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/*************************************************************************/
/* image.cpp */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* https://godotengine.org */
/*************************************************************************/
/* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur. */
/* Copyright (c) 2014-2022 Godot Engine contributors (cf. AUTHORS.md). */
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/* "Software"), to deal in the Software without restriction, including */
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/* 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.*/
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/*************************************************************************/
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# include "image.h"
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# include "core/error_macros.h"
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# include "core/math/math.h"
# include "core/math/vector3.h"
# include "memory.h"
# include <memory.h>
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# include <stdio.h>
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# include <map>
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const char * Image : : format_names [ Image : : FORMAT_MAX ] = {
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" Lum8 " , // luminance
" LumAlpha8 " , // luminance-alpha
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" Red8 " ,
" RedGreen " ,
" RGB8 " ,
" RGBA8 " ,
" RGBA4444 " ,
" RGBA5551 " ,
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" RFloat " , // float
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" RGFloat " ,
" RGBFloat " ,
" RGBAFloat " ,
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" RHalf " , // half float
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" RGHalf " ,
" RGBHalf " ,
" RGBAHalf " ,
" RGBE9995 " ,
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" DXT1 RGB8 " , // s3tc
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" DXT3 RGBA8 " ,
" DXT5 RGBA8 " ,
" RGTC Red8 " ,
" RGTC RedGreen8 " ,
" BPTC_RGBA " ,
" BPTC_RGBF " ,
" BPTC_RGBFU " ,
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" PVRTC2 " , // pvrtc
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" PVRTC2A " ,
" PVRTC4 " ,
" PVRTC4A " ,
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" ETC " , // etc1
" ETC2_R11 " , // etc2
" ETC2_R11S " , // signed", NOT srgb.
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" ETC2_RG11 " ,
" ETC2_RG11S " ,
" ETC2_RGB8 " ,
" ETC2_RGBA8 " ,
" ETC2_RGB8A1 " ,
} ;
void Image : : _put_pixelb ( int p_x , int p_y , uint32_t p_pixel_size , uint8_t * p_data , const uint8_t * p_pixel ) {
uint32_t ofs = ( p_y * width + p_x ) * p_pixel_size ;
memcpy ( p_data + ofs , p_pixel , p_pixel_size ) ;
}
void Image : : _get_pixelb ( int p_x , int p_y , uint32_t p_pixel_size , const uint8_t * p_data , uint8_t * p_pixel ) {
uint32_t ofs = ( p_y * width + p_x ) * p_pixel_size ;
memcpy ( p_pixel , p_data + ofs , p_pixel_size ) ;
}
int Image : : get_format_pixel_size ( Format p_format ) {
switch ( p_format ) {
case FORMAT_L8 :
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return 1 ; // luminance
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case FORMAT_LA8 :
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return 2 ; // luminance-alpha
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case FORMAT_R8 :
return 1 ;
case FORMAT_RG8 :
return 2 ;
case FORMAT_RGB8 :
return 3 ;
case FORMAT_RGBA8 :
return 4 ;
case FORMAT_RGBA4444 :
return 2 ;
case FORMAT_RGBA5551 :
return 2 ;
case FORMAT_RF :
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return 4 ; // float
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case FORMAT_RGF :
return 8 ;
case FORMAT_RGBF :
return 12 ;
case FORMAT_RGBAF :
return 16 ;
case FORMAT_RH :
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return 2 ; // half float
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case FORMAT_RGH :
return 4 ;
case FORMAT_RGBH :
return 6 ;
case FORMAT_RGBAH :
return 8 ;
case FORMAT_RGBE9995 :
return 4 ;
case FORMAT_DXT1 :
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return 1 ; // s3tc bc1
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case FORMAT_DXT3 :
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return 1 ; // bc2
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case FORMAT_DXT5 :
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return 1 ; // bc3
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case FORMAT_RGTC_R :
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return 1 ; // bc4
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case FORMAT_RGTC_RG :
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return 1 ; // bc5
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case FORMAT_BPTC_RGBA :
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return 1 ; // btpc bc6h
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case FORMAT_BPTC_RGBF :
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return 1 ; // float /
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case FORMAT_BPTC_RGBFU :
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return 1 ; // unsigned float
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case FORMAT_PVRTC2 :
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return 1 ; // pvrtc
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case FORMAT_PVRTC2A :
return 1 ;
case FORMAT_PVRTC4 :
return 1 ;
case FORMAT_PVRTC4A :
return 1 ;
case FORMAT_ETC :
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return 1 ; // etc1
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case FORMAT_ETC2_R11 :
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return 1 ; // etc2
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case FORMAT_ETC2_R11S :
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return 1 ; // signed: return 1; NOT srgb.
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case FORMAT_ETC2_RG11 :
return 1 ;
case FORMAT_ETC2_RG11S :
return 1 ;
case FORMAT_ETC2_RGB8 :
return 1 ;
case FORMAT_ETC2_RGBA8 :
return 1 ;
case FORMAT_ETC2_RGB8A1 :
return 1 ;
case FORMAT_MAX : {
}
}
return 0 ;
}
void Image : : get_format_min_pixel_size ( Format p_format , int & r_w , int & r_h ) {
switch ( p_format ) {
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case FORMAT_DXT1 : // s3tc bc1
case FORMAT_DXT3 : // bc2
case FORMAT_DXT5 : // bc3
case FORMAT_RGTC_R : // bc4
case FORMAT_RGTC_RG : { // bc5 case case FORMAT_DXT1:
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r_w = 4 ;
r_h = 4 ;
} break ;
case FORMAT_PVRTC2 :
case FORMAT_PVRTC2A : {
r_w = 16 ;
r_h = 8 ;
} break ;
case FORMAT_PVRTC4A :
case FORMAT_PVRTC4 : {
r_w = 8 ;
r_h = 8 ;
} break ;
case FORMAT_ETC : {
r_w = 4 ;
r_h = 4 ;
} break ;
case FORMAT_BPTC_RGBA :
case FORMAT_BPTC_RGBF :
case FORMAT_BPTC_RGBFU : {
r_w = 4 ;
r_h = 4 ;
} break ;
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case FORMAT_ETC2_R11 : // etc2
case FORMAT_ETC2_R11S : // signed: NOT srgb.
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case FORMAT_ETC2_RG11 :
case FORMAT_ETC2_RG11S :
case FORMAT_ETC2_RGB8 :
case FORMAT_ETC2_RGBA8 :
case FORMAT_ETC2_RGB8A1 : {
r_w = 4 ;
r_h = 4 ;
} break ;
default : {
r_w = 1 ;
r_h = 1 ;
} break ;
}
}
int Image : : get_format_pixel_rshift ( Format p_format ) {
if ( p_format = = FORMAT_DXT1 | | p_format = = FORMAT_RGTC_R | | p_format = = FORMAT_PVRTC4 | | p_format = = FORMAT_PVRTC4A | | p_format = = FORMAT_ETC | | p_format = = FORMAT_ETC2_R11 | | p_format = = FORMAT_ETC2_R11S | | p_format = = FORMAT_ETC2_RGB8 | | p_format = = FORMAT_ETC2_RGB8A1 ) {
return 1 ;
} else if ( p_format = = FORMAT_PVRTC2 | | p_format = = FORMAT_PVRTC2A ) {
return 2 ;
} else {
return 0 ;
}
}
int Image : : get_format_block_size ( Format p_format ) {
switch ( p_format ) {
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case FORMAT_DXT1 : // s3tc bc1
case FORMAT_DXT3 : // bc2
case FORMAT_DXT5 : // bc3
case FORMAT_RGTC_R : // bc4
case FORMAT_RGTC_RG : { // bc5 case case FORMAT_DXT1:
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return 4 ;
}
case FORMAT_PVRTC2 :
case FORMAT_PVRTC2A : {
return 4 ;
}
case FORMAT_PVRTC4A :
case FORMAT_PVRTC4 : {
return 4 ;
}
case FORMAT_ETC : {
return 4 ;
}
case FORMAT_BPTC_RGBA :
case FORMAT_BPTC_RGBF :
case FORMAT_BPTC_RGBFU : {
return 4 ;
}
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case FORMAT_ETC2_R11 : // etc2
case FORMAT_ETC2_R11S : // signed: NOT srgb.
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case FORMAT_ETC2_RG11 :
case FORMAT_ETC2_RG11S :
case FORMAT_ETC2_RGB8 :
case FORMAT_ETC2_RGBA8 :
case FORMAT_ETC2_RGB8A1 : {
return 4 ;
}
default : {
}
}
return 1 ;
}
void Image : : _get_mipmap_offset_and_size ( int p_mipmap , int & r_offset , int & r_width , int & r_height ) const {
int w = width ;
int h = height ;
int ofs = 0 ;
int pixel_size = get_format_pixel_size ( format ) ;
int pixel_rshift = get_format_pixel_rshift ( format ) ;
int block = get_format_block_size ( format ) ;
int minw , minh ;
get_format_min_pixel_size ( format , minw , minh ) ;
for ( int i = 0 ; i < p_mipmap ; i + + ) {
int bw = w % block ! = 0 ? w + ( block - w % block ) : w ;
int bh = h % block ! = 0 ? h + ( block - h % block ) : h ;
int s = bw * bh ;
s * = pixel_size ;
s > > = pixel_rshift ;
ofs + = s ;
w = MAX ( minw , w > > 1 ) ;
h = MAX ( minh , h > > 1 ) ;
}
r_offset = ofs ;
r_width = w ;
r_height = h ;
}
int Image : : get_mipmap_offset ( int p_mipmap ) const {
ERR_FAIL_INDEX_V ( p_mipmap , get_mipmap_count ( ) + 1 , - 1 ) ;
int ofs , w , h ;
_get_mipmap_offset_and_size ( p_mipmap , ofs , w , h ) ;
return ofs ;
}
void Image : : get_mipmap_offset_and_size ( int p_mipmap , int & r_ofs , int & r_size ) const {
int ofs , w , h ;
_get_mipmap_offset_and_size ( p_mipmap , ofs , w , h ) ;
int ofs2 ;
_get_mipmap_offset_and_size ( p_mipmap + 1 , ofs2 , w , h ) ;
r_ofs = ofs ;
r_size = ofs2 - ofs ;
}
void Image : : get_mipmap_offset_size_and_dimensions ( int p_mipmap , int & r_ofs , int & r_size , int & w , int & h ) const {
int ofs ;
_get_mipmap_offset_and_size ( p_mipmap , ofs , w , h ) ;
int ofs2 , w2 , h2 ;
_get_mipmap_offset_and_size ( p_mipmap + 1 , ofs2 , w2 , h2 ) ;
r_ofs = ofs ;
r_size = ofs2 - ofs ;
}
int Image : : get_width ( ) const {
return width ;
}
int Image : : get_height ( ) const {
return height ;
}
Vector2 Image : : get_size ( ) const {
return Vector2 ( width , height ) ;
}
bool Image : : has_mipmaps ( ) const {
return mipmaps ;
}
int Image : : get_mipmap_count ( ) const {
if ( mipmaps ) {
return get_image_required_mipmaps ( width , height , format ) ;
} else {
return 0 ;
}
}
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// using template generates perfectly optimized code due to constant expression reduction and unused variable removal present in all compilers
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template < uint32_t read_bytes , bool read_alpha , uint32_t write_bytes , bool write_alpha , bool read_gray , bool write_gray >
static void _convert ( int p_width , int p_height , const uint8_t * p_src , uint8_t * p_dst ) {
uint32_t max_bytes = MAX ( read_bytes , write_bytes ) ;
for ( int y = 0 ; y < p_height ; y + + ) {
for ( int x = 0 ; x < p_width ; x + + ) {
const uint8_t * rofs = & p_src [ ( ( y * p_width ) + x ) * ( read_bytes + ( read_alpha ? 1 : 0 ) ) ] ;
uint8_t * wofs = & p_dst [ ( ( y * p_width ) + x ) * ( write_bytes + ( write_alpha ? 1 : 0 ) ) ] ;
uint8_t rgba [ 4 ] ;
if ( read_gray ) {
rgba [ 0 ] = rofs [ 0 ] ;
rgba [ 1 ] = rofs [ 0 ] ;
rgba [ 2 ] = rofs [ 0 ] ;
} else {
for ( uint32_t i = 0 ; i < max_bytes ; i + + ) {
rgba [ i ] = ( i < read_bytes ) ? rofs [ i ] : 0 ;
}
}
if ( read_alpha | | write_alpha ) {
rgba [ 3 ] = read_alpha ? rofs [ read_bytes ] : 255 ;
}
if ( write_gray ) {
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// TODO: not correct grayscale, should use fixed point version of actual weights
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wofs [ 0 ] = uint8_t ( ( uint16_t ( rofs [ 0 ] ) + uint16_t ( rofs [ 1 ] ) + uint16_t ( rofs [ 2 ] ) ) / 3 ) ;
} else {
for ( uint32_t i = 0 ; i < write_bytes ; i + + ) {
wofs [ i ] = rgba [ i ] ;
}
}
if ( write_alpha ) {
wofs [ write_bytes ] = rgba [ 3 ] ;
}
}
}
}
void Image : : convert ( Format p_new_format ) {
if ( data . size ( ) = = 0 ) {
return ;
}
if ( p_new_format = = format ) {
return ;
}
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ERR_FAIL_COND_MSG ( write_lock , " Cannot convert image when it is locked. " ) ;
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if ( format > FORMAT_RGBE9995 | | p_new_format > FORMAT_RGBE9995 ) {
ERR_FAIL_MSG ( " Cannot convert to <-> from compressed formats. Use compress() and decompress() instead. " ) ;
} else if ( format > FORMAT_RGBA8 | | p_new_format > FORMAT_RGBA8 ) {
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// use put/set pixel which is slower but works with non byte formats
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Image new_img ( width , height , false , p_new_format ) ;
lock ( ) ;
new_img . lock ( ) ;
for ( int i = 0 ; i < width ; i + + ) {
for ( int j = 0 ; j < height ; j + + ) {
new_img . set_pixel ( i , j , get_pixel ( i , j ) ) ;
}
}
unlock ( ) ;
new_img . unlock ( ) ;
if ( has_mipmaps ( ) ) {
new_img . generate_mipmaps ( ) ;
}
_copy_internals_from ( new_img ) ;
return ;
}
Image new_img ( width , height , false , p_new_format ) ;
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write_lock = true ;
const uint8_t * rptr = data . data ( ) ;
uint8_t * wptr = new_img . data . dataw ( ) ;
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int conversion_type = format | p_new_format < < 8 ;
switch ( conversion_type ) {
case FORMAT_L8 | ( FORMAT_LA8 < < 8 ) :
_convert < 1 , false , 1 , true , true , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_L8 | ( FORMAT_R8 < < 8 ) :
_convert < 1 , false , 1 , false , true , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_L8 | ( FORMAT_RG8 < < 8 ) :
_convert < 1 , false , 2 , false , true , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_L8 | ( FORMAT_RGB8 < < 8 ) :
_convert < 1 , false , 3 , false , true , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_L8 | ( FORMAT_RGBA8 < < 8 ) :
_convert < 1 , false , 3 , true , true , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_LA8 | ( FORMAT_L8 < < 8 ) :
_convert < 1 , true , 1 , false , true , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_LA8 | ( FORMAT_R8 < < 8 ) :
