Merge branch 'master' into x3d_pugi_migration

pull/4079/head
René Martin 2021-09-07 15:04:08 +02:00
parent 6db142ee51
commit 3001d88172
295 changed files with 5518 additions and 11500 deletions

2
.gitignore vendored
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@ -25,7 +25,7 @@ CMakeSettings.json
# Output
bin/
lib/
x64/
# QtCreator
CMakeLists.txt.user

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@ -44,10 +44,10 @@ CMAKE_MINIMUM_REQUIRED( VERSION 3.10 )
option(ASSIMP_HUNTER_ENABLED "Enable Hunter package manager support" OFF)
IF(ASSIMP_HUNTER_ENABLED)
include("cmake/HunterGate.cmake")
include("cmake-modules/HunterGate.cmake")
HunterGate(
URL "https://github.com/cpp-pm/hunter/archive/v0.23.293.tar.gz"
SHA1 "e8e5470652db77149d9b38656db2a6c0b7642693"
URL "https://github.com/cpp-pm/hunter/archive/v0.23.311.tar.gz"
SHA1 "1a82b9b73055879181cb1466b2ab5d48ee8ae410"
)
add_definitions(-DASSIMP_USE_HUNTER)
@ -135,11 +135,11 @@ IF ( WIN32 )
# Use subset of Windows.h
ADD_DEFINITIONS( -DWIN32_LEAN_AND_MEAN )
OPTION ( ASSIMP_BUILD_ASSIMP_VIEW
"If the Assimp view tool is built. (requires DirectX)"
OFF )
IF(MSVC)
OPTION ( ASSIMP_BUILD_ASSIMP_VIEW
"If the Assimp view tool is built. (requires DirectX)"
OFF )
OPTION( ASSIMP_INSTALL_PDB
"Install MSVC debug files."
ON )
@ -268,6 +268,8 @@ ELSEIF(MSVC)
ADD_COMPILE_OPTIONS(/wd4351)
ENDIF()
SET(CMAKE_CXX_FLAGS_DEBUG "${CMAKE_CXX_FLAGS_DEBUG} /D_DEBUG /Zi /Od")
SET(CMAKE_CXX_FLAGS_RELEASE "${CMAKE_CXX_FLAGS_RELEASE} /Zi")
SET(CMAKE_SHARED_LINKER_FLAGS_RELEASE "${CMAKE_SHARED_LINKER_FLAGS_RELEASE} /DEBUG:FULL /PDBALTPATH:%_PDB% /OPT:REF /OPT:ICF")
ELSEIF (CMAKE_CXX_COMPILER_ID MATCHES "Clang" )
IF(NOT ASSIMP_HUNTER_ENABLED)
SET(CMAKE_CXX_STANDARD 11)
@ -395,14 +397,14 @@ set(GENERATED_DIR "${CMAKE_CURRENT_BINARY_DIR}/generated")
IF(ASSIMP_HUNTER_ENABLED)
set(CONFIG_INSTALL_DIR "lib/cmake/${PROJECT_NAME}")
set(CMAKE_CONFIG_TEMPLATE_FILE "cmake/assimp-hunter-config.cmake.in")
set(CMAKE_CONFIG_TEMPLATE_FILE "cmake-modules/assimp-hunter-config.cmake.in")
set(NAMESPACE "${PROJECT_NAME}::")
set(TARGETS_EXPORT_NAME "${PROJECT_NAME}Targets")
set(VERSION_CONFIG "${GENERATED_DIR}/${PROJECT_NAME}ConfigVersion.cmake")
set(PROJECT_CONFIG "${GENERATED_DIR}/${PROJECT_NAME}Config.cmake")
ELSE()
set(CONFIG_INSTALL_DIR "${ASSIMP_LIB_INSTALL_DIR}/cmake/assimp-${ASSIMP_VERSION_MAJOR}.${ASSIMP_VERSION_MINOR}")
set(CMAKE_CONFIG_TEMPLATE_FILE "cmake/assimp-plain-config.cmake.in")
set(CMAKE_CONFIG_TEMPLATE_FILE "cmake-modules/assimp-plain-config.cmake.in")
string(TOLOWER ${PROJECT_NAME} PROJECT_NAME_LOWERCASE)
set(NAMESPACE "${PROJECT_NAME_LOWERCASE}::")
set(TARGETS_EXPORT_NAME "${PROJECT_NAME_LOWERCASE}Targets")

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@ -1,17 +0,0 @@
# Find IrrXMl from irrlicht project
#
# Find LibIrrXML headers and library
#
# IRRXML_FOUND - IrrXML found
# IRRXML_INCLUDE_DIR - Headers location
# IRRXML_LIBRARY - IrrXML main library
find_path(IRRXML_INCLUDE_DIR irrXML.h
PATH_SUFFIXES include/irrlicht include/irrxml)
find_library(IRRXML_LIBRARY IrrXML)
include(FindPackageHandleStandardArgs)
find_package_handle_standard_args(IrrXML REQUIRED_VARS IRRXML_INCLUDE_DIR IRRXML_LIBRARY)
mark_as_advanced(IRRXML_INCLUDE_DIR IRRXML_LIBRARY)

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@ -0,0 +1,19 @@
@PACKAGE_INIT@
find_package(RapidJSON CONFIG REQUIRED)
find_package(ZLIB CONFIG REQUIRED)
find_package(utf8cpp CONFIG REQUIRED)
find_package(minizip CONFIG REQUIRED)
find_package(openddlparser CONFIG REQUIRED)
find_package(poly2tri CONFIG REQUIRED)
find_package(polyclipping CONFIG REQUIRED)
find_package(zip CONFIG REQUIRED)
find_package(pugixml CONFIG REQUIRED)
find_package(stb CONFIG REQUIRED)
if(@ASSIMP_BUILD_DRACO@)
find_package(draco CONFIG REQUIRED)
endif()
include("${CMAKE_CURRENT_LIST_DIR}/@TARGETS_EXPORT_NAME@.cmake")
check_required_components("@PROJECT_NAME@")

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@ -1,18 +0,0 @@
@PACKAGE_INIT@
find_package(RapidJSON CONFIG REQUIRED)
find_package(ZLIB CONFIG REQUIRED)
find_package(utf8cpp CONFIG REQUIRED)
find_package(minizip CONFIG REQUIRED)
find_package(openddlparser CONFIG REQUIRED)
find_package(poly2tri CONFIG REQUIRED)
find_package(polyclipping CONFIG REQUIRED)
find_package(zip CONFIG REQUIRED)
find_package(pugixml CONFIG REQUIRED)
if(@ASSIMP_BUILD_DRACO@)
find_package(draco CONFIG REQUIRED)
endif()
include("${CMAKE_CURRENT_LIST_DIR}/@TARGETS_EXPORT_NAME@.cmake")
check_required_components("@PROJECT_NAME@")

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@ -68,8 +68,8 @@ void Discreet3DSImporter::ReplaceDefaultMaterial() {
unsigned int idx(NotSet);
for (unsigned int i = 0; i < mScene->mMaterials.size(); ++i) {
std::string s = mScene->mMaterials[i].mName;
for (std::string::iterator it = s.begin(); it != s.end(); ++it) {
*it = static_cast<char>(::tolower(static_cast<unsigned char>(*it)));
for (char & it : s) {
it = static_cast<char>(::tolower(static_cast<unsigned char>(it)));
}
if (std::string::npos == s.find("default")) continue;
@ -79,12 +79,7 @@ void Discreet3DSImporter::ReplaceDefaultMaterial() {
mScene->mMaterials[i].mDiffuse.r !=
mScene->mMaterials[i].mDiffuse.b) continue;
if (mScene->mMaterials[i].sTexDiffuse.mMapName.length() != 0 ||
mScene->mMaterials[i].sTexBump.mMapName.length() != 0 ||
mScene->mMaterials[i].sTexOpacity.mMapName.length() != 0 ||
mScene->mMaterials[i].sTexEmissive.mMapName.length() != 0 ||
mScene->mMaterials[i].sTexSpecular.mMapName.length() != 0 ||
mScene->mMaterials[i].sTexShininess.mMapName.length() != 0) {
if (ContainsTextures(i)) {
continue;
}
idx = i;

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@ -291,7 +291,7 @@ void Discreet3DSExporter::WriteMaterials() {
ChunkWriter curChunk(writer, Discreet3DS::CHUNK_MAT_SPECULAR);
WriteColor(color);
}
if (mat.Get(AI_MATKEY_COLOR_AMBIENT, color) == AI_SUCCESS) {
ChunkWriter curChunk(writer, Discreet3DS::CHUNK_MAT_AMBIENT);
WriteColor(color);

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@ -348,16 +348,16 @@ struct Texture {
// empty
}
Texture(Texture &&other) AI_NO_EXCEPT : mTextureBlend(std::move(other.mTextureBlend)),
Texture(Texture &&other) AI_NO_EXCEPT : mTextureBlend(other.mTextureBlend),
mMapName(std::move(other.mMapName)),
mOffsetU(std::move(other.mOffsetU)),
mOffsetV(std::move(other.mOffsetV)),
mScaleU(std::move(other.mScaleU)),
mScaleV(std::move(other.mScaleV)),
mRotation(std::move(other.mRotation)),
mMapMode(std::move(other.mMapMode)),
bPrivate(std::move(other.bPrivate)),
iUVSrc(std::move(other.iUVSrc)) {
mOffsetU(other.mOffsetU),
mOffsetV(other.mOffsetV),
mScaleU(other.mScaleU),
mScaleV(other.mScaleV),
mRotation(other.mRotation),
mMapMode(other.mMapMode),
bPrivate(other.bPrivate),
iUVSrc(other.iUVSrc) {
// empty
}
@ -366,16 +366,16 @@ struct Texture {
return *this;
}
mTextureBlend = std::move(other.mTextureBlend);
mTextureBlend = other.mTextureBlend;
mMapName = std::move(other.mMapName);
mOffsetU = std::move(other.mOffsetU);
mOffsetV = std::move(other.mOffsetV);
mScaleU = std::move(other.mScaleU);
mScaleV = std::move(other.mScaleV);
mRotation = std::move(other.mRotation);
mMapMode = std::move(other.mMapMode);
bPrivate = std::move(other.bPrivate);
iUVSrc = std::move(other.iUVSrc);
mOffsetU = other.mOffsetU;
mOffsetV = other.mOffsetV;
mScaleU = other.mScaleU;
mScaleV = other.mScaleV;
mRotation = other.mRotation;
mMapMode = other.mMapMode;
bPrivate = other.bPrivate;
iUVSrc = other.iUVSrc;
return *this;
}
@ -461,13 +461,13 @@ struct Material {
//! Move constructor. This is explicitly written because MSVC doesn't support defaulting it
Material(Material &&other) AI_NO_EXCEPT : mName(std::move(other.mName)),
mDiffuse(std::move(other.mDiffuse)),
mSpecularExponent(std::move(other.mSpecularExponent)),
mShininessStrength(std::move(other.mShininessStrength)),
mSpecular(std::move(other.mSpecular)),
mAmbient(std::move(other.mAmbient)),
mShading(std::move(other.mShading)),
mTransparency(std::move(other.mTransparency)),
mDiffuse(other.mDiffuse),
mSpecularExponent(other.mSpecularExponent),
mShininessStrength(other.mShininessStrength),
mSpecular(other.mSpecular),
mAmbient(other.mAmbient),
mShading(other.mShading),
mTransparency(other.mTransparency),
sTexDiffuse(std::move(other.sTexDiffuse)),
sTexOpacity(std::move(other.sTexOpacity)),
sTexSpecular(std::move(other.sTexSpecular)),
@ -475,10 +475,10 @@ struct Material {
sTexBump(std::move(other.sTexBump)),
sTexEmissive(std::move(other.sTexEmissive)),
sTexShininess(std::move(other.sTexShininess)),
mBumpHeight(std::move(other.mBumpHeight)),
mEmissive(std::move(other.mEmissive)),
mBumpHeight(other.mBumpHeight),
mEmissive(other.mEmissive),
sTexAmbient(std::move(other.sTexAmbient)),
mTwoSided(std::move(other.mTwoSided)) {
mTwoSided(other.mTwoSided) {
// empty
}
@ -488,13 +488,13 @@ struct Material {
}
mName = std::move(other.mName);
mDiffuse = std::move(other.mDiffuse);
mSpecularExponent = std::move(other.mSpecularExponent);
mShininessStrength = std::move(other.mShininessStrength),
mSpecular = std::move(other.mSpecular);
mAmbient = std::move(other.mAmbient);
mShading = std::move(other.mShading);
mTransparency = std::move(other.mTransparency);
mDiffuse = other.mDiffuse;
mSpecularExponent = other.mSpecularExponent;
mShininessStrength = other.mShininessStrength,
mSpecular = other.mSpecular;
mAmbient = other.mAmbient;
mShading = other.mShading;
mTransparency = other.mTransparency;
sTexDiffuse = std::move(other.sTexDiffuse);
sTexOpacity = std::move(other.sTexOpacity);
sTexSpecular = std::move(other.sTexSpecular);
@ -502,10 +502,10 @@ struct Material {
sTexBump = std::move(other.sTexBump);
sTexEmissive = std::move(other.sTexEmissive);
sTexShininess = std::move(other.sTexShininess);
mBumpHeight = std::move(other.mBumpHeight);
mEmissive = std::move(other.mEmissive);
mBumpHeight = other.mBumpHeight;
mEmissive = other.mEmissive;
sTexAmbient = std::move(other.sTexAmbient);
mTwoSided = std::move(other.mTwoSided);
mTwoSided = other.mTwoSided;
return *this;
}

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@ -208,6 +208,15 @@ protected:
*/
void ReplaceDefaultMaterial();
bool ContainsTextures(unsigned int i) const {
return !mScene->mMaterials[i].sTexDiffuse.mMapName.empty() ||
!mScene->mMaterials[i].sTexBump.mMapName.empty() ||
!mScene->mMaterials[i].sTexOpacity.mMapName.empty() ||
!mScene->mMaterials[i].sTexEmissive.mMapName.empty() ||
!mScene->mMaterials[i].sTexSpecular.mMapName.empty() ||
!mScene->mMaterials[i].sTexShininess.mMapName.empty() ;
}
// -------------------------------------------------------------------
/** Convert the whole scene
*/

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@ -0,0 +1,165 @@
/*
Open Asset Import Library (assimp)
----------------------------------------------------------------------
Copyright (c) 2006-2021, assimp team
All rights reserved.
Redistribution and use of this software in source and binary forms,
with or without modification, are permitted provided that the
following conditions are met:
* Redistributions of source code must retain the above
copyright notice, this list of conditions and the
following disclaimer.
* 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.
* Neither the name of the assimp team, nor the names of its
contributors may be used to endorse or promote products
derived from this software without specific prior
written permission of the assimp team.
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
OWNER 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.
----------------------------------------------------------------------
*/
#pragma once
#include <assimp/vector3.h>
#include <assimp/matrix4x4.h>
#include <assimp/ParsingUtils.h>
#include <vector>
#include <string>
struct aiMaterial;
struct aiMesh;
namespace Assimp {
namespace D3MF {
enum class ResourceType {
RT_Object,
RT_BaseMaterials,
RT_EmbeddedTexture2D,
RT_Texture2DGroup,
RT_Unknown
}; // To be extended with other resource types (eg. material extension resources like Texture2d, Texture2dGroup...)
class Resource {
public:
int mId;
Resource(int id) :
mId(id) {
// empty
}
virtual ~Resource() {
// empty
}
virtual ResourceType getType() const {
return ResourceType::RT_Unknown;
}
};
class EmbeddedTexture : public Resource {
public:
std::string mPath;
std::string mContentType;
std::string mTilestyleU;
std::string mTilestyleV;
std::vector<char> mBuffer;
EmbeddedTexture(int id) :
Resource(id),
mPath(),
mContentType(),
mTilestyleU(),
mTilestyleV() {
// empty
}
~EmbeddedTexture() = default;
ResourceType getType() const override {
return ResourceType::RT_EmbeddedTexture2D;
}
};
class Texture2DGroup : public Resource {
public:
std::vector<aiVector2D> mTex2dCoords;
int mTexId;
Texture2DGroup(int id) :
Resource(id),
mTexId(-1) {
// empty
}
~Texture2DGroup() = default;
ResourceType getType() const override {
return ResourceType::RT_Texture2DGroup;
}
};
class BaseMaterials : public Resource {
public:
std::vector<unsigned int> mMaterialIndex;
BaseMaterials(int id) :
Resource(id),
mMaterialIndex() {
// empty
}
~BaseMaterials() = default;
ResourceType getType() const override {
return ResourceType::RT_BaseMaterials;
}
};
struct Component {
int mObjectId;
aiMatrix4x4 mTransformation;
};
class Object : public Resource {
public:
std::vector<aiMesh *> mMeshes;
std::vector<unsigned int> mMeshIndex;
std::vector<Component> mComponents;
std::string mName;
Object(int id) :
Resource(id),
mName(std::string("Object_") + ai_to_string(id)) {
// empty
}
~Object() = default;
ResourceType getType() const override {
return ResourceType::RT_Object;
}
};
} // namespace D3MF
} // namespace Assimp

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@ -80,13 +80,21 @@ namespace XmlTag {
const char* const item = "item";
const char* const objectid = "objectid";
const char* const transform = "transform";
const char *const path = "path";
// Material definitions
const char* const basematerials = "basematerials";
const char* const basematerials_id = "id";
const char* const basematerials_base = "base";
const char* const basematerials_name = "name";
const char* const basematerials_displaycolor = "displaycolor";
const char* const texture_2d = "m:texture2d";
const char *const texture_group = "m:texture2dgroup";
const char *const texture_content_type = "contenttype";
const char *const texture_tilestyleu = "tilestyleu";
const char *const texture_tilestylev = "tilestylev";
const char *const texture_2d_coord = "m:tex2coord";
const char *const texture_cuurd_u = "u";
const char *const texture_cuurd_v = "v";
// Meta info tags
const char* const CONTENT_TYPES_ARCHIVE = "[Content_Types].xml";
@ -103,7 +111,7 @@ namespace XmlTag {
const char* const PACKAGE_TEXTURE_RELATIONSHIP_TYPE = "http://schemas.microsoft.com/3dmanufacturing/2013/01/3dtexture";
const char* const PACKAGE_CORE_PROPERTIES_RELATIONSHIP_TYPE = "http://schemas.openxmlformats.org/package/2006/relationships/metadata/core-properties";
const char* const PACKAGE_THUMBNAIL_RELATIONSHIP_TYPE = "http://schemas.openxmlformats.org/package/2006/relationships/metadata/thumbnail";
}
}
} // Namespace D3MF
} // Namespace Assimp

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@ -44,6 +44,7 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "D3MFImporter.h"
#include "3MFXmlTags.h"
#include "D3MFOpcPackage.h"
#include "XmlSerializer.h"
#include <assimp/StringComparison.h>
#include <assimp/StringUtils.h>
@ -61,513 +62,9 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include <string>
#include <vector>
#include <iomanip>
#include <string.h>
#include <cstring>
namespace Assimp {
namespace D3MF {
enum class ResourceType {
RT_Object,
RT_BaseMaterials,
RT_Unknown
}; // To be extended with other resource types (eg. material extension resources like Texture2d, Texture2dGroup...)
class Resource {
public:
int mId;
Resource(int id) :
mId(id) {
// empty
}
virtual ~Resource() {
// empty
}
virtual ResourceType getType() const {
return ResourceType::RT_Unknown;
}
};
class BaseMaterials : public Resource {
public:
std::vector<aiMaterial *> mMaterials;
std::vector<unsigned int> mMaterialIndex;
BaseMaterials(int id) :
Resource(id),
mMaterials(),
mMaterialIndex() {
// empty
}
~BaseMaterials() = default;
ResourceType getType() const override {
return ResourceType::RT_BaseMaterials;
}
};
struct Component {
int mObjectId;
aiMatrix4x4 mTransformation;
};
class Object : public Resource {
public:
std::vector<aiMesh *> mMeshes;
std::vector<unsigned int> mMeshIndex;
std::vector<Component> mComponents;
std::string mName;
Object(int id) :
Resource(id),
mName(std::string("Object_") + ai_to_string(id)) {
// empty
}
~Object() = default;
ResourceType getType() const override {
return ResourceType::RT_Object;
}
};
class XmlSerializer {
public:
XmlSerializer(XmlParser *xmlParser) :
mResourcesDictionnary(),
mMaterialCount(0),
mMeshCount(0),
mXmlParser(xmlParser) {
// empty
}
~XmlSerializer() {
for (auto it = mResourcesDictionnary.begin(); it != mResourcesDictionnary.end(); ++it ) {
delete it->second;
}
}
void ImportXml(aiScene *scene) {
if (nullptr == scene) {
return;
}
scene->mRootNode = new aiNode(XmlTag::RootTag);
XmlNode node = mXmlParser->getRootNode().child(XmlTag::model);
if (node.empty()) {
return;
}
XmlNode resNode = node.child(XmlTag::resources);
for (auto &currentNode : resNode.children()) {
const std::string currentNodeName = currentNode.name();
if (currentNodeName == XmlTag::object) {
ReadObject(currentNode);
} else if (currentNodeName == XmlTag::basematerials) {
ReadBaseMaterials(currentNode);
} else if (currentNodeName == XmlTag::meta) {
ReadMetadata(currentNode);
}
}
XmlNode buildNode = node.child(XmlTag::build);
for (auto &currentNode : buildNode.children()) {
const std::string currentNodeName = currentNode.name();
if (currentNodeName == XmlTag::item) {
int objectId = -1;
std::string transformationMatrixStr;
aiMatrix4x4 transformationMatrix;
getNodeAttribute(currentNode, D3MF::XmlTag::objectid, objectId);
bool hasTransform = getNodeAttribute(currentNode, D3MF::XmlTag::transform, transformationMatrixStr);
auto it = mResourcesDictionnary.find(objectId);
if (it != mResourcesDictionnary.end() && it->second->getType() == ResourceType::RT_Object) {
Object *obj = static_cast<Object *>(it->second);
if (hasTransform) {
transformationMatrix = parseTransformMatrix(transformationMatrixStr);
}
addObjectToNode(scene->mRootNode, obj, transformationMatrix);
}
}
}
// import the metadata
if (!mMetaData.empty()) {
const size_t numMeta = mMetaData.size();
scene->mMetaData = aiMetadata::Alloc(static_cast<unsigned int>(numMeta));
for (size_t i = 0; i < numMeta; ++i) {
aiString val(mMetaData[i].value);
scene->mMetaData->Set(static_cast<unsigned int>(i), mMetaData[i].name, val);
}
}
// import the meshes
scene->mNumMeshes = static_cast<unsigned int>(mMeshCount);
if (scene->mNumMeshes != 0) {
scene->mMeshes = new aiMesh *[scene->mNumMeshes]();
for (auto it = mResourcesDictionnary.begin(); it != mResourcesDictionnary.end(); ++it) {
if (it->second->getType() == ResourceType::RT_Object) {
Object *obj = static_cast<Object *>(it->second);
ai_assert(nullptr != obj);
for (unsigned int i = 0; i < obj->mMeshes.size(); ++i) {
scene->mMeshes[obj->mMeshIndex[i]] = obj->mMeshes[i];
}
}
}
}
// import the materials
scene->mNumMaterials = mMaterialCount;
if (scene->mNumMaterials != 0) {
scene->mMaterials = new aiMaterial *[scene->mNumMaterials];
for (auto it = mResourcesDictionnary.begin(); it != mResourcesDictionnary.end(); ++it) {
if (it->second->getType() == ResourceType::RT_BaseMaterials) {
BaseMaterials *baseMaterials = static_cast<BaseMaterials *>(it->second);
for (unsigned int i = 0; i < baseMaterials->mMaterials.size(); ++i) {
scene->mMaterials[baseMaterials->mMaterialIndex[i]] = baseMaterials->mMaterials[i];
}
}
}
}
}
private:
void addObjectToNode(aiNode *parent, Object *obj, aiMatrix4x4 nodeTransform) {
ai_assert(nullptr != obj);
aiNode *sceneNode = new aiNode(obj->mName);
sceneNode->mNumMeshes = static_cast<unsigned int>(obj->mMeshes.size());
sceneNode->mMeshes = new unsigned int[sceneNode->mNumMeshes];
std::copy(obj->mMeshIndex.begin(), obj->mMeshIndex.end(), sceneNode->mMeshes);
sceneNode->mTransformation = nodeTransform;
if (nullptr != parent) {
parent->addChildren(1, &sceneNode);
}
for (size_t i = 0; i < obj->mComponents.size(); ++i) {
Component c = obj->mComponents[i];
auto it = mResourcesDictionnary.find(c.mObjectId);
if (it != mResourcesDictionnary.end() && it->second->getType() == ResourceType::RT_Object) {
addObjectToNode(sceneNode, static_cast<Object *>(it->second), c.mTransformation);
}
}
}
bool getNodeAttribute(const XmlNode &node, const std::string &attribute, std::string &value) {
pugi::xml_attribute objectAttribute = node.attribute(attribute.c_str());
if (!objectAttribute.empty()) {
value = objectAttribute.as_string();
return true;
}
return false;
}
bool getNodeAttribute(const XmlNode &node, const std::string &attribute, int &value) {
std::string strValue;
bool ret = getNodeAttribute(node, attribute, strValue);
if (ret) {
value = std::atoi(strValue.c_str());
return true;
}
return false;
}
aiMatrix4x4 parseTransformMatrix(std::string matrixStr) {
// split the string
std::vector<float> numbers;
std::string currentNumber;
for (size_t i = 0; i < matrixStr.size(); ++i) {
const char c = matrixStr[i];
if (c == ' ') {
if (currentNumber.size() > 0) {
float f = std::stof(currentNumber);
numbers.push_back(f);
currentNumber.clear();
}
} else {
currentNumber.push_back(c);
}
}
if (currentNumber.size() > 0) {
const float f = std::stof(currentNumber);
numbers.push_back(f);
}
aiMatrix4x4 transformMatrix;
transformMatrix.a1 = numbers[0];
transformMatrix.b1 = numbers[1];
transformMatrix.c1 = numbers[2];
transformMatrix.d1 = 0;
transformMatrix.a2 = numbers[3];
transformMatrix.b2 = numbers[4];
transformMatrix.c2 = numbers[5];
transformMatrix.d2 = 0;
transformMatrix.a3 = numbers[6];
transformMatrix.b3 = numbers[7];
transformMatrix.c3 = numbers[8];
transformMatrix.d3 = 0;
transformMatrix.a4 = numbers[9];
transformMatrix.b4 = numbers[10];
transformMatrix.c4 = numbers[11];
transformMatrix.d4 = 1;
return transformMatrix;
}
void ReadObject(XmlNode &node) {
int id = -1, pid = -1, pindex = -1;
bool hasId = getNodeAttribute(node, XmlTag::id, id);
bool hasPid = getNodeAttribute(node, XmlTag::pid, pid);
bool hasPindex = getNodeAttribute(node, XmlTag::pindex, pindex);
if (!hasId) {
return;
}
Object *obj = new Object(id);
for (XmlNode &currentNode : node.children()) {
const std::string &currentName = currentNode.name();
if (currentName == D3MF::XmlTag::mesh) {
auto mesh = ReadMesh(currentNode);
mesh->mName.Set(ai_to_string(id));
if (hasPid) {
auto it = mResourcesDictionnary.find(pid);
if (hasPindex && it != mResourcesDictionnary.end() && it->second->getType() == ResourceType::RT_BaseMaterials) {
BaseMaterials *materials = static_cast<BaseMaterials *>(it->second);
mesh->mMaterialIndex = materials->mMaterialIndex[pindex];
}
}
obj->mMeshes.push_back(mesh);
obj->mMeshIndex.push_back(mMeshCount);
mMeshCount++;
} else if (currentName == D3MF::XmlTag::components) {
for (XmlNode &currentSubNode : currentNode.children()) {
const std::string subNodeName = currentSubNode.name();
if (subNodeName == D3MF::XmlTag::component) {
int objectId = -1;
std::string componentTransformStr;
aiMatrix4x4 componentTransform;
if (getNodeAttribute(currentSubNode, D3MF::XmlTag::transform, componentTransformStr)) {
componentTransform = parseTransformMatrix(componentTransformStr);
}
if (getNodeAttribute(currentSubNode, D3MF::XmlTag::objectid, objectId)) {
obj->mComponents.push_back({ objectId, componentTransform });
}
}
}
}
}
mResourcesDictionnary.insert(std::make_pair(id, obj));
}
aiMesh *ReadMesh(XmlNode &node) {
aiMesh *mesh = new aiMesh();
for (XmlNode &currentNode : node.children()) {
const std::string currentName = currentNode.name();
if (currentName == XmlTag::vertices) {
ImportVertices(currentNode, mesh);
} else if (currentName == XmlTag::triangles) {
ImportTriangles(currentNode, mesh);
}
}
return mesh;
}
void ReadMetadata(XmlNode &node) {
pugi::xml_attribute attribute = node.attribute(D3MF::XmlTag::meta_name);
const std::string name = attribute.as_string();
const std::string value = node.value();
if (name.empty()) {
return;
}
MetaEntry entry;
entry.name = name;
entry.value = value;
mMetaData.push_back(entry);
}
void ImportVertices(XmlNode &node, aiMesh *mesh) {
std::vector<aiVector3D> vertices;
for (XmlNode &currentNode : node.children()) {
const std::string currentName = currentNode.name();
if (currentName == XmlTag::vertex) {
vertices.push_back(ReadVertex(currentNode));
}
}
mesh->mNumVertices = static_cast<unsigned int>(vertices.size());
mesh->mVertices = new aiVector3D[mesh->mNumVertices];
std::copy(vertices.begin(), vertices.end(), mesh->mVertices);
}
aiVector3D ReadVertex(XmlNode &node) {
aiVector3D vertex;
vertex.x = ai_strtof(node.attribute(XmlTag::x).as_string(), nullptr);
vertex.y = ai_strtof(node.attribute(XmlTag::y).as_string(), nullptr);
vertex.z = ai_strtof(node.attribute(XmlTag::z).as_string(), nullptr);
return vertex;
}
void ImportTriangles(XmlNode &node, aiMesh *mesh) {
std::vector<aiFace> faces;
for (XmlNode &currentNode : node.children()) {
const std::string currentName = currentNode.name();
if (currentName == XmlTag::triangle) {
aiFace face = ReadTriangle(currentNode);
faces.push_back(face);
int pid = 0, p1 = 0;
bool hasPid = getNodeAttribute(currentNode, D3MF::XmlTag::pid, pid);
bool hasP1 = getNodeAttribute(currentNode, D3MF::XmlTag::p1, p1);
if (hasPid && hasP1) {
auto it = mResourcesDictionnary.find(pid);
if (it != mResourcesDictionnary.end()) {
if (it->second->getType() == ResourceType::RT_BaseMaterials) {
BaseMaterials *baseMaterials = static_cast<BaseMaterials *>(it->second);
mesh->mMaterialIndex = baseMaterials->mMaterialIndex[p1];
}
// TODO: manage the separation into several meshes if the triangles of the mesh do not all refer to the same material
}
}
}
}
mesh->mNumFaces = static_cast<unsigned int>(faces.size());
mesh->mFaces = new aiFace[mesh->mNumFaces];
mesh->mPrimitiveTypes = aiPrimitiveType_TRIANGLE;
std::copy(faces.begin(), faces.end(), mesh->mFaces);
}
aiFace ReadTriangle(XmlNode &node) {
aiFace face;
face.mNumIndices = 3;
face.mIndices = new unsigned int[face.mNumIndices];
face.mIndices[0] = static_cast<unsigned int>(std::atoi(node.attribute(XmlTag::v1).as_string()));
face.mIndices[1] = static_cast<unsigned int>(std::atoi(node.attribute(XmlTag::v2).as_string()));
face.mIndices[2] = static_cast<unsigned int>(std::atoi(node.attribute(XmlTag::v3).as_string()));
return face;
}
void ReadBaseMaterials(XmlNode &node) {
int id = -1;
if (getNodeAttribute(node, D3MF::XmlTag::basematerials_id, id)) {
BaseMaterials *baseMaterials = new BaseMaterials(id);
for (XmlNode &currentNode : node.children()) {
const std::string currentName = currentNode.name();
if (currentName == XmlTag::basematerials_base) {
baseMaterials->mMaterialIndex.push_back(mMaterialCount);
baseMaterials->mMaterials.push_back(readMaterialDef(currentNode, id));
++mMaterialCount;
}
}
mResourcesDictionnary.insert(std::make_pair(id, baseMaterials));
}
}
bool parseColor(const char *color, aiColor4D &diffuse) {
if (nullptr == color) {
return false;
}
//format of the color string: #RRGGBBAA or #RRGGBB (3MF Core chapter 5.1.1)
const size_t len = strlen(color);
if (9 != len && 7 != len) {
return false;
}
const char *buf(color);
if ('#' != buf[0]) {
return false;
}
char r[3] = { buf[1], buf[2], '\0' };
diffuse.r = static_cast<ai_real>(strtol(r, nullptr, 16)) / ai_real(255.0);
char g[3] = { buf[3], buf[4], '\0' };
diffuse.g = static_cast<ai_real>(strtol(g, nullptr, 16)) / ai_real(255.0);
char b[3] = { buf[5], buf[6], '\0' };
diffuse.b = static_cast<ai_real>(strtol(b, nullptr, 16)) / ai_real(255.0);
if (7 == len)
return true;
char a[3] = { buf[7], buf[8], '\0' };
diffuse.a = static_cast<ai_real>(strtol(a, nullptr, 16)) / ai_real(255.0);
return true;
}
void assignDiffuseColor(XmlNode &node, aiMaterial *mat) {
const char *color = node.attribute(XmlTag::basematerials_displaycolor).as_string();
aiColor4D diffuse;
if (parseColor(color, diffuse)) {
mat->AddProperty<aiColor4D>(&diffuse, 1, AI_MATKEY_COLOR_DIFFUSE);
}
}
aiMaterial *readMaterialDef(XmlNode &node, unsigned int basematerialsId) {
aiMaterial *material = new aiMaterial();
material->mNumProperties = 0;
std::string name;
bool hasName = getNodeAttribute(node, D3MF::XmlTag::basematerials_name, name);
std::string stdMaterialName;
const std::string strId(ai_to_string(basematerialsId));
stdMaterialName += "id";
stdMaterialName += strId;
stdMaterialName += "_";
if (hasName) {
stdMaterialName += std::string(name);
} else {
stdMaterialName += "basemat_";
stdMaterialName += ai_to_string(mMaterialCount - basematerialsId);
}
aiString assimpMaterialName(stdMaterialName);
material->AddProperty(&assimpMaterialName, AI_MATKEY_NAME);
assignDiffuseColor(node, material);
return material;
}
private:
struct MetaEntry {
std::string name;
std::string value;
};
std::vector<MetaEntry> mMetaData;
std::map<unsigned int, Resource *> mResourcesDictionnary;
unsigned int mMaterialCount, mMeshCount;
XmlParser *mXmlParser;
};
} //namespace D3MF
using namespace D3MF;
@ -597,7 +94,9 @@ bool D3MFImporter::CanRead(const std::string &filename, IOSystem *pIOHandler, bo
const std::string extension(GetExtension(filename));
if (extension == desc.mFileExtensions) {
return true;
} else if (!extension.length() || checkSig) {
}
if (!extension.length() || checkSig) {
if (nullptr == pIOHandler) {
return false;
}
@ -611,7 +110,7 @@ bool D3MFImporter::CanRead(const std::string &filename, IOSystem *pIOHandler, bo
return false;
}
void D3MFImporter::SetupProperties(const Importer * /*pImp*/) {
void D3MFImporter::SetupProperties(const Importer*) {
// empty
}
@ -626,6 +125,15 @@ void D3MFImporter::InternReadFile(const std::string &filename, aiScene *pScene,
if (xmlParser.parse(opcPackage.RootStream())) {
XmlSerializer xmlSerializer(&xmlParser);
xmlSerializer.ImportXml(pScene);
const std::vector<aiTexture*> &tex = opcPackage.GetEmbeddedTextures();
if (!tex.empty()) {
pScene->mNumTextures = static_cast<unsigned int>(tex.size());
pScene->mTextures = new aiTexture *[pScene->mNumTextures];
for (unsigned int i = 0; i < pScene->mNumTextures; ++i) {
pScene->mTextures[i] = tex[i];
}
}
}
}

