/* --------------------------------------------------------------------------- Free Asset Import Library (ASSIMP) --------------------------------------------------------------------------- Copyright (c) 2006-2008, ASSIMP Development Team All rights reserved. Redistribution and use of this software in source and binary forms, with or without modification, are permitted provided that the 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 Development 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 PLY parser class */ #include "PLYLoader.h" #include "MaterialSystem.h" #include "fast_atof.h" #include "../include/IOStream.h" #include "../include/IOSystem.h" #include "../include/aiMesh.h" #include "../include/aiScene.h" #include "../include/aiAssert.h" #include using namespace Assimp; // ------------------------------------------------------------------------------------------------ PLY::EDataType PLY::Property::ParseDataType(const char* p_szIn,const char** p_szOut) { PLY::EDataType eOut = PLY::EDT_INVALID; if (0 == ASSIMP_strincmp(p_szIn,"char",4) || 0 == ASSIMP_strincmp(p_szIn,"int8",4)) { p_szIn+=4; eOut = PLY::EDT_Char; } else if (0 == ASSIMP_strincmp(p_szIn,"uchar",5) || 0 == ASSIMP_strincmp(p_szIn,"uint8",5)) { p_szIn+=5; eOut = PLY::EDT_UChar; } else if (0 == ASSIMP_strincmp(p_szIn,"short",5) || 0 == ASSIMP_strincmp(p_szIn,"int16",5)) { p_szIn+=5; eOut = PLY::EDT_Short; } else if (0 == ASSIMP_strincmp(p_szIn,"ushort",6) || 0 == ASSIMP_strincmp(p_szIn,"uint16",6)) { p_szIn+=6; eOut = PLY::EDT_UShort; } else if (0 == ASSIMP_strincmp(p_szIn,"int32",5)) { p_szIn+=5; eOut = PLY::EDT_Int; } else if (0 == ASSIMP_strincmp(p_szIn,"uint32",6)) { p_szIn+=6; eOut = PLY::EDT_UInt; } else if (0 == ASSIMP_strincmp(p_szIn,"int",3)) { p_szIn+=3; eOut = PLY::EDT_Int; } else if (0 == ASSIMP_strincmp(p_szIn,"uint",4)) { p_szIn+=4; eOut = PLY::EDT_UInt; } else if (0 == ASSIMP_strincmp(p_szIn,"float32",7)) { p_szIn+=7; eOut = PLY::EDT_Float; } else if (0 == ASSIMP_strincmp(p_szIn,"float",5)) { p_szIn+=5; eOut = PLY::EDT_Float; } else if (0 == ASSIMP_strincmp(p_szIn,"float64",7)) { p_szIn+=7; eOut = PLY::EDT_Double; } else if (0 == ASSIMP_strincmp(p_szIn,"double64",8)) { p_szIn+=8; eOut = PLY::EDT_Double; } else if (0 == ASSIMP_strincmp(p_szIn,"double",6)) { p_szIn+=6; eOut = PLY::EDT_Double; } // either end of line or space, but no other characters allowed if (!(IsSpace(*p_szIn) || IsLineEnd(*p_szIn))) { eOut = PLY::EDT_INVALID; } *p_szOut = p_szIn; return eOut; } // ------------------------------------------------------------------------------------------------ PLY::ESemantic PLY::Property::ParseSemantic(const char* p_szIn,const char** p_szOut) { PLY::ESemantic eOut = PLY::EST_INVALID; if (0 == ASSIMP_strincmp(p_szIn,"red",3)) { p_szIn+=3; eOut = PLY::EST_Red; } else if (0 == ASSIMP_strincmp(p_szIn,"green",4)) { p_szIn+=5; eOut = PLY::EST_Green; } else if (0 == ASSIMP_strincmp(p_szIn,"blue",4)) { p_szIn+=4; eOut = PLY::EST_Blue; } else if (0 == ASSIMP_strincmp(p_szIn,"alpha",5)) { p_szIn+=5; eOut = PLY::EST_Alpha; } else