|
- /*
- ---------------------------------------------------------------------------
- Open Asset Import Library (assimp)
- ---------------------------------------------------------------------------
-
- Copyright (c) 2006-2012, 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 Implementation of the STL importer class */
-
- #include "AssimpPCH.h"
- #ifndef ASSIMP_BUILD_NO_NFF_IMPORTER
-
- // internal headers
- #include "NFFLoader.h"
- #include "ParsingUtils.h"
- #include "StandardShapes.h"
- #include "fast_atof.h"
- #include "RemoveComments.h"
-
- using namespace Assimp;
-
- static const aiImporterDesc desc = {
- "Neutral File Format Importer",
- "",
- "",
- "",
- aiImporterFlags_SupportBinaryFlavour,
- 0,
- 0,
- 0,
- 0,
- "enff nff"
- };
-
- // ------------------------------------------------------------------------------------------------
- // Constructor to be privately used by Importer
- NFFImporter::NFFImporter()
- {}
-
- // ------------------------------------------------------------------------------------------------
- // Destructor, private as well
- NFFImporter::~NFFImporter()
- {}
-
- // ------------------------------------------------------------------------------------------------
- // Returns whether the class can handle the format of the given file.
- bool NFFImporter::CanRead( const std::string& pFile, IOSystem* /*pIOHandler*/, bool /*checkSig*/) const
- {
- return SimpleExtensionCheck(pFile,"nff","enff");
- }
-
- // ------------------------------------------------------------------------------------------------
- // Get the list of all supported file extensions
- const aiImporterDesc* NFFImporter::GetInfo () const
- {
- return &desc;
- }
-
- // ------------------------------------------------------------------------------------------------
- #define AI_NFF_PARSE_FLOAT(f) \
- SkipSpaces(&sz); \
- if (!::IsLineEnd(*sz))sz = fast_atoreal_move<float>(sz, (float&)f);
-
- // ------------------------------------------------------------------------------------------------
- #define AI_NFF_PARSE_TRIPLE(v) \
- AI_NFF_PARSE_FLOAT(v[0]) \
- AI_NFF_PARSE_FLOAT(v[1]) \
- AI_NFF_PARSE_FLOAT(v[2])
-
- // ------------------------------------------------------------------------------------------------
- #define AI_NFF_PARSE_SHAPE_INFORMATION() \
- aiVector3D center, radius(1.0f,get_qnan(),get_qnan()); \
- AI_NFF_PARSE_TRIPLE(center); \
- AI_NFF_PARSE_TRIPLE(radius); \
- if (is_qnan(radius.z))radius.z = radius.x; \
- if (is_qnan(radius.y))radius.y = radius.x; \
- currentMesh.radius = radius; \
- currentMesh.center = center;
-
- // ------------------------------------------------------------------------------------------------
- #define AI_NFF2_GET_NEXT_TOKEN() \
- do \
- { \
- if (!GetNextLine(buffer,line)) \
- {DefaultLogger::get()->warn("NFF2: Unexpected EOF, can't read next token");break;} \
- SkipSpaces(line,&sz); \
- } \
- while(IsLineEnd(*sz))
-
-
- // ------------------------------------------------------------------------------------------------
- // Loads the materail table for the NFF2 file format from an external file
- void NFFImporter::LoadNFF2MaterialTable(std::vector<ShadingInfo>& output,
- const std::string& path, IOSystem* pIOHandler)
- {
- boost::scoped_ptr<IOStream> file( pIOHandler->Open( path, "rb"));
-
- // Check whether we can read from the file
- if( !file.get()) {
- DefaultLogger::get()->error("NFF2: Unable to open material library " + path + ".");
- return;
- }
-
- // get the size of the file
- const unsigned int m = (unsigned int)file->FileSize();
-
- // allocate storage and copy the contents of the file to a memory buffer
- // (terminate it with zero)
- std::vector<char> mBuffer2(m+1);
- TextFileToBuffer(file.get(),mBuffer2);
- const char* buffer = &mBuffer2[0];
-
- // First of all: remove all comments from the file
- CommentRemover::RemoveLineComments("//",&mBuffer2[0]);
-
- // The file should start with the magic sequence "mat"
- if (!TokenMatch(buffer,"mat",3)) {
- DefaultLogger::get()->error("NFF2: Not a valid material library " + path + ".");
- return;
- }
-
- ShadingInfo* curShader = NULL;
-
- // No read the file line per line
- char line[4096];
- const char* sz;
- while (GetNextLine(buffer,line))
- {
- SkipSpaces(line,&sz);
-
- // 'version' defines the version of the file format
- if (TokenMatch(sz,"version",7))
- {
- DefaultLogger::get()->info("NFF (Sense8) material library file format: " + std::string(sz));
- }
- // 'matdef' starts a new material in the file
- else if (TokenMatch(sz,"matdef",6))
- {
- // add a new material to the list
- output.push_back( ShadingInfo() );
- curShader = & output.back();
-
- // parse the name of the material
- }
- else if (!TokenMatch(sz,"valid",5))
- {
- // check whether we have an active material at the moment
- if (!IsLineEnd(*sz))
- {
- if (!curShader)
- {
- DefaultLogger::get()->error(std::string("NFF2 material library: Found element ") +
- sz + "but there is no active material");
- continue;
- }
- }
- else continue;
-
- // now read the material property and determine its type
- aiColor3D c;
- if (TokenMatch(sz,"ambient",7))
- {
- AI_NFF_PARSE_TRIPLE(c);
- curShader->ambient = c;
- }
- else if (TokenMatch(sz,"diffuse",7) || TokenMatch(sz,"ambientdiffuse",14) /* correct? */)
- {
- AI_NFF_PARSE_TRIPLE(c);
- curShader->diffuse = curShader->ambient = c;
- }
- else if (TokenMatch(sz,"specular",8))
- {
- AI_NFF_PARSE_TRIPLE(c);
- curShader->specular = c;
- }
- else if (TokenMatch(sz,"emission",8))
- {
- AI_NFF_PARSE_TRIPLE(c);
- curShader->emissive = c;
- }
- else if (TokenMatch(sz,"shininess",9))
- {
- AI_NFF_PARSE_FLOAT(curShader->shininess);
- }
- else if (TokenMatch(sz,"opacity",7))
- {
- AI_NFF_PARSE_FLOAT(curShader->opacity);
- }
- }
- }
- }
-
- // ------------------------------------------------------------------------------------------------
- // Imports the given file into the given scene structure.
