2023-10-02 05:23:24 -04:00
/* stb_image_resize - v0.97 - public domain image resizing
by Jorge L Rodriguez ( @ VinoBS ) - 2014
http : //github.com/nothings/stb
Written with emphasis on usability , portability , and efficiency . ( No
SIMD or threads , so it be easily outperformed by libs that use those . )
Only scaling and translation is supported , no rotations or shears .
Easy API downsamples w / Mitchell filter , upsamples w / cubic interpolation .
COMPILING & LINKING
In one C / C + + file that # includes this file , do this :
# define STB_IMAGE_RESIZE_IMPLEMENTATION
before the # include . That will create the implementation in that file .
QUICKSTART
stbir_resize_uint8 ( input_pixels , in_w , in_h , 0 ,
output_pixels , out_w , out_h , 0 , num_channels )
stbir_resize_float ( . . . )
stbir_resize_uint8_srgb ( input_pixels , in_w , in_h , 0 ,
output_pixels , out_w , out_h , 0 ,
num_channels , alpha_chan , 0 )
stbir_resize_uint8_srgb_edgemode (
input_pixels , in_w , in_h , 0 ,
output_pixels , out_w , out_h , 0 ,
num_channels , alpha_chan , 0 , STBIR_EDGE_CLAMP )
// WRAP/REFLECT/ZERO
FULL API
See the " header file " section of the source for API documentation .
ADDITIONAL DOCUMENTATION
SRGB & FLOATING POINT REPRESENTATION
The sRGB functions presume IEEE floating point . If you do not have
IEEE floating point , define STBIR_NON_IEEE_FLOAT . This will use
a slower implementation .
MEMORY ALLOCATION
The resize functions here perform a single memory allocation using
malloc . To control the memory allocation , before the # include that
triggers the implementation , do :
# define STBIR_MALLOC(size,context) ...
# define STBIR_FREE(ptr,context) ...
Each resize function makes exactly one call to malloc / free , so to use
temp memory , store the temp memory in the context and return that .
ASSERT
Define STBIR_ASSERT ( boolval ) to override assert ( ) and not use assert . h
OPTIMIZATION
Define STBIR_SATURATE_INT to compute clamp values in - range using
integer operations instead of float operations . This may be faster
on some platforms .
DEFAULT FILTERS
For functions which don ' t provide explicit control over what filters
to use , you can change the compile - time defaults with
# define STBIR_DEFAULT_FILTER_UPSAMPLE STBIR_FILTER_something
# define STBIR_DEFAULT_FILTER_DOWNSAMPLE STBIR_FILTER_something
See stbir_filter in the header - file section for the list of filters .
NEW FILTERS
A number of 1 D filter kernels are used . For a list of
supported filters see the stbir_filter enum . To add a new filter ,
write a filter function and add it to stbir__filter_info_table .
PROGRESS
For interactive use with slow resize operations , you can install
a progress - report callback :
# define STBIR_PROGRESS_REPORT(val) some_func(val)
The parameter val is a float which goes from 0 to 1 as progress is made .
For example :
static void my_progress_report ( float progress ) ;
# define STBIR_PROGRESS_REPORT(val) my_progress_report(val)
# define STB_IMAGE_RESIZE_IMPLEMENTATION
# include "stb_image_resize.h"
static void my_progress_report ( float progress )
{
printf ( " Progress: %f%% \n " , progress * 100 ) ;
}
MAX CHANNELS
If your image has more than 64 channels , define STBIR_MAX_CHANNELS
to the max you ' ll have .
ALPHA CHANNEL
Most of the resizing functions provide the ability to control how
the alpha channel of an image is processed . The important things
to know about this :
1. The best mathematically - behaved version of alpha to use is
called " premultiplied alpha " , in which the other color channels
have had the alpha value multiplied in . If you use premultiplied
alpha , linear filtering ( such as image resampling done by this
library , or performed in texture units on GPUs ) does the " right
thing " . While premultiplied alpha is standard in the movie CGI
industry , it is still uncommon in the videogame / real - time world .
If you linearly filter non - premultiplied alpha , strange effects
occur . ( For example , the 50 / 50 average of 99 % transparent bright green
and 1 % transparent black produces 50 % transparent dark green when
non - premultiplied , whereas premultiplied it produces 50 %
transparent near - black . The former introduces green energy
that doesn ' t exist in the source image . )
2. Artists should not edit premultiplied - alpha images ; artists
want non - premultiplied alpha images . Thus , art tools generally output
non - premultiplied alpha images .
3. You will get best results in most cases by converting images
to premultiplied alpha before processing them mathematically .
4. If you pass the flag STBIR_FLAG_ALPHA_PREMULTIPLIED , the
resizer does not do anything special for the alpha channel ;
it is resampled identically to other channels . This produces
the correct results for premultiplied - alpha images , but produces
less - than - ideal results for non - premultiplied - alpha images .
5. If you do not pass the flag STBIR_FLAG_ALPHA_PREMULTIPLIED ,
then the resizer weights the contribution of input pixels
based on their alpha values , or , equivalently , it multiplies
the alpha value into the color channels , resamples , then divides
by the resultant alpha value . Input pixels which have alpha = 0 do
not contribute at all to output pixels unless _all_ of the input
pixels affecting that output pixel have alpha = 0 , in which case
the result for that pixel is the same as it would be without
STBIR_FLAG_ALPHA_PREMULTIPLIED . However , this is only true for
input images in integer formats . For input images in float format ,
input pixels with alpha = 0 have no effect , and output pixels
which have alpha = 0 will be 0 in all channels . ( For float images ,
you can manually achieve the same result by adding a tiny epsilon
value to the alpha channel of every image , and then subtracting
or clamping it at the end . )
6. You can suppress the behavior described in # 5 and make
all - 0 - alpha pixels have 0 in all channels by # defining
STBIR_NO_ALPHA_EPSILON .
7. You can separately control whether the alpha channel is
interpreted as linear or affected by the colorspace . By default
it is linear ; you almost never want to apply the colorspace .
( For example , graphics hardware does not apply sRGB conversion
to the alpha channel . )
CONTRIBUTORS
Jorge L Rodriguez : Implementation
Sean Barrett : API design , optimizations
Aras Pranckevicius : bugfix
Nathan Reed : warning fixes
REVISIONS
0.97 ( 2020 - 02 - 02 ) fixed warning
0.96 ( 2019 - 03 - 04 ) fixed warnings
0.95 ( 2017 - 07 - 23 ) fixed warnings
0.94 ( 2017 - 03 - 18 ) fixed warnings
0.93 ( 2017 - 03 - 03 ) fixed bug with certain combinations of heights
0.92 ( 2017 - 01 - 02 ) fix integer overflow on large ( > 2 GB ) images
0.91 ( 2016 - 04 - 02 ) fix warnings ; fix handling of subpixel regions
0.90 ( 2014 - 09 - 17 ) first released version
LICENSE
See end of file for license information .
TODO
Don ' t decode all of the image data when only processing a partial tile
Don ' t use full - width decode buffers when only processing a partial tile
When processing wide images , break processing into tiles so data fits in L1 cache
Installable filters ?
Resize that respects alpha test coverage
( Reference code : FloatImage : : alphaTestCoverage and FloatImage : : scaleAlphaToCoverage :
https : //code.google.com/p/nvidia-texture-tools/source/browse/trunk/src/nvimage/FloatImage.cpp )
*/
# ifndef STBIR_INCLUDE_STB_IMAGE_RESIZE_H
# define STBIR_INCLUDE_STB_IMAGE_RESIZE_H
# ifdef _MSC_VER
typedef unsigned char stbir_uint8 ;
typedef unsigned short stbir_uint16 ;
typedef unsigned int stbir_uint32 ;
# else
# include <stdint.h>
typedef uint8_t stbir_uint8 ;
typedef uint16_t stbir_uint16 ;
typedef uint32_t stbir_uint32 ;
# endif
# ifndef STBIRDEF
# ifdef STB_IMAGE_RESIZE_STATIC
# define STBIRDEF static
# else
# ifdef __cplusplus
# define STBIRDEF extern "C"
# else
# define STBIRDEF extern
# endif
# endif
# endif
//////////////////////////////////////////////////////////////////////////////
//
// Easy-to-use API:
//
// * "input pixels" points to an array of image data with 'num_channels' channels (e.g. RGB=3, RGBA=4)
// * input_w is input image width (x-axis), input_h is input image height (y-axis)
// * stride is the offset between successive rows of image data in memory, in bytes. you can
// specify 0 to mean packed continuously in memory
// * alpha channel is treated identically to other channels.
