FOSS-VG/src/lib/nbt.hpp

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// Copyright 2022, FOSS-VG Developers and Contributers
//
// This program is free software: you can redistribute it and/or modify it
// under the terms of the GNU Affero General Public License as published
// by the Free Software Foundation, version 3.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied
// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
// See the GNU Affero General Public License for more details.
//
// You should have received a copy of the GNU Affero General Public License
// version 3 along with this program.
// If not, see https://www.gnu.org/licenses/agpl-3.0.en.html
// information taken from https://wiki.vg/NBT
// This is an attempt at creating a uniform model for all NBT tags to allow for a uniform interface based on subclassing a single NBT tag super class.
// NBT tags have a type, optionally a name which consists of the name size and the name string, optionally content type, and optionally a payload which can consist of optionally content type, optionally a content size,
// and the stored content. The format in which they are stored is as follows: <type><name size><name><payload>. All numbers are stored in big endian representation.
// All tag types:
// generic representation: Tag(uint8:tag_type, String:name, uint16:name_size, byte[]:content, int32:size)
// None (compound end): Tag( 0, "", 0, None, 0) => used to determine the end of a compound tag, only the type gets stored
// int8: Tag( 1, String:name, uint16:name_size, int8:content, 1) => a single signed byte, size not stored
// int16: Tag( 2, String:name, uint16:name_size, int16:content, 2) => 16 bit signed integer, size not stored
// int32: Tag( 3, String:name, uint16:name_size, int32:content, 4) => 32 bit signed integer, size not stored
// int64: Tag( 4, String:name, uint16:name_size, int64:content, 8) => 64 bit signed integer, size not stored
// float32: Tag( 5, String:name, uint16:name_size, float32:content,4) => 32 bit IEEE754 floating point number, size not stored
// float64: Tag( 6, String:name, uint16:name_size, float64:content,8) => 64 bit IEEE754 floating point number, size not stored
// int8[]: Tag( 7, String:name, uint16:name_size, int8[]:content, int32:size) => content stored prefixed with size
// String: Tag( 8, String:name, uint16:name_size, String:content, uint16:size) => Java style modified UTF-8 string, content stored prefixed with size
// Tag[] (list): Tag<Tag:type>( 9, String:name, uint16:name_size, Tag[]:content, int32:size) => list of tags of the same type with tag type and name information omitted prefixed by (in order) content type and size
// Tag[] (compound): Tag(10, String:name, uint16:name_size, Tag[]:content, int32:size) => list of tags, last tag is always an end tag, size not stored
// int32[]: Tag(11, String:name, uint16:name_size, int32[]:content,int32:size) => list of 32 bit signed integers prefixed with its size, endianness not verified at this point
// int64[]: Tag(12, String:name, uint16:name_size, int64[]:content,int32:size) => list of 64 bit signed integers prefixed with its size, endianness not verified at this point
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#pragma once
#include <cstdint>
#include <vector>
#include <tinyutf8/tinyutf8.h>
#include "error.hpp"
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namespace NBT {
namespace helper {
ErrorOr<int8_t> readInt8(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
ErrorOr<int16_t> readInt16(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
ErrorOr<int32_t> readInt32(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
ErrorOr<int64_t> readInt64(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
//FIXME: we just assume that float is a single-precision IEEE754
// floating point number
ErrorOr<float> readFloat32(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
//FIXME: we just assume that double is a double-precision IEEE754
// floating point number
ErrorOr<double> readFloat64(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
ErrorOr<std::vector<int8_t>> readInt8Array(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
ErrorOr<tiny_utf8::string> readString(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
ErrorOr<std::vector<int32_t>> readInt32Array(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
ErrorOr<std::vector<int64_t>> readInt64Array(uint8_t data[], uint64_t dataSize, uint64_t currentPosition);
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void writeInt8(std::vector<uint8_t>* destination, int8_t data);
void writeInt16(std::vector<uint8_t>* destination, int16_t data);
void writeInt32(std::vector<uint8_t>* destination, int32_t data);
void writeInt64(std::vector<uint8_t>* destination, int64_t data);
//FIXME: we just assume that float is a single-precision IEEE754
// floating point number
void writeFloat32(std::vector<uint8_t>* destination, float data);
//FIXME: we just assume that double is a single-precision IEEE754
// floating point number
void writeFloat64(std::vector<uint8_t>* destination, double data);
void writeInt8Array(std::vector<uint8_t>* destination, std::vector<int8_t> data);
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void writeInt8Array(std::vector<uint8_t>* destination, int8_t data[], uint32_t dataSize);
void writeString(std::vector<uint8_t>* destination, tiny_utf8::string data);
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void writeInt32Array(std::vector<uint8_t>* destination, std::vector<int32_t> data);
void writeInt32Array(std::vector<uint8_t>* destination, int32_t data[], uint32_t dataSize);
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void writeInt64Array(std::vector<uint8_t>* destination, std::vector<int64_t> data);
void writeInt64Array(std::vector<uint8_t>* destination, int64_t data[], uint32_t dataSize);
}
bool validateRawNBTData(uint8_t data[], int length);
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}