_convert < 1 , true , 1 , false , true , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_LA8 | ( FORMAT_RG8 < < 8 ) :
_convert < 1 , true , 2 , false , true , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_LA8 | ( FORMAT_RGB8 < < 8 ) :
_convert < 1 , true , 3 , false , true , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_LA8 | ( FORMAT_RGBA8 < < 8 ) :
_convert < 1 , true , 3 , true , true , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_R8 | ( FORMAT_L8 < < 8 ) :
_convert < 1 , false , 1 , false , false , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_R8 | ( FORMAT_LA8 < < 8 ) :
_convert < 1 , false , 1 , true , false , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_R8 | ( FORMAT_RG8 < < 8 ) :
_convert < 1 , false , 2 , false , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_R8 | ( FORMAT_RGB8 < < 8 ) :
_convert < 1 , false , 3 , false , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_R8 | ( FORMAT_RGBA8 < < 8 ) :
_convert < 1 , false , 3 , true , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RG8 | ( FORMAT_L8 < < 8 ) :
_convert < 2 , false , 1 , false , false , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RG8 | ( FORMAT_LA8 < < 8 ) :
_convert < 2 , false , 1 , true , false , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RG8 | ( FORMAT_R8 < < 8 ) :
_convert < 2 , false , 1 , false , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RG8 | ( FORMAT_RGB8 < < 8 ) :
_convert < 2 , false , 3 , false , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RG8 | ( FORMAT_RGBA8 < < 8 ) :
_convert < 2 , false , 3 , true , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGB8 | ( FORMAT_L8 < < 8 ) :
_convert < 3 , false , 1 , false , false , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGB8 | ( FORMAT_LA8 < < 8 ) :
_convert < 3 , false , 1 , true , false , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGB8 | ( FORMAT_R8 < < 8 ) :
_convert < 3 , false , 1 , false , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGB8 | ( FORMAT_RG8 < < 8 ) :
_convert < 3 , false , 2 , false , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGB8 | ( FORMAT_RGBA8 < < 8 ) :
_convert < 3 , false , 3 , true , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGBA8 | ( FORMAT_L8 < < 8 ) :
_convert < 3 , true , 1 , false , false , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGBA8 | ( FORMAT_LA8 < < 8 ) :
_convert < 3 , true , 1 , true , false , true > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGBA8 | ( FORMAT_R8 < < 8 ) :
_convert < 3 , true , 1 , false , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGBA8 | ( FORMAT_RG8 < < 8 ) :
_convert < 3 , true , 2 , false , false , false > ( width , height , rptr , wptr ) ;
break ;
case FORMAT_RGBA8 | ( FORMAT_RGB8 < < 8 ) :
_convert < 3 , true , 3 , false , false , false > ( width , height , rptr , wptr ) ;
break ;
}
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write_lock = false ;
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bool gen_mipmaps = mipmaps ;
_copy_internals_from ( new_img ) ;
if ( gen_mipmaps ) {
generate_mipmaps ( ) ;
}
}
Image : : Format Image : : get_format ( ) const {
return format ;
}
static double _bicubic_interp_kernel ( double x ) {
x = ABS ( x ) ;
double bc = 0 ;
if ( x < = 1 ) {
bc = ( 1.5 * x - 2.5 ) * x * x + 1 ;
} else if ( x < 2 ) {
bc = ( ( - 0.5 * x + 2.5 ) * x - 4 ) * x + 2 ;
}
return bc ;
}
template < int CC , class T >
static void _scale_cubic ( const uint8_t * __restrict p_src , uint8_t * __restrict p_dst , uint32_t p_src_width , uint32_t p_src_height , uint32_t p_dst_width , uint32_t p_dst_height ) {
// get source image size
int width = p_src_width ;
int height = p_src_height ;
double xfac = ( double ) width / p_dst_width ;
double yfac = ( double ) height / p_dst_height ;
// coordinates of source points and coefficients
double ox , oy , dx , dy , k1 , k2 ;
int ox1 , oy1 , ox2 , oy2 ;
// destination pixel values
// width and height decreased by 1
int ymax = height - 1 ;
int xmax = width - 1 ;
// temporary pointer
for ( uint32_t y = 0 ; y < p_dst_height ; y + + ) {
// Y coordinates
oy = ( double ) y * yfac - 0.5f ;
oy1 = ( int ) oy ;
dy = oy - ( double ) oy1 ;
for ( uint32_t x = 0 ; x < p_dst_width ; x + + ) {
// X coordinates
ox = ( double ) x * xfac - 0.5f ;
ox1 = ( int ) ox ;
dx = ox - ( double ) ox1 ;
// initial pixel value
T * __restrict dst = ( ( T * ) p_dst ) + ( y * p_dst_width + x ) * CC ;
double color [ CC ] ;
for ( int i = 0 ; i < CC ; i + + ) {
color [ i ] = 0 ;
}
for ( int n = - 1 ; n < 3 ; n + + ) {
// get Y coefficient
k1 = _bicubic_interp_kernel ( dy - ( double ) n ) ;
oy2 = oy1 + n ;
if ( oy2 < 0 ) {
oy2 = 0 ;
}
if ( oy2 > ymax ) {
oy2 = ymax ;
}
for ( int m = - 1 ; m < 3 ; m + + ) {
// get X coefficient
k2 = k1 * _bicubic_interp_kernel ( ( double ) m - dx ) ;
ox2 = ox1 + m ;
if ( ox2 < 0 ) {
ox2 = 0 ;
}
if ( ox2 > xmax ) {
ox2 = xmax ;
}
// get pixel of original image
const T * __restrict p = ( ( T * ) p_src ) + ( oy2 * p_src_width + ox2 ) * CC ;
for ( int i = 0 ; i < CC ; i + + ) {
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if ( sizeof ( T ) = = 2 ) { // half float
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color [ i ] = Math : : half_to_float ( p [ i ] ) ;
} else {
color [ i ] + = p [ i ] * k2 ;
}
}
}
}
for ( int i = 0 ; i < CC ; i + + ) {
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if ( sizeof ( T ) = = 1 ) { // byte
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dst [ i ] = CLAMP ( Math : : fast_ftoi ( color [ i ] ) , 0 , 255 ) ;
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} else if ( sizeof ( T ) = = 2 ) { // half float
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dst [ i ] = Math : : make_half_float ( color [ i ] ) ;
} else {
dst [ i ] = color [ i ] ;
}
}
}
}
}
template < int CC , class T >
static void _scale_bilinear ( const uint8_t * __restrict p_src , uint8_t * __restrict p_dst , uint32_t p_src_width , uint32_t p_src_height , uint32_t p_dst_width , uint32_t p_dst_height ) {
enum {
FRAC_BITS = 8 ,
FRAC_LEN = ( 1 < < FRAC_BITS ) ,
FRAC_HALF = ( FRAC_LEN > > 1 ) ,
FRAC_MASK = FRAC_LEN - 1
} ;
for ( uint32_t i = 0 ; i < p_dst_height ; i + + ) {
// Add 0.5 in order to interpolate based on pixel center
uint32_t src_yofs_up_fp = ( i + 0.5 ) * p_src_height * FRAC_LEN / p_dst_height ;
// Calculate nearest src pixel center above current, and truncate to get y index
uint32_t src_yofs_up = src_yofs_up_fp > = FRAC_HALF ? ( src_yofs_up_fp - FRAC_HALF ) > > FRAC_BITS : 0 ;
uint32_t src_yofs_down = ( src_yofs_up_fp + FRAC_HALF ) > > FRAC_BITS ;
if ( src_yofs_down > = p_src_height ) {
src_yofs_down = p_src_height - 1 ;
}
// Calculate distance to pixel center of src_yofs_up
uint32_t src_yofs_frac = src_yofs_up_fp & FRAC_MASK ;
src_yofs_frac = src_yofs_frac > = FRAC_HALF ? src_yofs_frac - FRAC_HALF : src_yofs_frac + FRAC_HALF ;
uint32_t y_ofs_up = src_yofs_up * p_src_width * CC ;
uint32_t y_ofs_down = src_yofs_down * p_src_width * CC ;
for ( uint32_t j = 0 ; j < p_dst_width ; j + + ) {
uint32_t src_xofs_left_fp = ( j + 0.5 ) * p_src_width * FRAC_LEN / p_dst_width ;
uint32_t src_xofs_left = src_xofs_left_fp > = FRAC_HALF ? ( src_xofs_left_fp - FRAC_HALF ) > > FRAC_BITS : 0 ;
uint32_t src_xofs_right = ( src_xofs_left_fp + FRAC_HALF ) > > FRAC_BITS ;
if ( src_xofs_right > = p_src_width ) {
src_xofs_right = p_src_width - 1 ;
}
uint32_t src_xofs_frac = src_xofs_left_fp & FRAC_MASK ;
src_xofs_frac = src_xofs_frac > = FRAC_HALF ? src_xofs_frac - FRAC_HALF : src_xofs_frac + FRAC_HALF ;
src_xofs_left * = CC ;
src_xofs_right * = CC ;
for ( uint32_t l = 0 ; l < CC ; l + + ) {
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if ( sizeof ( T ) = = 1 ) { // uint8
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uint32_t p00 = p_src [ y_ofs_up + src_xofs_left + l ] < < FRAC_BITS ;
uint32_t p10 = p_src [ y_ofs_up + src_xofs_right + l ] < < FRAC_BITS ;
uint32_t p01 = p_src [ y_ofs_down + src_xofs_left + l ] < < FRAC_BITS ;
uint32_t p11 = p_src [ y_ofs_down + src_xofs_right + l ] < < FRAC_BITS ;
uint32_t interp_up = p00 + ( ( ( p10 - p00 ) * src_xofs_frac ) > > FRAC_BITS ) ;
uint32_t interp_down = p01 + ( ( ( p11 - p01 ) * src_xofs_frac ) > > FRAC_BITS ) ;
uint32_t interp = interp_up + ( ( ( interp_down - interp_up ) * src_yofs_frac ) > > FRAC_BITS ) ;
interp > > = FRAC_BITS ;
p_dst [ i * p_dst_width * CC + j * CC + l ] = interp ;
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} else if ( sizeof ( T ) = = 2 ) { // half float
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float xofs_frac = float ( src_xofs_frac ) / ( 1 < < FRAC_BITS ) ;
float yofs_frac = float ( src_yofs_frac ) / ( 1 < < FRAC_BITS ) ;
const T * src = ( ( const T * ) p_src ) ;
T * dst = ( ( T * ) p_dst ) ;
float p00 = Math : : half_to_float ( src [ y_ofs_up + src_xofs_left + l ] ) ;
float p10 = Math : : half_to_float ( src [ y_ofs_up + src_xofs_right + l ] ) ;
float p01 = Math : : half_to_float ( src [ y_ofs_down + src_xofs_left + l ] ) ;
float p11 = Math : : half_to_float ( src [ y_ofs_down + src_xofs_right + l ] ) ;
float interp_up = p00 + ( p10 - p00 ) * xofs_frac ;
float interp_down = p01 + ( p11 - p01 ) * xofs_frac ;
float interp = interp_up + ( ( interp_down - interp_up ) * yofs_frac ) ;
dst [ i * p_dst_width * CC + j * CC + l ] = Math : : make_half_float ( interp ) ;
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} else if ( sizeof ( T ) = = 4 ) { // float
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float xofs_frac = float ( src_xofs_frac ) / ( 1 < < FRAC_BITS ) ;
float yofs_frac = float ( src_yofs_frac ) / ( 1 < < FRAC_BITS ) ;
const T * src = ( ( const T * ) p_src ) ;
T * dst = ( ( T * ) p_dst ) ;
float p00 = src [ y_ofs_up + src_xofs_left + l ] ;
float p10 = src [ y_ofs_up + src_xofs_right + l ] ;
float p01 = src [ y_ofs_down + src_xofs_left + l ] ;
float p11 = src [ y_ofs_down + src_xofs_right + l ] ;
float interp_up = p00 + ( p10 - p00 ) * xofs_frac ;
float interp_down = p01 + ( p11 - p01 ) * xofs_frac ;
float interp = interp_up + ( ( interp_down - interp_up ) * yofs_frac ) ;
dst [ i * p_dst_width * CC + j * CC + l ] = interp ;
}
}
}
}
}
template < int CC , class T >
static void _scale_nearest ( const uint8_t * __restrict p_src , uint8_t * __restrict p_dst , uint32_t p_src_width , uint32_t p_src_height , uint32_t p_dst_width , uint32_t p_dst_height ) {
for ( uint32_t i = 0 ; i < p_dst_height ; i + + ) {
uint32_t src_yofs = i * p_src_height / p_dst_height ;
uint32_t y_ofs = src_yofs * p_src_width * CC ;
for ( uint32_t j = 0 ; j < p_dst_width ; j + + ) {
uint32_t src_xofs = j * p_src_width / p_dst_width ;
src_xofs * = CC ;
for ( uint32_t l = 0 ; l < CC ; l + + ) {
const T * src = ( ( const T * ) p_src ) ;
T * dst = ( ( T * ) p_dst ) ;
T p = src [ y_ofs + src_xofs + l ] ;
dst [ i * p_dst_width * CC + j * CC + l ] = p ;
}
}
}
}
# define LANCZOS_TYPE 3
static float _lanczos ( float p_x ) {
return Math : : abs ( p_x ) > = LANCZOS_TYPE ? 0 : Math : : sincn ( p_x ) * Math : : sincn ( p_x / LANCZOS_TYPE ) ;
}
template < int CC , class T >
static void _scale_lanczos ( const uint8_t * __restrict p_src , uint8_t * __restrict p_dst , uint32_t p_src_width , uint32_t p_src_height , uint32_t p_dst_width , uint32_t p_dst_height ) {
int32_t src_width = p_src_width ;
int32_t src_height = p_src_height ;
int32_t dst_height = p_dst_height ;
int32_t dst_width = p_dst_width ;
uint32_t buffer_size = src_height * dst_width * CC ;
float * buffer = memnew_arr ( float , buffer_size ) ; // Store the first pass in a buffer
{ // FIRST PASS (horizontal)
float x_scale = float ( src_width ) / float ( dst_width ) ;
float scale_factor = MAX ( x_scale , 1 ) ; // A larger kernel is required only when downscaling
int32_t half_kernel = LANCZOS_TYPE * scale_factor ;
float * kernel = memnew_arr ( float , half_kernel * 2 ) ;
for ( int32_t buffer_x = 0 ; buffer_x < dst_width ; buffer_x + + ) {
// The corresponding point on the source image
float src_x = ( buffer_x + 0.5f ) * x_scale ; // Offset by 0.5 so it uses the pixel's center
int32_t start_x = MAX ( 0 , int32_t ( src_x ) - half_kernel + 1 ) ;
int32_t end_x = MIN ( src_width - 1 , int32_t ( src_x ) + half_kernel ) ;
// Create the kernel used by all the pixels of the column
for ( int32_t target_x = start_x ; target_x < = end_x ; target_x + + ) {
kernel [ target_x - start_x ] = _lanczos ( ( target_x + 0.5f - src_x ) / scale_factor ) ;
}
for ( int32_t buffer_y = 0 ; buffer_y < src_height ; buffer_y + + ) {
float pixel [ CC ] = { 0 } ;
float weight = 0 ;
for ( int32_t target_x = start_x ; target_x < = end_x ; target_x + + ) {
float lanczos_val = kernel [ target_x - start_x ] ;
weight + = lanczos_val ;
const T * __restrict src_data = ( ( const T * ) p_src ) + ( buffer_y * src_width + target_x ) * CC ;
for ( uint32_t i = 0 ; i < CC ; i + + ) {
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if ( sizeof ( T ) = = 2 ) { // half float
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pixel [ i ] + = Math : : half_to_float ( src_data [ i ] ) * lanczos_val ;
} else {
pixel [ i ] + = src_data [ i ] * lanczos_val ;
}
}
}
float * dst_data = ( ( float * ) buffer ) + ( buffer_y * dst_width + buffer_x ) * CC ;
for ( uint32_t i = 0 ; i < CC ; i + + ) {
dst_data [ i ] = pixel [ i ] / weight ; // Normalize the sum of all the samples
}
}
}
memdelete_arr ( kernel ) ;
} // End of first pass
{ // SECOND PASS (vertical + result)
float y_scale = float ( src_height ) / float ( dst_height ) ;
float scale_factor = MAX ( y_scale , 1 ) ;
int32_t half_kernel = LANCZOS_TYPE * scale_factor ;
float * kernel = memnew_arr ( float , half_kernel * 2 ) ;
for ( int32_t dst_y = 0 ; dst_y < dst_height ; dst_y + + ) {
float buffer_y = ( dst_y + 0.5f ) * y_scale ;
int32_t start_y = MAX ( 0 , int32_t ( buffer_y ) - half_kernel + 1 ) ;
int32_t end_y = MIN ( src_height - 1 , int32_t ( buffer_y ) + half_kernel ) ;
for ( int32_t target_y = start_y ; target_y < = end_y ; target_y + + ) {
kernel [ target_y - start_y ] = _lanczos ( ( target_y + 0.5f - buffer_y ) / scale_factor ) ;
}
for ( int32_t dst_x = 0 ; dst_x < dst_width ; dst_x + + ) {
float pixel [ CC ] = { 0 } ;
float weight = 0 ;
for ( int32_t target_y = start_y ; target_y < = end_y ; target_y + + ) {
float lanczos_val = kernel [ target_y - start_y ] ;
weight + = lanczos_val ;
float * buffer_data = ( ( float * ) buffer ) + ( target_y * dst_width + dst_x ) * CC ;
for ( uint32_t i = 0 ; i < CC ; i + + ) {
pixel [ i ] + = buffer_data [ i ] * lanczos_val ;
}
}
T * dst_data = ( ( T * ) p_dst ) + ( dst_y * dst_width + dst_x ) * CC ;
for ( uint32_t i = 0 ; i < CC ; i + + ) {