View File

@ -4,7 +4,6 @@ Open Asset Import Library (assimp)
Copyright (c) 2006-2021, assimp team
All rights reserved.
Redistribution and use of this software in source and binary forms,
@ -47,17 +46,40 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
namespace Assimp {
// ---------------------------------------------------------------------------
/// @brief The 3MF-importer class.
///
/// Implements the basic topology import and embedded textures.
// ---------------------------------------------------------------------------
class D3MFImporter : public BaseImporter {
public:
/// @brief The default class constructor.
D3MFImporter();
~D3MFImporter();
bool CanRead(const std::string &pFile, IOSystem *pIOHandler, bool checkSig) const;
void SetupProperties(const Importer *pImp);
const aiImporterDesc *GetInfo() const;
/// @brief The class destructor.
~D3MFImporter() override;
/// @brief Performs the data format detection.
/// @param pFile The filename to check.
/// @param pIOHandler The used IO-System.
/// @param checkSig true for signature checking.
/// @return true for can be loaded, false for not.
bool CanRead(const std::string &pFile, IOSystem *pIOHandler, bool checkSig) const override;
/// @brief Not used
/// @param pImp Not used
void SetupProperties(const Importer *pImp) override;
/// @brief The importer description getter.
/// @return The info
const aiImporterDesc *GetInfo() const override;
protected:
void InternReadFile(const std::string &pFile, aiScene *pScene, IOSystem *pIOHandler);
/// @brief Internal read function, performs the file parsing.
/// @param pFile The filename
/// @param pScene The scene to load in.
/// @param pIOHandler The io-system
void InternReadFile(const std::string &pFile, aiScene *pScene, IOSystem *pIOHandler) override;
};
} // Namespace Assimp

View File

@ -43,14 +43,13 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "D3MFOpcPackage.h"
#include <assimp/Exceptional.h>
#include <assimp/XmlParser.h>
#include <assimp/ZipArchiveIOSystem.h>
#include <assimp/ai_assert.h>
#include <assimp/DefaultLogger.hpp>
#include <assimp/IOStream.hpp>
#include <assimp/IOSystem.hpp>
#include <assimp/texture.h>
#include "3MFXmlTags.h"
#include <algorithm>
#include <cassert>
@ -64,11 +63,12 @@ namespace Assimp {
namespace D3MF {
// ------------------------------------------------------------------------------------------------
typedef std::shared_ptr<OpcPackageRelationship> OpcPackageRelationshipPtr;
using OpcPackageRelationshipPtr = std::shared_ptr<OpcPackageRelationship>;
class OpcPackageRelationshipReader {
public:
OpcPackageRelationshipReader(XmlParser &parser) {
OpcPackageRelationshipReader(XmlParser &parser) :
m_relationShips() {
XmlNode root = parser.getRootNode();
ParseRootNode(root);
}
@ -91,6 +91,7 @@ public:
if (relPtr->id.empty() || relPtr->type.empty() || relPtr->target.empty()) {
return false;
}
return true;
}
@ -100,7 +101,7 @@ public:
}
for (XmlNode currentNode = node.first_child(); currentNode; currentNode = currentNode.next_sibling()) {
std::string name = currentNode.name();
const std::string name = currentNode.name();
if (name == "Relationship") {
OpcPackageRelationshipPtr relPtr(new OpcPackageRelationship());
relPtr->id = currentNode.attribute(XmlTag::RELS_ATTRIB_ID).as_string();
@ -116,11 +117,23 @@ public:
std::vector<OpcPackageRelationshipPtr> m_relationShips;
};
static bool IsEmbeddedTexture( const std::string &filename ) {
const std::string extension = BaseImporter::GetExtension(filename);
if (extension == "jpg" || extension == "png") {
std::string::size_type pos = filename.find("thumbnail");
if (pos == std::string::npos) {
return false;
}
return true;
}
return false;
}
// ------------------------------------------------------------------------------------------------
D3MFOpcPackage::D3MFOpcPackage(IOSystem *pIOHandler, const std::string &rFile) :
mRootStream(nullptr),
mZipArchive() {
mZipArchive.reset(new ZipArchiveIOSystem(pIOHandler, rFile));
mZipArchive = new ZipArchiveIOSystem(pIOHandler, rFile);
if (!mZipArchive->isOpen()) {
throw DeadlyImportError("Failed to open file ", rFile, ".");
}
@ -141,13 +154,13 @@ D3MFOpcPackage::D3MFOpcPackage(IOSystem *pIOHandler, const std::string &rFile) :
}
std::string rootFile = ReadPackageRootRelationship(fileStream);
if (rootFile.size() > 0 && rootFile[0] == '/') {
if (!rootFile.empty() && rootFile[0] == '/') {
rootFile = rootFile.substr(1);
if (rootFile[0] == '/') {
// deal with zip-bug
rootFile = rootFile.substr(1);
}
}
}
ASSIMP_LOG_VERBOSE_DEBUG(rootFile);
@ -158,9 +171,12 @@ D3MFOpcPackage::D3MFOpcPackage(IOSystem *pIOHandler, const std::string &rFile) :
if (nullptr == mRootStream) {
throw DeadlyImportError("Cannot open root-file in archive : " + rootFile);
}
} else if (file == D3MF::XmlTag::CONTENT_TYPES_ARCHIVE) {
ASSIMP_LOG_WARN("Ignored file of unsupported type CONTENT_TYPES_ARCHIVES", file);
} else if (IsEmbeddedTexture(file)) {
IOStream *fileStream = mZipArchive->Open(file.c_str());
LoadEmbeddedTextures(fileStream, file);
mZipArchive->Close(fileStream);
} else {
ASSIMP_LOG_WARN("Ignored file of unknown type: ", file);
}
@ -169,20 +185,26 @@ D3MFOpcPackage::D3MFOpcPackage(IOSystem *pIOHandler, const std::string &rFile) :
D3MFOpcPackage::~D3MFOpcPackage() {
mZipArchive->Close(mRootStream);
delete mZipArchive;
mZipArchive = nullptr;
}
IOStream *D3MFOpcPackage::RootStream() const {
return mRootStream;
}
static const std::string ModelRef = "3D/3dmodel.model";
const std::vector<aiTexture *> &D3MFOpcPackage::GetEmbeddedTextures() const {
return mEmbeddedTextures;
}
static const char *const ModelRef = "3D/3dmodel.model";
bool D3MFOpcPackage::validate() {
if (nullptr == mRootStream || nullptr == mZipArchive) {
return false;
}
return mZipArchive->Exists(ModelRef.c_str());
return mZipArchive->Exists(ModelRef);
}
std::string D3MFOpcPackage::ReadPackageRootRelationship(IOStream *stream) {
@ -204,6 +226,31 @@ std::string D3MFOpcPackage::ReadPackageRootRelationship(IOStream *stream) {
return (*itr)->target;
}
void D3MFOpcPackage::LoadEmbeddedTextures(IOStream *fileStream, const std::string &filename) {
if (nullptr == fileStream) {
return;
}
const size_t size = fileStream->FileSize();
if (0 == size) {
return;
}
unsigned char *data = new unsigned char[size];
fileStream->Read(data, 1, size);
aiTexture *texture = new aiTexture;
std::string embName = "*" + filename;
texture->mFilename.Set(embName.c_str());
texture->mWidth = static_cast<unsigned int>(size);
texture->mHeight = 0;
texture->achFormatHint[0] = 'p';
texture->achFormatHint[1] = 'n';
texture->achFormatHint[2] = 'g';
texture->achFormatHint[3] = '\0';
texture->pcData = (aiTexel*) data;
mEmbeddedTextures.emplace_back(texture);
}
} // Namespace D3MF
} // Namespace Assimp

View File

@ -46,8 +46,11 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include <string>
#include <assimp/IOSystem.hpp>
struct aiTexture;
namespace Assimp {
class ZipArchiveIOSystem;
class ZipArchiveIOSystem;
namespace D3MF {
@ -63,16 +66,19 @@ public:
~D3MFOpcPackage();
IOStream* RootStream() const;
bool validate();
const std::vector<aiTexture*> &GetEmbeddedTextures() const;
protected:
std::string ReadPackageRootRelationship(IOStream* stream);
void LoadEmbeddedTextures(IOStream *fileStream, const std::string &filename);
private:
IOStream* mRootStream;
std::unique_ptr<ZipArchiveIOSystem> mZipArchive;
ZipArchiveIOSystem *mZipArchive;
std::vector<aiTexture *> mEmbeddedTextures;
};
} // Namespace D3MF
} // Namespace Assimp
} // namespace D3MF
} // namespace Assimp
#endif // D3MFOPCPACKAGE_H

View File

@ -0,0 +1,594 @@
/*
Open Asset Import Library (assimp)
----------------------------------------------------------------------
Copyright (c) 2006-2021, assimp team
All rights reserved.
Redistribution and use of this software in source and binary forms,
with or without modification, are permitted provided that the
following conditions are met:
* Redistributions of source code must retain the above
copyright notice, this list of conditions and the
following disclaimer.
* 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.
* Neither the name of the assimp team, nor the names of its
contributors may be used to endorse or promote products
derived from this software without specific prior
written permission of the assimp team.
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
OWNER 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.
----------------------------------------------------------------------
*/
#include "XmlSerializer.h"
#include "D3MFOpcPackage.h"
#include "3MFXmlTags.h"
#include "3MFTypes.h"
#include <assimp/scene.h>
namespace Assimp {
namespace D3MF {
static const int IdNotSet = -1;
namespace {
static const size_t ColRGBA_Len = 9;
static const size_t ColRGB_Len = 7;
// format of the color string: #RRGGBBAA or #RRGGBB (3MF Core chapter 5.1.1)
bool validateColorString(const char *color) {
const size_t len = strlen(color);
if (ColRGBA_Len != len && ColRGB_Len != len) {
return false;
}
return true;
}
aiFace ReadTriangle(XmlNode &node) {
aiFace face;
face.mNumIndices = 3;
face.mIndices = new unsigned int[face.mNumIndices];
face.mIndices[0] = static_cast<unsigned int>(std::atoi(node.attribute(XmlTag::v1).as_string()));
face.mIndices[1] = static_cast<unsigned int>(std::atoi(node.attribute(XmlTag::v2).as_string()));
face.mIndices[2] = static_cast<unsigned int>(std::atoi(node.attribute(XmlTag::v3).as_string()));
return face;
}
aiVector3D ReadVertex(XmlNode &node) {
aiVector3D vertex;
vertex.x = ai_strtof(node.attribute(XmlTag::x).as_string(), nullptr);
vertex.y = ai_strtof(node.attribute(XmlTag::y).as_string(), nullptr);
vertex.z = ai_strtof(node.attribute(XmlTag::z).as_string(), nullptr);
return vertex;
}
bool getNodeAttribute(const XmlNode &node, const std::string &attribute, std::string &value) {
pugi::xml_attribute objectAttribute = node.attribute(attribute.c_str());
if (!objectAttribute.empty()) {
value = objectAttribute.as_string();
return true;
}
return false;
}
bool getNodeAttribute(const XmlNode &node, const std::string &attribute, int &value) {
std::string strValue;
const bool ret = getNodeAttribute(node, attribute, strValue);
if (ret) {
value = std::atoi(strValue.c_str());
return true;
}
return false;
}
aiMatrix4x4 parseTransformMatrix(std::string matrixStr) {
// split the string
std::vector<float> numbers;
std::string currentNumber;
for (char c : matrixStr) {
if (c == ' ') {
if (!currentNumber.empty()) {
float f = std::stof(currentNumber);
numbers.push_back(f);
currentNumber.clear();
}
} else {
currentNumber.push_back(c);
}
}
if (!currentNumber.empty()) {
const float f = std::stof(currentNumber);
numbers.push_back(f);
}
aiMatrix4x4 transformMatrix;
transformMatrix.a1 = numbers[0];
transformMatrix.b1 = numbers[1];
transformMatrix.c1 = numbers[2];
transformMatrix.d1 = 0;
transformMatrix.a2 = numbers[3];
transformMatrix.b2 = numbers[4];
transformMatrix.c2 = numbers[5];
transformMatrix.d2 = 0;
transformMatrix.a3 = numbers[6];
transformMatrix.b3 = numbers[7];
transformMatrix.c3 = numbers[8];
transformMatrix.d3 = 0;
transformMatrix.a4 = numbers[9];
transformMatrix.b4 = numbers[10];
transformMatrix.c4 = numbers[11];
transformMatrix.d4 = 1;
return transformMatrix;
}
bool parseColor(const char *color, aiColor4D &diffuse) {
if (nullptr == color) {
return false;
}
if (!validateColorString(color)) {
return false;
}
//const char *buf(color);
if ('#' != color[0]) {
return false;
}
char r[3] = { color[1], color[2], '\0' };
diffuse.r = static_cast<ai_real>(strtol(r, nullptr, 16)) / ai_real(255.0);
char g[3] = { color[3], color[4], '\0' };
diffuse.g = static_cast<ai_real>(strtol(g, nullptr, 16)) / ai_real(255.0);
char b[3] = { color[5], color[6], '\0' };
diffuse.b = static_cast<ai_real>(strtol(b, nullptr, 16)) / ai_real(255.0);
const size_t len = strlen(color);
if (ColRGB_Len == len) {
return true;
}
char a[3] = { color[7], color[8], '\0' };
diffuse.a = static_cast<ai_real>(strtol(a, nullptr, 16)) / ai_real(255.0);
return true;
}
void assignDiffuseColor(XmlNode &node, aiMaterial *mat) {
const char *color = node.attribute(XmlTag::basematerials_displaycolor).as_string();
aiColor4D diffuse;
if (parseColor(color, diffuse)) {
mat->AddProperty<aiColor4D>(&diffuse, 1, AI_MATKEY_COLOR_DIFFUSE);
}
}
} // namespace
XmlSerializer::XmlSerializer(XmlParser *xmlParser) :
mResourcesDictionnary(),
mMeshCount(0),
mXmlParser(xmlParser) {
ai_assert(nullptr != xmlParser);
}
XmlSerializer::~XmlSerializer() {
for (auto &it : mResourcesDictionnary) {
delete it.second;
}
}
void XmlSerializer::ImportXml(aiScene *scene) {
if (nullptr == scene) {
return;
}
scene->mRootNode = new aiNode(XmlTag::RootTag);
XmlNode node = mXmlParser->getRootNode().child(XmlTag::model);
if (node.empty()) {
return;
}
XmlNode resNode = node.child(XmlTag::resources);
for (auto &currentNode : resNode.children()) {
const std::string currentNodeName = currentNode.name();
if (currentNodeName == XmlTag::texture_2d) {
ReadEmbeddecTexture(currentNode);
} else if (currentNodeName == XmlTag::texture_group) {
ReadTextureGroup(currentNode);
} else if (currentNodeName == XmlTag::object) {
ReadObject(currentNode);
} else if (currentNodeName == XmlTag::basematerials) {
ReadBaseMaterials(currentNode);
} else if (currentNodeName == XmlTag::meta) {
ReadMetadata(currentNode);
}
}
StoreMaterialsInScene(scene);
XmlNode buildNode = node.child(XmlTag::build);
if (buildNode.empty()) {
return;
}
for (auto &currentNode : buildNode.children()) {
const std::string currentNodeName = currentNode.name();
if (currentNodeName == XmlTag::item) {
int objectId = IdNotSet;
std::string transformationMatrixStr;
aiMatrix4x4 transformationMatrix;
getNodeAttribute(currentNode, D3MF::XmlTag::objectid, objectId);
bool hasTransform = getNodeAttribute(currentNode, D3MF::XmlTag::transform, transformationMatrixStr);
auto it = mResourcesDictionnary.find(objectId);
if (it != mResourcesDictionnary.end() && it->second->getType() == ResourceType::RT_Object) {
Object *obj = static_cast<Object *>(it->second);
if (hasTransform) {
transformationMatrix = parseTransformMatrix(transformationMatrixStr);
}
addObjectToNode(scene->mRootNode, obj, transformationMatrix);
}
}
}
// import the metadata
if (!mMetaData.empty()) {
const size_t numMeta = mMetaData.size();
scene->mMetaData = aiMetadata::Alloc(static_cast<unsigned int>(numMeta));
for (size_t i = 0; i < numMeta; ++i) {
aiString val(mMetaData[i].value);
scene->mMetaData->Set(static_cast<unsigned int>(i), mMetaData[i].name, val);
}
}
// import the meshes, materials are already stored
scene->mNumMeshes = static_cast<unsigned int>(mMeshCount);
if (scene->mNumMeshes != 0) {
scene->mMeshes = new aiMesh *[scene->mNumMeshes]();
for (auto &it : mResourcesDictionnary) {
if (it.second->getType() == ResourceType::RT_Object) {
Object *obj = static_cast<Object *>(it.second);
ai_assert(nullptr != obj);
for (unsigned int i = 0; i < obj->mMeshes.size(); ++i) {
scene->mMeshes[obj->mMeshIndex[i]] = obj->mMeshes[i];
}
}
}
}
}
void XmlSerializer::addObjectToNode(aiNode *parent, Object *obj, aiMatrix4x4 nodeTransform) {
ai_assert(nullptr != obj);
aiNode *sceneNode = new aiNode(obj->mName);
sceneNode->mNumMeshes = static_cast<unsigned int>(obj->mMeshes.size());
sceneNode->mMeshes = new unsigned int[sceneNode->mNumMeshes];
std::copy(obj->mMeshIndex.begin(), obj->mMeshIndex.end(), sceneNode->mMeshes);
sceneNode->mTransformation = nodeTransform;
if (nullptr != parent) {
parent->addChildren(1, &sceneNode);
}
for (Assimp::D3MF::Component c : obj->mComponents) {
auto it = mResourcesDictionnary.find(c.mObjectId);
if (it != mResourcesDictionnary.end() && it->second->getType() == ResourceType::RT_Object) {
addObjectToNode(sceneNode, static_cast<Object *>(it->second), c.mTransformation);
}
}
}
void XmlSerializer::ReadObject(XmlNode &node) {
int id = IdNotSet, pid = IdNotSet, pindex = IdNotSet;
bool hasId = getNodeAttribute(node, XmlTag::id, id);
if (!hasId) {
return;
}
bool hasPid = getNodeAttribute(node, XmlTag::pid, pid);
bool hasPindex = getNodeAttribute(node, XmlTag::pindex, pindex);
Object *obj = new Object(id);
for (XmlNode &currentNode : node.children()) {
const std::string currentName = currentNode.name();
if (currentName == D3MF::XmlTag::mesh) {
auto mesh = ReadMesh(currentNode);
mesh->mName.Set(ai_to_string(id));
if (hasPid) {
auto it = mResourcesDictionnary.find(pid);
if (hasPindex && it != mResourcesDictionnary.end() && it->second->getType() == ResourceType::RT_BaseMaterials) {
BaseMaterials *materials = static_cast<BaseMaterials *>(it->second);
mesh->mMaterialIndex = materials->mMaterialIndex[pindex];
}
}
obj->mMeshes.push_back(mesh);
obj->mMeshIndex.push_back(mMeshCount);
mMeshCount++;
} else if (currentName == D3MF::XmlTag::components) {
for (XmlNode &currentSubNode : currentNode.children()) {
const std::string subNodeName = currentSubNode.name();
if (subNodeName == D3MF::XmlTag::component) {
int objectId = IdNotSet;
std::string componentTransformStr;
aiMatrix4x4 componentTransform;
if (getNodeAttribute(currentSubNode, D3MF::XmlTag::transform, componentTransformStr)) {
componentTransform = parseTransformMatrix(componentTransformStr);
}
if (getNodeAttribute(currentSubNode, D3MF::XmlTag::objectid, objectId)) {
obj->mComponents.push_back({ objectId, componentTransform });
}
}
}
}
}
mResourcesDictionnary.insert(std::make_pair(id, obj));
}
aiMesh *XmlSerializer::ReadMesh(XmlNode &node) {
if (node.empty()) {
return nullptr;
}
aiMesh *mesh = new aiMesh();
for (XmlNode &currentNode : node.children()) {
const std::string currentName = currentNode.name();
if (currentName == XmlTag::vertices) {
ImportVertices(currentNode, mesh);
} else if (currentName == XmlTag::triangles) {
ImportTriangles(currentNode, mesh);
}
}
return mesh;
}
void XmlSerializer::ReadMetadata(XmlNode &node) {
pugi::xml_attribute attribute = node.attribute(D3MF::XmlTag::meta_name);
const std::string name = attribute.as_string();
const std::string value = node.value();
if (name.empty()) {
return;
}
MetaEntry entry;
entry.name = name;
entry.value = value;
mMetaData.push_back(entry);
}
void XmlSerializer::ImportVertices(XmlNode &node, aiMesh *mesh) {
ai_assert(nullptr != mesh);
std::vector<aiVector3D> vertices;
for (XmlNode &currentNode : node.children()) {
const std::string currentName = currentNode.name();
if (currentName == XmlTag::vertex) {
vertices.push_back(ReadVertex(currentNode));
}
}
mesh->mNumVertices = static_cast<unsigned int>(vertices.size());
mesh->mVertices = new aiVector3D[mesh->mNumVertices];
std::copy(vertices.begin(), vertices.end(), mesh->mVertices);
}
void XmlSerializer::ImportTriangles(XmlNode &node, aiMesh *mesh) {
std::vector<aiFace> faces;
for (XmlNode &currentNode : node.children()) {
const std::string currentName = currentNode.name();
if (currentName == XmlTag::triangle) {
int pid = IdNotSet, p1 = IdNotSet;
bool hasPid = getNodeAttribute(currentNode, D3MF::XmlTag::pid, pid);
bool hasP1 = getNodeAttribute(currentNode, D3MF::XmlTag::p1, p1);
if (hasPid && hasP1) {
auto it = mResourcesDictionnary.find(pid);
if (it != mResourcesDictionnary.end()) {
if (it->second->getType() == ResourceType::RT_BaseMaterials) {
BaseMaterials *baseMaterials = static_cast<BaseMaterials *>(it->second);
mesh->mMaterialIndex = baseMaterials->mMaterialIndex[p1];
} else if (it->second->getType() == ResourceType::RT_Texture2DGroup) {
if (mesh->mTextureCoords[0] == nullptr) {
Texture2DGroup *group = static_cast<Texture2DGroup *>(it->second);
const std::string name = ai_to_string(group->mTexId);
for (size_t i = 0; i < mMaterials.size(); ++i) {
if (name == mMaterials[i]->GetName().C_Str()) {
mesh->mMaterialIndex = static_cast<unsigned int>(i);
}
}
mesh->mTextureCoords[0] = new aiVector3D[group->mTex2dCoords.size()];
for (unsigned int i = 0; i < group->mTex2dCoords.size(); ++i) {
mesh->mTextureCoords[0][i] = aiVector3D(group->mTex2dCoords[i].x, group->mTex2dCoords[i].y, 0);
}
}
}
}
}
aiFace face = ReadTriangle(currentNode);
faces.push_back(face);
}
}
mesh->mNumFaces = static_cast<unsigned int>(faces.size());
mesh->mFaces = new aiFace[mesh->mNumFaces];
mesh->mPrimitiveTypes = aiPrimitiveType_TRIANGLE;
std::copy(faces.begin(), faces.end(), mesh->mFaces);
}
void XmlSerializer::ReadBaseMaterials(XmlNode &node) {
int id = IdNotSet;
if (getNodeAttribute(node, D3MF::XmlTag::id, id)) {
BaseMaterials *baseMaterials = new BaseMaterials(id);
for (XmlNode &currentNode : node.children()) {
const std::string currentName = currentNode.name();
if (currentName == XmlTag::basematerials_base) {
baseMaterials->mMaterialIndex.push_back(static_cast<unsigned int>(mMaterials.size()));
mMaterials.push_back(readMaterialDef(currentNode, id));
}
}
mResourcesDictionnary.insert(std::make_pair(id, baseMaterials));
}
}
void XmlSerializer::ReadEmbeddecTexture(XmlNode &node) {
if (node.empty()) {
return;
}
std::string value;
EmbeddedTexture *tex2D = nullptr;
if (XmlParser::getStdStrAttribute(node, XmlTag::id, value)) {
tex2D = new EmbeddedTexture(atoi(value.c_str()));
}
if (nullptr == tex2D) {
return;
}
if (XmlParser::getStdStrAttribute(node, XmlTag::path, value)) {
tex2D->mPath = value;
}
if (XmlParser::getStdStrAttribute(node, XmlTag::texture_content_type, value)) {
tex2D->mContentType = value;
}
if (XmlParser::getStdStrAttribute(node, XmlTag::texture_tilestyleu, value)) {
tex2D->mTilestyleU = value;
}
if (XmlParser::getStdStrAttribute(node, XmlTag::texture_tilestylev, value)) {
tex2D->mTilestyleV = value;
}
mEmbeddedTextures.emplace_back(tex2D);
StoreEmbeddedTexture(tex2D);
}
void XmlSerializer::StoreEmbeddedTexture(EmbeddedTexture *tex) {
aiMaterial *mat = new aiMaterial;
aiString s;
s.Set(ai_to_string(tex->mId).c_str());
mat->AddProperty(&s, AI_MATKEY_NAME);
const std::string name = "*" + tex->mPath;
s.Set(name);
mat->AddProperty(&s, AI_MATKEY_TEXTURE_DIFFUSE(0));
aiColor3D col;
mat->AddProperty<aiColor3D>(&col, 1, AI_MATKEY_COLOR_DIFFUSE);
mat->AddProperty<aiColor3D>(&col, 1, AI_MATKEY_COLOR_AMBIENT);
mat->AddProperty<aiColor3D>(&col, 1, AI_MATKEY_COLOR_EMISSIVE);
mat->AddProperty<aiColor3D>(&col, 1, AI_MATKEY_COLOR_SPECULAR);
mMaterials.emplace_back(mat);
}
void XmlSerializer::ReadTextureCoords2D(XmlNode &node, Texture2DGroup *tex2DGroup) {
if (node.empty() || nullptr == tex2DGroup) {
return;
}
int id = IdNotSet;
if (XmlParser::getIntAttribute(node, "texid", id)) {
tex2DGroup->mTexId = id;
}
double value = 0.0;
for (XmlNode currentNode : node.children()) {
const std::string currentName = currentNode.name();
aiVector2D texCoord;
if (currentName == XmlTag::texture_2d_coord) {
XmlParser::getDoubleAttribute(currentNode, XmlTag::texture_cuurd_u, value);
texCoord.x = (ai_real)value;
XmlParser::getDoubleAttribute(currentNode, XmlTag::texture_cuurd_v, value);
texCoord.y = (ai_real)value;
tex2DGroup->mTex2dCoords.push_back(texCoord);
}
}
}
void XmlSerializer::ReadTextureGroup(XmlNode &node) {
if (node.empty()) {
return;
}
int id = IdNotSet;
if (!XmlParser::getIntAttribute(node, XmlTag::id, id)) {
return;
}
Texture2DGroup *group = new Texture2DGroup(id);
ReadTextureCoords2D(node, group);
mResourcesDictionnary.insert(std::make_pair(id, group));
}
aiMaterial *XmlSerializer::readMaterialDef(XmlNode &node, unsigned int basematerialsId) {
aiMaterial *material = new aiMaterial();
material->mNumProperties = 0;
std::string name;
bool hasName = getNodeAttribute(node, D3MF::XmlTag::basematerials_name, name);
std::string stdMaterialName;
const std::string strId(ai_to_string(basematerialsId));
stdMaterialName += "id";
stdMaterialName += strId;
stdMaterialName += "_";
if (hasName) {
stdMaterialName += std::string(name);
} else {
stdMaterialName += "basemat_";
stdMaterialName += ai_to_string(mMaterials.size());
}
aiString assimpMaterialName(stdMaterialName);
material->AddProperty(&assimpMaterialName, AI_MATKEY_NAME);
assignDiffuseColor(node, material);
return material;
}
void XmlSerializer::StoreMaterialsInScene(aiScene *scene) {
if (nullptr == scene || mMaterials.empty()) {
return;
}
scene->mNumMaterials = static_cast<unsigned int>(mMaterials.size());
scene->mMaterials = new aiMaterial *[scene->mNumMaterials];
for (size_t i = 0; i < mMaterials.size(); ++i) {
scene->mMaterials[i] = mMaterials[i];
}
}
} // namespace D3MF
} // namespace Assimp

