String ResourceInteractiveLoaderBinary::recognize(FileAccess *p_f) { error=OK; f=p_f; uint8_t header[4]; f->get_buffer(header,4); if (header[0]=='R' && header[1]=='S' && header[2]=='C' && header[3]=='C') { //compressed FileAccessCompressed *fac = memnew( FileAccessCompressed ); fac->open_after_magic(f); f=fac; } else if (header[0]!='R' || header[1]!='S' || header[2]!='R' || header[3]!='C') { //not normal error=ERR_FILE_UNRECOGNIZED; return ""; } bool big_endian = f->get_32(); #ifdef BIG_ENDIAN_ENABLED endian_swap = !big_endian; #else bool endian_swap = big_endian; #endif bool use_real64 = f->get_32(); f->set_endian_swap(big_endian!=0); //read big endian if saved as big endian uint32_t ver_major=f->get_32(); uint32_t ver_minor=f->get_32(); uint32_t ver_format=f->get_32(); if (ver_format<FORMAT_VERSION || ver_major>VERSION_MAJOR) { f->close(); return ""; } String type=get_unicode_string(); return type; }
/*********************************************************************** * init_user_process_params * * Fill the RTL_USER_PROCESS_PARAMETERS structure from the server. */ static NTSTATUS init_user_process_params( SIZE_T data_size, HANDLE *exe_file ) { void *ptr; WCHAR *src, *dst; SIZE_T info_size, env_size, size, alloc_size; NTSTATUS status; startup_info_t *info; RTL_USER_PROCESS_PARAMETERS *params = NULL; if (!(info = RtlAllocateHeap( GetProcessHeap(), 0, data_size ))) return STATUS_NO_MEMORY; SERVER_START_REQ( get_startup_info ) { wine_server_set_reply( req, info, data_size ); if (!(status = wine_server_call( req ))) { data_size = wine_server_reply_size( reply ); info_size = reply->info_size; env_size = data_size - info_size; *exe_file = wine_server_ptr_handle( reply->exe_file ); } } SERVER_END_REQ; if (status != STATUS_SUCCESS) goto done; size = sizeof(*params); size += MAX_NT_PATH_LENGTH * sizeof(WCHAR); size += info->dllpath_len + sizeof(WCHAR); size += info->imagepath_len + sizeof(WCHAR); size += info->cmdline_len + sizeof(WCHAR); size += info->title_len + sizeof(WCHAR); size += info->desktop_len + sizeof(WCHAR); size += info->shellinfo_len + sizeof(WCHAR); size += info->runtime_len + sizeof(WCHAR); alloc_size = size; status = NtAllocateVirtualMemory( NtCurrentProcess(), (void **)¶ms, 0, &alloc_size, MEM_COMMIT, PAGE_READWRITE ); if (status != STATUS_SUCCESS) goto done; NtCurrentTeb()->Peb->ProcessParameters = params; params->AllocationSize = alloc_size; params->Size = size; params->Flags = PROCESS_PARAMS_FLAG_NORMALIZED; params->DebugFlags = info->debug_flags; params->ConsoleHandle = wine_server_ptr_handle( info->console ); params->ConsoleFlags = info->console_flags; params->hStdInput = wine_server_ptr_handle( info->hstdin ); params->hStdOutput = wine_server_ptr_handle( info->hstdout ); params->hStdError = wine_server_ptr_handle( info->hstderr ); params->dwX = info->x; params->dwY = info->y; params->dwXSize = info->xsize; params->dwYSize = info->ysize; params->dwXCountChars = info->xchars; params->dwYCountChars = info->ychars; params->dwFillAttribute = info->attribute; params->dwFlags = info->flags; params->wShowWindow = info->show; src = (WCHAR *)(info + 1); dst = (WCHAR *)(params + 1); /* current directory needs more space */ get_unicode_string( ¶ms->CurrentDirectory.DosPath, &src, &dst, info->curdir_len ); params->CurrentDirectory.DosPath.MaximumLength = MAX_NT_PATH_LENGTH * sizeof(WCHAR); dst = (WCHAR *)(params + 1) + MAX_NT_PATH_LENGTH; get_unicode_string( ¶ms->DllPath, &src, &dst, info->dllpath_len ); get_unicode_string( ¶ms->ImagePathName, &src, &dst, info->imagepath_len ); get_unicode_string( ¶ms->CommandLine, &src, &dst, info->cmdline_len ); get_unicode_string( ¶ms->WindowTitle, &src, &dst, info->title_len ); get_unicode_string( ¶ms->Desktop, &src, &dst, info->desktop_len ); get_unicode_string( ¶ms->ShellInfo, &src, &dst, info->shellinfo_len ); /* runtime info isn't a real string */ params->RuntimeInfo.Buffer = dst; params->RuntimeInfo.Length = params->RuntimeInfo.MaximumLength = info->runtime_len; memcpy( dst, src, info->runtime_len ); /* environment needs to be a separate memory block */ ptr = NULL; alloc_size = max( 1, env_size ); status = NtAllocateVirtualMemory( NtCurrentProcess(), &ptr, 0, &alloc_size, MEM_COMMIT, PAGE_READWRITE ); if (status != STATUS_SUCCESS) goto done; memcpy( ptr, (char *)info + info_size, env_size ); params->Environment = ptr; done: RtlFreeHeap( GetProcessHeap(), 0, info ); return status; }
Error ResourceInteractiveLoaderBinary::parse_variant(Variant &r_v) { uint32_t type = f->get_32(); print_bl("find property of type: " + itos(type)); switch (type) { case VARIANT_NIL: { r_v = Variant(); } break; case VARIANT_BOOL: { r_v = bool(f->get_32()); } break; case VARIANT_INT: { r_v = int(f->get_32()); } break; case VARIANT_INT64: { r_v = int64_t(f->get_64()); } break; case VARIANT_REAL: { r_v = f->get_real(); } break; case VARIANT_DOUBLE: { r_v = f->get_double(); } break; case VARIANT_STRING: { r_v = get_unicode_string(); } break; case VARIANT_VECTOR2: { Vector2 v; v.x = f->get_real(); v.y = f->get_real(); r_v = v; } break; case VARIANT_RECT2: { Rect2 v; v.position.x = f->get_real(); v.position.y = f->get_real(); v.size.x = f->get_real(); v.size.y = f->get_real(); r_v = v; } break; case VARIANT_VECTOR3: { Vector3 v; v.x = f->get_real(); v.y = f->get_real(); v.z = f->get_real(); r_v = v; } break; case VARIANT_PLANE: { Plane v; v.normal.x = f->get_real(); v.normal.y = f->get_real(); v.normal.z = f->get_real(); v.d = f->get_real(); r_v = v; } break; case VARIANT_QUAT: { Quat v; v.x = f->get_real(); v.y = f->get_real(); v.z = f->get_real(); v.w = f->get_real(); r_v = v; } break; case VARIANT_AABB: { AABB v; v.position.x = f->get_real(); v.position.y = f->get_real(); v.position.z = f->get_real(); v.size.x = f->get_real(); v.size.y = f->get_real(); v.size.z = f->get_real(); r_v = v; } break; case VARIANT_MATRIX32: { Transform2D v; v.elements[0].x = f->get_real(); v.elements[0].y = f->get_real(); v.elements[1].x = f->get_real(); v.elements[1].y = f->get_real(); v.elements[2].x = f->get_real(); v.elements[2].y = f->get_real(); r_v = v; } break; case VARIANT_MATRIX3: { Basis v; v.elements[0].x = f->get_real(); v.elements[0].y = f->get_real(); v.elements[0].z = f->get_real(); v.elements[1].x = f->get_real(); v.elements[1].y = f->get_real(); v.elements[1].z = f->get_real(); v.elements[2].x = f->get_real(); v.elements[2].y = f->get_real(); v.elements[2].z = f->get_real(); r_v = v; } break; case VARIANT_TRANSFORM: { Transform v; v.basis.elements[0].x = f->get_real(); v.basis.elements[0].y = f->get_real(); v.basis.elements[0].z = f->get_real(); v.basis.elements[1].x = f->get_real(); v.basis.elements[1].y = f->get_real(); v.basis.elements[1].z = f->get_real(); v.basis.elements[2].x = f->get_real(); v.basis.elements[2].y = f->get_real(); v.basis.elements[2].z = f->get_real(); v.origin.x = f->get_real(); v.origin.y = f->get_real(); v.origin.z = f->get_real(); r_v = v; } break; case VARIANT_COLOR: { Color v; v.r = f->get_real(); v.g = f->get_real(); v.b = f->get_real(); v.a = f->get_real(); r_v = v; } break; case VARIANT_NODE_PATH: { Vector<StringName> names; Vector<StringName> subnames; bool absolute; int name_count = f->get_16(); uint32_t subname_count = f->get_16(); absolute = subname_count & 0x8000; subname_count &= 0x7FFF; if (ver_format < FORMAT_VERSION_NO_NODEPATH_PROPERTY) { subname_count += 1; // has a property field, so we should count it as well } for (int i = 0; i < name_count; i++) names.push_back(_get_string()); for (uint32_t i = 0; i < subname_count; i++) subnames.push_back(_get_string()); NodePath np = NodePath(names, subnames, absolute); r_v = np; } break; case VARIANT_RID: { r_v = f->get_32(); } break; case VARIANT_OBJECT: { uint32_t objtype = f->get_32(); switch (objtype) { case OBJECT_EMPTY: { //do none } break; case OBJECT_INTERNAL_RESOURCE: { uint32_t index = f->get_32(); String path = res_path + "::" + itos(index); RES res = ResourceLoader::load(path); if (res.is_null()) { WARN_PRINT(String("Couldn't load resource: " + path).utf8().get_data()); } r_v = res; } break; case OBJECT_EXTERNAL_RESOURCE: { //old file format, still around for compatibility String exttype = get_unicode_string(); String path = get_unicode_string(); if (path.find("://") == -1 && path.is_rel_path()) { // path is relative to file being loaded, so convert to a resource path path = ProjectSettings::get_singleton()->localize_path(res_path.get_base_dir().plus_file(path)); } if (remaps.find(path)) { path = remaps[path]; } RES res = ResourceLoader::load(path, exttype); if (res.is_null()) { WARN_PRINT(String("Couldn't load resource: " + path).utf8().get_data()); } r_v = res; } break; case OBJECT_EXTERNAL_RESOURCE_INDEX: { //new file format, just refers to an index in the external list int erindex = f->get_32(); if (erindex < 0 || erindex >= external_resources.size()) { WARN_PRINT("Broken external resource! (index out of size)"); r_v = Variant(); } else { String exttype = external_resources[erindex].type; String path = external_resources[erindex].path; if (path.find("://") == -1 && path.is_rel_path()) { // path is relative to file being loaded, so convert to a resource path path = ProjectSettings::get_singleton()->localize_path(res_path.get_base_dir().plus_file(path)); } RES res = ResourceLoader::load(path, exttype); if (res.is_null()) { WARN_PRINT(String("Couldn't load resource: " + path).utf8().get_data()); } r_v = res; } } break; default: { ERR_FAIL_V(ERR_FILE_CORRUPT); } break; } } break; case VARIANT_DICTIONARY: { uint32_t len = f->get_32(); Dictionary d; //last bit means shared len &= 0x7FFFFFFF; for (uint32_t i = 0; i < len; i++) { Variant key; Error err = parse_variant(key); ERR_FAIL_COND_V(err, ERR_FILE_CORRUPT); Variant value; err = parse_variant(value); ERR_FAIL_COND_V(err, ERR_FILE_CORRUPT); d[key] = value; } r_v = d; } break; case VARIANT_ARRAY: { uint32_t len = f->get_32(); Array a; //last bit means shared len &= 0x7FFFFFFF; a.resize(len); for (uint32_t i = 0; i < len; i++) { Variant val; Error err = parse_variant(val); ERR_FAIL_COND_V(err, ERR_FILE_CORRUPT); a[i] = val; } r_v = a; } break; case VARIANT_RAW_ARRAY: { uint32_t len = f->get_32(); PoolVector<uint8_t> array; array.resize(len); PoolVector<uint8_t>::Write w = array.write(); f->get_buffer(w.ptr(), len); _advance_padding(len); w = PoolVector<uint8_t>::Write(); r_v = array; } break; case VARIANT_INT_ARRAY: { uint32_t len = f->get_32(); PoolVector<int> array; array.resize(len); PoolVector<int>::Write w = array.write(); f->get_buffer((uint8_t *)w.ptr(), len * 4); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr = (uint32_t *)w.ptr(); for (int i = 0; i < len; i++) { ptr[i] = BSWAP32(ptr[i]); } } #endif w = PoolVector<int>::Write(); r_v = array; } break; case VARIANT_REAL_ARRAY: { uint32_t len = f->get_32(); PoolVector<real_t> array; array.resize(len); PoolVector<real_t>::Write