/* --------------------------------------------------------------------------- Open Asset Import Library (assimp) --------------------------------------------------------------------------- Copyright (c) 2006-2021, assimp team All rights reserved. Redistribution and use of this software in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the assimp team, nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission of the assimp team. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. --------------------------------------------------------------------------- */ /** @file XFileImporter.cpp * @brief Implementation of the XFile importer class */ #ifndef ASSIMP_BUILD_NO_X_IMPORTER #include "AssetLib/X/XFileImporter.h" #include "AssetLib/X/XFileParser.h" #include "PostProcessing/ConvertToLHProcess.h" #include #include #include #include #include #include #include #include using namespace Assimp; using namespace Assimp::Formatter; static const aiImporterDesc desc = { "Direct3D XFile Importer", "", "", "", aiImporterFlags_SupportTextFlavour | aiImporterFlags_SupportBinaryFlavour | aiImporterFlags_SupportCompressedFlavour, 1, 3, 1, 5, "x" }; // ------------------------------------------------------------------------------------------------ // Constructor to be privately used by Importer XFileImporter::XFileImporter() : mBuffer() { // empty } // ------------------------------------------------------------------------------------------------ // Destructor, private as well XFileImporter::~XFileImporter() { // empty } // ------------------------------------------------------------------------------------------------ // Returns whether the class can handle the format of the given file. bool XFileImporter::CanRead( const std::string& pFile, IOSystem* pIOHandler, bool checkSig) const { std::string extension = GetExtension(pFile); if(extension == "x") { return true; } if (!extension.length() || checkSig) { uint32_t token[1]; token[0] = AI_MAKE_MAGIC("xof "); return CheckMagicToken(pIOHandler,pFile,token,1,0); } return false; } // ------------------------------------------------------------------------------------------------ // Get file extension list const aiImporterDesc* XFileImporter::GetInfo () const { return &desc; } // ------------------------------------------------------------------------------------------------ // Imports the given file into the given scene structure. void XFileImporter::InternReadFile( const std::string& pFile, aiScene* pScene, IOSystem* pIOHandler) { // read file into memory std::unique_ptr file( pIOHandler->Open( pFile)); if ( file.get() == nullptr ) { throw DeadlyImportError( "Failed to open file ", pFile, "." ); } static const size_t MinSize = 16; size_t fileSize = file->FileSize(); if ( fileSize < MinSize ) { throw DeadlyImportError( "XFile is too small." ); } // in the hope that binary files will never start with a BOM ... mBuffer.resize( fileSize + 1); file->Read( &mBuffer.front(), 1, fileSize); ConvertToUTF8(mBuffer); // parse the file into a temporary representation XFileParser parser( mBuffer); // and create the proper return structures out of it CreateDataRepresentationFromImport( pScene, parser.GetImportedData()); // if nothing came from it, report it as error if ( !pScene->mRootNode ) { throw DeadlyImportError( "XFile is ill-formatted - no content imported." ); } } // ------------------------------------------------------------------------------------------------ // Constructs the return data structure out of the imported data. void XFileImporter::CreateDataRepresentationFromImport( aiScene* pScene, XFile::Scene* pData) { // Read the global materials first so that meshes referring to them can find them later ConvertMaterials( pScene, pData->mGlobalMaterials); // copy nodes, extracting meshes