mirror of
https://github.com/Relintai/pandemonium_engine.git
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343 lines
13 KiB
C++
343 lines
13 KiB
C++
#ifndef INPUT_BUFFER_H
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#define INPUT_BUFFER_H
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/*************************************************************************/
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/* data_buffer.h */
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/*************************************************************************/
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/* This file is part of: */
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/* GODOT ENGINE */
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/* https://godotengine.org */
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/*************************************************************************/
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/* Copyright (c) 2007-2021 Juan Linietsky, Ariel Manzur. */
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/* Copyright (c) 2014-2021 Godot Engine contributors (cf. AUTHORS.md). */
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/* */
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/* Permission is hereby granted, free of charge, to any person obtaining */
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/* a copy of this software and associated documentation files (the */
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/* "Software"), to deal in the Software without restriction, including */
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/* without limitation the rights to use, copy, modify, merge, publish, */
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/* distribute, sublicense, and/or sell copies of the Software, and to */
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/* permit persons to whom the Software is furnished to do so, subject to */
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/* the following conditions: */
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/* */
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/* The above copyright notice and this permission notice shall be */
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/* included in all copies or substantial portions of the Software. */
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/* */
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/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
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/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
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/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
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/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
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/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
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/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
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/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
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/*************************************************************************/
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/**
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@author AndreaCatania
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*/
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#include "core/object/class_db.h"
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#include "bit_array.h"
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class DataBuffer : public Object {
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GDCLASS(DataBuffer, Object);
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public:
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enum DataType {
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DATA_TYPE_BOOL,
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DATA_TYPE_INT,
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DATA_TYPE_REAL,
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DATA_TYPE_POSITIVE_UNIT_REAL,
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DATA_TYPE_UNIT_REAL,
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DATA_TYPE_VECTOR2,
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DATA_TYPE_NORMALIZED_VECTOR2,
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DATA_TYPE_VECTOR3,
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DATA_TYPE_NORMALIZED_VECTOR3,
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// The only dynamic sized value.
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DATA_TYPE_VARIANT
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};
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/// Compression level for the stored input data.
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///
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/// Depending on the data type and the compression level used the amount of
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/// bits used and loss change.
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///
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///
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/// ## Bool
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/// Always use 1 bit
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///
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///
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/// ## Int
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/// COMPRESSION_LEVEL_0: 64 bits are used - Stores integers -9223372036854775808 / 9223372036854775807
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/// COMPRESSION_LEVEL_1: 32 bits are used - Stores integers -2147483648 / 2147483647
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/// COMPRESSION_LEVEL_2: 16 bits are used - Stores integers -32768 / 32767
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/// COMPRESSION_LEVEL_3: 8 bits are used - Stores integers -128 / 127
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///
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///
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/// ## Real
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/// Precision depends on an integer range
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/// COMPRESSION_LEVEL_0: 64 bits are used - Double precision. Up to 16 precision is 0.00000000000000177636 in worst case. Up to 512 precision is 0.00000000000005684342 in worst case. Up to 1024 precision is 0.00000000000011368684 in worst case.
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/// COMPRESSION_LEVEL_1: 32 bits are used - Single precision (float). Up to 16 precision is 0.00000095367431640625 in worst case. Up to 512 precision is 0.000030517578125 in worst case. Up to 1024 precision is 0.00006103515625 in worst case.
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/// COMPRESSION_LEVEL_2: 16 bits are used - Half precision. Up to 16 precision is 0.0078125 in worst case. Up to 512 precision is 0.25 in worst case. Up to 1024 precision is 0.5.
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/// COMPRESSION_LEVEL_3: 8 bits are used - Minifloat: Up to 2 precision is 0.125. Up to 4 precision is 0.25. Up to 8 precision is 0.5.
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///
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/// To get the exact precision for the stored number, you need to find the lower power of two relative to the number and divide it by 2^mantissa_bits.
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/// To get the mantissa or exponent bits for a specific compression level, you can use the get_mantissa_bits and get_exponent_bits functions.
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///
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///
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/// ## Positive unit real
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/// COMPRESSION_LEVEL_0: 10 bits are used - Max loss ~0.005%
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/// COMPRESSION_LEVEL_1: 8 bits are used - Max loss ~0.020%
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/// COMPRESSION_LEVEL_2: 6 bits are used - Max loss ~0.793%
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/// COMPRESSION_LEVEL_3: 4 bits are used - Max loss ~3.333%
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///
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///
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/// ## Unit real (uses one extra bit for the sign)
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/// COMPRESSION_LEVEL_0: 11 bits are used - Max loss ~0.005%
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/// COMPRESSION_LEVEL_1: 9 bits are used - Max loss ~0.020%
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/// COMPRESSION_LEVEL_2: 7 bits are used - Max loss ~0.793%
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/// COMPRESSION_LEVEL_3: 5 bits are used - Max loss ~3.333%
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///
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///
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/// ## Vector2
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/// COMPRESSION_LEVEL_0: 2 * 64 bits are used - Double precision (will fallback to level 1 if REAL_T_IS_DOUBLE is not defined)
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/// COMPRESSION_LEVEL_1: 2 * 32 bits are used - Single precision
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/// COMPRESSION_LEVEL_2: 2 * 16 bits are used - Half precision
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/// COMPRESSION_LEVEL_3: 2 * 8 bits are used - Minifloat
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///
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/// For floating point precision, check the Real compression section.