- void NFFImporter::InternReadFile( const std::string& pFile,
- aiScene* pScene, IOSystem* pIOHandler)
- {
- boost::scoped_ptr<IOStream> file( pIOHandler->Open( pFile, "rb"));
-
- // Check whether we can read from the file
- if( !file.get())
- throw DeadlyImportError( "Failed to open NFF file " + pFile + ".");
-
- unsigned int m = (unsigned int)file->FileSize();
-
- // allocate storage and copy the contents of the file to a memory buffer
- // (terminate it with zero)
- std::vector<char> mBuffer2;
- TextFileToBuffer(file.get(),mBuffer2);
- const char* buffer = &mBuffer2[0];
-
- // mesh arrays - separate here to make the handling of the pointers below easier.
- std::vector<MeshInfo> meshes;
- std::vector<MeshInfo> meshesWithNormals;
- std::vector<MeshInfo> meshesWithUVCoords;
- std::vector<MeshInfo> meshesLocked;
-
- char line[4096];
- const char* sz;
-
- // camera parameters
- aiVector3D camPos, camUp(0.f,1.f,0.f), camLookAt(0.f,0.f,1.f);
- float angle = 45.f;
- aiVector2D resolution;
-
- bool hasCam = false;
-
- MeshInfo* currentMeshWithNormals = NULL;
- MeshInfo* currentMesh = NULL;
- MeshInfo* currentMeshWithUVCoords = NULL;
-
- ShadingInfo s; // current material info
-
- // degree of tesselation
- unsigned int iTesselation = 4;
-
- // some temporary variables we need to parse the file
- unsigned int sphere = 0,
- cylinder = 0,
- cone = 0,
- numNamed = 0,
- dodecahedron = 0,
- octahedron = 0,
- tetrahedron = 0,
- hexahedron = 0;
-
- // lights imported from the file
- std::vector<Light> lights;
-
- // check whether this is the NFF2 file format
- if (TokenMatch(buffer,"nff",3))
- {
- const float qnan = get_qnan();
- const aiColor4D cQNAN = aiColor4D (qnan,0.f,0.f,1.f);
- const aiVector3D vQNAN = aiVector3D(qnan,0.f,0.f);
-
- // another NFF file format ... just a raw parser has been implemented
- // no support for further details, I don't think it is worth the effort
- // http://ozviz.wasp.uwa.edu.au/~pbourke/dataformats/nff/nff2.html
- // http://www.netghost.narod.ru/gff/graphics/summary/sense8.htm
-
- // First of all: remove all comments from the file
- CommentRemover::RemoveLineComments("//",&mBuffer2[0]);
-
- while (GetNextLine(buffer,line))
- {
- SkipSpaces(line,&sz);
- if (TokenMatch(sz,"version",7))
- {
- DefaultLogger::get()->info("NFF (Sense8) file format: " + std::string(sz));
- }
- else if (TokenMatch(sz,"viewpos",7))
- {
- AI_NFF_PARSE_TRIPLE(camPos);
- hasCam = true;
- }
- else if (TokenMatch(sz,"viewdir",7))
- {
- AI_NFF_PARSE_TRIPLE(camLookAt);
- hasCam = true;
- }
- // This starts a new object section
- else if (!IsSpaceOrNewLine(*sz))
- {
- unsigned int subMeshIdx = 0;
-
- // read the name of the object, skip all spaces
- // at the end of it.
- const char* sz3 = sz;
- while (!IsSpaceOrNewLine(*sz))++sz;
- std::string objectName = std::string(sz3,(unsigned int)(sz-sz3));
-
- const unsigned int objStart = (unsigned int)meshes.size();
-
- // There could be a material table in a separate file
- std::vector<ShadingInfo> materialTable;
- while (true)
- {
- AI_NFF2_GET_NEXT_TOKEN();
-
- // material table - an external file
- if (TokenMatch(sz,"mtable",6))
- {
- SkipSpaces(&sz);
- sz3 = sz;
- while (!IsSpaceOrNewLine(*sz))++sz;
- const unsigned int diff = (unsigned int)(sz-sz3);
- if (!diff)DefaultLogger::get()->warn("NFF2: Found empty mtable token");
- else
- {
- // The material table has the file extension .mat.
- // If it is not there, we need to append it
- std::string path = std::string(sz3,diff);
- if(std::string::npos == path.find_last_of(".mat"))
- {
- path.append(".mat");
- }
-
- // Now extract the working directory from the path to
- // this file and append the material library filename
- // to it.