w = array.write(); f->get_buffer((uint8_t *)w.ptr(), len * sizeof(real_t)); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr = (uint32_t *)w.ptr(); for (int i = 0; i < len; i++) { ptr[i] = BSWAP32(ptr[i]); } } #endif w = PoolVector<real_t>::Write(); r_v = array; } break; case VARIANT_STRING_ARRAY: { uint32_t len = f->get_32(); PoolVector<String> array; array.resize(len); PoolVector<String>::Write w = array.write(); for (uint32_t i = 0; i < len; i++) w[i] = get_unicode_string(); w = PoolVector<String>::Write(); r_v = array; } break; case VARIANT_VECTOR2_ARRAY: { uint32_t len = f->get_32(); PoolVector<Vector2> array; array.resize(len); PoolVector<Vector2>::Write w = array.write(); if (sizeof(Vector2) == 8) { f->get_buffer((uint8_t *)w.ptr(), len * sizeof(real_t) * 2); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr = (uint32_t *)w.ptr(); for (int i = 0; i < len * 2; i++) { ptr[i] = BSWAP32(ptr[i]); } } #endif } else { ERR_EXPLAIN("Vector2 size is NOT 8!"); ERR_FAIL_V(ERR_UNAVAILABLE); } w = PoolVector<Vector2>::Write(); r_v = array; } break; case VARIANT_VECTOR3_ARRAY: { uint32_t len = f->get_32(); PoolVector<Vector3> array; array.resize(len); PoolVector<Vector3>::Write w = array.write(); if (sizeof(Vector3) == 12) { f->get_buffer((uint8_t *)w.ptr(), len * sizeof(real_t) * 3); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr = (uint32_t *)w.ptr(); for (int i = 0; i < len * 3; i++) { ptr[i] = BSWAP32(ptr[i]); } } #endif } else { ERR_EXPLAIN("Vector3 size is NOT 12!"); ERR_FAIL_V(ERR_UNAVAILABLE); } w = PoolVector<Vector3>::Write(); r_v = array; } break; case VARIANT_COLOR_ARRAY: { uint32_t len = f->get_32(); PoolVector<Color> array; array.resize(len); PoolVector<Color>::Write w = array.write(); if (sizeof(Color) == 16) { f->get_buffer((uint8_t *)w.ptr(), len * sizeof(real_t) * 4); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr = (uint32_t *)w.ptr(); for (int i = 0; i < len * 4; i++) { ptr[i] = BSWAP32(ptr[i]); } } #endif } else { ERR_EXPLAIN("Color size is NOT 16!"); ERR_FAIL_V(ERR_UNAVAILABLE); } w = PoolVector<Color>::Write(); r_v = array; } break; #ifndef DISABLE_DEPRECATED case VARIANT_IMAGE: { uint32_t encoding = f->get_32(); if (encoding == IMAGE_ENCODING_EMPTY) { r_v = Ref<Image>(); break; } else if (encoding == IMAGE_ENCODING_RAW) { uint32_t width = f->get_32(); uint32_t height = f->get_32(); uint32_t mipmaps = f->get_32(); uint32_t format = f->get_32(); const uint32_t format_version_shift = 24; const uint32_t format_version_mask = format_version_shift - 1; uint32_t format_version = format >> format_version_shift; const uint32_t current_version = 0; if (format_version > current_version) { ERR_PRINT("Format version for encoded binary image is too new"); return ERR_PARSE_ERROR; } Image::Format fmt = Image::Format(format & format_version_mask); //if format changes, we can add a compatibility bit on top uint32_t datalen = f->get_32(); PoolVector<uint8_t> imgdata; imgdata.resize(datalen); PoolVector<uint8_t>::Write w = imgdata.write(); f->get_buffer(w.ptr(), datalen); _advance_padding(datalen); w = PoolVector<uint8_t>::Write(); Ref<Image> image; image.instance(); image->create(width, height, mipmaps, fmt, imgdata); r_v = image; } else { //compressed PoolVector<uint8_t> data; data.resize(f->get_32()); PoolVector<uint8_t>::Write w = data.write(); f->get_buffer(w.ptr(), data.size()); w = PoolVector<uint8_t>::Write(); Ref<Image> image; if (encoding == IMAGE_ENCODING_LOSSY && Image::lossy_unpacker) { image = Image::lossy_unpacker(data); } else if (encoding == IMAGE_ENCODING_LOSSLESS && Image::lossless_unpacker) { image = Image::lossless_unpacker(data); } _advance_padding(data.size()); r_v = image; } } break;