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///
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///
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/// ## Normalized Vector2
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/// COMPRESSION_LEVEL_0: 12 bits are used - Max loss 0.17°
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/// COMPRESSION_LEVEL_1: 11 bits are used - Max loss 0.35°
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/// COMPRESSION_LEVEL_2: 10 bits are used - Max loss 0.7°
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/// COMPRESSION_LEVEL_3: 9 bits are used - Max loss 1.1°
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///
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///
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/// ## Vector3
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/// COMPRESSION_LEVEL_0: 3 * 64 bits are used - Double precision (will fallback to level 1 if REAL_T_IS_DOUBLE is not defined)
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/// COMPRESSION_LEVEL_1: 3 * 32 bits are used - Single precision
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/// COMPRESSION_LEVEL_2: 3 * 16 bits are used - Half precision
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/// COMPRESSION_LEVEL_3: 3 * 8 bits are used - Minifloat
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///
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/// For floating point precision, check the Real compression section.
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///
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///
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/// ## Normalized Vector3
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/// COMPRESSION_LEVEL_0: 11 * 3 bits are used - Max loss ~0.005% per axis
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/// COMPRESSION_LEVEL_1: 9 * 3 bits are used - Max loss ~0.020% per axis
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/// COMPRESSION_LEVEL_2: 7 * 3 bits are used - Max loss ~0.793% per axis
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/// COMPRESSION_LEVEL_3: 5 * 3 bits are used - Max loss ~3.333% per axis
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///
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/// ## Variant
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/// It's dynamic sized. It's not possible to compress it.
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enum CompressionLevel {
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COMPRESSION_LEVEL_0,
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COMPRESSION_LEVEL_1,
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COMPRESSION_LEVEL_2,
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COMPRESSION_LEVEL_3
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};
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private:
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int metadata_size = 0;
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int bit_offset = 0;
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int bit_size = 0;
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bool is_reading = false;
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BitArray buffer;
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public:
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static void _bind_methods();
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DataBuffer() = default;
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DataBuffer(const DataBuffer &p_other);
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DataBuffer(const BitArray &p_buffer);
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const BitArray &get_buffer() const {
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return buffer;
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}
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BitArray &get_buffer_mut() {
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return buffer;
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}
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/// Begin write.
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void begin_write(int p_metadata_size);
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/// Make sure the buffer takes least space possible.
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void dry();
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/// Seek the offset to a specific bit. Seek to a bit greater than the actual
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/// size is not allowed.
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void seek(int p_bits);
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/// Set the bit size and the metadata size.
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void shrink_to(int p_metadata_bit_size, int p_bit_size);
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/// Returns the metadata size in bits.
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int get_metadata_size() const;
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/// Returns the buffer size in bits
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int size() const;
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/// Total size in bits.
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int total_size() const;
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/// Returns the bit offset.
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int get_bit_offset() const;
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/// Skip n bits.
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void skip(int p_bits);
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/// Begin read.
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void begin_read();
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/// Add a boolean to the buffer.
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/// Returns the same data.
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bool add_bool(bool p_input);
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/// Parse the next data as boolean.
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bool read_bool();
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/// Add the next data as int.
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int64_t add_int(int64_t p_input, CompressionLevel p_compression_level);
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/// Parse the next data as int.
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int64_t read_int(CompressionLevel p_compression_level);
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/// Add a real into the buffer. Depending on the compression level is possible
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/// to store different range level.
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/// The fractional part has a precision of ~0.3%
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///
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/// Returns the compressed value so both the client and the peers can use
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/// the same data.
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double add_real(double p_input, CompressionLevel p_compression_level);
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/// Parse the following data as a real.
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double read_real(CompressionLevel p_compression_level);
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/// Add a positive unit real into the buffer.
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///
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/// **Note:** Not unitary values lead to unexpected behaviour.
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///
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/// Returns the compressed value so both the client and the peers can use
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/// the same data.
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real_t add_positive_unit_real(real_t p_input, CompressionLevel p_compression_level);
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/// Parse the following data as a positive unit real.
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real_t read_positive_unit_real(CompressionLevel p_compression_level);
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/// Add a unit real into the buffer.