- std::string::size_type s;
- if ((std::string::npos == (s = path.find_last_of('\\')) || !s) &&
- (std::string::npos == (s = path.find_last_of('/')) || !s) )
- {
- s = pFile.find_last_of('\\');
- if (std::string::npos == s)s = pFile.find_last_of('/');
- if (std::string::npos != s)
- {
- path = pFile.substr(0,s+1) + path;
- }
- }
- LoadNFF2MaterialTable(materialTable,path,pIOHandler);
- }
- }
- else break;
- }
-
- // read the numbr of vertices
- unsigned int num = ::strtoul10(sz,&sz);
-
- // temporary storage
- std::vector<aiColor4D> tempColors;
- std::vector<aiVector3D> tempPositions,tempTextureCoords,tempNormals;
-
- bool hasNormals = false,hasUVs = false,hasColor = false;
-
- tempPositions.reserve (num);
- tempColors.reserve (num);
- tempNormals.reserve (num);
- tempTextureCoords.reserve (num);
- for (unsigned int i = 0; i < num; ++i)
- {
- AI_NFF2_GET_NEXT_TOKEN();
- aiVector3D v;
- AI_NFF_PARSE_TRIPLE(v);
- tempPositions.push_back(v);
-
- // parse all other attributes in the line
- while (true)
- {
- SkipSpaces(&sz);
- if (IsLineEnd(*sz))break;
-
- // color definition
- if (TokenMatch(sz,"0x",2))
- {
- hasColor = true;
- register unsigned int numIdx = ::strtoul16(sz,&sz);
- aiColor4D clr;
- clr.a = 1.f;
-
- // 0xRRGGBB
- clr.r = ((numIdx >> 16u) & 0xff) / 255.f;
- clr.g = ((numIdx >> 8u) & 0xff) / 255.f;
- clr.b = ((numIdx) & 0xff) / 255.f;
- tempColors.push_back(clr);
- }
- // normal vector
- else if (TokenMatch(sz,"norm",4))
- {
- hasNormals = true;
- AI_NFF_PARSE_TRIPLE(v);
- tempNormals.push_back(v);
- }
- // UV coordinate
- else if (TokenMatch(sz,"uv",2))
- {
- hasUVs = true;
- AI_NFF_PARSE_FLOAT(v.x);
- AI_NFF_PARSE_FLOAT(v.y);
- v.z = 0.f;
- tempTextureCoords.push_back(v);
- }
- }
-
- // fill in dummies for all attributes that have not been set
- if (tempNormals.size() != tempPositions.size())
- tempNormals.push_back(vQNAN);
-
- if (tempTextureCoords.size() != tempPositions.size())
- tempTextureCoords.push_back(vQNAN);
-
- if (tempColors.size() != tempPositions.size())
- tempColors.push_back(cQNAN);
- }
-
- AI_NFF2_GET_NEXT_TOKEN();
- if (!num)throw DeadlyImportError("NFF2: There are zero vertices");
- num = ::strtoul10(sz,&sz);
-
- std::vector<unsigned int> tempIdx;
- tempIdx.reserve(10);
- for (unsigned int i = 0; i < num; ++i)
- {
- AI_NFF2_GET_NEXT_TOKEN();
- SkipSpaces(line,&sz);
- unsigned int numIdx = ::strtoul10(sz,&sz);
-
- // read all faces indices
- if (numIdx)
- {
- // mesh.faces.push_back(numIdx);
- // tempIdx.erase(tempIdx.begin(),tempIdx.end());
- tempIdx.resize(numIdx);
-
- for (unsigned int a = 0; a < numIdx;++a)
- {
- SkipSpaces(sz,&sz);
- m = ::strtoul10(sz,&sz);
- if (m >= (unsigned int)tempPositions.size())
- {
- DefaultLogger::get()->error("NFF2: Vertex index overflow");
- m= 0;
- }
- // mesh.vertices.push_back (tempPositions[idx]);
- tempIdx[a] = m;
- }
- }
-
- // build a temporary shader object for the face.
- ShadingInfo shader;
- unsigned int matIdx = 0;
-
- // white material color - we have vertex colors
- shader.color = aiColor3D(1.f,1.f,1.f);
- aiColor4D c = aiColor4D(1.f,1.f,1.f,1.f);
- while (true)
- {
- SkipSpaces(sz,&sz);
- if(IsLineEnd(*sz))break;
-
- // per-polygon colors
- if (TokenMatch(sz,"0x",2))
- {
- hasColor = true;
- const char* sz2 = sz;
- numIdx = ::strtoul16(sz,&sz);
- const unsigned int diff = (unsigned int)(sz-sz2);
-
- // 0xRRGGBB
- if (diff > 3)
- {
- c.r = ((numIdx >> 16u) & 0xff) / 255.f;
- c.g = ((numIdx >> 8u) & 0xff) / 255.f;
- c.b = ((numIdx) & 0xff) / 255.f;
- }
- // 0xRGB
- else
- {
- c.r = ((numIdx >> 8u) & 0xf) / 16.f;
- c.g = ((numIdx >> 4u) & 0xf) / 16.f;
- c.b = ((numIdx) & 0xf) / 16.f;
- }
- }
- // TODO - implement texture mapping here
- #if 0
- // mirror vertex texture coordinate?
