#ifdef SLIC3R_PRUS #include #include #include #include #include #include #include "../libslic3r.h" #include "../Model.hpp" #include "PRUS.hpp" #if 0 // Enable debugging and assert in this file. #define DEBUG #define _DEBUG #undef NDEBUG #endif #include namespace Slic3r { struct StlHeader { char comment[80]; uint32_t nTriangles; }; static_assert(sizeof(StlHeader) == 84, "StlHeader size not correct"); // Buffered line reader for the wxInputStream. class LineReader { public: LineReader(wxInputStream &input_stream, const char *initial_data, int initial_len) : m_input_stream(input_stream), m_pos(0), m_len(initial_len) { assert(initial_len >= 0 && initial_len < m_bufsize); memcpy(m_buffer, initial_data, initial_len); } const char* next_line() { for (;;) { // Skip empty lines. while (m_pos < m_len && (m_buffer[m_pos] == '\r' || m_buffer[m_pos] == '\n')) ++ m_pos; if (m_pos == m_len) { // Empty buffer, fill it from the input stream. m_pos = 0; m_input_stream.Read(m_buffer, m_bufsize - 1); m_len = m_input_stream.LastRead(); assert(m_len >= 0 && m_len < m_bufsize); if (m_len == 0) // End of file. return nullptr; // Skip empty lines etc. continue; } // The buffer is nonempty and it does not start with end of lines. Find the first end of line. int end = m_pos + 1; while (end < m_len && m_buffer[end] != '\r' && m_buffer[end] != '\n') ++ end; if (end == m_len && ! m_input_stream.Eof() && m_len < m_bufsize) { // Move the buffer content to the buffer start and fill the rest of the buffer. assert(m_pos > 0); memmove(m_buffer, m_buffer + m_pos, m_len - m_pos); m_len -= m_pos; assert(m_len >= 0 && m_len < m_bufsize); m_pos = 0; m_input_stream.Read(m_buffer + m_len, m_bufsize - 1 - m_len); int new_data = m_input_stream.LastRead(); if (new_data > 0) { m_len += new_data; assert(m_len >= 0 && m_len < m_bufsize); continue; } } char *ptr_out = m_buffer + m_pos; m_pos = end + 1; m_buffer[end] = 0; if (m_pos >= m_len) { m_pos = 0; m_len = 0; } return ptr_out; } } int next_line_scanf(const char *format, ...) { const char *line = next_line(); if (line == nullptr) return -1; int result; va_list arglist; va_start(arglist, format); result = vsscanf(line, format, arglist); va_end(arglist); return result; } private: wxInputStream &m_input_stream; static const int m_bufsize = 4096; char m_buffer[m_bufsize]; int m_pos = 0; int m_len = 0; }; // Load a PrusaControl project file into a provided model. bool load_prus(const char *path, Model *model) { // To receive the content of the zipped 'scene.xml' file. std::vector scene_xml_data; wxFFileInputStream in( #ifdef WIN32 // On Windows, convert to a 16bit unicode string. boost::nowide::widen(path).c_str() #else path #endif ); wxZipInputStream zip(in); std::unique_ptr entry; size_t num_models = 0; std::map group_to_model_object; while (entry.reset(zip.GetNextEntry()), entry.get() != NULL) { wxString name = entry->GetName(); if (name == "scene.xml") { if (! scene_xml_data.empty()) { // scene.xml has been found more than once in the archive. return false; } size_t size_last = 0; size_t size_incr = 4096; scene_xml_data.resize(size_incr); while (! zip.Read(scene_xml_data.data() + size_last, size_incr).Eof()) { size_last += zip.LastRead(); if (scene_xml_data.size() < size_last + size_incr) scene_xml_data.resize(size_last + size_incr); } size_last += zip.LastRead(); if (scene_xml_data.size() == size_last) scene_xml_data.resize(size_last + 1); else if (scene_xml_data.size() > size_last + 1) scene_xml_data.erase(scene_xml_data.begin() + size_last + 1, scene_xml_data.end()); scene_xml_data[size_last] = 0; } else if (name.EndsWith(".stl") || name.EndsWith(".STL")) { // Find the model entry in the XML data. const wxScopedCharBuffer name_utf8 = name.ToUTF8(); char model_name_tag[1024]; sprintf(model_name_tag, "", name_utf8.data()); const char *model_xml = strstr(scene_xml_data.data(), model_name_tag); const char *zero_tag = ""; const char *zero_xml = strstr(scene_xml_data.data(), zero_tag); float trafo[3][4] = { 0 }; double instance_rotation = 0.; double instance_scaling_factor = 1.f; Pointf instance_offset(0., 0.); bool trafo_set = false; unsigned int group_id = (unsigned int)-1; unsigned int extruder_id = (unsigned int)-1; ModelObject *model_object = nullptr; if (model_xml != nullptr) { model_xml += strlen(model_name_tag); const char *position_tag = ""; const char *position_xml = strstr(model_xml, position_tag); const char *rotation_tag = ""; const char *rotation_xml = strstr(model_xml, rotation_tag); const char *scale_tag = ""; const char *scale_xml = strstr(model_xml, scale_tag); float position[3], rotation[3], scale[3], zero[3]; if (position_xml != nullptr && rotation_xml != nullptr && scale_xml != nullptr && zero_xml != nullptr && sscanf(position_xml+strlen(position_tag), "[%f, %f, %f]", position, position+1, position+2) == 3 && sscanf(rotation_xml+strlen(rotation_tag), "[%f, %f, %f]", rotation, rotation+1, rotation+2) == 3 && sscanf(scale_xml+strlen(scale_tag), "[%f, %f, %f]", scale, scale+1, scale+2) == 3 && sscanf(zero_xml+strlen(zero_tag), "[%f, %f, %f]", zero, zero+1, zero+2) == 3) { if (scale[0] == scale[1] && scale[1] == scale[2]) { instance_scaling_factor = scale[0]; scale[0] = scale[1] = scale[2] = 1.; } if (rotation[0] == 0. && rotation[1] == 0.) { instance_rotation = - rotation[2]; rotation[2] = 0.; } Eigen::Matrix3f mat_rot, mat_scale, mat_trafo; mat_rot = Eigen::AngleAxisf(-rotation[2], Eigen::Vector3f::UnitZ()) * Eigen::AngleAxisf(-rotation[1], Eigen::Vector3f::UnitY()) * Eigen::AngleAxisf(-rotation[0], Eigen::Vector3f::UnitX()); mat_scale = Eigen::Scaling(scale[0], scale[1], scale[2]); mat_trafo = mat_rot * mat_scale; for (size_t r = 0; r < 3; ++ r) { for (size_t c = 0; c < 3; ++ c) trafo[r][c] += mat_trafo(r, c); } instance_offset.x = position[0] - zero[0]; instance_offset.y = position[1] - zero[1]; trafo[2][3] = position[2] / instance_scaling_factor; trafo_set = true; } const char *group_tag = ""; const char *group_xml = strstr(model_xml, group_tag); const char *extruder_tag = ""; const char *extruder_xml = strstr(model_xml, extruder_tag); if (group_xml != nullptr) { int group = atoi(group_xml + strlen(group_tag)); if (group > 0) { group_id = group; auto it = group_to_model_object.find(group_id); if (it != group_to_model_object.end()) model_object = it->second; } } if (extruder_xml != nullptr) { int e = atoi(extruder_xml + strlen(extruder_tag)); if (e > 0) extruder_id = e; } } if (trafo_set) { // Extract the STL. StlHeader header; TriangleMesh mesh; bool mesh_valid = false; bool stl_ascii = false; if (!zip.Read((void*)&header, sizeof(StlHeader)).Eof()) { if (strncmp(header.comment, "solid ", 6) == 0) stl_ascii = true; else { // Header has been extracted. Now read the faces. stl_file &stl = mesh.stl; stl.error = 0; stl.stats.type = inmemory; stl.stats.number_of_facets = header.nTriangles; stl.stats.original_num_facets = header.nTriangles; stl_allocate(&stl); if (header.nTriangles > 0 && zip.ReadAll((void*)stl.facet_start, 50 * header.nTriangles)) { if (sizeof(stl_facet) > SIZEOF_STL_FACET) { // The stl.facet_start is not packed tightly. Unpack the array of stl_facets. unsigned char *data = (unsigned char*)stl.facet_start; for (size_t i = header.nTriangles - 1; i > 0; -- i) memmove(data + i * sizeof(stl_facet), data + i * SIZEOF_STL_FACET, SIZEOF_STL_FACET); } // All the faces have been read. stl_get_size(&stl); mesh.repair(); // Transform the model. stl_transform(&stl, &trafo[0][0]); if (std::abs(stl.stats.min.z) < EPSILON) stl.stats.min.z = 0.; // Add a mesh to a model. if (mesh.facets_count() > 0) mesh_valid = true; } } } else stl_ascii = true; if (stl_ascii) { // Try to parse ASCII STL. char normal_buf[3][32]; stl_facet facet; std::vector facets; LineReader line_reader(zip, (char*)&header, zip.LastRead()); std::string solid_name; facet.extra[0] = facet.extra[1] = 0; for (;;) { const char *line = line_reader.next_line(); if (line == nullptr) // End of file. break; if (strncmp(line, "solid", 5) == 0) { // Opening the "solid" block. if (! solid_name.empty()) { // Error, solid block is already open. facets.clear(); break; } solid_name = line + 5; if (solid_name.empty()) solid_name = "unknown"; continue; } if (strncmp(line, "endsolid", 8) == 0) { // Closing the "solid" block. if (solid_name.empty()) { // Error, no solid block is open. facets.clear(); break; } solid_name.clear(); continue; } // Line has to start with the word solid. int res_normal = sscanf(line, " facet normal %31s %31s %31s", normal_buf[0], normal_buf[1], normal_buf[2]); assert(res_normal == 3); int res_outer_loop = line_reader.next_line_scanf(" outer loop"); assert(res_outer_loop == 0); int res_vertex1 = line_reader.next_line_scanf(" vertex %f %f %f", &facet.vertex[0].x, &facet.vertex[0].y, &facet.vertex[0].z); assert(res_vertex1 == 3); int res_vertex2 = line_reader.next_line_scanf(" vertex %f %f %f", &facet.vertex[1].x, &facet.vertex[1].y, &facet.vertex[1].z); assert(res_vertex2 == 3); int res_vertex3 = line_reader.next_line_scanf(" vertex %f %f %f", &facet.vertex[2].x, &facet.vertex[2].y, &facet.vertex[2].z); assert(res_vertex3 == 3); int res_endloop = line_reader.next_line_scanf(" endloop"); assert(res_endloop == 0); int res_endfacet = line_reader.next_line_scanf(" endfacet"); if (res_normal != 3 || res_outer_loop != 0 || res_vertex1 != 3 || res_vertex2 != 3 || res_vertex3 != 3 || res_endloop != 0 || res_endfacet != 0) { // perror("Something is syntactically very wrong with this ASCII STL!"); facets.clear(); break; } // The facet normal has been parsed as a single string as to workaround for not a numbers in the normal definition. if (sscanf(normal_buf[0], "%f", &facet.normal.x) != 1 || sscanf(normal_buf[1], "%f", &facet.normal.y) != 1 || sscanf(normal_buf[2], "%f", &facet.normal.z) != 1) { // Normal was mangled. Maybe denormals or "not a number" were stored? // Just reset the normal and silently ignore it. memset(&facet.normal, 0, sizeof(facet.normal)); } facets.emplace_back(facet); } if (! facets.empty() && solid_name.empty()) { stl_file &stl = mesh.stl; stl.stats.type = inmemory; stl.stats.number_of_facets = facets.size(); stl.stats.original_num_facets = facets.size(); stl_allocate(&stl); memcpy((void*)stl.facet_start, facets.data(), facets.size() * 50); stl_get_size(&stl); mesh.repair(); // Transform the model. stl_transform(&stl, &trafo[0][0]); // Add a mesh to a model. if (mesh.facets_count() > 0) mesh_valid = true; } } if (mesh_valid) { // Add this mesh to the model. ModelVolume *volume = nullptr; if (model_object == nullptr) { // This is a first mesh of a group. Create a new object & volume. model_object = model->add_object(name_utf8.data(), path, std::move(mesh)); volume = model_object->volumes.front(); ModelInstance *instance = model_object->add_instance(); instance->rotation = instance_rotation; instance->scaling_factor = instance_scaling_factor; instance->offset = instance_offset; ++ num_models; if (group_id != (size_t)-1) group_to_model_object[group_id] = model_object; } else { // This is not the 1st mesh of a group. Add it to the ModelObject. volume = model_object->add_volume(std::move(mesh)); volume->name = name_utf8.data(); } // Set the extruder to the volume. if (extruder_id != (unsigned int)-1) { char str_extruder[64]; sprintf(str_extruder, "%ud", extruder_id); volume->config.set_deserialize("extruder", str_extruder); } } } } } return num_models > 0; } }; // namespace Slic3r #endif /* SLIC3R_PRUS */