
break; case 0xd6: v.type = rd(&v.ext, 1, 0) && rd(&v.uns, 4, 1) && rdbuf(&v.str, v.sz = v.uns) ? EXT : ERR;
break; case 0xd7: v.type = rd(&v.ext, 1, 0) && rd(&v.uns, 8, 1) && rdbuf(&v.str, v.sz = v.uns) ? EXT : ERR;
break; case 0xd8: v.type = rd(&v.ext, 1, 0) && rd(&v.uns,16, 1) && rdbuf(&v.str, v.sz = v.uns) ? EXT : ERR;
break; case 0xc7: v.type = rd(&v.sz, 1, 0) && rd(&v.ext, 1, 0) && rdbuf(&v.str,v.sz) ? EXT : ERR;
break; case 0xc8: v.type = rd(&v.sz, 2, 1) && rd(&v.ext, 1, 1) && rdbuf(&v.str,v.sz) ? EXT : ERR;
break; case 0xc9: v.type = rd(&v.sz, 4, 1) && rd(&v.ext, 1, 1) && rdbuf(&v.str,v.sz) ? EXT : ERR;
}
return *w = v, v.type != ERR;
}
bool msgunpack_nil() {
return msgunpack_var(&in.v) && (in.v.type == NIL);
}
bool msgunpack_chr(bool *chr) {
return msgunpack_var(&in.v) && (*chr = in.v.chr, in.v.type == BOL);
}
bool msgunpack_uns(uint64_t *uns) {
return msgunpack_var(&in.v) && (*uns = in.v.uns, in.v.type == UNS);
}
bool msgunpack_int(int64_t *sig) {
return msgunpack_var(&in.v) && (*sig = in.v.sig, in.v.type == SIG);
}
bool msgunpack_flt(float *flt) {
return msgunpack_var(&in.v) && (*flt = in.v.flt, in.v.type == FLT);
}
bool msgunpack_dbl(double *dbl) {
return msgunpack_var(&in.v) && (*dbl = in.v.flt, in.v.type == FLT);
}
bool msgunpack_bin(void **bin, uint64_t *len) {
return msgunpack_var(&in.v) && (*bin = in.v.bin, *len = in.v.sz, in.v.type == BIN);
}
bool msgunpack_str(char **str) {
return msgunpack_var(&in.v) && (str ? *str = in.v.str, in.v.type == STR : in.v.type == STR);
}
bool msgunpack_ext(uint8_t *key, void **val, uint64_t *len) {
return msgunpack_var(&in.v) && (*key = in.v.ext, *val = in.v.bin, *len = in.v.sz, in.v.type == EXT);
}
bool msgunpack_arr(uint64_t *len) {
return msgunpack_var(&in.v) && (*len = in.v.sz, in.v.type == ARR);
}
bool msgunpack_map(uint64_t *len) {
return msgunpack_var(&in.v) && (*len = in.v.sz, in.v.type == MAP);
}
int msgpack(const char *fmt, ... ) {
int count = 0;
va_list vl;
va_start(vl, fmt);
while( *fmt ) {
char f = *fmt++;
switch( f ) {
break; case '{': { int i = va_arg(vl, int64_t); count += msgpack_map( i ); }
break; case '[': { int i = va_arg(vl, int64_t); count += msgpack_arr( i ); }
break; case 'b': { bool v = !!va_arg(vl, int64_t); count += msgpack_chr(v); }
break; case 'e': { uint8_t k = va_arg(vl, uint64_t); void *v = va_arg(vl, void*); size_t l = va_arg(vl, uint64_t); count += msgpack_ext( k, v, l ); }
break; case 'n': { count += msgpack_nil(); }
break; case 'p': { void *p = va_arg(vl, void*); size_t l = va_arg(vl, uint64_t); count += msgpack_bin( p, l ); }
break; case 's': { const char *v = va_arg(vl, const char *); count += msgpack_str(v); }
break; case 'u': { uint64_t v = va_arg(vl, uint64_t); count += msgpack_uns(v); }
break; case 'd': case 'i': { int64_t v = va_arg(vl, int64_t); count += msgpack_int(v); }
break; case 'f': case 'g': { double v = va_arg(vl, double); count += msgpack_flt(v); }
default: /*count = 0;*/ break;
}
}
va_end(vl);
return count;
}
bool msgunpack(const char *fmt, ... ) {
int count = 0;
va_list vl;
va_start(vl, fmt);
while( *fmt ) {
char f = *fmt++;
switch( f ) {
break; case '{': { int64_t *i = va_arg(vl, int64_t*); count += msgunpack_map( i ); }
break; case '[': { int64_t *i = va_arg(vl, int64_t*); count += msgunpack_arr( i ); }
break; case 'f': { float *v = va_arg(vl, float*); count += msgunpack_flt(v); }
break; case 'g': { double *v = va_arg(vl, double*); count += msgunpack_dbl(v); }
break; case 's': { char **v = va_arg(vl, char **); count += msgunpack_str(v); }
// break; case 'b': { bool *v = !!va_arg(vl, bool*); count += msgunpack_chr(v); }
// break; case 'e': { uint8_t k = va_arg(vl, uint64_t); void *v = va_arg(vl, void*); size_t l = va_arg(vl, uint64_t); count += msgunpack_ext( k, v, l ); }
// break; case 'n': { count += msgunpack_nil(); }
// break; case 'p': { void *p = va_arg(vl, void*); size_t l = va_arg(vl, uint64_t); count += msgunpack_bin( p, l ); }
// break; case 'u': { uint64_t v = va_arg(vl, uint64_t); count += msgunpack_uns(v); }
// break; case 'd': case 'i': { int64_t v = va_arg(vl, int64_t); count += msgunpack_int(v); }
default: /*count = 0;*/ break;
}
}
va_end(vl);
return count;
}
#if 0
AUTORUN {
# define unit(title)
# define data(data) msgunpack_new(data, sizeof(data) -1 )
# define TEST(expr) test(msgunpack_var(&obj) && !!(expr))
int test_len;
const char *test_data = 0;
struct variant obj = {0};
/*
* Test vectors are derived from
* `https://github.com/ludocode/mpack/blob/v0.8.2/test/test-write.c`.
*/
unit("(minposfixint)");
data("\x00");
TEST(obj.type == UNS && obj.sz == 1 && obj.uns == 0);
unit("(maxposfixint)");
data("\x7f");
TEST(obj.type == UNS && obj.sz == 1 && obj.uns == 127);
unit("(maxnegfixint)");
data("\xe0");
TEST(obj.type == SIG && obj.sz == 1 && obj.uns == -32);
unit("(minnegfixint)");
data("\xff");
TEST(obj.type == SIG && obj.sz == 1 && obj.uns == -1);
unit("(uint8)");
data("\xcc\0");
TEST(obj.type == UNS && obj.sz == 1 && obj.uns == 0);
unit("(uint16)");
data("\xcd\0\0");
TEST(obj.type == UNS && obj.sz == 2 && obj.uns == 0);
unit("(uint32)");
data("\xce\0\0\0\0");
TEST(obj.type == UNS && obj.sz == 4 && obj.uns == 0);
unit("(uint64)");
data("\xcf\0\0\0\0\0\0\0\0");
TEST(obj.type == UNS && obj.sz == 8 && obj.uns == 0);
unit("(float32)");
data("\xca\0\0\0\0");
TEST(obj.type == FLT && obj.sz == 4 && obj.uns == 0);
