assimp/code/AssetLib/Collada/ColladaLoader.cpp

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/*
---------------------------------------------------------------------------
Open Asset Import Library (assimp)
---------------------------------------------------------------------------
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Copyright (c) 2006-2021, assimp team
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All rights reserved.
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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.
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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
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A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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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.
---------------------------------------------------------------------------
*/
/** @file Implementation of the Collada loader */
#ifndef ASSIMP_BUILD_NO_COLLADA_IMPORTER
#include "ColladaLoader.h"
#include "ColladaParser.h"
#include <assimp/ColladaMetaData.h>
#include <assimp/CreateAnimMesh.h>
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#include <assimp/Defines.h>
#include <assimp/ParsingUtils.h>
#include <assimp/SkeletonMeshBuilder.h>
#include <assimp/ZipArchiveIOSystem.h>
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#include <assimp/anim.h>
#include <assimp/fast_atof.h>
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#include <assimp/importerdesc.h>
#include <assimp/scene.h>
#include <assimp/DefaultLogger.hpp>
#include <assimp/Importer.hpp>
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#include <numeric>
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namespace Assimp {
using namespace Assimp::Formatter;
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using namespace Assimp::Collada;
static const aiImporterDesc desc = {
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"Collada Importer",
"",
"",
"http://collada.org",
aiImporterFlags_SupportTextFlavour | aiImporterFlags_SupportCompressedFlavour,
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1,
3,
1,
5,
"dae xml zae"
};
static const float kMillisecondsFromSeconds = 1000.f;
// Add an item of metadata to a node
// Assumes the key is not already in the list
template <typename T>
inline void AddNodeMetaData(aiNode *node, const std::string &key, const T &value) {
if (nullptr == node->mMetaData) {
node->mMetaData = new aiMetadata();
}
node->mMetaData->Add(key, value);
}
// ------------------------------------------------------------------------------------------------
// Constructor to be privately used by Importer
ColladaLoader::ColladaLoader() :
mFileName(),
mMeshIndexByID(),
mMaterialIndexByName(),
mMeshes(),
newMats(),
mCameras(),
mLights(),
mTextures(),
mAnims(),
noSkeletonMesh(false),
ignoreUpDirection(false),
useColladaName(false),
mNodeNameCounter(0) {
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// empty
}
// ------------------------------------------------------------------------------------------------
// Destructor, private as well
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ColladaLoader::~ColladaLoader() {
// empty
}
// ------------------------------------------------------------------------------------------------
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// Returns whether the class can handle the format of the given file.
bool ColladaLoader::CanRead(const std::string &pFile, IOSystem *pIOHandler, bool checkSig) const {
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// check file extension
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const std::string extension = GetExtension(pFile);
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const bool readSig = checkSig && (pIOHandler != nullptr);
if (!readSig) {
if (extension == "dae" || extension == "zae") {
return true;
}
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} else {
// Look for a DAE file inside, but don't extract it
ZipArchiveIOSystem zip_archive(pIOHandler, pFile);
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if (zip_archive.isOpen()) {
return !ColladaParser::ReadZaeManifest(zip_archive).empty();
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}
}
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// XML - too generic, we need to open the file and search for typical keywords
if (extension == "xml" || !extension.length() || checkSig) {
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/* 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.
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*/
if (!pIOHandler) {
return true;
}
static const char *tokens[] = { "<collada" };
return SearchFileHeaderForToken(pIOHandler, pFile, tokens, 1);
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}
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return false;
}
// ------------------------------------------------------------------------------------------------
void ColladaLoader::SetupProperties(const Importer *pImp) {
noSkeletonMesh = pImp->GetPropertyInteger(AI_CONFIG_IMPORT_NO_SKELETON_MESHES, 0) != 0;
ignoreUpDirection = pImp->GetPropertyInteger(AI_CONFIG_IMPORT_COLLADA_IGNORE_UP_DIRECTION, 0) != 0;
useColladaName = pImp->GetPropertyInteger(AI_CONFIG_IMPORT_COLLADA_USE_COLLADA_NAMES, 0) != 0;
}
// ------------------------------------------------------------------------------------------------
// Get file extension list
const aiImporterDesc *ColladaLoader::GetInfo() const {
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return &desc;
}
// ------------------------------------------------------------------------------------------------
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// Imports the given file into the given scene structure.
void ColladaLoader::InternReadFile(const std::string &pFile, aiScene *pScene, IOSystem *pIOHandler) {
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mFileName = pFile;
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// clean all member arrays - just for safety, it should work even if we did not
mMeshIndexByID.clear();
mMaterialIndexByName.clear();
mMeshes.clear();
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mTargetMeshes.clear();
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newMats.clear();
mLights.clear();
mCameras.clear();
mTextures.clear();
mAnims.clear();
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// parse the input file
ColladaParser parser(pIOHandler, pFile);
if (!parser.mRootNode) {
throw DeadlyImportError("Collada: File came out empty. Something is wrong here.");
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}
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// reserve some storage to avoid unnecessary reallocs
newMats.reserve(parser.mMaterialLibrary.size() * 2u);
mMeshes.reserve(parser.mMeshLibrary.size() * 2u);
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mCameras.reserve(parser.mCameraLibrary.size());
mLights.reserve(parser.mLightLibrary.size());
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// create the materials first, for the meshes to find
BuildMaterials(parser, pScene);
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// build the node hierarchy from it
pScene->mRootNode = BuildHierarchy(parser, parser.mRootNode);
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// ... then fill the materials with the now adjusted settings
FillMaterials(parser, pScene);
// Apply unit-size scale calculation
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pScene->mRootNode->mTransformation *= aiMatrix4x4(parser.mUnitSize, 0, 0, 0,
0, parser.mUnitSize, 0, 0,
0, 0, parser.mUnitSize, 0,
0, 0, 0, 1);
if (!ignoreUpDirection) {
// Convert to Y_UP, if different orientation
if (parser.mUpDirection == ColladaParser::UP_X) {
pScene->mRootNode->mTransformation *= aiMatrix4x4(
0, -1, 0, 0,
1, 0, 0, 0,
0, 0, 1, 0,
0, 0, 0, 1);
} else if (parser.mUpDirection == ColladaParser::UP_Z) {
pScene->mRootNode->mTransformation *= aiMatrix4x4(
1, 0, 0, 0,
0, 0, 1, 0,
0, -1, 0, 0,
0, 0, 0, 1);
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}
}
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// Store scene metadata
if (!parser.mAssetMetaData.empty()) {
const size_t numMeta(parser.mAssetMetaData.size());
pScene->mMetaData = aiMetadata::Alloc(static_cast<unsigned int>(numMeta));
size_t i = 0;
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for (auto it = parser.mAssetMetaData.cbegin(); it != parser.mAssetMetaData.cend(); ++it, ++i) {
pScene->mMetaData->Set(static_cast<unsigned int>(i), (*it).first, (*it).second);
}
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}
StoreSceneMeshes(pScene);
StoreSceneMaterials(pScene);
StoreSceneTextures(pScene);
StoreSceneLights(pScene);
StoreSceneCameras(pScene);
StoreAnimations(pScene, parser);
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// If no meshes have been loaded, it's probably just an animated skeleton.
if (0u == pScene->mNumMeshes) {
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if (!noSkeletonMesh) {
SkeletonMeshBuilder hero(pScene);
}
pScene->mFlags |= AI_SCENE_FLAGS_INCOMPLETE;
}
}
// ------------------------------------------------------------------------------------------------
// Recursively constructs a scene node for the given parser node and returns it.
aiNode *ColladaLoader::BuildHierarchy(const ColladaParser &pParser, const Collada::Node *pNode) {
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// create a node for it
aiNode *node = new aiNode();
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// find a name for the new node. It's more complicated than you might think
node->mName.Set(FindNameForNode(pNode));
// if we're not using the unique IDs, hold onto them for reference and export
if (useColladaName) {
if (!pNode->mID.empty()) {
AddNodeMetaData(node, AI_METADATA_COLLADA_ID, aiString(pNode->mID));
}
if (!pNode->mSID.empty()) {
AddNodeMetaData(node, AI_METADATA_COLLADA_SID, aiString(pNode->mSID));
}
}
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// calculate the transformation matrix for it
node->mTransformation = pParser.CalculateResultTransform(pNode->mTransforms);
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// now resolve node instances
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std::vector<const Node*> instances;
ResolveNodeInstances(pParser, pNode, instances);
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// add children. first the *real* ones
node->mNumChildren = static_cast<unsigned int>(pNode->mChildren.size() + instances.size());
node->mChildren = new aiNode *[node->mNumChildren];
for (size_t a = 0; a < pNode->mChildren.size(); ++a) {
node->mChildren[a] = BuildHierarchy(pParser, pNode->mChildren[a]);
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node->mChildren[a]->mParent = node;
}
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// ... and finally the resolved node instances
for (size_t a = 0; a < instances.size(); ++a) {
node->mChildren[pNode->mChildren.size() + a] = BuildHierarchy(pParser, instances[a]);
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node->mChildren[pNode->mChildren.size() + a]->mParent = node;
}
BuildMeshesForNode(pParser, pNode, node);
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BuildCamerasForNode(pParser, pNode, node);
BuildLightsForNode(pParser, pNode, node);
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return node;
}
// ------------------------------------------------------------------------------------------------
// Resolve node instances
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void ColladaLoader::ResolveNodeInstances(const ColladaParser &pParser, const Node *pNode,
std::vector<const Node*> &resolved) {
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// reserve enough storage
resolved.reserve(pNode->mNodeInstances.size());
// ... and iterate through all nodes to be instanced as children of pNode
for (const auto &nodeInst : pNode->mNodeInstances) {
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// find the corresponding node in the library
const ColladaParser::NodeLibrary::const_iterator itt = pParser.mNodeLibrary.find(nodeInst.mNode);
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const Node *nd = itt == pParser.mNodeLibrary.end() ? nullptr : (*itt).second;
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// FIX for http://sourceforge.net/tracker/?func=detail&aid=3054873&group_id=226462&atid=1067632
// need to check for both name and ID to catch all. To avoid breaking valid files,
// the workaround is only enabled when the first attempt to resolve the node has failed.