if (0 == ASSIMP_strincmp(p_szIn,"vertex_index",12)) { p_szIn+=12; eOut = PLY::EST_VertexIndex; } else if (0 == ASSIMP_strincmp(p_szIn,"vertex_indices",14)) { p_szIn+=14; eOut = PLY::EST_VertexIndex; } else if (0 == ASSIMP_strincmp(p_szIn,"material_index",14)) { p_szIn+=14; eOut = PLY::EST_MaterialIndex; } else if (0 == ASSIMP_strincmp(p_szIn,"ambient_red",11)) { p_szIn+=11; eOut = PLY::EST_AmbientRed; } else if (0 == ASSIMP_strincmp(p_szIn,"ambient_green",13)) { p_szIn+=13; eOut = PLY::EST_AmbientGreen; } else if (0 == ASSIMP_strincmp(p_szIn,"ambient_blue",12)) { p_szIn+=12; eOut = PLY::EST_AmbientBlue; } else if (0 == ASSIMP_strincmp(p_szIn,"ambient_alpha",13)) { p_szIn+=13; eOut = PLY::EST_AmbientAlpha; } else if (0 == ASSIMP_strincmp(p_szIn,"diffuse_red",11)) { p_szIn+=11; eOut = PLY::EST_DiffuseRed; } else if (0 == ASSIMP_strincmp(p_szIn,"diffuse_green",13)) { p_szIn+=13; eOut = PLY::EST_DiffuseGreen; } else if (0 == ASSIMP_strincmp(p_szIn,"diffuse_blue",12)) { p_szIn+=12; eOut = PLY::EST_DiffuseBlue; } else if (0 == ASSIMP_strincmp(p_szIn,"diffuse_alpha",13)) { p_szIn+=13; eOut = PLY::EST_DiffuseAlpha; } else if (0 == ASSIMP_strincmp(p_szIn,"specular_red",12)) { p_szIn+=12; eOut = PLY::EST_SpecularRed; } else if (0 == ASSIMP_strincmp(p_szIn,"specular_green",14)) { p_szIn+=14; eOut = PLY::EST_SpecularGreen; } else if (0 == ASSIMP_strincmp(p_szIn,"specular_blue",13)) { p_szIn+=13; eOut = PLY::EST_SpecularBlue; } else if (0 == ASSIMP_strincmp(p_szIn,"specular_alpha",14)) { p_szIn+=14; eOut = PLY::EST_SpecularAlpha; } else if (0 == ASSIMP_strincmp(p_szIn,"opacity",7)) { p_szIn+=7; eOut = PLY::EST_Opacity; } else if (0 == ASSIMP_strincmp(p_szIn,"specular_power",6)) { p_szIn+=7; eOut = PLY::EST_PhongPower; } else if (0 == ASSIMP_strincmp(p_szIn,"r",1)) { p_szIn++; eOut = PLY::EST_Red; } else if (0 == ASSIMP_strincmp(p_szIn,"g",1)) { p_szIn++; eOut = PLY::EST_Green; } else if (0 == ASSIMP_strincmp(p_szIn,"b",1)) { p_szIn++; eOut = PLY::EST_Blue; } else if (0 == ASSIMP_strincmp(p_szIn,"tx",2)) { p_szIn+=2; eOut = PLY::EST_UTextureCoord; } else if (0 == ASSIMP_strincmp(p_szIn,"ty",2)) { p_szIn+=2; eOut = PLY::EST_VTextureCoord; } else if (0 == ASSIMP_strincmp(p_szIn,"u",1)) { p_szIn++; eOut = PLY::EST_UTextureCoord; } else if (0 == ASSIMP_strincmp(p_szIn,"v",1)) { p_szIn++; eOut = PLY::EST_VTextureCoord; } else if (0 == ASSIMP_strincmp(p_szIn,"x",1)) { p_szIn++; eOut = PLY::EST_XCoord; } else if (0 == ASSIMP_strincmp(p_szIn,"y",1)) { p_szIn++; eOut = PLY::EST_YCoord; } else if (0 == ASSIMP_strincmp(p_szIn,"z",1)) { p_szIn++; eOut = PLY::EST_ZCoord; } else { // ... find the next space or new line while (*p_szIn != ' ' && *p_szIn != '\t' && *p_szIn != '\r' && *p_szIn != '\0' && *p_szIn != '\n')p_szIn++; } // either end of line or space, but no other characters allowed if (!