unit("(float64)");
data("\xcb\0\0\0\0\0\0\0\0");
TEST(obj.type == FLT && obj.sz == 8 && obj.uns == 0);
unit("(string)");
data("\xa5Hello");
TEST(obj.type == STR && obj.sz == 5 && !strcmp(obj.str, "Hello"));
unit("(str8)");
data("\xd9\x05Hello");
TEST(obj.type == STR && obj.sz == 5 && !strcmp(obj.str, "Hello"));
unit("(str16)");
data("\xda\0\x05Hello");
TEST(obj.type == STR && obj.sz == 5 && !strcmp(obj.str, "Hello"));
unit("(str32)");
data("\xdb\0\0\0\x05Hello");
TEST(obj.type == STR && obj.sz == 5 && !strcmp(obj.str, "Hello"));
unit("(array)");
data("\x91\x01");
TEST(obj.type == ARR && obj.sz == 1);
unit("(array8)");
data("\x91\x01");
TEST(obj.type == ARR && obj.sz == 1);
unit("(array16)");
data("\xdc\0\x01\x01");
TEST(obj.type == ARR && obj.sz == 1);
unit("(map8)");
data("\x81\x01\x01");
TEST(obj.type == MAP && obj.sz == 1);
TEST(obj.type == UNS && obj.sz == 1 && obj.uns == 1);
TEST(obj.type == UNS && obj.sz == 1 && obj.uns == 1);
unit("(map32)");
data("\xdf\0\0\0\x01\xa5Hello\x01");
TEST(obj.type == MAP && obj.sz == 1);
TEST(obj.type == STR && obj.sz == 5 && !strcmp(obj.str, "Hello"));
TEST(obj.type == UNS && obj.sz == 1 && obj.uns == 1);
unit("(+fixnum)");
data("\x00"); TEST(obj.type == UNS && obj.uns == 0);
data("\x01"); TEST(obj.type == UNS && obj.uns == 1);
data("\x02"); TEST(obj.type == UNS && obj.uns == 2);
data("\x0f"); TEST(obj.type == UNS && obj.uns == 0x0f);
data("\x10"); TEST(obj.type == UNS && obj.uns == 0x10);
data("\x7f"); TEST(obj.type == UNS && obj.uns == 0x7f);
unit("(-fixnum)");
data("\xff"); TEST(obj.type == SIG && obj.sig == -1);
data("\xfe"); TEST(obj.type == SIG && obj.sig == -2);
data("\xf0"); TEST(obj.type == SIG && obj.sig == -16);
data("\xe0"); TEST(obj.type == SIG && obj.sig == -32);
unit("(+int)");
data("\xcc\x80"); TEST(obj.type == UNS && obj.uns == 0x80);
data("\xcc\xff"); TEST(obj.type == UNS && obj.uns == 0xff);
data("\xcd\x01\x00"); TEST(obj.type == UNS && obj.uns == 0x100);
data("\xcd\xff\xff"); TEST(obj.type == UNS && obj.uns == 0xffff);
data("\xce\x00\x01\x00\x00"); TEST(obj.type == UNS && obj.uns == 0x10000);
data("\xce\xff\xff\xff\xff"); TEST(obj.type == UNS && obj.uns == 0xffffffffull);
data("\xcf\x00\x00\x00\x01\x00\x00\x00\x00"); TEST(obj.type == UNS && obj.uns == 0x100000000ull);
data("\xcf\xff\xff\xff\xff\xff\xff\xff\xff"); TEST(obj.type == UNS && obj.uns == 0xffffffffffffffffull);
unit("(-int)");
data("\xd0\xdf"); TEST(obj.type == SIG && obj.sig == -33);
data("\xd0\x80"); TEST(obj.type == SIG && obj.sig == -128);
data("\xd1\xff\x7f"); TEST(obj.type == SIG && obj.sig == -129);
data("\xd1\x80\x00"); TEST(obj.type == SIG && obj.sig == -32768);
data("\xd2\xff\xff\x7f\xff"); TEST(obj.type == SIG && obj.sig == -32769);
data("\xd2\x80\x00\x00\x00"); TEST(obj.type == SIG && obj.sig == -2147483648ll);
data("\xd3\xff\xff\xff\xff\x7f\xff\xff\xff"); TEST(obj.type == SIG && obj.sig == -2147483649ll);
data("\xd3\x80\x00\x00\x00\x00\x00\x00\x00"); TEST(obj.type == SIG && obj.sig == INT64_MIN);
unit("(misc)");
data("\xc0"); TEST(obj.type == NIL && obj.chr == 0);
data("\xc2"); TEST(obj.type == BOL && obj.chr == 0);
data("\xc3"); TEST(obj.type == BOL && obj.chr == 1);
data("\x90"); TEST(obj.type == ARR && obj.sz == 0);
data("\x91\xc0");
TEST(obj.type==ARR && obj.sz==1);
TEST(obj.type==NIL);
data("\x9f\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d\x0e");
TEST(obj.type==ARR && obj.sz==15);
for(int i = 0; i < 15; ++i) {
TEST(obj.type==UNS && obj.sig==i);
}
data("\xdc\x00\x10\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c"
"\x0d\x0e\x0f");
TEST(obj.type==ARR && obj.sz==16);
for(unsigned i = 0; i < 16; ++i) {
TEST(obj.type == UNS && obj.uns == i);
}
data("\x80");
TEST(obj.type == MAP && obj.sz == 0);
data("\x81\xc0\xc0");
TEST(obj.type == MAP && obj.sz == 1);
TEST(obj.type == NIL);
TEST(obj.type == NIL);
data("\x82\x00\x00\x01\x01");
TEST(obj.type == MAP && obj.sz == 2);
TEST(obj.type == UNS && obj.sig == 0);
TEST(obj.type == UNS && obj.sig == 0);
TEST(obj.type == UNS && obj.sig == 1);
TEST(obj.type == UNS && obj.sig == 1);
data("\x8f\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d\x0e"
"\x0f\x10\x11\x12\x13\x14\x15\x16\x17\x18\x19\x1a\x1b\x1c\x1d");
TEST(obj.type == MAP && obj.sz == 15);
for(unsigned i = 0; i < 15; ++i) {
TEST(obj.type == UNS && obj.uns == i*2+0);
TEST(obj.type == UNS && obj.uns == i*2+1);
}
data("\xde\x00\x10\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c"
"\x0d\x0e\x0f\x10\x11\x12\x13\x14\x15\x16\x17\x18\x19\x1a\x1b\x1c"
"\x1d\x1e\x1f");
TEST(obj.type == MAP && obj.sz == 16);
for(unsigned i = 0; i < 16; ++i) {
TEST(obj.type == UNS && obj.uns == i*2+0);
TEST(obj.type == UNS && obj.uns == i*2+1);
}
data("\x91\x90");
test( obj.type == ARR && obj.sz == 1 );
test( obj.type == ARR && obj.sz == 0 );
data("\x93\x90\x91\x00\x92\x01\x02");
test( obj.type == ARR && obj.sz == 3 );
test( obj.type == ARR && obj.sz == 0 );
test( obj.type == ARR && obj.sz == 1 );
test( obj.type == UNS && obj.uns == 0 );
test( obj.type == ARR && obj.sz == 2 );
test( obj.type == UNS && obj.uns == 1 );
test( obj.type == UNS && obj.uns == 2 );
data("\x95\x90\x91\xc0\x92\x90\x91\xc0\x9f\x00\x01\x02\x03\x04\x05\x06"
"\x07\x08\x09\x0a\x0b\x0c\x0d\x0e\xdc\x00\x10\x00\x01\x02\x03\x04"
"\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d\x0e\x0f");
test( obj.type == ARR && obj.sz == 5 );