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if (nullptr == nd) {
nd = FindNode(pParser.mRootNode, nodeInst.mNode);
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}
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if (nullptr == nd) {
ASSIMP_LOG_ERROR("Collada: Unable to resolve reference to instanced node ", nodeInst.mNode);
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} else {
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// attach this node to the list of children
resolved.push_back(nd);
}
}
}
// ------------------------------------------------------------------------------------------------
// Resolve UV channels
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void ColladaLoader::ApplyVertexToEffectSemanticMapping(Sampler &sampler, const SemanticMappingTable &table) {
SemanticMappingTable::InputSemanticMap::const_iterator it = table.mMap.find(sampler.mUVChannel);
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if (it == table.mMap.end()) {
return;
}
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if (it->second.mType != IT_Texcoord) {
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ASSIMP_LOG_ERROR("Collada: Unexpected effect input mapping");
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}
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sampler.mUVId = it->second.mSet;
}
// ------------------------------------------------------------------------------------------------
// Builds lights for the given node and references them
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void ColladaLoader::BuildLightsForNode(const ColladaParser &pParser, const Node *pNode, aiNode *pTarget) {
for (const LightInstance &lid : pNode->mLights) {
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// find the referred light
ColladaParser::LightLibrary::const_iterator srcLightIt = pParser.mLightLibrary.find(lid.mLight);
if (srcLightIt == pParser.mLightLibrary.end()) {
ASSIMP_LOG_WARN("Collada: Unable to find light for ID \"", lid.mLight, "\". Skipping.");
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continue;
}
const Collada::Light *srcLight = &srcLightIt->second;
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// now fill our ai data structure
aiLight *out = new aiLight();
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out->mName = pTarget->mName;
out->mType = (aiLightSourceType)srcLight->mType;
// collada lights point in -Z by default, rest is specified in node transform
out->mDirection = aiVector3D(0.f, 0.f, -1.f);
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out->mAttenuationConstant = srcLight->mAttConstant;
out->mAttenuationLinear = srcLight->mAttLinear;
out->mAttenuationQuadratic = srcLight->mAttQuadratic;
out->mColorDiffuse = out->mColorSpecular = out->mColorAmbient = srcLight->mColor * srcLight->mIntensity;
if (out->mType == aiLightSource_AMBIENT) {
out->mColorDiffuse = out->mColorSpecular = aiColor3D(0, 0, 0);
out->mColorAmbient = srcLight->mColor * srcLight->mIntensity;
} else {
// collada doesn't differentiate between these color types
out->mColorDiffuse = out->mColorSpecular = srcLight->mColor * srcLight->mIntensity;
out->mColorAmbient = aiColor3D(0, 0, 0);
}
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// convert falloff angle and falloff exponent in our representation, if given
if (out->mType == aiLightSource_SPOT) {
out->mAngleInnerCone = AI_DEG_TO_RAD(srcLight->mFalloffAngle);
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// ... some extension magic.
if (srcLight->mOuterAngle >= ASSIMP_COLLADA_LIGHT_ANGLE_NOT_SET * (1 - 1e-6f)) {
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// ... some deprecation magic.
if (srcLight->mPenumbraAngle >= ASSIMP_COLLADA_LIGHT_ANGLE_NOT_SET * (1 - 1e-6f)) {
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// Need to rely on falloff_exponent. I don't know how to interpret it, so I need to guess ....
// epsilon chosen to be 0.1
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float f = 1.0f;
if ( 0.0f != srcLight->mFalloffExponent ) {
f = 1.f / srcLight->mFalloffExponent;
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}
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out->mAngleOuterCone = std::acos(std::pow(0.1f, f)) +
out->mAngleInnerCone;
} else {
out->mAngleOuterCone = out->mAngleInnerCone + AI_DEG_TO_RAD(srcLight->mPenumbraAngle);
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if (out->mAngleOuterCone < out->mAngleInnerCone)
std::swap(out->mAngleInnerCone, out->mAngleOuterCone);
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}
} else {
out->mAngleOuterCone = AI_DEG_TO_RAD(srcLight->mOuterAngle);
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}
}
// add to light list
mLights.push_back(out);
}
}
// ------------------------------------------------------------------------------------------------
// Builds cameras for the given node and references them
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void ColladaLoader::BuildCamerasForNode(const ColladaParser &pParser, const Node *pNode, aiNode *pTarget) {
for (const CameraInstance &cid : pNode->mCameras) {
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// find the referred light
ColladaParser::CameraLibrary::const_iterator srcCameraIt = pParser.mCameraLibrary.find(cid.mCamera);
if (srcCameraIt == pParser.mCameraLibrary.end()) {
ASSIMP_LOG_WARN("Collada: Unable to find camera for ID \"", cid.mCamera, "\". Skipping.");
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continue;
}
const Collada::Camera *srcCamera = &srcCameraIt->second;
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// orthographic cameras not yet supported in Assimp
if (srcCamera->mOrtho) {
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ASSIMP_LOG_WARN("Collada: Orthographic cameras are not supported.");
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}
// now fill our ai data structure
aiCamera *out = new aiCamera();
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out->mName = pTarget->mName;
// collada cameras point in -Z by default, rest is specified in node transform
out->mLookAt = aiVector3D(0.f, 0.f, -1.f);
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// near/far z is already ok
out->mClipPlaneFar = srcCamera->mZFar;
out->mClipPlaneNear = srcCamera->mZNear;
// ... but for the rest some values are optional
// and we need to compute the others in any combination.
if (srcCamera->mAspect != 10e10f) {
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out->mAspect = srcCamera->mAspect;
}
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if (srcCamera->mHorFov != 10e10f) {
out->mHorizontalFOV = srcCamera->mHorFov;
if (srcCamera->mVerFov != 10e10f && srcCamera->mAspect == 10e10f) {
out->mAspect = std::tan(AI_DEG_TO_RAD(srcCamera->mHorFov)) /
std::tan(AI_DEG_TO_RAD(srcCamera->mVerFov));
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}
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} else if (srcCamera->mAspect != 10e10f && srcCamera->mVerFov != 10e10f) {
out->mHorizontalFOV = 2.0f * AI_RAD_TO_DEG(std::atan(srcCamera->mAspect *
std::tan(AI_DEG_TO_RAD(srcCamera->mVerFov) * 0.5f)));
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}
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// Collada uses degrees, we use radians
out->mHorizontalFOV = AI_DEG_TO_RAD(out->mHorizontalFOV);
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// add to camera list
mCameras.push_back(out);
}
}
// ------------------------------------------------------------------------------------------------
// Builds meshes for the given node and references them
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void ColladaLoader::BuildMeshesForNode(const ColladaParser &pParser, const Node *pNode, aiNode *pTarget) {
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// accumulated mesh references by this node
std::vector<size_t> newMeshRefs;
newMeshRefs.reserve(pNode->mMeshes.size());
// add a mesh for each subgroup in each collada mesh
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for (const MeshInstance &mid : pNode->mMeshes) {
const Mesh *srcMesh = nullptr;
const Controller *srcController = nullptr;
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// find the referred mesh
ColladaParser::MeshLibrary::const_iterator srcMeshIt = pParser.mMeshLibrary.find(mid.mMeshOrController);
if (srcMeshIt == pParser.mMeshLibrary.end()) {
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// if not found in the mesh-library, it might also be a controller referring to a mesh
ColladaParser::ControllerLibrary::const_iterator srcContrIt = pParser.mControllerLibrary.find(mid.mMeshOrController);
if (srcContrIt != pParser.mControllerLibrary.end()) {
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srcController = &srcContrIt->second;
srcMeshIt = pParser.mMeshLibrary.find(srcController->mMeshId);
if (srcMeshIt != pParser.mMeshLibrary.end()) {
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srcMesh = srcMeshIt->second;
}
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}
if (nullptr == srcMesh) {
ASSIMP_LOG_WARN("Collada: Unable to find geometry for ID \"", mid.mMeshOrController, "\". Skipping.");
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continue;
}
} else {
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// ID found in the mesh library -> direct reference to an unskinned mesh
srcMesh = srcMeshIt->second;
}
// build a mesh for each of its subgroups
size_t vertexStart = 0, faceStart = 0;
for (size_t sm = 0; sm < srcMesh->mSubMeshes.size(); ++sm) {
const Collada::SubMesh &submesh = srcMesh->mSubMeshes[sm];
if (submesh.mNumFaces == 0) {
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continue;
}
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// find material assigned to this submesh
std::string meshMaterial;
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std::map<std::string, SemanticMappingTable>::const_iterator meshMatIt = mid.mMaterials.find(submesh.mMaterial);
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const Collada::SemanticMappingTable *table = nullptr;
if (meshMatIt != mid.mMaterials.end()) {
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table = &meshMatIt->second;
meshMaterial = table->mMatName;
} else {
ASSIMP_LOG_WARN("Collada: No material specified for subgroup <", submesh.mMaterial, "> in geometry <",
mid.mMeshOrController, ">.");
if (!mid.mMaterials.empty()) {
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meshMaterial = mid.mMaterials.begin()->second.mMatName;
}
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}
// OK ... here the *real* fun starts ... we have the vertex-input-to-effect-semantic-table
// given. The only mapping stuff which we do actually support is the UV channel.
std::map<std::string, size_t>::const_iterator matIt = mMaterialIndexByName.find(meshMaterial);
unsigned int matIdx = 0;
if (matIt != mMaterialIndexByName.end()) {
matIdx = static_cast<unsigned int>(matIt->second);
}
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if (table && !table->mMap.empty()) {
std::pair<Collada::Effect *, aiMaterial *> &mat = newMats[matIdx];
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// Iterate through all texture channels assigned to the effect and
// check whether we have mapping information for it.