- else if (TokenMatch(sz,"mirror",6))
- {
- }
- // texture coordinate scaling
- else if (TokenMatch(sz,"scale",5))
- {
- }
- // texture coordinate translation
- else if (TokenMatch(sz,"trans",5))
- {
- }
- // texture coordinate rotation angle
- else if (TokenMatch(sz,"rot",3))
- {
- }
- #endif
-
- // texture file name for this polygon + mapping information
- else if ('_' == sz[0])
- {
- // get mapping information
- switch (sz[1])
- {
- case 'v':
- case 'V':
-
- shader.shaded = false;
- break;
-
- case 't':
- case 'T':
- case 'u':
- case 'U':
-
- DefaultLogger::get()->warn("Unsupported NFF2 texture attribute: trans");
- };
- if (!sz[1] || '_' != sz[2])
- {
- DefaultLogger::get()->warn("NFF2: Expected underscore after texture attributes");
- continue;
- }
- const char* sz2 = sz+3;
- while (!IsSpaceOrNewLine( *sz ))++sz;
- const unsigned int diff = (unsigned int)(sz-sz2);
- if (diff)shader.texFile = std::string(sz2,diff);
- }
-
- // Two-sided material?
- else if (TokenMatch(sz,"both",4))
- {
- shader.twoSided = true;
- }
-
- // Material ID?
- else if (!materialTable.empty() && TokenMatch(sz,"matid",5))
- {
- SkipSpaces(&sz);
- matIdx = ::strtoul10(sz,&sz);
- if (matIdx >= materialTable.size())
- {
- DefaultLogger::get()->error("NFF2: Material index overflow.");
- matIdx = 0;
- }
-
- // now combine our current shader with the shader we
- // read from the material table.
- ShadingInfo& mat = materialTable[matIdx];
- shader.ambient = mat.ambient;
- shader.diffuse = mat.diffuse;
- shader.emissive = mat.emissive;
- shader.opacity = mat.opacity;
- shader.specular = mat.specular;
- shader.shininess = mat.shininess;
- }
- else SkipToken(sz);
- }
-
- // search the list of all shaders we have for this object whether
- // there is an identical one. In this case, we append our mesh
- // data to it.
- MeshInfo* mesh = NULL;
- for (std::vector<MeshInfo>::iterator it = meshes.begin() + objStart, end = meshes.end();
- it != end; ++it)
- {
- if ((*it).shader == shader && (*it).matIndex == matIdx)
- {
- // we have one, we can append our data to it
- mesh = &(*it);
- }
- }
- if (!mesh)
- {
- meshes.push_back(MeshInfo(PatchType_Simple,false));
- mesh = &meshes.back();
- mesh->matIndex = matIdx;
-
- // We need to add a new mesh to the list. We assign
- // an unique name to it to make sure the scene will
- // pass the validation step for the moment.
- // TODO: fix naming of objects in the scenegraph later
- if (objectName.length())
- {
- ::strcpy(mesh->name,objectName.c_str());
- ASSIMP_itoa10(&mesh->name[objectName.length()],30,subMeshIdx++);
- }
-
- // copy the shader to the mesh.
- mesh->shader = shader;
- }
-
- // fill the mesh with data
- if (!tempIdx.empty())
- {
- mesh->faces.push_back((unsigned int)tempIdx.size());
- for (std::vector<unsigned int>::const_iterator it = tempIdx.begin(), end = tempIdx.end();
- it != end;++it)
- {
- m = *it;
-
- // copy colors -vertex color specifications override polygon color specifications
- if (hasColor)
- {
- const aiColor4D& clr = tempColors[m];
- mesh->colors.push_back((is_qnan( clr.r ) ? c : clr));
- }
-
- // positions should always be there
- mesh->vertices.push_back (tempPositions[m]);
-
- // copy normal vectors
- if (hasNormals)
- mesh->normals.push_back (tempNormals[m]);
-
- // copy texture coordinates
- if (hasUVs)
- mesh->uvs.push_back (tempTextureCoords[m]);
- }
- }
- }
- if (!num)throw DeadlyImportError("NFF2: There are zero faces");
- }
- }
- camLookAt = camLookAt + camPos;
- }
- else // "Normal" Neutral file format that is quite more common
- {
- while (GetNextLine(buffer,line))
- {
- sz = line;
- if ('p' == line[0] || TokenMatch(sz,"tpp",3))
- {
- MeshInfo* out = NULL;
-
- // 'tpp' - texture polygon patch primitive
- if ('t' == line[0])
- {
- currentMeshWithUVCoords = NULL;
- for (std::vector<MeshInfo>::iterator it = meshesWithUVCoords.begin(), end = meshesWithUVCoords.end();
- it != end;++it)
- {
- if ((*it).shader == s)
- {
- currentMeshWithUVCoords = &(*it);
- break;
- }
- }
-
- if (!currentMeshWithUVCoords)
- {
- meshesWithUVCoords.push_back(MeshInfo(PatchType_UVAndNormals));
- currentMeshWithUVCoords = &meshesWithUVCoords.back();
