void FrontPentTest::testFindMain() { // Test the algorithm for finding main, when there is a call to __libc_start_main // Also tests the loader hack BinaryFileFactory bff; BinaryFile *pBF = bff.Load(FEDORA2_TRUE); CPPUNIT_ASSERT(pBF != NULL); Prog *prog = new Prog; FrontEnd *pFE = new PentiumFrontEnd(pBF, prog, &bff); prog->setFrontEnd(pFE); CPPUNIT_ASSERT(pFE != NULL); bool found; ADDRESS addr = pFE->getMainEntryPoint(found); ADDRESS expected = 0x8048b10; CPPUNIT_ASSERT_EQUAL(expected, addr); pBF->Close(); bff.UnLoad(); pBF = bff.Load(FEDORA3_TRUE); CPPUNIT_ASSERT(pBF != NULL); pFE = new PentiumFrontEnd(pBF, prog, &bff); prog->setFrontEnd(pFE); CPPUNIT_ASSERT(pFE != NULL); addr = pFE->getMainEntryPoint(found); expected = 0x8048c4a; CPPUNIT_ASSERT_EQUAL(expected, addr); pBF->Close(); bff.UnLoad(); pBF = bff.Load(SUSE_TRUE); CPPUNIT_ASSERT(pBF != NULL); pFE = new PentiumFrontEnd(pBF, prog, &bff); prog->setFrontEnd(pFE); CPPUNIT_ASSERT(pFE != NULL); addr = pFE->getMainEntryPoint(found); expected = 0x8048b60; CPPUNIT_ASSERT_EQUAL(expected, addr); pBF->Close(); delete pFE; }
/** * * @author OLiver */ bool Savegame::Save(const std::string& filename) { BinaryFile file; if(!file.Open(filename, OFM_WRITE)) return false; bool ret = Save(file); file.Close(); return ret; }
/** * * @author OLiver */ bool Savegame::Load(const std::string& filePath, const bool load_players, const bool load_sgd) { BinaryFile file; if(!file.Open(filePath, OFM_READ)) return false; bool ret = Load(file, load_players, load_sgd); file.Close(); return ret; }
bool AssimpModelImporter::ConvertToPyrosFormat(const std::string &Filename) { BinaryFile *bin = new BinaryFile(); if (bin->Open(Filename.c_str(), 'w')) { // Save Materials int32 materialsSize = materials.size(); bin->Write(&materialsSize, sizeof(int32)); for (std::vector<MaterialProperties>::iterator i=materials.begin();i!=materials.end();i++) { // Material ID bin->Write(&(*i).id,sizeof(int32)); // Material Name int32 nameSize = (*i).Name.size(); bin->Write(&nameSize,sizeof(int32)); if (nameSize>0) bin->Write((*i).Name.c_str(),sizeof(char)*nameSize); // Color uchar Out = (uchar)(*i).haveColor; bin->Write(&Out, sizeof(uchar)); bin->Write(&(*i).Color, sizeof(Vec4)); // Specular Out = (uchar)(*i).haveSpecular; bin->Write(&Out, sizeof(uchar)); bin->Write(&(*i).Specular, sizeof(Vec4)); // Ambient Out = (uchar)(*i).haveAmbient; bin->Write(&Out, sizeof(uchar)); bin->Write(&(*i).Ambient, sizeof(Vec4)); // Emissive Out = (uchar)(*i).haveEmissive; bin->Write(&Out, sizeof(uchar)); bin->Write(&(*i).Emissive, sizeof(Vec4)); // WireFrame Out = (uchar)(*i).WireFrame; bin->Write(&Out, sizeof(uchar)); // Twosided Out = (uchar)(*i).Twosided; bin->Write(&Out, sizeof(uchar)); // Opacity bin->Write(&(*i).Opacity,sizeof(f32)); // Shininess bin->Write(&(*i).Shininess,sizeof(f32)); // Shininess Strength bin->Write(&(*i).ShininessStrength,sizeof(f32)); // Textures // Color Map Out = (uchar)(*i).haveColorMap; bin->Write(&Out, sizeof(uchar)); int32 colorMapSize = (*i).colorMap.size(); bin->Write(&colorMapSize,sizeof(int32)); if (colorMapSize>0) bin->Write((*i).colorMap.c_str(),sizeof(char)*colorMapSize); // Specular Map Out = (uchar)(*i).haveSpecularMap; bin->Write(&Out, sizeof(uchar)); int32 specularMapSize = (*i).specularMap.size(); bin->Write(&specularMapSize,sizeof(int32)); if (specularMapSize>0) bin->Write((*i).specularMap.c_str(),sizeof(char)*specularMapSize); // Normal Map Out = (uchar)(*i).haveNormalMap; bin->Write(&Out, sizeof(uchar)); int32 normalMapSize = (*i).normalMap.size(); bin->Write(&normalMapSize,sizeof(int32)); if (normalMapSize>0) bin->Write((*i).normalMap.c_str(),sizeof(char)*normalMapSize); // Have Bones Out = (uchar)(*i).haveBones; bin->Write(&Out, sizeof(uchar)); } // Skeleton int32 skeletonSize = skeleton.size(); bin->Write(&skeletonSize,sizeof(int32)); if (skeletonSize>0) { // Write ids for (std::map<uint32, Bone>::iterator i=skeleton.begin();i!