ApplyVertexToEffectSemanticMapping(mat.first->mTexDiffuse, *table);
ApplyVertexToEffectSemanticMapping(mat.first->mTexAmbient, *table);
ApplyVertexToEffectSemanticMapping(mat.first->mTexSpecular, *table);
ApplyVertexToEffectSemanticMapping(mat.first->mTexEmissive, *table);
ApplyVertexToEffectSemanticMapping(mat.first->mTexTransparent, *table);
ApplyVertexToEffectSemanticMapping(mat.first->mTexBump, *table);
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}
// built lookup index of the Mesh-Submesh-Material combination
ColladaMeshIndex index(mid.mMeshOrController, sm, meshMaterial);
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// if we already have the mesh at the library, just add its index to the node's array
std::map<ColladaMeshIndex, size_t>::const_iterator dstMeshIt = mMeshIndexByID.find(index);
if (dstMeshIt != mMeshIndexByID.end()) {
newMeshRefs.push_back(dstMeshIt->second);
} else {
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// else we have to add the mesh to the collection and store its newly assigned index at the node
aiMesh *dstMesh = CreateMesh(pParser, srcMesh, submesh, srcController, vertexStart, faceStart);
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// store the mesh, and store its new index in the node
newMeshRefs.push_back(mMeshes.size());
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mMeshIndexByID[index] = mMeshes.size();
mMeshes.push_back(dstMesh);
vertexStart += dstMesh->mNumVertices;
faceStart += submesh.mNumFaces;
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// assign the material index
std::map<std::string, size_t>::const_iterator subMatIt = mMaterialIndexByName.find(submesh.mMaterial);
if (subMatIt != mMaterialIndexByName.end()) {
dstMesh->mMaterialIndex = static_cast<unsigned int>(subMatIt->second);
} else {
dstMesh->mMaterialIndex = matIdx;
}
if (dstMesh->mName.length == 0) {
dstMesh->mName = mid.mMeshOrController;
}
}
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}
}
// now place all mesh references we gathered in the target node
pTarget->mNumMeshes = static_cast<unsigned int>(newMeshRefs.size());
if (newMeshRefs.size()) {
struct UIntTypeConverter {
unsigned int operator()(const size_t &v) const {
return static_cast<unsigned int>(v);
}
};
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pTarget->mMeshes = new unsigned int[pTarget->mNumMeshes];
std::transform(newMeshRefs.begin(), newMeshRefs.end(), pTarget->mMeshes, UIntTypeConverter());
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}
}
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// ------------------------------------------------------------------------------------------------
// Find mesh from either meshes or morph target meshes
aiMesh *ColladaLoader::findMesh(const std::string &meshid) {
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if (meshid.empty()) {
return nullptr;
}
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for (auto & mMeshe : mMeshes) {
if (std::string(mMeshe->mName.data) == meshid) {
return mMeshe;
}
}
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for (auto & mTargetMeshe : mTargetMeshes) {
if (std::string(mTargetMeshe->mName.data) == meshid) {
return mTargetMeshe;
}
}
return nullptr;
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}
// ------------------------------------------------------------------------------------------------
// Creates a mesh for the given ColladaMesh face subset and returns the newly created mesh
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aiMesh *ColladaLoader::CreateMesh(const ColladaParser &pParser, const Mesh *pSrcMesh, const SubMesh &pSubMesh,
const Controller *pSrcController, size_t pStartVertex, size_t pStartFace) {
std::unique_ptr<aiMesh> dstMesh(new aiMesh);
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if (useColladaName) {
dstMesh->mName = pSrcMesh->mName;
} else {
dstMesh->mName = pSrcMesh->mId;
}
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// 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));
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// copy positions
dstMesh->mNumVertices = static_cast<unsigned int>(numVertices);
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dstMesh->mVertices = new aiVector3D[numVertices];
std::copy(pSrcMesh->mPositions.begin() + pStartVertex, pSrcMesh->mPositions.begin() + pStartVertex + numVertices, dstMesh->mVertices);
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// normals, if given. HACK: (thom) Due to the glorious Collada spec we never
// know if we have the same number of normals as there are positions. So we
// also ignore any vertex attribute if it has a different count
if (pSrcMesh->mNormals.size() >= pStartVertex + numVertices) {
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dstMesh->mNormals = new aiVector3D[numVertices];
std::copy(pSrcMesh->mNormals.begin() + pStartVertex, pSrcMesh->mNormals.begin() + pStartVertex + numVertices, dstMesh->mNormals);
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}
// tangents, if given.
if (pSrcMesh->mTangents.size() >= pStartVertex + numVertices) {
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dstMesh->mTangents = new aiVector3D[numVertices];
std::copy(pSrcMesh->mTangents.begin() + pStartVertex, pSrcMesh->mTangents.begin() + pStartVertex + numVertices, dstMesh->mTangents);
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}
// bitangents, if given.
if (pSrcMesh->mBitangents.size() >= pStartVertex + numVertices) {
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dstMesh->mBitangents = new aiVector3D[numVertices];
std::copy(pSrcMesh->mBitangents.begin() + pStartVertex, pSrcMesh->mBitangents.begin() + pStartVertex + numVertices, dstMesh->mBitangents);
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}
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// same for texture coords, as many as we have
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// empty slots are not allowed, need to pack and adjust UV indexes accordingly
for (size_t a = 0, real = 0; a < AI_MAX_NUMBER_OF_TEXTURECOORDS; ++a) {
if (pSrcMesh->mTexCoords[a].size() >= pStartVertex + numVertices) {
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dstMesh->mTextureCoords[real] = new aiVector3D[numVertices];
for (size_t b = 0; b < numVertices; ++b) {
dstMesh->mTextureCoords[real][b] = pSrcMesh->mTexCoords[a][pStartVertex + b];
}
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dstMesh->mNumUVComponents[real] = pSrcMesh->mNumUVComponents[a];
++real;
}
}
// same for vertex colors, as many as we have. again the same packing to avoid empty slots
for (size_t a = 0, real = 0; a < AI_MAX_NUMBER_OF_COLOR_SETS; ++a) {
if (pSrcMesh->mColors[a].size() >= pStartVertex + numVertices) {
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dstMesh->mColors[real] = new aiColor4D[numVertices];
std::copy(pSrcMesh->mColors[a].begin() + pStartVertex, pSrcMesh->mColors[a].begin() + pStartVertex + numVertices, dstMesh->mColors[real]);
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++real;
}
}
// create faces. Due to the fact that each face uses unique vertices, we can simply count up on each vertex
size_t vertex = 0;
dstMesh->mNumFaces = static_cast<unsigned int>(pSubMesh.mNumFaces);
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dstMesh->mFaces = new aiFace[dstMesh->mNumFaces];
for (size_t a = 0; a < dstMesh->mNumFaces; ++a) {
size_t s = pSrcMesh->mFaceSize[pStartFace + a];
aiFace &face = dstMesh->mFaces[a];
face.mNumIndices = static_cast<unsigned int>(s);
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face.mIndices = new unsigned int[s];
for (size_t b = 0; b < s; ++b) {
face.mIndices[b] = static_cast<unsigned int>(vertex++);
}
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}
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// create morph target meshes if any
std::vector<aiMesh *> targetMeshes;
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std::vector<float> targetWeights;
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Collada::MorphMethod method = Normalized;
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for (std::map<std::string, Controller>::const_iterator it = pParser.mControllerLibrary.begin();
it != pParser.mControllerLibrary.end(); ++it) {
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const Controller &c = it->second;
const Collada::Mesh *baseMesh = pParser.ResolveLibraryReference(pParser.mMeshLibrary, c.mMeshId);
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if (c.mType == Collada::Morph && baseMesh->mName == pSrcMesh->mName) {
const Collada::Accessor &targetAccessor = pParser.ResolveLibraryReference(pParser.mAccessorLibrary, c.mMorphTarget);
const Collada::Accessor &weightAccessor = pParser.ResolveLibraryReference(pParser.mAccessorLibrary, c.mMorphWeight);
const Collada::Data &targetData = pParser.ResolveLibraryReference(pParser.mDataLibrary, targetAccessor.mSource);
const Collada::Data &weightData = pParser.ResolveLibraryReference(pParser.mDataLibrary, weightAccessor.mSource);
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// take method
method = c.mMethod;
if (!targetData.mIsStringArray) {
throw DeadlyImportError("target data must contain id. ");
}
if (weightData.mIsStringArray) {
throw DeadlyImportError("target weight data must not be textual ");
}
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for (const auto & mString : targetData.mStrings) {
const Mesh *targetMesh = pParser.ResolveLibraryReference(pParser.mMeshLibrary, mString);
