2022-03-20 23:30:30 +01:00
/*************************************************************************/
/* data_buffer.cpp */
/*************************************************************************/
2023-12-18 00:18:53 +01:00
/* This file is part of: */
/* PANDEMONIUM ENGINE */
/* https://github.com/Relintai/pandemonium_engine */
2022-03-20 23:30:30 +01:00
/*************************************************************************/
2023-12-18 00:18:53 +01:00
/* Copyright (c) 2022-present Péter Magyar. */
/* Copyright (c) 2014-2022 Godot Engine contributors (cf. AUTHORS.md). */
/* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur. */
2022-03-20 23:30:30 +01:00
/* */
/* 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. */
/*************************************************************************/
/**
@ author AndreaCatania
*/
# include "data_buffer.h"
# include "core/io/marshalls.h"
// TODO improve the allocation mechanism.
void DataBuffer : : _bind_methods ( ) {
BIND_ENUM_CONSTANT ( DATA_TYPE_BOOL ) ;
BIND_ENUM_CONSTANT ( DATA_TYPE_INT ) ;
BIND_ENUM_CONSTANT ( DATA_TYPE_REAL ) ;
BIND_ENUM_CONSTANT ( DATA_TYPE_UNIT_REAL ) ;
BIND_ENUM_CONSTANT ( DATA_TYPE_VECTOR2 ) ;
BIND_ENUM_CONSTANT ( DATA_TYPE_NORMALIZED_VECTOR2 ) ;
BIND_ENUM_CONSTANT ( DATA_TYPE_VECTOR3 ) ;
BIND_ENUM_CONSTANT ( DATA_TYPE_NORMALIZED_VECTOR3 ) ;
BIND_ENUM_CONSTANT ( COMPRESSION_LEVEL_0 ) ;
BIND_ENUM_CONSTANT ( COMPRESSION_LEVEL_1 ) ;
BIND_ENUM_CONSTANT ( COMPRESSION_LEVEL_2 ) ;
BIND_ENUM_CONSTANT ( COMPRESSION_LEVEL_3 ) ;
ClassDB : : bind_method ( D_METHOD ( " size " ) , & DataBuffer : : size ) ;
ClassDB : : bind_method ( D_METHOD ( " add_bool " , " value " ) , & DataBuffer : : add_bool ) ;
ClassDB : : bind_method ( D_METHOD ( " add_int " , " value " , " compression_level " ) , & DataBuffer : : add_int , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " add_real " , " value " , " compression_level " ) , & DataBuffer : : add_real , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " add_positive_unit_real " , " value " , " compression_level " ) , & DataBuffer : : add_positive_unit_real , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " add_unit_real " , " value " , " compression_level " ) , & DataBuffer : : add_unit_real , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " add_vector2 " , " value " , " compression_level " ) , & DataBuffer : : add_vector2 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " add_normalized_vector2 " , " value " , " compression_level " ) , & DataBuffer : : add_normalized_vector2 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " add_vector3 " , " value " , " compression_level " ) , & DataBuffer : : add_vector3 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " add_normalized_vector3 " , " value " , " compression_level " ) , & DataBuffer : : add_normalized_vector3 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " add_variant " , " value " ) , & DataBuffer : : add_variant ) ;
ClassDB : : bind_method ( D_METHOD ( " read_bool " ) , & DataBuffer : : read_bool ) ;
ClassDB : : bind_method ( D_METHOD ( " read_int " , " compression_level " ) , & DataBuffer : : read_int , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_real " , " compression_level " ) , & DataBuffer : : read_real , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_unit_real " , " compression_level " ) , & DataBuffer : : read_unit_real , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_vector2 " , " compression_level " ) , & DataBuffer : : read_vector2 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_normalized_vector2 " , " compression_level " ) , & DataBuffer : : read_normalized_vector2 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_vector3 " , " compression_level " ) , & DataBuffer : : read_vector3 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_normalized_vector3 " , " compression_level " ) , & DataBuffer : : read_normalized_vector3 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_variant " ) , & DataBuffer : : read_variant ) ;
ClassDB : : bind_method ( D_METHOD ( " skip_bool " ) , & DataBuffer : : skip_bool ) ;
ClassDB : : bind_method ( D_METHOD ( " skip_int " , " compression_level " ) , & DataBuffer : : skip_int , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " skip_real " , " compression_level " ) , & DataBuffer : : skip_real , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " skip_unit_real " , " compression_level " ) , & DataBuffer : : skip_unit_real , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " skip_vector2 " , " compression_level " ) , & DataBuffer : : skip_vector2 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " skip_normalized_vector2 " , " compression_level " ) , & DataBuffer : : skip_normalized_vector2 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " skip_vector3 " , " compression_level " ) , & DataBuffer : : skip_vector3 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " skip_normalized_vector3 " , " compression_level " ) , & DataBuffer : : skip_normalized_vector3 , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " get_bool_size " ) , & DataBuffer : : get_bool_size ) ;