// * colorspace is linear or sRGB as specified by function name
// * returned result is 1 for success or 0 in case of an error.
// #define STBIR_ASSERT() to trigger an assert on parameter validation errors.
// * Memory required grows approximately linearly with input and output size, but with
// discontinuities at input_w == output_w and input_h == output_h.
// * These functions use a "default" resampling filter defined at compile time. To change the filter,
// you can change the compile-time defaults by #defining STBIR_DEFAULT_FILTER_UPSAMPLE
// and STBIR_DEFAULT_FILTER_DOWNSAMPLE, or you can use the medium-complexity API.
STBIRDEF int stbir_resize_uint8 ( const unsigned char * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
unsigned char * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels ) ;
STBIRDEF int stbir_resize_float ( const float * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
float * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels ) ;
// The following functions interpret image data as gamma-corrected sRGB.
// Specify STBIR_ALPHA_CHANNEL_NONE if you have no alpha channel,
// or otherwise provide the index of the alpha channel. Flags value
// of 0 will probably do the right thing if you're not sure what
// the flags mean.
# define STBIR_ALPHA_CHANNEL_NONE -1
// Set this flag if your texture has premultiplied alpha. Otherwise, stbir will
// use alpha-weighted resampling (effectively premultiplying, resampling,
// then unpremultiplying).
# define STBIR_FLAG_ALPHA_PREMULTIPLIED (1 << 0)
// The specified alpha channel should be handled as gamma-corrected value even
// when doing sRGB operations.
# define STBIR_FLAG_ALPHA_USES_COLORSPACE (1 << 1)
STBIRDEF int stbir_resize_uint8_srgb ( const unsigned char * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
unsigned char * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags ) ;
typedef enum
{
STBIR_EDGE_CLAMP = 1 ,
STBIR_EDGE_REFLECT = 2 ,
STBIR_EDGE_WRAP = 3 ,
STBIR_EDGE_ZERO = 4 ,
} stbir_edge ;
// This function adds the ability to specify how requests to sample off the edge of the image are handled.
STBIRDEF int stbir_resize_uint8_srgb_edgemode ( const unsigned char * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
unsigned char * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_wrap_mode ) ;
//////////////////////////////////////////////////////////////////////////////
//
// Medium-complexity API
//
// This extends the easy-to-use API as follows:
//
// * Alpha-channel can be processed separately
// * If alpha_channel is not STBIR_ALPHA_CHANNEL_NONE
// * Alpha channel will not be gamma corrected (unless flags&STBIR_FLAG_GAMMA_CORRECT)
// * Filters will be weighted by alpha channel (unless flags&STBIR_FLAG_ALPHA_PREMULTIPLIED)
// * Filter can be selected explicitly
// * uint16 image type
// * sRGB colorspace available for all types
// * context parameter for passing to STBIR_MALLOC
typedef enum
{
STBIR_FILTER_DEFAULT = 0 , // use same filter type that easy-to-use API chooses
STBIR_FILTER_BOX = 1 , // A trapezoid w/1-pixel wide ramps, same result as box for integer scale ratios
STBIR_FILTER_TRIANGLE = 2 , // On upsampling, produces same results as bilinear texture filtering
STBIR_FILTER_CUBICBSPLINE = 3 , // The cubic b-spline (aka Mitchell-Netrevalli with B=1,C=0), gaussian-esque
STBIR_FILTER_CATMULLROM = 4 , // An interpolating cubic spline
STBIR_FILTER_MITCHELL = 5 , // Mitchell-Netrevalli filter with B=1/3, C=1/3
} stbir_filter ;
typedef enum
{
STBIR_COLORSPACE_LINEAR ,
STBIR_COLORSPACE_SRGB ,
STBIR_MAX_COLORSPACES ,
} stbir_colorspace ;
// The following functions are all identical except for the type of the image data
STBIRDEF int stbir_resize_uint8_generic ( const unsigned char * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
unsigned char * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_wrap_mode , stbir_filter filter , stbir_colorspace space ,
void * alloc_context ) ;
STBIRDEF int stbir_resize_uint16_generic ( const stbir_uint16 * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
stbir_uint16 * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_wrap_mode , stbir_filter filter , stbir_colorspace space ,
void * alloc_context ) ;
STBIRDEF int stbir_resize_float_generic ( const float * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
float * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_wrap_mode , stbir_filter filter , stbir_colorspace space ,
void * alloc_context ) ;
//////////////////////////////////////////////////////////////////////////////
//
// Full-complexity API
//
// This extends the medium API as follows:
//
// * uint32 image type
// * not typesafe
// * separate filter types for each axis
// * separate edge modes for each axis
// * can specify scale explicitly for subpixel correctness
// * can specify image source tile using texture coordinates
typedef enum
{
STBIR_TYPE_UINT8 ,
STBIR_TYPE_UINT16 ,
STBIR_TYPE_UINT32 ,
STBIR_TYPE_FLOAT ,
STBIR_MAX_TYPES
} stbir_datatype ;
STBIRDEF int stbir_resize ( const void * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
void * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
stbir_datatype datatype ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_mode_horizontal , stbir_edge edge_mode_vertical ,
stbir_filter filter_horizontal , stbir_filter filter_vertical ,
stbir_colorspace space , void * alloc_context ) ;
STBIRDEF int stbir_resize_subpixel ( const void * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
void * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
stbir_datatype datatype ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_mode_horizontal , stbir_edge edge_mode_vertical ,
stbir_filter filter_horizontal , stbir_filter filter_vertical ,
stbir_colorspace space , void * alloc_context ,
float x_scale , float y_scale ,
float x_offset , float y_offset ) ;
STBIRDEF int stbir_resize_region ( const void * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
void * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
stbir_datatype datatype ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_mode_horizontal , stbir_edge edge_mode_vertical ,
stbir_filter filter_horizontal , stbir_filter filter_vertical ,
stbir_colorspace space , void * alloc_context ,
float s0 , float t0 , float s1 , float t1 ) ;
// (s0, t0) & (s1, t1) are the top-left and bottom right corner (uv addressing style: [0, 1]x[0, 1]) of a region of the input image to use.
//
//
//// end header file /////////////////////////////////////////////////////
# endif // STBIR_INCLUDE_STB_IMAGE_RESIZE_H
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# ifdef STB_IMAGE_RESIZE_IMPLEMENTATION
# ifndef STBIR_ASSERT
# include <assert.h>
# define STBIR_ASSERT(x) assert(x)
# endif
// For memset
# include <string.h>
# include <math.h>
# ifndef STBIR_MALLOC
# include <stdlib.h>
// use comma operator to evaluate c, to avoid "unused parameter" warnings
# define STBIR_MALLOC(size,c) ((void)(c), malloc(size))
# define STBIR_FREE(ptr,c) ((void)(c), free(ptr))
# endif
# ifndef _MSC_VER
# ifdef __cplusplus
# define stbir__inline inline
# else
# define stbir__inline
# endif
# else
# define stbir__inline __forceinline
# endif
// should produce compiler error if size is wrong
typedef unsigned char stbir__validate_uint32 [ sizeof ( stbir_uint32 ) = = 4 ? 1 : - 1 ] ;
# ifdef _MSC_VER
# define STBIR__NOTUSED(v) (void)(v)
# else
# define STBIR__NOTUSED(v) (void)sizeof(v)
# endif
# define STBIR__ARRAY_SIZE(a) (sizeof((a)) / sizeof((a)[0]))
# ifndef STBIR_DEFAULT_FILTER_UPSAMPLE
# define STBIR_DEFAULT_FILTER_UPSAMPLE STBIR_FILTER_CATMULLROM
# endif
# ifndef STBIR_DEFAULT_FILTER_DOWNSAMPLE
# define STBIR_DEFAULT_FILTER_DOWNSAMPLE STBIR_FILTER_MITCHELL
# endif
# ifndef STBIR_PROGRESS_REPORT
# define STBIR_PROGRESS_REPORT(float_0_to_1)
# endif
# ifndef STBIR_MAX_CHANNELS
# define STBIR_MAX_CHANNELS 64
# endif
# if STBIR_MAX_CHANNELS > 65536
# error "Too many channels; STBIR_MAX_CHANNELS must be no more than 65536."
// because we store the indices in 16-bit variables
# endif
// This value is added to alpha just before premultiplication to avoid
// zeroing out color values. It is equivalent to 2^-80. If you don't want
// that behavior (it may interfere if you have floating point images with
// very small alpha values) then you can define STBIR_NO_ALPHA_EPSILON to
// disable it.