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aiMesh *aimesh = findMesh(useColladaName ? targetMesh->mName : targetMesh->mId);
if (!aimesh) {
if (targetMesh->mSubMeshes.size() > 1) {
throw DeadlyImportError("Morphing target mesh must be a single");
}
aimesh = CreateMesh(pParser, targetMesh, targetMesh->mSubMeshes.at(0), nullptr, 0, 0);
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mTargetMeshes.push_back(aimesh);
}
targetMeshes.push_back(aimesh);
}
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for (float mValue : weightData.mValues) {
targetWeights.push_back(mValue);
}
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}
}
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if (!targetMeshes.empty() && targetWeights.size() == targetMeshes.size()) {
std::vector<aiAnimMesh *> animMeshes;
for (unsigned int i = 0; i < targetMeshes.size(); ++i) {
aiMesh *targetMesh = targetMeshes.at(i);
aiAnimMesh *animMesh = aiCreateAnimMesh(targetMesh);
float weight = targetWeights[i];
animMesh->mWeight = weight == 0 ? 1.0f : weight;
animMesh->mName = targetMesh->mName;
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animMeshes.push_back(animMesh);
}
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dstMesh->mMethod = (method == Relative) ? aiMorphingMethod_MORPH_RELATIVE : aiMorphingMethod_MORPH_NORMALIZED;
dstMesh->mAnimMeshes = new aiAnimMesh *[animMeshes.size()];
dstMesh->mNumAnimMeshes = static_cast<unsigned int>(animMeshes.size());
for (unsigned int i = 0; i < animMeshes.size(); ++i) {
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dstMesh->mAnimMeshes[i] = animMeshes.at(i);
}
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}
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// create bones if given
if (pSrcController && pSrcController->mType == Collada::Skin) {
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// resolve references - joint names
const Collada::Accessor &jointNamesAcc = pParser.ResolveLibraryReference(pParser.mAccessorLibrary, pSrcController->mJointNameSource);
const Collada::Data &jointNames = pParser.ResolveLibraryReference(pParser.mDataLibrary, jointNamesAcc.mSource);
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// joint offset matrices
const Collada::Accessor &jointMatrixAcc = pParser.ResolveLibraryReference(pParser.mAccessorLibrary, pSrcController->mJointOffsetMatrixSource);
const Collada::Data &jointMatrices = pParser.ResolveLibraryReference(pParser.mDataLibrary, jointMatrixAcc.mSource);
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// joint vertex_weight name list - should refer to the same list as the joint names above. If not, report and reconsider
const Collada::Accessor &weightNamesAcc = pParser.ResolveLibraryReference(pParser.mAccessorLibrary, pSrcController->mWeightInputJoints.mAccessor);
if (&weightNamesAcc != &jointNamesAcc)
throw DeadlyImportError("Temporary implementational laziness. If you read this, please report to the author.");
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// vertex weights
const Collada::Accessor &weightsAcc = pParser.ResolveLibraryReference(pParser.mAccessorLibrary, pSrcController->mWeightInputWeights.mAccessor);
const Collada::Data &weights = pParser.ResolveLibraryReference(pParser.mDataLibrary, weightsAcc.mSource);
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if (!jointNames.mIsStringArray || jointMatrices.mIsStringArray || weights.mIsStringArray) {
throw DeadlyImportError("Data type mismatch while resolving mesh joints");
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}
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// sanity check: we rely on the vertex weights always coming as pairs of BoneIndex-WeightIndex
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if (pSrcController->mWeightInputJoints.mOffset != 0 || pSrcController->mWeightInputWeights.mOffset != 1) {
throw DeadlyImportError("Unsupported vertex_weight addressing scheme. ");
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}
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// create containers to collect the weights for each bone
size_t numBones = jointNames.mStrings.size();
std::vector<std::vector<aiVertexWeight>> dstBones(numBones);
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// build a temporary array of pointers to the start of each vertex's weights
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using IndexPairVector = std::vector<std::pair<size_t, size_t>>;
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std::vector<IndexPairVector::const_iterator> weightStartPerVertex;
weightStartPerVertex.resize(pSrcController->mWeightCounts.size(), pSrcController->mWeights.end());
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IndexPairVector::const_iterator pit = pSrcController->mWeights.begin();
for (size_t a = 0; a < pSrcController->mWeightCounts.size(); ++a) {
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weightStartPerVertex[a] = pit;
pit += pSrcController->mWeightCounts[a];
}
// now for each vertex put the corresponding vertex weights into each bone's weight collection
for (size_t a = pStartVertex; a < pStartVertex + numVertices; ++a) {
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// which position index was responsible for this vertex? that's also the index by which
// the controller assigns the vertex weights
size_t orgIndex = pSrcMesh->mFacePosIndices[a];
// find the vertex weights for this vertex
IndexPairVector::const_iterator iit = weightStartPerVertex[orgIndex];
size_t pairCount = pSrcController->mWeightCounts[orgIndex];
for (size_t b = 0; b < pairCount; ++b, ++iit) {
const size_t jointIndex = iit->first;
const size_t vertexIndex = iit->second;
ai_real weight = 1.0f;
if (!weights.mValues.empty()) {
weight = ReadFloat(weightsAcc, weights, vertexIndex, 0);
}
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// one day I gonna kill that XSI Collada exporter
if (weight > 0.0f) {
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aiVertexWeight w;
w.mVertexId = static_cast<unsigned int>(a - pStartVertex);
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w.mWeight = weight;
dstBones[jointIndex].push_back(w);
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}
}
}
// count the number of bones which influence vertices of the current submesh
size_t numRemainingBones = 0;
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for (const auto & dstBone : dstBones) {
if (!dstBone.empty()) {
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++numRemainingBones;
}
}
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// create bone array and copy bone weights one by one
dstMesh->mNumBones = static_cast<unsigned int>(numRemainingBones);
dstMesh->mBones = new aiBone *[numRemainingBones];
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size_t boneCount = 0;
for (size_t a = 0; a < numBones; ++a) {
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// omit bones without weights
if (dstBones[a].empty()) {
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continue;
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}
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// create bone with its weights
aiBone *bone = new aiBone;
bone->mName = ReadString(jointNamesAcc, jointNames, a);
bone->mOffsetMatrix.a1 = ReadFloat(jointMatrixAcc, jointMatrices, a, 0);
bone->mOffsetMatrix.a2 = ReadFloat(jointMatrixAcc, jointMatrices, a, 1);
bone->mOffsetMatrix.a3 = ReadFloat(jointMatrixAcc, jointMatrices, a, 2);
bone->mOffsetMatrix.a4 = ReadFloat(jointMatrixAcc, jointMatrices, a, 3);
bone->mOffsetMatrix.b1 = ReadFloat(jointMatrixAcc, jointMatrices, a, 4);
bone->mOffsetMatrix.b2 = ReadFloat(jointMatrixAcc, jointMatrices, a, 5);
bone->mOffsetMatrix.b3 = ReadFloat(jointMatrixAcc, jointMatrices, a, 6);
bone->mOffsetMatrix.b4 = ReadFloat(jointMatrixAcc, jointMatrices, a, 7);
bone->mOffsetMatrix.c1 = ReadFloat(jointMatrixAcc, jointMatrices, a, 8);
bone->mOffsetMatrix.c2 = ReadFloat(jointMatrixAcc, jointMatrices, a, 9);
bone->mOffsetMatrix.c3 = ReadFloat(jointMatrixAcc, jointMatrices, a, 10);
bone->mOffsetMatrix.c4 = ReadFloat(jointMatrixAcc, jointMatrices, a, 11);
bone->mNumWeights = static_cast<unsigned int>(dstBones[a].size());
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bone->mWeights = new aiVertexWeight[bone->mNumWeights];
std::copy(dstBones[a].begin(), dstBones[a].end(), bone->mWeights);
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// apply bind shape matrix to offset matrix
aiMatrix4x4 bindShapeMatrix;
bindShapeMatrix.a1 = pSrcController->mBindShapeMatrix[0];
bindShapeMatrix.a2 = pSrcController->mBindShapeMatrix[1];
bindShapeMatrix.a3 = pSrcController->mBindShapeMatrix[2];
bindShapeMatrix.a4 = pSrcController->mBindShapeMatrix[3];
bindShapeMatrix.b1 = pSrcController->mBindShapeMatrix[4];
bindShapeMatrix.b2 = pSrcController->mBindShapeMatrix[5];
bindShapeMatrix.b3 = pSrcController->mBindShapeMatrix[6];
bindShapeMatrix.b4 = pSrcController->mBindShapeMatrix[7];
bindShapeMatrix.c1 = pSrcController->mBindShapeMatrix[8];
bindShapeMatrix.c2 = pSrcController->mBindShapeMatrix[9];
bindShapeMatrix.c3 = pSrcController->mBindShapeMatrix[10];
bindShapeMatrix.c4 = pSrcController->mBindShapeMatrix[11];
bindShapeMatrix.d1 = pSrcController->mBindShapeMatrix[12];
bindShapeMatrix.d2 = pSrcController->mBindShapeMatrix[13];
bindShapeMatrix.d3 = pSrcController->mBindShapeMatrix[14];
bindShapeMatrix.d4 = pSrcController->mBindShapeMatrix[15];
bone->mOffsetMatrix *= bindShapeMatrix;
// HACK: (thom) Some exporters address the bone nodes by SID, others address them by ID or even name.