ClassDB : : bind_method ( D_METHOD ( " get_int_size " , " compression_level " ) , & DataBuffer : : get_int_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " get_real_size " , " compression_level " ) , & DataBuffer : : get_real_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " get_unit_real_size " , " compression_level " ) , & DataBuffer : : get_unit_real_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " get_vector2_size " , " compression_level " ) , & DataBuffer : : get_vector2_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " get_normalized_vector2_size " , " compression_level " ) , & DataBuffer : : get_normalized_vector2_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " get_vector3_size " , " compression_level " ) , & DataBuffer : : get_vector3_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " get_normalized_vector3_size " , " compression_level " ) , & DataBuffer : : get_normalized_vector3_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_bool_size " ) , & DataBuffer : : read_bool_size ) ;
ClassDB : : bind_method ( D_METHOD ( " read_int_size " , " compression_level " ) , & DataBuffer : : read_int_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_real_size " , " compression_level " ) , & DataBuffer : : read_real_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_unit_real_size " , " compression_level " ) , & DataBuffer : : read_unit_real_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_vector2_size " , " compression_level " ) , & DataBuffer : : read_vector2_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_normalized_vector2_size " , " compression_level " ) , & DataBuffer : : read_normalized_vector2_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_vector3_size " , " compression_level " ) , & DataBuffer : : read_vector3_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_normalized_vector3_size " , " compression_level " ) , & DataBuffer : : read_normalized_vector3_size , DEFVAL ( COMPRESSION_LEVEL_1 ) ) ;
ClassDB : : bind_method ( D_METHOD ( " read_variant_size " ) , & DataBuffer : : read_variant_size ) ;
ClassDB : : bind_method ( D_METHOD ( " begin_read " ) , & DataBuffer : : begin_read ) ;
ClassDB : : bind_method ( D_METHOD ( " begin_write " , " meta_size " ) , & DataBuffer : : begin_write ) ;
ClassDB : : bind_method ( D_METHOD ( " dry " ) , & DataBuffer : : dry ) ;
}
DataBuffer : : DataBuffer ( const DataBuffer & p_other ) :
Object ( ) ,
metadata_size ( p_other . metadata_size ) ,
bit_offset ( p_other . bit_offset ) ,
bit_size ( p_other . bit_size ) ,
is_reading ( p_other . is_reading ) ,
buffer ( p_other . buffer ) { }
DataBuffer : : DataBuffer ( const BitArray & p_buffer ) :
Object ( ) ,
bit_size ( p_buffer . size_in_bits ( ) ) ,
is_reading ( true ) ,
buffer ( p_buffer ) { }
void DataBuffer : : begin_write ( int p_metadata_size ) {
CRASH_COND_MSG ( p_metadata_size < 0 , " Metadata size can't be negative " ) ;
metadata_size = p_metadata_size ;
bit_size = 0 ;
bit_offset = 0 ;
is_reading = false ;
}
void DataBuffer : : dry ( ) {
buffer . resize_in_bits ( metadata_size + bit_size ) ;
}
void DataBuffer : : seek ( int p_bits ) {
ERR_FAIL_INDEX ( p_bits , metadata_size + bit_size + 1 ) ;
bit_offset = p_bits ;
}
void DataBuffer : : shrink_to ( int p_metadata_bit_size , int p_bit_size ) {
CRASH_COND_MSG ( p_metadata_bit_size < 0 , " Metadata size can't be negative " ) ;
ERR_FAIL_COND_MSG ( p_bit_size < 0 , " Bit size can't be negative " ) ;
ERR_FAIL_COND_MSG ( buffer . size_in_bits ( ) < ( p_metadata_bit_size + p_bit_size ) , " The buffer is smaller than the new given size. " ) ;
metadata_size = p_metadata_bit_size ;
bit_size = p_bit_size ;
}
int DataBuffer : : get_metadata_size ( ) const {
return metadata_size ;
}
int DataBuffer : : size ( ) const {
return bit_size ;
}
int DataBuffer : : total_size ( ) const {
return bit_size + metadata_size ;
}
int DataBuffer : : get_bit_offset ( ) const {
return bit_offset ;
}
void DataBuffer : : skip ( int p_bits ) {
ERR_FAIL_COND ( ( metadata_size + bit_size ) < ( bit_offset + p_bits ) ) ;
bit_offset + = p_bits ;
}
void DataBuffer : : begin_read ( ) {
bit_offset = 0 ;
is_reading = true ;
}
bool DataBuffer : : add_bool ( bool p_input ) {
ERR_FAIL_COND_V ( is_reading = = true , p_input ) ;
const int bits = get_bit_taken ( DATA_TYPE_BOOL , COMPRESSION_LEVEL_0 ) ;
make_room_in_bits ( bits ) ;
buffer . store_bits ( bit_offset , p_input , bits ) ;
bit_offset + = bits ;
# ifdef DEBUG_ENABLED
// Can't never happen because the buffer size is correctly handled.