# ifndef STBIR_ALPHA_EPSILON
# define STBIR_ALPHA_EPSILON ((float)1 / (1 << 20) / (1 << 20) / (1 << 20) / (1 << 20))
# endif
# ifdef _MSC_VER
# define STBIR__UNUSED_PARAM(v) (void)(v)
# else
# define STBIR__UNUSED_PARAM(v) (void)sizeof(v)
# endif
// must match stbir_datatype
static unsigned char stbir__type_size [ ] = {
1 , // STBIR_TYPE_UINT8
2 , // STBIR_TYPE_UINT16
4 , // STBIR_TYPE_UINT32
4 , // STBIR_TYPE_FLOAT
} ;
// Kernel function centered at 0
typedef float ( stbir__kernel_fn ) ( float x , float scale ) ;
typedef float ( stbir__support_fn ) ( float scale ) ;
typedef struct
{
stbir__kernel_fn * kernel ;
stbir__support_fn * support ;
} stbir__filter_info ;
// When upsampling, the contributors are which source pixels contribute.
// When downsampling, the contributors are which destination pixels are contributed to.
typedef struct
{
int n0 ; // First contributing pixel
int n1 ; // Last contributing pixel
} stbir__contributors ;
typedef struct
{
const void * input_data ;
int input_w ;
int input_h ;
int input_stride_bytes ;
void * output_data ;
int output_w ;
int output_h ;
int output_stride_bytes ;
float s0 , t0 , s1 , t1 ;
float horizontal_shift ; // Units: output pixels
float vertical_shift ; // Units: output pixels
float horizontal_scale ;
float vertical_scale ;
int channels ;
int alpha_channel ;
stbir_uint32 flags ;
stbir_datatype type ;
stbir_filter horizontal_filter ;
stbir_filter vertical_filter ;
stbir_edge edge_horizontal ;
stbir_edge edge_vertical ;
stbir_colorspace colorspace ;
stbir__contributors * horizontal_contributors ;
float * horizontal_coefficients ;
stbir__contributors * vertical_contributors ;
float * vertical_coefficients ;
int decode_buffer_pixels ;
float * decode_buffer ;
float * horizontal_buffer ;
// cache these because ceil/floor are inexplicably showing up in profile
int horizontal_coefficient_width ;
int vertical_coefficient_width ;
int horizontal_filter_pixel_width ;
int vertical_filter_pixel_width ;
int horizontal_filter_pixel_margin ;
int vertical_filter_pixel_margin ;
int horizontal_num_contributors ;
int vertical_num_contributors ;
int ring_buffer_length_bytes ; // The length of an individual entry in the ring buffer. The total number of ring buffers is stbir__get_filter_pixel_width(filter)
int ring_buffer_num_entries ; // Total number of entries in the ring buffer.
int ring_buffer_first_scanline ;
int ring_buffer_last_scanline ;
int ring_buffer_begin_index ; // first_scanline is at this index in the ring buffer
float * ring_buffer ;
float * encode_buffer ; // A temporary buffer to store floats so we don't lose precision while we do multiply-adds.
int horizontal_contributors_size ;
int horizontal_coefficients_size ;
int vertical_contributors_size ;
int vertical_coefficients_size ;
int decode_buffer_size ;
int horizontal_buffer_size ;
int ring_buffer_size ;
int encode_buffer_size ;
} stbir__info ;
static const float stbir__max_uint8_as_float = 255.0f ;
static const float stbir__max_uint16_as_float = 65535.0f ;
static const double stbir__max_uint32_as_float = 4294967295.0 ;
static stbir__inline int stbir__min ( int a , int b )
{
return a < b ? a : b ;
}
static stbir__inline float stbir__saturate ( float x )
{
if ( x < 0 )
return 0 ;
if ( x > 1 )
return 1 ;
return x ;
}
# ifdef STBIR_SATURATE_INT
static stbir__inline stbir_uint8 stbir__saturate8 ( int x )
{
if ( ( unsigned int ) x < = 255 )
return x ;
if ( x < 0 )
return 0 ;
return 255 ;
}
static stbir__inline stbir_uint16 stbir__saturate16 ( int x )
{
if ( ( unsigned int ) x < = 65535 )
return x ;
if ( x < 0 )
return 0 ;
return 65535 ;
}
# endif
static float stbir__srgb_uchar_to_linear_float [ 256 ] = {
0.000000f , 0.000304f , 0.000607f , 0.000911f , 0.001214f , 0.001518f , 0.001821f , 0.002125f , 0.002428f , 0.002732f , 0.003035f ,
0.003347f , 0.003677f , 0.004025f , 0.004391f , 0.004777f , 0.005182f , 0.005605f , 0.006049f , 0.006512f , 0.006995f , 0.007499f ,
0.008023f , 0.008568f , 0.009134f , 0.009721f , 0.010330f , 0.010960f , 0.011612f , 0.012286f , 0.012983f , 0.013702f , 0.014444f ,
0.015209f , 0.015996f , 0.016807f , 0.017642f , 0.018500f , 0.019382f , 0.020289f , 0.021219f , 0.022174f , 0.023153f , 0.024158f ,
0.025187f , 0.026241f , 0.027321f , 0.028426f , 0.029557f , 0.030713f , 0.031896f , 0.033105f , 0.034340f , 0.035601f , 0.036889f ,
0.038204f , 0.039546f , 0.040915f , 0.042311f , 0.043735f , 0.045186f , 0.046665f , 0.048172f , 0.049707f , 0.051269f , 0.052861f ,
0.054480f , 0.056128f , 0.057805f , 0.059511f , 0.061246f , 0.063010f , 0.064803f , 0.066626f , 0.068478f , 0.070360f , 0.072272f ,
0.074214f , 0.076185f , 0.078187f , 0.080220f , 0.082283f , 0.084376f , 0.086500f , 0.088656f , 0.090842f , 0.093059f , 0.095307f ,
0.097587f , 0.099899f , 0.102242f , 0.104616f , 0.107023f , 0.109462f , 0.111932f , 0.114435f , 0.116971f , 0.119538f , 0.122139f ,
0.124772f , 0.127438f , 0.130136f , 0.132868f , 0.135633f , 0.138432f , 0.141263f , 0.144128f , 0.147027f , 0.149960f , 0.152926f ,
0.155926f , 0.158961f , 0.162029f , 0.165132f , 0.168269f , 0.171441f , 0.174647f , 0.177888f , 0.181164f , 0.184475f , 0.187821f ,
0.191202f , 0.194618f , 0.198069f , 0.201556f , 0.205079f , 0.208637f , 0.212231f , 0.215861f , 0.219526f , 0.223228f , 0.226966f ,
0.230740f , 0.234551f , 0.238398f , 0.242281f , 0.246201f , 0.250158f , 0.254152f , 0.258183f , 0.262251f , 0.266356f , 0.270498f ,
0.274677f , 0.278894f , 0.283149f , 0.287441f , 0.291771f , 0.296138f , 0.300544f , 0.304987f , 0.309469f , 0.313989f , 0.318547f ,
0.323143f , 0.327778f , 0.332452f , 0.337164f , 0.341914f , 0.346704f , 0.351533f , 0.356400f , 0.361307f , 0.366253f , 0.371238f ,
0.376262f , 0.381326f , 0.386430f , 0.391573f , 0.396755f , 0.401978f , 0.407240f , 0.412543f , 0.417885f , 0.423268f , 0.428691f ,
0.434154f , 0.439657f , 0.445201f , 0.450786f , 0.456411f , 0.462077f , 0.467784f , 0.473532f , 0.479320f , 0.485150f , 0.491021f ,
0.496933f , 0.502887f , 0.508881f , 0.514918f , 0.520996f , 0.527115f , 0.533276f , 0.539480f , 0.545725f , 0.552011f , 0.558340f ,
0.564712f , 0.571125f , 0.577581f , 0.584078f , 0.590619f , 0.597202f , 0.603827f , 0.610496f , 0.617207f , 0.623960f , 0.630757f ,
0.637597f , 0.644480f , 0.651406f , 0.658375f , 0.665387f , 0.672443f , 0.679543f , 0.686685f , 0.693872f , 0.701102f , 0.708376f ,