pixel [ i ] / = weight ;
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if ( sizeof ( T ) = = 1 ) { // byte
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dst_data [ i ] = CLAMP ( Math : : fast_ftoi ( pixel [ i ] ) , 0 , 255 ) ;
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} else if ( sizeof ( T ) = = 2 ) { // half float
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dst_data [ i ] = Math : : make_half_float ( pixel [ i ] ) ;
} else { // float
dst_data [ i ] = pixel [ i ] ;
}
}
}
}
memdelete_arr ( kernel ) ;
} // End of second pass
memdelete_arr ( buffer ) ;
}
static void _overlay ( const uint8_t * __restrict p_src , uint8_t * __restrict p_dst , float p_alpha , uint32_t p_width , uint32_t p_height , uint32_t p_pixel_size ) {
uint16_t alpha = MIN ( ( uint16_t ) ( p_alpha * 256.0f ) , 256 ) ;
for ( uint32_t i = 0 ; i < p_width * p_height * p_pixel_size ; i + + ) {
p_dst [ i ] = ( p_dst [ i ] * ( 256 - alpha ) + p_src [ i ] * alpha ) > > 8 ;
}
}
bool Image : : is_size_po2 ( ) const {
return uint32_t ( width ) = = next_power_of_2 ( width ) & & uint32_t ( height ) = = next_power_of_2 ( height ) ;
}
void Image : : resize_to_po2 ( bool p_square , Interpolation p_interpolation ) {
ERR_FAIL_COND_MSG ( ! _can_modify ( format ) , " Cannot resize in compressed or custom image formats. " ) ;
int w = next_power_of_2 ( width ) ;
int h = next_power_of_2 ( height ) ;
if ( p_square ) {
w = h = MAX ( w , h ) ;
}
if ( w = = width & & h = = height ) {
if ( ! p_square | | w = = h ) {
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return ; // nothing to do
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}
}
resize ( w , h , p_interpolation ) ;
}
void Image : : resize ( int p_width , int p_height , Interpolation p_interpolation ) {
ERR_FAIL_COND_MSG ( data . size ( ) = = 0 , " Cannot resize image before creating it, use create() or create_from_data() first. " ) ;
ERR_FAIL_COND_MSG ( ! _can_modify ( format ) , " Cannot resize in compressed or custom image formats. " ) ;
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ERR_FAIL_COND_MSG ( write_lock , " Cannot resize image when it is locked. " ) ;
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bool mipmap_aware = p_interpolation = = INTERPOLATE_TRILINEAR /* || p_interpolation == INTERPOLATE_TRICUBIC */ ;
ERR_FAIL_COND_MSG ( p_width < = 0 , " Image width must be greater than 0. " ) ;
ERR_FAIL_COND_MSG ( p_height < = 0 , " Image height must be greater than 0. " ) ;
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ERR_FAIL_COND_MSG ( p_width > MAX_WIDTH , " Image width cannot be greater than " + String : : num ( MAX_WIDTH ) + " . " ) ;
ERR_FAIL_COND_MSG ( p_height > MAX_HEIGHT , " Image height cannot be greater than " + String : : num ( MAX_HEIGHT ) + " . " ) ;
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if ( p_width = = width & & p_height = = height ) {
return ;
}
Image dst ( p_width , p_height , false , format ) ;
// Setup mipmap-aware scaling
Image dst2 ;
int mip1 = 0 ;
int mip2 = 0 ;
float mip1_weight = 0 ;
if ( mipmap_aware ) {
float avg_scale = ( ( float ) p_width / width + ( float ) p_height / height ) * 0.5f ;
if ( avg_scale > = 1.0f ) {
mipmap_aware = false ;
} else {
float level = Math : : log ( 1.0f / avg_scale ) / Math : : log ( 2.0f ) ;
mip1 = CLAMP ( ( int ) Math : : floor ( level ) , 0 , get_mipmap_count ( ) ) ;
mip2 = CLAMP ( ( int ) Math : : ceil ( level ) , 0 , get_mipmap_count ( ) ) ;
mip1_weight = 1.0f - ( level - mip1 ) ;
}
}
bool interpolate_mipmaps = mipmap_aware & & mip1 ! = mip2 ;
if ( interpolate_mipmaps ) {
dst2 . create ( p_width , p_height , false , format ) ;
}
bool had_mipmaps = mipmaps ;
if ( interpolate_mipmaps & & ! had_mipmaps ) {
generate_mipmaps ( ) ;
}
// --
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write_lock = true ;
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const unsigned char * r_ptr = data . data ( ) ;
unsigned char * w_ptr = dst . data . dataw ( ) ;
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switch ( p_interpolation ) {
case INTERPOLATE_NEAREST : {
if ( format > = FORMAT_L8 & & format < = FORMAT_RGBA8 ) {
switch ( get_format_pixel_size ( format ) ) {
case 1 :
_scale_nearest < 1 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 2 :
_scale_nearest < 2 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 3 :
_scale_nearest < 3 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 4 :
_scale_nearest < 4 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
}
} else if ( format > = FORMAT_RF & & format < = FORMAT_RGBAF ) {
switch ( get_format_pixel_size ( format ) ) {
case 4 :
_scale_nearest < 1 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 8 :
_scale_nearest < 2 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 12 :
_scale_nearest < 3 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 16 :
_scale_nearest < 4 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
}
} else if ( format > = FORMAT_RH & & format < = FORMAT_RGBAH ) {
switch ( get_format_pixel_size ( format ) ) {
case 2 :
_scale_nearest < 1 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 4 :
_scale_nearest < 2 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 6 :
_scale_nearest < 3 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 8 :
_scale_nearest < 4 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
}
}
} break ;
case INTERPOLATE_BILINEAR :
case INTERPOLATE_TRILINEAR : {
for ( int i = 0 ; i < 2 ; + + i ) {
int src_width ;
int src_height ;
const unsigned char * src_ptr ;
if ( ! mipmap_aware ) {
if ( i = = 0 ) {
// Standard behavior
src_width = width ;
src_height = height ;
src_ptr = r_ptr ;
} else {
// No need for a second iteration
break ;
}
} else {
if ( i = = 0 ) {
// Read from the first mipmap that will be interpolated
// (if both levels are the same, we will not interpolate, but at least we'll sample from the right level)
int offs ;
_get_mipmap_offset_and_size ( mip1 , offs , src_width , src_height ) ;
src_ptr = r_ptr + offs ;
} else if ( ! interpolate_mipmaps ) {
// No need generate a second image
break ;
} else {
// Switch to read from the second mipmap that will be interpolated
int offs ;
_get_mipmap_offset_and_size ( mip2 , offs , src_width , src_height ) ;
src_ptr = r_ptr + offs ;
// Switch to write to the second destination image
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w_ptr = dst2 . data . dataw ( ) ;
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}
}
if ( format > = FORMAT_L8 & & format < = FORMAT_RGBA8 ) {
switch ( get_format_pixel_size ( format ) ) {
case 1 :
_scale_bilinear < 1 , uint8_t > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
case 2 :
_scale_bilinear < 2 , uint8_t > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
case 3 :
_scale_bilinear < 3 , uint8_t > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
case 4 :
_scale_bilinear < 4 , uint8_t > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
}
} else if ( format > = FORMAT_RF & & format < = FORMAT_RGBAF ) {
switch ( get_format_pixel_size ( format ) ) {
case 4 :
_scale_bilinear < 1 , float > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
case 8 :
_scale_bilinear < 2 , float > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
case 12 :
_scale_bilinear < 3 , float > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
case 16 :
_scale_bilinear < 4 , float > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
}
} else if ( format > = FORMAT_RH & & format < = FORMAT_RGBAH ) {
switch ( get_format_pixel_size ( format ) ) {
case 2 :
_scale_bilinear < 1 , uint16_t > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
case 4 :
_scale_bilinear < 2 , uint16_t > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
case 6 :
_scale_bilinear < 3 , uint16_t > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
case 8 :
_scale_bilinear < 4 , uint16_t > ( src_ptr , w_ptr , src_width , src_height , p_width , p_height ) ;
break ;
}
}
}
if ( interpolate_mipmaps ) {
// Switch to read again from the first scaled mipmap to overlay it over the second
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_overlay ( dst . data . data ( ) , w_ptr , mip1_weight , p_width , p_height , get_format_pixel_size ( format ) ) ;
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}
} break ;
case INTERPOLATE_CUBIC : {
if ( format > = FORMAT_L8 & & format < = FORMAT_RGBA8 ) {
switch ( get_format_pixel_size ( format ) ) {
case 1 :
_scale_cubic < 1 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 2 :
_scale_cubic < 2 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 3 :
_scale_cubic < 3 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 4 :
_scale_cubic < 4 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
}
} else if ( format > = FORMAT_RF & & format < = FORMAT_RGBAF ) {
switch ( get_format_pixel_size ( format ) ) {
case 4 :
_scale_cubic < 1 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 8 :
_scale_cubic < 2 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 12 :
_scale_cubic < 3 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 16 :
_scale_cubic < 4 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
}
} else if ( format > = FORMAT_RH & & format < = FORMAT_RGBAH ) {
switch ( get_format_pixel_size ( format ) ) {
case 2 :
_scale_cubic < 1 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 4 :
_scale_cubic < 2 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 6 :
_scale_cubic < 3 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 8 :
_scale_cubic < 4 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
}
}
} break ;
case INTERPOLATE_LANCZOS : {
if ( format > = FORMAT_L8 & & format < = FORMAT_RGBA8 ) {
switch ( get_format_pixel_size ( format ) ) {
case 1 :
_scale_lanczos < 1 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 2 :
_scale_lanczos < 2 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 3 :
_scale_lanczos < 3 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 4 :
_scale_lanczos < 4 , uint8_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
}
} else if ( format > = FORMAT_RF & & format < = FORMAT_RGBAF ) {
switch ( get_format_pixel_size ( format ) ) {
case 4 :
_scale_lanczos < 1 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 8 :
_scale_lanczos < 2 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 12 :
_scale_lanczos < 3 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 16 :
_scale_lanczos < 4 , float > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
}
} else if ( format > = FORMAT_RH & & format < = FORMAT_RGBAH ) {
switch ( get_format_pixel_size ( format ) ) {
case 2 :
_scale_lanczos < 1 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 4 :
_scale_lanczos < 2 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 6 :
_scale_lanczos < 3 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
case 8 :
_scale_lanczos < 4 , uint16_t > ( r_ptr , w_ptr , width , height , p_width , p_height ) ;
break ;
}
}
} break ;
}
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write_lock = false ;
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if ( interpolate_mipmaps ) {
dst . _copy_internals_from ( dst2 ) ;
}
if ( had_mipmaps ) {
dst . generate_mipmaps ( ) ;
}
_copy_internals_from ( dst ) ;
}
void Image : : crop_from_point ( int p_x , int p_y , int p_width , int p_height ) {
ERR_FAIL_COND_MSG ( ! _can_modify ( format ) , " Cannot crop in compressed or custom image formats. " ) ;
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ERR_FAIL_COND_MSG ( write_lock , " Cannot modify image when it is locked. " ) ;
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ERR_FAIL_COND_MSG ( p_x < 0 , " Start x position cannot be smaller than 0. " ) ;
ERR_FAIL_COND_MSG ( p_y < 0 , " Start y position cannot be smaller than 0. " ) ;
ERR_FAIL_COND_MSG ( p_width < = 0 , " Width of image must be greater than 0. " ) ;
ERR_FAIL_COND_MSG ( p_height < = 0 , " Height of image must be greater than 0. " ) ;
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ERR_FAIL_COND_MSG ( p_x + p_width > MAX_WIDTH , " End x position cannot be greater than " + String : : num ( MAX_WIDTH ) + " . " ) ;
ERR_FAIL_COND_MSG ( p_y + p_height > MAX_HEIGHT , " End y position cannot be greater than " + String : : num ( MAX_HEIGHT ) + " . " ) ;
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/* to save memory, cropping should be done in-place, however, since this function
will most likely either not be used much , or in critical areas , for now it won ' t , because
it ' s a waste of time . */
if ( p_width = = width & & p_height = = height & & p_x = = 0 & & p_y = = 0 ) {
return ;
}
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uint8_t pdata [ 16 ] ; // largest is 16
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uint32_t pixel_size = get_format_pixel_size ( format ) ;
Image dst ( p_width , p_height , false , format ) ;
{
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write_lock = true ;
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int m_h = p_y + p_height ;
int m_w = p_x + p_width ;
for ( int y = p_y ; y < m_h ; y + + ) {
for ( int x = p_x ; x < m_w ; x + + ) {
if ( ( x > = width | | y > = height ) ) {
for ( uint32_t i = 0 ; i < pixel_size ; i + + ) {
pdata [ i ] = 0 ;
}
} else {
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_get_pixelb ( x , y , pixel_size , data . data ( ) , pdata ) ;
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}
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dst . _put_pixelb ( x - p_x , y - p_y , pixel_size , dst . data . dataw ( ) , pdata ) ;
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}
}
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write_lock = false ;
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}
if ( has_mipmaps ( ) ) {
dst . generate_mipmaps ( ) ;
}
_copy_internals_from ( dst ) ;
}
void Image : : crop ( int p_width , int p_height ) {
crop_from_point ( 0 , 0 , p_width , p_height ) ;
}
void Image : : flip_y ( ) {
ERR_FAIL_COND_MSG ( ! _can_modify ( format ) , " Cannot flip_y in compressed or custom image formats. " ) ;
bool used_mipmaps = has_mipmaps ( ) ;
if ( used_mipmaps ) {
clear_mipmaps ( ) ;
}
{
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write_lock = true ;
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uint8_t up [ 16 ] ;
uint8_t down [ 16 ] ;
uint32_t pixel_size = get_format_pixel_size ( format ) ;
for ( int y = 0 ; y < height / 2 ; y + + ) {
for ( int x = 0 ; x < width ; x + + ) {
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_get_pixelb ( x , y , pixel_size , data . data ( ) , up ) ;
_get_pixelb ( x , height - y - 1 , pixel_size , data . data ( ) , down ) ;