CRASH_COND ( ( metadata_size + bit_size ) > buffer . size_in_bits ( ) & & bit_offset > buffer . size_in_bits ( ) ) ;
# endif
return p_input ;
}
bool DataBuffer : : read_bool ( ) {
ERR_FAIL_COND_V ( is_reading = = false , false ) ;
const int bits = get_bit_taken ( DATA_TYPE_BOOL , COMPRESSION_LEVEL_0 ) ;
const bool d = buffer . read_bits ( bit_offset , bits ) ;
bit_offset + = bits ;
return d ;
}
int64_t DataBuffer : : add_int ( int64_t p_input , CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = true , p_input ) ;
const int bits = get_bit_taken ( DATA_TYPE_INT , p_compression_level ) ;
int64_t value = p_input ;
// Clamp the value to the max that the bit can store.
if ( bits = = 8 ) {
value = CLAMP ( value , INT8_MIN , INT8_MAX ) ;
} else if ( bits = = 16 ) {
value = CLAMP ( value , INT16_MIN , INT16_MAX ) ;
} else if ( bits = = 32 ) {
value = CLAMP ( value , INT32_MIN , INT32_MAX ) ;
} else {
// Nothing to do here
}
make_room_in_bits ( bits ) ;
buffer . store_bits ( bit_offset , value , bits ) ;
bit_offset + = bits ;
# ifdef DEBUG_ENABLED
// Can't never happen because the buffer size is correctly handled.
CRASH_COND ( ( metadata_size + bit_size ) > buffer . size_in_bits ( ) & & bit_offset > buffer . size_in_bits ( ) ) ;
# endif
if ( bits = = 8 ) {
return static_cast < int8_t > ( value ) ;
} else if ( bits = = 16 ) {
return static_cast < int16_t > ( value ) ;
} else if ( bits = = 32 ) {
return static_cast < int32_t > ( value ) ;
} else {
return value ;
}
}
int64_t DataBuffer : : read_int ( CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = false , 0 ) ;
const int bits = get_bit_taken ( DATA_TYPE_INT , p_compression_level ) ;
const uint64_t value = buffer . read_bits ( bit_offset , bits ) ;
bit_offset + = bits ;
if ( bits = = 8 ) {
return static_cast < int8_t > ( value ) ;
} else if ( bits = = 16 ) {
return static_cast < int16_t > ( value ) ;
} else if ( bits = = 32 ) {
return static_cast < int32_t > ( value ) ;
} else {
return static_cast < int64_t > ( value ) ;
}
}
double DataBuffer : : add_real ( double p_input , CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = true , p_input ) ;
// Clamp the input value according to the compression level
// Minifloat (compression level 0) have a special bias
const int exponent_bits = get_exponent_bits ( p_compression_level ) ;
const int mantissa_bits = get_mantissa_bits ( p_compression_level ) ;
const double bias = p_compression_level = = COMPRESSION_LEVEL_3 ? Math : : pow ( 2.0 , exponent_bits ) - 3 : Math : : pow ( 2.0 , exponent_bits - 1 ) - 1 ;
const double max_value = ( 2.0 - Math : : pow ( 2.0 , - ( mantissa_bits - 1 ) ) ) * Math : : pow ( 2.0 , bias ) ;
const double clamped_input = CLAMP ( p_input , - max_value , max_value ) ;
// Split number according to IEEE 754 binary format.
// Mantissa floating point value represented in range (-1;-0.5], [0.5; 1).
int exponent ;
double mantissa = frexp ( clamped_input , & exponent ) ;
// Extract sign.
const bool sign = mantissa < 0 ;
mantissa = Math : : abs ( mantissa ) ;
// Round mantissa into the specified number of bits (like float -> double conversion).
double mantissa_scale = Math : : pow ( 2.0 , mantissa_bits ) ;
if ( exponent < = 0 ) {
// Subnormal value, apply exponent to mantissa and reduce power of scale by one.
mantissa * = Math : : pow ( 2.0 , exponent ) ;
exponent = 0 ;
mantissa_scale / = 2.0 ;
}
mantissa = Math : : round ( mantissa * mantissa_scale ) / mantissa_scale ; // Round to specified number of bits.
if ( mantissa < 0.5 & & mantissa ! = 0 ) {
// Check underflow, extract exponent from mantissa.
exponent + = ilogb ( mantissa ) + 1 ;
mantissa / = Math : : pow ( 2.0 , exponent ) ;
} else if ( mantissa = = 1 ) {
// Check overflow, increment the exponent.
+ + exponent ;
mantissa = 0.5 ;
}
// Convert the mantissa to an integer that represents the offset index (IEE 754 floating point representation) to send over network safely.
const uint64_t integer_mantissa = exponent < = 0 ? mantissa * mantissa_scale * Math : : pow ( 2.0 , exponent ) : ( mantissa - 0.5 ) * mantissa_scale ;
make_room_in_bits ( mantissa_bits + exponent_bits ) ;
buffer . store_bits ( bit_offset , sign , 1 ) ;
bit_offset + = 1 ;
buffer . store_bits ( bit_offset , integer_mantissa , mantissa_bits - 1 ) ;
bit_offset + = mantissa_bits - 1 ;
// Send unsigned value (just shift it by bias) to avoid sign issues.