test( obj.type == ARR && obj.sz == 0 );
test( obj.type == ARR && obj.sz == 1 );
test( obj.type == NIL );
test( obj.type == ARR && obj.sz == 2 );
test( obj.type == ARR && obj.sz == 0 );
test( obj.type == ARR && obj.sz == 1 );
test( obj.type == NIL );
test( obj.type == ARR && obj.sz == 15 );
for( unsigned i = 0; i < 15; ++i ) {
test( obj.type == UNS && obj.uns == i );
}
test( obj.type == ARR && obj.sz == 16 );
for( unsigned i = 0; i < 15; ++i ) {
test( obj.type == UNS && obj.uns == i );
}
data("\x85\x00\x80\x01\x81\x00\xc0\x02\x82\x00\x80\x01\x81\xc0\xc0\x03"
"\x8f\x00\x00\x01\x01\x02\x02\x03\x03\x04\x04\x05\x05\x06\x06\x07"
"\x07\x08\x08\x09\x09\x0a\x0a\x0b\x0b\x0c\x0c\x0d\x0d\x0e\x0e\x04"
"\xde\x00\x10\x00\x00\x01\x01\x02\x02\x03\x03\x04\x04\x05\x05\x06"
"\x06\x07\x07\x08\x08\x09\x09\x0a\x0a\x0b\x0b\x0c\x0c\x0d\x0d\x0e"
"\x0e\x0f\x0f");
TEST(obj.type == MAP && obj.sz == 5);
TEST(obj.type == UNS && obj.uns == 0);
TEST(obj.type == MAP && obj.sz == 0);
TEST(obj.type == UNS && obj.uns == 1);
TEST(obj.type == MAP && obj.sz == 1);
TEST(obj.type == UNS && obj.uns == 0);
TEST(obj.type == NIL);
TEST(obj.type == UNS && obj.uns == 2);
TEST(obj.type == MAP && obj.sz == 2);
TEST(obj.type == UNS && obj.uns == 0);
TEST(obj.type == MAP && obj.sz == 0);
TEST(obj.type == UNS && obj.uns == 1);
TEST(obj.type == MAP && obj.sz == 1);
TEST(obj.type == NIL);
TEST(obj.type == NIL);
TEST(obj.type == UNS && obj.uns == 3);
TEST(obj.type == MAP && obj.sz == 15);
for( unsigned i = 0; i < 15; ++i ) {
TEST(obj.type == UNS && obj.uns == i);
TEST(obj.type == UNS && obj.uns == i);
}
TEST(obj.type == UNS && obj.uns == 4);
TEST(obj.type == MAP && obj.sz == 16);
for( unsigned i = 0; i < 16; ++i ) {
TEST(obj.type == UNS && obj.uns == i);
TEST(obj.type == UNS && obj.uns == i);
}
data("\x85\xd0\xd1\x91\xc0\x90\x81\xc0\x00\xc0\x82\xc0\x90\x04\x05\xa5"
"\x68\x65\x6c\x6c\x6f\x93\xa7\x62\x6f\x6e\x6a\x6f\x75\x72\xc0\xff"
"\x91\x5c\xcd\x01\x5e");
TEST(obj.type == MAP && obj.sz == 5);
TEST(obj.type == SIG && obj.sig == -47);
TEST(obj.type == ARR && obj.sz == 1);
TEST(obj.type == NIL);
TEST(obj.type == ARR && obj.sz == 0);
TEST(obj.type == MAP && obj.sz == 1);
TEST(obj.type == NIL);
TEST(obj.type == UNS && obj.uns == 0);
TEST(obj.type == NIL);
TEST(obj.type == MAP && obj.sz == 2);
TEST(obj.type == NIL);
TEST(obj.type == ARR && obj.sz == 0);
TEST(obj.type == UNS && obj.uns == 4);
TEST(obj.type == UNS && obj.uns == 5);
TEST(obj.type == STR && !strcmp(obj.str, "hello"));
TEST(obj.type == ARR && obj.sz == 3);
TEST(obj.type == STR && !strcmp(obj.str, "bonjour"));
TEST(obj.type == NIL);
TEST(obj.type == SIG && obj.sig == -1);
TEST(obj.type == ARR && obj.sz == 1);
TEST(obj.type == UNS && obj.uns == 92);
TEST(obj.type == UNS && obj.uns == 350);
data("\x82\xa7" "compact" "\xc3\xa6" "schema" "\x00");
TEST(obj.type == MAP && obj.sz == 2);
TEST(obj.type == STR && obj.sz == 7 && !strcmp(obj.str, "compact"));
TEST(obj.type == BOL && obj.chr == 1);
TEST(obj.type == STR && obj.sz == 6 && !strcmp(obj.str, "schema"));
TEST(obj.type == UNS && obj.sz == 1 && obj.uns == 0);
# undef TEST
# undef data
# undef unit
}
bool vardump( struct variant *w ) {
static int tabs = 0;
struct variant v = *w;
printf("%.*s", tabs, "\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t");
switch( v.type ) {
default: case ERR:
if( !msgunpack_eof() ) printf("ERROR: unknown tag type (%02X)\n", (int)v.type);
return false;
break; case NIL: printf("(%s)\n", "null");
break; case BOL: printf("bool: %d\n", v.chr);
break; case SIG: printf("int: %lld\n", v.sig);
break; case UNS: printf("uint: %llu\n", v.uns);
break; case FLT: printf("float: %g\n", v.flt);
break; case STR: printf("string: '%s'\n", v.str);
break; case BIN: { for( size_t n = 0; n < v.sz; n++ ) printf("%s%02x(%c)", n > 0 ? " ":"binary: ", v.str[n], v.str[n] >= 32 ? v.str[n] : '.'); puts(""); }
break; case EXT: { printf("ext: [%02X (%d)] ", v.ext, v.ext); for( size_t n = 0; n < v.sz; n++ ) printf("%s%02x(%c)", n > 0 ? " ":"", v.str[n], v.str[n] >= 32 ? v.str[n] : '.'); puts(""); }
break; case ARR: {
++tabs; puts("[");
for( size_t n = v.sz; n-- > 0; ) {
if( !msgunpack_var(&v) || !vardump(&v) ) return false;
}
--tabs; puts("]");
}
break; case MAP: {
++tabs; puts("{");
for( size_t n = v.sz; n-- > 0; ) {
if( !msgunpack_var(&v) || !vardump(&v) ) return false;
if( !msgunpack_var(&v) || !vardump(&v) ) return false;
}
--tabs; puts("}");
}}
return true;
}
void testdump( const char *fname ) {
FILE *fp = fopen(fname, "rb");
if( !fp ) {
fputs("Cannot read input stream", stderr);
} else {
if( msgunpack_new(fp, 0) ) {
struct variant v;
while( msgunpack_var(&v) ) {
vardump(&v);
}
if( msgunpack_err() ) {
fputs("Error while unpacking", stderr);
}
}
fclose(fp);
}
}
void testwrite(const char *outfile) {
char buf[256];
msgpack_new(buf, 256);
int len = msgpack("ddufs [dddddddd-dddddddd {sisi bne"/*bp0*/,
-123LL, 123LL, 123456ULL, 3.14159f, "hello world",
16ULL,
-31LL, -32LL, -127LL, -128LL, -255LL, -256LL, -511LL, -512LL, // ,121, 3, "hi",
+31LL, +32LL, +127LL, +128LL, +255LL, +256LL, +511LL, +512LL, // ,121, 3, "hi",
2ULL,
"hello", -123LL,
"world", -456LL,
1ULL,
0xeeULL, "this is an EXT type", sizeof("this is an EXT type")-1
);
hexdump(buf, len);
FILE *fp = fopen(outfile, "wb");
if( fp ) {
fwrite( buf, len, 1, fp );
fclose(fp);
}
}
AUTORUN {
testwrite("out.mp");
testdump("out.mp");
}
#endif