- currentMeshWithUVCoords->shader = s;
- }
- out = currentMeshWithUVCoords;
- }
- // 'pp' - polygon patch primitive
- else if ('p' == line[1])
- {
- currentMeshWithNormals = NULL;
- for (std::vector<MeshInfo>::iterator it = meshesWithNormals.begin(), end = meshesWithNormals.end();
- it != end;++it)
- {
- if ((*it).shader == s)
- {
- currentMeshWithNormals = &(*it);
- break;
- }
- }
-
- if (!currentMeshWithNormals)
- {
- meshesWithNormals.push_back(MeshInfo(PatchType_Normals));
- currentMeshWithNormals = &meshesWithNormals.back();
- currentMeshWithNormals->shader = s;
- }
- sz = &line[2];out = currentMeshWithNormals;
- }
- // 'p' - polygon primitive
- else
- {
- currentMesh = NULL;
- for (std::vector<MeshInfo>::iterator it = meshes.begin(), end = meshes.end();
- it != end;++it)
- {
- if ((*it).shader == s)
- {
- currentMesh = &(*it);
- break;
- }
- }
-
- if (!currentMesh)
- {
- meshes.push_back(MeshInfo(PatchType_Simple));
- currentMesh = &meshes.back();
- currentMesh->shader = s;
- }
- sz = &line[1];out = currentMesh;
- }
- SkipSpaces(sz,&sz);
- m = strtoul10(sz);
-
- // ---- flip the face order
- out->vertices.resize(out->vertices.size()+m);
- if (out != currentMesh)
- {
- out->normals.resize(out->vertices.size());
- }
- if (out == currentMeshWithUVCoords)
- {
- out->uvs.resize(out->vertices.size());
- }
- for (unsigned int n = 0; n < m;++n)
- {
- if(!GetNextLine(buffer,line))
- {
- DefaultLogger::get()->error("NFF: Unexpected EOF was encountered. Patch definition incomplete");
- continue;
- }
-
- aiVector3D v; sz = &line[0];
- AI_NFF_PARSE_TRIPLE(v);
- out->vertices[out->vertices.size()-n-1] = v;
-
- if (out != currentMesh)
- {
- AI_NFF_PARSE_TRIPLE(v);
- out->normals[out->vertices.size()-n-1] = v;
- }
- if (out == currentMeshWithUVCoords)
- {
- // FIX: in one test file this wraps over multiple lines
- SkipSpaces(&sz);
- if (IsLineEnd(*sz))
- {
- GetNextLine(buffer,line);
- sz = line;
- }
- AI_NFF_PARSE_FLOAT(v.x);
- SkipSpaces(&sz);
- if (IsLineEnd(*sz))
- {
- GetNextLine(buffer,line);
- sz = line;
- }
- AI_NFF_PARSE_FLOAT(v.y);
- v.y = 1.f - v.y;
- out->uvs[out->vertices.size()-n-1] = v;
- }
- }
- out->faces.push_back(m);
- }
- // 'f' - shading information block
- else if (TokenMatch(sz,"f",1))
- {
- float d;
-
- // read the RGB colors
- AI_NFF_PARSE_TRIPLE(s.color);
-
- // read the other properties
- AI_NFF_PARSE_FLOAT(s.diffuse.r);
- AI_NFF_PARSE_FLOAT(s.specular.r);
- AI_NFF_PARSE_FLOAT(d); // skip shininess and transmittance
- AI_NFF_PARSE_FLOAT(d);
- AI_NFF_PARSE_FLOAT(s.refracti);
-
- // NFF2 uses full colors here so we need to use them too
- // although NFF uses simple scaling factors
- s.diffuse.g = s.diffuse.b = s.diffuse.r;
- s.specular.g = s.specular.b = s.specular.r;
-
- // if the next one is NOT a number we assume it is a texture file name
- // this feature is used by some NFF files on the internet and it has
- // been implemented as it can be really useful
- SkipSpaces(&sz);
- if (!IsNumeric(*sz))
- {
- // TODO: Support full file names with spaces and quotation marks ...
- const char* p = sz;
- while (!IsSpaceOrNewLine( *sz ))++sz;
-
- unsigned int diff = (unsigned int)(sz-p);
- if (diff)
- {
- s.texFile = std::string(p,diff);
- }
- }
- else
- {
- AI_NFF_PARSE_FLOAT(s.ambient); // optional
- }
- }
- // 'shader' - other way to specify a texture
- else if (TokenMatch(sz,"shader",6))
- {
- SkipSpaces(&sz);
- const char* old = sz;
- while (!IsSpaceOrNewLine(*sz))++sz;
- s.texFile = std::string(old, (uintptr_t)sz - (uintptr_t)old);
- }
- // 'l' - light source
- else if (TokenMatch(sz,"l",1))
- {
- lights.push_back(Light());
- Light& light = lights.back();
-
- AI_NFF_PARSE_TRIPLE(light.position);
- AI_NFF_PARSE_FLOAT (light.intensity);
- AI_NFF_PARSE_TRIPLE(light.color);
- }
- // 's' - sphere
- else if (TokenMatch(sz,"s",1))
- {
- meshesLocked.push_back(MeshInfo(PatchType_Simple,true));
- MeshInfo& currentMesh = meshesLocked.back();
- currentMesh.shader = s;
- currentMesh.shader.mapping = aiTextureMapping_SPHERE;
-
- AI_NFF_PARSE_SHAPE_INFORMATION();
-
- // we don't need scaling or translation here - we do it in the node's transform