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_put_pixelb ( x , height - y - 1 , pixel_size , data . dataw ( ) , up ) ;
_put_pixelb ( x , y , pixel_size , data . dataw ( ) , down ) ;
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}
}
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write_lock = false ;
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}
if ( used_mipmaps ) {
generate_mipmaps ( ) ;
}
}
void Image : : flip_x ( ) {
ERR_FAIL_COND_MSG ( ! _can_modify ( format ) , " Cannot flip_x in compressed or custom image formats. " ) ;
bool used_mipmaps = has_mipmaps ( ) ;
if ( used_mipmaps ) {
clear_mipmaps ( ) ;
}
{
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write_lock = true ;
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uint8_t up [ 16 ] ;
uint8_t down [ 16 ] ;
uint32_t pixel_size = get_format_pixel_size ( format ) ;
for ( int y = 0 ; y < height ; y + + ) {
for ( int x = 0 ; x < width / 2 ; x + + ) {
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_get_pixelb ( x , y , pixel_size , data . data ( ) , up ) ;
_get_pixelb ( width - x - 1 , y , pixel_size , data . data ( ) , down ) ;
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_put_pixelb ( width - x - 1 , y , pixel_size , data . dataw ( ) , up ) ;
_put_pixelb ( x , y , pixel_size , data . dataw ( ) , down ) ;
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}
}
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write_lock = false ;
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}
if ( used_mipmaps ) {
generate_mipmaps ( ) ;
}
}
int Image : : _get_dst_image_size ( int p_width , int p_height , Format p_format , int & r_mipmaps , int p_mipmaps ) {
int size = 0 ;
int w = p_width ;
int h = p_height ;
int mm = 0 ;
int pixsize = get_format_pixel_size ( p_format ) ;
int pixshift = get_format_pixel_rshift ( p_format ) ;
int block = get_format_block_size ( p_format ) ;
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// technically, you can still compress up to 1 px no matter the format, so commenting this
// int minw, minh;
// get_format_min_pixel_size(p_format, minw, minh);
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int minw = 1 , minh = 1 ;
while ( true ) {
int bw = w % block ! = 0 ? w + ( block - w % block ) : w ;
int bh = h % block ! = 0 ? h + ( block - h % block ) : h ;
int s = bw * bh ;
s * = pixsize ;
s > > = pixshift ;
size + = s ;
if ( p_mipmaps > = 0 & & mm = = p_mipmaps ) {
break ;
}
if ( p_mipmaps > = 0 ) {
w = MAX ( minw , w > > 1 ) ;
h = MAX ( minh , h > > 1 ) ;
} else {
if ( w = = minw & & h = = minh ) {
break ;
}
w = MAX ( minw , w > > 1 ) ;
h = MAX ( minh , h > > 1 ) ;
}
mm + + ;
} ;
r_mipmaps = mm ;
return size ;
}
bool Image : : _can_modify ( Format p_format ) const {
return p_format < = FORMAT_RGBE9995 ;
}
template < class Component , int CC , bool renormalize ,
void ( * average_func ) ( Component & , const Component & , const Component & , const Component & , const Component & ) ,
void ( * renormalize_func ) ( Component * ) >
static void _generate_po2_mipmap ( const Component * p_src , Component * p_dst , uint32_t p_width , uint32_t p_height ) {
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// fast power of 2 mipmap generation
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uint32_t dst_w = MAX ( p_width > > 1 , 1 ) ;
uint32_t dst_h = MAX ( p_height > > 1 , 1 ) ;
int right_step = ( p_width = = 1 ) ? 0 : CC ;
int down_step = ( p_height = = 1 ) ? 0 : ( p_width * CC ) ;
for ( uint32_t i = 0 ; i < dst_h ; i + + ) {
const Component * rup_ptr = & p_src [ i * 2 * down_step ] ;
const Component * rdown_ptr = rup_ptr + down_step ;
Component * dst_ptr = & p_dst [ i * dst_w * CC ] ;
uint32_t count = dst_w ;
while ( count ) {
count - - ;
for ( int j = 0 ; j < CC ; j + + ) {
average_func ( dst_ptr [ j ] , rup_ptr [ j ] , rup_ptr [ j + right_step ] , rdown_ptr [ j ] , rdown_ptr [ j + right_step ] ) ;
}
if ( renormalize ) {
renormalize_func ( dst_ptr ) ;
}
dst_ptr + = CC ;
rup_ptr + = right_step * 2 ;
rdown_ptr + = right_step * 2 ;
}
}
}
void Image : : shrink_x2 ( ) {
ERR_FAIL_COND ( ! _can_modify ( format ) ) ;
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ERR_FAIL_COND_MSG ( write_lock , " Cannot modify image when it is locked. " ) ;
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ERR_FAIL_COND ( data . size ( ) = = 0 ) ;
if ( mipmaps ) {
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// just use the lower mipmap as base and copy all
Vector < uint8_t > new_img ;
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int ofs = get_mipmap_offset ( 1 ) ;
int new_size = data . size ( ) - ofs ;
new_img . resize ( new_size ) ;
ERR_FAIL_COND ( new_img . size ( ) = = 0 ) ;
{
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write_lock = true ;
memcpy ( new_img . dataw ( ) , & data . data ( ) [ ofs ] , new_size ) ;
write_lock = false ;
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}
width = MAX ( width / 2 , 1 ) ;
height = MAX ( height / 2 , 1 ) ;
data = new_img ;
} else {
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Vector < uint8_t > new_img ;
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ERR_FAIL_COND ( ! _can_modify ( format ) ) ;
int ps = get_format_pixel_size ( format ) ;
new_img . resize ( ( width / 2 ) * ( height / 2 ) * ps ) ;
ERR_FAIL_COND ( new_img . size ( ) = = 0 ) ;
ERR_FAIL_COND ( data . size ( ) = = 0 ) ;
{
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write_lock = true ;
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switch ( format ) {
case FORMAT_L8 :
case FORMAT_R8 :
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_generate_po2_mipmap < uint8_t , 1 , false , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( data . data ( ) , new_img . dataw ( ) , width , height ) ;
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break ;
case FORMAT_LA8 :
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_generate_po2_mipmap < uint8_t , 2 , false , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( data . data ( ) , new_img . dataw ( ) , width , height ) ;
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break ;
case FORMAT_RG8 :
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_generate_po2_mipmap < uint8_t , 2 , false , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( data . data ( ) , new_img . dataw ( ) , width , height ) ;
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break ;
case FORMAT_RGB8 :
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_generate_po2_mipmap < uint8_t , 3 , false , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( data . data ( ) , new_img . dataw ( ) , width , height ) ;
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break ;
case FORMAT_RGBA8 :
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_generate_po2_mipmap < uint8_t , 4 , false , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( data . data ( ) , new_img . dataw ( ) , width , height ) ;
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break ;
case FORMAT_RF :
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_generate_po2_mipmap < float , 1 , false , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( data . data ( ) ) , reinterpret_cast < float * > ( new_img . dataw ( ) ) , width , height ) ;
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break ;
case FORMAT_RGF :
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_generate_po2_mipmap < float , 2 , false , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( data . data ( ) ) , reinterpret_cast < float * > ( new_img . dataw ( ) ) , width , height ) ;
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break ;
case FORMAT_RGBF :
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_generate_po2_mipmap < float , 3 , false , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( data . data ( ) ) , reinterpret_cast < float * > ( new_img . dataw ( ) ) , width , height ) ;
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break ;
case FORMAT_RGBAF :
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_generate_po2_mipmap < float , 4 , false , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( data . data ( ) ) , reinterpret_cast < float * > ( new_img . dataw ( ) ) , width , height ) ;
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break ;
case FORMAT_RH :
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_generate_po2_mipmap < uint16_t , 1 , false , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( data . data ( ) ) , reinterpret_cast < uint16_t * > ( new_img . dataw ( ) ) , width , height ) ;
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break ;
case FORMAT_RGH :
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_generate_po2_mipmap < uint16_t , 2 , false , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( data . data ( ) ) , reinterpret_cast < uint16_t * > ( new_img . dataw ( ) ) , width , height ) ;
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break ;
case FORMAT_RGBH :
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_generate_po2_mipmap < uint16_t , 3 , false , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( data . data ( ) ) , reinterpret_cast < uint16_t * > ( new_img . dataw ( ) ) , width , height ) ;
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break ;
case FORMAT_RGBAH :
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_generate_po2_mipmap < uint16_t , 4 , false , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( data . data ( ) ) , reinterpret_cast < uint16_t * > ( new_img . dataw ( ) ) , width , height ) ;
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break ;
case FORMAT_RGBE9995 :
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_generate_po2_mipmap < uint32_t , 1 , false , Image : : average_4_rgbe9995 , Image : : renormalize_rgbe9995 > ( reinterpret_cast < const uint32_t * > ( data . data ( ) ) , reinterpret_cast < uint32_t * > ( new_img . dataw ( ) ) , width , height ) ;
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break ;
default : {
}
}
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write_lock = false ;
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}
width / = 2 ;
height / = 2 ;
data = new_img ;
}
}
void Image : : normalize ( ) {
bool used_mipmaps = has_mipmaps ( ) ;
if ( used_mipmaps ) {
clear_mipmaps ( ) ;
}
lock ( ) ;
for ( int y = 0 ; y < height ; y + + ) {
for ( int x = 0 ; x < width ; x + + ) {
Color c = get_pixel ( x , y ) ;
Vector3 v ( c . r * 2.0 - 1.0 , c . g * 2.0 - 1.0 , c . b * 2.0 - 1.0 ) ;
v . normalize ( ) ;
c . r = v . x * 0.5 + 0.5 ;
c . g = v . y * 0.5 + 0.5 ;
c . b = v . z * 0.5 + 0.5 ;
set_pixel ( x , y , c ) ;
}
}
unlock ( ) ;
if ( used_mipmaps ) {
generate_mipmaps ( true ) ;
}
}
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int Image : : generate_mipmaps ( bool p_renormalize ) {
ERR_FAIL_COND_V_MSG ( ! _can_modify ( format ) , 1 , " Cannot generate mipmaps in compressed or custom image formats. " ) ;
ERR_FAIL_COND_V_MSG ( write_lock , 1 , " Cannot modify image when it is locked. " ) ;
ERR_FAIL_COND_V_MSG ( format = = FORMAT_RGBA4444 | | format = = FORMAT_RGBA5551 , 1 , " Cannot generate mipmaps in custom image formats. " ) ;
ERR_FAIL_COND_V_MSG ( width = = 0 | | height = = 0 , 2 , " Cannot generate mipmaps with width or height equal to 0. " ) ;
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int mmcount ;
int size = _get_dst_image_size ( width , height , format , mmcount ) ;
data . resize ( size ) ;
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uint8_t * wp = data . dataw ( ) ;
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int prev_ofs = 0 ;
int prev_h = height ;
int prev_w = width ;
for ( int i = 1 ; i < = mmcount ; i + + ) {
int ofs , w , h ;
_get_mipmap_offset_and_size ( i , ofs , w , h ) ;
switch ( format ) {
case FORMAT_L8 :
case FORMAT_R8 :
_generate_po2_mipmap < uint8_t , 1 , false , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( & wp [ prev_ofs ] , & wp [ ofs ] , prev_w , prev_h ) ;
break ;
case FORMAT_LA8 :
case FORMAT_RG8 :
_generate_po2_mipmap < uint8_t , 2 , false , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( & wp [ prev_ofs ] , & wp [ ofs ] , prev_w , prev_h ) ;
break ;
case FORMAT_RGB8 :
if ( p_renormalize ) {
_generate_po2_mipmap < uint8_t , 3 , true , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( & wp [ prev_ofs ] , & wp [ ofs ] , prev_w , prev_h ) ;
} else {
_generate_po2_mipmap < uint8_t , 3 , false , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( & wp [ prev_ofs ] , & wp [ ofs ] , prev_w , prev_h ) ;
}
break ;
case FORMAT_RGBA8 :
if ( p_renormalize ) {
_generate_po2_mipmap < uint8_t , 4 , true , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( & wp [ prev_ofs ] , & wp [ ofs ] , prev_w , prev_h ) ;
} else {
_generate_po2_mipmap < uint8_t , 4 , false , Image : : average_4_uint8 , Image : : renormalize_uint8 > ( & wp [ prev_ofs ] , & wp [ ofs ] , prev_w , prev_h ) ;
}
break ;
case FORMAT_RF :
_generate_po2_mipmap < float , 1 , false , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( & wp [ prev_ofs ] ) , reinterpret_cast < float * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
break ;
case FORMAT_RGF :
_generate_po2_mipmap < float , 2 , false , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( & wp [ prev_ofs ] ) , reinterpret_cast < float * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
break ;
case FORMAT_RGBF :
if ( p_renormalize ) {
_generate_po2_mipmap < float , 3 , true , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( & wp [ prev_ofs ] ) , reinterpret_cast < float * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
} else {
_generate_po2_mipmap < float , 3 , false , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( & wp [ prev_ofs ] ) , reinterpret_cast < float * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
}
break ;
case FORMAT_RGBAF :
if ( p_renormalize ) {
_generate_po2_mipmap < float , 4 , true , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( & wp [ prev_ofs ] ) , reinterpret_cast < float * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
} else {
_generate_po2_mipmap < float , 4 , false , Image : : average_4_float , Image : : renormalize_float > ( reinterpret_cast < const float * > ( & wp [ prev_ofs ] ) , reinterpret_cast < float * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
}
break ;
case FORMAT_RH :
_generate_po2_mipmap < uint16_t , 1 , false , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( & wp [ prev_ofs ] ) , reinterpret_cast < uint16_t * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
break ;
case FORMAT_RGH :