0.715694f , 0.723055f , 0.730461f , 0.737911f , 0.745404f , 0.752942f , 0.760525f , 0.768151f , 0.775822f , 0.783538f , 0.791298f ,
0.799103f , 0.806952f , 0.814847f , 0.822786f , 0.830770f , 0.838799f , 0.846873f , 0.854993f , 0.863157f , 0.871367f , 0.879622f ,
0.887923f , 0.896269f , 0.904661f , 0.913099f , 0.921582f , 0.930111f , 0.938686f , 0.947307f , 0.955974f , 0.964686f , 0.973445f ,
0.982251f , 0.991102f , 1.0f
} ;
static float stbir__srgb_to_linear ( float f )
{
if ( f < = 0.04045f )
return f / 12.92f ;
else
return ( float ) pow ( ( f + 0.055f ) / 1.055f , 2.4f ) ;
}
static float stbir__linear_to_srgb ( float f )
{
if ( f < = 0.0031308f )
return f * 12.92f ;
else
return 1.055f * ( float ) pow ( f , 1 / 2.4f ) - 0.055f ;
}
# ifndef STBIR_NON_IEEE_FLOAT
// From https://gist.github.com/rygorous/2203834
typedef union
{
stbir_uint32 u ;
float f ;
} stbir__FP32 ;
static const stbir_uint32 fp32_to_srgb8_tab4 [ 104 ] = {
0x0073000d , 0x007a000d , 0x0080000d , 0x0087000d , 0x008d000d , 0x0094000d , 0x009a000d , 0x00a1000d ,
0x00a7001a , 0x00b4001a , 0x00c1001a , 0x00ce001a , 0x00da001a , 0x00e7001a , 0x00f4001a , 0x0101001a ,
0x010e0033 , 0x01280033 , 0x01410033 , 0x015b0033 , 0x01750033 , 0x018f0033 , 0x01a80033 , 0x01c20033 ,
0x01dc0067 , 0x020f0067 , 0x02430067 , 0x02760067 , 0x02aa0067 , 0x02dd0067 , 0x03110067 , 0x03440067 ,
0x037800ce , 0x03df00ce , 0x044600ce , 0x04ad00ce , 0x051400ce , 0x057b00c5 , 0x05dd00bc , 0x063b00b5 ,
0x06970158 , 0x07420142 , 0x07e30130 , 0x087b0120 , 0x090b0112 , 0x09940106 , 0x0a1700fc , 0x0a9500f2 ,
0x0b0f01cb , 0x0bf401ae , 0x0ccb0195 , 0x0d950180 , 0x0e56016e , 0x0f0d015e , 0x0fbc0150 , 0x10630143 ,
0x11070264 , 0x1238023e , 0x1357021d , 0x14660201 , 0x156601e9 , 0x165a01d3 , 0x174401c0 , 0x182401af ,
0x18fe0331 , 0x1a9602fe , 0x1c1502d2 , 0x1d7e02ad , 0x1ed4028d , 0x201a0270 , 0x21520256 , 0x227d0240 ,
0x239f0443 , 0x25c003fe , 0x27bf03c4 , 0x29a10392 , 0x2b6a0367 , 0x2d1d0341 , 0x2ebe031f , 0x304d0300 ,
0x31d105b0 , 0x34a80555 , 0x37520507 , 0x39d504c5 , 0x3c37048b , 0x3e7c0458 , 0x40a8042a , 0x42bd0401 ,
0x44c20798 , 0x488e071e , 0x4c1c06b6 , 0x4f76065d , 0x52a50610 , 0x55ac05cc , 0x5892058f , 0x5b590559 ,
0x5e0c0a23 , 0x631c0980 , 0x67db08f6 , 0x6c55087f , 0x70940818 , 0x74a007bd , 0x787d076c , 0x7c330723 ,
} ;
static stbir_uint8 stbir__linear_to_srgb_uchar ( float in )
{
static const stbir__FP32 almostone = { 0x3f7fffff } ; // 1-eps
static const stbir__FP32 minval = { ( 127 - 13 ) < < 23 } ;
stbir_uint32 tab , bias , scale , t ;
stbir__FP32 f ;
// Clamp to [2^(-13), 1-eps]; these two values map to 0 and 1, respectively.
// The tests are carefully written so that NaNs map to 0, same as in the reference
// implementation.
if ( ! ( in > minval . f ) ) // written this way to catch NaNs
in = minval . f ;
if ( in > almostone . f )
in = almostone . f ;
// Do the table lookup and unpack bias, scale
f . f = in ;
tab = fp32_to_srgb8_tab4 [ ( f . u - minval . u ) > > 20 ] ;
bias = ( tab > > 16 ) < < 9 ;
scale = tab & 0xffff ;
// Grab next-highest mantissa bits and perform linear interpolation
t = ( f . u > > 12 ) & 0xff ;
return ( unsigned char ) ( ( bias + scale * t ) > > 16 ) ;
}
# else
// sRGB transition values, scaled by 1<<28
static int stbir__srgb_offset_to_linear_scaled [ 256 ] =
{
0 , 40738 , 122216 , 203693 , 285170 , 366648 , 448125 , 529603 ,
611080 , 692557 , 774035 , 855852 , 942009 , 1033024 , 1128971 , 1229926 ,
1335959 , 1447142 , 1563542 , 1685229 , 1812268 , 1944725 , 2082664 , 2226148 ,
2375238 , 2529996 , 2690481 , 2856753 , 3028870 , 3206888 , 3390865 , 3580856 ,
3776916 , 3979100 , 4187460 , 4402049 , 4622919 , 4850123 , 5083710 , 5323731 ,
5570236 , 5823273 , 6082892 , 6349140 , 6622065 , 6901714 , 7188133 , 7481369 ,
7781466 , 8088471 , 8402427 , 8723380 , 9051372 , 9386448 , 9728650 , 10078021 ,
10434603 , 10798439 , 11169569 , 11548036 , 11933879 , 12327139 , 12727857 , 13136073 ,
13551826 , 13975156 , 14406100 , 14844697 , 15290987 , 15745007 , 16206795 , 16676389 ,
17153826 , 17639142 , 18132374 , 18633560 , 19142734 , 19659934 , 20185196 , 20718552 ,
21260042 , 21809696 , 22367554 , 22933648 , 23508010 , 24090680 , 24681686 , 25281066 ,
25888850 , 26505076 , 27129772 , 27762974 , 28404716 , 29055026 , 29713942 , 30381490 ,
31057708 , 31742624 , 32436272 , 33138682 , 33849884 , 34569912 , 35298800 , 36036568 ,
36783260 , 37538896 , 38303512 , 39077136 , 39859796 , 40651528 , 41452360 , 42262316 ,
43081432 , 43909732 , 44747252 , 45594016 , 46450052 , 47315392 , 48190064 , 49074096 ,
49967516 , 50870356 , 51782636 , 52704392 , 53635648 , 54576432 , 55526772 , 56486700 ,
57456236 , 58435408 , 59424248 , 60422780 , 61431036 , 62449032 , 63476804 , 64514376 ,
65561776 , 66619028 , 67686160 , 68763192 , 69850160 , 70947088 , 72053992 , 73170912 ,
74297864 , 75434880 , 76581976 , 77739184 , 78906536 , 80084040 , 81271736 , 82469648 ,
83677792 , 84896192 , 86124888 , 87363888 , 88613232 , 89872928 , 91143016 , 92423512 ,
93714432 , 95015816 , 96327688 , 97650056 , 98982952 , 100326408 , 101680440 , 103045072 ,
104420320 , 105806224 , 107202800 , 108610064 , 110028048 , 111456776 , 112896264 , 114346544 ,
115807632 , 117279552 , 118762328 , 120255976 , 121760536 , 123276016 , 124802440 , 126339832 ,
127888216 , 129447616 , 131018048 , 132599544 , 134192112 , 135795792 , 137410592 , 139036528 ,
140673648 , 142321952 , 143981456 , 145652208 , 147334208 , 149027488 , 150732064 , 152447968 ,
154175200 , 155913792 , 157663776 , 159425168 , 161197984 , 162982240 , 164777968 , 166585184 ,
168403904 , 170234160 , 172075968 , 173929344 , 175794320 , 177670896 , 179559120 , 181458992 ,
183370528 , 185293776 , 187228736 , 189175424 , 191133888 , 193104112 , 195086128 , 197079968 ,
199085648 , 201103184 , 203132592 , 205173888 , 207227120 , 209292272 , 211369392 , 213458480 ,
215559568 , 217672656 , 219797792 , 221934976 , 224084240 , 226245600 , 228419056 , 230604656 ,
232802400 , 235012320 , 237234432 , 239468736 , 241715280 , 243974080 , 246245120 , 248528464 ,
250824112 , 253132064 , 255452368 , 257785040 , 260130080 , 262487520 , 264857376 , 267239664 ,
} ;
static stbir_uint8 stbir__linear_to_srgb_uchar ( float f )
{
int x = ( int ) ( f * ( 1 < < 28 ) ) ; // has headroom so you don't need to clamp
int v = 0 ;
int i ;
// Refine the guess with a short binary search.