(IsSpace(*p_szIn) || IsLineEnd(*p_szIn))) { eOut = PLY::EST_INVALID; } *p_szOut = p_szIn; return eOut; } // ------------------------------------------------------------------------------------------------ bool PLY::Property::ParseProperty (const char* p_szIn, const char** p_szOut, PLY::Property* pOut) { // Forms supported: // "property float x" // "property list uchar int vertex_index" *p_szOut = p_szIn; // skip leading spaces if (!SkipSpaces(p_szIn,&p_szIn))return false; // skip the "property" string at the beginning if (0 != ASSIMP_strincmp(p_szIn,"property",8) || !IsSpace(*(p_szIn+8))) { // seems not to be a valid property entry return false; } // get next word p_szIn += 9; if (!SkipSpaces(p_szIn,&p_szIn))return false; if (0 == ASSIMP_strincmp(p_szIn,"list",4) && IsSpace(*(p_szIn+4))) { pOut->bIsList = true; // seems to be a list. p_szIn += 5; if(EDT_INVALID == (pOut->eFirstType = PLY::Property::ParseDataType(p_szIn, &p_szIn))) { // unable to parse list size data type SkipLine(p_szIn,&p_szIn); *p_szOut = p_szIn; return false; } if (!SkipSpaces(p_szIn,&p_szIn))return false; if(EDT_INVALID == (pOut->eType = PLY::Property::ParseDataType(p_szIn, &p_szIn))) { // unable to parse list data type SkipLine(p_szIn,&p_szIn); *p_szOut = p_szIn; return false; } } else { if(EDT_INVALID == (pOut->eType = PLY::Property::ParseDataType(p_szIn, &p_szIn))) { // unable to parse data type. Skip the property SkipLine(p_szIn,&p_szIn); *p_szOut = p_szIn; return false; } } if (!SkipSpaces(p_szIn,&p_szIn))return false; const char* szCur = p_szIn; pOut->Semantic = PLY::Property::ParseSemantic(p_szIn, &p_szIn); if (PLY::EST_INVALID == pOut->Semantic) { // store the name of the semantic uintptr_t iDiff = (uintptr_t)p_szIn - (uintptr_t)szCur; pOut->szName = std::string(szCur,iDiff); } SkipSpacesAndLineEnd(p_szIn,&p_szIn); *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ PLY::EElementSemantic PLY::Element::ParseSemantic(const char* p_szIn, const char** p_szOut) { PLY::EElementSemantic eOut = PLY::EEST_INVALID; if (0 == ASSIMP_strincmp(p_szIn,"vertex",6)) { p_szIn+=6; eOut = PLY::EEST_Vertex; } else if (0 == ASSIMP_strincmp(p_szIn,"face",4)) { p_szIn+=4; eOut = PLY::EEST_Face; } #if 0 else if (0 == ASSIMP_strincmp(p_szIn,"range_grid",10)) { p_szIn+=10; eOut = PLY::EEST_Face; } #endif else if (0 == ASSIMP_strincmp(p_szIn,"tristrips",9)) { p_szIn+=9; eOut = PLY::EEST_TriStrip; } else if (0 == ASSIMP_strincmp(p_szIn,"edge",4)) { p_szIn+=4; eOut = PLY::EEST_Edge; } else if (0 == ASSIMP_strincmp(p_szIn,"material",8)) { p_szIn+=8; eOut = PLY::EEST_Material; } // either end of line or space, but no other characters allowed if (!(IsSpace(*p_szIn) || IsLineEnd(*p_szIn))) { eOut = PLY::EEST_INVALID; } *p_szOut = p_szIn; return eOut; } // ------------------------------------------------------------------------------------------------ bool PLY::Element::ParseElement (const char* p_szIn, const char** p_szOut, PLY::Element* pOut) { // Example format: "element vertex 8" *p_szOut = p_szIn; // skip leading spaces if (!SkipSpaces(p_szIn,&p_szIn))return false; // skip the "element" string at the beginning if (0 != ASSIMP_strincmp(p_szIn,"element",7) || !IsSpace(*(p_szIn+7))) { // seems not to be a valid property entry return false; } // get next word p_szIn += 8; if (!SkipSpaces(p_szIn,&p_szIn))return