void ResourceInteractiveLoaderBinary::open(FileAccess *p_f) { error=OK; f=p_f; uint8_t header[4]; f->get_buffer(header,4); if (header[0]=='R' && header[1]=='S' && header[2]=='C' && header[3]=='C') { //compressed FileAccessCompressed *fac = memnew( FileAccessCompressed ); fac->open_after_magic(f); f=fac; } else if (header[0]!='R' || header[1]!='S' || header[2]!='R' || header[3]!='C') { //not normal error=ERR_FILE_UNRECOGNIZED; ERR_EXPLAIN("Unrecognized binary resource file: "+local_path); ERR_FAIL_V(); } bool big_endian = f->get_32(); #ifdef BIG_ENDIAN_ENABLED endian_swap = !big_endian; #else bool endian_swap = big_endian; #endif bool use_real64 = f->get_32(); f->set_endian_swap(big_endian!=0); //read big endian if saved as big endian uint32_t ver_major=f->get_32(); uint32_t ver_minor=f->get_32(); uint32_t ver_format=f->get_32(); print_bl("big endian: "+itos(big_endian)); print_bl("endian swap: "+itos(endian_swap)); print_bl("real64: "+itos(use_real64)); print_bl("major: "+itos(ver_major)); print_bl("minor: "+itos(ver_minor)); print_bl("format: "+itos(ver_format)); if (ver_format<FORMAT_VERSION || ver_major>VERSION_MAJOR || (ver_major==VERSION_MAJOR && ver_minor>VERSION_MINOR)) { f->close(); ERR_EXPLAIN("File Format '"+itos(FORMAT_VERSION)+"."+itos(ver_major)+"."+itos(ver_minor)+"' is too new! Please upgrade to a a new engine version: "+local_path); ERR_FAIL(); } type=get_unicode_string(); print_bl("type: "+type); importmd_ofs = f->get_64(); for(int i=0;i<14;i++) f->get_32(); //skip a few reserved fields uint32_t string_table_size=f->get_32(); string_map.resize(string_table_size); for(uint32_t i=0;i<string_table_size;i++) { StringName s = get_unicode_string(); string_map[i]=s; } print_bl("strings: "+itos(string_table_size)); uint32_t ext_resources_size=f->get_32(); for(uint32_t i=0;i<ext_resources_size;i++) { ExtResoucre er; er.type=get_unicode_string(); er.path=get_unicode_string(); external_resources.push_back(er); } print_bl("ext resources: "+itos(ext_resources_size)); uint32_t int_resources_size=f->get_32(); for(uint32_t i=0;i<int_resources_size;i++) { IntResoucre ir; ir.path=get_unicode_string(); ir.offset=f->get_64(); internal_resources.push_back(ir); } print_bl("int resources: "+itos(int_resources_size)); if (f->eof_reached()) { error=ERR_FILE_CORRUPT; ERR_EXPLAIN("Premature End Of File: "+local_path); ERR_FAIL(); } }
Error ResourceInteractiveLoaderBinary::poll(){ if (error!=OK) return error; int s = stage; if (s<external_resources.size()) { RES res = ResourceLoader::load(external_resources[s].path,external_resources[s].type); if (res.is_null()) { if (!ResourceLoader::get_abort_on_missing_resources()) { ResourceLoader::notify_load_error("Resource Not Found: "+external_resources[s].path); } else { error=ERR_FILE_CORRUPT; ERR_EXPLAIN("Can't load dependency: "+external_resources[s].path); ERR_FAIL_V(error); } } else { resource_cache.push_back(res); } stage++; return OK; } s-=external_resources.size(); if (s>=internal_resources.size()) { error=ERR_BUG; ERR_FAIL_COND_V(s>=internal_resources.size(),error); } bool main = s==(internal_resources.size()-1); //maybe it is loaded already String path; if (!main) { path=internal_resources[s].path; if (path.begins_with("local://")) path=path.replace("local://",res_path+"::"); if (ResourceCache::has(path)) { //already loaded, don't do anything stage++; error=OK; return error; } } else { path=res_path; } uint64_t offset = internal_resources[s].offset; f->seek(offset); String t = get_unicode_string(); Object *obj = ObjectTypeDB::instance(t); if (!obj) { error=ERR_FILE_CORRUPT; ERR_EXPLAIN(local_path+":Resource of unrecognized type in file: "+t); } ERR_FAIL_COND_V(!obj,ERR_FILE_CORRUPT); Resource *r = obj->cast_to<Resource>(); if (!r) { error=ERR_FILE_CORRUPT; memdelete(obj); //bye ERR_EXPLAIN(local_path+":Resoucre type in resource field not a resource, type is: "+obj->get_type()); ERR_FAIL_COND_V(!r,ERR_FILE_CORRUPT); } RES res = RES( r ); r->set_path(path); int pc = f->get_32(); //set properties for(int i=0;i<pc;i++) { uint32_t name_idx = f->get_32(); if (name_idx>=(uint32_t)string_map.size()) { error=ERR_FILE_CORRUPT; ERR_FAIL_V(ERR_FILE_CORRUPT); } Variant value; error = parse_variant(value); if (error) return error; res->set(string_map[name_idx],value); } #ifdef TOOLS_ENABLED res->set_edited(false); #endif stage++; resource_cache.push_back(res); if (main) { if (importmd_ofs) { f->seek(importmd_ofs); Ref<ResourceImportMetadata> imd = memnew( ResourceImportMetadata ); imd->set_editor(get_unicode_string()); int sc = f->get_32(); for(int i=0;i<sc;i++) { String src = get_unicode_string(); String md5 = get_unicode_string(); imd->add_source(src,md5); } int pc = f->get_32(); for(int i=0;i<pc;i++) { String name = get_unicode_string(); Variant val; parse_variant(val); imd->set_option(name,val); } res->set_import_metadata(imd); } f->close(); resource=res; error=ERR_FILE_EOF; } else { error=OK; } return OK; }
Error ResourceInteractiveLoaderBinary::parse_variant(Variant& r_v) { uint32_t type = f->get_32(); print_bl("find property of type: "+itos(type)); switch(type) { case VARIANT_NIL: { r_v=Variant(); } break; case VARIANT_BOOL: { r_v=bool(f->get_32()); } break; case VARIANT_INT: { r_v=int(f->get_32()); } break; case VARIANT_REAL: { r_v=f->get_real(); } break; case VARIANT_STRING: { r_v=get_unicode_string(); } break; case VARIANT_VECTOR2: { Vector2 v; v.x=f->get_real(); v.y=f->get_real(); r_v=v; } break; case VARIANT_RECT2: { Rect2 v; v.pos.x=f->get_real(); v.pos.y=f->get_real(); v.size.x=f->get_real(); v.size.y=f->get_real(); r_v=v; } break; case VARIANT_VECTOR3: { Vector3 v; v.x=f->get_real(); v.y=f->get_real(); v.z=f->get_real(); r_v=v; } break; case VARIANT_PLANE: { Plane v; v.normal.x=f->get_real(); v.normal.y=f->get_real(); v.normal.z=f->get_real(); v.d=f->get_real(); r_v=v; } break; case VARIANT_QUAT: { Quat v; v.x=f->get_real(); v.y=f->get_real(); v.z=f->get_real(); v.w=f->get_real(); r_v=v; } break; case VARIANT_AABB: { AABB v; v.pos.x=f->get_real(); v.pos.y=f->get_real(); v.pos.z=f->get_real(); v.size.x=f->get_real(); v.size.y=f->get_real(); v.size.z=f->get_real(); r_v=v; } break; case VARIANT_MATRIX32: { Matrix32 v; v.elements[0].x=f->get_real(); v.elements[0].y=f->get_real(); v.elements[1].x=f->get_real(); v.elements[1].y=f->get_real(); v.elements[2].x=f->get_real(); v.elements[2].y=f->get_real(); r_v=v; } break; case VARIANT_MATRIX3: { Matrix3 v; v.elements[0].x=f->get_real(); v.elements[0].y=f->get_real(); v.elements[0].z=f->get_real(); v.elements[1].x=f->get_real(); v.elements[1].y=f->get_real(); v.elements[1].z=f->get_real(); v.elements[2].x=f->get_real(); v.elements[2].y=f->get_real(); v.elements[2].z=f->get_real(); r_v=v; } break; case VARIANT_TRANSFORM: { Transform v; v.basis.elements[0].x=f->get_real(); v.basis.elements[0].y=f->get_real(); v.basis.elements[0].z=f->get_real(); v.basis.elements[1].x=f->get_real(); v.basis.elements[1].y=f->get_real(); v.basis.elements[1].z=f->get_real(); v.basis.elements[2].x=f->get_real(); v.basis.elements[2].y=f->get_real(); v.basis.elements[2].z=f->get_real(); v.origin.x=f->get_real(); v.origin.y=f->get_real(); v.origin.z=f->get_real(); r_v=v; } break; case