i = v + 128 ; if ( x > = stbir__srgb_offset_to_linear_scaled [ i ] ) v = i ;
i = v + 64 ; if ( x > = stbir__srgb_offset_to_linear_scaled [ i ] ) v = i ;
i = v + 32 ; if ( x > = stbir__srgb_offset_to_linear_scaled [ i ] ) v = i ;
i = v + 16 ; if ( x > = stbir__srgb_offset_to_linear_scaled [ i ] ) v = i ;
i = v + 8 ; if ( x > = stbir__srgb_offset_to_linear_scaled [ i ] ) v = i ;
i = v + 4 ; if ( x > = stbir__srgb_offset_to_linear_scaled [ i ] ) v = i ;
i = v + 2 ; if ( x > = stbir__srgb_offset_to_linear_scaled [ i ] ) v = i ;
i = v + 1 ; if ( x > = stbir__srgb_offset_to_linear_scaled [ i ] ) v = i ;
return ( stbir_uint8 ) v ;
}
# endif
static float stbir__filter_trapezoid ( float x , float scale )
{
float halfscale = scale / 2 ;
float t = 0.5f + halfscale ;
STBIR_ASSERT ( scale < = 1 ) ;
x = ( float ) fabs ( x ) ;
if ( x > = t )
return 0 ;
else
{
float r = 0.5f - halfscale ;
if ( x < = r )
return 1 ;
else
return ( t - x ) / scale ;
}
}
static float stbir__support_trapezoid ( float scale )
{
STBIR_ASSERT ( scale < = 1 ) ;
return 0.5f + scale / 2 ;
}
static float stbir__filter_triangle ( float x , float s )
{
STBIR__UNUSED_PARAM ( s ) ;
x = ( float ) fabs ( x ) ;
if ( x < = 1.0f )
return 1 - x ;
else
return 0 ;
}
static float stbir__filter_cubic ( float x , float s )
{
STBIR__UNUSED_PARAM ( s ) ;
x = ( float ) fabs ( x ) ;
if ( x < 1.0f )
return ( 4 + x * x * ( 3 * x - 6 ) ) / 6 ;
else if ( x < 2.0f )
return ( 8 + x * ( - 12 + x * ( 6 - x ) ) ) / 6 ;
return ( 0.0f ) ;
}
static float stbir__filter_catmullrom ( float x , float s )
{
STBIR__UNUSED_PARAM ( s ) ;
x = ( float ) fabs ( x ) ;
if ( x < 1.0f )
return 1 - x * x * ( 2.5f - 1.5f * x ) ;
else if ( x < 2.0f )
return 2 - x * ( 4 + x * ( 0.5f * x - 2.5f ) ) ;
return ( 0.0f ) ;
}
static float stbir__filter_mitchell ( float x , float s )
{
STBIR__UNUSED_PARAM ( s ) ;
x = ( float ) fabs ( x ) ;
if ( x < 1.0f )
return ( 16 + x * x * ( 21 * x - 36 ) ) / 18 ;
else if ( x < 2.0f )
return ( 32 + x * ( - 60 + x * ( 36 - 7 * x ) ) ) / 18 ;
return ( 0.0f ) ;
}
static float stbir__support_zero ( float s )
{
STBIR__UNUSED_PARAM ( s ) ;
return 0 ;
}
static float stbir__support_one ( float s )
{
STBIR__UNUSED_PARAM ( s ) ;
return 1 ;
}
static float stbir__support_two ( float s )
{
STBIR__UNUSED_PARAM ( s ) ;
return 2 ;
}
static stbir__filter_info stbir__filter_info_table [ ] = {
{ NULL , stbir__support_zero } ,
{ stbir__filter_trapezoid , stbir__support_trapezoid } ,
{ stbir__filter_triangle , stbir__support_one } ,
{ stbir__filter_cubic , stbir__support_two } ,
{ stbir__filter_catmullrom , stbir__support_two } ,
{ stbir__filter_mitchell , stbir__support_two } ,
} ;
stbir__inline static int stbir__use_upsampling ( float ratio )
{
return ratio > 1 ;
}
stbir__inline static int stbir__use_width_upsampling ( stbir__info * stbir_info )
{
return stbir__use_upsampling ( stbir_info - > horizontal_scale ) ;
}
stbir__inline static int stbir__use_height_upsampling ( stbir__info * stbir_info )
{
return stbir__use_upsampling ( stbir_info - > vertical_scale ) ;
}
// This is the maximum number of input samples that can affect an output sample
// with the given filter
static int stbir__get_filter_pixel_width ( stbir_filter filter , float scale )
{
STBIR_ASSERT ( filter ! = 0 ) ;
STBIR_ASSERT ( filter < STBIR__ARRAY_SIZE ( stbir__filter_info_table ) ) ;
if ( stbir__use_upsampling ( scale ) )
return ( int ) ceil ( stbir__filter_info_table [ filter ] . support ( 1 / scale ) * 2 ) ;
else
return ( int ) ceil ( stbir__filter_info_table [ filter ] . support ( scale ) * 2 / scale ) ;
}
// This is how much to expand buffers to account for filters seeking outside
// the image boundaries.
static int stbir__get_filter_pixel_margin ( stbir_filter filter , float scale )
{
return stbir__get_filter_pixel_width ( filter , scale ) / 2 ;
}
static int stbir__get_coefficient_width ( stbir_filter filter , float scale )
{
if ( stbir__use_upsampling ( scale ) )
return ( int ) ceil ( stbir__filter_info_table [ filter ] . support ( 1 / scale ) * 2 ) ;
else
return ( int ) ceil ( stbir__filter_info_table [ filter ] . support ( scale ) * 2 ) ;
}
static int stbir__get_contributors ( float scale , stbir_filter filter , int input_size , int output_size )
{
if ( stbir__use_upsampling ( scale ) )
return output_size ;
else
return ( input_size + stbir__get_filter_pixel_margin ( filter , scale ) * 2 ) ;
}
static int stbir__get_total_horizontal_coefficients ( stbir__info * info )
{
return info - > horizontal_num_contributors
* stbir__get_coefficient_width ( info - > horizontal_filter , info - > horizontal_scale ) ;
}
static int stbir__get_total_vertical_coefficients ( stbir__info * info )
{
return info - > vertical_num_contributors
* stbir__get_coefficient_width ( info - > vertical_filter , info - > vertical_scale ) ;
}
static stbir__contributors * stbir__get_contributor ( stbir__contributors * contributors , int n )
{
return & contributors [ n ] ;
}
// For perf reasons this code is duplicated in stbir__resample_horizontal_upsample/downsample,
// if you change it here change it there too.