View File

@ -0,0 +1,96 @@
/*
Open Asset Import Library (assimp)
----------------------------------------------------------------------
Copyright (c) 2006-2021, assimp team
All rights reserved.
Redistribution and use of this software in source and binary forms,
with or without modification, are permitted provided that the
following conditions are met:
* Redistributions of source code must retain the above
copyright notice, this list of conditions and the
following disclaimer.
* 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.
* Neither the name of the assimp team, nor the names of its
contributors may be used to endorse or promote products
derived from this software without specific prior
written permission of the assimp team.
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
OWNER 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.
----------------------------------------------------------------------
*/
#pragma once
#include <assimp/XmlParser.h>
#include <assimp/mesh.h>
#include <vector>
#include <map>
struct aiNode;
struct aiMesh;
struct aiMaterial;
namespace Assimp {
namespace D3MF {
class Resource;
class D3MFOpcPackage;
class Object;
class Texture2DGroup;
class EmbeddedTexture;
class XmlSerializer {
public:
XmlSerializer(XmlParser *xmlParser);
~XmlSerializer();
void ImportXml(aiScene *scene);
private:
void addObjectToNode(aiNode *parent, Object *obj, aiMatrix4x4 nodeTransform);
void ReadObject(XmlNode &node);
aiMesh *ReadMesh(XmlNode &node);
void ReadMetadata(XmlNode &node);
void ImportVertices(XmlNode &node, aiMesh *mesh);
void ImportTriangles(XmlNode &node, aiMesh *mesh);
void ReadBaseMaterials(XmlNode &node);
void ReadEmbeddecTexture(XmlNode &node);
void StoreEmbeddedTexture(EmbeddedTexture *tex);
void ReadTextureCoords2D(XmlNode &node, Texture2DGroup *tex2DGroup);
void ReadTextureGroup(XmlNode &node);
aiMaterial *readMaterialDef(XmlNode &node, unsigned int basematerialsId);
void StoreMaterialsInScene(aiScene *scene);
private:
struct MetaEntry {
std::string name;
std::string value;
};
std::vector<MetaEntry> mMetaData;
std::vector<EmbeddedTexture *> mEmbeddedTextures;
std::vector<aiMaterial *> mMaterials;
std::map<unsigned int, Resource *> mResourcesDictionnary;
unsigned int mMeshCount;
XmlParser *mXmlParser;
};
} // namespace D3MF
} // namespace Assimp

View File

@ -303,7 +303,7 @@ void AMFImporter::ParseNode_Root() {
}
XmlNode node = *root;
mUnit = ai_tolower(std::string(node.attribute("unit").as_string()));
mVersion = node.attribute("version").as_string();
// Read attributes for node <amf>.

View File

@ -75,7 +75,7 @@ void AMFImporter::ParseNode_Mesh(XmlNode &node) {
found_volumes = true;
}
ParseHelper_Node_Exit();
}
}
if (!found_verts && !found_volumes) {
mNodeElement_Cur->Child.push_back(ne);
@ -199,9 +199,9 @@ void AMFImporter::ParseNode_Volume(XmlNode &node) {
// Read attributes for node <color>.
// and assign read data
((AMFVolume *)ne)->MaterialID = node.attribute("materialid").as_string();
((AMFVolume *)ne)->Type = type;
// Check for child nodes
bool col_read = false;

View File

@ -69,7 +69,7 @@ aiColor4D AMFImporter::SPP_Material::GetColor(const float /*pX*/, const float /*
}
tcol = Color->Color;
// Check if default color must be used
if ((tcol.r == 0) && (tcol.g == 0) && (tcol.b == 0) && (tcol.a == 0)) {
tcol.r = 0.5f;
@ -99,10 +99,10 @@ void AMFImporter::PostprocessHelper_CreateMeshDataArray(const AMFMesh &nodeEleme
}
// all coordinates stored as child and we need to reserve space for future push_back's.
vertexCoordinateArray.reserve(vn->Child.size());
vertexCoordinateArray.reserve(vn->Child.size());
// colors count equal vertices count.
pVertexColorArray.resize(vn->Child.size());
pVertexColorArray.resize(vn->Child.size());
col_idx = 0;
// Inside vertices collect all data and place to arrays

View File

@ -95,8 +95,8 @@ struct Material : public D3DS::Material {
Material(Material &&other) AI_NO_EXCEPT
: D3DS::Material(std::move(other)),
avSubMaterials(std::move(other.avSubMaterials)),
pcInstance(std::move(other.pcInstance)),
bNeed(std::move(other.bNeed)) {
pcInstance(other.pcInstance),
bNeed(other.bNeed) {
other.pcInstance = nullptr;
}
@ -108,8 +108,8 @@ struct Material : public D3DS::Material {
//D3DS::Material::operator=(std::move(other));
avSubMaterials = std::move(other.avSubMaterials);
pcInstance = std::move(other.pcInstance);
bNeed = std::move(other.bNeed);
pcInstance = other.pcInstance;
bNeed = other.bNeed;
other.pcInstance = nullptr;

View File

@ -172,7 +172,7 @@ inline size_t Write<aiQuaternion>(IOStream *stream, const aiQuaternion &v) {
t += Write<float>(stream, v.z);
ai_assert(t == 16);
return 16;
return t;
}
// -----------------------------------------------------------------------------------

View File

@ -41,12 +41,17 @@ public:
enum {
Flag_DoNotIndent = 0x1,
Flag_WriteSpecialFloats = 0x2,
Flag_SkipWhitespaces = 0x4
};
JSONWriter(Assimp::IOStream &out, unsigned int flags = 0u) :
out(out), first(), flags(flags) {
out(out), indent (""), newline("\n"), space(" "), buff (), first(false), flags(flags) {
// make sure that all formatting happens using the standard, C locale and not the user's current locale
buff.imbue(std::locale("C"));
if (flags & Flag_SkipWhitespaces) {
newline = "";
space = "";
}
}
~JSONWriter() {
@ -70,7 +75,7 @@ public:
void Key(const std::string &name) {
AddIndentation();
Delimit();
buff << '\"' + name + "\": ";
buff << '\"' + name + "\":" << space;
}
template <typename Literal>
@ -78,12 +83,12 @@ public:
AddIndentation();
Delimit();
LiteralToString(buff, name) << '\n';
LiteralToString(buff, name) << newline;
}
template <typename Literal>
void SimpleValue(const Literal &s) {
LiteralToString(buff, s) << '\n';
LiteralToString(buff, s) << newline;
}
void SimpleValue(const void *buffer, size_t len) {
@ -102,7 +107,7 @@ public:
}
}
buff << '\"' << cur_out << "\"\n";
buff << '\"' << cur_out << "\"" << newline;
delete[] cur_out;
}
@ -115,7 +120,7 @@ public:
}
}
first = true;
buff << "{\n";
buff << "{" << newline;
PushIndent();
}
@ -123,7 +128,7 @@ public:
PopIndent();
AddIndentation();
first = false;
buff << "}\n";
buff << "}" << newline;
}
void StartArray(bool is_element = false) {
@ -135,19 +140,19 @@ public:
}
}
first = true;
buff << "[\n";
buff << "[" << newline;
PushIndent();
}
void EndArray() {
PopIndent();
AddIndentation();
buff << "]\n";
buff << "]" << newline;
first = false;
}
void AddIndentation() {
if (!(flags & Flag_DoNotIndent)) {
if (!(flags & Flag_DoNotIndent) && !(flags & Flag_SkipWhitespaces)) {
buff << indent;
}
}
@ -156,7 +161,7 @@ public:
if (!first) {
buff << ',';
} else {
buff << ' ';
buff << space;
first = false;
}
}
@ -227,7 +232,9 @@ private:
private:
Assimp::IOStream &out;
std::string indent, newline;
std::string indent;
std::string newline;
std::string space;
std::stringstream buff;
bool first;
@ -765,7 +772,7 @@ void Write(JSONWriter &out, const aiScene &ai) {
out.EndObj();
}
void ExportAssimp2Json(const char *file, Assimp::IOSystem *io, const aiScene *scene, const Assimp::ExportProperties *) {
void ExportAssimp2Json(const char *file, Assimp::IOSystem *io, const aiScene *scene, const Assimp::ExportProperties *pProperties) {
std::unique_ptr<Assimp::IOStream> str(io->Open(file, "wt"));
if (!str) {
throw DeadlyExportError("could not open output file");
@ -782,7 +789,12 @@ void ExportAssimp2Json(const char *file, Assimp::IOSystem *io, const aiScene *sc
splitter.Execute(scenecopy_tmp);
// XXX Flag_WriteSpecialFloats is turned on by default, right now we don't have a configuration interface for exporters
JSONWriter s(*str, JSONWriter::Flag_WriteSpecialFloats);
unsigned int flags = JSONWriter::Flag_WriteSpecialFloats;
if (pProperties->GetPropertyBool("JSON_SKIP_WHITESPACES", false)) {
flags |= JSONWriter::Flag_SkipWhitespaces;
}
JSONWriter s(*str, flags);
Write(s, *scenecopy_tmp);
} catch (...) {

View File

@ -110,7 +110,7 @@ void MeshSplitter :: SplitMesh(unsigned int a, aiMesh* in_mesh, std::vector<std:
// we need to split this mesh into sub meshes. Estimate submesh size
const unsigned int sub_meshes = (in_mesh->mNumVertices / LIMIT) + 1;
// create a std::vector<unsigned int> to remember which vertices have already
// create a std::vector<unsigned int> to remember which vertices have already
// been copied and to which position (i.e. output index)
std::vector<unsigned int> was_copied_to;
was_copied_to.resize(in_mesh->mNumVertices,WAS_NOT_COPIED);
@ -125,7 +125,7 @@ void MeshSplitter :: SplitMesh(unsigned int a, aiMesh* in_mesh, std::vector<std:
while (true) {
const unsigned int out_vertex_index = LIMIT;
aiMesh* out_mesh = new aiMesh();
aiMesh* out_mesh = new aiMesh();
out_mesh->mNumVertices = 0;
out_mesh->mMaterialIndex = in_mesh->mMaterialIndex;
@ -179,7 +179,7 @@ void MeshSplitter :: SplitMesh(unsigned int a, aiMesh* in_mesh, std::vector<std:
// check whether we do already have this vertex
if (WAS_NOT_COPIED == was_copied_to[index]) {
iNeed++;
iNeed++;
}
}
if (out_mesh->mNumVertices + iNeed > out_vertex_index) {
@ -240,7 +240,7 @@ void MeshSplitter :: SplitMesh(unsigned int a, aiMesh* in_mesh, std::vector<std:
out_mesh->mTextureCoords[c][out_mesh->mNumVertices] = in_mesh->mTextureCoords[c][index];
}
}
// vertex colors
// vertex colors
for (unsigned int c = 0; c < AI_MAX_NUMBER_OF_COLOR_SETS;++c) {
if (in_mesh->HasVertexColors( c)) {
out_mesh->mColors[c][out_mesh->mNumVertices] = in_mesh->mColors[c][index];

View File

@ -22,13 +22,13 @@ struct aiNode;
// ---------------------------------------------------------------------------
/** Splits meshes of unique vertices into meshes with no more vertices than
* a given, configurable threshold value.
* a given, configurable threshold value.
*/
class MeshSplitter
class MeshSplitter
{
public:
void SetLimit(unsigned int l) {
LIMIT = l;
}

View File

@ -50,7 +50,7 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include <assimp/IOSystem.hpp>
#include <assimp/Exporter.hpp>
namespace Assimp {
namespace Assimp {
void ExportSceneAssxml(const char* pFile, IOSystem* pIOSystem, const aiScene* pScene, const ExportProperties* /*pProperties*/)
{

View File

@ -143,7 +143,7 @@ AI_WONT_RETURN void B3DImporter::Oops() {
}
// ------------------------------------------------------------------------------------------------
AI_WONT_RETURN void B3DImporter::Fail(string str) {
AI_WONT_RETURN void B3DImporter::Fail(const string &str) {
#ifdef DEBUG_B3D
ASSIMP_LOG_ERROR("Error in B3D file data: ", str);
#endif

View File

@ -96,7 +96,7 @@ private:
};
AI_WONT_RETURN void Oops() AI_WONT_RETURN_SUFFIX;
AI_WONT_RETURN void Fail( std::string str ) AI_WONT_RETURN_SUFFIX;
AI_WONT_RETURN void Fail(const std::string &str) AI_WONT_RETURN_SUFFIX;
void ReadTEXS();
void ReadBRUS();

View File

@ -679,7 +679,7 @@ void BlenderImporter::BuildMaterials(ConversionData &conv_data) {
BuildDefaultMaterial(conv_data);
for (std::shared_ptr<Material> mat : conv_data.materials_raw) {
for (const std::shared_ptr<Material> &mat : conv_data.materials_raw) {
// reset per material global counters
for (size_t i = 0; i < sizeof(conv_data.next_texture) / sizeof(conv_data.next_texture[0]); ++i) {

View File

@ -52,9 +52,9 @@ namespace Assimp {
namespace Blender {
// -------------------------------------------------------------------------------------------
/**
/**
* Dummy base class for all blender modifiers. Modifiers are reused between imports, so
* they should be stateless and not try to cache model data.
* they should be stateless and not try to cache model data.
*/
// -------------------------------------------------------------------------------------------
class BlenderModifier {
@ -67,7 +67,7 @@ public:
}
// --------------------
/**
/**
* Check if *this* modifier is active, given a ModifierData& block.
*/
virtual bool IsActive( const ModifierData& /*modin*/) {
@ -75,10 +75,10 @@ public:
}
// --------------------
/**
/**
* Apply the modifier to a given output node. The original data used
* to construct the node is given as well. Not called unless IsActive()
* was called and gave positive response.
* was called and gave positive response.
*/
virtual void DoIt(aiNode& /*out*/,
ConversionData& /*conv_data*/,
@ -92,8 +92,8 @@ public:
};
// -------------------------------------------------------------------------------------------
/**
* Manage all known modifiers and instance and apply them if necessary
/**
* Manage all known modifiers and instance and apply them if necessary
*/
// -------------------------------------------------------------------------------------------
class BlenderModifierShowcase {
@ -113,8 +113,8 @@ private:
// MODIFIERS /////////////////////////////////////////////////////////////////////////////////
// -------------------------------------------------------------------------------------------
/**
* Mirror modifier. Status: implemented.
/**
* Mirror modifier. Status: implemented.
*/
// -------------------------------------------------------------------------------------------
class BlenderModifier_Mirror : public BlenderModifier {

View File

@ -146,8 +146,14 @@ void C4DImporter::InternReadFile( const std::string& pFile, aiScene* pScene, IOS
ThrowException("failed to read document " + pFile);
}
// Generate the root-node
pScene->mRootNode = new aiNode("<C4DRoot>");
// convert left-handed to right-handed
pScene->mRootNode->mTransformation.a1 = 0.01f;
pScene->mRootNode->mTransformation.b2 = 0.01f;
pScene->mRootNode->mTransformation.c3 = -0.01f;
// first convert all materials
ReadMaterials(doc->GetFirstMaterial());

View File

@ -230,7 +230,7 @@ void COBImporter::InternReadFile(const std::string &pFile, aiScene *pScene, IOSy
}
// ------------------------------------------------------------------------------------------------
void ConvertTexture(std::shared_ptr<Texture> tex, aiMaterial *out, aiTextureType type) {
void ConvertTexture(const std::shared_ptr<Texture> &tex, aiMaterial *out, aiTextureType type) {
const aiString path(tex->path);
out->AddProperty(&path, AI_MATKEY_TEXTURE(type, 0));
out->AddProperty(&tex->transform, 1, AI_MATKEY_UVTRANSFORM(type, 0));
@ -884,7 +884,7 @@ void COBImporter::ReadBinaryFile(Scene &out, StreamReaderLE *reader) {
std::string type;
type += reader->GetI1();
type += reader->GetI1();
type += reader->GetI1();
type += reader->GetI1();
type += reader->GetI1();
ChunkInfo nfo;

View File

@ -77,7 +77,7 @@ class COBImporter : public BaseImporter
public:
COBImporter();
~COBImporter();
// --------------------
bool CanRead( const std::string& pFile, IOSystem* pIOHandler,
bool checkSig) const;

View File

@ -135,14 +135,15 @@ bool ColladaLoader::CanRead(const std::string &pFile, IOSystem *pIOHandler, bool
// XML - too generic, we need to open the file and search for typical keywords
if (extension == "xml" || !extension.length() || checkSig) {
/* If CanRead() is called in order to check whether we
* support a specific file extension in general pIOHandler
* might be nullptr and it's our duty to return true here.
*/
if (!pIOHandler) {
// If CanRead() is called in order to check whether we
// support a specific file extension in general pIOHandler
// might be nullptr and it's our duty to return true here.
if (nullptr == pIOHandler) {
return true;
}
static const char *tokens[] = { "<collada" };
static const char* tokens[] = {
"<collada"
};
return SearchFileHeaderForToken(pIOHandler, pFile, tokens, 1);
}
@ -573,7 +574,7 @@ void ColladaLoader::BuildMeshesForNode(const ColladaParser &pParser, const Node
// now place all mesh references we gathered in the target node
pTarget->mNumMeshes = static_cast<unsigned int>(newMeshRefs.size());
if (newMeshRefs.size()) {
if (!newMeshRefs.empty()) {
struct UIntTypeConverter {
unsigned int operator()(const size_t &v) const {
return static_cast<unsigned int>(v);
@ -619,6 +620,10 @@ aiMesh *ColladaLoader::CreateMesh(const ColladaParser &pParser, const Mesh *pSrc
dstMesh->mName = pSrcMesh->mId;
}
if (pSrcMesh->mPositions.empty()) {
return dstMesh.release();
}
// count the vertices addressed by its faces
const size_t numVertices = std::accumulate(pSrcMesh->mFaceSize.begin() + pStartFace,
pSrcMesh->mFaceSize.begin() + pStartFace + pSubMesh.mNumFaces, size_t(0));
@ -1540,7 +1545,7 @@ void ColladaLoader::AddTexture(aiMaterial &mat,
map = -1;
for (std::string::const_iterator it = sampler.mUVChannel.begin(); it != sampler.mUVChannel.end(); ++it) {
if (IsNumeric(*it)) {
map = strtoul10(&(*it));
map = strtoul10(&(*it));
break;
}
}
@ -1671,7 +1676,7 @@ void ColladaLoader::BuildMaterials(ColladaParser &pParser, aiScene * /*pScene*/)
const Material &material = matIt->second;
// a material is only a reference to an effect
ColladaParser::EffectLibrary::iterator effIt = pParser.mEffectLibrary.find(material.mEffect);
if (effIt == pParser.mEffectLibrary.end())
if (effIt == pParser.mEffectLibrary.end())
continue;
Effect &effect = effIt->second;
@ -1682,7 +1687,7 @@ void ColladaLoader::BuildMaterials(ColladaParser &pParser, aiScene * /*pScene*/)
// store the material
mMaterialIndexByName[matIt->first] = newMats.size();
newMats.push_back(std::pair<Effect *, aiMaterial *>(&effect, mat));
newMats.emplace_back(&effect, mat);
}
// ScenePreprocessor generates a default material automatically if none is there.
// All further code here in this loader works well without a valid material so