VARIANT_COLOR: { Color v; v.r=f->get_real(); v.g=f->get_real(); v.b=f->get_real(); v.a=f->get_real(); r_v=v; } break; case VARIANT_IMAGE: { uint32_t encoding = f->get_32(); if (encoding==IMAGE_ENCODING_EMPTY) { r_v=Variant(); break; } else if (encoding==IMAGE_ENCODING_RAW) { uint32_t width = f->get_32(); uint32_t height = f->get_32(); uint32_t mipmaps = f->get_32(); uint32_t format = f->get_32(); Image::Format fmt; switch(format) { case IMAGE_FORMAT_GRAYSCALE: { fmt=Image::FORMAT_GRAYSCALE; } break; case IMAGE_FORMAT_INTENSITY: { fmt=Image::FORMAT_INTENSITY; } break; case IMAGE_FORMAT_GRAYSCALE_ALPHA: { fmt=Image::FORMAT_GRAYSCALE_ALPHA; } break; case IMAGE_FORMAT_RGB: { fmt=Image::FORMAT_RGB; } break; case IMAGE_FORMAT_RGBA: { fmt=Image::FORMAT_RGBA; } break; case IMAGE_FORMAT_INDEXED: { fmt=Image::FORMAT_INDEXED; } break; case IMAGE_FORMAT_INDEXED_ALPHA: { fmt=Image::FORMAT_INDEXED_ALPHA; } break; case IMAGE_FORMAT_BC1: { fmt=Image::FORMAT_BC1; } break; case IMAGE_FORMAT_BC2: { fmt=Image::FORMAT_BC2; } break; case IMAGE_FORMAT_BC3: { fmt=Image::FORMAT_BC3; } break; case IMAGE_FORMAT_BC4: { fmt=Image::FORMAT_BC4; } break; case IMAGE_FORMAT_BC5: { fmt=Image::FORMAT_BC5; } break; case IMAGE_FORMAT_PVRTC2: { fmt=Image::FORMAT_PVRTC2; } break; case IMAGE_FORMAT_PVRTC2_ALPHA: { fmt=Image::FORMAT_PVRTC2_ALPHA; } break; case IMAGE_FORMAT_PVRTC4: { fmt=Image::FORMAT_PVRTC4; } break; case IMAGE_FORMAT_PVRTC4_ALPHA: { fmt=Image::FORMAT_PVRTC4_ALPHA; } break; case IMAGE_FORMAT_ETC: { fmt=Image::FORMAT_ETC; } break; case IMAGE_FORMAT_CUSTOM: { fmt=Image::FORMAT_CUSTOM; } break; default: { ERR_FAIL_V(ERR_FILE_CORRUPT); } } uint32_t datalen = f->get_32(); DVector<uint8_t> imgdata; imgdata.resize(datalen); DVector<uint8_t>::Write w = imgdata.write(); f->get_buffer(w.ptr(),datalen); _advance_padding(datalen); w=DVector<uint8_t>::Write(); r_v=Image(width,height,mipmaps,fmt,imgdata); } else { //compressed DVector<uint8_t> data; data.resize(f->get_32()); DVector<uint8_t>::Write w = data.write(); f->get_buffer(w.ptr(),data.size()); w = DVector<uint8_t>::Write(); Image img; if (encoding==IMAGE_ENCODING_LOSSY && Image::lossy_unpacker) { img = Image::lossy_unpacker(data); } else if (encoding==IMAGE_ENCODING_LOSSLESS && Image::lossless_unpacker) { img = Image::lossless_unpacker(data); } _advance_padding(data.size()); r_v=img; } } break; case VARIANT_NODE_PATH: { Vector<StringName> names; Vector<StringName> subnames; StringName property; bool absolute; int name_count = f->get_16(); uint32_t subname_count = f->get_16(); absolute=subname_count&0x8000; subname_count&=0x7FFF; for(int i=0;i<name_count;i++) names.push_back(string_map[f->get_32()]); for(uint32_t i=0;i<subname_count;i++) subnames.push_back(string_map[f->get_32()]); property=string_map[f->get_32()]; NodePath np = NodePath(names,subnames,absolute,property); //print_line("got path: "+String(np)); r_v=np; } break; case VARIANT_RID: { r_v=f->get_32(); } break; case VARIANT_OBJECT: { uint32_t type=f->get_32(); switch(type) { case OBJECT_EMPTY: { //do none } break; case OBJECT_INTERNAL_RESOURCE: { uint32_t index=f->get_32(); String path = res_path+"::"+itos(index); RES res = ResourceLoader::load(path); if (res.is_null()) { WARN_PRINT(String("Couldn't load resource: "+path).utf8().get_data()); } r_v=res; } break; case OBJECT_EXTERNAL_RESOURCE: { String type = get_unicode_string(); String path = get_unicode_string(); if (path.find("://")==-1 && path.is_rel_path()) { // path is relative to file being loaded, so convert to a resource path path=Globals::get_singleton()->localize_path(res_path.get_base_dir()+"/"+path); } RES