static float * stbir__get_coefficient ( float * coefficients , stbir_filter filter , float scale , int n , int c )
{
int width = stbir__get_coefficient_width ( filter , scale ) ;
return & coefficients [ width * n + c ] ;
}
static int stbir__edge_wrap_slow ( stbir_edge edge , int n , int max )
{
switch ( edge )
{
case STBIR_EDGE_ZERO :
return 0 ; // we'll decode the wrong pixel here, and then overwrite with 0s later
case STBIR_EDGE_CLAMP :
if ( n < 0 )
return 0 ;
if ( n > = max )
return max - 1 ;
return n ; // NOTREACHED
case STBIR_EDGE_REFLECT :
{
if ( n < 0 )
{
if ( n < max )
return - n ;
else
return max - 1 ;
}
if ( n > = max )
{
int max2 = max * 2 ;
if ( n > = max2 )
return 0 ;
else
return max2 - n - 1 ;
}
return n ; // NOTREACHED
}
case STBIR_EDGE_WRAP :
if ( n > = 0 )
return ( n % max ) ;
else
{
int m = ( - n ) % max ;
if ( m ! = 0 )
m = max - m ;
return ( m ) ;
}
// NOTREACHED
default :
STBIR_ASSERT ( ! " Unimplemented edge type " ) ;
return 0 ;
}
}
stbir__inline static int stbir__edge_wrap ( stbir_edge edge , int n , int max )
{
// avoid per-pixel switch
if ( n > = 0 & & n < max )
return n ;
return stbir__edge_wrap_slow ( edge , n , max ) ;
}
// What input pixels contribute to this output pixel?
static void stbir__calculate_sample_range_upsample ( int n , float out_filter_radius , float scale_ratio , float out_shift , int * in_first_pixel , int * in_last_pixel , float * in_center_of_out )
{
float out_pixel_center = ( float ) n + 0.5f ;
float out_pixel_influence_lowerbound = out_pixel_center - out_filter_radius ;
float out_pixel_influence_upperbound = out_pixel_center + out_filter_radius ;
float in_pixel_influence_lowerbound = ( out_pixel_influence_lowerbound + out_shift ) / scale_ratio ;
float in_pixel_influence_upperbound = ( out_pixel_influence_upperbound + out_shift ) / scale_ratio ;
* in_center_of_out = ( out_pixel_center + out_shift ) / scale_ratio ;
* in_first_pixel = ( int ) ( floor ( in_pixel_influence_lowerbound + 0.5 ) ) ;
* in_last_pixel = ( int ) ( floor ( in_pixel_influence_upperbound - 0.5 ) ) ;
}
// What output pixels does this input pixel contribute to?
static void stbir__calculate_sample_range_downsample ( int n , float in_pixels_radius , float scale_ratio , float out_shift , int * out_first_pixel , int * out_last_pixel , float * out_center_of_in )
{
float in_pixel_center = ( float ) n + 0.5f ;
float in_pixel_influence_lowerbound = in_pixel_center - in_pixels_radius ;
float in_pixel_influence_upperbound = in_pixel_center + in_pixels_radius ;
float out_pixel_influence_lowerbound = in_pixel_influence_lowerbound * scale_ratio - out_shift ;
float out_pixel_influence_upperbound = in_pixel_influence_upperbound * scale_ratio - out_shift ;
* out_center_of_in = in_pixel_center * scale_ratio - out_shift ;
* out_first_pixel = ( int ) ( floor ( out_pixel_influence_lowerbound + 0.5 ) ) ;
* out_last_pixel = ( int ) ( floor ( out_pixel_influence_upperbound - 0.5 ) ) ;
}
static void stbir__calculate_coefficients_upsample ( stbir_filter filter , float scale , int in_first_pixel , int in_last_pixel , float in_center_of_out , stbir__contributors * contributor , float * coefficient_group )
{
int i ;
float total_filter = 0 ;
float filter_scale ;
STBIR_ASSERT ( in_last_pixel - in_first_pixel < = ( int ) ceil ( stbir__filter_info_table [ filter ] . support ( 1 / scale ) * 2 ) ) ; // Taken directly from stbir__get_coefficient_width() which we can't call because we don't know if we're horizontal or vertical.
contributor - > n0 = in_first_pixel ;
contributor - > n1 = in_last_pixel ;
STBIR_ASSERT ( contributor - > n1 > = contributor - > n0 ) ;
for ( i = 0 ; i < = in_last_pixel - in_first_pixel ; i + + )
{
float in_pixel_center = ( float ) ( i + in_first_pixel ) + 0.5f ;
coefficient_group [ i ] = stbir__filter_info_table [ filter ] . kernel ( in_center_of_out - in_pixel_center , 1 / scale ) ;
// If the coefficient is zero, skip it. (Don't do the <0 check here, we want the influence of those outside pixels.)
if ( i = = 0 & & ! coefficient_group [ i ] )
{
contributor - > n0 = + + in_first_pixel ;
i - - ;
continue ;
}
total_filter + = coefficient_group [ i ] ;
}
// NOTE(fg): Not actually true in general, nor is there any reason to expect it should be.
// It would be true in exact math but is at best approximately true in floating-point math,
// and it would not make sense to try and put actual bounds on this here because it depends
// on the image aspect ratio which can get pretty extreme.
//STBIR_ASSERT(stbir__filter_info_table[filter].kernel((float)(in_last_pixel + 1) + 0.5f - in_center_of_out, 1/scale) == 0);
STBIR_ASSERT ( total_filter > 0.9 ) ;
STBIR_ASSERT ( total_filter < 1.1f ) ; // Make sure it's not way off.
// Make sure the sum of all coefficients is 1.
filter_scale = 1 / total_filter ;
for ( i = 0 ; i < = in_last_pixel - in_first_pixel ; i + + )
coefficient_group [ i ] * = filter_scale ;
for ( i = in_last_pixel - in_first_pixel ; i > = 0 ; i - - )
{
if ( coefficient_group [ i ] )
break ;
// This line has no weight. We can skip it.
contributor - > n1 = contributor - > n0 + i - 1 ;
}
}
static void stbir__calculate_coefficients_downsample ( stbir_filter filter , float scale_ratio , int out_first_pixel , int out_last_pixel , float out_center_of_in , stbir__contributors * contributor , float * coefficient_group )
{
int i ;
STBIR_ASSERT ( out_last_pixel - out_first_pixel < = ( int ) ceil ( stbir__filter_info_table [ filter ] . support ( scale_ratio ) * 2 ) ) ; // Taken directly from stbir__get_coefficient_width() which we can't call because we don't know if we're horizontal or vertical.
contributor - > n0 = out_first_pixel ;
contributor - > n1 = out_last_pixel ;
STBIR_ASSERT ( contributor - > n1 > = contributor - > n0 ) ;
for ( i = 0 ; i < = out_last_pixel - out_first_pixel ; i + + )
{
float out_pixel_center = ( float ) ( i + out_first_pixel ) + 0.5f ;
float x = out_pixel_center - out_center_of_in ;
coefficient_group [ i ] = stbir__filter_info_table [ filter ] . kernel ( x , scale_ratio ) * scale_ratio ;
}
// NOTE(fg): Not actually true in general, nor is there any reason to expect it should be.
// It would be true in exact math but is at best approximately true in floating-point math,
// and it would not make sense to try and put actual bounds on this here because it depends
// on the image aspect ratio which can get pretty extreme.
//STBIR_ASSERT(stbir__filter_info_table[filter].kernel((float)(out_last_pixel + 1) + 0.5f - out_center_of_in, scale_ratio) == 0);
for ( i = out_last_pixel - out_first_pixel ; i > = 0 ; i - - )
{
if ( coefficient_group [ i ] )
break ;
// This line has no weight. We can skip it.
contributor - > n1 = contributor - > n0 + i - 1 ;
}
}
static void stbir__normalize_downsample_coefficients ( stbir__contributors * contributors , float * coefficients , stbir_filter filter , float scale_ratio , int input_size , int output_size )
{
int num_contributors = stbir__get_contributors ( scale_ratio , filter , input_size , output_size ) ;
int num_coefficients = stbir__get_coefficient_width ( filter , scale_ratio ) ;
int i , j ;
int skip ;
for ( i = 0 ; i < output_size ; i + + )
{
float scale ;
float total = 0 ;
for ( j = 0 ; j < num_contributors ; j + + )
{
if ( i > = contributors [ j ] . n0 & & i < = contributors [ j ] . n1 )
{
float coefficient = * stbir__get_coefficient ( coefficients , filter , scale_ratio , j , i - contributors [ j ] . n0 ) ;
total + = coefficient ;
}
else if ( i < contributors [ j ] . n0 )
break ;
}
STBIR_ASSERT ( total > 0.9f ) ;
STBIR_ASSERT ( total < 1.1f ) ;
scale = 1 / total ;
for ( j = 0 ; j < num_contributors ; j + + )
{
if ( i > = contributors [ j ] . n0 & & i < = contributors [ j ] . n1 )
* stbir__get_coefficient ( coefficients , filter , scale_ratio , j , i - contributors [ j ] . n0 ) * = scale ;
else if ( i < contributors [ j ] . n0 )
break ;
}
}
// Optimize: Skip zero coefficients and contributions outside of image bounds.