// Therefore I added a little name replacement here: I search for the bone's node by either name, ID or SID,
// and replace the bone's name by the node's name so that the user can use the standard
// find-by-name method to associate nodes with bones.
const Collada::Node *bnode = FindNode(pParser.mRootNode, bone->mName.data);
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if (nullptr == bnode) {
bnode = FindNodeBySID(pParser.mRootNode, bone->mName.data);
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}
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// assign the name that we would have assigned for the source node
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if (nullptr != bnode) {
bone->mName.Set(FindNameForNode(bnode));
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} else {
ASSIMP_LOG_WARN("ColladaLoader::CreateMesh(): could not find corresponding node for joint \"", bone->mName.data, "\".");
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}
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// and insert bone
dstMesh->mBones[boneCount++] = bone;
}
}
return dstMesh.release();
}
// ------------------------------------------------------------------------------------------------
// Stores all meshes in the given scene
void ColladaLoader::StoreSceneMeshes(aiScene *pScene) {
pScene->mNumMeshes = static_cast<unsigned int>(mMeshes.size());
if (mMeshes.empty()) {
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return;
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}
pScene->mMeshes = new aiMesh *[mMeshes.size()];
std::copy(mMeshes.begin(), mMeshes.end(), pScene->mMeshes);
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mMeshes.clear();
}
// ------------------------------------------------------------------------------------------------
// Stores all cameras in the given scene
void ColladaLoader::StoreSceneCameras(aiScene *pScene) {
pScene->mNumCameras = static_cast<unsigned int>(mCameras.size());
if (mCameras.empty()) {
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return;
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}
pScene->mCameras = new aiCamera *[mCameras.size()];
std::copy(mCameras.begin(), mCameras.end(), pScene->mCameras);
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mCameras.clear();
}
// ------------------------------------------------------------------------------------------------
// Stores all lights in the given scene
void ColladaLoader::StoreSceneLights(aiScene *pScene) {
pScene->mNumLights = static_cast<unsigned int>(mLights.size());
if (mLights.empty()) {
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return;
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}
pScene->mLights = new aiLight *[mLights.size()];
std::copy(mLights.begin(), mLights.end(), pScene->mLights);
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mLights.clear();
}
// ------------------------------------------------------------------------------------------------
// Stores all textures in the given scene
void ColladaLoader::StoreSceneTextures(aiScene *pScene) {
pScene->mNumTextures = static_cast<unsigned int>(mTextures.size());
if (mTextures.empty()) {
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return;
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}
pScene->mTextures = new aiTexture *[mTextures.size()];
std::copy(mTextures.begin(), mTextures.end(), pScene->mTextures);
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mTextures.clear();
}
// ------------------------------------------------------------------------------------------------
// Stores all materials in the given scene
void ColladaLoader::StoreSceneMaterials(aiScene *pScene) {
pScene->mNumMaterials = static_cast<unsigned int>(newMats.size());
if (newMats.empty()) {
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return;
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}
pScene->mMaterials = new aiMaterial *[newMats.size()];
for (unsigned int i = 0; i < newMats.size(); ++i) {
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pScene->mMaterials[i] = newMats[i].second;
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}
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newMats.clear();
}
// ------------------------------------------------------------------------------------------------
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// Stores all animations
void ColladaLoader::StoreAnimations(aiScene *pScene, const ColladaParser &pParser) {
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// recursively collect all animations from the collada scene
StoreAnimations(pScene, pParser, &pParser.mAnims, "");
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// catch special case: many animations with the same length, each affecting only a single node.
// we need to unite all those single-node-anims to a proper combined animation
for (size_t a = 0; a < mAnims.size(); ++a) {
aiAnimation *templateAnim = mAnims[a];
if (templateAnim->mNumChannels == 1) {
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// search for other single-channel-anims with the same duration
std::vector<size_t> collectedAnimIndices;
for (size_t b = a + 1; b < mAnims.size(); ++b) {
aiAnimation *other = mAnims[b];
if (other->mNumChannels == 1 && other->mDuration == templateAnim->mDuration &&
other->mTicksPerSecond == templateAnim->mTicksPerSecond)
collectedAnimIndices.push_back(b);
}
// We only want to combine the animations if they have different channels
std::set<std::string> animTargets;
animTargets.insert(templateAnim->mChannels[0]->mNodeName.C_Str());
bool collectedAnimationsHaveDifferentChannels = true;
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for (unsigned long long collectedAnimIndice : collectedAnimIndices) {
aiAnimation *srcAnimation = mAnims[(int)collectedAnimIndice];
std::string channelName = std::string(srcAnimation->mChannels[0]->mNodeName.C_Str());
if (animTargets.find(channelName) == animTargets.end()) {
animTargets.insert(channelName);
} else {
collectedAnimationsHaveDifferentChannels = false;
break;
}
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}
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if (!collectedAnimationsHaveDifferentChannels) {
continue;
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}
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// if there are other animations which fit the template anim, combine all channels into a single anim
if (!collectedAnimIndices.empty()) {
aiAnimation *combinedAnim = new aiAnimation();
combinedAnim->mName = aiString(std::string("combinedAnim_") + char('0' + a));
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combinedAnim->mDuration = templateAnim->mDuration;
combinedAnim->mTicksPerSecond = templateAnim->mTicksPerSecond;
combinedAnim->mNumChannels = static_cast<unsigned int>(collectedAnimIndices.size() + 1);
combinedAnim->mChannels = new aiNodeAnim *[combinedAnim->mNumChannels];
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// add the template anim as first channel by moving its aiNodeAnim to the combined animation
combinedAnim->mChannels[0] = templateAnim->mChannels[0];
templateAnim->mChannels[0] = nullptr;
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delete templateAnim;
// combined animation replaces template animation in the anim array
mAnims[a] = combinedAnim;
// move the memory of all other anims to the combined anim and erase them from the source anims
for (size_t b = 0; b < collectedAnimIndices.size(); ++b) {
aiAnimation *srcAnimation = mAnims[collectedAnimIndices[b]];
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combinedAnim->mChannels[1 + b] = srcAnimation->mChannels[0];
srcAnimation->mChannels[0] = nullptr;
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delete srcAnimation;
}
// in a second go, delete all the single-channel-anims that we've stripped from their channels
// back to front to preserve indices - you know, removing an element from a vector moves all elements behind the removed one
while (!collectedAnimIndices.empty()) {
mAnims.erase(mAnims.begin() + collectedAnimIndices.back());
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collectedAnimIndices.pop_back();
}
}
}
}
// now store all anims in the scene
if (!mAnims.empty()) {
pScene->mNumAnimations = static_cast<unsigned int>(mAnims.size());
pScene->mAnimations = new aiAnimation *[mAnims.size()];
std::copy(mAnims.begin(), mAnims.end(), pScene->mAnimations);
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}
mAnims.clear();
}
// ------------------------------------------------------------------------------------------------
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// Constructs the animations for the given source anim
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void ColladaLoader::StoreAnimations(aiScene *pScene, const ColladaParser &pParser, const Animation *pSrcAnim, const std::string &pPrefix) {
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std::string animName = pPrefix.empty() ? pSrcAnim->mName : pPrefix + "_" + pSrcAnim->mName;
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// create nested animations, if given
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for (auto mSubAnim : pSrcAnim->mSubAnims) {
StoreAnimations(pScene, pParser, mSubAnim, animName);
}
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// create animation channels, if any
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if (!pSrcAnim->mChannels.empty()) {
CreateAnimation(pScene, pParser, pSrcAnim, animName);
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}
}
struct MorphTimeValues {
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float mTime;
struct key {
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float mWeight;
unsigned int mValue;
};
std::vector<key> mKeys;
};
void insertMorphTimeValue(std::vector<MorphTimeValues> &values, float time, float weight, unsigned int value) {
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MorphTimeValues::key k;
k.mValue = value;
k.mWeight = weight;
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if (values.empty() || time < values[0].mTime) {
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MorphTimeValues val;
val.mTime = time;
val.mKeys.push_back(k);
values.insert(values.begin(), val);
return;
}
if (time > values.back().mTime) {
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MorphTimeValues val;
val.mTime = time;
val.mKeys.push_back(k);
values.insert(values.end(), val);
return;
}
for (unsigned int i = 0; i < values.size(); i++) {
if (std::abs(time - values[i].mTime) < 1e-6f) {
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values[i].mKeys.push_back(k);
return;
} else if (time > values[i].mTime && time < values[i + 1].mTime) {
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MorphTimeValues val;
val.mTime = time;
val.mKeys.push_back(k);
values.insert(values.begin() + i, val);
return;
}
}
}
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static float getWeightAtKey(const std::vector<MorphTimeValues> &values, int key, unsigned int value) {
for (auto mKey : values[key].mKeys) {
if (mKey.mValue == value) {
return mKey.mWeight;
}
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}
// no value at key found, try to interpolate if present at other keys. if not, return zero
// TODO: interpolation
return 0.0f;
}
// ------------------------------------------------------------------------------------------------
// Constructs the animation for the given source anim