_generate_po2_mipmap < uint16_t , 2 , false , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( & wp [ prev_ofs ] ) , reinterpret_cast < uint16_t * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
break ;
case FORMAT_RGBH :
if ( p_renormalize ) {
_generate_po2_mipmap < uint16_t , 3 , true , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( & wp [ prev_ofs ] ) , reinterpret_cast < uint16_t * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
} else {
_generate_po2_mipmap < uint16_t , 3 , false , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( & wp [ prev_ofs ] ) , reinterpret_cast < uint16_t * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
}
break ;
case FORMAT_RGBAH :
if ( p_renormalize ) {
_generate_po2_mipmap < uint16_t , 4 , true , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( & wp [ prev_ofs ] ) , reinterpret_cast < uint16_t * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
} else {
_generate_po2_mipmap < uint16_t , 4 , false , Image : : average_4_half , Image : : renormalize_half > ( reinterpret_cast < const uint16_t * > ( & wp [ prev_ofs ] ) , reinterpret_cast < uint16_t * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
}
break ;
case FORMAT_RGBE9995 :
if ( p_renormalize ) {
_generate_po2_mipmap < uint32_t , 1 , true , Image : : average_4_rgbe9995 , Image : : renormalize_rgbe9995 > ( reinterpret_cast < const uint32_t * > ( & wp [ prev_ofs ] ) , reinterpret_cast < uint32_t * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
} else {
_generate_po2_mipmap < uint32_t , 1 , false , Image : : average_4_rgbe9995 , Image : : renormalize_rgbe9995 > ( reinterpret_cast < const uint32_t * > ( & wp [ prev_ofs ] ) , reinterpret_cast < uint32_t * > ( & wp [ ofs ] ) , prev_w , prev_h ) ;
}
break ;
default : {
}
}
prev_ofs = ofs ;
prev_w = w ;
prev_h = h ;
}
mipmaps = true ;
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return 0 ;
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}
void Image : : clear_mipmaps ( ) {
if ( ! mipmaps ) {
return ;
}
if ( empty ( ) ) {
return ;
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}
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int ofs , w , h ;
_get_mipmap_offset_and_size ( 1 , ofs , w , h ) ;
data . resize ( ofs ) ;
mipmaps = false ;
}
bool Image : : empty ( ) const {
return ( data . size ( ) = = 0 ) ;
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}
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Vector < uint8_t > Image : : get_data ( ) const {
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return data ;
}
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const uint8_t * Image : : datar ( ) const {
return data . data ( ) ;
}
uint8_t * Image : : dataw ( ) {
return data . dataw ( ) ;
}
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void Image : : create ( int p_width , int p_height , bool p_use_mipmaps , Format p_format ) {
ERR_FAIL_COND_MSG ( p_width < = 0 , " Image width must be greater than 0. " ) ;
ERR_FAIL_COND_MSG ( p_height < = 0 , " Image height must be greater than 0. " ) ;
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ERR_FAIL_COND_MSG ( p_width > MAX_WIDTH , " Image width cannot be greater than " + String : : num ( MAX_WIDTH ) + " . " ) ;
ERR_FAIL_COND_MSG ( p_height > MAX_HEIGHT , " Image height cannot be greater than " + String : : num ( MAX_HEIGHT ) + " . " ) ;
ERR_FAIL_COND_MSG ( write_lock , " Cannot create image when it is locked. " ) ;
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ERR_FAIL_INDEX_MSG ( p_format , FORMAT_MAX , " Image format out of range, please see Image's Format enum. " ) ;
int mm = 0 ;
int size = _get_dst_image_size ( p_width , p_height , p_format , mm , p_use_mipmaps ? - 1 : 0 ) ;
data . resize ( size ) ;
{
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write_lock = true ;
memset ( data . dataw ( ) , 0 , size ) ;
write_lock = false ;
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}
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width = p_width ;
height = p_height ;
mipmaps = p_use_mipmaps ;
format = p_format ;
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}
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void Image : : create ( int p_width , int p_height , bool p_use_mipmaps , Format p_format , const Vector < uint8_t > & p_data ) {
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ERR_FAIL_COND_MSG ( p_width < = 0 , " Image width must be greater than 0. " ) ;
ERR_FAIL_COND_MSG ( p_height < = 0 , " Image height must be greater than 0. " ) ;
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ERR_FAIL_COND_MSG ( p_width > MAX_WIDTH , " Image width cannot be greater than " + String : : num ( MAX_WIDTH ) + " . " ) ;
ERR_FAIL_COND_MSG ( p_height > MAX_HEIGHT , " Image height cannot be greater than " + String : : num ( MAX_HEIGHT ) + " . " ) ;
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ERR_FAIL_INDEX_MSG ( p_format , FORMAT_MAX , " Image format out of range, please see Image's Format enum. " ) ;
int mm ;
int size = _get_dst_image_size ( p_width , p_height , p_format , mm , p_use_mipmaps ? - 1 : 0 ) ;
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ERR_FAIL_COND_MSG ( p_data . size ( ) ! = size , " Expected data size of " + String : : num ( size ) + " bytes in Image::create(), got instead " + String : : num ( p_data . size ( ) ) + " bytes. " ) ;
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height = p_height ;
width = p_width ;
format = p_format ;
data = p_data ;
mipmaps = p_use_mipmaps ;
}
void Image : : create ( const char * * p_xpm ) {
int size_width = 0 ;
int size_height = 0 ;
int pixelchars = 0 ;
mipmaps = false ;
bool has_alpha = false ;
enum Status {
READING_HEADER ,
READING_COLORS ,
READING_PIXELS ,
DONE
} ;
Status status = READING_HEADER ;
int line = 0 ;
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std : : map < String , Color > colormap ;
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int colormap_size = 0 ;
uint32_t pixel_size = 0 ;
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uint8_t * w_ptr ;
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while ( status ! = DONE ) {
const char * line_ptr = p_xpm [ line ] ;
switch ( status ) {
case READING_HEADER : {
String line_str = line_ptr ;
line_str . replace ( " \t " , " " ) ;
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size_width = line_str . get_slice ( ' ' , 0 ) . to_int ( ) ;
size_height = line_str . get_slice ( ' ' , 1 ) . to_int ( ) ;
colormap_size = line_str . get_slice ( ' ' , 2 ) . to_int ( ) ;
pixelchars = line_str . get_slice ( ' ' , 3 ) . to_int ( ) ;
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ERR_FAIL_COND ( colormap_size > 32766 ) ;
ERR_FAIL_COND ( pixelchars > 5 ) ;
ERR_FAIL_COND ( size_width > 32767 ) ;
ERR_FAIL_COND ( size_height > 32767 ) ;
status = READING_COLORS ;
} break ;
case READING_COLORS : {
String colorstring ;
for ( int i = 0 ; i < pixelchars ; i + + ) {
colorstring + = * line_ptr ;
line_ptr + + ;
}
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// skip spaces
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while ( * line_ptr = = ' ' | | * line_ptr = = ' \t ' | | * line_ptr = = 0 ) {
if ( * line_ptr = = 0 ) {
break ;
}
line_ptr + + ;
}
if ( * line_ptr = = ' c ' ) {
line_ptr + + ;
while ( * line_ptr = = ' ' | | * line_ptr = = ' \t ' | | * line_ptr = = 0 ) {
if ( * line_ptr = = 0 ) {
break ;
}
line_ptr + + ;
}
if ( * line_ptr = = ' # ' ) {
line_ptr + + ;
uint8_t col_r = 0 ;
uint8_t col_g = 0 ;
uint8_t col_b = 0 ;
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// uint8_t col_a=255;
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for ( int i = 0 ; i < 6 ; i + + ) {
char v = line_ptr [ i ] ;
if ( v > = ' 0 ' & & v < = ' 9 ' ) {
v - = ' 0 ' ;
} else if ( v > = ' A ' & & v < = ' F ' ) {
v = ( v - ' A ' ) + 10 ;
} else if ( v > = ' a ' & & v < = ' f ' ) {
v = ( v - ' a ' ) + 10 ;
} else {
break ;
}
switch ( i ) {
case 0 :
col_r = v < < 4 ;
break ;
case 1 :
col_r | = v ;
break ;
case 2 :
col_g = v < < 4 ;
break ;
case 3 :
col_g | = v ;
break ;
case 4 :
col_b = v < < 4 ;
break ;
case 5 :
col_b | = v ;
break ;
} ;
}
// magenta mask
if ( col_r = = 255 & & col_g = = 0 & & col_b = = 255 ) {
colormap [ colorstring ] = Color ( 0 , 0 , 0 , 0 ) ;
has_alpha = true ;
} else {
colormap [ colorstring ] = Color ( col_r / 255.0 , col_g / 255.0 , col_b / 255.0 , 1.0 ) ;
}
}
}
if ( line = = colormap_size ) {
status = READING_PIXELS ;
create ( size_width , size_height , false , has_alpha ? FORMAT_RGBA8 : FORMAT_RGB8 ) ;
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w_ptr = data . dataw ( ) ;
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pixel_size = has_alpha ? 4 : 3 ;
}
} break ;
case READING_PIXELS : {
int y = line - colormap_size - 1 ;
for ( int x = 0 ; x < size_width ; x + + ) {
char pixelstr [ 6 ] = { 0 , 0 , 0 , 0 , 0 , 0 } ;
for ( int i = 0 ; i < pixelchars ; i + + ) {
pixelstr [ i ] = line_ptr [ x * pixelchars + i ] ;
}
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Color * colorptr = & colormap [ pixelstr ] ;
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ERR_FAIL_COND ( ! colorptr ) ;
uint8_t pixel [ 4 ] ;
for ( uint32_t i = 0 ; i < pixel_size ; i + + ) {
pixel [ i ] = CLAMP ( ( * colorptr ) [ i ] * 255 , 0 , 255 ) ;
}
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_put_pixelb ( x , y , pixel_size , w_ptr , pixel ) ;
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}
if ( y = = ( size_height - 1 ) ) {
status = DONE ;
}
} break ;
default : {
}
}
line + + ;
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}
}
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# define DETECT_ALPHA_MAX_THRESHOLD 254
# define DETECT_ALPHA_MIN_THRESHOLD 2
# define DETECT_ALPHA(m_value) \
{ \
uint8_t value = m_value ; \
if ( value < DETECT_ALPHA_MIN_THRESHOLD ) \
bit = true ; \
else if ( value < DETECT_ALPHA_MAX_THRESHOLD ) { \
detected = true ; \
break ; \
} \
}
# define DETECT_NON_ALPHA(m_value) \
{ \
uint8_t value = m_value ; \
if ( value > 0 ) { \
detected = true ; \
break ; \
} \
}
bool Image : : is_invisible ( ) const {
if ( format = = FORMAT_L8 | |
format = = FORMAT_RGB8 | | format = = FORMAT_RG8 ) {
return false ;
}
int len = data . size ( ) ;
if ( len = = 0 ) {
return true ;
}
int w , h ;
_get_mipmap_offset_and_size ( 1 , len , w , h ) ;
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const unsigned char * data_ptr = data . data ( ) ;
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bool detected = false ;
switch ( format ) {
case FORMAT_LA8 : {
for ( int i = 0 ; i < ( len > > 1 ) ; i + + ) {
DETECT_NON_ALPHA ( data_ptr [ ( i < < 1 ) + 1 ] ) ;
}
} break ;
case FORMAT_RGBA8 : {
for ( int i = 0 ; i < ( len > > 2 ) ; i + + ) {
DETECT_NON_ALPHA ( data_ptr [ ( i < < 2 ) + 3 ] )
}
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} break ;
case FORMAT_PVRTC2A :
case FORMAT_PVRTC4A :
case FORMAT_DXT3 :
case FORMAT_DXT5 : {
detected = true ;
} break ;
default : {
}
}
return ! detected ;
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}
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Image : : AlphaMode Image : : detect_alpha ( ) const {
int len = data . size ( ) ;
if ( len = = 0 ) {
return ALPHA_NONE ;
}
int w , h ;
_get_mipmap_offset_and_size ( 1 , len , w , h ) ;
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const unsigned char * data_ptr = data . data ( ) ;
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bool bit = false ;
bool detected = false ;
switch ( format ) {
case FORMAT_LA8 : {
for ( int i = 0 ; i < ( len > > 1 ) ; i + + ) {
DETECT_ALPHA ( data_ptr [ ( i < < 1 ) + 1 ] ) ;
}
} break ;
case FORMAT_RGBA8 : {
for ( int i = 0 ; i < ( len > > 2 ) ; i + + ) {
DETECT_ALPHA ( data_ptr [ ( i < < 2 ) + 3 ] )
}
} break ;
case FORMAT_PVRTC2A :
case FORMAT_PVRTC4A :
case FORMAT_DXT3 :
case FORMAT_DXT5 : {
detected = true ;
} break ;
default : {
}
}
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if ( detected ) {
return ALPHA_BLEND ;
} else if ( bit ) {
return ALPHA_BIT ;
} else {
return ALPHA_NONE ;
}
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}
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int Image : : get_image_data_size ( int p_width , int p_height , Format p_format , bool p_mipmaps ) {
int mm ;
return _get_dst_image_size ( p_width , p_height , p_format , mm , p_mipmaps ? - 1 : 0 ) ;
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}
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int Image : : get_image_required_mipmaps ( int p_width , int p_height , Format p_format ) {
int mm ;
_get_dst_image_size ( p_width , p_height , p_format , mm , - 1 ) ;
return mm ;
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}
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int Image : : get_image_mipmap_offset ( int p_width , int p_height , Format p_format , int p_mipmap ) {
if ( p_mipmap < = 0 ) {
return 0 ;
}
int mm ;
return _get_dst_image_size ( p_width , p_height , p_format , mm , p_mipmap - 1 ) ;
}
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bool Image : : is_compressed ( ) const {
return format > FORMAT_RGBE9995 ;
}
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Image : : Image ( const char * * p_xpm ) {
width = 0 ;
height = 0 ;
mipmaps = false ;
format = FORMAT_L8 ;
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create ( p_xpm ) ;
}
Image : : Image ( int p_width , int p_height , bool p_use_mipmaps , Format p_format ) {
width = 0 ;
height = 0 ;
mipmaps = p_use_mipmaps ;
format = FORMAT_L8 ;
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create ( p_width , p_height , p_use_mipmaps , p_format ) ;
}
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Image : : Image ( int p_width , int p_height , bool p_mipmaps , Format p_format , const Vector < uint8_t > & p_data ) {
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width = 0 ;
height = 0 ;
mipmaps = p_mipmaps ;
format = FORMAT_L8 ;
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create ( p_width , p_height , p_mipmaps , p_format , p_data ) ;
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}
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Rect2 Image : : get_used_rect ( ) const {
if ( format ! = FORMAT_LA8 & & format ! = FORMAT_RGBA8 & & format ! = FORMAT_RGBAF & & format ! = FORMAT_RGBAH & & format ! = FORMAT_RGBA4444 & & format ! = FORMAT_RGBA5551 ) {
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return Rect2 ( Vector2 ( ) , Vector2 ( width , height ) ) ;
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}
int len = data . size ( ) ;
if ( len = = 0 ) {
return Rect2 ( ) ;
}
const_cast < Image * > ( this ) - > lock ( ) ;