and materials on the way pScene->mRootNode = CreateNodes( pScene, nullptr, pData->mRootNode); // extract animations CreateAnimations( pScene, pData); // read the global meshes that were stored outside of any node if( !pData->mGlobalMeshes.empty() ) { // create a root node to hold them if there isn't any, yet if( pScene->mRootNode == nullptr ) { pScene->mRootNode = new aiNode; pScene->mRootNode->mName.Set( "$dummy_node"); } // convert all global meshes and store them in the root node. // If there was one before, the global meshes now suddenly have its transformation matrix... // Don't know what to do there, I don't want to insert another node under the present root node // just to avoid this. CreateMeshes( pScene, pScene->mRootNode, pData->mGlobalMeshes); } if (!pScene->mRootNode) { throw DeadlyImportError( "No root node" ); } // Convert everything to OpenGL space... it's the same operation as the conversion back, so we can reuse the step directly MakeLeftHandedProcess convertProcess; convertProcess.Execute( pScene); FlipWindingOrderProcess flipper; flipper.Execute(pScene); // finally: create a dummy material if not material was imported if( pScene->mNumMaterials == 0) { pScene->mNumMaterials = 1; // create the Material aiMaterial* mat = new aiMaterial; int shadeMode = (int) aiShadingMode_Gouraud; mat->AddProperty( &shadeMode, 1, AI_MATKEY_SHADING_MODEL); // material colours int specExp = 1; aiColor3D clr = aiColor3D( 0, 0, 0); mat->AddProperty( &clr, 1, AI_MATKEY_COLOR_EMISSIVE); mat->AddProperty( &clr, 1, AI_MATKEY_COLOR_SPECULAR); clr = aiColor3D( 0.5f, 0.5f, 0.5f); mat->AddProperty( &clr, 1, AI_MATKEY_COLOR_DIFFUSE); mat->AddProperty( &specExp, 1, AI_MATKEY_SHININESS); pScene->mMaterials = new aiMaterial*[1]; pScene->mMaterials[0] = mat; } } // ------------------------------------------------------------------------------------------------ // Recursively creates scene nodes from the imported hierarchy. aiNode* XFileImporter::CreateNodes( aiScene* pScene, aiNode* pParent, const XFile::Node* pNode) { if ( !pNode ) { return nullptr; } // create node aiNode* node = new aiNode; node->mName.length = (ai_uint32)pNode->mName.length(); node->mParent = pParent; memcpy( node->mName.data, pNode->mName.c_str(), pNode->mName.length()); node->mName.data[node->mName.length] = 0; node->mTransformation = pNode->mTrafoMatrix; // convert meshes from the source node CreateMeshes( pScene, node, pNode->mMeshes); // handle childs if( !pNode->mChildren.empty() ) { node->mNumChildren = (unsigned int)pNode->mChildren.size(); node->mChildren = new aiNode* [node->mNumChildren]; for ( unsigned int a = 0; a < pNode->mChildren.size(); ++a ) { node->mChildren[ a ] = CreateNodes( pScene, node, pNode->mChildren[ a ] ); } } return node; } // ------------------------------------------------------------------------------------------------ // Creates the meshes for the given node. void XFileImporter::CreateMeshes( aiScene* pScene, aiNode* pNode, const std::vector& pMeshes) { if (pMeshes.empty()) { return; } // create a mesh for each mesh-material combination in the source node std::vector meshes; for( unsigned int a = 0; a < pMeshes.size(); ++a ) { XFile::Mesh* sourceMesh = pMeshes[a]; if ( nullptr == sourceMesh ) { continue; } // first convert its materials so that we can find them with their index afterwards ConvertMaterials( pScene, sourceMesh->mMaterials); unsigned int numMaterials = std::max( (unsigned int)sourceMesh->mMaterials.size(), 1u); for( unsigned int b = 0; b < numMaterials; ++b ) { // collect the faces belonging to this material std::vector faces; unsigned int numVertices = 0; if( !sourceMesh->mFaceMaterials.empty() ) { // if there is a per-face material defined, select the faces with the corresponding material for( unsigned int c = 0; c < sourceMesh->mFaceMaterials.size(); ++c ) { if( sourceMesh->mFaceMaterials[c] == b) { faces.push_back( c); numVertices += (unsigned int)sourceMesh->mPosFaces[c].mIndices.size(); } } } else { // if there is no per-face material, place everything into one mesh for( unsigned int c = 0; c < sourceMesh->mPosFaces.size(); ++c ) { faces.push_back( c); numVertices += (unsigned int)sourceMesh->mPosFaces[c].mIndices.size(); } } // no faces/vertices using this material? strange... if ( numVertices == 0 ) { continue; } // create a submesh using this material aiMesh* mesh = new aiMesh; meshes.push_back( mesh); // find the material in the scene's material list. Either own material // or referenced material, it should already have a valid index if( !sourceMesh->mFaceMaterials.empty() ) { mesh->mMaterialIndex = static_cast(sourceMesh->mMaterials[b].sceneIndex); } else { mesh->mMaterialIndex = 0; } // Create properly sized data arrays in the mesh. We store unique vertices per face, // as specified mesh->mNumVertices = numVertices; mesh->mVertices = new aiVector3D[numVertices]; mesh->mNumFaces = (unsigned int)faces.size(); mesh->mFaces = new aiFace[mesh->mNumFaces]; // name mesh->mName.Set(sourceMesh->mName); // normals? if ( sourceMesh->mNormals.size() > 0 ) { mesh->mNormals = new aiVector3D[ numVertices ]; } // texture coords for( unsigned int c = 0; c < AI_MAX_NUMBER_OF_TEXTURECOORDS; ++c ) { if ( !sourceMesh->mTexCoords[ c ].empty() ) { mesh->mTextureCoords[ c ] = new aiVector3D[ numVertices ]; } } // vertex colors for( unsigned int c = 0; c < AI_MAX_NUMBER_OF_COLOR_SETS; ++c ) { if ( !sourceMesh->mColors[ c ].empty() ) { mesh->mColors[ c ] = new aiColor4D[ numVertices ]; } } // now collect the vertex data of all data streams present in the imported mesh unsigned int newIndex( 0 ); std::vector orgPoints; // from which original point each new vertex stems orgPoints.resize( numVertices, 0); for( unsigned int c = 0; c < faces.size(); ++c ) { unsigned int f = faces[c]; // index of the source face const XFile::Face& pf = sourceMesh->mPosFaces[f]; // position source face // create face. either triangle or triangle fan depending on the index count aiFace& df = mesh->mFaces[c]; // destination face df.mNumIndices = (unsigned int)pf.mIndices.size(); df.mIndices = new unsigned int[ df.mNumIndices]; // collect vertex data for indices of this face for( unsigned int d = 0; d < df.mNumIndices; ++d ) { df.mIndices[ d ] = newIndex; const unsigned int newIdx( pf.mIndices[ d ] ); if ( newIdx > sourceMesh->mPositions.size() ) { continue; } orgPoints[newIndex] = pf.mIndices[d]; // Position mesh->mVertices[newIndex] = sourceMesh->mPositions[pf.mIndices[d]]; // Normal, if present if ( mesh->HasNormals() ) { if ( sourceMesh->mNormFaces[ f ].mIndices.size() > d ) { const size_t idx( sourceMesh->mNormFaces[ f ].mIndices[ d ] ); mesh->mNormals[ newIndex ] = sourceMesh->mNormals[ idx ]; } } // texture coord sets for( unsigned int e = 0; e < AI_MAX_NUMBER_OF_TEXTURECOORDS; ++e ) { if( mesh->HasTextureCoords( e)) { aiVector2D tex = sourceMesh->mTexCoords[e][pf.mIndices[d]]; mesh->mTextureCoords[e][newIndex] = aiVector3D( tex.x, 1.0f - tex.y, 0.0f); } } // vertex color sets for ( unsigned int e = 0; e < AI_MAX_NUMBER_OF_COLOR_SETS; ++e ) { if ( mesh->HasVertexColors( e ) ) { mesh->mColors[ e ][ newIndex ] = sourceMesh->mColors[ e ][ pf.mIndices[ d ] ]; } } newIndex++; } } // there should be as much new vertices as we calculated before ai_assert( newIndex == numVertices); // convert all bones of the source mesh which influence vertices in this newly created mesh const std::vector& bones = sourceMesh->mBones; std::vector newBones; for( unsigned int c = 0; c < bones.size(); ++c ) { const XFile::Bone& obone = bones[c]; // set up a vertex-linear array of the weights for quick