false; // parse the semantic of the element const char* szCur = p_szIn; pOut->eSemantic = PLY::Element::ParseSemantic(p_szIn,&p_szIn); if (PLY::EEST_INVALID == pOut->eSemantic) { // store the name of the semantic uintptr_t iDiff = (uintptr_t)p_szIn - (uintptr_t)szCur; pOut->szName = std::string(szCur,iDiff); } if (!SkipSpaces(p_szIn,&p_szIn))return false; //parse the number of occurences of this element pOut->NumOccur = strtol10(p_szIn,&p_szIn); // go to the next line SkipSpacesAndLineEnd(p_szIn,&p_szIn); // now parse all properties of the element while(true) { // skip all comments PLY::DOM::SkipComments(p_szIn,&p_szIn); PLY::Property* prop = new PLY::Property(); if(!PLY::Property::ParseProperty(p_szIn,&p_szIn,prop))break; // add the property to the property list pOut->alProperties.push_back(prop); } *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ bool PLY::DOM::SkipComments (const char* p_szIn, const char** p_szOut) { *p_szOut = p_szIn; // skip spaces if (!SkipSpaces(p_szIn,&p_szIn))return false; if (0 == ASSIMP_strincmp(p_szIn,"comment",7)) { p_szIn += 7; SkipLine(p_szIn,&p_szIn); SkipComments(p_szIn,&p_szIn); *p_szOut = p_szIn; return true; } return false; } // ------------------------------------------------------------------------------------------------ bool PLY::DOM::ParseHeader (const char* p_szIn,const char** p_szOut) { // after ply and format line *p_szOut = p_szIn; // parse all elements while (true) { // skip all comments PLY::DOM::SkipComments(p_szIn,&p_szIn); PLY::Element* out = new PLY::Element(); if(PLY::Element::ParseElement(p_szIn,&p_szIn,out)) { // add the element to the list of elements this->alElements.push_back(out); } else if (0 == ASSIMP_strincmp(p_szIn,"end_header",10) && IsSpaceOrNewLine(*(p_szIn+10))) { // we have reached the end of the header p_szIn += 11; break; } // ignore unknown header elements } SkipSpacesAndLineEnd(p_szIn,&p_szIn); *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ bool PLY::DOM::ParseElementInstanceLists ( const char* p_szIn, const char** p_szOut) { this->alElementData.resize(this->alElements.size()); std::vector::const_iterator i = this->alElements.begin(); std::vector::iterator a = this->alElementData.begin(); // parse all element instances for (;i != this->alElements.end();++i,++a) { *a = new PLY::ElementInstanceList((*i)); // reserve enough storage PLY::ElementInstanceList::ParseInstanceList(p_szIn,&p_szIn,(*i),(*a)); } return true; } // ------------------------------------------------------------------------------------------------ bool PLY::DOM::ParseElementInstanceListsBinary ( const char* p_szIn, const char** p_szOut, bool p_bBE) { this->alElementData.resize(this->alElements.size()); std::vector::const_iterator i = this->alElements.begin(); std::vector::iterator a = this->alElementData.begin(); // parse all element instances for (;i != this->alElements.end();++i,++a) { *a = new PLY::ElementInstanceList((*i)); // reserve enough storage PLY::ElementInstanceList::ParseInstanceListBinary(p_szIn,&p_szIn,(*i),(*a),p_bBE); } return