/**************************************************************************/ /* plist.cpp */ /**************************************************************************/ /* This file is part of: */ /* GODOT ENGINE */ /* https://godotengine.org */ /**************************************************************************/ /* Copyright (c) 2014-present Godot Engine contributors (see AUTHORS.md). */ /* Copyright (c) 2007-2014 Juan Linietsky, Ariel Manzur. */ /* */ /* Permission is hereby granted, free of charge, to any person obtaining */ /* a copy of this software and associated documentation files (the */ /* "Software"), to deal in the Software without restriction, including */ /* without limitation the rights to use, copy, modify, merge, publish, */ /* distribute, sublicense, and/or sell copies of the Software, and to */ /* permit persons to whom the Software is furnished to do so, subject to */ /* the following conditions: */ /* */ /* The above copyright notice and this permission notice shall be */ /* included in all copies or substantial portions of the Software. */ /* */ /* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */ /* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */ /* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. */ /* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */ /* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */ /* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */ /* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /**************************************************************************/ #include "plist.h" PList::PLNodeType PListNode::get_type() const { return data_type; } Variant PListNode::get_value() const { switch (data_type) { case PList::PL_NODE_TYPE_NIL: { return Variant(); } break; case PList::PL_NODE_TYPE_STRING: { return String::utf8(data_string.get_data()); } break; case PList::PL_NODE_TYPE_ARRAY: { Array arr; for (const Ref &E : data_array) { arr.push_back(E); } return arr; } break; case PList::PL_NODE_TYPE_DICT: { Dictionary dict; for (const KeyValue> &E : data_dict) { dict[E.key] = E.value; } return dict; } break; case PList::PL_NODE_TYPE_BOOLEAN: { return data_bool; } break; case PList::PL_NODE_TYPE_INTEGER: { return data_int; } break; case PList::PL_NODE_TYPE_REAL: { return data_real; } break; case PList::PL_NODE_TYPE_DATA: { int strlen = data_string.length(); size_t arr_len = 0; Vector buf; { buf.resize(strlen / 4 * 3 + 1); uint8_t *w = buf.ptrw(); ERR_FAIL_COND_V(CryptoCore::b64_decode(&w[0], buf.size(), &arr_len, (unsigned char *)data_string.get_data(), strlen) != OK, Vector()); } buf.resize(arr_len); return buf; } break; case PList::PL_NODE_TYPE_DATE: { return String(data_string.get_data()); } break; } return Variant(); } Ref PListNode::new_node(const Variant &p_value) { Ref node; node.instantiate(); switch (p_value.get_type()) { case Variant::NIL: { node->data_type = PList::PL_NODE_TYPE_NIL; } break; case Variant::BOOL: { node->data_type = PList::PL_NODE_TYPE_BOOLEAN; node->data_bool = p_value; } break; case Variant::INT: { node->data_type = PList::PL_NODE_TYPE_INTEGER; node->data_int = p_value; } break; case Variant::FLOAT: { node->data_type = PList::PL_NODE_TYPE_REAL; node->data_real = p_value; } break; case Variant::STRING_NAME: case Variant::STRING: { node->data_type = PList::PL_NODE_TYPE_STRING; node->data_string = p_value.operator String().utf8(); } break; case Variant::DICTIONARY: { node->data_type = PList::PL_NODE_TYPE_DICT; Dictionary dict = p_value; const Variant *next = dict.next(nullptr); while (next) { Ref sub_node = dict[*next]; ERR_FAIL_COND_V_MSG(sub_node.is_null(), Ref(), "Invalid dictionary element, should be PListNode."); node->data_dict[*next] = sub_node; next = dict.next(next); } } break; case Variant::ARRAY: { node->data_type = PList::PL_NODE_TYPE_ARRAY; Array ar = p_value; for (int i = 0; i < ar.size(); i++) { Ref sub_node = ar[i]; ERR_FAIL_COND_V_MSG(sub_node.is_null(), Ref(), "Invalid array element, should be PListNode."); node->data_array.push_back(sub_node); } } break; case Variant::PACKED_BYTE_ARRAY: { node->data_type = PList::PL_NODE_TYPE_DATA; PackedByteArray buf = p_value; node->data_string = CryptoCore::b64_encode_str(buf.ptr(), buf.size()).utf8(); } break; default: { ERR_FAIL_V_MSG(Ref(), "Unsupported data type."); } break; } return node; } Ref PListNode::new_array() { Ref node = memnew(PListNode()); ERR_FAIL_COND_V(node.is_null(), Ref()); node->data_type = PList::PLNodeType::PL_NODE_TYPE_ARRAY; return node; } Ref PListNode::new_dict() { Ref node = memnew(PListNode()); ERR_FAIL_COND_V(node.is_null(), Ref()); node->data_type = PList::PLNodeType::PL_NODE_TYPE_DICT; return node; } Ref PListNode::new_string(const String &p_string) { Ref node = memnew(PListNode()); ERR_FAIL_COND_V(node.is_null(), Ref()); node->data_type = PList::PLNodeType::PL_NODE_TYPE_STRING; node->data_string = p_string.utf8(); return node; } Ref PListNode::new_data(const String &p_string) { Ref node = memnew(PListNode()); ERR_FAIL_COND_V(node.is_null(), Ref()); node->data_type = PList::PLNodeType::PL_NODE_TYPE_DATA; node->data_string = p_string.utf8(); return node; } Ref PListNode::new_date(const String &p_string) { Ref node = memnew(PListNode()); ERR_FAIL_COND_V(node.is_null(), Ref()); node->data_type = PList::PLNodeType::PL_NODE_TYPE_DATE; node->data_string = p_string.utf8(); node->data_real = (double)Time::get_singleton()->get_unix_time_from_datetime_string(p_string) - 978307200.0; return node; } Ref PListNode::new_bool(bool p_bool) { Ref node = memnew(PListNode()); ERR_FAIL_COND_V(node.is_null(), Ref()); node->data_type = PList::PLNodeType::PL_NODE_TYPE_BOOLEAN; node->data_bool = p_bool; return node; } Ref PListNode::new_int(int64_t p_int) { Ref node = memnew(PListNode()); ERR_FAIL_COND_V(node.is_null(), Ref()); node->data_type = PList::PLNodeType::PL_NODE_TYPE_INTEGER; node->data_int = p_int; return node; } Ref PListNode::new_real(double p_real) { Ref node = memnew(PListNode()); ERR_FAIL_COND_V(node.is_null(), Ref()); node->data_type = PList::PLNodeType::PL_NODE_TYPE_REAL; node->data_real = p_real; return node; } bool PListNode::push_subnode(const Ref &p_node, const String &p_key) { ERR_FAIL_COND_V(p_node.is_null(), false); if (data_type == PList::PLNodeType::PL_NODE_TYPE_DICT) { ERR_FAIL_COND_V(p_key.is_empty(), false); ERR_FAIL_COND_V(data_dict.has(p_key), false); data_dict[p_key] = p_node; return true; } else if (data_type == PList::PLNodeType::PL_NODE_TYPE_ARRAY) { data_array.push_back(p_node); return true; } else { ERR_FAIL_V_MSG(false, "PList: Invalid parent node type, should be DICT or ARRAY."); } } size_t PListNode::get_asn1_size(uint8_t