buffer . store_bits ( bit_offset , exponent + bias , exponent_bits ) ;
bit_offset + = exponent_bits ;
return ldexp ( sign ? - mantissa : mantissa , exponent ) ;
}
double DataBuffer : : read_real ( CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = false , 0.0 ) ;
const bool sign = buffer . read_bits ( bit_offset , 1 ) ;
bit_offset + = 1 ;
const int mantissa_bits = get_mantissa_bits ( p_compression_level ) ;
const uint64_t integer_mantissa = buffer . read_bits ( bit_offset , mantissa_bits - 1 ) ;
bit_offset + = mantissa_bits - 1 ;
const int exponent_bits = get_exponent_bits ( p_compression_level ) ;
const double bias = p_compression_level = = COMPRESSION_LEVEL_3 ? Math : : pow ( 2.0 , exponent_bits ) - 3 : Math : : pow ( 2.0 , exponent_bits - 1 ) - 1 ;
int exponent = static_cast < int > ( buffer . read_bits ( bit_offset , exponent_bits ) ) - static_cast < int > ( bias ) ;
bit_offset + = exponent_bits ;
// Convert integer mantissa into the floating point representation
// When the index of the mantissa and exponent are 0, then this is a special case and the mantissa is 0.
const double mantissa_scale = Math : : pow ( 2.0 , exponent < = 0 ? mantissa_bits - 1 : mantissa_bits ) ;
const double mantissa = exponent < = 0 ? integer_mantissa / mantissa_scale / Math : : pow ( 2.0 , exponent ) : integer_mantissa / mantissa_scale + 0.5 ;
return ldexp ( sign ? - mantissa : mantissa , exponent ) ;
}
real_t DataBuffer : : add_positive_unit_real ( real_t p_input , CompressionLevel p_compression_level ) {
# ifdef DEBUG_ENABLED
ERR_FAIL_COND_V_MSG ( p_input < 0 | | p_input > 1 , p_input , " Value must be between zero and one. " ) ;
# endif
ERR_FAIL_COND_V ( is_reading = = true , p_input ) ;
const int bits = get_bit_taken ( DATA_TYPE_UNIT_REAL , p_compression_level ) ;
const double max_value = static_cast < double > ( ~ ( UINT64_MAX < < bits ) ) ;
const uint64_t compressed_val = compress_unit_float ( p_input , max_value ) ;
make_room_in_bits ( bits ) ;
buffer . store_bits ( bit_offset , compressed_val , bits ) ;
bit_offset + = bits ;
# ifdef DEBUG_ENABLED
// Can't never happen because the buffer size is correctly handled.
CRASH_COND ( ( metadata_size + bit_size ) > buffer . size_in_bits ( ) & & bit_offset > buffer . size_in_bits ( ) ) ;
# endif
return decompress_unit_float ( compressed_val , max_value ) ;
}
real_t DataBuffer : : read_positive_unit_real ( CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = false , 0.0 ) ;
const int bits = get_bit_taken ( DATA_TYPE_UNIT_REAL , p_compression_level ) ;
const double max_value = static_cast < double > ( ~ ( UINT64_MAX < < bits ) ) ;
const uint64_t compressed_val = buffer . read_bits ( bit_offset , bits ) ;
bit_offset + = bits ;
return decompress_unit_float ( compressed_val , max_value ) ;
}
real_t DataBuffer : : add_unit_real ( real_t p_input , CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = true , p_input ) ;
const real_t added_real = add_positive_unit_real ( ABS ( p_input ) , p_compression_level ) ;
const int bits_for_sign = 1 ;
const uint32_t is_negative = p_input < 0.0 ;
make_room_in_bits ( bits_for_sign ) ;
buffer . store_bits ( bit_offset , is_negative , bits_for_sign ) ;
bit_offset + = bits_for_sign ;
# ifdef DEBUG_ENABLED
// Can't never happen because the buffer size is correctly handled.
CRASH_COND ( ( metadata_size + bit_size ) > buffer . size_in_bits ( ) & & bit_offset > buffer . size_in_bits ( ) ) ;
# endif
return is_negative ? - added_real : added_real ;
}
real_t DataBuffer : : read_unit_real ( CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = false , 0.0 ) ;
const real_t value = read_positive_unit_real ( p_compression_level ) ;
const int bits_for_sign = 1 ;
const bool is_negative = buffer . read_bits ( bit_offset , bits_for_sign ) ;
bit_offset + = bits_for_sign ;
return is_negative ? - value : value ;
}
Vector2 DataBuffer : : add_vector2 ( Vector2 p_input , CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = true , p_input ) ;
# ifndef REAL_T_IS_DOUBLE
// Fallback to compression level 1 if real_t is float
if ( p_compression_level = = DataBuffer : : COMPRESSION_LEVEL_0 ) {
WARN_PRINT_ONCE ( " Compression level 0 is not supported for Vector2 for a binary compiled with single precision float. Falling back to compression level 1 " ) ;
p_compression_level = DataBuffer : : COMPRESSION_LEVEL_1 ;
}
# endif
Vector2 r ;
r [ 0 ] = add_real ( p_input [ 0 ] , p_compression_level ) ;
r [ 1 ] = add_real ( p_input [ 1 ] , p_compression_level ) ;
return r ;
}
Vector2 DataBuffer : : read_vector2 ( CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = false , Vector2 ( ) ) ;
# ifndef REAL_T_IS_DOUBLE
// Fallback to compression level 1 if real_t is float
if ( p_compression_level = = DataBuffer : : COMPRESSION_LEVEL_0 ) {
WARN_PRINT_ONCE ( " Compression level 0 is not supported for Vector2 for a binary compiled with single precision float. Falling back to compression level 1 " ) ;