res=ResourceLoader::load(path,type); if (res.is_null()) { WARN_PRINT(String("Couldn't load resource: "+path).utf8().get_data()); } r_v=res; } break; default: { ERR_FAIL_V(ERR_FILE_CORRUPT); } break; } } break; case VARIANT_INPUT_EVENT: { } break; case VARIANT_DICTIONARY: { uint32_t len=f->get_32(); Dictionary d(len&0x80000000); //last bit means shared len&=0x7FFFFFFF; for(uint32_t i=0;i<len;i++) { Variant key; Error err = parse_variant(key); ERR_FAIL_COND_V(err,ERR_FILE_CORRUPT); Variant value; err = parse_variant(value); ERR_FAIL_COND_V(err,ERR_FILE_CORRUPT); d[key]=value; } r_v=d; } break; case VARIANT_ARRAY: { uint32_t len=f->get_32(); Array a(len&0x80000000); //last bit means shared len&=0x7FFFFFFF; a.resize(len); for(uint32_t i=0;i<len;i++) { Variant val; Error err = parse_variant(val); ERR_FAIL_COND_V(err,ERR_FILE_CORRUPT); a[i]=val; } r_v=a; } break; case VARIANT_RAW_ARRAY: { uint32_t len = f->get_32(); DVector<uint8_t> array; array.resize(len); DVector<uint8_t>::Write w = array.write(); f->get_buffer(w.ptr(),len); _advance_padding(len); w=DVector<uint8_t>::Write(); r_v=array; } break; case VARIANT_INT_ARRAY: { uint32_t len = f->get_32(); DVector<int> array; array.resize(len); DVector<int>::Write w = array.write(); f->get_buffer((uint8_t*)w.ptr(),len*4); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr=(uint32_t*)w.ptr(); for(int i=0;i<len;i++) { ptr[i]=BSWAP32(ptr[i]); } } #endif w=DVector<int>::Write(); r_v=array; } break; case VARIANT_REAL_ARRAY: { uint32_t len = f->get_32(); DVector<real_t> array; array.resize(len); DVector<real_t>::Write w = array.write(); f->get_buffer((uint8_t*)w.ptr(),len*sizeof(real_t)); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr=(uint32_t*)w.ptr(); for(int i=0;i<len;i++) { ptr[i]=BSWAP32(ptr[i]); } } #endif w=DVector<real_t>::Write(); r_v=array; } break; case VARIANT_STRING_ARRAY: { uint32_t len = f->get_32(); DVector<String> array; array.resize(len); DVector<String>::Write w = array.write(); for(uint32_t i=0;i<len;i++) w[i]=get_unicode_string(); w=DVector<String>::Write(); r_v=array; } break; case VARIANT_VECTOR2_ARRAY: { uint32_t len = f->get_32(); DVector<Vector2> array; array.resize(len); DVector<Vector2>::Write w = array.write(); if (sizeof(Vector2)==8) { f->get_buffer((uint8_t*)w.ptr(),len*sizeof(real_t)*2); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr=(uint32_t*)w.ptr(); for(int i=0;i<len*2;i++) { ptr[i]=BSWAP32(ptr[i]); } } #endif } else { ERR_EXPLAIN("Vector2 size is NOT 8!"); ERR_FAIL_V(ERR_UNAVAILABLE); } w=DVector<Vector2>::Write(); r_v=array; } break; case VARIANT_VECTOR3_ARRAY: { uint32_t len = f->get_32(); DVector<Vector3> array; array.resize(len); DVector<Vector3>::Write w = array.write(); if (sizeof(Vector3)==12) { f->get_buffer((uint8_t*)w.ptr(),len*sizeof(real_t)*3); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr=(uint32_t*)w.ptr(); for(int i=0;i<len*3;i++) { ptr[i]=BSWAP32(ptr[i]); } } #endif } else { ERR_EXPLAIN("Vector3 size is NOT 12!"); ERR_FAIL_V(ERR_UNAVAILABLE); } w=DVector<Vector3>::Write(); r_v=array; } break; case VARIANT_COLOR_ARRAY: { uint32_t len = f->get_32(); DVector<Color> array; array.resize(len); DVector<Color>::Write w = array.write(); if (sizeof(Color)==16) { f->get_buffer((uint8_t*)w.ptr(),len*sizeof(real_t)*4); #ifdef BIG_ENDIAN_ENABLED { uint32_t *ptr=(uint32_t*)w.ptr(); for(int i=0;i<len*4;i++) { ptr[i]=BSWAP32(ptr[i]); } } #endif } else { ERR_EXPLAIN("Color size is NOT 16!"); ERR_FAIL_V(ERR_UNAVAILABLE); } w=DVector<Color>::Write(); r_v=array; } break; default: { ERR_FAIL_V(ERR_FILE_CORRUPT); } break; } return OK; //never reach anyway }