- StandardShapes::MakeSphere(iTesselation, currentMesh.vertices);
- currentMesh.faces.resize(currentMesh.vertices.size()/3,3);
-
- // generate a name for the mesh
- ::sprintf(currentMesh.name,"sphere_%i",sphere++);
- }
- // 'dod' - dodecahedron
- else if (TokenMatch(sz,"dod",3))
- {
- meshesLocked.push_back(MeshInfo(PatchType_Simple,true));
- MeshInfo& currentMesh = meshesLocked.back();
- currentMesh.shader = s;
- currentMesh.shader.mapping = aiTextureMapping_SPHERE;
-
- AI_NFF_PARSE_SHAPE_INFORMATION();
-
- // we don't need scaling or translation here - we do it in the node's transform
- StandardShapes::MakeDodecahedron(currentMesh.vertices);
- currentMesh.faces.resize(currentMesh.vertices.size()/3,3);
-
- // generate a name for the mesh
- ::sprintf(currentMesh.name,"dodecahedron_%i",dodecahedron++);
- }
-
- // 'oct' - octahedron
- else if (TokenMatch(sz,"oct",3))
- {
- meshesLocked.push_back(MeshInfo(PatchType_Simple,true));
- MeshInfo& currentMesh = meshesLocked.back();
- currentMesh.shader = s;
- currentMesh.shader.mapping = aiTextureMapping_SPHERE;
-
- AI_NFF_PARSE_SHAPE_INFORMATION();
-
- // we don't need scaling or translation here - we do it in the node's transform
- StandardShapes::MakeOctahedron(currentMesh.vertices);
- currentMesh.faces.resize(currentMesh.vertices.size()/3,3);
-
- // generate a name for the mesh
- ::sprintf(currentMesh.name,"octahedron_%i",octahedron++);
- }
-
- // 'tet' - tetrahedron
- else if (TokenMatch(sz,"tet",3))
- {
- meshesLocked.push_back(MeshInfo(PatchType_Simple,true));
- MeshInfo& currentMesh = meshesLocked.back();
- currentMesh.shader = s;
- currentMesh.shader.mapping = aiTextureMapping_SPHERE;
-
- AI_NFF_PARSE_SHAPE_INFORMATION();
-
- // we don't need scaling or translation here - we do it in the node's transform
- StandardShapes::MakeTetrahedron(currentMesh.vertices);
- currentMesh.faces.resize(currentMesh.vertices.size()/3,3);
-
- // generate a name for the mesh
- ::sprintf(currentMesh.name,"tetrahedron_%i",tetrahedron++);
- }
-
- // 'hex' - hexahedron
- else if (TokenMatch(sz,"hex",3))
- {
- meshesLocked.push_back(MeshInfo(PatchType_Simple,true));
- MeshInfo& currentMesh = meshesLocked.back();
- currentMesh.shader = s;
- currentMesh.shader.mapping = aiTextureMapping_BOX;
-
- AI_NFF_PARSE_SHAPE_INFORMATION();
-
- // we don't need scaling or translation here - we do it in the node's transform
- StandardShapes::MakeHexahedron(currentMesh.vertices);
- currentMesh.faces.resize(currentMesh.vertices.size()/3,3);
-
- // generate a name for the mesh
- ::sprintf(currentMesh.name,"hexahedron_%i",hexahedron++);
- }
- // 'c' - cone
- else if (TokenMatch(sz,"c",1))
- {
- meshesLocked.push_back(MeshInfo(PatchType_Simple,true));
- MeshInfo& currentMesh = meshesLocked.back();
- currentMesh.shader = s;
- currentMesh.shader.mapping = aiTextureMapping_CYLINDER;
-
- if(!GetNextLine(buffer,line))
- {
- DefaultLogger::get()->error("NFF: Unexpected end of file (cone definition not complete)");
- break;
- }
- sz = line;
-
- // read the two center points and the respective radii
- aiVector3D center1, center2; float radius1, radius2;
- AI_NFF_PARSE_TRIPLE(center1);
- AI_NFF_PARSE_FLOAT(radius1);
-
- if(!GetNextLine(buffer,line))
- {
- DefaultLogger::get()->error("NFF: Unexpected end of file (cone definition not complete)");
- break;
- }
- sz = line;
-
- AI_NFF_PARSE_TRIPLE(center2);
- AI_NFF_PARSE_FLOAT(radius2);
-
- // compute the center point of the cone/cylinder -
- // it is its local transformation origin
- currentMesh.dir = center2-center1;
- currentMesh.center = center1+currentMesh.dir/2.f;
-
- float f;
- if (( f = currentMesh.dir.Length()) < 10e-3f )
- {
- DefaultLogger::get()->error("NFF: Cone height is close to zero");
- continue;
- }
- currentMesh.dir /= f; // normalize
-
- // generate the cone - it consists of simple triangles
- StandardShapes::MakeCone(f, radius1, radius2,
- integer_pow(4, iTesselation), currentMesh.vertices);
-
- // MakeCone() returns tris
- currentMesh.faces.resize(currentMesh.vertices.size()/3,3);
-
- // generate a name for the mesh. 'cone' if it a cone,
- // 'cylinder' if it is a cylinder. Funny, isn't it?