p_compression_level = DataBuffer : : COMPRESSION_LEVEL_1 ;
}
# endif
Vector2 r ;
r [ 0 ] = read_real ( p_compression_level ) ;
r [ 1 ] = read_real ( p_compression_level ) ;
return r ;
}
Vector2 DataBuffer : : add_normalized_vector2 ( Vector2 p_input , CompressionLevel p_compression_level ) {
# ifdef DEBUG_ENABLED
ERR_FAIL_COND_V ( p_input . is_normalized ( ) = = false , p_input ) ;
# endif
ERR_FAIL_COND_V ( is_reading = = true , p_input ) ;
const int bits = get_bit_taken ( DATA_TYPE_NORMALIZED_VECTOR2 , p_compression_level ) ;
const int bits_for_the_angle = bits - 1 ;
const int bits_for_zero = 1 ;
const double angle = p_input . angle ( ) ;
const uint32_t is_not_zero = p_input . length_squared ( ) > CMP_EPSILON ;
const double max_value = static_cast < double > ( ~ ( UINT64_MAX < < bits_for_the_angle ) ) ;
const uint64_t compressed_angle = compress_unit_float ( ( angle + Math_PI ) / Math_TAU , max_value ) ;
make_room_in_bits ( bits ) ;
buffer . store_bits ( bit_offset , is_not_zero , bits_for_zero ) ;
buffer . store_bits ( bit_offset + 1 , compressed_angle , bits_for_the_angle ) ;
bit_offset + = bits ;
const real_t decompressed_angle = ( decompress_unit_float ( compressed_angle , max_value ) * Math_TAU ) - Math_PI ;
const real_t x = Math : : cos ( decompressed_angle ) ;
const real_t y = Math : : sin ( decompressed_angle ) ;
# ifdef DEBUG_ENABLED
// Can't never happen because the buffer size is correctly handled.
CRASH_COND ( ( metadata_size + bit_size ) > buffer . size_in_bits ( ) & & bit_offset > buffer . size_in_bits ( ) ) ;
# endif
return Vector2 ( x , y ) * is_not_zero ;
}
Vector2 DataBuffer : : read_normalized_vector2 ( CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = false , Vector2 ( ) ) ;
const int bits = get_bit_taken ( DATA_TYPE_NORMALIZED_VECTOR2 , p_compression_level ) ;
const int bits_for_the_angle = bits - 1 ;
const int bits_for_zero = 1 ;
const double max_value = static_cast < double > ( ~ ( UINT64_MAX < < bits_for_the_angle ) ) ;
const real_t is_not_zero = buffer . read_bits ( bit_offset , bits_for_zero ) ;
const uint64_t compressed_angle = buffer . read_bits ( bit_offset + 1 , bits_for_the_angle ) ;
bit_offset + = bits ;
const real_t decompressed_angle = ( decompress_unit_float ( compressed_angle , max_value ) * Math_TAU ) - Math_PI ;
const real_t x = Math : : cos ( decompressed_angle ) ;
const real_t y = Math : : sin ( decompressed_angle ) ;
return Vector2 ( x , y ) * is_not_zero ;
}
Vector3 DataBuffer : : add_vector3 ( Vector3 p_input , CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = true , p_input ) ;
# ifndef REAL_T_IS_DOUBLE
// Fallback to compression level 1 if real_t is float
if ( p_compression_level = = DataBuffer : : COMPRESSION_LEVEL_0 ) {
WARN_PRINT_ONCE ( " Compression level 0 is not supported for Vector3 for a binary compiled with single precision float. Falling back to compression level 1 " ) ;
p_compression_level = DataBuffer : : COMPRESSION_LEVEL_1 ;
}
# endif
Vector3 r ;
r [ 0 ] = add_real ( p_input [ 0 ] , p_compression_level ) ;
r [ 1 ] = add_real ( p_input [ 1 ] , p_compression_level ) ;
r [ 2 ] = add_real ( p_input [ 2 ] , p_compression_level ) ;
return r ;
}
Vector3 DataBuffer : : read_vector3 ( CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = false , Vector3 ( ) ) ;
# ifndef REAL_T_IS_DOUBLE
// Fallback to compression level 1 if real_t is float
if ( p_compression_level = = DataBuffer : : COMPRESSION_LEVEL_0 ) {
WARN_PRINT_ONCE ( " Compression level 0 is not supported for Vector3 for a binary compiled with single precision float. Falling back to compression level 1 " ) ;
p_compression_level = DataBuffer : : COMPRESSION_LEVEL_1 ;
}
# endif
Vector3 r ;
r [ 0 ] = read_real ( p_compression_level ) ;
r [ 1 ] = read_real ( p_compression_level ) ;
r [ 2 ] = read_real ( p_compression_level ) ;
return r ;
}
Vector3 DataBuffer : : add_normalized_vector3 ( Vector3 p_input , CompressionLevel p_compression_level ) {
# ifdef DEBUG_ENABLED
ERR_FAIL_COND_V ( p_input . is_normalized ( ) = = false , p_input ) ;
# endif
ERR_FAIL_COND_V ( is_reading = = true , p_input ) ;
const real_t x_axis = add_unit_real ( p_input . x , p_compression_level ) ;
const real_t y_axis = add_unit_real ( p_input . y , p_compression_level ) ;
const real_t z_axis = add_unit_real ( p_input . z , p_compression_level ) ;
return Vector3 ( x_axis , y_axis , z_axis ) ;
}
Vector3 DataBuffer : : read_normalized_vector3 ( CompressionLevel p_compression_level ) {
ERR_FAIL_COND_V ( is_reading = = false , Vector3 ( ) ) ;
const real_t x_axis = read_unit_real ( p_compression_level ) ;
const real_t y_axis = read_unit_real ( p_compression_level ) ;
const real_t z_axis = read_unit_real ( p_compression_level ) ;
return Vector3 ( x_axis , y_axis , z_axis ) ;
}
Variant DataBuffer : : add_variant ( const Variant & p_input ) {
// TODO consider to use a method similar to `_encode_and_compress_variant`
// to compress the encoded data a bit.