searching if a bone influences a vertex std::vector oldWeights( sourceMesh->mPositions.size(), 0.0); for ( unsigned int d = 0; d < obone.mWeights.size(); ++d ) { oldWeights[ obone.mWeights[ d ].mVertex ] = obone.mWeights[ d ].mWeight; } // collect all vertex weights that influence a vertex in the new mesh std::vector newWeights; newWeights.reserve( numVertices); for( unsigned int d = 0; d < orgPoints.size(); ++d ) { // does the new vertex stem from an old vertex which was influenced by this bone? ai_real w = oldWeights[orgPoints[d]]; if ( w > 0.0 ) { newWeights.push_back( aiVertexWeight( d, w ) ); } } // if the bone has no weights in the newly created mesh, ignore it if ( newWeights.empty() ) { continue; } // create aiBone* nbone = new aiBone; newBones.push_back( nbone); // copy name and matrix nbone->mName.Set( obone.mName); nbone->mOffsetMatrix = obone.mOffsetMatrix; nbone->mNumWeights = (unsigned int)newWeights.size(); nbone->mWeights = new aiVertexWeight[nbone->mNumWeights]; for ( unsigned int d = 0; d < newWeights.size(); ++d ) { nbone->mWeights[ d ] = newWeights[ d ]; } } // store the bones in the mesh mesh->mNumBones = (unsigned int)newBones.size(); if( !newBones.empty()) { mesh->mBones = new aiBone*[mesh->mNumBones]; std::copy( newBones.begin(), newBones.end(), mesh->mBones); } } } // reallocate scene mesh array to be large enough aiMesh** prevArray = pScene->mMeshes; pScene->mMeshes = new aiMesh*[pScene->mNumMeshes + meshes.size()]; if( prevArray) { memcpy( pScene->mMeshes, prevArray, pScene->mNumMeshes * sizeof( aiMesh*)); delete [] prevArray; } // allocate mesh index array in the node pNode->mNumMeshes = (unsigned int)meshes.size(); pNode->mMeshes = new unsigned int[pNode->mNumMeshes]; // store all meshes in the mesh library of the scene and store their indices in the node for( unsigned int a = 0; a < meshes.size(); a++) { pScene->mMeshes[pScene->mNumMeshes] = meshes[a]; pNode->mMeshes[a] = pScene->mNumMeshes; pScene->mNumMeshes++; } } // ------------------------------------------------------------------------------------------------ // Converts the animations from the given imported data and creates them in the scene. void XFileImporter::CreateAnimations( aiScene* pScene, const XFile::Scene* pData) { std::vector newAnims; for( unsigned int a = 0; a < pData->mAnims.size(); ++a ) { const XFile::Animation* anim = pData->mAnims[a]; // some exporters mock me with empty animation tags. if ( anim->mAnims.empty() ) { continue; } // create a new animation to hold the data aiAnimation* nanim = new aiAnimation; newAnims.push_back( nanim); nanim->mName.Set( anim->mName); // duration will be determined by the maximum length nanim->mDuration = 0; nanim->mTicksPerSecond = pData->mAnimTicksPerSecond; nanim->mNumChannels = (unsigned int)anim->mAnims.size(); nanim->mChannels = new aiNodeAnim*[nanim->mNumChannels]; for( unsigned int b = 0; b < anim->mAnims.size(); ++b ) { const XFile::AnimBone* bone = anim->mAnims[b]; aiNodeAnim* nbone = new aiNodeAnim; nbone->mNodeName.Set( bone->mBoneName); nanim->mChannels[b] = nbone; // key-frames are given as combined transformation matrix keys if( !bone->mTrafoKeys.empty() ) { nbone->mNumPositionKeys = (unsigned int)bone->mTrafoKeys.size(); nbone->mPositionKeys = new aiVectorKey[nbone->mNumPositionKeys]; nbone->mNumRotationKeys = (unsigned int)bone->mTrafoKeys.size(); nbone->mRotationKeys = new aiQuatKey[nbone->mNumRotationKeys]; nbone->mNumScalingKeys = (unsigned int)bone->mTrafoKeys.size(); nbone->mScalingKeys = new aiVectorKey[nbone->mNumScalingKeys]; for( unsigned int c = 0; c < bone->mTrafoKeys.size(); ++c) { // deconstruct each matrix into separate position, rotation and scaling double time = bone->mTrafoKeys[c].mTime; aiMatrix4x4 trafo = bone->mTrafoKeys[c].mMatrix; // extract