true; } // ------------------------------------------------------------------------------------------------ bool PLY::DOM::ParseInstanceBinary (const char* p_szIn,DOM* p_pcOut,bool p_bBE) { if(!p_pcOut->ParseHeader(p_szIn,&p_szIn)) { return false; } if(!p_pcOut->ParseElementInstanceListsBinary(p_szIn,&p_szIn,p_bBE)) { return false; } return true; } // ------------------------------------------------------------------------------------------------ bool PLY::DOM::ParseInstance (const char* p_szIn,DOM* p_pcOut) { if(!p_pcOut->ParseHeader(p_szIn,&p_szIn)) { return false; } if(!p_pcOut->ParseElementInstanceLists(p_szIn,&p_szIn)) { return false; } return true; } // ------------------------------------------------------------------------------------------------ bool PLY::ElementInstanceList::ParseInstanceList (const char* p_szIn,const char** p_szOut, const PLY::Element* pcElement, PLY::ElementInstanceList* p_pcOut) { if (EEST_INVALID == pcElement->eSemantic) { // if the element has an unknown semantic we can skip all lines // However, there could be comments for (unsigned int i = 0; i < pcElement->NumOccur;++i) { PLY::DOM::SkipComments(p_szIn,&p_szIn); SkipLine(p_szIn,&p_szIn); } } else { // be sure to have enough storage p_pcOut->alInstances.resize(pcElement->NumOccur); for (unsigned int i = 0; i < pcElement->NumOccur;++i) { PLY::DOM::SkipComments(p_szIn,&p_szIn); PLY::ElementInstance* out = new PLY::ElementInstance(); PLY::ElementInstance::ParseInstance(p_szIn, &p_szIn,pcElement, out); // add it to the list p_pcOut->alInstances[i] = out; } } *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ bool PLY::ElementInstanceList::ParseInstanceListBinary ( const char* p_szIn, const char** p_szOut, const PLY::Element* pcElement, PLY::ElementInstanceList* p_pcOut, bool p_bBE /* = false */) { // we can add special handling code for unknown element semantics since // we can't skip it as a whole block (we don't know its exact size // due to the fact that lists could be contained in the property list // of the unknown element) for (unsigned int i = 0; i < pcElement->NumOccur;++i) { PLY::ElementInstance* out = new PLY::ElementInstance(); PLY::ElementInstance::ParseInstanceBinary(p_szIn, &p_szIn,pcElement, out, p_bBE); // add it to the list p_pcOut->alInstances[i] = out; } *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ bool PLY::ElementInstance::ParseInstance ( const char* p_szIn, const char** p_szOut, const PLY::Element* pcElement, PLY::ElementInstance* p_pcOut) { if (!SkipSpaces(p_szIn, &p_szIn))return false; // allocate enough storage p_pcOut->alProperties.resize(pcElement->alProperties.size()); *p_szOut = p_szIn; std::vector::iterator i = p_pcOut->alProperties.begin(); std::vector::const_iterator a = pcElement->alProperties.begin(); for (;i != p_pcOut->alProperties.end();++i,++a) { if(!