// Get the variant size.
int len = 0 ;
const Error len_err = encode_variant (
p_input ,
nullptr ,
len ,
false ) ;
ERR_FAIL_COND_V_MSG (
len_err ! = OK ,
Variant ( ) ,
" Was not possible encode the variant. " ) ;
// Variant encoding pads the data to byte, so doesn't make sense write it
// unpadded.
make_room_pad_to_next_byte ( ) ;
make_room_in_bits ( len * 8 ) ;
# ifdef DEBUG_ENABLED
// This condition is always false thanks to the `make_room_pad_to_next_byte`.
// so it's safe to assume we are starting from the begin of the byte.
CRASH_COND ( ( bit_offset % 8 ) ! = 0 ) ;
# endif
const Error write_err = encode_variant (
p_input ,
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buffer . get_bytes_mut ( ) . write ( ) . ptr ( ) + ( bit_offset / 8 ) ,
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len ,
false ) ;
ERR_FAIL_COND_V_MSG (
write_err ! = OK ,
Variant ( ) ,
" Was not possible encode the variant. " ) ;
bit_offset + = len * 8 ;
return p_input ;
}
Variant DataBuffer : : read_variant ( ) {
Variant ret ;
int len = 0 ;
// The Variant is always written starting from the beginning of the byte.
const bool success = pad_to_next_byte ( ) ;
ERR_FAIL_COND_V_MSG ( success = = false , Variant ( ) , " Padding failed. " ) ;
# ifdef DEBUG_ENABLED
// This condition is always false thanks to the `pad_to_next_byte`; So is
// safe to assume we are starting from the begin of the byte.
CRASH_COND ( ( bit_offset % 8 ) ! = 0 ) ;
# endif
const Error read_err = decode_variant (
ret ,
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buffer . get_bytes_mut ( ) . write ( ) . ptr ( ) + ( bit_offset / 8 ) ,
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buffer . size_in_bytes ( ) - ( bit_offset / 8 ) ,
& len ,
false ) ;
ERR_FAIL_COND_V_MSG (
read_err ! = OK ,
Variant ( ) ,
" Was not possible decode the variant. " ) ;
bit_offset + = len * 8 ;
return ret ;
}
void DataBuffer : : zero ( ) {
buffer . zero ( ) ;
}
void DataBuffer : : skip_bool ( ) {
const int bits = get_bool_size ( ) ;
skip ( bits ) ;
}
void DataBuffer : : skip_int ( CompressionLevel p_compression ) {
const int bits = get_int_size ( p_compression ) ;
skip ( bits ) ;
}
void DataBuffer : : skip_real ( CompressionLevel p_compression ) {
const int bits = get_real_size ( p_compression ) ;
skip ( bits ) ;
}
void DataBuffer : : skip_unit_real ( CompressionLevel p_compression ) {
const int bits = get_unit_real_size ( p_compression ) ;
skip ( bits ) ;
}
void DataBuffer : : skip_vector2 ( CompressionLevel p_compression ) {
const int bits = get_vector2_size ( p_compression ) ;
skip ( bits ) ;
}
void DataBuffer : : skip_normalized_vector2 ( CompressionLevel p_compression ) {
const int bits = get_normalized_vector2_size ( p_compression ) ;
skip ( bits ) ;
}
void DataBuffer : : skip_vector3 ( CompressionLevel p_compression ) {
const int bits = get_vector3_size ( p_compression ) ;
skip ( bits ) ;
}
void DataBuffer : : skip_normalized_vector3 ( CompressionLevel p_compression ) {
const int bits = get_normalized_vector3_size ( p_compression ) ;
skip ( bits ) ;
}
int DataBuffer : : get_bool_size ( ) const {
return DataBuffer : : get_bit_taken ( DATA_TYPE_BOOL , COMPRESSION_LEVEL_0 ) ;
}
int DataBuffer : : get_int_size ( CompressionLevel p_compression ) const {
return DataBuffer : : get_bit_taken ( DATA_TYPE_INT , p_compression ) ;
}