View File

@ -170,10 +170,10 @@ ColladaParser::ColladaParser(IOSystem *pIOHandler, const std::string &pFile) :
// ------------------------------------------------------------------------------------------------
// Destructor, private as well
ColladaParser::~ColladaParser() {
for (auto & it : mNodeLibrary) {
for (auto &it : mNodeLibrary) {
delete it.second;
}
for (auto & it : mMeshLibrary) {
for (auto &it : mMeshLibrary) {
delete it.second;
}
}
@ -231,11 +231,7 @@ void ColladaParser::UriDecodePath(aiString &ss) {
// Maxon Cinema Collada Export writes "file:///C:\andsoon" with three slashes...
// I need to filter it without destroying linux paths starting with "/somewhere"
#if defined(_MSC_VER)
if (ss.data[0] == '/' && isalpha((unsigned char)ss.data[1]) && ss.data[2] == ':') {
#else
if (ss.data[0] == '/' && isalpha((unsigned char)ss.data[1]) && ss.data[2] == ':') {
#endif
--ss.length;
::memmove(ss.data, ss.data + 1, ss.length);
ss.data[ss.length] = 0;
@ -396,7 +392,7 @@ void ColladaParser::ReadAnimationClipLibrary(XmlNode &node) {
std::string animName;
if (!XmlParser::getStdStrAttribute(node, "name", animName)) {
if (!XmlParser::getStdStrAttribute( node, "id", animName )) {
if (!XmlParser::getStdStrAttribute(node, "id", animName)) {
animName = std::string("animation_") + ai_to_string(mAnimationClipLibrary.size());
}
}
@ -420,7 +416,7 @@ void ColladaParser::ReadAnimationClipLibrary(XmlNode &node) {
void ColladaParser::PostProcessControllers() {
std::string meshId;
for (auto & it : mControllerLibrary) {
for (auto &it : mControllerLibrary) {
meshId = it.second.mMeshId;
if (meshId.empty()) {
continue;
@ -445,7 +441,7 @@ void ColladaParser::PostProcessRootAnimations() {
}
Animation temp;
for (auto & it : mAnimationClipLibrary) {
for (auto &it : mAnimationClipLibrary) {
std::string clipName = it.first;
Animation *clip = new Animation();
@ -453,7 +449,7 @@ void ColladaParser::PostProcessRootAnimations() {
temp.mSubAnims.push_back(clip);
for (std::string animationID : it.second) {
for (const std::string &animationID : it.second) {
AnimationLibrary::iterator animation = mAnimationLibrary.find(animationID);
if (animation != mAnimationLibrary.end()) {
@ -529,7 +525,7 @@ void ColladaParser::ReadAnimation(XmlNode &node, Collada::Animation *pParent) {
// have it read into a channel
ChannelMap::iterator newChannel = channels.insert(std::make_pair(id, AnimationChannel())).first;
ReadAnimationSampler(currentNode, newChannel->second);
}
}
} else if (currentName == "channel") {
std::string source_name, target;
XmlParser::getStdStrAttribute(currentNode, "source", source_name);
@ -552,7 +548,7 @@ void ColladaParser::ReadAnimation(XmlNode &node, Collada::Animation *pParent) {
pParent->mSubAnims.push_back(anim);
}
for (const auto & channel : channels) {
for (const auto &channel : channels) {
anim->mChannels.push_back(channel.second);
}
@ -626,8 +622,6 @@ void ColladaParser::ReadController(XmlNode &node, Collada::Controller &controlle
XmlNodeIterator xmlIt(node, XmlNodeIterator::PreOrderMode);
XmlNode currentNode;
while (xmlIt.getNext(currentNode)) {
//for (XmlNode &currentNode : node.children()) {
const std::string &currentName = currentNode.name();
if (currentName == "morph") {
controller.mType = Morph;
@ -644,7 +638,7 @@ void ColladaParser::ReadController(XmlNode &node, Collada::Controller &controlle
} else if (currentName == "skin") {
std::string id;
if (XmlParser::getStdStrAttribute(currentNode, "source", id)) {
controller.mMeshId = id.substr(1, id.size()-1);
controller.mMeshId = id.substr(1, id.size() - 1);
}
} else if (currentName == "bind_shape_matrix") {
std::string v;
@ -698,7 +692,7 @@ void ColladaParser::ReadControllerJoints(XmlNode &node, Collada::Controller &pCo
} else if (strcmp(attrSemantic, "INV_BIND_MATRIX") == 0) {
pController.mJointOffsetMatrixSource = attrSource;
} else {
throw DeadlyImportError("Unknown semantic \"" , attrSemantic , "\" in <joints> data <input> element");
throw DeadlyImportError("Unknown semantic \"", attrSemantic, "\" in <joints> data <input> element");
}
}
}
@ -708,7 +702,7 @@ void ColladaParser::ReadControllerJoints(XmlNode &node, Collada::Controller &pCo
// Reads the joint weights for the given controller
void ColladaParser::ReadControllerWeights(XmlNode &node, Collada::Controller &pController) {
// Read vertex count from attributes and resize the array accordingly
int vertexCount=0;
int vertexCount = 0;
XmlParser::getIntAttribute(node, "count", vertexCount);
pController.mWeightCounts.resize(vertexCount);
@ -723,7 +717,7 @@ void ColladaParser::ReadControllerWeights(XmlNode &node, Collada::Controller &pC
// local URLS always start with a '#'. We don't support global URLs
if (attrSource[0] != '#') {
throw DeadlyImportError( "Unsupported URL format in \"", attrSource, "\" in source attribute of <vertex_weights> data <input> element");
throw DeadlyImportError("Unsupported URL format in \"", attrSource, "\" in source attribute of <vertex_weights> data <input> element");
}
channel.mAccessor = attrSource + 1;
@ -777,7 +771,7 @@ void ColladaParser::ReadImageLibrary(XmlNode &node) {
const std::string &currentName = currentNode.name();
if (currentName == "image") {
std::string id;
if (XmlParser::getStdStrAttribute( currentNode, "id", id )) {
if (XmlParser::getStdStrAttribute(currentNode, "id", id)) {
mImageLibrary[id] = Image();
// read on from there
ReadImage(currentNode, mImageLibrary[id]);
@ -907,7 +901,7 @@ void ColladaParser::ReadCameraLibrary(XmlNode &node) {
if (!name.empty()) {
cam.mName = name;
}
ReadCamera(currentNode, cam);
ReadCamera(currentNode, cam);
}
}
}
@ -920,7 +914,7 @@ void ColladaParser::ReadMaterial(XmlNode &node, Collada::Material &pMaterial) {
if (currentName == "instance_effect") {
std::string url;
readUrlAttribute(currentNode, url);
pMaterial.mEffect = url.c_str();
pMaterial.mEffect = url;
}
}
}
@ -1361,8 +1355,8 @@ void ColladaParser::ReadMesh(XmlNode &node, Mesh &pMesh) {
} else if (currentName == "vertices") {
ReadVertexData(currentNode, pMesh);
} else if (currentName == "triangles" || currentName == "lines" || currentName == "linestrips" ||
currentName == "polygons" || currentName == "polylist" || currentName == "trifans" ||
currentName == "tristrips") {
currentName == "polygons" || currentName == "polylist" || currentName == "trifans" ||
currentName == "tristrips") {
ReadIndexData(currentNode, pMesh);
}
}
@ -1439,9 +1433,8 @@ void ColladaParser::ReadDataArray(XmlNode &node) {
throw DeadlyImportError("Expected more values while reading float_array contents.");
}
ai_real value;
// read a number
//SkipSpacesAndLineEnd(&content);
ai_real value;
content = fast_atoreal_move<ai_real>(content, value);
data.mValues.push_back(value);
// skip whitespace after it
@ -1489,11 +1482,10 @@ void ColladaParser::ReadAccessor(XmlNode &node, const std::string &pID) {
std::string name;
if (XmlParser::hasAttribute(currentNode, "name")) {
XmlParser::getStdStrAttribute(currentNode, "name", name);
//name = mReader->getAttributeValue(attrName);
// analyse for common type components and store it's sub-offset in the corresponding field
/* Cartesian coordinates */
// Cartesian coordinates
if (name == "X")
acc.mSubOffset[0] = acc.mParams.size();
else if (name == "Y")
@ -1674,12 +1666,9 @@ void ColladaParser::ReadInputChannel(XmlNode &node, std::vector<InputChannel> &p
// read set if texture coordinates
if (channel.mType == IT_Texcoord || channel.mType == IT_Color) {
int attrSet = -1;
if (XmlParser::hasAttribute(node, "set")) {
XmlParser::getIntAttribute(node, "set", attrSet);
}
channel.mIndex = attrSet;
unsigned int attrSet = 0;
if (XmlParser::getUIntAttribute(node, "set", attrSet))
channel.mIndex = attrSet;
}
// store, if valid type
@ -1704,20 +1693,20 @@ size_t ColladaParser::ReadPrimitives(XmlNode &node, Mesh &pMesh, std::vector<Inp
// determine the expected number of indices
size_t expectedPointCount = 0;
switch (pPrimType) {
case Prim_Polylist: {
for (size_t i : pVCount)
expectedPointCount += i;
break;
}
case Prim_Lines:
expectedPointCount = 2 * pNumPrimitives;
break;
case Prim_Triangles:
expectedPointCount = 3 * pNumPrimitives;
break;
default:
// other primitive types don't state the index count upfront... we need to guess
break;
case Prim_Polylist: {
for (size_t i : pVCount)
expectedPointCount += i;
break;
}
case Prim_Lines:
expectedPointCount = 2 * pNumPrimitives;
break;
case Prim_Triangles:
expectedPointCount = 3 * pNumPrimitives;
break;
default:
// other primitive types don't state the index count upfront... we need to guess
break;
}
// and read all indices into a temporary array
@ -1727,7 +1716,7 @@ size_t ColladaParser::ReadPrimitives(XmlNode &node, Mesh &pMesh, std::vector<Inp
}
// It is possible to not contain any indices
if (pNumPrimitives > 0) {
if (pNumPrimitives > 0) {
std::string v;
XmlParser::getValueAsString(node, v);
const char *content = v.c_str();
@ -1925,87 +1914,87 @@ void ColladaParser::ExtractDataObjectFromChannel(const InputChannel &pInput, siz
// now we reinterpret it according to the type we're reading here
switch (pInput.mType) {
case IT_Position: // ignore all position streams except 0 - there can be only one position
if (pInput.mIndex == 0) {
pMesh.mPositions.push_back(aiVector3D(obj[0], obj[1], obj[2]));
} else {
ASSIMP_LOG_ERROR("Collada: just one vertex position stream supported");
}
break;
case IT_Normal:
case IT_Position: // ignore all position streams except 0 - there can be only one position
if (pInput.mIndex == 0) {
pMesh.mPositions.push_back(aiVector3D(obj[0], obj[1], obj[2]));
} else {
ASSIMP_LOG_ERROR("Collada: just one vertex position stream supported");
}
break;
case IT_Normal:
// pad to current vertex count if necessary
if (pMesh.mNormals.size() < pMesh.mPositions.size() - 1)
pMesh.mNormals.insert(pMesh.mNormals.end(), pMesh.mPositions.size() - pMesh.mNormals.size() - 1, aiVector3D(0, 1, 0));
// ignore all normal streams except 0 - there can be only one normal
if (pInput.mIndex == 0) {
pMesh.mNormals.push_back(aiVector3D(obj[0], obj[1], obj[2]));
} else {
ASSIMP_LOG_ERROR("Collada: just one vertex normal stream supported");
}
break;
case IT_Tangent:
// pad to current vertex count if necessary
if (pMesh.mTangents.size() < pMesh.mPositions.size() - 1)
pMesh.mTangents.insert(pMesh.mTangents.end(), pMesh.mPositions.size() - pMesh.mTangents.size() - 1, aiVector3D(1, 0, 0));
// ignore all tangent streams except 0 - there can be only one tangent
if (pInput.mIndex == 0) {
pMesh.mTangents.push_back(aiVector3D(obj[0], obj[1], obj[2]));
} else {
ASSIMP_LOG_ERROR("Collada: just one vertex tangent stream supported");
}
break;
case IT_Bitangent:
// pad to current vertex count if necessary
if (pMesh.mBitangents.size() < pMesh.mPositions.size() - 1) {
pMesh.mBitangents.insert(pMesh.mBitangents.end(), pMesh.mPositions.size() - pMesh.mBitangents.size() - 1, aiVector3D(0, 0, 1));
}
// ignore all bitangent streams except 0 - there can be only one bitangent
if (pInput.mIndex == 0) {
pMesh.mBitangents.push_back(aiVector3D(obj[0], obj[1], obj[2]));
} else {
ASSIMP_LOG_ERROR("Collada: just one vertex bitangent stream supported");
}
break;
case IT_Texcoord:
// up to 4 texture coord sets are fine, ignore the others
if (pInput.mIndex < AI_MAX_NUMBER_OF_TEXTURECOORDS) {
// pad to current vertex count if necessary
if (pMesh.mNormals.size() < pMesh.mPositions.size() - 1)
pMesh.mNormals.insert(pMesh.mNormals.end(), pMesh.mPositions.size() - pMesh.mNormals.size() - 1, aiVector3D(0, 1, 0));
if (pMesh.mTexCoords[pInput.mIndex].size() < pMesh.mPositions.size() - 1)
pMesh.mTexCoords[pInput.mIndex].insert(pMesh.mTexCoords[pInput.mIndex].end(),
pMesh.mPositions.size() - pMesh.mTexCoords[pInput.mIndex].size() - 1, aiVector3D(0, 0, 0));
// ignore all normal streams except 0 - there can be only one normal
if (pInput.mIndex == 0) {
pMesh.mNormals.push_back(aiVector3D(obj[0], obj[1], obj[2]));
} else {
ASSIMP_LOG_ERROR("Collada: just one vertex normal stream supported");
pMesh.mTexCoords[pInput.mIndex].push_back(aiVector3D(obj[0], obj[1], obj[2]));
if (0 != acc.mSubOffset[2] || 0 != acc.mSubOffset[3]) {
pMesh.mNumUVComponents[pInput.mIndex] = 3;
}
break;
case IT_Tangent:
} else {
ASSIMP_LOG_ERROR("Collada: too many texture coordinate sets. Skipping.");
}
break;
case IT_Color:
// up to 4 color sets are fine, ignore the others
if (pInput.mIndex < AI_MAX_NUMBER_OF_COLOR_SETS) {
// pad to current vertex count if necessary
if (pMesh.mTangents.size() < pMesh.mPositions.size() - 1)
pMesh.mTangents.insert(pMesh.mTangents.end(), pMesh.mPositions.size() - pMesh.mTangents.size() - 1, aiVector3D(1, 0, 0));
if (pMesh.mColors[pInput.mIndex].size() < pMesh.mPositions.size() - 1)
pMesh.mColors[pInput.mIndex].insert(pMesh.mColors[pInput.mIndex].end(),
pMesh.mPositions.size() - pMesh.mColors[pInput.mIndex].size() - 1, aiColor4D(0, 0, 0, 1));
// ignore all tangent streams except 0 - there can be only one tangent
if (pInput.mIndex == 0) {
pMesh.mTangents.push_back(aiVector3D(obj[0], obj[1], obj[2]));
} else {
ASSIMP_LOG_ERROR("Collada: just one vertex tangent stream supported");
}
break;
case IT_Bitangent:
// pad to current vertex count if necessary
if (pMesh.mBitangents.size() < pMesh.mPositions.size() - 1) {
pMesh.mBitangents.insert(pMesh.mBitangents.end(), pMesh.mPositions.size() - pMesh.mBitangents.size() - 1, aiVector3D(0, 0, 1));
aiColor4D result(0, 0, 0, 1);
for (size_t i = 0; i < pInput.mResolved->mSize; ++i) {
result[static_cast<unsigned int>(i)] = obj[pInput.mResolved->mSubOffset[i]];
}
pMesh.mColors[pInput.mIndex].push_back(result);
} else {
ASSIMP_LOG_ERROR("Collada: too many vertex color sets. Skipping.");
}
// ignore all bitangent streams except 0 - there can be only one bitangent
if (pInput.mIndex == 0) {
pMesh.mBitangents.push_back(aiVector3D(obj[0], obj[1], obj[2]));
} else {
ASSIMP_LOG_ERROR("Collada: just one vertex bitangent stream supported");
}
break;
case IT_Texcoord:
// up to 4 texture coord sets are fine, ignore the others
if (pInput.mIndex < AI_MAX_NUMBER_OF_TEXTURECOORDS) {
// pad to current vertex count if necessary
if (pMesh.mTexCoords[pInput.mIndex].size() < pMesh.mPositions.size() - 1)
pMesh.mTexCoords[pInput.mIndex].insert(pMesh.mTexCoords[pInput.mIndex].end(),
pMesh.mPositions.size() - pMesh.mTexCoords[pInput.mIndex].size() - 1, aiVector3D(0, 0, 0));
pMesh.mTexCoords[pInput.mIndex].push_back(aiVector3D(obj[0], obj[1], obj[2]));
if (0 != acc.mSubOffset[2] || 0 != acc.mSubOffset[3]) {
pMesh.mNumUVComponents[pInput.mIndex] = 3;
}
} else {
ASSIMP_LOG_ERROR("Collada: too many texture coordinate sets. Skipping.");
}
break;
case IT_Color:
// up to 4 color sets are fine, ignore the others
if (pInput.mIndex < AI_MAX_NUMBER_OF_COLOR_SETS) {
// pad to current vertex count if necessary
if (pMesh.mColors[pInput.mIndex].size() < pMesh.mPositions.size() - 1)
pMesh.mColors[pInput.mIndex].insert(pMesh.mColors[pInput.mIndex].end(),
pMesh.mPositions.size() - pMesh.mColors[pInput.mIndex].size() - 1, aiColor4D(0, 0, 0, 1));
aiColor4D result(0, 0, 0, 1);
for (size_t i = 0; i < pInput.mResolved->mSize; ++i) {
result[static_cast<unsigned int>(i)] = obj[pInput.mResolved->mSubOffset[i]];
}
pMesh.mColors[pInput.mIndex].push_back(result);
} else {
ASSIMP_LOG_ERROR("Collada: too many vertex color sets. Skipping.");
}
break;
default:
// IT_Invalid and IT_Vertex
ai_assert(false && "shouldn't ever get here");
break;
default:
// IT_Invalid and IT_Vertex
ai_assert(false && "shouldn't ever get here");
}
}
@ -2170,10 +2159,10 @@ void ColladaParser::ReadNodeTransformation(XmlNode &node, Node *pNode, Transform
// read as many parameters and store in the transformation
for (unsigned int a = 0; a < sNumParameters[pType]; a++) {
// skip whitespace before the number
SkipSpacesAndLineEnd(&content);
// read a number
content = fast_atoreal_move<ai_real>(content, tf.f[a]);
// skip whitespace after it
SkipSpacesAndLineEnd(&content);
}
// place the transformation at the queue of the node
@ -2215,8 +2204,8 @@ void ColladaParser::ReadMaterialVertexInputBinding(XmlNode &node, Collada::Seman
void ColladaParser::ReadEmbeddedTextures(ZipArchiveIOSystem &zip_archive) {
// Attempt to load any undefined Collada::Image in ImageLibrary
for (ImageLibrary::iterator it = mImageLibrary.begin(); it != mImageLibrary.end(); ++it) {
Collada::Image &image = (*it).second;
for (auto & it : mImageLibrary) {
Collada::Image &image = it.second;
if (image.mImageData.empty()) {
std::unique_ptr<IOStream> image_file(zip_archive.Open(image.mFileName.c_str()));

View File

@ -5,8 +5,6 @@ Open Asset Import Library (assimp)
Copyright (c) 2006-2021, assimp team
All rights reserved.
Redistribution and use of this software in source and binary forms,
@ -549,7 +547,7 @@ void DXFImporter::ParseEntities(DXF::LineReader& reader, DXF::FileData& output)
++reader;
}
ASSIMP_LOG_VERBOSE_DEBUG( "DXF: got ", block.lines.size()," polylines and ", block.insertions.size(),
ASSIMP_LOG_VERBOSE_DEBUG( "DXF: got ", block.lines.size()," polylines and ", block.insertions.size(),
" inserted blocks in ENTITIES" );
}

View File

@ -63,7 +63,7 @@ namespace DXF {
}
// ---------------------------------------------------------------------------
/**
/**
* @brief DXF importer implementation.
*/
class DXFImporter : public BaseImporter {

View File

@ -862,7 +862,7 @@ bool FBXConverter::GenerateTransformationNodeChain(const Model &model, const std
output_nodes.push_back(std::move(nd));
return false;
}
void FBXConverter::SetupNodeMetadata(const Model &model, aiNode &nd) {
const PropertyTable &props = model.Props();
DirectPropertyMap unparsedProperties = props.GetUnparsedProperties();
@ -917,8 +917,10 @@ void FBXConverter::ConvertModel(const Model &model, aiNode *parent, aiNode *root
} else if (line) {
const std::vector<unsigned int> &indices = ConvertLine(*line, root_node);
std::copy(indices.begin(), indices.end(), std::back_inserter(meshes));
} else {
} else if (geo) {
FBXImporter::LogWarn("ignoring unrecognized geometry: ", geo->Name());
} else {
FBXImporter::LogWarn("skipping null geometry");
}
}
@ -1766,6 +1768,7 @@ void FBXConverter::TrySetTextureProperties(aiMaterial *out_mat, const TextureMap
// XXX handle all kinds of UV transformations
uvTrafo.mScaling = tex->UVScaling();
uvTrafo.mTranslation = tex->UVTranslation();
uvTrafo.mRotation = tex->UVRotation();
out_mat->AddProperty(&uvTrafo, 1, _AI_MATKEY_UVTRANSFORM_BASE, target, 0);
const PropertyTable &props = tex->Props();
@ -1885,6 +1888,7 @@ void FBXConverter::TrySetTextureProperties(aiMaterial *out_mat, const LayeredTex
// XXX handle all kinds of UV transformations
uvTrafo.mScaling = tex->UVScaling();
uvTrafo.mTranslation = tex->UVTranslation();
uvTrafo.mRotation = tex->UVRotation();
out_mat->AddProperty(&uvTrafo, 1, _AI_MATKEY_UVTRANSFORM_BASE, target, texIndex);
const PropertyTable &props = tex->Props();
@ -2129,7 +2133,7 @@ void FBXConverter::SetShadingPropertiesCommon(aiMaterial *out_mat, const Propert
if (ok) {
out_mat->AddProperty(&Emissive, 1, AI_MATKEY_COLOR_EMISSIVE);
} else {
const aiColor3D &emissiveColor = GetColorPropertyFromMaterial(props, "Maya|emissive", ok);
const aiColor3D &emissiveColor = GetColorProperty(props, "Maya|emissive", ok);
if (ok) {
out_mat->AddProperty(&emissiveColor, 1, AI_MATKEY_COLOR_EMISSIVE);
}
@ -2216,7 +2220,7 @@ void FBXConverter::SetShadingPropertiesCommon(aiMaterial *out_mat, const Propert
}
// PBR material information
const aiColor3D &baseColor = GetColorPropertyFromMaterial(props, "Maya|base_color", ok);
const aiColor3D &baseColor = GetColorProperty(props, "Maya|base_color", ok);
if (ok) {
out_mat->AddProperty(&baseColor, 1, AI_MATKEY_BASE_COLOR);
}
@ -2324,6 +2328,7 @@ void FBXConverter::SetShadingPropertiesRaw(aiMaterial *out_mat, const PropertyTa
// XXX handle all kinds of UV transformations
uvTrafo.mScaling = tex->UVScaling();
uvTrafo.mTranslation = tex->UVTranslation();
uvTrafo.mRotation = tex->UVRotation();
out_mat->AddProperty(&uvTrafo, 1, (name + "|uvtrafo").c_str(), aiTextureType_UNKNOWN, 0);
int uvIndex = 0;
@ -2599,7 +2604,7 @@ void FBXConverter::ConvertAnimationStack(const AnimationStack &st) {
anim->mMorphMeshChannels = new aiMeshMorphAnim *[numMorphMeshChannels];
anim->mNumMorphMeshChannels = numMorphMeshChannels;
unsigned int i = 0;
for (auto morphAnimIt : morphAnimDatas) {
for (const auto &morphAnimIt : morphAnimDatas) {
morphAnimData *animData = morphAnimIt.second;
unsigned int numKeys = static_cast<unsigned int>(animData->size());
aiMeshMorphAnim *meshMorphAnim = new aiMeshMorphAnim();
@ -3569,7 +3574,7 @@ void FBXConverter::ConvertOrphanedEmbeddedTextures() {
if (texture->Media() && texture->Media()->ContentLength() > 0) {
realTexture = texture;
}
}
}
}
} catch (...) {
// do nothing

View File

@ -76,7 +76,7 @@ namespace Assimp {
namespace FBX {
class Document;
/**
/**
* Convert a FBX #Document to #aiScene
* @param out Empty scene to be populated
* @param doc Parsed FBX document
@ -182,7 +182,7 @@ private:
// ------------------------------------------------------------------------------------------------
void ConvertModel(const Model &model, aiNode *parent, aiNode *root_node,
const aiMatrix4x4 &absolute_transform);
// ------------------------------------------------------------------------------------------------
// MeshGeometry -> aiMesh, return mesh index + 1 or 0 if the conversion failed
std::vector<unsigned int>

View File

@ -57,9 +57,10 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include <assimp/DefaultLogger.hpp>
#include <memory>
#include <functional>
#include <map>
#include <memory>
#include <utility>
namespace Assimp {
namespace FBX {
@ -248,10 +249,8 @@ Object::~Object()
}
// ------------------------------------------------------------------------------------------------
FileGlobalSettings::FileGlobalSettings(const Document& doc, std::shared_ptr<const PropertyTable> props)
: props(props)
, doc(doc)
{
FileGlobalSettings::FileGlobalSettings(const Document &doc, std::shared_ptr<const PropertyTable> props) :
props(std::move(props)), doc(doc) {
// empty
}
@ -636,7 +635,7 @@ std::vector<const Connection*> Document::GetConnectionsBySourceSequenced(uint64_
}
// ------------------------------------------------------------------------------------------------
std::vector<const Connection*> Document::GetConnectionsBySourceSequenced(uint64_t source,
std::vector<const Connection*> Document::GetConnectionsBySourceSequenced(uint64_t source,
const char* const* classnames, size_t count) const
{
return GetConnectionsSequenced(source, true, ConnectionsBySource(),classnames, count);

View File

@ -500,6 +500,10 @@ public:
return uvScaling;
}
const ai_real &UVRotation() const {
return uvRotation;
}
const PropertyTable& Props() const {
ai_assert(props.get());
return *props.get();
@ -517,6 +521,7 @@ public:
private:
aiVector2D uvTrans;
aiVector2D uvScaling;
ai_real uvRotation;
std::string type;
std::string relativeFileName;

View File

@ -144,9 +144,8 @@ void FBX::Node::AddP70time(
// public member functions for writing nodes to stream
void FBX::Node::Dump(
std::shared_ptr<Assimp::IOStream> outfile,
bool binary, int indent
) {
const std::shared_ptr<Assimp::IOStream> &outfile,
bool binary, int indent) {
if (binary) {
Assimp::StreamWriterLE outstream(outfile);
DumpBinary(outstream);

View File

@ -60,7 +60,7 @@ namespace FBX {
}
class FBX::Node {
public:
public:
// TODO: accessors
std::string name; // node name
std::vector<FBX::FBXExportProperty> properties; // node properties
@ -157,9 +157,8 @@ public: // member functions for writing data to a file or stream
// write the full node to the given file or stream
void Dump(
std::shared_ptr<Assimp::IOStream> outfile,
bool binary, int indent
);
const std::shared_ptr<Assimp::IOStream> &outfile,
bool binary, int indent);
void Dump(Assimp::StreamWriterLE &s, bool binary, int indent);
// these other functions are for writing data piece by piece.