106
engine/split/v4k_buffer.h 100644
View File

@ -0,0 +1,106 @@
// ----------------------------------------------------------------------------
// compression api
enum COMPRESS_FLAGS {
COMPRESS_RAW = 0,
COMPRESS_PPP = (1<<4),
COMPRESS_ULZ = (2<<4),
COMPRESS_LZ4 = (3<<4),
COMPRESS_CRUSH = (4<<4),
COMPRESS_DEFLATE = (5<<4),
COMPRESS_LZP1 = (6<<4),
COMPRESS_LZMA = (7<<4),
COMPRESS_BALZ = (8<<4),
COMPRESS_LZW3 = (9<<4),
COMPRESS_LZSS = (10<<4),
COMPRESS_BCM = (11<<4),
COMPRESS_ZLIB = (12<<4), // same as deflate with header
};
API unsigned zbounds(unsigned inlen, unsigned flags);
API unsigned zencode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
API unsigned zexcess(unsigned flags);
API unsigned zdecode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
// ----------------------------------------------------------------------------
// cobs en/decoding
API unsigned cobs_bounds(unsigned len);
API unsigned cobs_encode(const void *in, unsigned inlen, void *out, unsigned outlen);
API unsigned cobs_decode(const void *in, unsigned inlen, void *out, unsigned outlen);
// ----------------------------------------------------------------------------
// float un/packing: 8 (micro), 16 (half), 32 (float), 64 (double) types
#define pack754_8(f) ( pack754((f), 8, 4))
#define pack754_16(f) ( pack754((f), 16, 5))
#define pack754_32(f) ( pack754((f), 32, 8))
#define pack754_64(f) ( pack754((f), 64, 11))
#define unpack754_8(u) (unpack754((u), 8, 4))
#define unpack754_16(u) (unpack754((u), 16, 5))
#define unpack754_32(u) (unpack754((u), 32, 8))
#define unpack754_64(u) (unpack754((u), 64, 11))
API uint64_t pack754(long double f, unsigned bits, unsigned expbits);
API long double unpack754(uint64_t i, unsigned bits, unsigned expbits);
// ----------------------------------------------------------------------------
// msgpack v5, schema based struct/buffer bitpacking
// api v2
API int msgpack(const char *fmt, ... ); // va arg pack "n,b,u,d/i,s,p,f/g,e,[,{"
API bool msgunpack(const char *fmt, ... ); // va arg pack "n,b,u,d/i,s,p,f/g,e,[,{"
// api v1
API int msgpack_new(uint8_t *w, size_t l);
API int msgpack_nil(); // write null
API int msgpack_chr(bool n); // write boolean
API int msgpack_uns(uint64_t n); // write unsigned integer
API int msgpack_int(int64_t n); // write integer
API int msgpack_str(const char *s); // write string
API int msgpack_bin(const char *s, size_t n); // write binary pointer
API int msgpack_flt(double g); // write real
API int msgpack_ext(uint8_t key, void *val, size_t n); // write extension type
API int msgpack_arr(uint32_t n); // write array mark for next N items
API int msgpack_map(uint32_t n); // write map mark for next N pairs (N keys + N values)
API int msgpack_eof(); // write full?
API int msgpack_err(); // write error?
API bool msgunpack_new( const void *opaque_or_FILE, size_t bytes );
API bool msgunpack_nil();
API bool msgunpack_chr(bool *chr);
API bool msgunpack_uns(uint64_t *uns);
API bool msgunpack_int(int64_t *sig);
API bool msgunpack_str(char **str);
API bool msgunpack_bin(void **bin, uint64_t *len);
API bool msgunpack_flt(float *flt);
API bool msgunpack_dbl(double *dbl);
API bool msgunpack_ext(uint8_t *key, void **val, uint64_t *len);
API bool msgunpack_arr(uint64_t *len);
API bool msgunpack_map(uint64_t *len);
API bool msgunpack_eof();
API bool msgunpack_err();
// alt unpack api v1
enum {
ERR,NIL,BOL,UNS,SIG,STR,BIN,FLT,EXT,ARR,MAP
};
typedef struct variant {
union {
uint8_t chr;
uint64_t uns;
int64_t sig;
uint8_t *str;
void *bin;
double flt;
uint32_t u32;
};
uint64_t sz;
uint16_t ext;
uint16_t type; //[0..10]={err,nil,bol,uns,sig,str,bin,flt,ext,arr,map}
} variant;
API bool msgunpack_var(struct variant *var);