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void ColladaLoader::CreateAnimation(aiScene *pScene, const ColladaParser &pParser, const Animation *pSrcAnim, const std::string &pName) {
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// collect a list of animatable nodes
std::vector<const aiNode *> nodes;
CollectNodes(pScene->mRootNode, nodes);
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std::vector<aiNodeAnim *> anims;
std::vector<aiMeshMorphAnim *> morphAnims;
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for (auto node : nodes) {
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// find all the collada anim channels which refer to the current node
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std::vector<ChannelEntry> entries;
std::string nodeName = node->mName.data;
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// find the collada node corresponding to the aiNode
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const Node *srcNode = FindNode(pParser.mRootNode, nodeName);
if (!srcNode) {
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continue;
}
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// now check all channels if they affect the current node
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std::string targetID, subElement;
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for (std::vector<AnimationChannel>::const_iterator cit = pSrcAnim->mChannels.begin();
cit != pSrcAnim->mChannels.end(); ++cit) {
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const AnimationChannel &srcChannel = *cit;
ChannelEntry entry;
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// we expect the animation target to be of type "nodeName/transformID.subElement". Ignore all others
// find the slash that separates the node name - there should be only one
std::string::size_type slashPos = srcChannel.mTarget.find('/');
if (slashPos == std::string::npos) {
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std::string::size_type targetPos = srcChannel.mTarget.find(srcNode->mID);
if (targetPos == std::string::npos) {
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continue;
}
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// not node transform, but something else. store as unknown animation channel for now
entry.mChannel = &(*cit);
entry.mTargetId = srcChannel.mTarget.substr(targetPos + pSrcAnim->mName.length(),
srcChannel.mTarget.length() - targetPos - pSrcAnim->mName.length());
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if (entry.mTargetId.front() == '-') {
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entry.mTargetId = entry.mTargetId.substr(1);
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}
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entries.push_back(entry);
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continue;
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}
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if (srcChannel.mTarget.find('/', slashPos + 1) != std::string::npos) {
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continue;
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}
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targetID.clear();
targetID = srcChannel.mTarget.substr(0, slashPos);
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if (targetID != srcNode->mID) {
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continue;
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}
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// find the dot that separates the transformID - there should be only one or zero
std::string::size_type dotPos = srcChannel.mTarget.find('.');
if (dotPos != std::string::npos) {
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if (srcChannel.mTarget.find('.', dotPos + 1) != std::string::npos) {
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continue;
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}
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entry.mTransformId = srcChannel.mTarget.substr(slashPos + 1, dotPos - slashPos - 1);
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subElement.clear();
subElement = srcChannel.mTarget.substr(dotPos + 1);
if (subElement == "ANGLE")
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entry.mSubElement = 3; // last number in an Axis-Angle-Transform is the angle
else if (subElement == "X")
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entry.mSubElement = 0;
else if (subElement == "Y")
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entry.mSubElement = 1;
else if (subElement == "Z")
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entry.mSubElement = 2;
else
ASSIMP_LOG_WARN("Unknown anim subelement <", subElement, ">. Ignoring");
} else {
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// no sub-element following, transformId is remaining string
entry.mTransformId = srcChannel.mTarget.substr(slashPos + 1);
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}
std::string::size_type bracketPos = srcChannel.mTarget.find('(');
if (bracketPos != std::string::npos) {
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entry.mTransformId = srcChannel.mTarget.substr(slashPos + 1, bracketPos - slashPos - 1);
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subElement.clear();
subElement = srcChannel.mTarget.substr(bracketPos);
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if (subElement == "(0)(0)")
entry.mSubElement = 0;
else if (subElement == "(1)(0)")
entry.mSubElement = 1;
else if (subElement == "(2)(0)")
entry.mSubElement = 2;
else if (subElement == "(3)(0)")
entry.mSubElement = 3;
else if (subElement == "(0)(1)")
entry.mSubElement = 4;
else if (subElement == "(1)(1)")
entry.mSubElement = 5;
else if (subElement == "(2)(1)")
entry.mSubElement = 6;
else if (subElement == "(3)(1)")
entry.mSubElement = 7;
else if (subElement == "(0)(2)")
entry.mSubElement = 8;
else if (subElement == "(1)(2)")
entry.mSubElement = 9;
else if (subElement == "(2)(2)")
entry.mSubElement = 10;
else if (subElement == "(3)(2)")
entry.mSubElement = 11;
else if (subElement == "(0)(3)")
entry.mSubElement = 12;
else if (subElement == "(1)(3)")
entry.mSubElement = 13;
else if (subElement == "(2)(3)")
entry.mSubElement = 14;
else if (subElement == "(3)(3)")
entry.mSubElement = 15;
}
// determine which transform step is affected by this channel
entry.mTransformIndex = SIZE_MAX;
for (size_t a = 0; a < srcNode->mTransforms.size(); ++a)
if (srcNode->mTransforms[a].mID == entry.mTransformId)
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entry.mTransformIndex = a;
if (entry.mTransformIndex == SIZE_MAX) {
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if (entry.mTransformId.find("morph-weights") == std::string::npos) {
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continue;
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}
entry.mTargetId = entry.mTransformId;
entry.mTransformId = std::string();
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}
entry.mChannel = &(*cit);
entries.push_back(entry);
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}
// if there's no channel affecting the current node, we skip it
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if (entries.empty()) {
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continue;
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}
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// resolve the data pointers for all anim channels. Find the minimum time while we're at it
ai_real startTime = ai_real(1e20), endTime = ai_real(-1e20);
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for (ChannelEntry & e : entries) {
e.mTimeAccessor = &pParser.ResolveLibraryReference(pParser.mAccessorLibrary, e.mChannel->mSourceTimes);
e.mTimeData = &pParser.ResolveLibraryReference(pParser.mDataLibrary, e.mTimeAccessor->mSource);
e.mValueAccessor = &pParser.ResolveLibraryReference(pParser.mAccessorLibrary, e.mChannel->mSourceValues);
e.mValueData = &pParser.ResolveLibraryReference(pParser.mDataLibrary, e.mValueAccessor->mSource);
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// time count and value count must match
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if (e.mTimeAccessor->mCount != e.mValueAccessor->mCount) {
throw DeadlyImportError("Time count / value count mismatch in animation channel \"", e.mChannel->mTarget, "\".");
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}
if (e.mTimeAccessor->mCount > 0) {
// find bounding times
startTime = std::min(startTime, ReadFloat(*e.mTimeAccessor, *e.mTimeData, 0, 0));
endTime = std::max(endTime, ReadFloat(*e.mTimeAccessor, *e.mTimeData, e.mTimeAccessor->mCount - 1, 0));
}
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}
std::vector<aiMatrix4x4> resultTrafos;
if (!entries.empty() && entries.front().mTimeAccessor->mCount > 0) {
// create a local transformation chain of the node's transforms
std::vector<Collada::Transform> transforms = srcNode->mTransforms;
// now for every unique point in time, find or interpolate the key values for that time
// and apply them to the transform chain. Then the node's present transformation can be calculated.
ai_real time = startTime;
while (1) {
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for (ChannelEntry & e : entries) {
// find the keyframe behind the current point in time
size_t pos = 0;
ai_real postTime = 0.0;
while (1) {
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if (pos >= e.mTimeAccessor->mCount) {
break;
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}
postTime = ReadFloat(*e.mTimeAccessor, *e.mTimeData, pos, 0);
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if (postTime >= time) {
break;
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}
++pos;
}
pos = std::min(pos, e.mTimeAccessor->mCount - 1);
// read values from there
ai_real temp[16];
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for (size_t c = 0; c < e.mValueAccessor->mSize; ++c) {
temp[c] = ReadFloat(*e.mValueAccessor, *e.mValueData, pos, c);
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}
// if not exactly at the key time, interpolate with previous value set
if (postTime > time && pos > 0) {
ai_real preTime = ReadFloat(*e.mTimeAccessor, *e.mTimeData, pos - 1, 0);
ai_real factor = (time - postTime) / (preTime - postTime);
for (size_t c = 0; c < e.mValueAccessor->mSize; ++c) {
ai_real v = ReadFloat(*e.mValueAccessor, *e.mValueData, pos - 1, c);
temp[c] += (v - temp[c]) * factor;
}
}
// Apply values to current transformation
std::copy(temp, temp + e.mValueAccessor->mSize, transforms[e.mTransformIndex].f + e.mSubElement);
}
// Calculate resulting transformation
aiMatrix4x4 mat = pParser.CalculateResultTransform(transforms);
// out of laziness: we store the time in matrix.d4
mat.d4 = time;
resultTrafos.push_back(mat);
// find next point in time to evaluate. That's the closest frame larger than the current in any channel
ai_real nextTime = ai_real(1e20);
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for (ChannelEntry & channelElement : entries) {
// find the next time value larger than the current
size_t pos = 0;
while (pos < channelElement.mTimeAccessor->mCount) {
const ai_real t = ReadFloat(*channelElement.mTimeAccessor, *channelElement.mTimeData, pos, 0);
if (t > time) {
nextTime = std::min(nextTime, t);
break;
}
++pos;
}
// https://github.com/assimp/assimp/issues/458
// Sub-sample axis-angle channels if the delta between two consecutive
// key-frame angles is >= 180 degrees.