View File

@ -498,7 +498,7 @@ void FBXExporter::WriteDocuments ()
if (!binary) {
WriteAsciiSectionHeader("Documents Description");
}
// not sure what the use of multiple documents would be,
// or whether any end-application supports it
FBX::Node docs("Documents");
@ -541,10 +541,17 @@ void FBXExporter::WriteReferences ()
// (before any actual data is written)
// ---------------------------------------------------------------
size_t count_nodes(const aiNode* n) {
size_t count = 1;
size_t count_nodes(const aiNode* n, const aiNode* root) {
size_t count;
if (n == root) {
count = n->mNumMeshes; // (not counting root node)
} else if (n->mNumMeshes > 1) {
count = n->mNumMeshes + 1;
} else {
count = 1;
}
for (size_t i = 0; i < n->mNumChildren; ++i) {
count += count_nodes(n->mChildren[i]);
count += count_nodes(n->mChildren[i], root);
}
return count;
}
@ -714,7 +721,7 @@ void FBXExporter::WriteDefinitions ()
// Model / FbxNode
// <~~ node hierarchy
count = int32_t(count_nodes(mScene->mRootNode)) - 1; // (not counting root node)
count = int32_t(count_nodes(mScene->mRootNode, mScene->mRootNode));
if (count) {
n = FBX::Node("ObjectType", "Model");
n.AddChild("Count", count);
@ -1251,7 +1258,7 @@ void FBXExporter::WriteObjects ()
indent = 2;
vertexcolors.End(outstream, binary, indent, true);
}
// uvs, if any
for (size_t uvi = 0; uvi < m->GetNumUVChannels(); ++uvi) {
if (m->mNumUVComponents[uvi] > 2) {
@ -1681,6 +1688,10 @@ void FBXExporter::WriteObjects ()
// link the image data to the texture
connections.emplace_back("C", "OO", image_uid, texture_uid);
aiUVTransform trafo;
unsigned int max = sizeof(aiUVTransform);
aiGetMaterialFloatArray(mat, AI_MATKEY_UVTRANSFORM(aiTextureType_DIFFUSE, 0), (ai_real *)&trafo, &max);
// now write the actual texture node
FBX::Node tnode("Texture");
// TODO: some way to determine texture name?
@ -1691,6 +1702,9 @@ void FBXExporter::WriteObjects ()
tnode.AddChild("Version", int32_t(202));
tnode.AddChild("TextureName", texture_name);
FBX::Node p("Properties70");
p.AddP70vectorA("Translation", trafo.mTranslation[0], trafo.mTranslation[1], 0.0);
p.AddP70vectorA("Rotation", 0, 0, trafo.mRotation);
p.AddP70vectorA("Scaling", trafo.mScaling[0], trafo.mScaling[1], 0.0);
p.AddP70enum("CurrentTextureBlendMode", 0); // TODO: verify
//p.AddP70string("UVSet", ""); // TODO: how should this work?
p.AddP70bool("UseMaterial", 1);
@ -1737,7 +1751,7 @@ void FBXExporter::WriteObjects ()
bsnode.AddProperty(blendshape_uid);
bsnode.AddProperty(blendshape_name + FBX::SEPARATOR + "Blendshape");
bsnode.AddProperty("Shape");
bsnode.AddChild("Version", int32_t(100));
bsnode.AddChild("Version", int32_t(100));
bsnode.Begin(outstream, binary, indent);
bsnode.DumpProperties(outstream, binary, indent);
bsnode.EndProperties(outstream, binary, indent);
@ -1863,7 +1877,7 @@ void FBXExporter::WriteObjects ()
// at the same time we can build a list of all the skeleton nodes,
// which will be used later to mark them as type "limbNode".
std::unordered_set<const aiNode*> limbnodes;
//actual bone nodes in fbx, without parenting-up
std::unordered_set<std::string> setAllBoneNamesInScene;
for(unsigned int m = 0; m < mScene->mNumMeshes; ++ m)
@ -1873,7 +1887,7 @@ void FBXExporter::WriteObjects ()
setAllBoneNamesInScene.insert(pMesh->mBones[b]->mName.data);
}
aiMatrix4x4 mxTransIdentity;
// and a map of nodes by bone name, as finding them is annoying.
std::map<std::string,aiNode*> node_by_bone;
for (size_t mi = 0; mi < mScene->mNumMeshes; ++mi) {
@ -1942,7 +1956,7 @@ void FBXExporter::WriteObjects ()
}
if (end) { break; }
}
// if it was the skeleton root we can finish here
if (end) { break; }
}
@ -2196,7 +2210,65 @@ void FBXExporter::WriteObjects ()
bpnode.Dump(outstream, binary, indent);
}*/
// TODO: cameras, lights
// lights
indent = 1;
lights_uids.clear();
for (size_t li = 0; li < mScene->mNumLights; ++li) {
aiLight* l = mScene->mLights[li];
int64_t uid = generate_uid();
const std::string lightNodeAttributeName = l->mName.C_Str() + FBX::SEPARATOR + "NodeAttribute";
FBX::Node lna("NodeAttribute");
lna.AddProperties(uid, lightNodeAttributeName, "Light");
FBX::Node lnap("Properties70");
// Light color.
lnap.AddP70colorA("Color", l->mColorDiffuse.r, l->mColorDiffuse.g, l->mColorDiffuse.b);
// TODO Assimp light description is quite concise and do not handle light intensity.
// Default value to 1000W.
lnap.AddP70numberA("Intensity", 1000);
// FBXLight::EType conversion
switch (l->mType) {
case aiLightSource_POINT:
lnap.AddP70enum("LightType", 0);
break;
case aiLightSource_DIRECTIONAL:
lnap.AddP70enum("LightType", 1);
break;
case aiLightSource_SPOT:
lnap.AddP70enum("LightType", 2);
lnap.AddP70numberA("InnerAngle", AI_RAD_TO_DEG(l->mAngleInnerCone));
lnap.AddP70numberA("OuterAngle", AI_RAD_TO_DEG(l->mAngleOuterCone));
break;
// TODO Assimp do not handle 'area' nor 'volume' lights, but FBX does.
/*case aiLightSource_AREA:
lnap.AddP70enum("LightType", 3);
lnap.AddP70enum("AreaLightShape", 0); // 0=Rectangle, 1=Sphere
break;
case aiLightSource_VOLUME:
lnap.AddP70enum("LightType", 4);
break;*/
default:
break;
}
// Did not understood how to configure the decay so disabling attenuation.
lnap.AddP70enum("DecayType", 0);
// Dump to FBX stream
lna.AddChild(lnap);
lna.AddChild("TypeFlags", FBX::FBXExportProperty("Light"));
lna.AddChild("GeometryVersion", FBX::FBXExportProperty(int32_t(124)));
lna.Dump(outstream, binary, indent);
// Store name and uid (will be used later when parsing scene nodes)
lights_uids[l->mName.C_Str()] = uid;
}
// TODO: cameras
// write nodes (i.e. model hierarchy)
// start at root node
@ -2600,10 +2672,19 @@ void FBXExporter::WriteModelNodes(
// and connect them
connections.emplace_back("C", "OO", node_attribute_uid, node_uid);
} else {
// generate a null node so we can add children to it
WriteModelNode(
outstream, binary, node, node_uid, "Null", transform_chain
);
const auto& lightIt = lights_uids.find(node->mName.C_Str());
if(lightIt != lights_uids.end()) {
// Node has a light connected to it.
WriteModelNode(
outstream, binary, node, node_uid, "Light", transform_chain
);
connections.emplace_back("C", "OO", lightIt->second, node_uid);
} else {
// generate a null node so we can add children to it
WriteModelNode(
outstream, binary, node, node_uid, "Null", transform_chain
);
}
}
// if more than one child mesh, make nodes for each mesh
@ -2625,17 +2706,14 @@ void FBXExporter::WriteModelNodes(
],
new_node_uid
);
// write model node
FBX::Node m("Model");
aiNode new_node;
// take name from mesh name, if it exists
std::string name = mScene->mMeshes[node->mMeshes[i]]->mName.C_Str();
name += FBX::SEPARATOR + "Model";
m.AddProperties(new_node_uid, name, "Mesh");
m.AddChild("Version", int32_t(232));
FBX::Node p("Properties70");
p.AddP70enum("InheritType", 1);
m.AddChild(p);
m.Dump(outstream, binary, 1);
new_node.mName = mScene->mMeshes[node->mMeshes[i]]->mName;
// write model node
WriteModelNode(
outstream, binary, &new_node, new_node_uid, "Mesh", std::vector<std::pair<std::string,aiVector3D>>()
);
}
}
@ -2647,16 +2725,14 @@ void FBXExporter::WriteModelNodes(
}
}
void FBXExporter::WriteAnimationCurveNode(
StreamWriterLE& outstream,
int64_t uid,
const std::string& name, // "T", "R", or "S"
aiVector3D default_value,
std::string property_name, // "Lcl Translation" etc
int64_t layer_uid,
int64_t node_uid
) {
StreamWriterLE &outstream,
int64_t uid,
const std::string &name, // "T", "R", or "S"
aiVector3D default_value,
const std::string &property_name, // "Lcl Translation" etc
int64_t layer_uid,
int64_t node_uid) {
FBX::Node n("AnimationCurveNode");
n.AddProperties(uid, name + FBX::SEPARATOR + "AnimCurveNode", "");
FBX::Node p("Properties70");
@ -2671,7 +2747,6 @@ void FBXExporter::WriteAnimationCurveNode(
this->connections.emplace_back("C", "OP", uid, node_uid, property_name);
}
void FBXExporter::WriteAnimationCurve(
StreamWriterLE& outstream,
double default_value,

View File

@ -63,10 +63,9 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
struct aiScene;
struct aiNode;
//struct aiMaterial;
struct aiLight;
namespace Assimp
{
namespace Assimp {
class IOSystem;
class IOStream;
class ExportProperties;
@ -95,6 +94,7 @@ namespace Assimp
std::vector<int64_t> mesh_uids;
std::vector<int64_t> material_uids;
std::map<const aiNode*,int64_t> node_uids;
std::map<std::string,int64_t> lights_uids;
// this crude unique-ID system is actually fine
int64_t last_uid = 999999;
@ -154,14 +154,13 @@ namespace Assimp
FBX::TransformInheritance ti_type=FBX::TransformInheritance_RSrs
);
void WriteAnimationCurveNode(
StreamWriterLE& outstream,
int64_t uid,
const std::string& name, // "T", "R", or "S"
aiVector3D default_value,
std::string property_name, // "Lcl Translation" etc
int64_t animation_layer_uid,
int64_t node_uid
);
StreamWriterLE &outstream,
int64_t uid,
const std::string &name, // "T", "R", or "S"
aiVector3D default_value,
const std::string &property_name, // "Lcl Translation" etc
int64_t animation_layer_uid,
int64_t node_uid);
void WriteAnimationCurve(
StreamWriterLE& outstream,
double default_value,

View File

@ -142,8 +142,8 @@ Material::~Material() {
// ------------------------------------------------------------------------------------------------
Texture::Texture(uint64_t id, const Element& element, const Document& doc, const std::string& name) :
Object(id,element,name),
uvScaling(1.0f,1.0f),
Object(id,element,name),
uvScaling(1.0f,1.0f),
media(0) {
const Scope& sc = GetRequiredScope(element);
@ -210,6 +210,11 @@ Texture::Texture(uint64_t id, const Element& element, const Document& doc, const
uvTrans.y = trans.y;
}
const aiVector3D &rotation = PropertyGet<aiVector3D>(*props, "Rotation", ok);
if (ok) {
uvRotation = rotation.z;
}
// resolve video links
if(doc.Settings().readTextures) {
const std::vector<const Connection*>& conns = doc.GetConnectionsByDestinationSequenced(ID());
@ -273,8 +278,8 @@ void LayeredTexture::fillTexture(const Document& doc) {
// ------------------------------------------------------------------------------------------------
Video::Video(uint64_t id, const Element& element, const Document& doc, const std::string& name) :
Object(id,element,name),
contentLength(0),
Object(id,element,name),
contentLength(0),
content(0) {
const Scope& sc = GetRequiredScope(element);

View File

@ -633,7 +633,7 @@ void MeshGeometry::ReadVertexDataMaterials(std::vector<int>& materials_out, cons
{
return;
}
// materials are handled separately. First of all, they are assigned per-face
// and not per polyvert. Secondly, ReferenceInformationType=IndexToDirect
// has a slightly different meaning for materials.

View File

@ -52,8 +52,8 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
namespace Assimp {
namespace FBX {
/**
* DOM base class for all kinds of FBX geometry
/**
* DOM base class for all kinds of FBX geometry
*/
class Geometry : public Object
{
@ -76,7 +76,7 @@ private:
typedef std::vector<int> MatIndexArray;
/**
/**
* DOM class for FBX geometry of type "Mesh"
*/
class MeshGeometry : public Geometry
@ -84,7 +84,7 @@ class MeshGeometry : public Geometry
public:
/** The class constructor */
MeshGeometry( uint64_t id, const Element& element, const std::string& name, const Document& doc );
/** The class destructor */
virtual ~MeshGeometry();

View File

@ -192,6 +192,10 @@ Scope::Scope(Parser& parser,bool topLevel)
}
const std::string& str = n->StringContents();
if (str.empty()) {
ParseError("unexpected content: empty string.");
}
elements.insert(ElementMap::value_type(str,new_Element(*n,parser)));
// Element() should stop at the next Key token (or right after a Close token)
@ -642,8 +646,7 @@ void ParseVectorDataArray(std::vector<aiVector3D>& out, const Element& el)
ai_assert(data == end);
uint64_t dataToRead = static_cast<uint64_t>(count) * (type == 'd' ? 8 : 4);
ai_assert(buff.size() == dataToRead);
if (dataToRead > buff.size()) {
if (dataToRead != buff.size()) {
ParseError("Invalid read size (binary)",&el);
}
@ -733,8 +736,7 @@ void ParseVectorDataArray(std::vector<aiColor4D>& out, const Element& el)
ai_assert(data == end);
uint64_t dataToRead = static_cast<uint64_t>(count) * (type == 'd' ? 8 : 4);
ai_assert(buff.size() == dataToRead);
if (dataToRead > buff.size()) {
if (dataToRead != buff.size()) {
ParseError("Invalid read size (binary)",&el);
}
@ -816,8 +818,7 @@ void ParseVectorDataArray(std::vector<aiVector2D>& out, const Element& el)
ai_assert(data == end);
uint64_t dataToRead = static_cast<uint64_t>(count) * (type == 'd' ? 8 : 4);
ai_assert(buff.size() == dataToRead);
if (dataToRead > buff.size()) {
if (dataToRead != buff.size()) {
ParseError("Invalid read size (binary)",&el);
}
@ -892,8 +893,7 @@ void ParseVectorDataArray(std::vector<int>& out, const Element& el)
ai_assert(data == end);
uint64_t dataToRead = static_cast<uint64_t>(count) * 4;
ai_assert(buff.size() == dataToRead);
if (dataToRead > buff.size()) {
if (dataToRead != buff.size()) {
ParseError("Invalid read size (binary)",&el);
}
@ -954,8 +954,7 @@ void ParseVectorDataArray(std::vector<float>& out, const Element& el)
ai_assert(data == end);
uint64_t dataToRead = static_cast<uint64_t>(count) * (type == 'd' ? 8 : 4);
ai_assert(buff.size() == dataToRead);
if (dataToRead > buff.size()) {
if (dataToRead != buff.size()) {
ParseError("Invalid read size (binary)",&el);
}
@ -1019,8 +1018,7 @@ void ParseVectorDataArray(std::vector<unsigned int>& out, const Element& el)
ai_assert(data == end);
uint64_t dataToRead = static_cast<uint64_t>(count) * 4;
ai_assert(buff.size() == dataToRead);
if (dataToRead > buff.size()) {
if (dataToRead != buff.size()) {
ParseError("Invalid read size (binary)",&el);
}
@ -1088,8 +1086,7 @@ void ParseVectorDataArray(std::vector<uint64_t>& out, const Element& el)
ai_assert(data == end);
uint64_t dataToRead = static_cast<uint64_t>(count) * 8;
ai_assert(buff.size() == dataToRead);
if (dataToRead > buff.size()) {
if (dataToRead != buff.size()) {
ParseError("Invalid read size (binary)",&el);
}
@ -1150,8 +1147,7 @@ void ParseVectorDataArray(std::vector<int64_t>& out, const Element& el)
ai_assert(data == end);
uint64_t dataToRead = static_cast<uint64_t>(count) * 8;
ai_assert(buff.size() == dataToRead);
if (dataToRead > buff.size()) {
if (dataToRead != buff.size()) {
ParseError("Invalid read size (binary)",&el);
}

View File

@ -52,6 +52,8 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "FBXDocumentUtil.h"
#include "FBXProperties.h"
#include <utility>
namespace Assimp {
namespace FBX {
@ -172,10 +174,8 @@ PropertyTable::PropertyTable()
}
// ------------------------------------------------------------------------------------------------
PropertyTable::PropertyTable(const Element& element, std::shared_ptr<const PropertyTable> templateProps)
: templateProps(templateProps)
, element(&element)
{
PropertyTable::PropertyTable(const Element &element, std::shared_ptr<const PropertyTable> templateProps) :
templateProps(std::move(templateProps)), element(&element) {
const Scope& scope = GetRequiredScope(element);
for(const ElementMap::value_type& v : scope.Elements()) {
if(v.first != "P") {
@ -199,7 +199,6 @@ PropertyTable::PropertyTable(const Element& element, std::shared_ptr<const Prope
}
}
// ------------------------------------------------------------------------------------------------
PropertyTable::~PropertyTable()
{

View File

@ -98,7 +98,7 @@ typedef std::fbx_unordered_map<std::string,std::shared_ptr<Property> > DirectPro
typedef std::fbx_unordered_map<std::string,const Property*> PropertyMap;
typedef std::fbx_unordered_map<std::string,const Element*> LazyPropertyMap;
/**
/**
* Represents a property table as can be found in the newer FBX files (Properties60, Properties70)
*/
class PropertyTable {
@ -130,7 +130,7 @@ private:
// ------------------------------------------------------------------------------------------------
template <typename T>
inline
inline
T PropertyGet(const PropertyTable& in, const std::string& name, const T& defaultValue) {
const Property* const prop = in.Get(name);
if( nullptr == prop) {
@ -148,7 +148,7 @@ T PropertyGet(const PropertyTable& in, const std::string& name, const T& default
// ------------------------------------------------------------------------------------------------
template <typename T>
inline
inline
T PropertyGet(const PropertyTable& in, const std::string& name, bool& result, bool useTemplate=false ) {
const Property* prop = in.Get(name);
if( nullptr == prop) {

View File

@ -101,7 +101,7 @@ std::string GetLineAndColumnText(unsigned int line, unsigned int column)
std::string GetTokenText(const Token* tok)
{
if(tok->IsBinary()) {
return static_cast<std::string>( Formatter::format() <<
return static_cast<std::string>( Formatter::format() <<
" (" << TokenTypeString(tok->Type()) <<
", offset 0x" << std::hex << tok->Offset() << ") " );
}

View File

@ -153,10 +153,10 @@ void HMPImporter::InternReadFile(const std::string &pFile,
} else {
// Print the magic word to the logger
std::string szBuffer = ai_str_toprintable((const char *)&iMagic, sizeof(iMagic));
delete[] mBuffer;
mBuffer = nullptr;
// We're definitely unable to load this file
throw DeadlyImportError("Unknown HMP subformat ", pFile,
". Magic word (", szBuffer, ") is not known");

View File

@ -513,7 +513,7 @@ void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const Schema_2x3::IfcPoly
}
// we got a list of in-out-combinations of intersections. That should be an even number of intersections, or
// we're fucked.
// we are facing a non-recoverable error.
if ((intersections.size() & 1) != 0) {
IFCImporter::LogWarn("Odd number of intersections, can't work with that. Omitting half space boundary check.");
continue;

View File

@ -514,7 +514,7 @@ IfcFloat Curve::GetParametricRangeDelta() const {
// ------------------------------------------------------------------------------------------------
size_t Curve::EstimateSampleCount(IfcFloat a, IfcFloat b) const {
(void)(a); (void)(b);
(void)(a); (void)(b);
ai_assert( InRange( a ) );
ai_assert( InRange( b ) );

View File

@ -740,7 +740,7 @@ bool ProcessGeometricItem(const Schema_2x3::IfcRepresentationItem& geo, unsigned
bool fix_orientation = false;
std::shared_ptr< TempMesh > meshtmp = std::make_shared<TempMesh>();
if(const Schema_2x3::IfcShellBasedSurfaceModel* shellmod = geo.ToPtr<Schema_2x3::IfcShellBasedSurfaceModel>()) {
for(std::shared_ptr<const Schema_2x3::IfcShell> shell :shellmod->SbsmBoundary) {
for (const std::shared_ptr<const Schema_2x3::IfcShell> &shell : shellmod->SbsmBoundary) {
try {
const ::Assimp::STEP::EXPRESS::ENTITY& e = shell->To<::Assimp::STEP::EXPRESS::ENTITY>();
const Schema_2x3::IfcConnectedFaceSet& fs = conv.db.MustGetObject(e).To<Schema_2x3::IfcConnectedFaceSet>();

View File

@ -75,7 +75,7 @@ static void FillMaterial(aiMaterial* mat,const IFC::Schema_2x3::IfcSurfaceStyle*
mat->AddProperty(&name,AI_MATKEY_NAME);
// now see which kinds of surface information are present
for(std::shared_ptr< const IFC::Schema_2x3::IfcSurfaceStyleElementSelect > sel2 : surf->Styles) {
for (const std::shared_ptr<const IFC::Schema_2x3::IfcSurfaceStyleElementSelect> &sel2 : surf->Styles) {
if (const IFC::Schema_2x3::IfcSurfaceStyleShading* shade = sel2->ResolveSelectPtr<IFC::Schema_2x3::IfcSurfaceStyleShading>(conv.db)) {
aiColor4D col_base,col;
@ -124,7 +124,7 @@ static void FillMaterial(aiMaterial* mat,const IFC::Schema_2x3::IfcSurfaceStyle*
}
}
}
}
}
}
}
@ -134,7 +134,7 @@ unsigned int ProcessMaterials(uint64_t id, unsigned int prevMatId, ConversionDat
for(;range.first != range.second; ++range.first) {
if(const IFC::Schema_2x3::IfcStyledItem* const styled = conv.db.GetObject((*range.first).second)->ToPtr<IFC::Schema_2x3::IfcStyledItem>()) {
for(const IFC::Schema_2x3::IfcPresentationStyleAssignment& as : styled->Styles) {
for(std::shared_ptr<const IFC::Schema_2x3::IfcPresentationStyleSelect> sel : as.Styles) {
for (const std::shared_ptr<const IFC::Schema_2x3::IfcPresentationStyleSelect> &sel : as.Styles) {
if( const IFC::Schema_2x3::IfcSurfaceStyle* const surf = sel->ResolveSelectPtr<IFC::Schema_2x3::IfcSurfaceStyle>(conv.db) ) {
// try to satisfy from cache

View File

@ -911,14 +911,14 @@ size_t CloseWindows(ContourVector& contours,
// compare base poly normal and contour normal to detect if we need to reverse the face winding
if(curmesh.mVertcnt.size() > 0) {
IfcVector3 basePolyNormal = TempMesh::ComputePolygonNormal(curmesh.mVerts.data(), curmesh.mVertcnt.front());
std::vector<IfcVector3> worldSpaceContourVtx(it->contour.size());
for(size_t a = 0; a < it->contour.size(); ++a)
worldSpaceContourVtx[a] = minv * IfcVector3(it->contour[a].x, it->contour[a].y, 0.0);
IfcVector3 contourNormal = TempMesh::ComputePolygonNormal(worldSpaceContourVtx.data(), worldSpaceContourVtx.size());
reverseCountourFaces = (contourNormal * basePolyNormal) > 0.0;
}