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///
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/// **Note:** Not unitary values lead to unexpected behaviour.
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///
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/// Returns the compressed value so both the client and the peers can use
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/// the same data.
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real_t add_unit_real(real_t p_input, CompressionLevel p_compression_level);
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/// Parse the following data as an unit real.
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real_t read_unit_real(CompressionLevel p_compression_level);
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/// Add a vector2 into the buffer.
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/// Note: This kind of vector occupies more space than the normalized verison.
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/// Consider use a normalized vector to save bandwidth if possible.
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///
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/// Returns the decompressed vector so both the client and the peers can use
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/// the same data.
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Vector2 add_vector2(Vector2 p_input, CompressionLevel p_compression_level);
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/// Parse next data as vector from the input buffer.
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Vector2 read_vector2(CompressionLevel p_compression_level);
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/// Add a normalized vector2 into the buffer.
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/// Note: The compression algorithm rely on the fact that this is a
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/// normalized vector. The behaviour is unexpected for not normalized vectors.
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///
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/// Returns the decompressed vector so both the client and the peers can use
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/// the same data.
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Vector2 add_normalized_vector2(Vector2 p_input, CompressionLevel p_compression_level);
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/// Parse next data as normalized vector from the input buffer.
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Vector2 read_normalized_vector2(CompressionLevel p_compression_level);
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/// Add a vector3 into the buffer.
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/// Note: This kind of vector occupies more space than the normalized verison.
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/// Consider use a normalized vector to save bandwidth if possible.
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///
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/// Returns the decompressed vector so both the client and the peers can use
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/// the same data.
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Vector3 add_vector3(Vector3 p_input, CompressionLevel p_compression_level);
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/// Parse next data as vector3 from the input buffer.
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Vector3 read_vector3(CompressionLevel p_compression_level);
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/// Add a normalized vector3 into the buffer.
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/// Note: The compression algorithm rely on the fact that this is a
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/// normalized vector. The behaviour is unexpected for not normalized vectors.
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///
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/// Returns the decompressed vector so both the client and the peers can use
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/// the same data.
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Vector3 add_normalized_vector3(Vector3 p_input, CompressionLevel p_compression_level);
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/// Parse next data as normalized vector3 from the input buffer.
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Vector3 read_normalized_vector3(CompressionLevel p_compression_level);
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/// Add a variant. This is the only supported dynamic sized value.
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Variant add_variant(const Variant &p_input);
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/// Parse the next data as Variant and returns it.
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Variant read_variant();
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/// Puts all the bytes to 0.
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void zero();
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/** Skips the amount of bits a type takes. */
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void skip_bool();
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void skip_int(CompressionLevel p_compression);
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void skip_real(CompressionLevel p_compression);
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void skip_unit_real(CompressionLevel p_compression);
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void skip_vector2(CompressionLevel p_compression);
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void skip_normalized_vector2(CompressionLevel p_compression);
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void skip_vector3(CompressionLevel p_compression);
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void skip_normalized_vector3(CompressionLevel p_compression);
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/** Just returns the size of a specific type. */
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int get_bool_size() const;
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int get_int_size(CompressionLevel p_compression) const;
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int get_real_size(CompressionLevel p_compression) const;
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int get_unit_real_size(CompressionLevel p_compression) const;
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int get_vector2_size(CompressionLevel p_compression) const;
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int get_normalized_vector2_size(CompressionLevel p_compression) const;
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int get_vector3_size(CompressionLevel p_compression) const;
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int get_normalized_vector3_size(CompressionLevel p_compression) const;
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/** Read the size and pass to the next parameter. */
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int read_bool_size();
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int read_int_size(CompressionLevel p_compression);
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int read_real_size(CompressionLevel p_compression);
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int read_unit_real_size(CompressionLevel p_compression);
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int read_vector2_size(CompressionLevel p_compression);
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int read_normalized_vector2_size(CompressionLevel p_compression);
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int read_vector3_size(CompressionLevel p_compression);
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int read_normalized_vector3_size(CompressionLevel p_compression);
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int read_variant_size();
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static int get_bit_taken(DataType p_data_type, CompressionLevel p_compression);
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static int get_mantissa_bits(CompressionLevel p_compression);
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static int get_exponent_bits(CompressionLevel p_compression);
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private:
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static uint64_t compress_unit_float(double p_value, double p_scale_factor);
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static double decompress_unit_float(uint64_t p_value, double p_scale_factor);
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void make_room_in_bits(int p_dim);
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void make_room_pad_to_next_byte();
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bool pad_to_next_byte();
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};
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VARIANT_ENUM_CAST(DataBuffer::DataType)
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VARIANT_ENUM_CAST(DataBuffer::CompressionLevel)
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#endif
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