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if (transforms[channelElement.mTransformIndex].mType == TF_ROTATE && channelElement.mSubElement == 3 && pos > 0 && pos < channelElement.mTimeAccessor->mCount) {
const ai_real cur_key_angle = ReadFloat(*channelElement.mValueAccessor, *channelElement.mValueData, pos, 0);
const ai_real last_key_angle = ReadFloat(*channelElement.mValueAccessor, *channelElement.mValueData, pos - 1, 0);
const ai_real cur_key_time = ReadFloat(*channelElement.mTimeAccessor, *channelElement.mTimeData, pos, 0);
const ai_real last_key_time = ReadFloat(*channelElement.mTimeAccessor, *channelElement.mTimeData, pos - 1, 0);
const ai_real last_eval_angle = last_key_angle + (cur_key_angle - last_key_angle) * (time - last_key_time) / (cur_key_time - last_key_time);
const ai_real delta = std::abs(cur_key_angle - last_eval_angle);
if (delta >= 180.0) {
const int subSampleCount = static_cast<int>(std::floor(delta / 90.0));
if (cur_key_time != time) {
const ai_real nextSampleTime = time + (cur_key_time - time) / subSampleCount;
nextTime = std::min(nextTime, nextSampleTime);
}
}
}
}
// no more keys on any channel after the current time -> we're done
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if (nextTime > 1e19) {
break;
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}
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// else construct next key-frame at this following time point
time = nextTime;
}
}
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// build an animation channel for the given node out of these trafo keys
if (!resultTrafos.empty()) {
aiNodeAnim *dstAnim = new aiNodeAnim;
dstAnim->mNodeName = nodeName;
dstAnim->mNumPositionKeys = static_cast<unsigned int>(resultTrafos.size());
dstAnim->mNumRotationKeys = static_cast<unsigned int>(resultTrafos.size());
dstAnim->mNumScalingKeys = static_cast<unsigned int>(resultTrafos.size());
dstAnim->mPositionKeys = new aiVectorKey[resultTrafos.size()];
dstAnim->mRotationKeys = new aiQuatKey[resultTrafos.size()];
dstAnim->mScalingKeys = new aiVectorKey[resultTrafos.size()];
for (size_t a = 0; a < resultTrafos.size(); ++a) {
aiMatrix4x4 mat = resultTrafos[a];
double time = double(mat.d4); // remember? time is stored in mat.d4
mat.d4 = 1.0f;
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dstAnim->mPositionKeys[a].mTime = time * kMillisecondsFromSeconds;
dstAnim->mRotationKeys[a].mTime = time * kMillisecondsFromSeconds;
dstAnim->mScalingKeys[a].mTime = time * kMillisecondsFromSeconds;
mat.Decompose(dstAnim->mScalingKeys[a].mValue, dstAnim->mRotationKeys[a].mValue, dstAnim->mPositionKeys[a].mValue);
}
anims.push_back(dstAnim);
} else {
ASSIMP_LOG_WARN("Collada loader: found empty animation channel, ignored. Please check your exporter.");
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}
if (!entries.empty() && entries.front().mTimeAccessor->mCount > 0) {
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std::vector<ChannelEntry> morphChannels;
for (ChannelEntry & e : entries) {
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// skip non-transform types
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if (e.mTargetId.empty()) {
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continue;
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}
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if (e.mTargetId.find("morph-weights") != std::string::npos) {
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morphChannels.push_back(e);
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}
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}
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if (!morphChannels.empty()) {
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// either 1) morph weight animation count should contain morph target count channels
// or 2) one channel with morph target count arrays
// assume first
aiMeshMorphAnim *morphAnim = new aiMeshMorphAnim;
morphAnim->mName.Set(nodeName);
std::vector<MorphTimeValues> morphTimeValues;
int morphAnimChannelIndex = 0;
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for (ChannelEntry & e : morphChannels) {
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std::string::size_type apos = e.mTargetId.find('(');
std::string::size_type bpos = e.mTargetId.find(')');
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// If unknown way to specify weight -> ignore this animation
if (apos == std::string::npos || bpos == std::string::npos) {
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continue;
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}
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// weight target can be in format Weight_M_N, Weight_N, WeightN, or some other way
// we ignore the name and just assume the channels are in the right order
for (unsigned int i = 0; i < e.mTimeData->mValues.size(); i++) {
insertMorphTimeValue(morphTimeValues, e.mTimeData->mValues[i], e.mValueData->mValues[i], morphAnimChannelIndex);
}
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++morphAnimChannelIndex;
}
morphAnim->mNumKeys = static_cast<unsigned int>(morphTimeValues.size());
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morphAnim->mKeys = new aiMeshMorphKey[morphAnim->mNumKeys];
for (unsigned int key = 0; key < morphAnim->mNumKeys; key++) {
morphAnim->mKeys[key].mNumValuesAndWeights = static_cast<unsigned int>(morphChannels.size());
morphAnim->mKeys[key].mValues = new unsigned int[morphChannels.size()];
morphAnim->mKeys[key].mWeights = new double[morphChannels.size()];
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morphAnim->mKeys[key].mTime = morphTimeValues[key].mTime * kMillisecondsFromSeconds;
for (unsigned int valueIndex = 0; valueIndex < morphChannels.size(); ++valueIndex) {
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morphAnim->mKeys[key].mValues[valueIndex] = valueIndex;
morphAnim->mKeys[key].mWeights[valueIndex] = getWeightAtKey(morphTimeValues, key, valueIndex);
}
}
morphAnims.push_back(morphAnim);
}
}
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}
if (!anims.empty() || !morphAnims.empty()) {
aiAnimation *anim = new aiAnimation;
anim->mName.Set(pName);
anim->mNumChannels = static_cast<unsigned int>(anims.size());
if (anim->mNumChannels > 0) {
anim->mChannels = new aiNodeAnim *[anims.size()];
std::copy(anims.begin(), anims.end(), anim->mChannels);
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}
anim->mNumMorphMeshChannels = static_cast<unsigned int>(morphAnims.size());
if (anim->mNumMorphMeshChannels > 0) {
anim->mMorphMeshChannels = new aiMeshMorphAnim *[anim->mNumMorphMeshChannels];
std::copy(morphAnims.begin(), morphAnims.end(), anim->mMorphMeshChannels);
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}
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anim->mDuration = 0.0f;
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for (auto & a : anims) {
anim->mDuration = std::max(anim->mDuration, a->mPositionKeys[a->mNumPositionKeys - 1].mTime);
anim->mDuration = std::max(anim->mDuration, a->mRotationKeys[a->mNumRotationKeys - 1].mTime);
anim->mDuration = std::max(anim->mDuration, a->mScalingKeys[a->mNumScalingKeys - 1].mTime);
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}
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for (auto & morphAnim : morphAnims) {
anim->mDuration = std::max(anim->mDuration, morphAnim->mKeys[morphAnim->mNumKeys - 1].mTime);
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}
anim->mTicksPerSecond = 1000.0;
mAnims.push_back(anim);
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}
}
// ------------------------------------------------------------------------------------------------
// Add a texture to a material structure
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void ColladaLoader::AddTexture(aiMaterial &mat,
const ColladaParser &pParser,
const Effect &effect,
const Sampler &sampler,
aiTextureType type,
unsigned int idx) {
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// first of all, basic file name
const aiString name = FindFilenameForEffectTexture(pParser, effect, sampler.mName);
mat.AddProperty(&name, _AI_MATKEY_TEXTURE_BASE, type, idx);
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// mapping mode
int map = aiTextureMapMode_Clamp;
if (sampler.mWrapU) {
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map = aiTextureMapMode_Wrap;
}
if (sampler.mWrapU && sampler.mMirrorU) {
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map = aiTextureMapMode_Mirror;
}
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mat.AddProperty(&map, 1, _AI_MATKEY_MAPPINGMODE_U_BASE, type, idx);
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map = aiTextureMapMode_Clamp;
if (sampler.mWrapV) {
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map = aiTextureMapMode_Wrap;
}
if (sampler.mWrapV && sampler.mMirrorV) {
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map = aiTextureMapMode_Mirror;
}
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mat.AddProperty(&map, 1, _AI_MATKEY_MAPPINGMODE_V_BASE, type, idx);
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// UV transformation
mat.AddProperty(&sampler.mTransform, 1,
_AI_MATKEY_UVTRANSFORM_BASE, type, idx);
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// Blend mode
mat.AddProperty((int *)&sampler.mOp, 1,
_AI_MATKEY_TEXBLEND_BASE, type, idx);
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// Blend factor
mat.AddProperty((ai_real *)&sampler.mWeighting, 1,
_AI_MATKEY_TEXBLEND_BASE, type, idx);
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// UV source index ... if we didn't resolve the mapping, it is actually just
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// a guess but it works in most cases. We search for the frst occurrence of a
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// number in the channel name. We assume it is the zero-based index into the
// UV channel array of all corresponding meshes. It could also be one-based
// for some exporters, but we won't care of it unless someone complains about.
if (sampler.mUVId != UINT_MAX) {
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map = sampler.mUVId;
} else {
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map = -1;
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for (std::string::const_iterator it = sampler.mUVChannel.begin(); it != sampler.mUVChannel.end(); ++it) {
if (IsNumeric(*it)) {
map = strtoul10(&(*it));
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break;
}
}
if (-1 == map) {
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ASSIMP_LOG_WARN("Collada: unable to determine UV channel for texture");
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map = 0;
}
}
mat.AddProperty(&map, 1, _AI_MATKEY_UVWSRC_BASE, type, idx);
}
// ------------------------------------------------------------------------------------------------
// Fills materials from the collada material definitions
void ColladaLoader::FillMaterials(const ColladaParser &pParser, aiScene * /*pScene*/) {
for (auto &elem : newMats) {
aiMaterial &mat = (aiMaterial &)*elem.second;
Collada::Effect &effect = *elem.first;
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// resolve shading mode
int shadeMode;
if (effect.mFaceted) {
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shadeMode = aiShadingMode_Flat;
} else {
switch (effect.mShadeType) {
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case Collada::Shade_Constant:
shadeMode = aiShadingMode_NoShading;
break;
case Collada::Shade_Lambert:
shadeMode = aiShadingMode_Gouraud;
break;
case Collada::Shade_Blinn:
shadeMode = aiShadingMode_Blinn;
break;
case Collada::Shade_Phong:
shadeMode = aiShadingMode_Phong;
break;
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default:
ASSIMP_LOG_WARN("Collada: Unrecognized shading mode, using gouraud shading");
shadeMode = aiShadingMode_Gouraud;
break;
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}
}
mat.AddProperty<int>(&shadeMode, 1, AI_MATKEY_SHADING_MODEL);
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// double-sided?
shadeMode = effect.mDoubleSided;
mat.AddProperty<int>(&shadeMode, 1, AI_MATKEY_TWOSIDED);
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// wire-frame?