int minx = 0xFFFFFF , miny = 0xFFFFFFF ;
int maxx = - 1 , maxy = - 1 ;
for ( int j = 0 ; j < height ; j + + ) {
for ( int i = 0 ; i < width ; i + + ) {
if ( ! ( get_pixel ( i , j ) . a > 0 ) ) {
continue ;
}
if ( i > maxx ) {
maxx = i ;
}
if ( j > maxy ) {
maxy = j ;
}
if ( i < minx ) {
minx = i ;
}
if ( j < miny ) {
miny = j ;
}
}
}
const_cast < Image * > ( this ) - > unlock ( ) ;
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if ( maxx = = - 1 ) {
return Rect2 ( ) ;
} else {
return Rect2 ( minx , miny , maxx - minx + 1 , maxy - miny + 1 ) ;
}
}
Ref < Image > Image : : get_rect ( const Rect2 & p_area ) const {
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Ref < Image > img = new Image ( p_area . x , p_area . y , mipmaps , format ) ;
img - > blit_rect ( Ref < Image > ( ( Image * ) this ) , p_area , Vector2 ( 0 , 0 ) ) ;
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return img ;
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}
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void Image : : blit_rect ( const Ref < Image > & p_src , const Rect2 & p_src_rect , const Vector2 & p_dest ) {
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ERR_FAIL_COND_MSG ( p_src . is_null ( ) , " It's not a reference to a valid Image object. " ) ;
int dsize = data . size ( ) ;
int srcdsize = p_src - > data . size ( ) ;
ERR_FAIL_COND ( dsize = = 0 ) ;
ERR_FAIL_COND ( srcdsize = = 0 ) ;
ERR_FAIL_COND ( format ! = p_src - > format ) ;
ERR_FAIL_COND_MSG ( ! _can_modify ( format ) , " Cannot blit_rect in compressed or custom image formats. " ) ;
Rect2i clipped_src_rect = Rect2i ( 0 , 0 , p_src - > width , p_src - > height ) . clip ( p_src_rect ) ;
if ( p_dest . x < 0 ) {
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clipped_src_rect . x = ABS ( p_dest . x ) ;
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}
if ( p_dest . y < 0 ) {
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clipped_src_rect . y = ABS ( p_dest . y ) ;
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}
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if ( clipped_src_rect . w < = 0 | | clipped_src_rect . h < = 0 ) {
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return ;
}
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Vector2 src_underscan = Vector2 ( MIN ( 0 , p_src_rect . x ) , MIN ( 0 , p_src_rect . y ) ) ;
Rect2i dest_rect = Rect2i ( 0 , 0 , width , height ) . clip ( Rect2i ( p_dest - src_underscan , clipped_src_rect . size ( ) ) ) ;
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write_lock = true ;
uint8_t * dst_data_ptr = data . dataw ( ) ;
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const uint8_t * src_data_ptr = p_src - > data . data ( ) ;
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int pixel_size = get_format_pixel_size ( format ) ;
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for ( int i = 0 ; i < dest_rect . h ; i + + ) {
for ( int j = 0 ; j < dest_rect . w ; j + + ) {
int src_x = clipped_src_rect . x + j ;
int src_y = clipped_src_rect . y + i ;
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int dst_x = dest_rect . x + j ;
int dst_y = dest_rect . y + i ;
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const uint8_t * src = & src_data_ptr [ ( src_y * p_src - > width + src_x ) * pixel_size ] ;
uint8_t * dst = & dst_data_ptr [ ( dst_y * width + dst_x ) * pixel_size ] ;
for ( int k = 0 ; k < pixel_size ; k + + ) {
dst [ k ] = src [ k ] ;
}
}
}
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write_lock = false ;
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}
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void Image : : blit_rect_mask ( const Ref < Image > & p_src , const Ref < Image > & p_mask , const Rect2 & p_src_rect , const Vector2 & p_dest ) {
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ERR_FAIL_COND_MSG ( p_src . is_null ( ) , " It's not a reference to a valid Image object. " ) ;
ERR_FAIL_COND_MSG ( p_mask . is_null ( ) , " It's not a reference to a valid Image object. " ) ;
int dsize = data . size ( ) ;
int srcdsize = p_src - > data . size ( ) ;
int maskdsize = p_mask - > data . size ( ) ;
ERR_FAIL_COND ( dsize = = 0 ) ;
ERR_FAIL_COND ( srcdsize = = 0 ) ;
ERR_FAIL_COND ( maskdsize = = 0 ) ;
ERR_FAIL_COND_MSG ( p_src - > width ! = p_mask - > width , " Source image width is different from mask width. " ) ;
ERR_FAIL_COND_MSG ( p_src - > height ! = p_mask - > height , " Source image height is different from mask height. " ) ;
ERR_FAIL_COND ( format ! = p_src - > format ) ;
Rect2i clipped_src_rect = Rect2i ( 0 , 0 , p_src - > width , p_src - > height ) . clip ( p_src_rect ) ;
if ( p_dest . x < 0 ) {
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clipped_src_rect . x = ABS ( p_dest . x ) ;
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}
if ( p_dest . y < 0 ) {
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clipped_src_rect . y = ABS ( p_dest . y ) ;
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}
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if ( clipped_src_rect . w < = 0 | | clipped_src_rect . h < = 0 ) {
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return ;
}
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Vector2 src_underscan = Vector2 ( MIN ( 0 , p_src_rect . x ) , MIN ( 0 , p_src_rect . y ) ) ;
Rect2i dest_rect = Rect2i ( 0 , 0 , width , height ) . clip ( Rect2i ( p_dest - src_underscan , clipped_src_rect . size ( ) ) ) ;
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write_lock = true ;
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uint8_t * dst_data_ptr = data . dataw ( ) ;
const uint8_t * src_data_ptr = p_src - > data . data ( ) ;
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int pixel_size = get_format_pixel_size ( format ) ;
Ref < Image > msk = p_mask ;
msk - > lock ( ) ;
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for ( int i = 0 ; i < dest_rect . h ; i + + ) {
for ( int j = 0 ; j < dest_rect . w ; j + + ) {
int src_x = clipped_src_rect . x + j ;
int src_y = clipped_src_rect . y + i ;
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if ( msk - > get_pixel ( src_x , src_y ) . a ! = 0 ) {
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int dst_x = dest_rect . x + j ;
int dst_y = dest_rect . y + i ;
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const uint8_t * src = & src_data_ptr [ ( src_y * p_src - > width + src_x ) * pixel_size ] ;
uint8_t * dst = & dst_data_ptr [ ( dst_y * width + dst_x ) * pixel_size ] ;
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for ( int k = 0 ; k < pixel_size ; k + + ) {
dst [ k ] = src [ k ] ;
}
}
}
}
msk - > unlock ( ) ;
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write_lock = false ;
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}
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void Image : : blend_rect ( const Ref < Image > & p_src , const Rect2 & p_src_rect , const Vector2 & p_dest ) {
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ERR_FAIL_COND_MSG ( p_src . is_null ( ) , " It's not a reference to a valid Image object. " ) ;
int dsize = data . size ( ) ;
int srcdsize = p_src - > data . size ( ) ;
ERR_FAIL_COND ( dsize = = 0 ) ;
ERR_FAIL_COND ( srcdsize = = 0 ) ;
ERR_FAIL_COND ( format ! = p_src - > format ) ;
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Rect2i clipped_src_rect = Rect2i ( 0 , 0 , p_src - > width , p_src - > height ) . clip ( p_src_rect ) ;
if ( p_dest . x < 0 ) {
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clipped_src_rect . x = ABS ( p_dest . x ) ;
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}
if ( p_dest . y < 0 ) {
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clipped_src_rect . y = ABS ( p_dest . y ) ;
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}
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if ( clipped_src_rect . w < = 0 | | clipped_src_rect . h < = 0 ) {
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return ;
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}
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Vector2 src_underscan = Vector2 ( MIN ( 0 , p_src_rect . x ) , MIN ( 0 , p_src_rect . y ) ) ;
Rect2i dest_rect = Rect2i ( 0 , 0 , width , height ) . clip ( Rect2i ( p_dest - src_underscan , clipped_src_rect . size ( ) ) ) ;
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lock ( ) ;
Ref < Image > img = p_src ;
img - > lock ( ) ;
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for ( int i = 0 ; i < dest_rect . h ; i + + ) {
for ( int j = 0 ; j < dest_rect . w ; j + + ) {
int src_x = clipped_src_rect . x + j ;
int src_y = clipped_src_rect . y + i ;
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int dst_x = dest_rect . x + j ;
int dst_y = dest_rect . y + i ;
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Color sc = img - > get_pixel ( src_x , src_y ) ;
if ( sc . a ! = 0 ) {
Color dc = get_pixel ( dst_x , dst_y ) ;
dc = dc . blend ( sc ) ;
set_pixel ( dst_x , dst_y , dc ) ;
}
}
}
img - > unlock ( ) ;
unlock ( ) ;
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}
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void Image : : blend_rect_mask ( const Ref < Image > & p_src , const Ref < Image > & p_mask , const Rect2 & p_src_rect , const Vector2 & p_dest ) {
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ERR_FAIL_COND_MSG ( p_src . is_null ( ) , " It's not a reference to a valid Image object. " ) ;
ERR_FAIL_COND_MSG ( p_mask . is_null ( ) , " It's not a reference to a valid Image object. " ) ;
int dsize = data . size ( ) ;
int srcdsize = p_src - > data . size ( ) ;
int maskdsize = p_mask - > data . size ( ) ;
ERR_FAIL_COND ( dsize = = 0 ) ;
ERR_FAIL_COND ( srcdsize = = 0 ) ;
ERR_FAIL_COND ( maskdsize = = 0 ) ;
ERR_FAIL_COND_MSG ( p_src - > width ! = p_mask - > width , " Source image width is different from mask width. " ) ;
ERR_FAIL_COND_MSG ( p_src - > height ! = p_mask - > height , " Source image height is different from mask height. " ) ;
ERR_FAIL_COND ( format ! = p_src - > format ) ;
Rect2i clipped_src_rect = Rect2i ( 0 , 0 , p_src - > width , p_src - > height ) . clip ( p_src_rect ) ;
if ( p_dest . x < 0 ) {
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clipped_src_rect . x = ABS ( p_dest . x ) ;
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}
if ( p_dest . y < 0 ) {
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clipped_src_rect . y = ABS ( p_dest . y ) ;
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}
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if ( clipped_src_rect . w < = 0 | | clipped_src_rect . h < = 0 ) {
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return ;
}
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Vector2 src_underscan = Vector2 ( MIN ( 0 , p_src_rect . x ) , MIN ( 0 , p_src_rect . y ) ) ;
Rect2i dest_rect = Rect2i ( 0 , 0 , width , height ) . clip ( Rect2i ( p_dest - src_underscan , clipped_src_rect . size ( ) ) ) ;
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lock ( ) ;
Ref < Image > img = p_src ;
Ref < Image > msk = p_mask ;
img - > lock ( ) ;
msk - > lock ( ) ;
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for ( int i = 0 ; i < dest_rect . h ; i + + ) {
for ( int j = 0 ; j < dest_rect . w ; j + + ) {
int src_x = clipped_src_rect . x + j ;
int src_y = clipped_src_rect . y + i ;
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// If the mask's pixel is transparent then we skip it
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// Color c = msk->get_pixel(src_x, src_y);
// if (c.a == 0) continue;
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if ( msk - > get_pixel ( src_x , src_y ) . a ! = 0 ) {
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int dst_x = dest_rect . x + j ;
int dst_y = dest_rect . y + i ;
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Color sc = img - > get_pixel ( src_x , src_y ) ;
if ( sc . a ! = 0 ) {
Color dc = get_pixel ( dst_x , dst_y ) ;
dc = dc . blend ( sc ) ;
set_pixel ( dst_x , dst_y , dc ) ;
}
}
}
}
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msk - > unlock ( ) ;
img - > unlock ( ) ;
unlock ( ) ;
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}
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// Repeats `p_pixel` `p_count` times in consecutive memory.
// Results in the original pixel and `p_count - 1` subsequent copies of it.
void Image : : _repeat_pixel_over_subsequent_memory ( uint8_t * p_pixel , int p_pixel_size , int p_count ) {
int offset = 1 ;
for ( int stride = 1 ; offset + stride < = p_count ; stride * = 2 ) {
memcpy ( p_pixel + offset * p_pixel_size , p_pixel , stride * p_pixel_size ) ;
offset + = stride ;
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}
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if ( offset < p_count ) {
memcpy ( p_pixel + offset * p_pixel_size , p_pixel , ( p_count - offset ) * p_pixel_size ) ;
}
}
void Image : : fill ( const Color & p_color ) {
ERR_FAIL_COND_MSG ( ! _can_modify ( format ) , " Cannot fill in compressed or custom image formats. " ) ;
lock ( ) ;
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uint8_t * dst_data_ptr = data . dataw ( ) ;
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int pixel_size = get_format_pixel_size ( format ) ;
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// Put first pixel with the format-aware API.
set_pixel ( 0 , 0 , p_color ) ;
_repeat_pixel_over_subsequent_memory ( dst_data_ptr , pixel_size , width * height ) ;
unlock ( ) ;
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}
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void Image : : fill_rect ( const Rect2 & p_rect , const Color & p_color ) {
ERR_FAIL_COND_MSG ( ! _can_modify ( format ) , " Cannot fill rect in compressed or custom image formats. " ) ;
Rect2i r = Rect2i ( 0 , 0 , width , height ) . clip ( p_rect . abs ( ) ) ;
if ( r . has_no_area ( ) ) {
return ;
}
lock ( ) ;
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uint8_t * dst_data_ptr = data . dataw ( ) ;
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int pixel_size = get_format_pixel_size ( format ) ;
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// Put first pixel with the format-aware API.
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uint8_t * rect_first_pixel_ptr = & dst_data_ptr [ ( r . y * width + r . x ) * pixel_size ] ;
set_pixelv ( r . position ( ) , p_color ) ;
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if ( r . x = = width ) {
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// No need to fill rows separately.