View File

@ -5,8 +5,8 @@ Open Asset Import Library (ASSIMP)
Copyright (c) 2006-2020, ASSIMP Development Team
All rights reserved.
Redistribution and use of this software in source and binary forms,
with or without modification, are permitted provided that the
Redistribution and use of this software in source and binary forms,
with or without modification, are permitted provided that the
following conditions are met:
* Redistributions of source code must retain the above
@ -23,16 +23,16 @@ following conditions are met:
derived from this software without specific prior
written permission of the ASSIMP Development Team.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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
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.
----------------------------------------------------------------------
@ -1063,27 +1063,27 @@ template <> size_t GenericFill<IfcRoot>(const DB& db, const LIST& params, IfcRoo
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcRoot"); } do { // convert the 'GlobalId' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRoot,4>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->GlobalId, arg, db ); break; }
try { GenericConvert( in->GlobalId, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRoot to be a `IfcGloballyUniqueId`")); }
} while(0);
do { // convert the 'OwnerHistory' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRoot,4>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->OwnerHistory, arg, db ); break; }
try { GenericConvert( in->OwnerHistory, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRoot to be a `IfcOwnerHistory`")); }
} while(0);
do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRoot,4>::aux_is_derived[2]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; }
try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcRoot to be a `IfcLabel`")); }
} while(0);
do { // convert the 'Description' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRoot,4>::aux_is_derived[3]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Description, arg, db ); break; }
try { GenericConvert( in->Description, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRoot to be a `IfcText`")); }
} while(0);
return base;
@ -1150,27 +1150,27 @@ template <> size_t GenericFill<IfcRepresentation>(const DB& db, const LIST& para
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcRepresentation"); } do { // convert the 'ContextOfItems' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentation,4>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->ContextOfItems, arg, db ); break; }
try { GenericConvert( in->ContextOfItems, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRepresentation to be a `IfcRepresentationContext`")); }
} while(0);
do { // convert the 'RepresentationIdentifier' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentation,4>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->RepresentationIdentifier, arg, db ); break; }
try { GenericConvert( in->RepresentationIdentifier, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRepresentation to be a `IfcLabel`")); }
} while(0);
do { // convert the 'RepresentationType' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentation,4>::aux_is_derived[2]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->RepresentationType, arg, db ); break; }
try { GenericConvert( in->RepresentationType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcRepresentation to be a `IfcLabel`")); }
} while(0);
do { // convert the 'Items' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentation,4>::aux_is_derived[3]=true; break; }
try { GenericConvert( in->Items, arg, db ); break; }
try { GenericConvert( in->Items, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRepresentation to be a `SET [1:?] OF IfcRepresentationItem`")); }
} while(0);
return base;
@ -1237,7 +1237,7 @@ template <> size_t GenericFill<IfcObject>(const DB& db, const LIST& params, IfcO
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcObject,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ObjectType, arg, db ); break; }
try { GenericConvert( in->ObjectType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcObject to be a `IfcLabel`")); }
} while(0);
return base;
@ -1290,20 +1290,20 @@ template <> size_t GenericFill<IfcProductRepresentation>(const DB& db, const LIS
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProductRepresentation,3>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; }
try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcProductRepresentation to be a `IfcLabel`")); }
} while(0);
do { // convert the 'Description' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProductRepresentation,3>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Description, arg, db ); break; }
try { GenericConvert( in->Description, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcProductRepresentation to be a `IfcText`")); }
} while(0);
do { // convert the 'Representations' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProductRepresentation,3>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->Representations, arg, db ); break; }
try { GenericConvert( in->Representations, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcProductRepresentation to be a `LIST [1:?] OF IfcRepresentation`")); }
} while(0);
return base;
@ -1316,14 +1316,14 @@ template <> size_t GenericFill<IfcProduct>(const DB& db, const LIST& params, Ifc
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProduct,2>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ObjectPlacement, arg, db ); break; }
try { GenericConvert( in->ObjectPlacement, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcProduct to be a `IfcObjectPlacement`")); }
} while(0);
do { // convert the 'Representation' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProduct,2>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Representation, arg, db ); break; }
try { GenericConvert( in->Representation, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 6 to IfcProduct to be a `IfcProductRepresentation`")); }
} while(0);
return base;
@ -1336,7 +1336,7 @@ template <> size_t GenericFill<IfcElement>(const DB& db, const LIST& params, Ifc
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcElement,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Tag, arg, db ); break; }
try { GenericConvert( in->Tag, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcElement to be a `IfcIdentifier`")); }
} while(0);
return base;
@ -1374,13 +1374,13 @@ template <> size_t GenericFill<IfcCompositeCurve>(const DB& db, const LIST& para
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcCompositeCurve"); } do { // convert the 'Segments' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCompositeCurve,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Segments, arg, db ); break; }
try { GenericConvert( in->Segments, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcCompositeCurve to be a `LIST [1:?] OF IfcCompositeCurveSegment`")); }
} while(0);
do { // convert the 'SelfIntersect' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCompositeCurve,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->SelfIntersect, arg, db ); break; }
try { GenericConvert( in->SelfIntersect, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcCompositeCurve to be a `LOGICAL`")); }
} while(0);
return base;
@ -1400,27 +1400,27 @@ template <> size_t GenericFill<IfcCartesianTransformationOperator>(const DB& db,
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator,4>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Axis1, arg, db ); break; }
try { GenericConvert( in->Axis1, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcCartesianTransformationOperator to be a `IfcDirection`")); }
} while(0);
do { // convert the 'Axis2' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator,4>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Axis2, arg, db ); break; }
try { GenericConvert( in->Axis2, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcCartesianTransformationOperator to be a `IfcDirection`")); }
} while(0);
do { // convert the 'LocalOrigin' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator,4>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->LocalOrigin, arg, db ); break; }
try { GenericConvert( in->LocalOrigin, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcCartesianTransformationOperator to be a `IfcCartesianPoint`")); }
} while(0);
do { // convert the 'Scale' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator,4>::aux_is_derived[3]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Scale, arg, db ); break; }
try { GenericConvert( in->Scale, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcCartesianTransformationOperator to be a `REAL`")); }
} while(0);
return base;
@ -1433,7 +1433,7 @@ template <> size_t GenericFill<IfcCartesianTransformationOperator3D>(const DB& d
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator3D,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Axis3, arg, db ); break; }
try { GenericConvert( in->Axis3, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcCartesianTransformationOperator3D to be a `IfcDirection`")); }
} while(0);
return base;
@ -1445,14 +1445,14 @@ template <> size_t GenericFill<IfcProperty>(const DB& db, const LIST& params, If
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcProperty"); } do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProperty,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Name, arg, db ); break; }
try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcProperty to be a `IfcIdentifier`")); }
} while(0);
do { // convert the 'Description' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProperty,2>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Description, arg, db ); break; }
try { GenericConvert( in->Description, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcProperty to be a `IfcText`")); }
} while(0);
return base;
@ -1497,7 +1497,7 @@ template <> size_t GenericFill<IfcElementarySurface>(const DB& db, const LIST& p
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcElementarySurface"); } do { // convert the 'Position' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcElementarySurface,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Position, arg, db ); break; }
try { GenericConvert( in->Position, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcElementarySurface to be a `IfcAxis2Placement3D`")); }
} while(0);
return base;
@ -1515,19 +1515,19 @@ template <> size_t GenericFill<IfcBooleanResult>(const DB& db, const LIST& param
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcBooleanResult"); } do { // convert the 'Operator' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBooleanResult,3>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Operator, arg, db ); break; }
try { GenericConvert( in->Operator, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcBooleanResult to be a `IfcBooleanOperator`")); }
} while(0);
do { // convert the 'FirstOperand' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBooleanResult,3>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->FirstOperand, arg, db ); break; }
try { GenericConvert( in->FirstOperand, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcBooleanResult to be a `IfcBooleanOperand`")); }
} while(0);
do { // convert the 'SecondOperand' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBooleanResult,3>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->SecondOperand, arg, db ); break; }
try { GenericConvert( in->SecondOperand, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcBooleanResult to be a `IfcBooleanOperand`")); }
} while(0);
return base;
@ -1551,7 +1551,7 @@ template <> size_t GenericFill<IfcManifoldSolidBrep>(const DB& db, const LIST& p
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcManifoldSolidBrep"); } do { // convert the 'Outer' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcManifoldSolidBrep,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Outer, arg, db ); break; }
try { GenericConvert( in->Outer, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcManifoldSolidBrep to be a `IfcClosedShell`")); }
} while(0);
return base;
@ -1630,12 +1630,12 @@ template <> size_t GenericFill<IfcRelFillsElement>(const DB& db, const LIST& par
size_t base = GenericFill(db,params,static_cast<IfcRelConnects*>(in));
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcRelFillsElement"); } do { // convert the 'RelatingOpeningElement' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->RelatingOpeningElement, arg, db ); break; }
try { GenericConvert( in->RelatingOpeningElement, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRelFillsElement to be a `IfcOpeningElement`")); }
} while(0);
do { // convert the 'RelatedBuildingElement' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->RelatedBuildingElement, arg, db ); break; }
try { GenericConvert( in->RelatedBuildingElement, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcRelFillsElement to be a `IfcElement`")); }
} while(0);
return base;
@ -1681,12 +1681,12 @@ template <> size_t GenericFill<IfcRelContainedInSpatialStructure>(const DB& db,
size_t base = GenericFill(db,params,static_cast<IfcRelConnects*>(in));
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcRelContainedInSpatialStructure"); } do { // convert the 'RelatedElements' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->RelatedElements, arg, db ); break; }
try { GenericConvert( in->RelatedElements, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRelContainedInSpatialStructure to be a `SET [1:?] OF IfcProduct`")); }
} while(0);
do { // convert the 'RelatingStructure' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->RelatingStructure, arg, db ); break; }
try { GenericConvert( in->RelatingStructure, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcRelContainedInSpatialStructure to be a `IfcSpatialStructureElement`")); }
} while(0);
return base;
@ -1772,7 +1772,7 @@ template <> size_t GenericFill<IfcDirection>(const DB& db, const LIST& params, I
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcDirection"); } do { // convert the 'DirectionRatios' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->DirectionRatios, arg, db ); break; }
try { GenericConvert( in->DirectionRatios, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcDirection to be a `LIST [2:3] OF REAL`")); }
} while(0);
return base;
@ -1784,14 +1784,14 @@ template <> size_t GenericFill<IfcProfileDef>(const DB& db, const LIST& params,
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcProfileDef"); } do { // convert the 'ProfileType' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProfileDef,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->ProfileType, arg, db ); break; }
try { GenericConvert( in->ProfileType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcProfileDef to be a `IfcProfileTypeEnum`")); }
} while(0);
do { // convert the 'ProfileName' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProfileDef,2>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ProfileName, arg, db ); break; }
try { GenericConvert( in->ProfileName, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcProfileDef to be a `IfcLabel`")); }
} while(0);
return base;
@ -1803,7 +1803,7 @@ template <> size_t GenericFill<IfcParameterizedProfileDef>(const DB& db, const L
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcParameterizedProfileDef"); } do { // convert the 'Position' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcParameterizedProfileDef,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Position, arg, db ); break; }
try { GenericConvert( in->Position, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcParameterizedProfileDef to be a `IfcAxis2Placement2D`")); }
} while(0);
return base;
@ -1910,7 +1910,7 @@ template <> size_t GenericFill<IfcCircleProfileDef>(const DB& db, const LIST& pa
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcCircleProfileDef"); } do { // convert the 'Radius' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCircleProfileDef,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Radius, arg, db ); break; }
try { GenericConvert( in->Radius, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcCircleProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0);
return base;
@ -1921,7 +1921,7 @@ template <> size_t GenericFill<IfcCircleHollowProfileDef>(const DB& db, const LI
size_t base = GenericFill(db,params,static_cast<IfcCircleProfileDef*>(in));
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcCircleHollowProfileDef"); } do { // convert the 'WallThickness' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->WallThickness, arg, db ); break; }
try { GenericConvert( in->WallThickness, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcCircleHollowProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0);
return base;
@ -1933,7 +1933,7 @@ template <> size_t GenericFill<IfcPlacement>(const DB& db, const LIST& params, I
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcPlacement"); } do { // convert the 'Location' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcPlacement,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Location, arg, db ); break; }
try { GenericConvert( in->Location, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcPlacement to be a `IfcCartesianPoint`")); }
} while(0);
return base;
@ -1945,13 +1945,13 @@ template <> size_t GenericFill<IfcAxis2Placement3D>(const DB& db, const LIST& pa
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcAxis2Placement3D"); } do { // convert the 'Axis' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Axis, arg, db ); break; }
try { GenericConvert( in->Axis, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcAxis2Placement3D to be a `IfcDirection`")); }
} while(0);
do { // convert the 'RefDirection' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->RefDirection, arg, db ); break; }
try { GenericConvert( in->RefDirection, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcAxis2Placement3D to be a `IfcDirection`")); }
} while(0);
return base;
@ -1964,7 +1964,7 @@ template <> size_t GenericFill<IfcPresentationStyle>(const DB& db, const LIST& p
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcPresentationStyle,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; }
try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcPresentationStyle to be a `IfcLabel`")); }
} while(0);
return base;
@ -1982,17 +1982,17 @@ template <> size_t GenericFill<IfcCompositeCurveSegment>(const DB& db, const LIS
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcCompositeCurveSegment"); } do { // convert the 'Transition' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Transition, arg, db ); break; }
try { GenericConvert( in->Transition, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcCompositeCurveSegment to be a `IfcTransitionCode`")); }
} while(0);
do { // convert the 'SameSense' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->SameSense, arg, db ); break; }
try { GenericConvert( in->SameSense, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcCompositeCurveSegment to be a `BOOLEAN`")); }
} while(0);
do { // convert the 'ParentCurve' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->ParentCurve, arg, db ); break; }
try { GenericConvert( in->ParentCurve, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcCompositeCurveSegment to be a `IfcCurve`")); }
} while(0);
return base;
@ -2004,13 +2004,13 @@ template <> size_t GenericFill<IfcRectangleProfileDef>(const DB& db, const LIST&
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcRectangleProfileDef"); } do { // convert the 'XDim' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRectangleProfileDef,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->XDim, arg, db ); break; }
try { GenericConvert( in->XDim, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRectangleProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'YDim' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRectangleProfileDef,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->YDim, arg, db ); break; }
try { GenericConvert( in->YDim, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRectangleProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0);
return base;
@ -2106,12 +2106,12 @@ template <> size_t GenericFill<IfcLocalPlacement>(const DB& db, const LIST& para
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcLocalPlacement"); } do { // convert the 'PlacementRelTo' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->PlacementRelTo, arg, db ); break; }
try { GenericConvert( in->PlacementRelTo, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcLocalPlacement to be a `IfcObjectPlacement`")); }
} while(0);
do { // convert the 'RelativePlacement' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->RelativePlacement, arg, db ); break; }
try { GenericConvert( in->RelativePlacement, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcLocalPlacement to be a `IfcAxis2Placement`")); }
} while(0);
return base;
@ -2123,13 +2123,13 @@ template <> size_t GenericFill<IfcSweptAreaSolid>(const DB& db, const LIST& para
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcSweptAreaSolid"); } do { // convert the 'SweptArea' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSweptAreaSolid,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->SweptArea, arg, db ); break; }
try { GenericConvert( in->SweptArea, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcSweptAreaSolid to be a `IfcProfileDef`")); }
} while(0);
do { // convert the 'Position' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSweptAreaSolid,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->Position, arg, db ); break; }
try { GenericConvert( in->Position, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcSweptAreaSolid to be a `IfcAxis2Placement3D`")); }
} while(0);
return base;
@ -2140,12 +2140,12 @@ template <> size_t GenericFill<IfcRevolvedAreaSolid>(const DB& db, const LIST& p
size_t base = GenericFill(db,params,static_cast<IfcSweptAreaSolid*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcRevolvedAreaSolid"); } do { // convert the 'Axis' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Axis, arg, db ); break; }
try { GenericConvert( in->Axis, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcRevolvedAreaSolid to be a `IfcAxis1Placement`")); }
} while(0);
do { // convert the 'Angle' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Angle, arg, db ); break; }
try { GenericConvert( in->Angle, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRevolvedAreaSolid to be a `IfcPlaneAngleMeasure`")); }
} while(0);
return base;
@ -2170,28 +2170,28 @@ template <> size_t GenericFill<IfcSweptDiskSolid>(const DB& db, const LIST& para
size_t base = GenericFill(db,params,static_cast<IfcSolidModel*>(in));
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcSweptDiskSolid"); } do { // convert the 'Directrix' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Directrix, arg, db ); break; }
try { GenericConvert( in->Directrix, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcSweptDiskSolid to be a `IfcCurve`")); }
} while(0);
do { // convert the 'Radius' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Radius, arg, db ); break; }
try { GenericConvert( in->Radius, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcSweptDiskSolid to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'InnerRadius' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->InnerRadius, arg, db ); break; }
try { GenericConvert( in->InnerRadius, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcSweptDiskSolid to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'StartParam' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->StartParam, arg, db ); break; }
try { GenericConvert( in->StartParam, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcSweptDiskSolid to be a `IfcParameterValue`")); }
} while(0);
do { // convert the 'EndParam' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->EndParam, arg, db ); break; }
try { GenericConvert( in->EndParam, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcSweptDiskSolid to be a `IfcParameterValue`")); }
} while(0);
return base;
@ -2203,13 +2203,13 @@ template <> size_t GenericFill<IfcHalfSpaceSolid>(const DB& db, const LIST& para
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcHalfSpaceSolid"); } do { // convert the 'BaseSurface' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcHalfSpaceSolid,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->BaseSurface, arg, db ); break; }
try { GenericConvert( in->BaseSurface, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcHalfSpaceSolid to be a `IfcSurface`")); }
} while(0);
do { // convert the 'AgreementFlag' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcHalfSpaceSolid,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->AgreementFlag, arg, db ); break; }
try { GenericConvert( in->AgreementFlag, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcHalfSpaceSolid to be a `BOOLEAN`")); }
} while(0);
return base;
@ -2220,12 +2220,12 @@ template <> size_t GenericFill<IfcPolygonalBoundedHalfSpace>(const DB& db, const
size_t base = GenericFill(db,params,static_cast<IfcHalfSpaceSolid*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcPolygonalBoundedHalfSpace"); } do { // convert the 'Position' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Position, arg, db ); break; }
try { GenericConvert( in->Position, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcPolygonalBoundedHalfSpace to be a `IfcAxis2Placement3D`")); }
} while(0);
do { // convert the 'PolygonalBoundary' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->PolygonalBoundary, arg, db ); break; }
try { GenericConvert( in->PolygonalBoundary, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcPolygonalBoundedHalfSpace to be a `IfcBoundedCurve`")); }
} while(0);
return base;
@ -2251,23 +2251,23 @@ template <> size_t GenericFill<IfcProject>(const DB& db, const LIST& params, Ifc
if (params.GetSize() < 9) { throw STEP::TypeError("expected 9 arguments to IfcProject"); } do { // convert the 'LongName' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->LongName, arg, db ); break; }
try { GenericConvert( in->LongName, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcProject to be a `IfcLabel`")); }
} while(0);
do { // convert the 'Phase' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Phase, arg, db ); break; }
try { GenericConvert( in->Phase, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 6 to IfcProject to be a `IfcLabel`")); }
} while(0);
do { // convert the 'RepresentationContexts' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->RepresentationContexts, arg, db ); break; }
try { GenericConvert( in->RepresentationContexts, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcProject to be a `SET [1:?] OF IfcRepresentationContext`")); }
} while(0);
do { // convert the 'UnitsInContext' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->UnitsInContext, arg, db ); break; }
try { GenericConvert( in->UnitsInContext, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 8 to IfcProject to be a `IfcUnitAssignment`")); }
} while(0);
return base;
@ -2327,27 +2327,27 @@ template <> size_t GenericFill<IfcTrimmedCurve>(const DB& db, const LIST& params
size_t base = GenericFill(db,params,static_cast<IfcBoundedCurve*>(in));
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcTrimmedCurve"); } do { // convert the 'BasisCurve' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->BasisCurve, arg, db ); break; }
try { GenericConvert( in->BasisCurve, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcTrimmedCurve to be a `IfcCurve`")); }
} while(0);
do { // convert the 'Trim1' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Trim1, arg, db ); break; }
try { GenericConvert( in->Trim1, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcTrimmedCurve to be a `SET [1:2] OF IfcTrimmingSelect`")); }
} while(0);
do { // convert the 'Trim2' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Trim2, arg, db ); break; }
try { GenericConvert( in->Trim2, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcTrimmedCurve to be a `SET [1:2] OF IfcTrimmingSelect`")); }
} while(0);
do { // convert the 'SenseAgreement' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->SenseAgreement, arg, db ); break; }
try { GenericConvert( in->SenseAgreement, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcTrimmedCurve to be a `BOOLEAN`")); }
} while(0);
do { // convert the 'MasterRepresentation' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->MasterRepresentation, arg, db ); break; }
try { GenericConvert( in->MasterRepresentation, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcTrimmedCurve to be a `IfcTrimmingPreference`")); }
} while(0);
return base;
@ -2359,7 +2359,7 @@ template <> size_t GenericFill<IfcRelDefines>(const DB& db, const LIST& params,
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcRelDefines"); } do { // convert the 'RelatedObjects' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRelDefines,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->RelatedObjects, arg, db ); break; }
try { GenericConvert( in->RelatedObjects, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRelDefines to be a `SET [1:?] OF IfcObject`")); }
} while(0);
return base;
@ -2371,7 +2371,7 @@ template <> size_t GenericFill<IfcRelDefinesByProperties>(const DB& db, const LI
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcRelDefinesByProperties"); } do { // convert the 'RelatingPropertyDefinition' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRelDefinesByProperties,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->RelatingPropertyDefinition, arg, db ); break; }
try { GenericConvert( in->RelatingPropertyDefinition, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcRelDefinesByProperties to be a `IfcPropertySetDefinition`")); }
} while(0);
return base;
@ -2404,7 +2404,7 @@ template <> size_t GenericFill<IfcArbitraryOpenProfileDef>(const DB& db, const L
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcArbitraryOpenProfileDef"); } do { // convert the 'Curve' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcArbitraryOpenProfileDef,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Curve, arg, db ); break; }
try { GenericConvert( in->Curve, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcArbitraryOpenProfileDef to be a `IfcBoundedCurve`")); }
} while(0);
return base;
@ -2570,13 +2570,13 @@ template <> size_t GenericFill<IfcRelDecomposes>(const DB& db, const LIST& param
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcRelDecomposes"); } do { // convert the 'RelatingObject' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRelDecomposes,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->RelatingObject, arg, db ); break; }
try { GenericConvert( in->RelatingObject, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRelDecomposes to be a `IfcObjectDefinition`")); }
} while(0);
do { // convert the 'RelatedObjects' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRelDecomposes,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->RelatedObjects, arg, db ); break; }
try { GenericConvert( in->RelatedObjects, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcRelDecomposes to be a `SET [1:?] OF IfcObjectDefinition`")); }
} while(0);
return base;
@ -2594,7 +2594,7 @@ template <> size_t GenericFill<IfcPolyline>(const DB& db, const LIST& params, If
size_t base = GenericFill(db,params,static_cast<IfcBoundedCurve*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcPolyline"); } do { // convert the 'Points' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Points, arg, db ); break; }
try { GenericConvert( in->Points, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcPolyline to be a `LIST [2:?] OF IfcCartesianPoint`")); }
} while(0);
return base;
@ -2626,12 +2626,12 @@ template <> size_t GenericFill<IfcMappedItem>(const DB& db, const LIST& params,
size_t base = GenericFill(db,params,static_cast<IfcRepresentationItem*>(in));
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcMappedItem"); } do { // convert the 'MappingSource' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->MappingSource, arg, db ); break; }
try { GenericConvert( in->MappingSource, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcMappedItem to be a `IfcRepresentationMap`")); }
} while(0);
do { // convert the 'MappingTarget' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->MappingTarget, arg, db ); break; }
try { GenericConvert( in->MappingTarget, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcMappedItem to be a `IfcCartesianTransformationOperator`")); }
} while(0);
return base;
@ -2658,13 +2658,13 @@ template <> size_t GenericFill<IfcNamedUnit>(const DB& db, const LIST& params, I
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcNamedUnit,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Dimensions, arg, db ); break; }
try { GenericConvert( in->Dimensions, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcNamedUnit to be a `IfcDimensionalExponents`")); }
} while(0);
do { // convert the 'UnitType' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcNamedUnit,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->UnitType, arg, db ); break; }
try { GenericConvert( in->UnitType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcNamedUnit to be a `IfcUnitEnum`")); }
} while(0);
return base;
@ -2719,13 +2719,13 @@ template <> size_t GenericFill<IfcSpatialStructureElement>(const DB& db, const L
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSpatialStructureElement,2>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->LongName, arg, db ); break; }
try { GenericConvert( in->LongName, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcSpatialStructureElement to be a `IfcLabel`")); }
} while(0);
do { // convert the 'CompositionType' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSpatialStructureElement,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->CompositionType, arg, db ); break; }
try { GenericConvert( in->CompositionType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 8 to IfcSpatialStructureElement to be a `IfcElementCompositionEnum`")); }
} while(0);
return base;
@ -2737,19 +2737,19 @@ template <> size_t GenericFill<IfcBuilding>(const DB& db, const LIST& params, If
if (params.GetSize() < 12) { throw STEP::TypeError("expected 12 arguments to IfcBuilding"); } do { // convert the 'ElevationOfRefHeight' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ElevationOfRefHeight, arg, db ); break; }
try { GenericConvert( in->ElevationOfRefHeight, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 9 to IfcBuilding to be a `IfcLengthMeasure`")); }
} while(0);
do { // convert the 'ElevationOfTerrain' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ElevationOfTerrain, arg, db ); break; }
try { GenericConvert( in->ElevationOfTerrain, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 10 to IfcBuilding to be a `IfcLengthMeasure`")); }
} while(0);
do { // convert the 'BuildingAddress' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->BuildingAddress, arg, db ); break; }
try { GenericConvert( in->BuildingAddress, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 11 to IfcBuilding to be a `IfcPostalAddress`")); }
} while(0);
return base;
@ -2761,7 +2761,7 @@ template <> size_t GenericFill<IfcConnectedFaceSet>(const DB& db, const LIST& pa
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcConnectedFaceSet"); } do { // convert the 'CfsFaces' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcConnectedFaceSet,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->CfsFaces, arg, db ); break; }
try { GenericConvert( in->CfsFaces, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcConnectedFaceSet to be a `SET [1:?] OF IfcFace`")); }
} while(0);
return base;
@ -2787,7 +2787,7 @@ template <> size_t GenericFill<IfcConic>(const DB& db, const LIST& params, IfcCo
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcConic"); } do { // convert the 'Position' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcConic,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Position, arg, db ); break; }
try { GenericConvert( in->Position, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcConic to be a `IfcAxis2Placement`")); }
} while(0);
return base;
@ -2834,32 +2834,32 @@ template <> size_t GenericFill<IfcIShapeProfileDef>(const DB& db, const LIST& pa
if (params.GetSize() < 8) { throw STEP::TypeError("expected 8 arguments to IfcIShapeProfileDef"); } do { // convert the 'OverallWidth' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->OverallWidth, arg, db ); break; }
try { GenericConvert( in->OverallWidth, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'OverallDepth' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->OverallDepth, arg, db ); break; }
try { GenericConvert( in->OverallDepth, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'WebThickness' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->WebThickness, arg, db ); break; }
try { GenericConvert( in->WebThickness, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'FlangeThickness' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[3]=true; break; }
try { GenericConvert( in->FlangeThickness, arg, db ); break; }
try { GenericConvert( in->FlangeThickness, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 6 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'FilletRadius' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[4]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->FilletRadius, arg, db ); break; }
try { GenericConvert( in->FilletRadius, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0);
return base;
@ -2933,13 +2933,13 @@ template <> size_t GenericFill<IfcPropertyListValue>(const DB& db, const LIST& p
size_t base = GenericFill(db,params,static_cast<IfcSimpleProperty*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcPropertyListValue"); } do { // convert the 'ListValues' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->ListValues, arg, db ); break; }
try { GenericConvert( in->ListValues, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcPropertyListValue to be a `LIST [1:?] OF IfcValue`")); }
} while(0);
do { // convert the 'Unit' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Unit, arg, db ); break; }
try { GenericConvert( in->Unit, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcPropertyListValue to be a `IfcUnit`")); }
} while(0);
return base;
@ -2965,13 +2965,13 @@ template <> size_t GenericFill<IfcDoor>(const DB& db, const LIST& params, IfcDoo
if (params.GetSize() < 10) { throw STEP::TypeError("expected 10 arguments to IfcDoor"); } do { // convert the 'OverallHeight' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->OverallHeight, arg, db ); break; }
try { GenericConvert( in->OverallHeight, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 8 to IfcDoor to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'OverallWidth' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->OverallWidth, arg, db ); break; }
try { GenericConvert( in->OverallWidth, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 9 to IfcDoor to be a `IfcPositiveLengthMeasure`")); }
} while(0);
return base;
@ -2984,20 +2984,20 @@ template <> size_t GenericFill<IfcStyledItem>(const DB& db, const LIST& params,
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcStyledItem,3>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Item, arg, db ); break; }
try { GenericConvert( in->Item, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcStyledItem to be a `IfcRepresentationItem`")); }
} while(0);
do { // convert the 'Styles' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcStyledItem,3>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->Styles, arg, db ); break; }
try { GenericConvert( in->Styles, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcStyledItem to be a `SET [1:?] OF IfcPresentationStyleAssignment`")); }
} while(0);
do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcStyledItem,3>::aux_is_derived[2]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; }
try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcStyledItem to be a `IfcLabel`")); }
} while(0);
return base;
@ -3023,7 +3023,7 @@ template <> size_t GenericFill<IfcArbitraryClosedProfileDef>(const DB& db, const
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcArbitraryClosedProfileDef"); } do { // convert the 'OuterCurve' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcArbitraryClosedProfileDef,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->OuterCurve, arg, db ); break; }
try { GenericConvert( in->OuterCurve, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcArbitraryClosedProfileDef to be a `IfcCurve`")); }
} while(0);
return base;
@ -3041,12 +3041,12 @@ template <> size_t GenericFill<IfcLine>(const DB& db, const LIST& params, IfcLin
size_t base = GenericFill(db,params,static_cast<IfcCurve*>(in));
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcLine"); } do { // convert the 'Pnt' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Pnt, arg, db ); break; }
try { GenericConvert( in->Pnt, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcLine to be a `IfcCartesianPoint`")); }
} while(0);
do { // convert the 'Dir' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Dir, arg, db ); break; }
try { GenericConvert( in->Dir, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcLine to be a `IfcVector`")); }
} while(0);
return base;
@ -3072,13 +3072,13 @@ template <> size_t GenericFill<IfcPropertySingleValue>(const DB& db, const LIST&
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcPropertySingleValue"); } do { // convert the 'NominalValue' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->NominalValue, arg, db ); break; }
try { GenericConvert( in->NominalValue, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcPropertySingleValue to be a `IfcValue`")); }
} while(0);
do { // convert the 'Unit' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Unit, arg, db ); break; }
try { GenericConvert( in->Unit, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcPropertySingleValue to be a `IfcUnit`")); }
} while(0);
return base;
@ -3111,7 +3111,7 @@ template <> size_t GenericFill<IfcSurfaceStyleShading>(const DB& db, const LIST&
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcSurfaceStyleShading"); } do { // convert the 'SurfaceColour' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSurfaceStyleShading,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->SurfaceColour, arg, db ); break; }
try { GenericConvert( in->SurfaceColour, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcSurfaceStyleShading to be a `IfcColourRgb`")); }
} while(0);
return base;