=skeleton.end();i++) { bin->Write(&(*i).first, sizeof(uint32)); // Name int32 nameSize = (*i).second.name.size(); bin->Write(&nameSize,sizeof(int32)); if (nameSize>0) bin->Write((*i).second.name.c_str(),sizeof(char)*nameSize); // Self bin->Write(&(*i).second.self, sizeof(int32)); // Parent bin->Write(&(*i).second.parent, sizeof(int32)); // Pos bin->Write(&(*i).second.pos, sizeof(Vec3)); // Rot bin->Write(&(*i).second.rot, sizeof(Quaternion)); // Scale bin->Write(&(*i).second.scale, sizeof(Vec3)); // BindPose bin->Write(&(*i).second.bindPoseMat.m[0], sizeof(Matrix)); // Skinned uchar Out = (uchar)(*i).second.skinned; bin->Write(&Out, sizeof(uchar)); } } // SubMeshes int32 subMeshesSize = subMeshes.size(); bin->Write(&subMeshesSize, sizeof(int32)); for (std::vector<SubMesh>::iterator i=subMeshes.begin();i!=subMeshes.end();i++) { // Name int32 nameSize = (*i).Name.size(); bin->Write(&nameSize,sizeof(int32)); if (nameSize>0) bin->Write((*i).Name.c_str(),sizeof(char)*nameSize); // Index int32 indexSize = (*i).tIndex.size(); bin->Write(&indexSize,sizeof(int32)); if (indexSize>0) bin->Write(&(*i).tIndex[0], sizeof(int32)*indexSize); // Vertex int32 vertexSize = (*i).tVertex.size(); bin->Write(&vertexSize,sizeof(int32)); if (vertexSize>0) bin->Write(&(*i).tVertex[0], sizeof(Vec3)*vertexSize); // Normal int32 normalSize = (*i).tNormal.size(); bin->Write(&normalSize,sizeof(int32)); if (normalSize>0) bin->Write(&(*i).tNormal[0], sizeof(Vec3)*normalSize); // Tangent int32 tangentSize = (*i).tTangent.size(); bin->Write(&tangentSize,sizeof(int32)); if (tangentSize>0) { bin->Write(&(*i).tTangent[0], sizeof(Vec3)*tangentSize); bin->Write(&(*i).tBitangent[0], sizeof(Vec3)*tangentSize); } // Texcoord int32 texcoordSize = (*i).tTexcoord.size(); bin->Write(&texcoordSize, sizeof(int32)); if (texcoordSize>0) bin->Write(&(*i).tTexcoord[0], sizeof(Vec2)*texcoordSize); // Vertex Color int32 vertexColorSize = (*i).tVertexColor.size(); bin->Write(&vertexColorSize, sizeof(int32)); if (vertexColorSize>0) bin->Write(&(*i).tVertexColor[0], sizeof(Vec4)*vertexColorSize); // Bones int32 BonesSize = (*i).tBonesID.size(); bin->Write(&BonesSize, sizeof(int32)); if (BonesSize>0) { bin->Write(&(*i).tBonesID[0], sizeof(Vec4)*BonesSize); bin->Write(&(*i).tBonesWeight[0], sizeof(Vec4)*BonesSize); } // Map Bones IDs int32 MapBoneIDsSize = (*i).MapBoneIDs.size(); bin->Write(&MapBoneIDsSize, sizeof(int32)); if (MapBoneIDsSize>0) { // Copy Index for (std::map<int32,int32>::iterator k=(*i).MapBoneIDs.begin();k!=(*i).MapBoneIDs.end();k++) { bin->Write(&(*k).first, sizeof(int32)); bin->Write(&(*k).second, sizeof(int32)); } } // Offset Matrix int32 BoneOffsetMatrixSize = (*i).BoneOffsetMatrix.size(); bin->Write(&BoneOffsetMatrixSize, sizeof(int32)); if (BoneOffsetMatrixSize>0) { // Copy Index for (std::map<int32,Matrix>::iterator k=(*i).BoneOffsetMatrix.begin();k!=(*i).BoneOffsetMatrix.end();k++) { bin->Write(&(*k).first, sizeof(int32)); bin->Write(&(*k).second.m[0], sizeof(Matrix)); } } // Material ID bin->Write(&(*i).materialID, sizeof(int32)); } bin->Close(); delete bin; return true; } else return false; }