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_repeat_pixel_over_subsequent_memory ( rect_first_pixel_ptr , pixel_size , width * r . h ) ;
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} else {
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_repeat_pixel_over_subsequent_memory ( rect_first_pixel_ptr , pixel_size , r . w ) ;
for ( int y = 1 ; y < r . h ; y + + ) {
memcpy ( rect_first_pixel_ptr + y * width * pixel_size , rect_first_pixel_ptr , r . w * pixel_size ) ;
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}
}
unlock ( ) ;
}
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void Image : : lock ( ) {
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ERR_FAIL_COND ( data . size ( ) = = 0 ) ;
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write_lock = true ;
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}
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void Image : : unlock ( ) {
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write_lock = false ;
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}
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Color Image : : get_pixelv ( const Vector2 & p_src ) const {
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return get_pixel ( p_src . x , p_src . y ) ;
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}
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Color Image : : get_pixel ( int p_x , int p_y ) const {
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const uint8_t * ptr = data . data ( ) ;
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# ifdef DEBUG_ENABLED
ERR_FAIL_COND_V_MSG ( ! ptr , Color ( ) , " Image must be locked with 'lock()' before using get_pixel(). " ) ;
ERR_FAIL_INDEX_V ( p_x , width , Color ( ) ) ;
ERR_FAIL_INDEX_V ( p_y , height , Color ( ) ) ;
# endif
uint32_t ofs = p_y * width + p_x ;
switch ( format ) {
case FORMAT_L8 : {
float l = ptr [ ofs ] / 255.0 ;
return Color ( l , l , l , 1 ) ;
}
case FORMAT_LA8 : {
float l = ptr [ ofs * 2 + 0 ] / 255.0 ;
float a = ptr [ ofs * 2 + 1 ] / 255.0 ;
return Color ( l , l , l , a ) ;
}
case FORMAT_R8 : {
float r = ptr [ ofs ] / 255.0 ;
return Color ( r , 0 , 0 , 1 ) ;
}
case FORMAT_RG8 : {
float r = ptr [ ofs * 2 + 0 ] / 255.0 ;
float g = ptr [ ofs * 2 + 1 ] / 255.0 ;
return Color ( r , g , 0 , 1 ) ;
}
case FORMAT_RGB8 : {
float r = ptr [ ofs * 3 + 0 ] / 255.0 ;
float g = ptr [ ofs * 3 + 1 ] / 255.0 ;
float b = ptr [ ofs * 3 + 2 ] / 255.0 ;
return Color ( r , g , b , 1 ) ;
}
case FORMAT_RGBA8 : {
float r = ptr [ ofs * 4 + 0 ] / 255.0 ;
float g = ptr [ ofs * 4 + 1 ] / 255.0 ;
float b = ptr [ ofs * 4 + 2 ] / 255.0 ;
float a = ptr [ ofs * 4 + 3 ] / 255.0 ;
return Color ( r , g , b , a ) ;
}
case FORMAT_RGBA4444 : {
uint16_t u = ( ( uint16_t * ) ptr ) [ ofs ] ;
float r = ( ( u > > 12 ) & 0xF ) / 15.0 ;
float g = ( ( u > > 8 ) & 0xF ) / 15.0 ;
float b = ( ( u > > 4 ) & 0xF ) / 15.0 ;
float a = ( u & 0xF ) / 15.0 ;
return Color ( r , g , b , a ) ;
}
case FORMAT_RGBA5551 : {
uint16_t u = ( ( uint16_t * ) ptr ) [ ofs ] ;
float r = ( ( u > > 11 ) & 0x1F ) / 15.0 ;
float g = ( ( u > > 6 ) & 0x1F ) / 15.0 ;
float b = ( ( u > > 1 ) & 0x1F ) / 15.0 ;
float a = ( u & 0x1 ) / 1.0 ;
return Color ( r , g , b , a ) ;
}
case FORMAT_RF : {
float r = ( ( float * ) ptr ) [ ofs ] ;
return Color ( r , 0 , 0 , 1 ) ;
}
case FORMAT_RGF : {
float r = ( ( float * ) ptr ) [ ofs * 2 + 0 ] ;
float g = ( ( float * ) ptr ) [ ofs * 2 + 1 ] ;
return Color ( r , g , 0 , 1 ) ;
}
case FORMAT_RGBF : {
float r = ( ( float * ) ptr ) [ ofs * 3 + 0 ] ;
float g = ( ( float * ) ptr ) [ ofs * 3 + 1 ] ;
float b = ( ( float * ) ptr ) [ ofs * 3 + 2 ] ;
return Color ( r , g , b , 1 ) ;
}
case FORMAT_RGBAF : {
float r = ( ( float * ) ptr ) [ ofs * 4 + 0 ] ;
float g = ( ( float * ) ptr ) [ ofs * 4 + 1 ] ;
float b = ( ( float * ) ptr ) [ ofs * 4 + 2 ] ;
float a = ( ( float * ) ptr ) [ ofs * 4 + 3 ] ;
return Color ( r , g , b , a ) ;
}
case FORMAT_RH : {
uint16_t r = ( ( uint16_t * ) ptr ) [ ofs ] ;
return Color ( Math : : half_to_float ( r ) , 0 , 0 , 1 ) ;
}
case FORMAT_RGH : {
uint16_t r = ( ( uint16_t * ) ptr ) [ ofs * 2 + 0 ] ;
uint16_t g = ( ( uint16_t * ) ptr ) [ ofs * 2 + 1 ] ;
return Color ( Math : : half_to_float ( r ) , Math : : half_to_float ( g ) , 0 , 1 ) ;
}
case FORMAT_RGBH : {
uint16_t r = ( ( uint16_t * ) ptr ) [ ofs * 3 + 0 ] ;
uint16_t g = ( ( uint16_t * ) ptr ) [ ofs * 3 + 1 ] ;
uint16_t b = ( ( uint16_t * ) ptr ) [ ofs * 3 + 2 ] ;
return Color ( Math : : half_to_float ( r ) , Math : : half_to_float ( g ) , Math : : half_to_float ( b ) , 1 ) ;
}
case FORMAT_RGBAH : {
uint16_t r = ( ( uint16_t * ) ptr ) [ ofs * 4 + 0 ] ;
uint16_t g = ( ( uint16_t * ) ptr ) [ ofs * 4 + 1 ] ;
uint16_t b = ( ( uint16_t * ) ptr ) [ ofs * 4 + 2 ] ;
uint16_t a = ( ( uint16_t * ) ptr ) [ ofs * 4 + 3 ] ;
return Color ( Math : : half_to_float ( r ) , Math : : half_to_float ( g ) , Math : : half_to_float ( b ) , Math : : half_to_float ( a ) ) ;
}
case FORMAT_RGBE9995 : {
return Color : : from_rgbe9995 ( ( ( uint32_t * ) ptr ) [ ofs ] ) ;
}
default : {
ERR_FAIL_V_MSG ( Color ( ) , " Can't get_pixel() on compressed image, sorry. " ) ;
}
}
}
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void Image : : set_pixelv ( const Vector2 & p_dst , const Color & p_color ) {
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set_pixel ( p_dst . x , p_dst . y , p_color ) ;
}
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void Image : : set_pixel ( int p_x , int p_y , const Color & p_color ) {
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uint8_t * ptr = data . dataw ( ) ;
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# ifdef DEBUG_ENABLED
ERR_FAIL_COND_MSG ( ! ptr , " Image must be locked with 'lock()' before using set_pixel(). " ) ;
ERR_FAIL_INDEX ( p_x , width ) ;
ERR_FAIL_INDEX ( p_y , height ) ;
# endif
uint32_t ofs = p_y * width + p_x ;
switch ( format ) {
case FORMAT_L8 : {
ptr [ ofs ] = uint8_t ( CLAMP ( p_color . get_v ( ) * 255.0 , 0 , 255 ) ) ;
} break ;
case FORMAT_LA8 : {
ptr [ ofs * 2 + 0 ] = uint8_t ( CLAMP ( p_color . get_v ( ) * 255.0 , 0 , 255 ) ) ;
ptr [ ofs * 2 + 1 ] = uint8_t ( CLAMP ( p_color . a * 255.0 , 0 , 255 ) ) ;
} break ;
case FORMAT_R8 : {
ptr [ ofs ] = uint8_t ( CLAMP ( p_color . r * 255.0 , 0 , 255 ) ) ;
} break ;
case FORMAT_RG8 : {
ptr [ ofs * 2 + 0 ] = uint8_t ( CLAMP ( p_color . r * 255.0 , 0 , 255 ) ) ;
ptr [ ofs * 2 + 1 ] = uint8_t ( CLAMP ( p_color . g * 255.0 , 0 , 255 ) ) ;
} break ;
case FORMAT_RGB8 : {
ptr [ ofs * 3 + 0 ] = uint8_t ( CLAMP ( p_color . r * 255.0 , 0 , 255 ) ) ;
ptr [ ofs * 3 + 1 ] = uint8_t ( CLAMP ( p_color . g * 255.0 , 0 , 255 ) ) ;
ptr [ ofs * 3 + 2 ] = uint8_t ( CLAMP ( p_color . b * 255.0 , 0 , 255 ) ) ;
} break ;
case FORMAT_RGBA8 : {
ptr [ ofs * 4 + 0 ] = uint8_t ( CLAMP ( p_color . r * 255.0 , 0 , 255 ) ) ;
ptr [ ofs * 4 + 1 ] = uint8_t ( CLAMP ( p_color . g * 255.0 , 0 , 255 ) ) ;
ptr [ ofs * 4 + 2 ] = uint8_t ( CLAMP ( p_color . b * 255.0 , 0 , 255 ) ) ;
ptr [ ofs * 4 + 3 ] = uint8_t ( CLAMP ( p_color . a * 255.0 , 0 , 255 ) ) ;
} break ;
case FORMAT_RGBA4444 : {
uint16_t rgba = 0 ;
rgba = uint16_t ( CLAMP ( p_color . r * 15.0 , 0 , 15 ) ) < < 12 ;
rgba | = uint16_t ( CLAMP ( p_color . g * 15.0 , 0 , 15 ) ) < < 8 ;
rgba | = uint16_t ( CLAMP ( p_color . b * 15.0 , 0 , 15 ) ) < < 4 ;
rgba | = uint16_t ( CLAMP ( p_color . a * 15.0 , 0 , 15 ) ) ;
( ( uint16_t * ) ptr ) [ ofs ] = rgba ;
} break ;
case FORMAT_RGBA5551 : {
uint16_t rgba = 0 ;
rgba = uint16_t ( CLAMP ( p_color . r * 31.0 , 0 , 31 ) ) < < 11 ;
rgba | = uint16_t ( CLAMP ( p_color . g * 31.0 , 0 , 31 ) ) < < 6 ;
rgba | = uint16_t ( CLAMP ( p_color . b * 31.0 , 0 , 31 ) ) < < 1 ;
rgba | = uint16_t ( p_color . a > 0.5 ? 1 : 0 ) ;
( ( uint16_t * ) ptr ) [ ofs ] = rgba ;
} break ;
case FORMAT_RF : {
( ( float * ) ptr ) [ ofs ] = p_color . r ;
} break ;
case FORMAT_RGF : {
( ( float * ) ptr ) [ ofs * 2 + 0 ] = p_color . r ;
( ( float * ) ptr ) [ ofs * 2 + 1 ] = p_color . g ;
} break ;
case FORMAT_RGBF : {
( ( float * ) ptr ) [ ofs * 3 + 0 ] = p_color . r ;
( ( float * ) ptr ) [ ofs * 3 + 1 ] = p_color . g ;
( ( float * ) ptr ) [ ofs * 3 + 2 ] = p_color . b ;
} break ;
case FORMAT_RGBAF : {
( ( float * ) ptr ) [ ofs * 4 + 0 ] = p_color . r ;
( ( float * ) ptr ) [ ofs * 4 + 1 ] = p_color . g ;
( ( float * ) ptr ) [ ofs * 4 + 2 ] = p_color . b ;
( ( float * ) ptr ) [ ofs * 4 + 3 ] = p_color . a ;
} break ;
case FORMAT_RH : {
( ( uint16_t * ) ptr ) [ ofs ] = Math : : make_half_float ( p_color . r ) ;
} break ;
case FORMAT_RGH : {
( ( uint16_t * ) ptr ) [ ofs * 2 + 0 ] = Math : : make_half_float ( p_color . r ) ;
( ( uint16_t * ) ptr ) [ ofs * 2 + 1 ] = Math : : make_half_float ( p_color . g ) ;
} break ;
case FORMAT_RGBH : {
( ( uint16_t * ) ptr ) [ ofs * 3 + 0 ] = Math : : make_half_float ( p_color . r ) ;
( ( uint16_t * ) ptr ) [ ofs * 3 + 1 ] = Math : : make_half_float ( p_color . g ) ;
( ( uint16_t * ) ptr ) [ ofs * 3 + 2 ] = Math : : make_half_float ( p_color . b ) ;
} break ;
case FORMAT_RGBAH : {
( ( uint16_t * ) ptr ) [ ofs * 4 + 0 ] = Math : : make_half_float ( p_color . r ) ;
( ( uint16_t * ) ptr ) [ ofs * 4 + 1 ] = Math : : make_half_float ( p_color . g ) ;
( ( uint16_t * ) ptr ) [ ofs * 4 + 2 ] = Math : : make_half_float ( p_color . b ) ;
( ( uint16_t * ) ptr ) [ ofs * 4 + 3 ] = Math : : make_half_float ( p_color . a ) ;
} break ;
case FORMAT_RGBE9995 : {
( ( uint32_t * ) ptr ) [ ofs ] = p_color . to_rgbe9995 ( ) ;
} break ;
default : {
ERR_FAIL_MSG ( " Can't set_pixel() on compressed image, sorry. " ) ;
}
}
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}
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Image : : DetectChannels Image : : get_detected_channels ( ) {
ERR_FAIL_COND_V ( data . size ( ) = = 0 , DETECTED_RGBA ) ;
ERR_FAIL_COND_V ( is_compressed ( ) , DETECTED_RGBA ) ;
bool r = false , g = false , b = false , a = false , c = false ;
lock ( ) ;
for ( int i = 0 ; i < width ; i + + ) {
for ( int j = 0 ; j < height ; j + + ) {
Color col = get_pixel ( i , j ) ;
if ( col . r > 0.001 ) {
r = true ;
}
if ( col . g > 0.001 ) {
g = true ;
}
if ( col . b > 0.001 ) {
b = true ;
}
if ( col . a < 0.999 ) {
a = true ;
}
if ( col . r ! = col . b | | col . r ! = col . g | | col . b ! = col . g ) {
c = true ;
}
}
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}
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unlock ( ) ;
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if ( ! c & & ! a ) {
return DETECTED_L ;
}
if ( ! c & & a ) {
return DETECTED_LA ;
}
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if ( r & & ! g & & ! b & & ! a ) {
return DETECTED_R ;
}
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if ( r & & g & & ! b & & ! a ) {
return DETECTED_RG ;
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}
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if ( r & & g & & b & & ! a ) {
return DETECTED_RGB ;
}
return DETECTED_RGBA ;
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}
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void Image : : optimize_channels ( ) {
switch ( get_detected_channels ( ) ) {
case DETECTED_L :
convert ( FORMAT_L8 ) ;
break ;
case DETECTED_LA :
convert ( FORMAT_LA8 ) ;
break ;
case DETECTED_R :
convert ( FORMAT_R8 ) ;
break ;
case DETECTED_RG :
convert ( FORMAT_RG8 ) ;
break ;
case DETECTED_RGB :
convert ( FORMAT_RGB8 ) ;
break ;
case DETECTED_RGBA :
convert ( FORMAT_RGBA8 ) ;
break ;
}
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}
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void Image : : normalmap_to_xy ( ) {
convert ( Image : : FORMAT_RGBA8 ) ;
{
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write_lock = true ;
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int len = data . size ( ) / 4 ;
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unsigned char * data_ptr = data . dataw ( ) ;
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for ( int i = 0 ; i < len ; i + + ) {
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data_ptr [ ( i < < 2 ) + 3 ] = data_ptr [ ( i < < 2 ) + 0 ] ; // x to w
data_ptr [ ( i < < 2 ) + 0 ] = data_ptr [ ( i < < 2 ) + 1 ] ; // y to xz
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data_ptr [ ( i < < 2 ) + 2 ] = data_ptr [ ( i < < 2 ) + 1 ] ;
}
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write_lock = false ;