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shadeMode = effect.mWireframe;
mat.AddProperty<int>(&shadeMode, 1, AI_MATKEY_ENABLE_WIREFRAME);
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// add material colors
mat.AddProperty(&effect.mAmbient, 1, AI_MATKEY_COLOR_AMBIENT);
mat.AddProperty(&effect.mDiffuse, 1, AI_MATKEY_COLOR_DIFFUSE);
mat.AddProperty(&effect.mSpecular, 1, AI_MATKEY_COLOR_SPECULAR);
mat.AddProperty(&effect.mEmissive, 1, AI_MATKEY_COLOR_EMISSIVE);
mat.AddProperty(&effect.mReflective, 1, AI_MATKEY_COLOR_REFLECTIVE);
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// scalar properties
mat.AddProperty(&effect.mShininess, 1, AI_MATKEY_SHININESS);
mat.AddProperty(&effect.mReflectivity, 1, AI_MATKEY_REFLECTIVITY);
mat.AddProperty(&effect.mRefractIndex, 1, AI_MATKEY_REFRACTI);
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// transparency, a very hard one. seemingly not all files are following the
// specification here (1.0 transparency => completely opaque)...
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// therefore, we let the opportunity for the user to manually invert
// the transparency if necessary and we add preliminary support for RGB_ZERO mode
if (effect.mTransparency >= 0.f && effect.mTransparency <= 1.f) {
// handle RGB transparency completely, cf Collada specs 1.5.0 pages 249 and 304
if (effect.mRGBTransparency) {
// use luminance as defined by ISO/CIE color standards (see ITU-R Recommendation BT.709-4)
effect.mTransparency *= (0.212671f * effect.mTransparent.r +
0.715160f * effect.mTransparent.g +
0.072169f * effect.mTransparent.b);
effect.mTransparent.a = 1.f;
mat.AddProperty(&effect.mTransparent, 1, AI_MATKEY_COLOR_TRANSPARENT);
} else {
effect.mTransparency *= effect.mTransparent.a;
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}
if (effect.mInvertTransparency) {
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effect.mTransparency = 1.f - effect.mTransparency;
}
// Is the material finally transparent ?
if (effect.mHasTransparency || effect.mTransparency < 1.f) {
mat.AddProperty(&effect.mTransparency, 1, AI_MATKEY_OPACITY);
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}
}
// add textures, if given
if (!effect.mTexAmbient.mName.empty()) {
// It is merely a light-map
AddTexture(mat, pParser, effect, effect.mTexAmbient, aiTextureType_LIGHTMAP);
}
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if (!effect.mTexEmissive.mName.empty())
AddTexture(mat, pParser, effect, effect.mTexEmissive, aiTextureType_EMISSIVE);
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if (!effect.mTexSpecular.mName.empty())
AddTexture(mat, pParser, effect, effect.mTexSpecular, aiTextureType_SPECULAR);
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if (!effect.mTexDiffuse.mName.empty())
AddTexture(mat, pParser, effect, effect.mTexDiffuse, aiTextureType_DIFFUSE);
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if (!effect.mTexBump.mName.empty())
AddTexture(mat, pParser, effect, effect.mTexBump, aiTextureType_NORMALS);
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if (!effect.mTexTransparent.mName.empty())
AddTexture(mat, pParser, effect, effect.mTexTransparent, aiTextureType_OPACITY);
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if (!effect.mTexReflective.mName.empty())
AddTexture(mat, pParser, effect, effect.mTexReflective, aiTextureType_REFLECTION);
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}
}
// ------------------------------------------------------------------------------------------------
// Constructs materials from the collada material definitions
void ColladaLoader::BuildMaterials(ColladaParser &pParser, aiScene * /*pScene*/) {
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newMats.reserve(pParser.mMaterialLibrary.size());
for (ColladaParser::MaterialLibrary::const_iterator matIt = pParser.mMaterialLibrary.begin();
matIt != pParser.mMaterialLibrary.end(); ++matIt) {
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const Material &material = matIt->second;
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// a material is only a reference to an effect
ColladaParser::EffectLibrary::iterator effIt = pParser.mEffectLibrary.find(material.mEffect);
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if (effIt == pParser.mEffectLibrary.end())
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continue;
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Effect &effect = effIt->second;
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// create material
aiMaterial *mat = new aiMaterial;
aiString name(material.mName.empty() ? matIt->first : material.mName);
mat->AddProperty(&name, AI_MATKEY_NAME);
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// store the material
mMaterialIndexByName[matIt->first] = newMats.size();
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newMats.push_back(std::pair<Effect *, aiMaterial *>(&effect, mat));
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}
// ScenePreprocessor generates a default material automatically if none is there.
// All further code here in this loader works well without a valid material so
// we can safely let it to ScenePreprocessor.
}
// ------------------------------------------------------------------------------------------------
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// Resolves the texture name for the given effect texture entry and loads the texture data
aiString ColladaLoader::FindFilenameForEffectTexture(const ColladaParser &pParser,
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const Effect &pEffect, const std::string &pName) {
aiString result;
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// recurse through the param references until we end up at an image
std::string name = pName;
while (1) {
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// the given string is a param entry. Find it
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Effect::ParamLibrary::const_iterator it = pEffect.mParams.find(name);
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// if not found, we're at the end of the recursion. The resulting string should be the image ID
if (it == pEffect.mParams.end())
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break;
// else recurse on
name = it->second.mReference;
}
// find the image referred by this name in the image library of the scene
ColladaParser::ImageLibrary::const_iterator imIt = pParser.mImageLibrary.find(name);
if (imIt == pParser.mImageLibrary.end()) {
ASSIMP_LOG_WARN("Collada: Unable to resolve effect texture entry \"", pName, "\", ended up at ID \"", name, "\".");
//set default texture file name
result.Set(name + ".jpg");
ColladaParser::UriDecodePath(result);
return result;
}
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// if this is an embedded texture image setup an aiTexture for it
if (!imIt->second.mImageData.empty()) {
aiTexture *tex = new aiTexture();
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// Store embedded texture name reference
tex->mFilename.Set(imIt->second.mFileName.c_str());
result.Set(imIt->second.mFileName);
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// setup format hint
if (imIt->second.mEmbeddedFormat.length() >= HINTMAXTEXTURELEN) {
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ASSIMP_LOG_WARN("Collada: texture format hint is too long, truncating to 3 characters");
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}
strncpy(tex->achFormatHint, imIt->second.mEmbeddedFormat.c_str(), 3);
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// and copy texture data
tex->mHeight = 0;
tex->mWidth = static_cast<unsigned int>(imIt->second.mImageData.size());
tex->pcData = (aiTexel *)new char[tex->mWidth];
memcpy(tex->pcData, &imIt->second.mImageData[0], tex->mWidth);
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// and add this texture to the list
mTextures.push_back(tex);
return result;
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}
if (imIt->second.mFileName.empty()) {
throw DeadlyImportError("Collada: Invalid texture, no data or file reference given");
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}
result.Set(imIt->second.mFileName);
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return result;
}
// ------------------------------------------------------------------------------------------------
// Reads a float value from an accessor and its data array.
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ai_real ColladaLoader::ReadFloat(const Accessor &pAccessor, const Data &pData, size_t pIndex, size_t pOffset) const {
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size_t pos = pAccessor.mStride * pIndex + pAccessor.mOffset + pOffset;
ai_assert(pos < pData.mValues.size());
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return pData.mValues[pos];
}
// ------------------------------------------------------------------------------------------------
// Reads a string value from an accessor and its data array.
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const std::string &ColladaLoader::ReadString(const Accessor &pAccessor, const Data &pData, size_t pIndex) const {
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size_t pos = pAccessor.mStride * pIndex + pAccessor.mOffset;
ai_assert(pos < pData.mStrings.size());
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return pData.mStrings[pos];
}
// ------------------------------------------------------------------------------------------------
// Collects all nodes into the given array
void ColladaLoader::CollectNodes(const aiNode *pNode, std::vector<const aiNode *> &poNodes) const {
poNodes.push_back(pNode);
for (size_t a = 0; a < pNode->mNumChildren; ++a) {
CollectNodes(pNode->mChildren[a], poNodes);
}
}
// ------------------------------------------------------------------------------------------------
// Finds a node in the collada scene by the given name
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const Node *ColladaLoader::FindNode(const Node *pNode, const std::string &pName) const {
if (pNode->mName == pName || pNode->mID == pName)
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return pNode;
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for (auto a : pNode->mChildren) {
const Collada::Node *node = FindNode(a, pName);
if (node) {
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return node;
}
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}
return nullptr;
}
// ------------------------------------------------------------------------------------------------
// Finds a node in the collada scene by the given SID
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const Node *ColladaLoader::FindNodeBySID(const Node *pNode, const std::string &pSID) const {
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if (nullptr == pNode) {
return nullptr;
}
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if (pNode->mSID == pSID) {
return pNode;
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}
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for (auto a : pNode->mChildren) {
const Collada::Node *node = FindNodeBySID(a, pSID);
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if (node) {
return node;
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}
}
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return nullptr;
}
// ------------------------------------------------------------------------------------------------
// Finds a proper unique name for a node derived from the collada-node's properties.
// The name must be unique for proper node-bone association.
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std::string ColladaLoader::FindNameForNode(const Node *pNode) {
// If explicitly requested, just use the collada name.
if (useColladaName) {
if (!pNode->mName.empty()) {
return pNode->mName;
} else {
return format() << "$ColladaAutoName$_" << mNodeNameCounter++;
}
} else {
// Now setup the name of the assimp node. The collada name might not be
// unique, so we use the collada ID.
if (!pNode->mID.empty())
return pNode->mID;
else if (!pNode->mSID.empty())
return pNode->mSID;
else {
// No need to worry. Unnamed nodes are no problem at all, except
// if cameras or lights need to be assigned to them.
return format() << "$ColladaAutoName$_" << mNodeNameCounter++;
}
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}
}
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} // Namespace Assimp
#endif // !! ASSIMP_BUILD_NO_DAE_IMPORTER