51
engine/split/v4k_data.c
View File

@ -298,54 +298,3 @@ bool data_tests() {
return true;
}
// compression api
static struct zcompressor {
// id of compressor
unsigned enumerator;
// name of compressor
const char name1, *name4, *name;
// returns worst case compression estimation for selected flags
unsigned (*bounds)(unsigned bytes, unsigned flags);
// returns number of bytes written. 0 if error.
unsigned (*encode)(const void *in, unsigned inlen, void *out, unsigned outcap, unsigned flags);
// returns number of excess bytes that will be overwritten when decoding.
unsigned (*excess)(unsigned flags);
// returns number of bytes written. 0 if error.
unsigned (*decode)(const void *in, unsigned inlen, void *out, unsigned outcap);
} zlist[] = {
{ COMPRESS_RAW, '0', "raw", "raw", raw_bounds, raw_encode, raw_excess, raw_decode },
{ COMPRESS_PPP, 'p', "ppp", "ppp", ppp_bounds, ppp_encode, ppp_excess, ppp_decode },
{ COMPRESS_ULZ, 'u', "ulz", "ulz", ulz_bounds, ulz_encode, ulz_excess, ulz_decode },
{ COMPRESS_LZ4, '4', "lz4x", "lz4x", lz4x_bounds, lz4x_encode, lz4x_excess, lz4x_decode },
{ COMPRESS_CRUSH, 'c', "crsh", "crush", crush_bounds, crush_encode, crush_excess, crush_decode },
{ COMPRESS_DEFLATE, 'd', "defl", "deflate", deflate_bounds, deflate_encode, deflate_excess, deflate_decode },
{ COMPRESS_LZP1, '1', "lzp1", "lzp1", lzp1_bounds, lzp1_encode, lzp1_excess, lzp1_decode },
{ COMPRESS_LZMA, 'm', "lzma", "lzma", lzma_bounds, lzma_encode, lzma_excess, lzma_decode },
{ COMPRESS_BALZ, 'b', "balz", "balz", balz_bounds, balz_encode, balz_excess, balz_decode },
{ COMPRESS_LZW3, 'w', "lzw3", "lzrw3a", lzrw3a_bounds, lzrw3a_encode, lzrw3a_excess, lzrw3a_decode },
{ COMPRESS_LZSS, 's', "lzss", "lzss", lzss_bounds, lzss_encode, lzss_excess, lzss_decode },
{ COMPRESS_BCM, 'B', "bcm", "bcm", bcm_bounds, bcm_encode, bcm_excess, bcm_decode },
{ COMPRESS_ZLIB, 'z', "zlib", "zlib", deflate_bounds, deflatez_encode, deflate_excess, deflatez_decode },
};
enum { COMPRESS_NUM = 14 };
static char *znameof(unsigned flags) {
static __thread char buf[16];
snprintf(buf, 16, "%4s.%c", zlist[(flags>>4)&0x0F].name4, "0123456789ABCDEF"[flags&0xF]);
return buf;
}
unsigned zencode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].encode(in, inlen, (uint8_t*)out, outlen, flags & 0x0F);
}
unsigned zdecode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].decode((uint8_t*)in, inlen, out, outlen);
}
unsigned zbounds(unsigned inlen, unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].bounds(inlen, flags & 0x0F);
}
unsigned zexcess(unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].excess(flags & 0x0F);
}

23
engine/split/v4k_data.h
View File

@ -34,26 +34,3 @@ API array(char) xml_blob(char *key);
API void xml_pop();
API bool data_tests();
// compression api
enum COMPRESS_FLAGS {
COMPRESS_RAW = 0,
COMPRESS_PPP = (1<<4),
COMPRESS_ULZ = (2<<4),
COMPRESS_LZ4 = (3<<4),
COMPRESS_CRUSH = (4<<4),
COMPRESS_DEFLATE = (5<<4),
COMPRESS_LZP1 = (6<<4),
COMPRESS_LZMA = (7<<4),
COMPRESS_BALZ = (8<<4),
COMPRESS_LZW3 = (9<<4),
COMPRESS_LZSS = (10<<4),
COMPRESS_BCM = (11<<4),
COMPRESS_ZLIB = (12<<4), // same as deflate with header
};
API unsigned zbounds(unsigned inlen, unsigned flags);
API unsigned zencode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
API unsigned zexcess(unsigned flags);
API unsigned zdecode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);