- if (radius1 != radius2)
- ::sprintf(currentMesh.name,"cone_%i",cone++);
- else ::sprintf(currentMesh.name,"cylinder_%i",cylinder++);
- }
- // 'tess' - tesselation
- else if (TokenMatch(sz,"tess",4))
- {
- SkipSpaces(&sz);
- iTesselation = strtoul10(sz);
- }
- // 'from' - camera position
- else if (TokenMatch(sz,"from",4))
- {
- AI_NFF_PARSE_TRIPLE(camPos);
- hasCam = true;
- }
- // 'at' - camera look-at vector
- else if (TokenMatch(sz,"at",2))
- {
- AI_NFF_PARSE_TRIPLE(camLookAt);
- hasCam = true;
- }
- // 'up' - camera up vector
- else if (TokenMatch(sz,"up",2))
- {
- AI_NFF_PARSE_TRIPLE(camUp);
- hasCam = true;
- }
- // 'angle' - (half?) camera field of view
- else if (TokenMatch(sz,"angle",5))
- {
- AI_NFF_PARSE_FLOAT(angle);
- hasCam = true;
- }
- // 'resolution' - used to compute the screen aspect
- else if (TokenMatch(sz,"resolution",10))
- {
- AI_NFF_PARSE_FLOAT(resolution.x);
- AI_NFF_PARSE_FLOAT(resolution.y);
- hasCam = true;
- }
- // 'pb' - bezier patch. Not supported yet
- else if (TokenMatch(sz,"pb",2))
- {
- DefaultLogger::get()->error("NFF: Encountered unsupported ID: bezier patch");
- }
- // 'pn' - NURBS. Not supported yet
- else if (TokenMatch(sz,"pn",2) || TokenMatch(sz,"pnn",3))
- {
- DefaultLogger::get()->error("NFF: Encountered unsupported ID: NURBS");
- }
- // '' - comment
- else if ('#' == line[0])
- {
- const char* sz;SkipSpaces(&line[1],&sz);
- if (!IsLineEnd(*sz))DefaultLogger::get()->info(sz);
- }
- }
- }
-
- // copy all arrays into one large
- meshes.reserve (meshes.size()+meshesLocked.size()+meshesWithNormals.size()+meshesWithUVCoords.size());
- meshes.insert (meshes.end(),meshesLocked.begin(),meshesLocked.end());
- meshes.insert (meshes.end(),meshesWithNormals.begin(),meshesWithNormals.end());
- meshes.insert (meshes.end(),meshesWithUVCoords.begin(),meshesWithUVCoords.end());
-
- // now generate output meshes. first find out how many meshes we'll need
- std::vector<MeshInfo>::const_iterator it = meshes.begin(), end = meshes.end();
- for (;it != end;++it)
- {
- if (!(*it).faces.empty())
- {
- ++pScene->mNumMeshes;
- if ((*it).name[0])++numNamed;
- }
- }
-
- // generate a dummy root node - assign all unnamed elements such
- // as polygons and polygon patches to the root node and generate
- // sub nodes for named objects such as spheres and cones.
- aiNode* const root = new aiNode();
- root->mName.Set("<NFF_Root>");
- root->mNumChildren = numNamed + (hasCam ? 1 : 0) + (unsigned int) lights.size();
- root->mNumMeshes = pScene->mNumMeshes-numNamed;
-
- aiNode** ppcChildren = NULL;
- unsigned int* pMeshes = NULL;
- if (root->mNumMeshes)
- pMeshes = root->mMeshes = new unsigned int[root->mNumMeshes];
- if (root->mNumChildren)
- ppcChildren = root->mChildren = new aiNode*[root->mNumChildren];
-
- // generate the camera
- if (hasCam)
- {
- aiNode* nd = *ppcChildren = new aiNode();
- nd->mName.Set("<NFF_Camera>");
- nd->mParent = root;
-
- // allocate the camera in the scene
- pScene->mNumCameras = 1;
- pScene->mCameras = new aiCamera*[1];
- aiCamera* c = pScene->mCameras[0] = new aiCamera;
-
- c->mName = nd->mName; // make sure the names are identical
- c->mHorizontalFOV = AI_DEG_TO_RAD( angle );
- c->mLookAt = camLookAt - camPos;
- c->mPosition = camPos;
- c->mUp = camUp;
-
- // If the resolution is not specified in the file, we
- // need to set 1.0 as aspect.
- c->mAspect = (!resolution.y ? 0.f : resolution.x / resolution.y);
- ++ppcChildren;
- }
-
- // generate light sources
- if (!lights.empty())
- {
- pScene->mNumLights = (unsigned int)lights.size();
- pScene->mLights = new aiLight*[pScene->mNumLights];
- for (unsigned int i = 0; i < pScene->mNumLights;++i,++ppcChildren)
- {
- const Light& l = lights[i];
-
- aiNode* nd = *ppcChildren = new aiNode();
- nd->mParent = root;
-
- nd->mName.length = ::sprintf(nd->mName.data,"<NFF_Light%i>",i);
-
- // allocate the light in the scene data structure
- aiLight* out = pScene->mLights[i] = new aiLight();
- out->mName = nd->mName; // make sure the names are identical
- out->mType = aiLightSource_POINT;
- out->mColorDiffuse = out->mColorSpecular = l.color * l.intensity;
- out->mPosition = l.position;
- }
- }
-
- if (!pScene->mNumMeshes)throw DeadlyImportError("NFF: No meshes loaded");
- pScene->mMeshes = new aiMesh*[pScene->mNumMeshes];
- pScene->mMaterials = new aiMaterial*[pScene->mNumMaterials = pScene->mNumMeshes];