p_len_octets) const { // Get size of all data, excluding type and size information. switch (data_type) { case PList::PLNodeType::PL_NODE_TYPE_NIL: { return 0; } break; case PList::PLNodeType::PL_NODE_TYPE_DATA: case PList::PLNodeType::PL_NODE_TYPE_DATE: { ERR_FAIL_V_MSG(0, "PList: DATE and DATA nodes are not supported by ASN.1 serialization."); } break; case PList::PLNodeType::PL_NODE_TYPE_STRING: { return data_string.length(); } break; case PList::PLNodeType::PL_NODE_TYPE_BOOLEAN: { return 1; } break; case PList::PLNodeType::PL_NODE_TYPE_INTEGER: case PList::PLNodeType::PL_NODE_TYPE_REAL: { return 4; } break; case PList::PLNodeType::PL_NODE_TYPE_ARRAY: { size_t size = 0; for (int i = 0; i < data_array.size(); i++) { size += 1 + _asn1_size_len(p_len_octets) + data_array[i]->get_asn1_size(p_len_octets); } return size; } break; case PList::PLNodeType::PL_NODE_TYPE_DICT: { size_t size = 0; for (const KeyValue> &E : data_dict) { size += 1 + _asn1_size_len(p_len_octets); // Sequence. size += 1 + _asn1_size_len(p_len_octets) + E.key.utf8().length(); //Key. size += 1 + _asn1_size_len(p_len_octets) + E.value->get_asn1_size(p_len_octets); // Value. } return size; } break; default: { return 0; } break; } } int PListNode::_asn1_size_len(uint8_t p_len_octets) { if (p_len_octets > 1) { return p_len_octets + 1; } else { return 1; } } void PListNode::store_asn1_size(PackedByteArray &p_stream, uint8_t p_len_octets) const { uint32_t size = get_asn1_size(p_len_octets); if (p_len_octets > 1) { p_stream.push_back(0x80 + p_len_octets); } for (int i = p_len_octets - 1; i >= 0; i--) { uint8_t x = (size >> i * 8) & 0xFF; p_stream.push_back(x); } } bool PListNode::store_asn1(PackedByteArray &p_stream, uint8_t p_len_octets) const { // Convert to binary ASN1 stream. bool valid = true; switch (data_type) { case PList::PLNodeType::PL_NODE_TYPE_NIL: { // Nothing to store. } break; case PList::PLNodeType::PL_NODE_TYPE_DATE: case PList::PLNodeType::PL_NODE_TYPE_DATA: { ERR_FAIL_V_MSG(false, "PList: DATE and DATA nodes are not supported by ASN.1 serialization."); } break; case PList::PLNodeType::PL_NODE_TYPE_STRING: { p_stream.push_back(0x0C); store_asn1_size(p_stream, p_len_octets); for (int i = 0; i < data_string.size(); i++) { p_stream.push_back(data_string[i]); } } break; case PList::PLNodeType::PL_NODE_TYPE_BOOLEAN: { p_stream.push_back(0x01); store_asn1_size(p_stream, p_len_octets); if (data_bool) { p_stream.push_back(0x01); } else { p_stream.push_back(0x00); } } break; case PList::PLNodeType::PL_NODE_TYPE_INTEGER: { p_stream.push_back(0x02); store_asn1_size(p_stream, p_len_octets); for (int i = 4; i >= 0; i--) { uint8_t x = (data_int >> i * 8) & 0xFF; p_stream.push_back(x); } } break; case PList::PLNodeType::PL_NODE_TYPE_REAL: { p_stream.push_back(0x03); store_asn1_size(p_stream, p_len_octets); for (int i = 4; i >= 0; i--) { uint8_t x = (data_int >> i * 8) & 0xFF; p_stream.push_back(x); } } break; case PList::PLNodeType::PL_NODE_TYPE_ARRAY: { p_stream.push_back(0x30); // Sequence. store_asn1_size(p_stream, p_len_octets); for (int i = 0; i < data_array.size(); i++) { valid = valid && data_array[i]->store_asn1(p_stream, p_len_octets); } } break; case PList::PLNodeType::PL_NODE_TYPE_DICT: { p_stream.push_back(0x31); // Set. store_asn1_size(p_stream, p_len_octets); for (const KeyValue> &E : data_dict) { CharString cs = E.key.utf8(); uint32_t size = cs.length(); // Sequence. p_stream.push_back(0x30); uint32_t seq_size = 2 * (1 + _asn1_size_len(p_len_octets)) + size + E.value->get_asn1_size(p_len_octets); if (p_len_octets > 1) { p_stream.push_back(0x80 + p_len_octets); } for (int i = p_len_octets - 1; i >= 0; i--) { uint8_t x = (seq_size >> i * 8) & 0xFF; p_stream.push_back(x); } // Key. p_stream.push_back(0x0C); if (p_len_octets > 1) { p_stream.push_back(0x80 + p_len_octets); } for (int i = p_len_octets - 1; i >= 0; i--) { uint8_t x = (size >> i * 8) & 0xFF; p_stream.push_back(x); } for (uint32_t i = 0; i < size; i++) { p_stream.push_back(cs[i]); } // Value. valid = valid && E.value->store_asn1(p_stream, p_len_octets); } } break; } return valid; } void PListNode::store_text(String &p_stream, uint8_t p_indent) const { // Convert to text XML stream. switch (data_type) { case PList::PLNodeType::PL_NODE_TYPE_NIL: { // Nothing to store. } break; case PList::PLNodeType::PL_NODE_TYPE_DATA: { p_stream += String("\t").repeat(p_indent); p_stream += "\n"; p_stream += String("\t").repeat(p_indent); p_stream += data_string + "\n"; p_stream += String("\t").repeat(p_indent); p_stream += "\n"; } break; case PList::PLNodeType::PL_NODE_TYPE_DATE: { p_stream += String("\t").repeat(p_indent); p_stream += ""; p_stream += data_string; p_stream += "\n"; } break; case PList::PLNodeType::PL_NODE_TYPE_STRING: { p_stream += String("\t").repeat(p_indent); p_stream += ""; p_stream += String::utf8(data_string); p_stream += "\n"; } break; case PList::PLNodeType::PL_NODE_TYPE_BOOLEAN: { p_stream += String("\t").repeat(p_indent); if (data_bool) { p_stream += "\n"; } else { p_stream += "\n"; } } break; case PList::PLNodeType::PL_NODE_TYPE_INTEGER: { p_stream += String("\t").repeat(p_indent); p_stream += ""; p_stream += itos(data_int); p_stream += "\n"; } break; case PList::PLNodeType::PL_NODE_TYPE_REAL: { p_stream += String("\t").repeat(p_indent); p_stream += ""; p_stream += rtos(data_real); p_stream += "\n"; } break; case PList::PLNodeType::PL_NODE_TYPE_ARRAY: { p_stream += String("\t").repeat(p_indent); p_stream += "\n"; for (int i = 0; i < data_array.size(); i++) { data_array[i]->store_text(p_stream, p_indent + 1); } p_stream += String("\t").repeat(p_indent); p_stream += "\n"; } break; case PList::PLNodeType::PL_NODE_TYPE_DICT: { p_stream += String("\t").repeat(p_indent); p_stream += "\n"; for (const KeyValue> &E : data_dict) { p_stream += String("\t").repeat(p_indent + 1); p_stream += ""; p_stream += E.key; p_stream += "\n"; E.value->store_text(p_stream, p_indent + 1); } p_stream += String("\t").repeat(p_indent); p_stream += "\n"; } break; } } /*************************************************************************/ PList::PList() { root = PListNode::new_dict(); } PList::PList(const String &p_string) { String err_str; bool ok = load_string(p_string, err_str); ERR_FAIL_COND_MSG(!ok, vformat("PList: %s.", err_str)); } uint64_t PList::read_bplist_var_size_int(Ref p_file, uint8_t p_size) { uint64_t pos = p_file->get_position(); uint64_t ret = 0; switch (p_size) { case 1: { ret = p_file->get_8(); } break; case 2: { ret = BSWAP16(p_file->get_16()); } break; case 3: { ret = BSWAP32(p_file->get_32() & 0x00FFFFFF); } break; case 4: { ret = BSWAP32(p_file->get_32()); } break; case 5: { ret = BSWAP64(p_file->get_64() & 0x000000FFFFFFFFFF); } break; case 6: { ret = BSWAP64(p_file->get_64() & 0x0000FFFFFFFFFFFF); } break; case 7: { ret = BSWAP64(p_file->get_64() & 0x00FFFFFFFFFFFFFF); } break; case 8: { ret = BSWAP64(p_file->get_64()); } break; default: { ret = 0; } } p_file->seek(pos + p_size); return ret; } Ref PList::read_bplist_obj(Ref p_file, uint64_t p_offset_idx) { Ref node; node.instantiate(); uint64_t ot_off = trailer.offset_table_start + p_offset_idx * trailer.offset_size; p_file->seek(ot_off); uint64_t marker_off = read_bplist_var_size_int(p_file, trailer.offset_size); ERR_FAIL_COND_V_MSG(marker_off == 0, Ref(), "Invalid marker size."); p_file->seek(marker_off); uint8_t marker = p_file->get_8(); uint8_t marker_type = marker & 0xF0; uint64_t marker_size = marker & 0x0F; switch (marker_type) { case 0x00: { if (marker_size == 0x00) { node->data_type = PL_NODE_TYPE_NIL; } else if (marker_size == 0x08) { node->data_type = PL_NODE_TYPE_BOOLEAN; node->data_bool = false; } else if (marker_size == 0x09) { node->data_type = PL_NODE_TYPE_BOOLEAN; node->data_bool = true; } else { ERR_FAIL_V_MSG(Ref(), "Invalid nil/bool marker value."); } } break; case 0x10: { node->data_type = PL_NODE_TYPE_INTEGER; node->data_int = static_cast(read_bplist_var_size_int(p_file, pow(2, marker_size))); } break; case 0x20: { node->data_type = PL_NODE_TYPE_REAL; node->data_int = static_cast(read_bplist_var_size_int(p_file, pow(2, marker_size))); } break; case 0x30: { node->data_type = PL_NODE_TYPE_DATE; node->data_int = BSWAP64(p_file->get_64()); node->data_string = Time::get_singleton()->get_datetime_string_from_unix_time(node->data_real + 978307200.0).utf8(); } break; case 0x40: { if (marker_size == 0x0F) { uint8_t ext = p_file->get_8() & 0xF; marker_size = read_bplist_var_size_int(p_file, pow(2, ext)); } node->data_type = PL_NODE_TYPE_DATA; PackedByteArray buf; buf.resize(marker_size + 1); p_file->get_buffer(reinterpret_cast(buf.ptrw()), marker_size); node->data_string = CryptoCore::b64_encode_str(buf.ptr(), buf.size()).utf8(); } break; case 0x50: { if (marker_size == 0x0F) { uint8_t ext = p_file->get_8() & 0xF; marker_size = read_bplist_var_size_int(p_file, pow(2, ext)); } node->data_type = PL_NODE_TYPE_STRING; node->data_string.resize(marker_size + 1); p_file->get_buffer(reinterpret_cast(node->data_string.ptrw()), marker_size); } break; case 0x60: { if (marker_size == 0x0F) { uint8_t ext = p_file->get_8() & 0xF; marker_size = read_bplist_var_size_int(p_file, pow(2, ext)); } Char16String cs16; cs16.resize(marker_size + 1); for (uint64_t i = 0; i < marker_size; i++) { cs16[i] = BSWAP16(p_file->get_16()); } node->data_type = PL_NODE_TYPE_STRING; node->data_string = String::utf16(cs16.ptr(), cs16.length()).utf8(); } break; case 0x80: { node->data_type = PL_NODE_TYPE_INTEGER; node->data_int = static_cast(read_bplist_var_size_int(p_file, marker_size + 1)); } break; case 0xA0: case 0xC0: { if (marker_size == 0x0F) { uint8_t ext = p_file->get_8() & 0xF; marker_size = read_bplist_var_size_int(p_file, pow(2, ext)); } uint64_t pos = p_file->get_position(); node->data_type = PL_NODE_TYPE_ARRAY; for (uint64_t i = 0; i < marker_size; i++) { p_file->seek(pos + trailer.ref_size * i); uint64_t ref = read_bplist_var_size_int(p_file, trailer.ref_size); Ref element = read_bplist_obj(p_file, ref); ERR_FAIL_COND_V(element.is_null(), Ref()); node->data_array.push_back(element); } } break; case 0xD0: { if (marker_size == 0x0F) { uint8_t ext = p_file->get_8() & 0xF; marker_size = read_bplist_var_size_int(p_file, pow(2, ext)); } uint64_t pos = p_file->get_position(); node->data_type = PL_NODE_TYPE_DICT; for (uint64_t i = 0; i < marker_size; i++) { p_file->seek(pos + trailer.ref_size * i); uint64_t key_ref = read_bplist_var_size_int(p_file, trailer.ref_size); p_file->seek(pos + trailer.ref_size * (i + marker_size)); uint64_t obj_ref = read_bplist_var_size_int(p_file, trailer.ref_size); Ref element_key = read_bplist_obj(p_file, key_ref); ERR_FAIL_COND_V(element_key.is_null() || element_key->data_type != PL_NODE_TYPE_STRING, Ref()); Ref element = read_bplist_obj(p_file, obj_ref); ERR_FAIL_COND_V(element.is_null(), Ref()); node->data_dict[String::utf8(element_key->data_string.ptr(), element_key->data_string.length())] = element; } } break; default: { ERR_FAIL_V_MSG(Ref(), "Invalid marker type."); } } return node; } bool PList::load_file(const String &p_filename) { root = Ref(); Ref fb = FileAccess::open(p_filename, FileAccess::READ); if (fb.is_null()) { return false; } unsigned char magic[8]; fb->get_buffer(magic, 8); if (String((const char *)magic, 8) == "bplist00") { fb->seek_end(-26); trailer.offset_size = fb->get_8(); trailer.ref_size = fb->get_8(); trailer.object_num = BSWAP64(fb->get_64()); trailer.root_offset_idx = BSWAP64(fb->get_64()); trailer.offset_table_start = BSWAP64(fb->get_64()); root = read_bplist_obj(fb, trailer.root_offset_idx); return root.is_valid(); } else { // Load text plist. Error err; Vector array = FileAccess::get_file_as_bytes(p_filename, &err); ERR_FAIL_COND_V(err != OK, false); String ret; ret.parse_utf8((const char *)array.ptr(), array.size()); String err_str; bool ok = load_string(ret, err_str); ERR_FAIL_COND_V_MSG(!ok, false, "PList: " + err_str); return true; } } bool PList::load_string(const String &p_string, String &r_err_out) { root = Ref(); int pos = 0; bool in_plist = false; bool done_plist = false; List> stack; String key; while (pos >= 0) { int open_token_s = p_string.find_char('<', pos); if (open_token_s == -1) { r_err_out = "Unexpected end of data. No tags found."; return false; } int open_token_e = p_string.find_char('>', open_token_s); pos = open_token_e; String token = p_string.substr(open_token_s + 1, open_token_e - open_token_s - 1); if (token.is_empty()) { r_err_out = "Invalid token name."; return false; } String value; if (token[0] == '?' || token[0] == '!') { // Skip and int end_token_e = p_string.find_char('>', open_token_s); pos = end_token_e; continue; } if (token.find("plist", 0) == 0) { in_plist = true; continue; } if (token == "/plist") { done_plist = true; break; } if (!in_plist) { r_err_out = "Node outside of tag."; return false; } if (token == "dict") { if (!stack.is_empty()) { // Add subnode end enter it. Ref dict = PListNode::new_dict(); dict->data_type = PList::PLNodeType::PL_NODE_TYPE_DICT; if (!stack.back()->get()->push_subnode(dict, key)) { r_err_out = "Can't push subnode, invalid parent type."; return false; } stack.push_back(dict); } else { // Add root node. if (!root.is_null()) { r_err_out = "Root node already set."; return false; } Ref dict = PListNode::new_dict(); stack.push_back(dict); root = dict; } continue; } if (token == "/dict") { // Exit current dict. if (stack.is_empty() || stack.back()->get()->data_type != PList::PLNodeType::PL_NODE_TYPE_DICT) { r_err_out = "Mismatched tag."; return false; } stack.pop_back(); continue; } if (token == "array") { if (!stack.is_empty()) { // Add subnode end enter it. Ref arr = PListNode::new_array(); if (!stack.back()->get()->push_subnode(arr, key)) { r_err_out = "Can't push subnode, invalid parent type."; return false; } stack.push_back(arr); } else { // Add root node. if (!root.is_null()) { r_err_out = "Root node already set."; return false; } Ref arr = PListNode::new_array(); stack.push_back(arr); root = arr; } continue; } if (token == "/array") { // Exit current array. if (stack.is_empty() || stack.back()->get()->data_type != PList::PLNodeType::PL_NODE_TYPE_ARRAY) { r_err_out = "Mismatched tag."; return false; } stack.pop_back(); continue; } if (token[token.length() - 1] == '/') { token = token.substr(0, token.length() - 1); } else { int end_token_s = p_string.find(" tag.", token); return false; } int end_token_e = p_string.find_char('>', end_token_s); pos = end_token_e; String end_token = p_string.substr(end_token_s + 2, end_token_e - end_token_s - 2); if (end_token != token) { r_err_out = vformat("Mismatched <%s> and <%s> token pair.", token, end_token); return false; } value = p_string.substr(open_token_e + 1, end_token_s - open_token_e - 1); } if (token == "key") { key = value; } else { Ref var = nullptr; if (token == "true") { var = PListNode::new_bool(true); } else if (token == "false") { var = PListNode::new_bool(false); } else if (token == "integer") { var = PListNode::new_int(value.to_int()); } else if (token == "real") { var = PListNode::new_real(value.to_float()); } else if (token == "string") { var = PListNode::new_string(value); } else if (token == "data") { var = PListNode::new_data(value); } else if (token == "date") { var = PListNode::new_date(value); } else { r_err_out = vformat("Invalid value type: %s.", token); return false; } if (stack.is_empty() || !stack.back()->get()->push_subnode(var, key)) { r_err_out = "Can't push subnode, invalid parent type."; return false; } } } if (!stack.is_empty() || !done_plist) { r_err_out = "Unexpected end of data. Root node is not closed."; return false; } return true; } PackedByteArray PList::save_asn1() const { if (root.is_null()) { ERR_FAIL_V_MSG(PackedByteArray(), "PList: Invalid PList, no root node."); } size_t size = root->get_asn1_size(1); uint8_t len_octets = 0; if (size < 0x80) { len_octets = 1; } else { size = root->get_asn1_size(2); if (size < 0xFFFF) { len_octets = 2; } else { size = root->get_asn1_size(3); if (size < 0xFFFFFF) { len_octets = 3; } else { size = root->get_asn1_size(4); if (size < 0xFFFFFFFF) { len_octets = 4; } else { ERR_FAIL_V_MSG(PackedByteArray(), "PList: Data is too big for ASN.1 serializer, should be < 4 GiB."); } } } } PackedByteArray ret; if (!root->store_asn1(ret, len_octets)) { ERR_FAIL_V_MSG(PackedByteArray(), "PList: ASN.1 serializer error."); } return ret; } String PList::save_text() const { if (root.is_null()) { ERR_FAIL_V_MSG(String(), "PList: Invalid PList, no root node."); } String ret; ret += "\n"; ret += "\n"; ret += "\n"; root->store_text(ret, 0); ret += "\n\n"; return ret; } Ref PList::get_root() { return root; }