// Do this after normalizing because normalization depends on the n0/n1 values.
for ( j = 0 ; j < num_contributors ; j + + )
{
int range , max , width ;
skip = 0 ;
while ( * stbir__get_coefficient ( coefficients , filter , scale_ratio , j , skip ) = = 0 )
skip + + ;
contributors [ j ] . n0 + = skip ;
while ( contributors [ j ] . n0 < 0 )
{
contributors [ j ] . n0 + + ;
skip + + ;
}
range = contributors [ j ] . n1 - contributors [ j ] . n0 + 1 ;
max = stbir__min ( num_coefficients , range ) ;
width = stbir__get_coefficient_width ( filter , scale_ratio ) ;
for ( i = 0 ; i < max ; i + + )
{
if ( i + skip > = width )
break ;
* stbir__get_coefficient ( coefficients , filter , scale_ratio , j , i ) = * stbir__get_coefficient ( coefficients , filter , scale_ratio , j , i + skip ) ;
}
continue ;
}
// Using min to avoid writing into invalid pixels.
for ( i = 0 ; i < num_contributors ; i + + )
contributors [ i ] . n1 = stbir__min ( contributors [ i ] . n1 , output_size - 1 ) ;
}
// Each scan line uses the same kernel values so we should calculate the kernel
// values once and then we can use them for every scan line.
static void stbir__calculate_filters ( stbir__contributors * contributors , float * coefficients , stbir_filter filter , float scale_ratio , float shift , int input_size , int output_size )
{
int n ;
int total_contributors = stbir__get_contributors ( scale_ratio , filter , input_size , output_size ) ;
if ( stbir__use_upsampling ( scale_ratio ) )
{
float out_pixels_radius = stbir__filter_info_table [ filter ] . support ( 1 / scale_ratio ) * scale_ratio ;
// Looping through out pixels
for ( n = 0 ; n < total_contributors ; n + + )
{
float in_center_of_out ; // Center of the current out pixel in the in pixel space
int in_first_pixel , in_last_pixel ;
stbir__calculate_sample_range_upsample ( n , out_pixels_radius , scale_ratio , shift , & in_first_pixel , & in_last_pixel , & in_center_of_out ) ;
stbir__calculate_coefficients_upsample ( filter , scale_ratio , in_first_pixel , in_last_pixel , in_center_of_out , stbir__get_contributor ( contributors , n ) , stbir__get_coefficient ( coefficients , filter , scale_ratio , n , 0 ) ) ;
}
}
else
{
float in_pixels_radius = stbir__filter_info_table [ filter ] . support ( scale_ratio ) / scale_ratio ;
// Looping through in pixels
for ( n = 0 ; n < total_contributors ; n + + )
{
float out_center_of_in ; // Center of the current out pixel in the in pixel space
int out_first_pixel , out_last_pixel ;
int n_adjusted = n - stbir__get_filter_pixel_margin ( filter , scale_ratio ) ;
stbir__calculate_sample_range_downsample ( n_adjusted , in_pixels_radius , scale_ratio , shift , & out_first_pixel , & out_last_pixel , & out_center_of_in ) ;
stbir__calculate_coefficients_downsample ( filter , scale_ratio , out_first_pixel , out_last_pixel , out_center_of_in , stbir__get_contributor ( contributors , n ) , stbir__get_coefficient ( coefficients , filter , scale_ratio , n , 0 ) ) ;
}
stbir__normalize_downsample_coefficients ( contributors , coefficients , filter , scale_ratio , input_size , output_size ) ;
}
}
static float * stbir__get_decode_buffer ( stbir__info * stbir_info )
{
// The 0 index of the decode buffer starts after the margin. This makes
// it okay to use negative indexes on the decode buffer.
return & stbir_info - > decode_buffer [ stbir_info - > horizontal_filter_pixel_margin * stbir_info - > channels ] ;
}
# define STBIR__DECODE(type, colorspace) ((int)(type) * (STBIR_MAX_COLORSPACES) + (int)(colorspace))
static void stbir__decode_scanline ( stbir__info * stbir_info , int n )
{
int c ;
int channels = stbir_info - > channels ;
int alpha_channel = stbir_info - > alpha_channel ;
int type = stbir_info - > type ;
int colorspace = stbir_info - > colorspace ;
int input_w = stbir_info - > input_w ;
size_t input_stride_bytes = stbir_info - > input_stride_bytes ;
float * decode_buffer = stbir__get_decode_buffer ( stbir_info ) ;
stbir_edge edge_horizontal = stbir_info - > edge_horizontal ;
stbir_edge edge_vertical = stbir_info - > edge_vertical ;
size_t in_buffer_row_offset = stbir__edge_wrap ( edge_vertical , n , stbir_info - > input_h ) * input_stride_bytes ;
const void * input_data = ( char * ) stbir_info - > input_data + in_buffer_row_offset ;
int max_x = input_w + stbir_info - > horizontal_filter_pixel_margin ;
int decode = STBIR__DECODE ( type , colorspace ) ;
int x = - stbir_info - > horizontal_filter_pixel_margin ;
// special handling for STBIR_EDGE_ZERO because it needs to return an item that doesn't appear in the input,
// and we want to avoid paying overhead on every pixel if not STBIR_EDGE_ZERO
if ( edge_vertical = = STBIR_EDGE_ZERO & & ( n < 0 | | n > = stbir_info - > input_h ) )
{
for ( ; x < max_x ; x + + )
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ x * channels + c ] = 0 ;
return ;
}
switch ( decode )
{
case STBIR__DECODE ( STBIR_TYPE_UINT8 , STBIR_COLORSPACE_LINEAR ) :
for ( ; x < max_x ; x + + )
{
int decode_pixel_index = x * channels ;
int input_pixel_index = stbir__edge_wrap ( edge_horizontal , x , input_w ) * channels ;
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ decode_pixel_index + c ] = ( ( float ) ( ( const unsigned char * ) input_data ) [ input_pixel_index + c ] ) / stbir__max_uint8_as_float ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT8 , STBIR_COLORSPACE_SRGB ) :
for ( ; x < max_x ; x + + )
{
int decode_pixel_index = x * channels ;
int input_pixel_index = stbir__edge_wrap ( edge_horizontal , x , input_w ) * channels ;
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ decode_pixel_index + c ] = stbir__srgb_uchar_to_linear_float [ ( ( const unsigned char * ) input_data ) [ input_pixel_index + c ] ] ;
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) )
decode_buffer [ decode_pixel_index + alpha_channel ] = ( ( float ) ( ( const unsigned char * ) input_data ) [ input_pixel_index + alpha_channel ] ) / stbir__max_uint8_as_float ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT16 , STBIR_COLORSPACE_LINEAR ) :
for ( ; x < max_x ; x + + )
{
int decode_pixel_index = x * channels ;
int input_pixel_index = stbir__edge_wrap ( edge_horizontal , x , input_w ) * channels ;
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ decode_pixel_index + c ] = ( ( float ) ( ( const unsigned short * ) input_data ) [ input_pixel_index + c ] ) / stbir__max_uint16_as_float ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT16 , STBIR_COLORSPACE_SRGB ) :
for ( ; x < max_x ; x + + )
{
int decode_pixel_index = x * channels ;
int input_pixel_index = stbir__edge_wrap ( edge_horizontal , x , input_w ) * channels ;
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ decode_pixel_index + c ] = stbir__srgb_to_linear ( ( ( float ) ( ( const unsigned short * ) input_data ) [ input_pixel_index + c ] ) / stbir__max_uint16_as_float ) ;
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) )