position aiVector3D pos( trafo.a4, trafo.b4, trafo.c4); nbone->mPositionKeys[c].mTime = time; nbone->mPositionKeys[c].mValue = pos; // extract scaling aiVector3D scale; scale.x = aiVector3D( trafo.a1, trafo.b1, trafo.c1).Length(); scale.y = aiVector3D( trafo.a2, trafo.b2, trafo.c2).Length(); scale.z = aiVector3D( trafo.a3, trafo.b3, trafo.c3).Length(); nbone->mScalingKeys[c].mTime = time; nbone->mScalingKeys[c].mValue = scale; // reconstruct rotation matrix without scaling aiMatrix3x3 rotmat( trafo.a1 / scale.x, trafo.a2 / scale.y, trafo.a3 / scale.z, trafo.b1 / scale.x, trafo.b2 / scale.y, trafo.b3 / scale.z, trafo.c1 / scale.x, trafo.c2 / scale.y, trafo.c3 / scale.z); // and convert it into a quaternion nbone->mRotationKeys[c].mTime = time; nbone->mRotationKeys[c].mValue = aiQuaternion( rotmat); } // longest lasting key sequence determines duration nanim->mDuration = std::max( nanim->mDuration, bone->mTrafoKeys.back().mTime); } else { // separate key sequences for position, rotation, scaling nbone->mNumPositionKeys = (unsigned int)bone->mPosKeys.size(); if (nbone->mNumPositionKeys != 0) { nbone->mPositionKeys = new aiVectorKey[nbone->mNumPositionKeys]; for( unsigned int c = 0; c < nbone->mNumPositionKeys; ++c ) { aiVector3D pos = bone->mPosKeys[c].mValue; nbone->mPositionKeys[c].mTime = bone->mPosKeys[c].mTime; nbone->mPositionKeys[c].mValue = pos; } } // rotation nbone->mNumRotationKeys = (unsigned int)bone->mRotKeys.size(); if (nbone->mNumRotationKeys != 0) { nbone->mRotationKeys = new aiQuatKey[nbone->mNumRotationKeys]; for( unsigned int c = 0; c < nbone->mNumRotationKeys; ++c ) { aiMatrix3x3 rotmat = bone->mRotKeys[c].mValue.GetMatrix(); nbone->mRotationKeys[c].mTime = bone->mRotKeys[c].mTime; nbone->mRotationKeys[c].mValue = aiQuaternion( rotmat); nbone->mRotationKeys[c].mValue.w *= -1.0f; // needs quat inversion } } // scaling nbone->mNumScalingKeys = (unsigned int)bone->mScaleKeys.size(); if (nbone->mNumScalingKeys != 0) { nbone->mScalingKeys = new aiVectorKey[nbone->mNumScalingKeys]; for( unsigned int c = 0; c < nbone->mNumScalingKeys; c++) nbone->mScalingKeys[c] = bone->mScaleKeys[c]; } // longest lasting key sequence determines duration if( bone->mPosKeys.size() > 0) nanim->mDuration = std::max( nanim->mDuration, bone->mPosKeys.back().mTime); if( bone->mRotKeys.size() > 0) nanim->mDuration = std::max( nanim->mDuration, bone->mRotKeys.back().mTime); if( bone->mScaleKeys.size() > 0) nanim->mDuration = std::max( nanim->mDuration, bone->mScaleKeys.back().mTime); } } } // store all converted animations in the scene if( newAnims.size() > 0) { pScene->mNumAnimations = (unsigned int)newAnims.size(); pScene->mAnimations = new aiAnimation* [pScene->mNumAnimations]; for( unsigned int a = 0; a < newAnims.size(); a++) pScene->mAnimations[a] = newAnims[a]; } } // ------------------------------------------------------------------------------------------------ // Converts all materials in the given array and stores them in the scene's material list. void XFileImporter::ConvertMaterials( aiScene* pScene, std::vector& pMaterials) { // count the non-referrer materials in the array unsigned int numNewMaterials( 0 ); for ( unsigned int a = 0; a < pMaterials.size(); ++a ) { if ( !pMaterials[ a ].mIsReference ) { ++numNewMaterials; } } // resize the scene's material list to offer enough space for the new materials if( numNewMaterials > 0 ) { aiMaterial** prevMats = pScene->mMaterials; pScene->mMaterials = new aiMaterial*[pScene->mNumMaterials + numNewMaterials]; if( nullptr != prevMats) { ::memcpy( pScene->mMaterials, prevMats, pScene->mNumMaterials * sizeof( aiMaterial*)); delete [] prevMats; } } // convert all the materials given in the array for( unsigned int a = 0; a < pMaterials.size(); ++a ) { XFile::Material& oldMat = pMaterials[a]; if( oldMat.mIsReference) { // find the material it refers to by name, and store its index for( size_t b = 0; b < pScene->mNumMaterials; ++b ) { aiString name; pScene->mMaterials[b]->Get( AI_MATKEY_NAME, name); if( strcmp( name.C_Str(), oldMat.mName.data()) == 0 ) { oldMat.sceneIndex = a; break; } } if( oldMat.sceneIndex == SIZE_MAX ) { ASSIMP_LOG_WARN_F( "Could not resolve global material reference \"", oldMat.mName, "\"" ); oldMat.sceneIndex = 0; } continue; } aiMaterial* mat = new aiMaterial; aiString name; name.Set( oldMat.mName); mat->AddProperty( &name, AI_MATKEY_NAME); // Shading model: hard-coded to PHONG, there is no such information in an XFile // FIX (aramis): If the specular exponent is 0, use gouraud shading. This is a bugfix // for some models in the SDK (e.g. good old tiny.x) int shadeMode = (int)oldMat.mSpecularExponent == 0.0f ? aiShadingMode_Gouraud : aiShadingMode_Phong; mat->AddProperty( &shadeMode, 1, AI_MATKEY_SHADING_MODEL); // material colours // Unclear: there's no ambient colour, but emissive. What to put for ambient? // Probably nothing at all, let the user select a suitable default. mat->AddProperty( &oldMat.mEmissive, 1, AI_MATKEY_COLOR_EMISSIVE); mat->AddProperty( &oldMat.mDiffuse, 1, AI_MATKEY_COLOR_DIFFUSE); mat->AddProperty( &oldMat.mSpecular, 1, AI_MATKEY_COLOR_SPECULAR); mat->AddProperty( &oldMat.mSpecularExponent, 1, AI_MATKEY_SHININESS); // texture, if there is one if (1 == oldMat.mTextures.size() ) { const XFile::TexEntry& otex = oldMat.mTextures.back(); if (otex.mName.length()) { // if there is only one texture assume it contains the diffuse color aiString tex( otex.mName); if ( otex.mIsNormalMap ) { mat->AddProperty( &tex, AI_MATKEY_TEXTURE_NORMALS( 0 ) ); } else { mat->AddProperty( &tex, AI_MATKEY_TEXTURE_DIFFUSE( 0 ) ); } } } else { // Otherwise ... try to search for typical strings in the // texture's file name like 'bump' or 'diffuse' unsigned int iHM = 0,iNM = 0,iDM = 0,iSM = 0,iAM = 0,iEM = 0; for( unsigned int b = 0; b < oldMat.mTextures.size(); ++b ) { const XFile::TexEntry& otex = oldMat.mTextures[b]; std::string sz = otex.mName; if ( !sz.length() ) { continue; } // find the file name std::string::size_type s = sz.find_last_of("\\/"); if ( std::string::npos == s ) { s = 0; } // cut off the file extension std::string::size_type sExt = sz.find_last_of('.'); if (std::string::npos != sExt){ sz[sExt] = '\0'; } // convert to lower case for easier comparison for ( unsigned int c = 0; c < sz.length(); ++c ) { if ( isalpha( (unsigned char) sz[ c ] ) ) { sz[ c ] = (char) tolower( (unsigned char) sz[ c ] ); } } // Place texture filename property under the corresponding name aiString tex( oldMat.mTextures[b].mName); // bump map if (std::string::npos != sz.find("bump", s) || std::string::npos != sz.find("height", s)) { mat->AddProperty( &tex, AI_MATKEY_TEXTURE_HEIGHT(iHM++)); } else if (otex.mIsNormalMap || std::string::npos != sz.find( "normal", s) || std::string::npos != sz.find("nm", s)) { mat->AddProperty( &tex, AI_MATKEY_TEXTURE_NORMALS(iNM++)); } else if (std::string::npos != sz.find( "spec", s) || std::string::npos != sz.find( "glanz", s)) { mat->AddProperty( &tex, AI_MATKEY_TEXTURE_SPECULAR(iSM++)); } else if (std::string::npos != sz.find( "ambi", s) || std::string::npos != sz.find( "env", s)) { mat->AddProperty( &tex, AI_MATKEY_TEXTURE_AMBIENT(iAM++)); } else if (std::string::npos != sz.find( "emissive", s) || std::string::npos != sz.find( "self", s)) { mat->AddProperty( &tex, AI_MATKEY_TEXTURE_EMISSIVE(iEM++)); } else { // Assume it is a diffuse texture mat->AddProperty( &tex, AI_MATKEY_TEXTURE_DIFFUSE(iDM++)); } } } pScene->mMaterials[pScene->mNumMaterials] = mat; oldMat.sceneIndex = pScene->mNumMaterials; pScene->mNumMaterials++; } } #endif // !! ASSIMP_BUILD_NO_X_IMPORTER