171
engine/split/v4k_id.c 100644
View File

@ -0,0 +1,171 @@
// -----------------------------------------------------------------------------
// factory of handle ids, based on code by randy gaul (PD/Zlib licensed)
// - rlyeh, public domain
//
// [src] http://www.randygaul.net/wp-content/uploads/2021/04/handle_table.cpp
// [ref] http://bitsquid.blogspot.com.es/2011/09/managing-decoupling-part-4-id-lookup.html
// [ref] http://glampert.com/2016/05-04/dissecting-idhashindex/
// [ref] https://github.com/nlguillemot/dof/blob/master/viewer/packed_freelist.h
// [ref] https://gist.github.com/pervognsen/ffd89e45b5750e9ce4c6c8589fc7f253
#if is(ems)
#define id_t id_t2
#endif
typedef union id_t {
uint64_t h;
struct {
#if (ID_INDEX_BITS+ID_COUNT_BITS) != 64
uint64_t padding : 64-ID_INDEX_BITS-ID_COUNT_BITS;
#endif
uint64_t index : ID_INDEX_BITS;
uint64_t count : ID_COUNT_BITS;
};
} id_t;
typedef struct id_factory id_factory;
id_factory id_factory_create(uint64_t capacity /*= 256*/);
id_t id_factory_insert(id_factory *f, uint64_t data);
uint64_t id_factory_getvalue(id_factory *f, id_t handle);
void id_factory_setvalue(id_factory *f, id_t handle, uint64_t data);
void id_factory_erase(id_factory *f, id_t handle);
bool id_factory_isvalid(id_factory *f, id_t handle);
void id_factory_destroy(id_factory *f);
// ---
typedef struct id_factory {
uint64_t freelist;
uint64_t capacity;
uint64_t canary;
union entry* entries;
} id_factory;
typedef union entry {
struct {
uint64_t data : ID_DATA_BITS;
uint64_t count : ID_COUNT_BITS;
};
uint64_t h;
} entry;
id_factory id_factory_create(uint64_t capacity) {
if(!capacity) capacity = 1ULL << ID_INDEX_BITS;
id_factory f = {0};
f.entries = CALLOC(1, sizeof(entry) * capacity);
f.capacity = capacity;
for (int i = 0; i < capacity - 1; ++i) {
f.entries[i].data = i + 1;
f.entries[i].count = 0;
}
f.entries[capacity - 1].h = 0;
f.entries[capacity - 1].data = ~0;
f.entries[capacity - 1].count = ~0;
f.canary = f.entries[capacity - 1].data;
return f;
}
void id_factory_destroy(id_factory *f) {
FREE(f->entries);
}
id_t id_factory_insert(id_factory *f, uint64_t data) {
// pop element off the free list
assert(f->freelist != f->canary && "max alive capacity reached");
uint64_t index = f->freelist;
f->freelist = f->entries[f->freelist].data;
// create new id_t
f->entries[index].data = data;
id_t handle = {0};
handle.index = index;
handle.count = f->entries[index].count;
return handle;
}
void id_factory_erase(id_factory *f, id_t handle) {
// push id_t onto the freelist
uint64_t index = handle.index;
f->entries[index].data = f->freelist;
f->freelist = index;
// increment the count. this signifies a change in lifetime (this particular id_t is now dead)
// the next time this particular index is used in alloc, a new `count` will be used to uniquely identify
f->entries[index].count++;
}
uint64_t id_factory_getvalue(id_factory *f, id_t handle) {
uint64_t index = handle.index;
uint64_t count = handle.count;
assert(f->entries[index].count == count);
return f->entries[index].data;
}
void id_factory_setvalue(id_factory *f, id_t handle, uint64_t data) {
uint64_t index = handle.index;
uint64_t count = handle.count;
assert(f->entries[index].count == count);
f->entries[index].data = data;
}
bool id_factory_isvalid(id_factory *f, id_t handle) {
uint64_t index = handle.index;
uint64_t count = handle.count;
if (index >= f->capacity) return false;
return f->entries[index].count == count;
}
#if 0
// monitor history of a single entity by running `id_factory | find " 123."`
AUTORUN {
trap_install();
id_factory f = id_factory_create(optioni("--NUM",256));
array(id_t) ids = 0;
for( int i = 0 ; ; ++i, i &= ((1ULL << ID_INDEX_BITS) - 1) ) { // infinite wrap
printf("count_ids(%d) ", array_count(ids));
bool insert = randf() < 0.49; // biased against deletion
if( insert ) {
id_t h = id_factory_insert(&f, i);
array_push(ids, h);
printf("add %llu.%llu\n", h.index, h.count);
} else {
int count = array_count(ids);
if( count ) {
int chosen = randi(0,count);
printf("del %d.\n", chosen);
id_t h = ids[chosen];
id_factory_erase(&f, h);
array_erase(ids, chosen);
}
}
}
}
#endif
// ----------------------------------------------------------------------
// public api
static id_factory fid; // @fixme: threadsafe
uintptr_t id_make(void *ptr) {
do_once fid = id_factory_create(0), id_factory_insert(&fid, 0); // init and reserve id(0)
id_t newid = id_factory_insert(&fid, (uint64_t)(uintptr_t)ptr ); // 48-bit effective addr
return newid.h;
}
void *id_handle(uintptr_t id) {
return (void *)(uintptr_t)id_factory_getvalue(&fid, ((id_t){ (uint64_t)id }) );
}
void id_dispose(uintptr_t id) {
id_factory_erase(&fid, ((id_t){ (uint64_t)id }) );
}
bool id_valid(uintptr_t id) {
return id_factory_isvalid(&fid, ((id_t){ (uint64_t)id }) );
}

26
engine/split/v4k_id.h 100644
View File

@ -0,0 +1,26 @@
// -----------------------------------------------------------------------------
// factory of handle ids, based on code by randy gaul (PD/Zlib licensed)
// - rlyeh, public domain
//
// [src] http://www.randygaul.net/wp-content/uploads/2021/04/handle_table.cpp
// [ref] http://bitsquid.blogspot.com.es/2011/09/managing-decoupling-part-4-id-lookup.html
// [ref] http://glampert.com/2016/05-04/dissecting-idhashindex/
// [ref] https://github.com/nlguillemot/dof/blob/master/viewer/packed_freelist.h
// [ref] https://gist.github.com/pervognsen/ffd89e45b5750e9ce4c6c8589fc7f253
// convert between hard refs (pointers) and weak refs (ids)
uintptr_t id_make(void *ptr);
void * id_handle(uintptr_t id);
void id_dispose(uintptr_t id);
bool id_valid(uintptr_t id);
// configuration:
// ideally, these two should be 32 each. they were changed to fit our OBJHEADER bits
#ifndef ID_INDEX_BITS
#define ID_INDEX_BITS 16
#endif
#ifndef ID_COUNT_BITS
#define ID_COUNT_BITS 3
#endif
// you cannot change this one: the number of ID_DATA_BITS you can store in a handle depends on ID_COUNT_BITS
#define ID_DATA_BITS (64-ID_COUNT_BITS)

3
engine/split/v4k_main.c
View File

@ -64,6 +64,9 @@ void v4k_quit(void) {
void v4k_init() {
do_once {
// abort run if any test suite failed
if( test_errs ) exit(-1);
// install signal handlers
ifdef(debug, trap_install());

1
engine/split/v4k_memory.h
View File

@ -30,6 +30,7 @@ API void* forget( void *ptr );
#define REALLOC(p,n) REALLOC_((p),(n))
#define CALLOC(m,n) CALLOC_((m),(n))
#define STRDUP(s) STRDUP_(s)
#define ALLOCA(n) ifdef(gcc, __builtin_alloca(n), _alloca(n))
static FORCE_INLINE void *(REALLOC_)(void *p, size_t n) { return n ? WATCH(xrealloc(p,n),n) : xrealloc(FORGET(p),0); } ///-
static FORCE_INLINE void *(CALLOC_)(size_t m, size_t n) { return n *= m, memset(REALLOC(0,n),0,n); } ///-