(PLY::PropertyInstance::ParseInstance(p_szIn, &p_szIn,(*a),&(*i)))) { // skip the rest of the instance SkipLine(p_szIn, &p_szIn); PLY::PropertyInstance::ValueUnion v = PLY::PropertyInstance::DefaultValue((*a)->eType); (*i).avList.push_back(v); } } *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ bool PLY::ElementInstance::ParseInstanceBinary ( const char* p_szIn, const char** p_szOut, const PLY::Element* pcElement, PLY::ElementInstance* p_pcOut, bool p_bBE /* = false */) { // allocate enough storage p_pcOut->alProperties.resize(pcElement->alProperties.size()); *p_szOut = p_szIn; std::vector::iterator i = p_pcOut->alProperties.begin(); std::vector::const_iterator a = pcElement->alProperties.begin(); for (;i != p_pcOut->alProperties.end();++i,++a) { if(!(PLY::PropertyInstance::ParseInstance(p_szIn, &p_szIn,(*a),&(*i)))) { PLY::PropertyInstance::ValueUnion v = PLY::PropertyInstance::DefaultValue((*a)->eType); (*i).avList.push_back(v); } } *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ bool PLY::PropertyInstance::ParseInstance (const char* p_szIn,const char** p_szOut, const PLY::Property* prop, PLY::PropertyInstance* p_pcOut) { *p_szOut = p_szIn; // skip spaces at the beginning if (!SkipSpaces(p_szIn, &p_szIn))return false; if (prop->bIsList) { // parse the number of elements in the list PLY::PropertyInstance::ValueUnion v; PLY::PropertyInstance::ParseValue(p_szIn, &p_szIn,prop->eFirstType,&v); // convert to unsigned int unsigned int iNum = PLY::PropertyInstance::ConvertTo(v,prop->eFirstType); // parse all list elements for (unsigned int i = 0; i < iNum;++i) { if (!SkipSpaces(p_szIn, &p_szIn))return false; PLY::PropertyInstance::ParseValue(p_szIn, &p_szIn,prop->eType,&v); p_pcOut->avList.push_back(v); } } else { // parse the property PLY::PropertyInstance::ValueUnion v; PLY::PropertyInstance::ParseValue(p_szIn, &p_szIn,prop->eType,&v); p_pcOut->avList.push_back(v); } SkipSpacesAndLineEnd(p_szIn, &p_szIn); *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ bool PLY::PropertyInstance::ParseInstanceBinary (const char* p_szIn,const char** p_szOut, const PLY::Property* prop, PLY::PropertyInstance* p_pcOut,bool p_bBE) { *p_szOut = p_szIn; if (prop->bIsList) { // parse the number of elements in the list PLY::PropertyInstance::ValueUnion v; PLY::PropertyInstance::ParseValueBinary(p_szIn, &p_szIn,prop->eFirstType,&v,p_bBE); // convert to unsigned int unsigned int iNum = PLY::PropertyInstance::ConvertTo(v,prop->eFirstType); // parse all list elements for (unsigned int i = 0; i < iNum;++i) { PLY::PropertyInstance::ParseValueBinary(p_szIn, &p_szIn,prop->eType,&v,p_bBE); p_pcOut->avList.push_back(v); } } else { // parse the property PLY::PropertyInstance::ValueUnion v; PLY::PropertyInstance::ParseValueBinary(p_szIn, &p_szIn,prop->eType,&v,p_bBE); p_pcOut->avList.push_back(v); } *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ PLY::PropertyInstance::ValueUnion PLY::PropertyInstance::DefaultValue( PLY::EDataType eType) { PLY::PropertyInstance::ValueUnion out; switch (eType) { case EDT_Float: out.fFloat = 0.0f; return out; case EDT_Double: out.fDouble = 0.0; return out; }; out.iUInt = 0; return out; } // ------------------------------------------------------------------------------------------------ bool PLY::PropertyInstance::ParseValue(const char* p_szIn,const