diff --git a/src/rmodels.c b/src/rmodels.c index 966a8665..5fb51240 100644 --- a/src/rmodels.c +++ b/src/rmodels.c @@ -2016,6 +2016,8 @@ static void ProcessMaterialsOBJ(Material *materials, tinyobj_material_t *mats, i // NOTE: Uses default shader, which only supports MATERIAL_MAP_DIFFUSE materials[m] = LoadMaterialDefault(); + if (mats == NULL) continue; + // Get default texture, in case no texture is defined // NOTE: rlgl default texture is a 1x1 pixel UNCOMPRESSED_R8G8B8A8 materials[m].maps[MATERIAL_MAP_DIFFUSE].texture = (Texture2D){ rlGetTextureIdDefault(), 1, 1, 1, PIXELFORMAT_UNCOMPRESSED_R8G8B8A8 }; @@ -4073,130 +4075,236 @@ static void BuildPoseFromParentJoints(BoneInfo *bones, int boneCount, Transform // - the mesh is automatically triangulated by tinyobj static Model LoadOBJ(const char *fileName) { + tinyobj_attrib_t objAttributes = { 0 }; + tinyobj_shape_t* objShapes = NULL; + unsigned int objShapeCount = 0; + + tinyobj_material_t* objMaterials = NULL; + unsigned int objMaterialCount = 0; + Model model = { 0 }; + model.transform = MatrixIdentity(); - tinyobj_attrib_t attrib = { 0 }; - tinyobj_shape_t *meshes = NULL; - unsigned int meshCount = 0; + char* fileText = LoadFileText(fileName); - tinyobj_material_t *materials = NULL; - unsigned int materialCount = 0; - - char *fileText = LoadFileText(fileName); - - if (fileText != NULL) + if (fileText == NULL) { - unsigned int dataSize = (unsigned int)strlen(fileText); + TRACELOG(LOG_ERROR, "MODEL Unable to read obj file %s", fileName); + return model; + } - char currentDir[1024] = { 0 }; - strcpy(currentDir, GetWorkingDirectory()); // Save current working directory - const char *workingDir = GetDirectoryPath(fileName); // Switch to OBJ directory for material path correctness - if (CHDIR(workingDir) != 0) + char currentDir[1024] = { 0 }; + strcpy(currentDir, GetWorkingDirectory()); // Save current working directory + const char* workingDir = GetDirectoryPath(fileName); // Switch to OBJ directory for material path correctness + if (CHDIR(workingDir) != 0) + { + TRACELOG(LOG_WARNING, "MODEL: [%s] Failed to change working directory", workingDir); + } + + unsigned int dataSize = (unsigned int)strlen(fileText); + + unsigned int flags = TINYOBJ_FLAG_TRIANGULATE; + int ret = tinyobj_parse_obj(&objAttributes, &objShapes, &objShapeCount, &objMaterials, &objMaterialCount, fileText, dataSize, flags); + + if (ret != TINYOBJ_SUCCESS) + { + TRACELOG(LOG_ERROR, "MODEL Unable to read obj data %s", fileName); + return model; + } + + UnloadFileText(fileText); + + unsigned int faceVertIndex = 0; + unsigned int nextShape = 1; + int lastMaterial = -1; + unsigned int meshIndex = 0; + + // count meshes + unsigned int nextShapeEnd = objAttributes.num_face_num_verts; + + // see how many verts till the next shape + + if (objShapeCount > 1) nextShapeEnd = objShapes[nextShape].face_offset; + + // walk all the faces + for (unsigned int faceId = 0; faceId < objAttributes.num_faces; faceId++) + { + if (faceVertIndex >= nextShapeEnd) { - TRACELOG(LOG_WARNING, "MODEL: [%s] Failed to change working directory", workingDir); + // try to find the last vert in the next shape + nextShape++; + if (nextShape < objShapeCount) nextShapeEnd = objShapes[nextShape].face_offset; + else nextShapeEnd = objAttributes.num_face_num_verts; // this is actually the total number of face verts in the file, not faces + meshIndex++; + } + else if (lastMaterial != -1 && objAttributes.material_ids[faceId] != lastMaterial) + { + meshIndex++;// if this is a new