70
engine/split/v4k_string.c
View File

@ -334,26 +334,43 @@ array(uint32_t) string32( const char *utf8 ) {
// -----------------------------------------------------------------------------
// quarks
unsigned quark_intern( quarks_db *quarks, const char *string ) {
if( !*quarks ) {
// copy null string on init
array_push(*quarks, '\0');
}
unsigned quark_intern( quarks_db *q, const char *string ) {
if( string && string[0] ) {
int slen = strlen(string)+1;
int qlen = array_count(*quarks);
array_resize(*quarks, qlen + slen);
memcpy( array_back(*quarks) + 1 - slen, string, slen );
return qlen;
int slen = strlen(string);
int qlen = array_count(q->blob);
char *found;
if( !qlen ) {
array_resize(q->blob, slen + 1 );
memcpy(found = q->blob, string, slen + 1);
} else {
found = strstr(q->blob, string);
if( !found ) {
array_resize(q->blob, qlen - 1 + slen + 1);
memcpy(found = q->blob + qlen - 1, string, slen + 1 );
}
}
// already interned? return that instead
vec2i offset_len = vec2i(found - q->blob, slen);
for( int i = 0; i < array_count(q->entries); ++i ) {
if( offset_len.x == q->entries[i].x )
if( offset_len.y == q->entries[i].y )
return i+1;
}
// else cache and return it
array_push(q->entries, offset_len);
return array_count(q->entries);
}
return 0;
}
const char *quark_string( quarks_db *quarks, unsigned key ) {
assert( *quarks );
return *quarks + key;
const char *quark_string( quarks_db *q, unsigned key ) {
if( key && key <= array_count(q->entries) ) {
vec2i offset_len = q->entries[key-1];
return va("%.*s", offset_len.y, q->blob + offset_len.x);
}
return "";
}
static __thread quarks_db qdb = 0;
static __thread quarks_db qdb;
unsigned intern( const char *string ) {
return quark_intern( &qdb, string );
}
@ -363,18 +380,29 @@ const char *quark( unsigned key ) {
#if 0
AUTORUN {
assert( !intern(NULL) ); // quark #0, cannot intern null string
assert( !intern("") ); // quark #0, ok to intern empty string
assert( !quark(0)[0] ); // empty string for quark #0
test( !intern(NULL) ); // quark #0, cannot intern null string
test( !intern("") ); // quark #0, ok to intern empty string
test( !quark(0)[0] ); // empty string for quark #0
unsigned q1 = intern("Hello"); // -> quark #1
unsigned q2 = intern("cruel"); // -> quark #2
unsigned q2 = intern("happy"); // -> quark #2
unsigned q3 = intern("world."); // -> quark #3
printf("%u %u %u\n", q1, q2, q3);
test( q1 );
test( q2 );
test( q3 );
test( q1 != q2 );
test( q1 != q3 );
test( q2 != q3 );
unsigned q4 = intern("happy");
printf("%x vs %x\n", q2, q4);
test( q4 );
test( q4 == q2 );
char buf[256];
sprintf(buf, "%s %s %s", quark(q1), quark(q2), quark(q3));
assert( !strcmp("Hello cruel world.", buf) );
assert(~puts("Ok"));
test( !strcmp("Hello happy world.", buf) );
}
#endif

6
engine/split/v4k_string.h
View File

@ -81,6 +81,10 @@ API array(uint32_t) string32( const char *utf8 ); /// convert from utf8 to utf32
unsigned intern( const char *string );
const char *quark( unsigned key );
typedef array(char) quarks_db;
typedef struct quarks_db {
array(char) blob;
array(vec2i) entries;
} quarks_db;
unsigned quark_intern( quarks_db*, const char *string );
const char *quark_string( quarks_db*, unsigned key );

4
engine/split/v4k_system.c
View File

@ -905,9 +905,9 @@ bool app_open(const char *link) {
// tests
static __thread int test_oks, test_errs, test_once;
static void test_exit(void) { printf("%d/%d tests passed\n", test_oks, test_oks+test_errs); }
static void test_exit(void) { fprintf(stderr, "%d/%d tests passed\n", test_oks, test_oks+test_errs); }
int (test)(const char *file, int line, const char *expr, bool result) {
test_once = test_once || !(atexit)(test_exit);
test_oks += result, test_errs += !result;
return fputc("F."[result], stdout) && (result || fprintf(stderr, "(%s %s:%d)", expr, file, line) );
return (result || fprintf(stderr, "(Test `%s` failed %s:%d)\n", expr, file, line) );
}

7
engine/split/v4k_system.h
View File

@ -77,6 +77,13 @@ API float* big32pf(void *n, int sz);
API uint64_t* big64p(void *n, int sz);
API double* big64pf(void *n, int sz);
#define hton16 big16
#define ntoh16 big16
#define hton32 big32
#define ntoh32 big32
#define hton64 big64
#define ntoh64 big64
#define PANIC(...) PANIC(va(__VA_ARGS__), __FILE__, __LINE__) // die() ?
API int (PANIC)(const char *error, const char *file, int line);

27997
engine/v4k
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File diff suppressed because it is too large Load Diff

1274
engine/v4k.c
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File diff suppressed because it is too large Load Diff