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}
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convert ( Image : : FORMAT_LA8 ) ;
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}
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Ref < Image > Image : : rgbe_to_srgb ( ) {
if ( data . size ( ) = = 0 ) {
return Ref < Image > ( ) ;
}
ERR_FAIL_COND_V ( format ! = FORMAT_RGBE9995 , Ref < Image > ( ) ) ;
Ref < Image > new_image ;
new_image . instance ( ) ;
new_image - > create ( width , height , false , Image : : FORMAT_RGB8 ) ;
lock ( ) ;
new_image - > lock ( ) ;
for ( int row = 0 ; row < height ; row + + ) {
for ( int col = 0 ; col < width ; col + + ) {
new_image - > set_pixel ( col , row , get_pixel ( col , row ) . to_srgb ( ) ) ;
}
}
unlock ( ) ;
new_image - > unlock ( ) ;
if ( has_mipmaps ( ) ) {
new_image - > generate_mipmaps ( ) ;
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}
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return new_image ;
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}
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void Image : : bumpmap_to_normalmap ( float bump_scale ) {
ERR_FAIL_COND ( ! _can_modify ( format ) ) ;
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ERR_FAIL_COND_MSG ( write_lock , " Cannot modify image when it is locked. " ) ;
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convert ( Image : : FORMAT_RF ) ;
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Vector < uint8_t > result_image ; // rgba output
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result_image . resize ( width * height * 4 ) ;
{
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write_lock = true ;
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unsigned char * write_ptr = result_image . dataw ( ) ;
float * read_ptr = ( float * ) data . dataw ( ) ;
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for ( int ty = 0 ; ty < height ; ty + + ) {
int py = ty + 1 ;
if ( py > = height ) {
py - = height ;
}
for ( int tx = 0 ; tx < width ; tx + + ) {
int px = tx + 1 ;
if ( px > = width ) {
px - = width ;
}
float here = read_ptr [ ty * width + tx ] ;
float to_right = read_ptr [ ty * width + px ] ;
float above = read_ptr [ py * width + tx ] ;
Vector3 up = Vector3 ( 0 , 1 , ( here - above ) * bump_scale ) ;
Vector3 across = Vector3 ( 1 , 0 , ( to_right - here ) * bump_scale ) ;
Vector3 normal = across . cross ( up ) ;
normal . normalize ( ) ;
write_ptr [ ( ( ty * width + tx ) < < 2 ) + 0 ] = ( 127.5 + normal . x * 127.5 ) ;
write_ptr [ ( ( ty * width + tx ) < < 2 ) + 1 ] = ( 127.5 + normal . y * 127.5 ) ;
write_ptr [ ( ( ty * width + tx ) < < 2 ) + 2 ] = ( 127.5 + normal . z * 127.5 ) ;
write_ptr [ ( ( ty * width + tx ) < < 2 ) + 3 ] = 255 ;
}
}
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write_lock = false ;
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}
format = FORMAT_RGBA8 ;
data = result_image ;
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}
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void Image : : srgb_to_linear ( ) {
if ( data . size ( ) = = 0 ) {
return ;
}
static const uint8_t srgb2lin [ 256 ] = { 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 1 , 1 , 1 , 1 , 1 , 1 , 1 , 1 , 1 , 2 , 2 , 2 , 2 , 2 , 2 , 2 , 3 , 3 , 3 , 3 , 3 , 4 , 4 , 4 , 4 , 4 , 5 , 5 , 5 , 5 , 6 , 6 , 6 , 6 , 7 , 7 , 7 , 8 , 8 , 8 , 9 , 9 , 9 , 10 , 10 , 10 , 11 , 11 , 11 , 12 , 12 , 13 , 13 , 13 , 14 , 14 , 15 , 15 , 16 , 16 , 16 , 17 , 17 , 18 , 18 , 19 , 19 , 20 , 20 , 21 , 22 , 22 , 23 , 23 , 24 , 24 , 25 , 26 , 26 , 27 , 27 , 28 , 29 , 29 , 30 , 31 , 31 , 32 , 33 , 33 , 34 , 35 , 36 , 36 , 37 , 38 , 38 , 39 , 40 , 41 , 42 , 42 , 43 , 44 , 45 , 46 , 47 , 47 , 48 , 49 , 50 , 51 , 52 , 53 , 54 , 55 , 55 , 56 , 57 , 58 , 59 , 60 , 61 , 62 , 63 , 64 , 65 , 66 , 67 , 68 , 70 , 71 , 72 , 73 , 74 , 75 , 76 , 77 , 78 , 80 , 81 , 82 , 83 , 84 , 85 , 87 , 88 , 89 , 90 , 92 , 93 , 94 , 95 , 97 , 98 , 99 , 101 , 102 , 103 , 105 , 106 , 107 , 109 , 110 , 112 , 113 , 114 , 116 , 117 , 119 , 120 , 122 , 123 , 125 , 126 , 128 , 129 , 131 , 132 , 134 , 135 , 137 , 139 , 140 , 142 , 144 , 145 , 147 , 148 , 150 , 152 , 153 , 155 , 157 , 159 , 160 , 162 , 164 , 166 , 167 , 169 , 171 , 173 , 175 , 176 , 178 , 180 , 182 , 184 , 186 , 188 , 190 , 192 , 193 , 195 , 197 , 199 , 201 , 203 , 205 , 207 , 209 , 211 , 213 , 215 , 218 , 220 , 222 , 224 , 226 , 228 , 230 , 232 , 235 , 237 , 239 , 241 , 243 , 245 , 248 , 250 , 252 , 255 } ;
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ERR_FAIL_COND ( format ! = FORMAT_RGB8 & & format ! = FORMAT_RGBA8 ) ;
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if ( format = = FORMAT_RGBA8 ) {
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write_lock = true ;
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int len = data . size ( ) / 4 ;
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unsigned char * data_ptr = data . dataw ( ) ;
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for ( int i = 0 ; i < len ; i + + ) {
data_ptr [ ( i < < 2 ) + 0 ] = srgb2lin [ data_ptr [ ( i < < 2 ) + 0 ] ] ;
data_ptr [ ( i < < 2 ) + 1 ] = srgb2lin [ data_ptr [ ( i < < 2 ) + 1 ] ] ;
data_ptr [ ( i < < 2 ) + 2 ] = srgb2lin [ data_ptr [ ( i < < 2 ) + 2 ] ] ;
}
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write_lock = false ;
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} else if ( format = = FORMAT_RGB8 ) {
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write_lock = true ;
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int len = data . size ( ) / 3 ;
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unsigned char * data_ptr = data . dataw ( ) ;
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for ( int i = 0 ; i < len ; i + + ) {
data_ptr [ ( i * 3 ) + 0 ] = srgb2lin [ data_ptr [ ( i * 3 ) + 0 ] ] ;
data_ptr [ ( i * 3 ) + 1 ] = srgb2lin [ data_ptr [ ( i * 3 ) + 1 ] ] ;
data_ptr [ ( i * 3 ) + 2 ] = srgb2lin [ data_ptr [ ( i * 3 ) + 2 ] ] ;
}
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write_lock = false ;
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}
}
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void Image : : premultiply_alpha ( ) {
if ( data . size ( ) = = 0 ) {
return ;
}
if ( format ! = FORMAT_RGBA8 ) {
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return ; // not needed
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}
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write_lock = true ;
unsigned char * data_ptr = data . dataw ( ) ;
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for ( int i = 0 ; i < height ; i + + ) {
for ( int j = 0 ; j < width ; j + + ) {
uint8_t * ptr = & data_ptr [ ( i * width + j ) * 4 ] ;
ptr [ 0 ] = ( uint16_t ( ptr [ 0 ] ) * uint16_t ( ptr [ 3 ] ) ) > > 8 ;
ptr [ 1 ] = ( uint16_t ( ptr [ 1 ] ) * uint16_t ( ptr [ 3 ] ) ) > > 8 ;
ptr [ 2 ] = ( uint16_t ( ptr [ 2 ] ) * uint16_t ( ptr [ 3 ] ) ) > > 8 ;
}
}
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write_lock = false ;
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}
void Image : : fix_alpha_edges ( ) {
ERR_FAIL_COND ( ! _can_modify ( format ) ) ;
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ERR_FAIL_COND_MSG ( write_lock , " Cannot modify image when it is locked. " ) ;
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if ( data . size ( ) = = 0 ) {
return ;
}
if ( format ! = FORMAT_RGBA8 ) {
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return ; // not needed
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}
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write_lock = true ;
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Vector < uint8_t > dcopy = data ;
const uint8_t * srcptr = dcopy . data ( ) ;
unsigned char * data_ptr = data . dataw ( ) ;
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const int max_radius = 4 ;
const int alpha_threshold = 20 ;
const int max_dist = 0x7FFFFFFF ;
for ( int i = 0 ; i < height ; i + + ) {
for ( int j = 0 ; j < width ; j + + ) {
const uint8_t * rptr = & srcptr [ ( i * width + j ) * 4 ] ;
uint8_t * wptr = & data_ptr [ ( i * width + j ) * 4 ] ;
if ( rptr [ 3 ] > = alpha_threshold ) {
continue ;
}
int closest_dist = max_dist ;
uint8_t closest_color [ 3 ] ;
int from_x = MAX ( 0 , j - max_radius ) ;
int to_x = MIN ( width - 1 , j + max_radius ) ;
int from_y = MAX ( 0 , i - max_radius ) ;
int to_y = MIN ( height - 1 , i + max_radius ) ;
for ( int k = from_y ; k < = to_y ; k + + ) {
for ( int l = from_x ; l < = to_x ; l + + ) {
int dy = i - k ;
int dx = j - l ;
int dist = dy * dy + dx * dx ;
if ( dist > = closest_dist ) {
continue ;
}
const uint8_t * rp2 = & srcptr [ ( k * width + l ) < < 2 ] ;
if ( rp2 [ 3 ] < alpha_threshold ) {
continue ;
}
closest_dist = dist ;
closest_color [ 0 ] = rp2 [ 0 ] ;
closest_color [ 1 ] = rp2 [ 1 ] ;
closest_color [ 2 ] = rp2 [ 2 ] ;
}
}
if ( closest_dist ! = max_dist ) {
wptr [ 0 ] = closest_color [ 0 ] ;
wptr [ 1 ] = closest_color [ 1 ] ;
wptr [ 2 ] = closest_color [ 2 ] ;
}
}
}
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write_lock = false ;
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}
String Image : : get_format_name ( Format p_format ) {
ERR_FAIL_INDEX_V ( p_format , FORMAT_MAX , String ( ) ) ;
return format_names [ p_format ] ;
}
void Image : : average_4_uint8 ( uint8_t & p_out , const uint8_t & p_a , const uint8_t & p_b , const uint8_t & p_c , const uint8_t & p_d ) {
p_out = static_cast < uint8_t > ( ( p_a + p_b + p_c + p_d + 2 ) > > 2 ) ;
}
void Image : : average_4_float ( float & p_out , const float & p_a , const float & p_b , const float & p_c , const float & p_d ) {
p_out = ( p_a + p_b + p_c + p_d ) * 0.25f ;
}
void Image : : average_4_half ( uint16_t & p_out , const uint16_t & p_a , const uint16_t & p_b , const uint16_t & p_c , const uint16_t & p_d ) {
p_out = Math : : make_half_float ( ( Math : : half_to_float ( p_a ) + Math : : half_to_float ( p_b ) + Math : : half_to_float ( p_c ) + Math : : half_to_float ( p_d ) ) * 0.25f ) ;
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}
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void Image : : average_4_rgbe9995 ( uint32_t & p_out , const uint32_t & p_a , const uint32_t & p_b , const uint32_t & p_c , const uint32_t & p_d ) {
p_out = ( ( Color : : from_rgbe9995 ( p_a ) + Color : : from_rgbe9995 ( p_b ) + Color : : from_rgbe9995 ( p_c ) + Color : : from_rgbe9995 ( p_d ) ) * 0.25f ) . to_rgbe9995 ( ) ;
}
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void Image : : renormalize_uint8 ( uint8_t * p_rgb ) {
Vector3 n ( p_rgb [ 0 ] / 255.0 , p_rgb [ 1 ] / 255.0 , p_rgb [ 2 ] / 255.0 ) ;
n * = 2.0 ;
n - = Vector3 ( 1 , 1 , 1 ) ;
n . normalize ( ) ;
n + = Vector3 ( 1 , 1 , 1 ) ;
n * = 0.5 ;
n * = 255 ;
p_rgb [ 0 ] = CLAMP ( int ( n . x ) , 0 , 255 ) ;
p_rgb [ 1 ] = CLAMP ( int ( n . y ) , 0 , 255 ) ;
p_rgb [ 2 ] = CLAMP ( int ( n . z ) , 0 , 255 ) ;
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}
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void Image : : renormalize_float ( float * p_rgb ) {
Vector3 n ( p_rgb [ 0 ] , p_rgb [ 1 ] , p_rgb [ 2 ] ) ;
n . normalize ( ) ;
p_rgb [ 0 ] = n . x ;
p_rgb [ 1 ] = n . y ;
p_rgb [ 2 ] = n . z ;
}
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void Image : : renormalize_half ( uint16_t * p_rgb ) {
Vector3 n ( Math : : half_to_float ( p_rgb [ 0 ] ) , Math : : half_to_float ( p_rgb [ 1 ] ) , Math : : half_to_float ( p_rgb [ 2 ] ) ) ;
n . normalize ( ) ;
p_rgb [ 0 ] = Math : : make_half_float ( n . x ) ;
p_rgb [ 1 ] = Math : : make_half_float ( n . y ) ;
p_rgb [ 2 ] = Math : : make_half_float ( n . z ) ;
}
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void Image : : renormalize_rgbe9995 ( uint32_t * p_rgb ) {
// Never used
}
Ref < Resource > Image : : duplicate ( bool p_subresources ) const {
Ref < Image > copy ;
copy . instance ( ) ;
copy - > _copy_internals_from ( * this ) ;
return copy ;
}
Image : : Image ( ) {
width = 0 ;
height = 0 ;
mipmaps = false ;
format = FORMAT_L8 ;
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write_lock = false ;
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}
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Image : : ~ Image ( ) {
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write_lock = false ;
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}