int DataBuffer : : get_real_size ( CompressionLevel p_compression ) const {
return DataBuffer : : get_bit_taken ( DATA_TYPE_REAL , p_compression ) ;
}
int DataBuffer : : get_unit_real_size ( CompressionLevel p_compression ) const {
return DataBuffer : : get_bit_taken ( DATA_TYPE_UNIT_REAL , p_compression ) ;
}
int DataBuffer : : get_vector2_size ( CompressionLevel p_compression ) const {
return DataBuffer : : get_bit_taken ( DATA_TYPE_VECTOR2 , p_compression ) ;
}
int DataBuffer : : get_normalized_vector2_size ( CompressionLevel p_compression ) const {
return DataBuffer : : get_bit_taken ( DATA_TYPE_NORMALIZED_VECTOR2 , p_compression ) ;
}
int DataBuffer : : get_vector3_size ( CompressionLevel p_compression ) const {
return DataBuffer : : get_bit_taken ( DATA_TYPE_VECTOR3 , p_compression ) ;
}
int DataBuffer : : get_normalized_vector3_size ( CompressionLevel p_compression ) const {
return DataBuffer : : get_bit_taken ( DATA_TYPE_NORMALIZED_VECTOR3 , p_compression ) ;
}
int DataBuffer : : read_bool_size ( ) {
const int bits = get_bool_size ( ) ;
skip ( bits ) ;
return bits ;
}
int DataBuffer : : read_int_size ( CompressionLevel p_compression ) {
const int bits = get_int_size ( p_compression ) ;
skip ( bits ) ;
return bits ;
}
int DataBuffer : : read_real_size ( CompressionLevel p_compression ) {
const int bits = get_real_size ( p_compression ) ;
skip ( bits ) ;
return bits ;
}
int DataBuffer : : read_unit_real_size ( CompressionLevel p_compression ) {
const int bits = get_unit_real_size ( p_compression ) ;
skip ( bits ) ;
return bits ;
}
int DataBuffer : : read_vector2_size ( CompressionLevel p_compression ) {
const int bits = get_vector2_size ( p_compression ) ;
skip ( bits ) ;
return bits ;
}
int DataBuffer : : read_normalized_vector2_size ( CompressionLevel p_compression ) {
const int bits = get_normalized_vector2_size ( p_compression ) ;
skip ( bits ) ;
return bits ;
}
int DataBuffer : : read_vector3_size ( CompressionLevel p_compression ) {
const int bits = get_vector3_size ( p_compression ) ;
skip ( bits ) ;
return bits ;
}
int DataBuffer : : read_normalized_vector3_size ( CompressionLevel p_compression ) {
const int bits = get_normalized_vector3_size ( p_compression ) ;
skip ( bits ) ;
return bits ;
}
int DataBuffer : : read_variant_size ( ) {
int len = 0 ;
Variant ret ;
// The Variant is always written starting from the beginning of the byte.
const bool success = pad_to_next_byte ( ) ;
ERR_FAIL_COND_V_MSG ( success = = false , Variant ( ) , " Padding failed. " ) ;
# ifdef DEBUG_ENABLED
// This condition is always false thanks to the `pad_to_next_byte`; So is
// safe to assume we are starting from the begin of the byte.
CRASH_COND ( ( bit_offset % 8 ) ! = 0 ) ;
# endif
const Error read_err = decode_variant (
ret ,
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buffer . get_bytes_mut ( ) . write ( ) . ptr ( ) + ( bit_offset / 8 ) ,
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buffer . size_in_bytes ( ) - ( bit_offset / 8 ) ,
& len ,
false ) ;
ERR_FAIL_COND_V_MSG (
read_err ! = OK ,
0 ,
" Was not possible to decode the variant, error: " + itos ( read_err ) ) ;
bit_offset + = len * 8 ;
return len * 8 ;
}
int DataBuffer : : get_bit_taken ( DataType p_data_type , CompressionLevel p_compression ) {
switch ( p_data_type ) {
case DATA_TYPE_BOOL :
// No matter what, 1 bit.