View File

@ -5,8 +5,8 @@ Open Asset Import Library (ASSIMP)
Copyright (c) 2006-2020, ASSIMP Development Team
All rights reserved.
Redistribution and use of this software in source and binary forms,
with or without modification, are permitted provided that the
Redistribution and use of this software in source and binary forms,
with or without modification, are permitted provided that the
following conditions are met:
* Redistributions of source code must retain the above
@ -23,16 +23,16 @@ following conditions are met:
derived from this software without specific prior
written permission of the ASSIMP Development Team.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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
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.
----------------------------------------------------------------------
@ -59,12 +59,12 @@ template <> size_t GenericFill<IfcSurfaceStyle>(const DB& db, const LIST& params
size_t base = GenericFill(db,params,static_cast<IfcPresentationStyle*>(in));
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcSurfaceStyle"); } do { // convert the 'Side' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Side, arg, db ); break; }
try { GenericConvert( in->Side, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcSurfaceStyle to be a `IfcSurfaceSide`")); }
} while(0);
do { // convert the 'Styles' argument
std::shared_ptr<const DataType> arg = params[ base++ ];
try { GenericConvert( in->Styles, arg, db ); break; }
try { GenericConvert( in->Styles, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcSurfaceStyle to be a `SET [1:5] OF IfcSurfaceStyleElementSelect`")); }
} while(0);
return base;
@ -118,7 +118,7 @@ template <> size_t GenericFill<IfcFace>(const DB& db, const LIST& params, IfcFac
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcFace"); } do { // convert the 'Bounds' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcFace,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Bounds, arg, db ); break; }
try { GenericConvert( in->Bounds, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcFace to be a `SET [1:?] OF IfcFaceBound`")); }
} while(0);
return base;
@ -173,7 +173,7 @@ template <> size_t GenericFill<IfcColourSpecification>(const DB& db, const LIST&
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcColourSpecification,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; }
try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcColourSpecification to be a `IfcLabel`")); }
} while(0);
return base;
@ -184,12 +184,12 @@ template <> size_t GenericFill<IfcVector>(const DB& db, const LIST& params, IfcV
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcVector"); } do { // convert the 'Orientation' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Orientation, arg, db ); break; }
try { GenericConvert( in->Orientation, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcVector to be a `IfcDirection`")); }
} while(0);
do { // convert the 'Magnitude' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Magnitude, arg, db ); break; }
try { GenericConvert( in->Magnitude, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcVector to be a `IfcLengthMeasure`")); }
} while(0);
return base;
@ -207,17 +207,17 @@ template <> size_t GenericFill<IfcColourRgb>(const DB& db, const LIST& params, I
size_t base = GenericFill(db,params,static_cast<IfcColourSpecification*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcColourRgb"); } do { // convert the 'Red' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Red, arg, db ); break; }
try { GenericConvert( in->Red, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcColourRgb to be a `IfcNormalisedRatioMeasure`")); }
} while(0);
do { // convert the 'Green' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Green, arg, db ); break; }
try { GenericConvert( in->Green, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcColourRgb to be a `IfcNormalisedRatioMeasure`")); }
} while(0);
do { // convert the 'Blue' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Blue, arg, db ); break; }
try { GenericConvert( in->Blue, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcColourRgb to be a `IfcNormalisedRatioMeasure`")); }
} while(0);
return base;
@ -243,31 +243,31 @@ template <> size_t GenericFill<IfcSite>(const DB& db, const LIST& params, IfcSit
if (params.GetSize() < 14) { throw STEP::TypeError("expected 14 arguments to IfcSite"); } do { // convert the 'RefLatitude' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->RefLatitude, arg, db ); break; }
try { GenericConvert( in->RefLatitude, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 9 to IfcSite to be a `IfcCompoundPlaneAngleMeasure`")); }
} while(0);
do { // convert the 'RefLongitude' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->RefLongitude, arg, db ); break; }
try { GenericConvert( in->RefLongitude, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 10 to IfcSite to be a `IfcCompoundPlaneAngleMeasure`")); }
} while(0);
do { // convert the 'RefElevation' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->RefElevation, arg, db ); break; }
try { GenericConvert( in->RefElevation, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 11 to IfcSite to be a `IfcLengthMeasure`")); }
} while(0);
do { // convert the 'LandTitleNumber' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->LandTitleNumber, arg, db ); break; }
try { GenericConvert( in->LandTitleNumber, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 12 to IfcSite to be a `IfcLabel`")); }
} while(0);
do { // convert the 'SiteAddress' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->SiteAddress, arg, db ); break; }
try { GenericConvert( in->SiteAddress, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 13 to IfcSite to be a `IfcPostalAddress`")); }
} while(0);
return base;
@ -412,31 +412,31 @@ template <> size_t GenericFill<IfcBSplineCurve>(const DB& db, const LIST& params
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcBSplineCurve"); } do { // convert the 'Degree' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Degree, arg, db ); break; }
try { GenericConvert( in->Degree, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcBSplineCurve to be a `INTEGER`")); }
} while(0);
do { // convert the 'ControlPointsList' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->ControlPointsList, arg, db ); break; }
try { GenericConvert( in->ControlPointsList, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcBSplineCurve to be a `LIST [2:?] OF IfcCartesianPoint`")); }
} while(0);
do { // convert the 'CurveForm' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->CurveForm, arg, db ); break; }
try { GenericConvert( in->CurveForm, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcBSplineCurve to be a `IfcBSplineCurveForm`")); }
} while(0);
do { // convert the 'ClosedCurve' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[3]=true; break; }
try { GenericConvert( in->ClosedCurve, arg, db ); break; }
try { GenericConvert( in->ClosedCurve, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcBSplineCurve to be a `LOGICAL`")); }
} while(0);
do { // convert the 'SelfIntersect' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[4]=true; break; }
try { GenericConvert( in->SelfIntersect, arg, db ); break; }
try { GenericConvert( in->SelfIntersect, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcBSplineCurve to be a `LOGICAL`")); }
} while(0);
return base;
@ -474,7 +474,7 @@ template <> size_t GenericFill<IfcShellBasedSurfaceModel>(const DB& db, const LI
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcShellBasedSurfaceModel"); } do { // convert the 'SbsmBoundary' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->SbsmBoundary, arg, db ); break; }
try { GenericConvert( in->SbsmBoundary, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcShellBasedSurfaceModel to be a `SET [1:?] OF IfcShell`")); }
} while(0);
return base;
@ -492,12 +492,12 @@ template <> size_t GenericFill<IfcExtrudedAreaSolid>(const DB& db, const LIST& p
size_t base = GenericFill(db,params,static_cast<IfcSweptAreaSolid*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcExtrudedAreaSolid"); } do { // convert the 'ExtrudedDirection' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->ExtrudedDirection, arg, db ); break; }
try { GenericConvert( in->ExtrudedDirection, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcExtrudedAreaSolid to be a `IfcDirection`")); }
} while(0);
do { // convert the 'Depth' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Depth, arg, db ); break; }
try { GenericConvert( in->Depth, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcExtrudedAreaSolid to be a `IfcPositiveLengthMeasure`")); }
} while(0);
return base;
@ -522,12 +522,12 @@ template <> size_t GenericFill<IfcRelVoidsElement>(const DB& db, const LIST& par
size_t base = GenericFill(db,params,static_cast<IfcRelConnects*>(in));
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcRelVoidsElement"); } do { // convert the 'RelatingBuildingElement' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->RelatingBuildingElement, arg, db ); break; }
try { GenericConvert( in->RelatingBuildingElement, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRelVoidsElement to be a `IfcElement`")); }
} while(0);
do { // convert the 'RelatedOpeningElement' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->RelatedOpeningElement, arg, db ); break; }
try { GenericConvert( in->RelatedOpeningElement, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcRelVoidsElement to be a `IfcFeatureElementSubtraction`")); }
} while(0);
return base;
@ -546,13 +546,13 @@ template <> size_t GenericFill<IfcCartesianTransformationOperator3DnonUniform>(c
if (params.GetSize() < 7) { throw STEP::TypeError("expected 7 arguments to IfcCartesianTransformationOperator3DnonUniform"); } do { // convert the 'Scale2' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Scale2, arg, db ); break; }
try { GenericConvert( in->Scale2, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcCartesianTransformationOperator3DnonUniform to be a `REAL`")); }
} while(0);
do { // convert the 'Scale3' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Scale3, arg, db ); break; }
try { GenericConvert( in->Scale3, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 6 to IfcCartesianTransformationOperator3DnonUniform to be a `REAL`")); }
} while(0);
return base;
@ -634,7 +634,7 @@ template <> size_t GenericFill<IfcAxis2Placement2D>(const DB& db, const LIST& pa
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcAxis2Placement2D"); } do { // convert the 'RefDirection' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->RefDirection, arg, db ); break; }
try { GenericConvert( in->RefDirection, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcAxis2Placement2D to be a `IfcDirection`")); }
} while(0);
return base;
@ -658,7 +658,7 @@ template <> size_t GenericFill<IfcCartesianPoint>(const DB& db, const LIST& para
size_t base = GenericFill(db,params,static_cast<IfcPoint*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcCartesianPoint"); } do { // convert the 'Coordinates' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Coordinates, arg, db ); break; }
try { GenericConvert( in->Coordinates, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcCartesianPoint to be a `LIST [1:3] OF IfcLengthMeasure`")); }
} while(0);
return base;
@ -682,7 +682,7 @@ template <> size_t GenericFill<IfcPolyLoop>(const DB& db, const LIST& params, If
size_t base = GenericFill(db,params,static_cast<IfcLoop*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcPolyLoop"); } do { // convert the 'Polygon' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Polygon, arg, db ); break; }
try { GenericConvert( in->Polygon, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcPolyLoop to be a `LIST [3:?] OF IfcCartesianPoint`")); }
} while(0);
return base;
@ -716,14 +716,14 @@ template <> size_t GenericFill<IfcRepresentationContext>(const DB& db, const LIS
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentationContext,2>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ContextIdentifier, arg, db ); break; }
try { GenericConvert( in->ContextIdentifier, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRepresentationContext to be a `IfcLabel`")); }
} while(0);
do { // convert the 'ContextType' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentationContext,2>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ContextType, arg, db ); break; }
try { GenericConvert( in->ContextType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRepresentationContext to be a `IfcLabel`")); }
} while(0);
return base;
@ -735,27 +735,27 @@ template <> size_t GenericFill<IfcGeometricRepresentationContext>(const DB& db,
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcGeometricRepresentationContext"); } do { // convert the 'CoordinateSpaceDimension' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcGeometricRepresentationContext,4>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->CoordinateSpaceDimension, arg, db ); break; }
try { GenericConvert( in->CoordinateSpaceDimension, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcGeometricRepresentationContext to be a `IfcDimensionCount`")); }
} while(0);
do { // convert the 'Precision' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcGeometricRepresentationContext,4>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Precision, arg, db ); break; }
try { GenericConvert( in->Precision, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcGeometricRepresentationContext to be a `REAL`")); }
} while(0);
do { // convert the 'WorldCoordinateSystem' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcGeometricRepresentationContext,4>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->WorldCoordinateSystem, arg, db ); break; }
try { GenericConvert( in->WorldCoordinateSystem, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcGeometricRepresentationContext to be a `IfcAxis2Placement`")); }
} while(0);
do { // convert the 'TrueNorth' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcGeometricRepresentationContext,4>::aux_is_derived[3]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->TrueNorth, arg, db ); break; }
try { GenericConvert( in->TrueNorth, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcGeometricRepresentationContext to be a `IfcDirection`")); }
} while(0);
return base;
@ -774,12 +774,12 @@ template <> size_t GenericFill<IfcSIUnit>(const DB& db, const LIST& params, IfcS
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcSIUnit"); } do { // convert the 'Prefix' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Prefix, arg, db ); break; }
try { GenericConvert( in->Prefix, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcSIUnit to be a `IfcSIPrefix`")); }
} while(0);
do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Name, arg, db ); break; }
try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcSIUnit to be a `IfcSIUnitName`")); }
} while(0);
return base;
@ -805,7 +805,7 @@ template <> size_t GenericFill<IfcAxis1Placement>(const DB& db, const LIST& para
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcAxis1Placement"); } do { // convert the 'Axis' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Axis, arg, db ); break; }
try { GenericConvert( in->Axis, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcAxis1Placement to be a `IfcDirection`")); }
} while(0);
return base;
@ -858,12 +858,12 @@ template <> size_t GenericFill<IfcRepresentationMap>(const DB& db, const LIST& p
size_t base = 0;
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcRepresentationMap"); } do { // convert the 'MappingOrigin' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->MappingOrigin, arg, db ); break; }
try { GenericConvert( in->MappingOrigin, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRepresentationMap to be a `IfcAxis2Placement`")); }
} while(0);
do { // convert the 'MappedRepresentation' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->MappedRepresentation, arg, db ); break; }
try { GenericConvert( in->MappedRepresentation, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRepresentationMap to be a `IfcRepresentation`")); }
} while(0);
return base;
@ -1012,12 +1012,12 @@ template <> size_t GenericFill<IfcMeasureWithUnit>(const DB& db, const LIST& par
size_t base = 0;
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcMeasureWithUnit"); } do { // convert the 'ValueComponent' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->ValueComponent, arg, db ); break; }
try { GenericConvert( in->ValueComponent, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcMeasureWithUnit to be a `IfcValue`")); }
} while(0);
do { // convert the 'UnitComponent' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->UnitComponent, arg, db ); break; }
try { GenericConvert( in->UnitComponent, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcMeasureWithUnit to be a `IfcUnit`")); }
} while(0);
return base;
@ -1125,7 +1125,7 @@ template <> size_t GenericFill<IfcFaceBasedSurfaceModel>(const DB& db, const LIS
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcFaceBasedSurfaceModel"); } do { // convert the 'FbsmFaces' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->FbsmFaces, arg, db ); break; }
try { GenericConvert( in->FbsmFaces, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcFaceBasedSurfaceModel to be a `SET [1:?] OF IfcConnectedFaceSet`")); }
} while(0);
return base;
@ -1172,13 +1172,13 @@ template <> size_t GenericFill<IfcFaceBound>(const DB& db, const LIST& params, I
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcFaceBound"); } do { // convert the 'Bound' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcFaceBound,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Bound, arg, db ); break; }
try { GenericConvert( in->Bound, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcFaceBound to be a `IfcLoop`")); }
} while(0);
do { // convert the 'Orientation' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcFaceBound,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->Orientation, arg, db ); break; }
try { GenericConvert( in->Orientation, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcFaceBound to be a `BOOLEAN`")); }
} while(0);
return base;
@ -1216,12 +1216,12 @@ template <> size_t GenericFill<IfcComplexProperty>(const DB& db, const LIST& par
size_t base = GenericFill(db,params,static_cast<IfcProperty*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcComplexProperty"); } do { // convert the 'UsageName' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->UsageName, arg, db ); break; }
try { GenericConvert( in->UsageName, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcComplexProperty to be a `IfcIdentifier`")); }
} while(0);
do { // convert the 'HasProperties' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->HasProperties, arg, db ); break; }
try { GenericConvert( in->HasProperties, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcComplexProperty to be a `SET [1:?] OF IfcProperty`")); }
} while(0);
return base;
@ -1274,7 +1274,7 @@ template <> size_t GenericFill<IfcUnitAssignment>(const DB& db, const LIST& para
size_t base = 0;
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcUnitAssignment"); } do { // convert the 'Units' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Units, arg, db ); break; }
try { GenericConvert( in->Units, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcUnitAssignment to be a `SET [1:?] OF IfcUnit`")); }
} while(0);
return base;
@ -1307,12 +1307,12 @@ template <> size_t GenericFill<IfcElementQuantity>(const DB& db, const LIST& par
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcElementQuantity"); } do { // convert the 'MethodOfMeasurement' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->MethodOfMeasurement, arg, db ); break; }
try { GenericConvert( in->MethodOfMeasurement, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcElementQuantity to be a `IfcLabel`")); }
} while(0);
do { // convert the 'Quantities' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Quantities, arg, db ); break; }
try { GenericConvert( in->Quantities, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcElementQuantity to be a `SET [1:?] OF IfcPhysicalQuantity`")); }
} while(0);
return base;
@ -1379,7 +1379,7 @@ template <> size_t GenericFill<IfcPresentationStyleAssignment>(const DB& db, con
size_t base = 0;
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcPresentationStyleAssignment"); } do { // convert the 'Styles' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Styles, arg, db ); break; }
try { GenericConvert( in->Styles, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcPresentationStyleAssignment to be a `SET [1:?] OF IfcPresentationStyleSelect`")); }
} while(0);
return base;
@ -1418,13 +1418,13 @@ template <> size_t GenericFill<IfcSpace>(const DB& db, const LIST& params, IfcSp
size_t base = GenericFill(db,params,static_cast<IfcSpatialStructureElement*>(in));
if (params.GetSize() < 11) { throw STEP::TypeError("expected 11 arguments to IfcSpace"); } do { // convert the 'InteriorOrExteriorSpace' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->InteriorOrExteriorSpace, arg, db ); break; }
try { GenericConvert( in->InteriorOrExteriorSpace, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 9 to IfcSpace to be a `IfcInternalOrExternalEnum`")); }
} while(0);
do { // convert the 'ElevationWithFlooring' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ElevationWithFlooring, arg, db ); break; }
try { GenericConvert( in->ElevationWithFlooring, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 10 to IfcSpace to be a `IfcLengthMeasure`")); }
} while(0);
return base;
@ -1484,7 +1484,7 @@ template <> size_t GenericFill<IfcSurfaceStyleWithTextures>(const DB& db, const
size_t base = 0;
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcSurfaceStyleWithTextures"); } do { // convert the 'Textures' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Textures, arg, db ); break; }
try { GenericConvert( in->Textures, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcSurfaceStyleWithTextures to be a `LIST [1:?] OF IfcSurfaceTexture`")); }
} while(0);
return base;
@ -1495,22 +1495,22 @@ template <> size_t GenericFill<IfcBoundingBox>(const DB& db, const LIST& params,
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcBoundingBox"); } do { // convert the 'Corner' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Corner, arg, db ); break; }
try { GenericConvert( in->Corner, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcBoundingBox to be a `IfcCartesianPoint`")); }
} while(0);
do { // convert the 'XDim' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->XDim, arg, db ); break; }
try { GenericConvert( in->XDim, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcBoundingBox to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'YDim' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->YDim, arg, db ); break; }
try { GenericConvert( in->YDim, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcBoundingBox to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'ZDim' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->ZDim, arg, db ); break; }
try { GenericConvert( in->ZDim, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcBoundingBox to be a `IfcPositiveLengthMeasure`")); }
} while(0);
return base;
@ -1535,7 +1535,7 @@ template <> size_t GenericFill<IfcCircle>(const DB& db, const LIST& params, IfcC
size_t base = GenericFill(db,params,static_cast<IfcConic*>(in));
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcCircle"); } do { // convert the 'Radius' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Radius, arg, db ); break; }
try { GenericConvert( in->Radius, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcCircle to be a `IfcPositiveLengthMeasure`")); }
} while(0);
return base;
@ -1623,12 +1623,12 @@ template <> size_t GenericFill<IfcConversionBasedUnit>(const DB& db, const LIST&
size_t base = GenericFill(db,params,static_cast<IfcNamedUnit*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcConversionBasedUnit"); } do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->Name, arg, db ); break; }
try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcConversionBasedUnit to be a `IfcLabel`")); }
} while(0);
do { // convert the 'ConversionFactor' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->ConversionFactor, arg, db ); break; }
try { GenericConvert( in->ConversionFactor, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcConversionBasedUnit to be a `IfcMeasureWithUnit`")); }
} while(0);
return base;
@ -1744,12 +1744,12 @@ template <> size_t GenericFill<IfcEllipse>(const DB& db, const LIST& params, Ifc
size_t base = GenericFill(db,params,static_cast<IfcConic*>(in));
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcEllipse"); } do { // convert the 'SemiAxis1' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->SemiAxis1, arg, db ); break; }
try { GenericConvert( in->SemiAxis1, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcEllipse to be a `IfcPositiveLengthMeasure`")); }
} while(0);
do { // convert the 'SemiAxis2' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->SemiAxis2, arg, db ); break; }
try { GenericConvert( in->SemiAxis2, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcEllipse to be a `IfcPositiveLengthMeasure`")); }
} while(0);
return base;
@ -1816,7 +1816,7 @@ template <> size_t GenericFill<IfcPropertySet>(const DB& db, const LIST& params,
size_t base = GenericFill(db,params,static_cast<IfcPropertySetDefinition*>(in));
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcPropertySet"); } do { // convert the 'HasProperties' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->HasProperties, arg, db ); break; }
try { GenericConvert( in->HasProperties, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcPropertySet to be a `SET [1:?] OF IfcProperty`")); }
} while(0);
return base;
@ -1828,48 +1828,48 @@ template <> size_t GenericFill<IfcSurfaceStyleRendering>(const DB& db, const LIS
if (params.GetSize() < 9) { throw STEP::TypeError("expected 9 arguments to IfcSurfaceStyleRendering"); } do { // convert the 'Transparency' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Transparency, arg, db ); break; }
try { GenericConvert( in->Transparency, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcSurfaceStyleRendering to be a `IfcNormalisedRatioMeasure`")); }
} while(0);
do { // convert the 'DiffuseColour' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->DiffuseColour, arg, db ); break; }
try { GenericConvert( in->DiffuseColour, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcSurfaceStyleRendering to be a `IfcColourOrFactor`")); }
} while(0);
do { // convert the 'TransmissionColour' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->TransmissionColour, arg, db ); break; }
try { GenericConvert( in->TransmissionColour, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcSurfaceStyleRendering to be a `IfcColourOrFactor`")); }
} while(0);
do { // convert the 'DiffuseTransmissionColour' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->DiffuseTransmissionColour, arg, db ); break; }
try { GenericConvert( in->DiffuseTransmissionColour, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcSurfaceStyleRendering to be a `IfcColourOrFactor`")); }
} while(0);
do { // convert the 'ReflectionColour' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ReflectionColour, arg, db ); break; }
try { GenericConvert( in->ReflectionColour, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcSurfaceStyleRendering to be a `IfcColourOrFactor`")); }
} while(0);
do { // convert the 'SpecularColour' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->SpecularColour, arg, db ); break; }
try { GenericConvert( in->SpecularColour, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 6 to IfcSurfaceStyleRendering to be a `IfcColourOrFactor`")); }
} while(0);
do { // convert the 'SpecularHighlight' argument
std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->SpecularHighlight, arg, db ); break; }
try { GenericConvert( in->SpecularHighlight, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcSurfaceStyleRendering to be a `IfcSpecularHighlightSelect`")); }
} while(0);
do { // convert the 'ReflectanceMethod' argument
std::shared_ptr<const DataType> arg = params[base++];
try { GenericConvert( in->ReflectanceMethod, arg, db ); break; }
try { GenericConvert( in->ReflectanceMethod, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 8 to IfcSurfaceStyleRendering to be a `IfcReflectanceMethodEnum`")); }
} while(0);
return base;

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@ -5,8 +5,8 @@ Open Asset Import Library (ASSIMP)
Copyright (c) 2006-2020, ASSIMP Development Team
All rights reserved.
Redistribution and use of this software in source and binary forms,
with or without modification, are permitted provided that the
Redistribution and use of this software in source and binary forms,
with or without modification, are permitted provided that the
following conditions are met:
* Redistributions of source code must retain the above
@ -23,16 +23,16 @@ following conditions are met:
derived from this software without specific prior
written permission of the ASSIMP Development Team.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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
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.
----------------------------------------------------------------------
@ -51,12 +51,12 @@ namespace Schema_4 {
using namespace STEP;
using namespace STEP::EXPRESS;
struct NotImplemented : public ObjectHelper<NotImplemented,0> {
};
// ******************************************************************************
// IFC Custom data types

View File

@ -54,6 +54,8 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include <assimp/mesh.h>
#include <assimp/material.h>
#include <utility>
struct aiNode;
namespace Assimp {
@ -137,14 +139,10 @@ struct TempOpening
}
// ------------------------------------------------------------------------------
TempOpening(const IFC::Schema_2x3::IfcSolidModel* solid,IfcVector3 extrusionDir,
std::shared_ptr<TempMesh> profileMesh,
std::shared_ptr<TempMesh> profileMesh2D)
: solid(solid)
, extrusionDir(extrusionDir)
, profileMesh(profileMesh)
, profileMesh2D(profileMesh2D)
{
TempOpening(const IFC::Schema_2x3::IfcSolidModel *solid, IfcVector3 extrusionDir,
std::shared_ptr<TempMesh> profileMesh,
std::shared_ptr<TempMesh> profileMesh2D) :
solid(solid), extrusionDir(extrusionDir), profileMesh(std::move(profileMesh)), profileMesh2D(std::move(profileMesh2D)) {
}
// ------------------------------------------------------------------------------

View File

@ -273,7 +273,7 @@ private:
std::vector<aiNodeAnim*>& anims);
private:
/// Configuration option: desired output FPS
/// Configuration option: desired output FPS
double fps;
/// Configuration option: speed flag was set?

View File

@ -114,7 +114,7 @@ enum PrePostBehaviour
/** \brief Data structure for a LWO animation keyframe
*/
struct Key {
Key() AI_NO_EXCEPT
Key() AI_NO_EXCEPT
: time()
, value()
, inter(IT_LINE)

View File

@ -200,7 +200,7 @@ void LWSImporter::ReadEnvelope(const LWS::Element &dad, LWO::Envelope &fill) {
// reserve enough storage
std::list<LWS::Element>::const_iterator it = dad.children.begin();
fill.keys.reserve(strtoul10(it->tokens[1].c_str()));
for (++it; it != dad.children.end(); ++it) {
@ -318,7 +318,7 @@ void LWSImporter::SetupNodeName(aiNode *nd, LWS::NodeDesc &src) {
} else {
++s;
}
std::string::size_type t = src.path.substr(s).find_last_of(".");
std::string::size_type t = src.path.substr(s).find_last_of('.');
nd->mName.length = ::ai_snprintf(nd->mName.data, MAXLEN, "%s_(%08X)", src.path.substr(s).substr(0, t).c_str(), combined);
return;
@ -466,7 +466,7 @@ std::string LWSImporter::FindLWOFile(const std::string &in) {
std::string tmp(in);
if (in.length() > 3 && in[1] == ':' && in[2] != '\\' && in[2] != '/') {
tmp = in[0] + (std::string(":\\") + in.substr(2));
}
}
if (io->Exists(tmp)) {
return in;

View File

@ -233,12 +233,12 @@ void M3DImporter::importMaterials(const M3DWrapper &m3d) {
ASSIMP_LOG_DEBUG("M3D: importMaterials ", mScene->mNumMaterials);
// add a default material as first
aiMaterial *mat = new aiMaterial;
mat->AddProperty(&name, AI_MATKEY_NAME);
aiMaterial *defaultMat = new aiMaterial;
defaultMat->AddProperty(&name, AI_MATKEY_NAME);
c.a = 1.0f;
c.b = c.g = c.r = 0.6f;
mat->AddProperty(&c, 1, AI_MATKEY_COLOR_DIFFUSE);
mScene->mMaterials[0] = mat;
defaultMat->AddProperty(&c, 1, AI_MATKEY_COLOR_DIFFUSE);
mScene->mMaterials[0] = defaultMat;
if (!m3d->nummaterial || !m3d->material) {
return;
@ -300,12 +300,12 @@ void M3DImporter::importMaterials(const M3DWrapper &m3d) {
m->prop[j].value.textureid < m3d->numtexture &&
m3d->texture[m->prop[j].value.textureid].name) {
name.Set(std::string(std::string(m3d->texture[m->prop[j].value.textureid].name) + ".png"));
mat->AddProperty(&name, aiTxProps[k].pKey, aiTxProps[k].type, aiTxProps[k].index);
newMat->AddProperty(&name, aiTxProps[k].pKey, aiTxProps[k].type, aiTxProps[k].index);
n = 0;
mat->AddProperty(&n, 1, _AI_MATKEY_UVWSRC_BASE, aiProps[k].type, aiProps[k].index);
newMat->AddProperty(&n, 1, _AI_MATKEY_UVWSRC_BASE, aiProps[k].type, aiProps[k].index);
}
}
mScene->mMaterials[i + 1] = mat;
mScene->mMaterials[i + 1] = newMat;
}
}
@ -655,7 +655,7 @@ void M3DImporter::convertPose(const M3DWrapper &m3d, aiMatrix4x4 *m, unsigned in
// ------------------------------------------------------------------------------------------------
// find a node by name
aiNode *M3DImporter::findNode(aiNode *pNode, aiString name) {
aiNode *M3DImporter::findNode(aiNode *pNode, const aiString &name) {
ai_assert(pNode != nullptr);
ai_assert(mScene != nullptr);

View File

@ -89,8 +89,8 @@ private:
// helper functions
aiColor4D mkColor(uint32_t c);
void convertPose(const M3DWrapper &m3d, aiMatrix4x4 *m, unsigned int posid, unsigned int orientid);
aiNode *findNode(aiNode *pNode, aiString name);
void calculateOffsetMatrix(aiNode *pNode, aiMatrix4x4 *m);
aiNode *findNode(aiNode *pNode, const aiString &name);
void calculateOffsetMatrix(aiNode *pNode, aiMatrix4x4 *m);
void populateMesh(const M3DWrapper &m3d, aiMesh *pMesh, std::vector<aiFace> *faces, std::vector<aiVector3D> *verteces,
std::vector<aiVector3D> *normals, std::vector<aiVector3D> *texcoords, std::vector<aiColor4D> *colors,
std::vector<unsigned int> *vertexids);

View File

@ -46,6 +46,7 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef AI_M3DWRAPPER_H_INC
#define AI_M3DWRAPPER_H_INC
#if !(ASSIMP_BUILD_NO_EXPORT || ASSIMP_BUILD_NO_M3D_EXPORTER) || !ASSIMP_BUILD_NO_M3D_IMPORTER
#include <memory>
@ -55,44 +56,75 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// Assimp specific M3D configuration. Comment out these defines to remove functionality
//#define ASSIMP_USE_M3D_READFILECB
// Share stb_image's PNG loader with other importers/exporters instead of bringing our own copy.
#define STBI_ONLY_PNG
#include <stb/stb_image.h>
#include "m3d.h"
namespace Assimp {
class IOSystem;
/// brief The M3D-Wrapper, provudes c++ access to the data.
class M3DWrapper {
m3d_t *m3d_ = nullptr;
unsigned char *saved_output_ = nullptr;
public:
// Construct an empty M3D model
/// Construct an empty M3D model
explicit M3DWrapper();
// Construct an M3D model from provided buffer
// NOTE: The m3d.h SDK function does not mark the data as const. Have assumed it does not write.
// BUG: SECURITY: The m3d.h SDK cannot be informed of the buffer size. BUFFER OVERFLOW IS CERTAIN
/// Construct an M3D model from provided buffer
/// @note The m3d.h SDK function does not mark the data as const. Have assumed it does not write.
/// BUG: SECURITY: The m3d.h SDK cannot be informed of the buffer size. BUFFER OVERFLOW IS CERTAIN
explicit M3DWrapper(IOSystem *pIOHandler, const std::vector<unsigned char> &buffer);
~M3DWrapper();
/// Theclasss destructor.
~M3DWrapper();
void reset();
/// Will reset the wrapper, all data will become nullptr.
void reset();
// Name
inline std::string Name() const {
if (m3d_) return std::string(m3d_->name);
return std::string();
}
// The Name access, empty string returned when no m3d instance.
std::string Name() const;
// Execute a save
/// Executes a save.
unsigned char *Save(int quality, int flags, unsigned int &size);
/// Clearer
void ClearSave();
inline explicit operator bool() const { return m3d_ != nullptr; }
/// True for m3d instance exists.
explicit operator bool() const;
// Allow direct access to M3D API
inline m3d_t *operator->() const { return m3d_; }
inline m3d_t *M3D() const { return m3d_; }
m3d_t *operator->() const;
m3d_t *M3D() const;
private:
m3d_t *m3d_ = nullptr;
unsigned char *saved_output_ = nullptr;
};
inline std::string M3DWrapper::Name() const {
if (nullptr != m3d_) {
if (nullptr != m3d_->name) {
return std::string(m3d_->name);
}
}
return std::string();
}
inline M3DWrapper::operator bool() const {
return m3d_ != nullptr;
}
inline m3d_t *M3DWrapper::operator->() const {
return m3d_;
}
inline m3d_t *M3DWrapper::M3D() const {
return m3d_;
}
} // namespace Assimp
#endif

File diff suppressed because it is too large Load Diff

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@ -485,7 +485,7 @@ void MD5Importer::LoadMD5MeshFile() {
}
MD5::WeightDesc &weightDesc = meshSrc.mWeights[w];
if (weightDesc.mWeight < AI_MD5_WEIGHT_EPSILON && weightDesc.mWeight >= -AI_MD5_WEIGHT_EPSILON) {
if (weightDesc.mWeight < AI_MD5_WEIGHT_EPSILON && weightDesc.mWeight >= -AI_MD5_WEIGHT_EPSILON) {
continue;
}

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@ -120,13 +120,13 @@ struct Surface {
, ulFlags()
, ulNumCompFrames()
, ulNumBaseFrames()
, ulNumShaders()
, ulNumShaders()
, ulNumVertices()
, ulNumTriangles()
, ulOffsetTriangles()
, ulOffsetShaders()
, ulOffsetTexCoords()
, ulOffsetBaseVerts()
, ulOffsetBaseVerts()
, ulOffsetCompVerts()
, ulOffsetFrameBaseFrames()
, ulOffsetFrameCompFrames()

View File

@ -629,7 +629,7 @@ void HL1MDLLoader::read_meshes() {
+-- bodypart --+-- model -- [mesh index, mesh index, ...]
| |
| +-- model -- [mesh index, mesh index, ...]
| |
| |
| ...
|
|-- bodypart -- ...
@ -1298,7 +1298,7 @@ void HL1MDLLoader::read_global_info() {
* @note The structure of this method is taken from HL2 source code.
* Although this is from HL2, it's implementation is almost identical
* to code found in HL1 SDK. See HL1 and HL2 SDKs for more info.
*
*
* source:
* HL1 source code.
* file: studio_render.cpp

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@ -102,7 +102,7 @@ namespace pmx
const unsigned int targetSize = size * 3; // enough to encode
char *targetStart = new char[targetSize];
std::memset(targetStart, 0, targetSize * sizeof(char));
utf8::utf16to8( sourceStart, sourceStart + size/2, targetStart );
std::string result(targetStart);
@ -516,13 +516,13 @@ namespace pmx
stream->read((char*) magic, sizeof(char) * 4);
if (magic[0] != 0x50 || magic[1] != 0x4d || magic[2] != 0x58 || magic[3] != 0x20)
{
throw DeadlyImportError("MMD: Invalid magic number.");
}
throw DeadlyImportError("MMD: Invalid magic number.");
}
stream->read((char*) &version, sizeof(float));
if (version != 2.0f && version != 2.1f)
{
throw DeadlyImportError("MMD: Unsupported version (must be 2.0 or 2.1): ", ai_to_string(version));
}
}
this->setting.Read(stream);
this->model_name = ReadString(stream, setting.encoding);