- for (it = meshes.begin(), m = 0; it != end;++it)
- {
- if ((*it).faces.empty())continue;
-
- const MeshInfo& src = *it;
- aiMesh* const mesh = pScene->mMeshes[m] = new aiMesh();
- mesh->mNumVertices = (unsigned int)src.vertices.size();
- mesh->mNumFaces = (unsigned int)src.faces.size();
-
- // Generate sub nodes for named meshes
- if (src.name[0])
- {
- aiNode* const node = *ppcChildren = new aiNode();
- node->mParent = root;
- node->mNumMeshes = 1;
- node->mMeshes = new unsigned int[1];
- node->mMeshes[0] = m;
- node->mName.Set(src.name);
-
- // setup the transformation matrix of the node
- aiMatrix4x4::FromToMatrix(aiVector3D(0.f,1.f,0.f),
- src.dir,node->mTransformation);
-
- aiMatrix4x4& mat = node->mTransformation;
- mat.a1 *= src.radius.x; mat.b1 *= src.radius.x; mat.c1 *= src.radius.x;
- mat.a2 *= src.radius.y; mat.b2 *= src.radius.y; mat.c2 *= src.radius.y;
- mat.a3 *= src.radius.z; mat.b3 *= src.radius.z; mat.c3 *= src.radius.z;
- mat.a4 = src.center.x;
- mat.b4 = src.center.y;
- mat.c4 = src.center.z;
-
- ++ppcChildren;
- }
- else *pMeshes++ = m;
-
- // copy vertex positions
- mesh->mVertices = new aiVector3D[mesh->mNumVertices];
- ::memcpy(mesh->mVertices,&src.vertices[0],
- sizeof(aiVector3D)*mesh->mNumVertices);
-
- // NFF2: there could be vertex colors
- if (!src.colors.empty())
- {
- ai_assert(src.colors.size() == src.vertices.size());
-
- // copy vertex colors
- mesh->mColors[0] = new aiColor4D[mesh->mNumVertices];
- ::memcpy(mesh->mColors[0],&src.colors[0],
- sizeof(aiColor4D)*mesh->mNumVertices);
- }
-
- if (!src.normals.empty())
- {
- ai_assert(src.normals.size() == src.vertices.size());
-
- // copy normal vectors
- mesh->mNormals = new aiVector3D[mesh->mNumVertices];
- ::memcpy(mesh->mNormals,&src.normals[0],
- sizeof(aiVector3D)*mesh->mNumVertices);
- }
-
- if (!src.uvs.empty())
- {
- ai_assert(src.uvs.size() == src.vertices.size());
-
- // copy texture coordinates
- mesh->mTextureCoords[0] = new aiVector3D[mesh->mNumVertices];
- ::memcpy(mesh->mTextureCoords[0],&src.uvs[0],
- sizeof(aiVector3D)*mesh->mNumVertices);
- }
-
- // generate faces
- unsigned int p = 0;
- aiFace* pFace = mesh->mFaces = new aiFace[mesh->mNumFaces];
- for (std::vector<unsigned int>::const_iterator it2 = src.faces.begin(),
- end2 = src.faces.end();
- it2 != end2;++it2,++pFace)
- {
- pFace->mIndices = new unsigned int [ pFace->mNumIndices = *it2 ];
- for (unsigned int o = 0; o < pFace->mNumIndices;++o)
- pFace->mIndices[o] = p++;
- }
-
- // generate a material for the mesh
- aiMaterial* pcMat = (aiMaterial*)(pScene->mMaterials[m] = new aiMaterial());
-
- mesh->mMaterialIndex = m++;
-
- aiString s;
- s.Set(AI_DEFAULT_MATERIAL_NAME);
- pcMat->AddProperty(&s, AI_MATKEY_NAME);
-
- // FIX: Ignore diffuse == 0
- aiColor3D c = src.shader.color * (src.shader.diffuse.r ? src.shader.diffuse : aiColor3D(1.f,1.f,1.f));
- pcMat->AddProperty(&c,1,AI_MATKEY_COLOR_DIFFUSE);
- c = src.shader.color * src.shader.specular;
- pcMat->AddProperty(&c,1,AI_MATKEY_COLOR_SPECULAR);
-
- // NFF2 - default values for NFF
- pcMat->AddProperty(&src.shader.ambient, 1,AI_MATKEY_COLOR_AMBIENT);
- pcMat->AddProperty(&src.shader.emissive,1,AI_MATKEY_COLOR_EMISSIVE);
- pcMat->AddProperty(&src.shader.opacity, 1,AI_MATKEY_OPACITY);
-
- // setup the first texture layer, if existing
- if (src.shader.texFile.length())
- {
- s.Set(src.shader.texFile);
- pcMat->AddProperty(&s,AI_MATKEY_TEXTURE_DIFFUSE(0));
-
- if (aiTextureMapping_UV != src.shader.mapping) {
-
- aiVector3D v(0.f,-1.f,0.f);
- pcMat->AddProperty(&v, 1,AI_MATKEY_TEXMAP_AXIS_DIFFUSE(0));
- pcMat->AddProperty((int*)&src.shader.mapping, 1,AI_MATKEY_MAPPING_DIFFUSE(0));
- }
- }
-
- // setup the name of the material
- if (src.shader.name.length())
- {
- s.Set(src.shader.texFile);
- pcMat->AddProperty(&s,AI_MATKEY_NAME);
- }
-
- // setup some more material properties that are specific to NFF2
- int i;
- if (src.shader.twoSided)
- {
- i = 1;
- pcMat->AddProperty(&i,1,AI_MATKEY_TWOSIDED);
- }
- i = (src.shader.shaded ? aiShadingMode_Gouraud : aiShadingMode_NoShading);
- if (src.shader.shininess)
- {
- i = aiShadingMode_Phong;
- pcMat->AddProperty(&src.shader.shininess,1,AI_MATKEY_SHININESS);
- }
- pcMat->AddProperty(&i,1,AI_MATKEY_SHADING_MODEL);
- }
- pScene->mRootNode = root;
- }
-
- #endif // !! ASSIMP_BUILD_NO_NFF_IMPORTER
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