175
engine/v4k.h
View File

@ -1511,6 +1511,115 @@ enum AUDIO_FLAGS {
API int audio_queue( const void *samples, int num_samples, int flags );
#line 0
#line 1 "v4k_buffer.h"
// ----------------------------------------------------------------------------
// compression api
enum COMPRESS_FLAGS {
COMPRESS_RAW = 0,
COMPRESS_PPP = (1<<4),
COMPRESS_ULZ = (2<<4),
COMPRESS_LZ4 = (3<<4),
COMPRESS_CRUSH = (4<<4),
COMPRESS_DEFLATE = (5<<4),
COMPRESS_LZP1 = (6<<4),
COMPRESS_LZMA = (7<<4),
COMPRESS_BALZ = (8<<4),
COMPRESS_LZW3 = (9<<4),
COMPRESS_LZSS = (10<<4),
COMPRESS_BCM = (11<<4),
COMPRESS_ZLIB = (12<<4), // same as deflate with header
};
API unsigned zbounds(unsigned inlen, unsigned flags);
API unsigned zencode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
API unsigned zexcess(unsigned flags);
API unsigned zdecode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
// ----------------------------------------------------------------------------
// cobs en/decoding
API unsigned cobs_bounds(unsigned len);
API unsigned cobs_encode(const void *in, unsigned inlen, void *out, unsigned outlen);
API unsigned cobs_decode(const void *in, unsigned inlen, void *out, unsigned outlen);
// ----------------------------------------------------------------------------
// float un/packing: 8 (micro), 16 (half), 32 (float), 64 (double) types
#define pack754_8(f) ( pack754((f), 8, 4))
#define pack754_16(f) ( pack754((f), 16, 5))
#define pack754_32(f) ( pack754((f), 32, 8))
#define pack754_64(f) ( pack754((f), 64, 11))
#define unpack754_8(u) (unpack754((u), 8, 4))
#define unpack754_16(u) (unpack754((u), 16, 5))
#define unpack754_32(u) (unpack754((u), 32, 8))
#define unpack754_64(u) (unpack754((u), 64, 11))
API uint64_t pack754(long double f, unsigned bits, unsigned expbits);
API long double unpack754(uint64_t i, unsigned bits, unsigned expbits);
// ----------------------------------------------------------------------------
// msgpack v5, schema based struct/buffer bitpacking
// api v2
API int msgpack(const char *fmt, ... ); // va arg pack "n,b,u,d/i,s,p,f/g,e,[,{"
API bool msgunpack(const char *fmt, ... ); // va arg pack "n,b,u,d/i,s,p,f/g,e,[,{"
// api v1
API int msgpack_new(uint8_t *w, size_t l);
API int msgpack_nil(); // write null
API int msgpack_chr(bool n); // write boolean
API int msgpack_uns(uint64_t n); // write unsigned integer
API int msgpack_int(int64_t n); // write integer
API int msgpack_str(const char *s); // write string
API int msgpack_bin(const char *s, size_t n); // write binary pointer
API int msgpack_flt(double g); // write real
API int msgpack_ext(uint8_t key, void *val, size_t n); // write extension type
API int msgpack_arr(uint32_t n); // write array mark for next N items
API int msgpack_map(uint32_t n); // write map mark for next N pairs (N keys + N values)
API int msgpack_eof(); // write full?
API int msgpack_err(); // write error?
API bool msgunpack_new( const void *opaque_or_FILE, size_t bytes );
API bool msgunpack_nil();
API bool msgunpack_chr(bool *chr);
API bool msgunpack_uns(uint64_t *uns);
API bool msgunpack_int(int64_t *sig);
API bool msgunpack_str(char **str);
API bool msgunpack_bin(void **bin, uint64_t *len);
API bool msgunpack_flt(float *flt);
API bool msgunpack_dbl(double *dbl);
API bool msgunpack_ext(uint8_t *key, void **val, uint64_t *len);
API bool msgunpack_arr(uint64_t *len);
API bool msgunpack_map(uint64_t *len);
API bool msgunpack_eof();
API bool msgunpack_err();
// alt unpack api v1
enum {
ERR,NIL,BOL,UNS,SIG,STR,BIN,FLT,EXT,ARR,MAP
};
typedef struct variant {
union {
uint8_t chr;
uint64_t uns;
int64_t sig;
uint8_t *str;
void *bin;
double flt;
uint32_t u32;
};
uint64_t sz;
uint16_t ext;
uint16_t type; //[0..10]={err,nil,bol,uns,sig,str,bin,flt,ext,arr,map}
} variant;
API bool msgunpack_var(struct variant *var);
#line 0
#line 1 "v4k_collide.h"
// -----------------------------------------------------------------------------
// original code by @vurtun (PD) and @barerose (CC0).
@ -1743,29 +1852,6 @@ API array(char) xml_blob(char *key);
API void xml_pop();
API bool data_tests();
// compression api
enum COMPRESS_FLAGS {
COMPRESS_RAW = 0,
COMPRESS_PPP = (1<<4),
COMPRESS_ULZ = (2<<4),
COMPRESS_LZ4 = (3<<4),
COMPRESS_CRUSH = (4<<4),
COMPRESS_DEFLATE = (5<<4),
COMPRESS_LZP1 = (6<<4),
COMPRESS_LZMA = (7<<4),
COMPRESS_BALZ = (8<<4),
COMPRESS_LZW3 = (9<<4),
COMPRESS_LZSS = (10<<4),
COMPRESS_BCM = (11<<4),
COMPRESS_ZLIB = (12<<4), // same as deflate with header
};
API unsigned zbounds(unsigned inlen, unsigned flags);
API unsigned zencode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
API unsigned zexcess(unsigned flags);
API unsigned zdecode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags);
#line 0
#line 1 "v4k_dll.h"
@ -2015,6 +2101,35 @@ API void* font_colorize(const char *text, const char *comma_types, const char *c
API vec2 font_highlight(const char *text, const void *colors);
#line 0
#line 1 "v4k_id.h"
// -----------------------------------------------------------------------------
// factory of handle ids, based on code by randy gaul (PD/Zlib licensed)
// - rlyeh, public domain
//
// [src] http://www.randygaul.net/wp-content/uploads/2021/04/handle_table.cpp
// [ref] http://bitsquid.blogspot.com.es/2011/09/managing-decoupling-part-4-id-lookup.html
// [ref] http://glampert.com/2016/05-04/dissecting-idhashindex/
// [ref] https://github.com/nlguillemot/dof/blob/master/viewer/packed_freelist.h
// [ref] https://gist.github.com/pervognsen/ffd89e45b5750e9ce4c6c8589fc7f253
// convert between hard refs (pointers) and weak refs (ids)
uintptr_t id_make(void *ptr);
void * id_handle(uintptr_t id);
void id_dispose(uintptr_t id);
bool id_valid(uintptr_t id);
// configuration:
// ideally, these two should be 32 each. they were changed to fit our OBJHEADER bits
#ifndef ID_INDEX_BITS
#define ID_INDEX_BITS 16
#endif
#ifndef ID_COUNT_BITS
#define ID_COUNT_BITS 3
#endif
// you cannot change this one: the number of ID_DATA_BITS you can store in a handle depends on ID_COUNT_BITS
#define ID_DATA_BITS (64-ID_COUNT_BITS)
#line 0
#line 1 "v4k_input.h"
// -----------------------------------------------------------------------------
// input framework
@ -2168,6 +2283,7 @@ API void* forget( void *ptr );
#define REALLOC(p,n) REALLOC_((p),(n))
#define CALLOC(m,n) CALLOC_((m),(n))
#define STRDUP(s) STRDUP_(s)
#define ALLOCA(n) ifdef(gcc, __builtin_alloca(n), _alloca(n))
static FORCE_INLINE void *(REALLOC_)(void *p, size_t n) { return n ? WATCH(xrealloc(p,n),n) : xrealloc(FORGET(p),0); } ///-
static FORCE_INLINE void *(CALLOC_)(size_t m, size_t n) { return n *= m, memset(REALLOC(0,n),0,n); } ///-
@ -3448,7 +3564,11 @@ API array(uint32_t) string32( const char *utf8 ); /// convert from utf8 to utf32
unsigned intern( const char *string );
const char *quark( unsigned key );
typedef array(char) quarks_db;
typedef struct quarks_db {
array(char) blob;
array(vec2i) entries;
} quarks_db;
unsigned quark_intern( quarks_db*, const char *string );
const char *quark_string( quarks_db*, unsigned key );
#line 0
@ -3580,6 +3700,13 @@ API float* big32pf(void *n, int sz);
API uint64_t* big64p(void *n, int sz);
API double* big64pf(void *n, int sz);
#define hton16 big16
#define ntoh16 big16
#define hton32 big32
#define ntoh32 big32
#define hton64 big64
#define ntoh64 big64
#define PANIC(...) PANIC(va(__VA_ARGS__), __FILE__, __LINE__) // die() ?
API int (PANIC)(const char *error, const char *file, int line);

2
tools/cook.ini
View File

@ -1,4 +1,4 @@
; this is where you specify and configure the FWK pipeline.
; this is where you specify and configure the V4K pipeline.
; tweak the pipeline and add new importers just by editing this file.
; there is no flow control in this script file: lines are parsed and evaluated, from top to bottom.