View File

@ -138,7 +138,7 @@ void OFFImporter::InternReadFile( const std::string& pFile, aiScene* pScene, IOS
const char* car = buffer;
const char* end = buffer + mBuffer2.size();
NextToken(&car, end);
if (car < end - 2 && car[0] == 'S' && car[1] == 'T') {
hasTexCoord = true; car += 2;
}
@ -164,7 +164,7 @@ void OFFImporter::InternReadFile( const std::string& pFile, aiScene* pScene, IOS
dimensions = 3;
hasHomogenous = false;
NextToken(&car, end);
// at this point the next token should be an integer number
if (car >= end - 1 || *car < '0' || *car > '9') {
throw DeadlyImportError("OFF: Header is invalid");
@ -223,7 +223,7 @@ void OFFImporter::InternReadFile( const std::string& pFile, aiScene* pScene, IOS
ASSIMP_LOG_ERROR("OFF: The number of verts in the header is incorrect");
break;
}
aiVector3D& v = mesh->mVertices[i];
aiVector3D& v = mesh->mVertices[i];
sz = line;
// helper array to write a for loop over possible dimension values
@ -255,7 +255,7 @@ void OFFImporter::InternReadFile( const std::string& pFile, aiScene* pScene, IOS
SkipSpaces(&sz);
fast_atoreal_move<ai_real>(sz,(ai_real&)n.z);
}
// reading colors is a pain because the specification says it can be
// integers or floats, and any number of them between 1 and 4 included,
// until the next comment or end of line
@ -321,7 +321,7 @@ void OFFImporter::InternReadFile( const std::string& pFile, aiScene* pScene, IOS
++i;
++faces;
}
// generate the output node graph
pScene->mRootNode = new aiNode();
pScene->mRootNode->mName.Set("<OFFRoot>");

View File

@ -67,7 +67,7 @@ public:
~ObjExporter();
std::string GetMaterialLibName();
std::string GetMaterialLibFileName();
/// public string-streams to write all output into
std::ostringstream mOutput, mOutputMat;
@ -137,13 +137,13 @@ private:
}
};
struct aiVectorCompare {
bool operator() (const aiVector3D& a, const aiVector3D& b) const {
if(a.x < b.x) return true;
if(a.x > b.x) return false;
if(a.y < b.y) return true;
if(a.y > b.y) return false;
if(a.z < b.z) return true;
struct aiVectorCompare {
bool operator() (const aiVector3D& a, const aiVector3D& b) const {
if(a.x < b.x) return true;
if(a.x > b.x) return false;
if(a.y < b.y) return true;
if(a.y > b.y) return false;
if(a.z < b.z) return true;
return false;
}
};
@ -153,7 +153,7 @@ private:
int mNextIndex;
typedef std::map<T, int, Compare> dataType;
dataType vecMap;
public:
indexMap()
: mNextIndex(1) {

View File

@ -162,7 +162,7 @@ void ObjFileImporter::InternReadFile(const std::string &file, aiScene *pScene, I
// ------------------------------------------------------------------------------------------------
// Create the data from parsed obj-file
void ObjFileImporter::CreateDataFromImport(const ObjFile::Model *pModel, aiScene *pScene) {
if (0L == pModel) {
if (nullptr == pModel) {
return;
}
@ -468,7 +468,7 @@ void ObjFileImporter::createVertexArray(const ObjFile::Model *pModel,
}
// Copy all vertex colors
if (!pModel->m_VertexColors.empty()) {
if (vertex < pModel->m_VertexColors.size()) {
const aiVector3D &color = pModel->m_VertexColors[vertex];
pMesh->mColors[0][newIndex] = aiColor4D(color.x, color.y, color.z, 1.0);
}

View File

@ -146,7 +146,7 @@ void ObjFileMtlImporter::load() {
++m_DataIt;
ai_real d;
getFloatValue(d);
m_pModel->m_pCurrentMaterial->alpha = static_cast<ai_real>(1.0) - d;
m_pModel->m_pCurrentMaterial->alpha = static_cast<ai_real>(1.0) - d;
}
m_DataIt = skipLine<DataArrayIt>(m_DataIt, m_DataItEnd, m_uiLine);
} break;

View File

@ -415,8 +415,8 @@ bool OgreImporter::ReadTextureUnit(const std::string &textureUnitName, stringstr
// User defined Assimp config property to detect texture type from filename.
if (m_detectTextureTypeFromFilename) {
size_t posSuffix = textureRef.find_last_of(".");
size_t posUnderscore = textureRef.find_last_of("_");
size_t posSuffix = textureRef.find_last_of('.');
size_t posUnderscore = textureRef.find_last_of('_');
if (posSuffix != string::npos && posUnderscore != string::npos && posSuffix > posUnderscore) {
string identifier = ai_tolower(textureRef.substr(posUnderscore, posSuffix - posUnderscore));

View File

@ -419,8 +419,7 @@ bool PLY::DOM::ParseHeader(IOStreamBuffer<char> &streamBuffer, std::vector<char>
if (PLY::Element::ParseElement(streamBuffer, buffer, &out)) {
// add the element to the list of elements
alElements.push_back(out);
} else if ( TokenMatch(buffer, "end_header\r", 11) || //checks for header end with /r/n ending
TokenMatch(buffer, "end_header", 10)) { //checks for /n ending, if it doesn't end with /r/n
} else if (TokenMatch(buffer, "end_header", 10)) { //checks for /n ending, if it doesn't end with /r/n
// we have reached the end of the header
break;
} else {
@ -501,6 +500,11 @@ bool PLY::DOM::ParseInstanceBinary(IOStreamBuffer<char> &streamBuffer, DOM *p_pc
}
streamBuffer.getNextBlock(buffer);
// remove first char if it's /n in case of file with /r/n
if (((char *)&buffer[0])[0] == '\n')
buffer.erase(buffer.begin(), buffer.begin() + 1);
unsigned int bufferSize = static_cast<unsigned int>(buffer.size());
const char *pCur = (char *)&buffer[0];
if (!p_pcOut->ParseElementInstanceListsBinary(streamBuffer, buffer, pCur, bufferSize, loader, p_bBE)) {

View File

@ -99,7 +99,7 @@ static void extractIds(const std::string &key, int &id1, int &id2) {
return;
}
const std::string::size_type pos = key.find(".");
const std::string::size_type pos = key.find('.');
if (std::string::npos == pos) {
return;
}
@ -208,7 +208,7 @@ void Q3BSPFileImporter::separateMapName(const std::string &importName, std::stri
return;
}
const std::string::size_type pos = importName.rfind(",");
const std::string::size_type pos = importName.rfind(',');
if (std::string::npos == pos) {
archiveName = importName;
return;

View File

@ -438,7 +438,7 @@ void SMDImporter::AddBoneChildren(aiNode* pcNode, uint32_t iParent) {
pc->mTransformation = bone.sAnim.asKeys[0].matrix;
}
if (bone.iParent == static_cast<uint32_t>(-1)) {
if (bone.iParent == static_cast<uint32_t>(-1)) {
bone.mOffsetMatrix = pc->mTransformation;
} else {
bone.mOffsetMatrix = asBones[bone.iParent].mOffsetMatrix * pc->mTransformation;

View File

@ -49,21 +49,22 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "STEPFileEncoding.h"
#include <assimp/TinyFormatter.h>
#include <assimp/fast_atof.h>
#include <memory>
#include <functional>
#include <memory>
#include <utility>
using namespace Assimp;
namespace EXPRESS = STEP::EXPRESS;
// ------------------------------------------------------------------------------------------------
std::string AddLineNumber(const std::string& s,uint64_t line /*= LINE_NOT_SPECIFIED*/, const std::string& prefix = "")
std::string AddLineNumber(const std::string& s,uint64_t line /*= LINE_NOT_SPECIFIED*/, const std::string& prefix = std::string())
{
return line == STEP::SyntaxError::LINE_NOT_SPECIFIED ? prefix+s : static_cast<std::string>( (Formatter::format(),prefix,"(line ",line,") ",s) );
}
// ------------------------------------------------------------------------------------------------
std::string AddEntityID(const std::string& s,uint64_t entity /*= ENTITY_NOT_SPECIFIED*/, const std::string& prefix = "")
std::string AddEntityID(const std::string& s,uint64_t entity /*= ENTITY_NOT_SPECIFIED*/, const std::string& prefix = std::string())
{
return entity == STEP::TypeError::ENTITY_NOT_SPECIFIED ? prefix+s : static_cast<std::string>( (Formatter::format(),prefix,"(entity #",entity,") ",s));
}
@ -87,7 +88,7 @@ static const char *ISO_Token = "ISO-10303-21;";
static const char *FILE_SCHEMA_Token = "FILE_SCHEMA";
// ------------------------------------------------------------------------------------------------
STEP::DB* STEP::ReadFileHeader(std::shared_ptr<IOStream> stream) {
std::shared_ptr<StreamReaderLE> reader = std::shared_ptr<StreamReaderLE>(new StreamReaderLE(stream));
std::shared_ptr<StreamReaderLE> reader = std::shared_ptr<StreamReaderLE>(new StreamReaderLE(std::move(stream)));
std::unique_ptr<STEP::DB> db = std::unique_ptr<STEP::DB>(new STEP::DB(reader));
LineSplitter &splitter = db->GetSplitter();

View File

@ -69,7 +69,7 @@ void ExportSceneSTL(const char* pFile,IOSystem* pIOSystem, const aiScene* pScene
if (exporter.mOutput.fail()) {
throw DeadlyExportError("output data creation failed. Most likely the file became too large: " + std::string(pFile));
}
// we're still here - export successfully completed. Write the file.
std::unique_ptr<IOStream> outfile (pIOSystem->Open(pFile,"wt"));
if (outfile == nullptr) {
@ -88,7 +88,7 @@ void ExportSceneSTLBinary(const char* pFile,IOSystem* pIOSystem, const aiScene*
if (exporter.mOutput.fail()) {
throw DeadlyExportError("output data creation failed. Most likely the file became too large: " + std::string(pFile));
}
// we're still here - export successfully completed. Write the file.
std::unique_ptr<IOStream> outfile (pIOSystem->Open(pFile,"wb"));
if (outfile == nullptr) {
@ -139,9 +139,9 @@ STLExporter::STLExporter(const char* _filename, const aiScene* pScene, bool expo
if (exportPointClouds) {
WritePointCloud("Assimp_Pointcloud", pScene );
return;
}
}
// Export the assimp mesh
// Export the assimp mesh
const std::string name = "AssimpScene";
mOutput << SolidToken << " " << name << endl;
for(unsigned int i = 0; i < pScene->mNumMeshes; ++i) {

View File

@ -372,7 +372,7 @@ void STLImporter::LoadASCIIFile(aiNode *root) {
pMesh->mVertices = new aiVector3D[pMesh->mNumVertices];
for (size_t i=0; i<pMesh->mNumVertices; ++i ) {
pMesh->mVertices[i].x = positionBuffer[i].x;
pMesh->mVertices[i].y = positionBuffer[i].y;
pMesh->mVertices[i].y = positionBuffer[i].y;
pMesh->mVertices[i].z = positionBuffer[i].z;
}
positionBuffer.clear();
@ -382,7 +382,7 @@ void STLImporter::LoadASCIIFile(aiNode *root) {
pMesh->mNormals = new aiVector3D[pMesh->mNumVertices];
for (size_t i=0; i<pMesh->mNumVertices; ++i ) {
pMesh->mNormals[i].x = normalBuffer[i].x;
pMesh->mNormals[i].y = normalBuffer[i].y;
pMesh->mNormals[i].y = normalBuffer[i].y;
pMesh->mNormals[i].z = normalBuffer[i].z;
}
normalBuffer.clear();

View File

@ -634,7 +634,7 @@ private:
};
template <typename T>
inline bool operator==(std::shared_ptr<LazyObject> lo, T whatever) {
inline bool operator==(const std::shared_ptr<LazyObject> &lo, T whatever) {
return *lo == whatever; // XXX use std::forward if we have 0x
}
@ -816,7 +816,7 @@ public:
typedef std::pair<RefMap::const_iterator, RefMap::const_iterator> RefMapRange;
private:
DB(std::shared_ptr<StreamReaderLE> reader) :
DB(const std::shared_ptr<StreamReaderLE> &reader) :
reader(reader), splitter(*reader, true, true), evaluated_count(), schema(nullptr) {}
public:

View File

@ -175,12 +175,11 @@ void StepExporter::WriteFile()
fColor.b = 0.8f;
int ind = 100; // the start index to be used
int faceEntryLen = 30; // number of entries for a triangle/face
std::vector<int> faceEntryLen; // numbers of entries for a triangle/face
// prepare unique (count triangles and vertices)
VectorIndexUMap uniqueVerts; // use a map to reduce find complexity to log(n)
VectorIndexUMap::iterator it;
int countFace = 0;
for (unsigned int i=0; i<mScene->mNumMeshes; ++i)
{
@ -189,7 +188,7 @@ void StepExporter::WriteFile()
{
aiFace* face = &(mesh->mFaces[j]);
if (face->mNumIndices == 3) countFace++;
if (face->mNumIndices >= 3) faceEntryLen.push_back(15 + 5 * face->mNumIndices);
}
for (unsigned int j=0; j<mesh->mNumVertices; ++j)
{
@ -218,10 +217,13 @@ void StepExporter::WriteFile()
// write the top of data
mOutput << "DATA" << endstr;
mOutput << "#1=MECHANICAL_DESIGN_GEOMETRIC_PRESENTATION_REPRESENTATION(' ',(";
for (int i=0; i<countFace; ++i)
size_t countFace = faceEntryLen.size();
size_t faceLenIndex = ind + 2 * uniqueVerts.size();
for (size_t i=0; i<countFace; ++i)
{
mOutput << "#" << i*faceEntryLen + ind + 2*uniqueVerts.size();
mOutput << "#" << faceLenIndex;
if (i!=countFace-1) mOutput << ",";
faceLenIndex += faceEntryLen[i];
}
mOutput << "),#6)" << endstr;
@ -253,10 +255,12 @@ void StepExporter::WriteFile()
mOutput << "#27=DIRECTION('',(1.0,0.0,0.0))" << endstr;
mOutput << "#28= (NAMED_UNIT(#21)LENGTH_UNIT()SI_UNIT(.MILLI.,.METRE.))" << endstr;
mOutput << "#29=CLOSED_SHELL('',(";
for (int i=0; i<countFace; ++i)
faceLenIndex = ind + 2 * uniqueVerts.size() + 8;
for (size_t i=0; i<countFace; ++i)
{
mOutput << "#" << i*faceEntryLen + ind + 2*uniqueVerts.size() + 8;
mOutput << "#" << faceLenIndex;
if (i!=countFace-1) mOutput << ",";
faceLenIndex += faceEntryLen[i];
}
mOutput << "))" << endstr;
@ -289,28 +293,29 @@ void StepExporter::WriteFile()
{
aiFace* face = &(mesh->mFaces[j]);
if (face->mNumIndices != 3) continue;
const int numIndices = face->mNumIndices;
if (numIndices < 3) continue;
aiVector3D* v1 = &(mesh->mVertices[face->mIndices[0]]);
aiVector3D* v2 = &(mesh->mVertices[face->mIndices[1]]);
aiVector3D* v3 = &(mesh->mVertices[face->mIndices[2]]);
aiVector3D dv12 = *v2 - *v1;
aiVector3D dv23 = *v3 - *v2;
aiVector3D dv31 = *v1 - *v3;
aiVector3D dv13 = *v3 - *v1;
dv12.Normalize();
dv23.Normalize();
dv31.Normalize();
dv13.Normalize();
std::vector<int> pidArray(numIndices, -1); // vertex id
std::vector<aiVector3D> dvArray(numIndices); // edge dir
for (int k = 0; k < numIndices; ++k)
{
aiVector3D *v1 = &(mesh->mVertices[face->mIndices[k]]);
pidArray[k] = uniqueVerts.find(v1)->second;
aiVector3D dvY = dv12;
aiVector3D dvX = dvY ^ dv13;
aiVector3D *v2 = nullptr;
if (k + 1 == numIndices)
v2 = &(mesh->mVertices[face->mIndices[0]]);
else
v2 = &(mesh->mVertices[face->mIndices[k + 1]]);
dvArray[k] = *v2 - *v1;
dvArray[k].Normalize();
}
aiVector3D dvY = dvArray[1];
aiVector3D dvX = dvY ^ dvArray[0];
dvX.Normalize();
int pid1 = uniqueVerts.find(v1)->second;
int pid2 = uniqueVerts.find(v2)->second;
int pid3 = uniqueVerts.find(v3)->second;
// mean vertex color for the face if available
if (mesh->HasVertexColors(0))
{
@ -339,35 +344,62 @@ void StepExporter::WriteFile()
/* 2 directions of the plane */
mOutput << "#" << sid+9 << "=PLANE('',#" << sid+10 << ")" << endstr;
mOutput << "#" << sid+10 << "=AXIS2_PLACEMENT_3D('',#" << pid1 << ", #" << sid+11 << ",#" << sid+12 << ")" << endstr;
mOutput << "#" << sid+10 << "=AXIS2_PLACEMENT_3D('',#" << pidArray[0] << ",#" << sid+11 << ",#" << sid+12 << ")" << endstr;
mOutput << "#" << sid + 11 << "=DIRECTION('',(" << dvX.x << "," << dvX.y << "," << dvX.z << "))" << endstr;
mOutput << "#" << sid + 12 << "=DIRECTION('',(" << dvY.x << "," << dvY.y << "," << dvY.z << "))" << endstr;
mOutput << "#" << sid+13 << "=FACE_BOUND('',#" << sid+14 << ",.T.)" << endstr;
mOutput << "#" << sid+14 << "=EDGE_LOOP('',(#" << sid+15 << ",#" << sid+16 << ",#" << sid+17 << "))" << endstr;
mOutput << "#" << sid+14 << "=EDGE_LOOP('',(";
int edgeLoopStart = sid + 15;
for (int k = 0; k < numIndices; ++k)
{
if (k == 0)
mOutput << "#";
else
mOutput << ",#";
mOutput << edgeLoopStart + k;
}
mOutput << "))" << endstr;
/* edge loop */
mOutput << "#" << sid+15 << "=ORIENTED_EDGE('',*,*,#" << sid+18 << ",.T.)" << endstr;
mOutput << "#" << sid+16 << "=ORIENTED_EDGE('',*,*,#" << sid+19 << ",.T.)" << endstr;
mOutput << "#" << sid+17 << "=ORIENTED_EDGE('',*,*,#" << sid+20 << ",.T.)" << endstr;
int orientedEdgesStart = edgeLoopStart + numIndices;
for (int k=0; k < numIndices; k++)
{
mOutput << "#" << edgeLoopStart+k << "=ORIENTED_EDGE('',*,*,#" << orientedEdgesStart + k << ",.T.)" << endstr;
}
/* oriented edges */
mOutput << "#" << sid+18 << "=EDGE_CURVE('',#" << pid1+1 << ",#" << pid2+1 << ",#" << sid+21 << ",.F.)" << endstr;
mOutput << "#" << sid+19 << "=EDGE_CURVE('',#" << pid2+1 << ",#" << pid3+1 << ",#" << sid+22 << ",.T.)" << endstr;
mOutput << "#" << sid+20 << "=EDGE_CURVE('',#" << pid3+1 << ",#" << pid1+1 << ",#" << sid+23 << ",.T.)" << endstr;
int lineStart = orientedEdgesStart + numIndices;
for (int k=0; k < numIndices; ++k)
{
if (k == 0)
mOutput << "#" << orientedEdgesStart+k << "=EDGE_CURVE('',#" << pidArray[k]+1 << ",#" << pidArray[k+1]+1 << ",#" << lineStart+k << ",.F.)" << endstr;
else if (k+1 == numIndices)
mOutput << "#" << orientedEdgesStart+k << "=EDGE_CURVE('',#" << pidArray[k]+1 << ",#" << pidArray[0]+1 << ",#" << lineStart+k << ",.T.)" << endstr;
else
mOutput << "#" << orientedEdgesStart+k << "=EDGE_CURVE('',#" << pidArray[k]+1 << ",#" << pidArray[k+1]+1 << ",#" << lineStart+k << ",.T.)" << endstr;
}
/* 3 lines and 3 vectors for the lines for the 3 edge curves */
mOutput << "#" << sid+21 << "=LINE('',#" << pid1 << ",#" << sid+24 << ")" << endstr;
mOutput << "#" << sid+22 << "=LINE('',#" << pid2 << ",#" << sid+25 << ")" << endstr;
mOutput << "#" << sid+23 << "=LINE('',#" << pid3 << ",#" << sid+26 << ")" << endstr;
mOutput << "#" << sid+24 << "=VECTOR('',#" << sid+27 << ",1.0)" << endstr;
mOutput << "#" << sid+25 << "=VECTOR('',#" << sid+28 << ",1.0)" << endstr;
mOutput << "#" << sid+26 << "=VECTOR('',#" << sid+29 << ",1.0)" << endstr;
mOutput << "#" << sid+27 << "=DIRECTION('',(" << dv12.x << "," << dv12.y << "," << dv12.z << "))" << endstr;
mOutput << "#" << sid+28 << "=DIRECTION('',(" << dv23.x << "," << dv23.y << "," << dv23.z << "))" << endstr;
mOutput << "#" << sid+29 << "=DIRECTION('',(" << dv31.x << "," << dv31.y << "," << dv31.z << "))" << endstr;
ind += faceEntryLen; // increase counter
/* n lines and n vectors for the lines for the n edge curves */
int vectorStart = lineStart + numIndices;
for (int k=0; k < numIndices; ++k)
{
mOutput << "#" << lineStart+k << "=LINE('',#" << pidArray[k] << ",#" << vectorStart+k << ")" << endstr;
}
int directionStart = vectorStart + numIndices;
for (int k=0; k < numIndices; ++k)
{
mOutput << "#" << vectorStart+k << "=VECTOR('',#" << directionStart+k << ",1.0)" << endstr;
}
for (int k=0; k < numIndices; ++k)
{
const aiVector3D &dv = dvArray[k];
mOutput << "#" << directionStart + k << "=DIRECTION('',(" << dv.x << "," << dv.y << "," << dv.z << "))" << endstr;
}
ind += 15 + 5*numIndices; // increase counter
}
}

View File

@ -86,7 +86,7 @@ void ExportSceneXFile(const char* pFile,IOSystem* pIOSystem, const aiScene* pSce
if (iDoTheExportThing.mOutput.fail()) {
throw DeadlyExportError("output data creation failed. Most likely the file became too large: " + std::string(pFile));
}
// we're still here - export successfully completed. Write result to the given IOSYstem
std::unique_ptr<IOStream> outfile (pIOSystem->Open(pFile,"wt"));
if (outfile == nullptr) {
@ -530,8 +530,8 @@ void XFileExporter::writePath(const aiString &path)
while( str.find( "\\\\") != std::string::npos)
str.replace( str.find( "\\\\"), 2, "\\");
while( str.find( "\\") != std::string::npos)
str.replace( str.find( "\\"), 1, "/");
while (str.find('\\') != std::string::npos)
str.replace(str.find('\\'), 1, "/");
mOutput << str;

View File

@ -94,9 +94,9 @@ protected:
void PushTag() { startstr.append( " "); }
/// Leaves an element, decreasing the indentation
void PopTag() {
ai_assert( startstr.length() > 1);
startstr.erase( startstr.length() - 2);
void PopTag() {
ai_assert( startstr.length() > 1);
startstr.erase( startstr.length() - 2);
}
public:

View File

@ -667,9 +667,7 @@ void XFileImporter::ConvertMaterials( aiScene* pScene, std::vector<XFile::Materi
// convert to lower case for easier comparison
for ( unsigned int c = 0; c < sz.length(); ++c ) {
if ( isalpha( (unsigned char) sz[ c ] ) ) {
sz[ c ] = (char) tolower( (unsigned char) sz[ c ] );
}
sz[ c ] = (char) tolower( (unsigned char) sz[ c ] );
}
// Place texture filename property under the corresponding name

View File

@ -63,9 +63,9 @@ class X3DExporter {
// empty
}
SAttribute(SAttribute && rhs) :
Name(std::move(rhs.Name)),
Value(std::move(rhs.Value)) {
SAttribute(SAttribute &&rhs) AI_NO_EXCEPT :
Name(rhs.Name),
Value(rhs.Value) {
// empty
}
};

View File

@ -2890,7 +2890,6 @@ void X3DImporter::Postprocess_CollectMetadata(const CX3DImporter_NodeElement &pN
} // if( !meta_list.empty() )
}
#endif // !ASSIMP_BUILD_NO_X3D_IMPORTER
} // namespace Assimp

View File

@ -240,7 +240,7 @@ void XGLImporter::InternReadFile(const std::string &pFile, aiScene *pScene, IOSy
void XGLImporter::ReadWorld(XmlNode &node, TempScope &scope) {
for (XmlNode &currentNode : node.children()) {
const std::string &s = ai_stdStrToLower(currentNode.name());
// XXX right now we'd skip <lighting> if it comes after
// <object> or <mesh>
if (s == "lighting") {
@ -250,7 +250,7 @@ void XGLImporter::ReadWorld(XmlNode &node, TempScope &scope) {
}
}
aiNode *const nd = ReadObject(node, scope, true);
aiNode *const nd = ReadObject(node, scope);
if (!nd) {
ThrowException("failure reading <world>");
}
@ -296,16 +296,13 @@ aiLight *XGLImporter::ReadDirectionalLight(XmlNode &node) {
}
// ------------------------------------------------------------------------------------------------
aiNode *XGLImporter::ReadObject(XmlNode &node, TempScope &scope, bool skipFirst/*, const char *closetag */) {
aiNode *XGLImporter::ReadObject(XmlNode &node, TempScope &scope) {
aiNode *nd = new aiNode;
std::vector<aiNode *> children;
std::vector<unsigned int> meshes;
try {
for (XmlNode &child : node.children()) {
skipFirst = false;
const std::string &s = ai_stdStrToLower(child.name());
if (s == "mesh") {
const size_t prev = scope.meshes_linear.size();

View File

@ -185,7 +185,7 @@ private:
void ReadWorld(XmlNode &node, TempScope &scope);
void ReadLighting(XmlNode &node, TempScope &scope);
aiLight *ReadDirectionalLight(XmlNode &node);
aiNode *ReadObject(XmlNode &node, TempScope &scope, bool skipFirst = false/*, const char *closetag = "object"*/);
aiNode *ReadObject(XmlNode &node, TempScope &scope);
bool ReadMesh(XmlNode &node, TempScope &scope);
void ReadMaterial(XmlNode &node, TempScope &scope);
aiVector2D ReadVec2(XmlNode &node);

View File

@ -456,11 +456,10 @@ namespace glTF
/// \param [in] pDecodedData - pointer to decoded data array.
/// \param [in] pDecodedData_Length - size of encoded region, in bytes.
/// \param [in] pID - ID of the region.
SEncodedRegion(const size_t pOffset, const size_t pEncodedData_Length, uint8_t* pDecodedData, const size_t pDecodedData_Length, const std::string pID)
: Offset(pOffset), EncodedData_Length(pEncodedData_Length), DecodedData(pDecodedData), DecodedData_Length(pDecodedData_Length), ID(pID)
{}
SEncodedRegion(const size_t pOffset, const size_t pEncodedData_Length, uint8_t *pDecodedData, const size_t pDecodedData_Length, const std::string &pID) :
Offset(pOffset), EncodedData_Length(pEncodedData_Length), DecodedData(pDecodedData), DecodedData_Length(pDecodedData_Length), ID(pID) {}
/// \fn ~SEncodedRegion()
/// \fn ~SEncodedRegion()
/// Destructor.
~SEncodedRegion() { delete [] DecodedData; }
};
@ -1149,8 +1148,7 @@ namespace glTF
void ReadExtensionsUsed(Document& doc);
IOStream* OpenFile(std::string path, const char* mode, bool absolute = false);
IOStream *OpenFile(const std::string &path, const char *mode, bool absolute = false);
};
}

View File

@ -1377,7 +1377,7 @@ inline void Asset::ReadExtensionsUsed(Document &doc) {
#undef CHECK_EXT
}
inline IOStream *Asset::OpenFile(std::string path, const char *mode, bool absolute) {
inline IOStream *Asset::OpenFile(const std::string& path, const char *mode, bool absolute) {
#ifdef ASSIMP_API
(void)absolute;
return mIOSystem->Open(path, mode);

View File

@ -195,11 +195,11 @@ inline void CopyValue(const glTFCommon::mat4 &v, aiMatrix4x4 &o) {
inline std::string getCurrentAssetDir(const std::string &pFile) {
std::string path = pFile;
int pos = std::max(int(pFile.rfind('/')), int(pFile.rfind('\\')));
if (pos != int(std::string::npos)) {
path = pFile.substr(0, pos + 1);
if (pos == int(std::string::npos)) {
return std::string();
}
return path;
return pFile.substr(0, pos + 1);
}
#if _MSC_VER
# pragma warning(pop)

View File

@ -408,8 +408,7 @@ void glTFExporter::ExportMaterials()
* Search through node hierarchy and find the node containing the given meshID.
* Returns true on success, and false otherwise.
*/
bool FindMeshNode(Ref<Node>& nodeIn, Ref<Node>& meshNode, std::string meshID)
{
bool FindMeshNode(Ref<Node> &nodeIn, Ref<Node> &meshNode, const std::string &meshID) {
for (unsigned int i = 0; i < nodeIn->meshes.size(); ++i) {
if (meshID.compare(nodeIn->meshes[i]->id) == 0) {
meshNode = nodeIn;
@ -530,6 +529,7 @@ void ExportSkin(Asset& mAsset, const aiMesh* aimesh, Ref<Mesh>& meshRef, Ref<Buf
#if defined(__has_warning)
#if __has_warning("-Wunused-but-set-variable")
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-but-set-variable"
#endif
#endif

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