material, we need to allocate a new mesh } - unsigned int flags = TINYOBJ_FLAG_TRIANGULATE; - int ret = tinyobj_parse_obj(&attrib, &meshes, &meshCount, &materials, &materialCount, fileText, dataSize, flags); + lastMaterial = objAttributes.material_ids[faceId]; + faceVertIndex += objAttributes.face_num_verts[faceId]; + } - if (ret != TINYOBJ_SUCCESS) TRACELOG(LOG_WARNING, "MODEL: [%s] Failed to load OBJ data", fileName); - else TRACELOG(LOG_INFO, "MODEL: [%s] OBJ data loaded successfully: %i meshes/%i materials", fileName, meshCount, materialCount); + // allocate the base meshes and materials + model.meshCount = meshIndex + 1; + model.meshes = (Mesh*)MemAlloc(sizeof(Mesh) * model.meshCount); - // WARNING: We are not splitting meshes by materials (previous implementation) - // Depending on the provided OBJ that was not the best option and it just crashed - // so, implementation was simplified to prioritize parsed meshes - model.meshCount = meshCount; + if (objMaterialCount > 0) + { + model.materialCount = objMaterialCount; + model.materials = (Material*)MemAlloc(sizeof(Material) * objMaterialCount); + } + else // we must allocate at least one material + { + model.materialCount = 1; + model.materials = (Material*)MemAlloc(sizeof(Material) * 1); + } - // Set number of materials available - // NOTE: There could be more materials available than meshes but it will be resolved at - // model.meshMaterial, just assigning the right material to corresponding mesh - model.materialCount = materialCount; - if (model.materialCount == 0) + model.meshMaterial = (int*)MemAlloc(sizeof(int) * model.meshCount); + + // see how many verts are in each mesh + unsigned int* localMeshVertexCounts = (unsigned int*)MemAlloc(sizeof(unsigned int) * model.meshCount); + + faceVertIndex = 0; + nextShapeEnd = objAttributes.num_face_num_verts; + lastMaterial = -1; + meshIndex = 0; + unsigned int localMeshVertexCount = 0; + + nextShape = 1; + if (objShapeCount > 1) + nextShapeEnd = objShapes[nextShape].face_offset; + + // walk all the faces + for (unsigned int faceId = 0; faceId < objAttributes.num_faces; faceId++) + { + bool newMesh = false; // do we need a new mesh? + if (faceVertIndex >= nextShapeEnd) { - model.materialCount = 1; - TRACELOG(LOG_INFO, "MODEL: No materials provided, setting one default material for all meshes"); + // try to find the last vert in the next shape + nextShape++; + if (nextShape < objShapeCount) nextShapeEnd = objShapes[nextShape].face_offset; + else nextShapeEnd = objAttributes.num_face_num_verts; // this is actually the total number of face verts in the file, not faces + + newMesh = true; } - else if (model.materialCount > 1 && model.meshCount > 1) + else if (lastMaterial != -1 && objAttributes.material_ids[faceId] != lastMaterial) { - // TEMP warning about multiple materials, to be removed when proper splitting code is implemented - // any obj with multiple materials will need to have it's materials assigned by the user in code to work at this time - TRACELOG(LOG_INFO, "MODEL: OBJ has multiple materials, manual material assignment will be required."); + newMesh = true; } - // Init model meshes and materials - model.meshes = (Mesh *)RL_CALLOC(model.meshCount, sizeof(Mesh)); - model.meshMaterial = (int *)RL_CALLOC(model.meshCount, sizeof(int)); // Material index assigned to each mesh - model.materials = (Material *)RL_CALLOC(model.materialCount, sizeof(Material)); + lastMaterial = objAttributes.material_ids[faceId]; - // Process each provided mesh - for (int i = 0; i < model.meshCount; i++) + if (newMesh) { - // WARNING: We need to calculate the mesh triangles manually using meshes[i].face_offset - // because in case of triangulated quads, meshes[i].length actually report quads, - // despite the triangulation that is efectively considered on attrib.num_faces - unsigned int tris = 0; - if (i == model.meshCount - 1) tris = attrib.num_faces - meshes[i].face_offset; - else tris = meshes[i + 1].face_offset; + localMeshVertexCounts[meshIndex] = localMeshVertexCount; - model.meshes[i].vertexCount = tris*3; - model.meshes[i].triangleCount = tris; // Face count (triangulated) - model.meshes[i].vertices = (float *)RL_CALLOC(model.meshes[i].vertexCount*3, sizeof(float)); - model.meshes[i].texcoords = (float *)RL_CALLOC(model.meshes[i].vertexCount*2, sizeof(float)); - model.meshes[i].normals = (float *)RL_CALLOC(model.meshes[i].vertexCount*3, sizeof(float)); - model.meshMaterial[i] = 0; // By default, assign material 0 to each mesh - - // Process all mesh faces - for (unsigned int face = 0, f = meshes[i].face_offset, v = 0, vt = 0, vn = 0; face < tris; face++, f++, v += 3, vt += 3, vn += 3) - { - // Get indices for the face - tinyobj_vertex_index_t idx0 = attrib.faces[f*3 + 0]; - tinyobj_vertex_index_t idx1 = attrib.faces[f*3 + 1]; - tinyobj_vertex_index_t idx2 = attrib.faces[f*3 + 2]; - - // Fill vertices buffer (float) using vertex index of the face - for (int n = 0; n < 3; n++) { model.meshes[i].vertices[v*3 + n] = attrib.vertices[idx0.v_idx*3 + n]; } - for (int n = 0; n < 3; n++) { model.meshes[i].vertices[(v + 1)*3 + n] = attrib.vertices[idx1.v_idx*3 + n]; } - for (int n = 0; n < 3; n++) { model.meshes[i].vertices[(v + 2)*3 + n] = attrib.vertices[idx2.v_idx*3 + n]; } - - if (attrib.num_texcoords > 0) - { - // Fill texcoords buffer (float) using vertex index of the face - // NOTE: Y-coordinate must be flipped upside-down - model.meshes[i].texcoords[vt*2 + 0] = attrib.texcoords[idx0.vt_idx*2 + 0]; - model.meshes[i].texcoords[vt*2 + 1] = 1.0f - attrib.texcoords[idx0.vt_idx*2 + 1]; - - model.meshes[i].texcoords[(vt + 1)*2 + 0] = attrib.texcoords[idx1.vt_idx*2 + 0]; - model.meshes[i].texcoords[(vt + 1)*2 + 1] = 1.0f - attrib.texcoords[idx1.vt_idx*2 + 1]; - - model.meshes[i].texcoords[(vt + 2)*2 + 0] = attrib.texcoords[idx2.vt_idx*2 + 0]; - model.meshes[i].texcoords[(vt + 2)*2 + 1] = 1.0f - attrib.texcoords[idx2.vt_idx*2 + 1]; - } - - if (attrib.num_normals > 0) - { - // Fill normals buffer (float) using vertex index of the face - for (int n = 0; n < 3; n++) { model.meshes[i].normals[vn*3 + n] = attrib.normals[idx0.vn_idx*3 + n]; } - for (int n = 0; n < 3; n++) { model.meshes[i].normals[(vn + 1)*3 + n] = attrib.normals[idx1.vn_idx*3 + n]; } - for (int n = 0; n < 3; n++) { model.meshes[i].normals[(vn + 2)*3 + n] = attrib.normals[idx2.vn_idx*3 + n]; } - } - } + localMeshVertexCount = 0; + meshIndex++; } - // Init model materials - if (materialCount > 0) ProcessMaterialsOBJ(model.materials, materials, materialCount); - else model.materials[0] = LoadMaterialDefault(); // Set default material for the mesh + faceVertIndex += objAttributes.face_num_verts[faceId]; + localMeshVertexCount += objAttributes.face_num_verts[faceId]; + } + localMeshVertexCounts[meshIndex] = localMeshVertexCount; - tinyobj_attrib_free(&attrib); - tinyobj_shapes_free(meshes, model.meshCount); - tinyobj_materials_free(materials, materialCount); + for (int i = 0; i < model.meshCount; i++) + { + // allocate the buffers for each mesh + unsigned int vertexCount = localMeshVertexCounts[i]; - UnloadFileText(fileText); + model.meshes[i].vertexCount = vertexCount; + model.meshes[i].triangleCount = vertexCount / 3; - // Restore current working directory - if (CHDIR(currentDir) != 0) + model.meshes[i].vertices = (float*)MemAlloc(sizeof(float) * vertexCount * 3); + model.meshes[i].normals = (float*)MemAlloc(sizeof(float) * vertexCount * 3); + model.meshes[i].texcoords = (float*)MemAlloc(sizeof(float) * vertexCount * 2); + model.meshes[i].colors = (unsigned char*)MemAlloc(sizeof(unsigned char) * vertexCount * 4); + } + + MemFree(localMeshVertexCounts); + localMeshVertexCounts = NULL; + + // fill meshes + faceVertIndex = 0; + + nextShapeEnd = objAttributes.num_face_num_verts; + + // see how many verts till the next shape + nextShape = 1; + if (objShapeCount > 1) nextShapeEnd = objShapes[nextShape].face_offset; + lastMaterial = -1; + meshIndex = 0; + localMeshVertexCount = 0; + + // walk all the faces + for (unsigned int faceId = 0; faceId < objAttributes.num_faces; faceId++) + { + bool newMesh = false; // do we need a new mesh? + if (faceVertIndex >= nextShapeEnd) { - TRACELOG(LOG_WARNING, "MODEL: [%s] Failed to change working directory", currentDir); + // try to find the last vert in the next shape + nextShape++; + if (nextShape < objShapeCount) nextShapeEnd = objShapes[nextShape].face_offset; + else nextShapeEnd = objAttributes.num_face_num_verts; // this is actually the total number of face verts in the file, not faces + newMesh = true; } + // if this is a new material, we need to allocate a new mesh + if (lastMaterial != -1 && objAttributes.material_ids[faceId] != lastMaterial) newMesh = true; + lastMaterial = objAttributes.material_ids[faceId];; + + if (newMesh) + { + localMeshVertexCount = 0; + meshIndex++; + } + + int matId = 0; + if (lastMaterial >= 0 && lastMaterial < (int)objMaterialCount) + matId = lastMaterial; + + model.meshMaterial[meshIndex] = matId; + + for (int f = 0; f < objAttributes.face_num_verts[faceId]; f++) + { + int vertIndex = objAttributes.faces[faceVertIndex].v_idx; + int normalIndex = objAttributes.faces[faceVertIndex].vn_idx; + int texcordIndex = objAttributes.faces[faceVertIndex].vt_idx; + + for (int i = 0; i < 3; i++) + model.meshes[meshIndex].vertices[localMeshVertexCount * 3 + i] = objAttributes.vertices[vertIndex * 3 + i]; + + for (int i = 0; i < 3; i++) + model.meshes[meshIndex].normals[localMeshVertexCount * 3 + i] = objAttributes.normals[normalIndex * 3 + i]; + + for (int i = 0; i < 2; i++) + model.meshes[meshIndex].texcoords[localMeshVertexCount * 2 + i] = objAttributes.texcoords[texcordIndex * 2 + i]; + + model.meshes[meshIndex].texcoords[localMeshVertexCount * 2 + 1] = 1.0f - model.meshes[meshIndex].texcoords[localMeshVertexCount * 2 + 1]; + + for (int i = 0; i < 4; i++) + model.meshes[meshIndex].colors[localMeshVertexCount * 4 + i] = 255; + + faceVertIndex++; + localMeshVertexCount++; + } + } + + if (objMaterialCount > 0) ProcessMaterialsOBJ(model.materials, objMaterials, objMaterialCount); + else model.materials[0] = LoadMaterialDefault(); // Set default material for the mesh + + tinyobj_attrib_free(&objAttributes); + tinyobj_shapes_free(objShapes, objShapeCount); + tinyobj_materials_free(objMaterials, objMaterialCount); + + for (int i = 0; i < model.meshCount; i++) + UploadMesh(model.meshes + i, true); + + // Restore current working directory + if (CHDIR(currentDir) != 0) + { + TRACELOG(LOG_WARNING, "MODEL: [%s] Failed to change working directory", currentDir); } return model;