char** p_szOut, PLY::EDataType eType,PLY::PropertyInstance::ValueUnion* out) { *p_szOut = p_szIn; switch (eType) { case EDT_UInt: case EDT_UShort: case EDT_UChar: // simply parse in a full uint out->iUInt = (uint32_t)strtol10(p_szIn, &p_szIn); break; case EDT_Int: case EDT_Short: case EDT_Char: { // simply parse in a full int // Take care of the sign at the beginning bool bMinus = false; if (*p_szIn == '-') { p_szIn++; bMinus = true; } out->iInt = (int32_t)strtol10(p_szIn, &p_szIn); if (bMinus)out->iInt *= -1; break; } case EDT_Float: // parse a simple float p_szIn = fast_atof_move(p_szIn,out->fFloat); break; case EDT_Double: // Parse a double float. .. TODO: support this float f; p_szIn = fast_atof_move(p_szIn,f); out->fDouble = (double)f; default: return false; } *p_szOut = p_szIn; return true; } // ------------------------------------------------------------------------------------------------ bool PLY::PropertyInstance::ParseValueBinary(const char* p_szIn,const char** p_szOut, PLY::EDataType eType,PLY::PropertyInstance::ValueUnion* out, bool p_bBE) { *p_szOut = p_szIn; switch (eType) { case EDT_UInt: out->iUInt = (uint32_t)*((uint32_t*)p_szIn); p_szIn += 4; if (p_bBE) { std::swap(((unsigned char*)(&out->iUInt))[0],((unsigned char*)(&out->iUInt))[3]); std::swap(((unsigned char*)(&out->iUInt))[1],((unsigned char*)(&out->iUInt))[2]); } break; case EDT_UShort: { uint16_t i = *((uint16_t*)p_szIn); if (p_bBE) { std::swap(((unsigned char*)(&i))[0],((unsigned char*)(&i))[1]); } out->iUInt = (uint32_t)i; p_szIn += 2; break; } case EDT_UChar: { uint8_t i = *((uint8_t*)p_szIn); out->iUInt = (uint32_t)i; p_szIn += 2; break; } case EDT_Int: out->iInt = *((int32_t*)p_szIn); p_szIn += 4; if (p_bBE) { std::swap(((unsigned char*)(&out->iInt))[0],((unsigned char*)(&out->iInt))[3]); std::swap(((unsigned char*)(&out->iInt))[1],((unsigned char*)(&out->iInt))[2]); } break; case EDT_Short: { int16_t i = *((int16_t*)p_szIn); if (p_bBE) { std::swap(((unsigned char*)(&i))[0],((unsigned char*)(&i))[1]); } out->iInt = (int32_t)i; p_szIn += 2; break; } case EDT_Char: out->iInt = (int32_t)*((int8_t*)p_szIn); p_szIn += 1; break; case EDT_Float: if (p_bBE) { union {char szArray[4]; float fValue; } _X; _X.szArray[0] = ((unsigned char*)p_szIn)[3]; _X.szArray[1] = ((unsigned char*)p_szIn)[2]; _X.szArray[2] = ((unsigned char*)p_szIn)[1]; _X.szArray[3] = ((unsigned char*)p_szIn)[0]; out->fFloat = _X.fValue; } else out->fFloat = *((float*)p_szIn); p_szIn += 4; break; case EDT_Double: if (p_bBE) { union {char szArray[8]; double fValue; } _X; _X.szArray[0] = ((unsigned char*)p_szIn)[7]; _X.szArray[1] = ((unsigned char*)p_szIn)[6]; _X.szArray[2] = ((unsigned char*)p_szIn)[5]; _X.szArray[3] = ((unsigned char*)p_szIn)[4]; _X.szArray[4] = ((unsigned char*)p_szIn)[3]; _X.szArray[5] = ((unsigned char*)p_szIn)[2]; _X.szArray[6] = ((unsigned char*)p_szIn)[1]; _X.szArray[7] = ((unsigned char*)p_szIn)[0]; out->fDouble = _X.fValue; } else out->fDouble = *((double*)p_szIn); p_szIn += 8; break; default: return false; } *p_szOut = p_szIn; return true; }