return 1 ;
case DATA_TYPE_INT : {
switch ( p_compression ) {
case COMPRESSION_LEVEL_0 :
return 64 ;
case COMPRESSION_LEVEL_1 :
return 32 ;
case COMPRESSION_LEVEL_2 :
return 16 ;
case COMPRESSION_LEVEL_3 :
return 8 ;
default :
// Unreachable
CRASH_NOW_MSG ( " Compression level not supported! " ) ;
}
} break ;
case DATA_TYPE_REAL : {
return get_mantissa_bits ( p_compression ) +
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get_exponent_bits ( p_compression ) ;
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} break ;
case DATA_TYPE_POSITIVE_UNIT_REAL : {
switch ( p_compression ) {
case COMPRESSION_LEVEL_0 :
return 10 ;
case COMPRESSION_LEVEL_1 :
return 8 ;
case COMPRESSION_LEVEL_2 :
return 6 ;
case COMPRESSION_LEVEL_3 :
return 4 ;
default :
// Unreachable
CRASH_NOW_MSG ( " Compression level not supported! " ) ;
}
} break ;
case DATA_TYPE_UNIT_REAL : {
return get_bit_taken ( DATA_TYPE_POSITIVE_UNIT_REAL , p_compression ) + 1 ;
} break ;
case DATA_TYPE_VECTOR2 : {
return get_bit_taken ( DATA_TYPE_REAL , p_compression ) * 2 ;
} break ;
case DATA_TYPE_NORMALIZED_VECTOR2 : {
// +1 bit to know if the vector is 0 or a direction
switch ( p_compression ) {
case CompressionLevel : : COMPRESSION_LEVEL_0 :
return 11 + 1 ;
case CompressionLevel : : COMPRESSION_LEVEL_1 :
return 10 + 1 ;
case CompressionLevel : : COMPRESSION_LEVEL_2 :
return 9 + 1 ;
case CompressionLevel : : COMPRESSION_LEVEL_3 :
return 8 + 1 ;
}
} break ;
case DATA_TYPE_VECTOR3 : {
return get_bit_taken ( DATA_TYPE_REAL , p_compression ) * 3 ;
} break ;
case DATA_TYPE_NORMALIZED_VECTOR3 : {
switch ( p_compression ) {
case CompressionLevel : : COMPRESSION_LEVEL_0 :
return 11 * 3 ;
case CompressionLevel : : COMPRESSION_LEVEL_1 :
return 10 * 3 ;
case CompressionLevel : : COMPRESSION_LEVEL_2 :
return 8 * 3 ;
case CompressionLevel : : COMPRESSION_LEVEL_3 :
return 6 * 3 ;
}
} break ;
case DATA_TYPE_VARIANT : {
ERR_FAIL_V_MSG ( 0 , " The variant size is dynamic and can't be know at compile time. " ) ;
}
default :
// Unreachable
CRASH_NOW_MSG ( " Input type not supported! " ) ;
}
// Unreachable
CRASH_NOW_MSG ( " It was not possible to obtain the bit taken by this input data. " ) ;
return 0 ; // Useless, but MS CI is too noisy.
}
int DataBuffer : : get_mantissa_bits ( CompressionLevel p_compression ) {
// https://en.wikipedia.org/wiki/IEEE_754#Basic_and_interchange_formats
switch ( p_compression ) {
case CompressionLevel : : COMPRESSION_LEVEL_0 :
return 53 ; // Binary64 format
case CompressionLevel : : COMPRESSION_LEVEL_1 :
return 24 ; // Binary32 format
case CompressionLevel : : COMPRESSION_LEVEL_2 :
return 11 ; // Binary16 format
case CompressionLevel : : COMPRESSION_LEVEL_3 :
return 4 ; // https://en.wikipedia.org/wiki/Minifloat
}
// Unreachable
CRASH_NOW_MSG ( " Unknown compression level. " ) ;
return 0 ; // Useless, but MS CI is too noisy.
}
int DataBuffer : : get_exponent_bits ( CompressionLevel p_compression ) {
// https://en.wikipedia.org/wiki/IEEE_754#Basic_and_interchange_formats
switch ( p_compression ) {
case CompressionLevel : : COMPRESSION_LEVEL_0 :
return 11 ; // Binary64 format
case CompressionLevel : : COMPRESSION_LEVEL_1 :
return 8 ; // Binary32 format
case CompressionLevel : : COMPRESSION_LEVEL_2 :
return 5 ; // Binary16 format
case CompressionLevel : : COMPRESSION_LEVEL_3 :
return 4 ; // https://en.wikipedia.org/wiki/Minifloat
}
// Unreachable
CRASH_NOW_MSG ( " Unknown compression level. " ) ;
return 0 ; // Useless, but MS CI is too noisy.
}
uint64_t DataBuffer : : compress_unit_float ( double p_value , double p_scale_factor ) {
return Math : : round ( MIN ( p_value * p_scale_factor , p_scale_factor ) ) ;
}
double DataBuffer : : decompress_unit_float ( uint64_t p_value , double p_scale_factor ) {
return static_cast < double > ( p_value ) / p_scale_factor ;
}
void DataBuffer : : make_room_in_bits ( int p_dim ) {
const int array_min_dim = bit_offset + p_dim ;
if ( array_min_dim > buffer . size_in_bits ( ) ) {
buffer . resize_in_bits ( array_min_dim ) ;
}
if ( array_min_dim > metadata_size ) {
const int new_bit_size = array_min_dim - metadata_size ;
if ( new_bit_size > bit_size ) {
bit_size = new_bit_size ;
}
}
}
void DataBuffer : : make_room_pad_to_next_byte ( ) {
const int bits_to_next_byte = ( ( bit_offset + 7 ) & ~ 7 ) - bit_offset ;
make_room_in_bits ( bits_to_next_byte ) ;
bit_offset + = bits_to_next_byte ;
}
bool DataBuffer : : pad_to_next_byte ( ) {
const int bits_to_next_byte = ( ( bit_offset + 7 ) & ~ 7 ) - bit_offset ;
ERR_FAIL_COND_V_MSG (
bit_offset + bits_to_next_byte > buffer . size_in_bits ( ) ,
false ,
" " ) ;
bit_offset + = bits_to_next_byte ;
return true ;
}