decode_buffer [ decode_pixel_index + alpha_channel ] = ( ( float ) ( ( const unsigned short * ) input_data ) [ input_pixel_index + alpha_channel ] ) / stbir__max_uint16_as_float ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT32 , STBIR_COLORSPACE_LINEAR ) :
for ( ; x < max_x ; x + + )
{
int decode_pixel_index = x * channels ;
int input_pixel_index = stbir__edge_wrap ( edge_horizontal , x , input_w ) * channels ;
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ decode_pixel_index + c ] = ( float ) ( ( ( double ) ( ( const unsigned int * ) input_data ) [ input_pixel_index + c ] ) / stbir__max_uint32_as_float ) ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT32 , STBIR_COLORSPACE_SRGB ) :
for ( ; x < max_x ; x + + )
{
int decode_pixel_index = x * channels ;
int input_pixel_index = stbir__edge_wrap ( edge_horizontal , x , input_w ) * channels ;
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ decode_pixel_index + c ] = stbir__srgb_to_linear ( ( float ) ( ( ( double ) ( ( const unsigned int * ) input_data ) [ input_pixel_index + c ] ) / stbir__max_uint32_as_float ) ) ;
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) )
decode_buffer [ decode_pixel_index + alpha_channel ] = ( float ) ( ( ( double ) ( ( const unsigned int * ) input_data ) [ input_pixel_index + alpha_channel ] ) / stbir__max_uint32_as_float ) ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_FLOAT , STBIR_COLORSPACE_LINEAR ) :
for ( ; x < max_x ; x + + )
{
int decode_pixel_index = x * channels ;
int input_pixel_index = stbir__edge_wrap ( edge_horizontal , x , input_w ) * channels ;
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ decode_pixel_index + c ] = ( ( const float * ) input_data ) [ input_pixel_index + c ] ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_FLOAT , STBIR_COLORSPACE_SRGB ) :
for ( ; x < max_x ; x + + )
{
int decode_pixel_index = x * channels ;
int input_pixel_index = stbir__edge_wrap ( edge_horizontal , x , input_w ) * channels ;
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ decode_pixel_index + c ] = stbir__srgb_to_linear ( ( ( const float * ) input_data ) [ input_pixel_index + c ] ) ;
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) )
decode_buffer [ decode_pixel_index + alpha_channel ] = ( ( const float * ) input_data ) [ input_pixel_index + alpha_channel ] ;
}
break ;
default :
STBIR_ASSERT ( ! " Unknown type/colorspace/channels combination. " ) ;
break ;
}
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_PREMULTIPLIED ) )
{
for ( x = - stbir_info - > horizontal_filter_pixel_margin ; x < max_x ; x + + )
{
int decode_pixel_index = x * channels ;
// If the alpha value is 0 it will clobber the color values. Make sure it's not.
float alpha = decode_buffer [ decode_pixel_index + alpha_channel ] ;
# ifndef STBIR_NO_ALPHA_EPSILON
if ( stbir_info - > type ! = STBIR_TYPE_FLOAT ) {
alpha + = STBIR_ALPHA_EPSILON ;
decode_buffer [ decode_pixel_index + alpha_channel ] = alpha ;
}
# endif
for ( c = 0 ; c < channels ; c + + )
{
if ( c = = alpha_channel )
continue ;
decode_buffer [ decode_pixel_index + c ] * = alpha ;
}
}
}
if ( edge_horizontal = = STBIR_EDGE_ZERO )
{
for ( x = - stbir_info - > horizontal_filter_pixel_margin ; x < 0 ; x + + )
{
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ x * channels + c ] = 0 ;
}
for ( x = input_w ; x < max_x ; x + + )
{
for ( c = 0 ; c < channels ; c + + )
decode_buffer [ x * channels + c ] = 0 ;
}
}
}
static float * stbir__get_ring_buffer_entry ( float * ring_buffer , int index , int ring_buffer_length )
{
return & ring_buffer [ index * ring_buffer_length ] ;
}
static float * stbir__add_empty_ring_buffer_entry ( stbir__info * stbir_info , int n )
{
int ring_buffer_index ;
float * ring_buffer ;
stbir_info - > ring_buffer_last_scanline = n ;
if ( stbir_info - > ring_buffer_begin_index < 0 )
{
ring_buffer_index = stbir_info - > ring_buffer_begin_index = 0 ;
stbir_info - > ring_buffer_first_scanline = n ;
}
else
{
ring_buffer_index = ( stbir_info - > ring_buffer_begin_index + ( stbir_info - > ring_buffer_last_scanline - stbir_info - > ring_buffer_first_scanline ) ) % stbir_info - > ring_buffer_num_entries ;
STBIR_ASSERT ( ring_buffer_index ! = stbir_info - > ring_buffer_begin_index ) ;
}
ring_buffer = stbir__get_ring_buffer_entry ( stbir_info - > ring_buffer , ring_buffer_index , stbir_info - > ring_buffer_length_bytes / sizeof ( float ) ) ;
memset ( ring_buffer , 0 , stbir_info - > ring_buffer_length_bytes ) ;
return ring_buffer ;
}
static void stbir__resample_horizontal_upsample ( stbir__info * stbir_info , float * output_buffer )
{
int x , k ;
int output_w = stbir_info - > output_w ;
int channels = stbir_info - > channels ;
float * decode_buffer = stbir__get_decode_buffer ( stbir_info ) ;
stbir__contributors * horizontal_contributors = stbir_info - > horizontal_contributors ;
float * horizontal_coefficients = stbir_info - > horizontal_coefficients ;
int coefficient_width = stbir_info - > horizontal_coefficient_width ;
for ( x = 0 ; x < output_w ; x + + )
{
int n0 = horizontal_contributors [ x ] . n0 ;
int n1 = horizontal_contributors [ x ] . n1 ;
int out_pixel_index = x * channels ;
int coefficient_group = coefficient_width * x ;
int coefficient_counter = 0 ;
STBIR_ASSERT ( n1 > = n0 ) ;
STBIR_ASSERT ( n0 > = - stbir_info - > horizontal_filter_pixel_margin ) ;
STBIR_ASSERT ( n1 > = - stbir_info - > horizontal_filter_pixel_margin ) ;
STBIR_ASSERT ( n0 < stbir_info - > input_w + stbir_info - > horizontal_filter_pixel_margin ) ;
STBIR_ASSERT ( n1 < stbir_info - > input_w + stbir_info - > horizontal_filter_pixel_margin ) ;
switch ( channels ) {
case 1 :
for ( k = n0 ; k < = n1 ; k + + )
{
int in_pixel_index = k * 1 ;
float coefficient = horizontal_coefficients [ coefficient_group + coefficient_counter + + ] ;
STBIR_ASSERT ( coefficient ! = 0 ) ;
output_buffer [ out_pixel_index + 0 ] + = decode_buffer [ in_pixel_index + 0 ] * coefficient ;
}
break ;
case 2 :
for ( k = n0 ; k < = n1 ; k + + )
{
int in_pixel_index = k * 2 ;
float coefficient = horizontal_coefficients [ coefficient_group + coefficient_counter + + ] ;
STBIR_ASSERT ( coefficient ! = 0 ) ;
output_buffer [ out_pixel_index + 0 ] + = decode_buffer [ in_pixel_index + 0 ] * coefficient ;
output_buffer [ out_pixel_index + 1 ] + = decode_buffer [ in_pixel_index + 1 ] * coefficient ;
}
break ;
case 3 :
for ( k = n0 ; k < = n1 ; k + + )
{
int in_pixel_index = k * 3 ;
float coefficient = horizontal_coefficients [ coefficient_group + coefficient_counter + + ] ;
STBIR_ASSERT ( coefficient ! = 0 ) ;
output_buffer [ out_pixel_index + 0 ] + = decode_buffer [ in_pixel_index + 0 ] * coefficient ;
output_buffer [ out_pixel_index + 1 ] + = decode_buffer [ in_pixel_index + 1 ] * coefficient ;
output_buffer [ out_pixel_index + 2 ] + = decode_buffer [ in_pixel_index + 2 ] * coefficient ;
}
break ;
case 4 :
for ( k = n0 ; k < = n1 ; k + + )
{
int in_pixel_index = k * 4 ;
float coefficient = horizontal_coefficients [ coefficient_group + coefficient_counter + + ] ;
STBIR_ASSERT ( coefficient ! = 0 ) ;
output_buffer [ out_pixel_index + 0 ] + = decode_buffer [ in_pixel_index + 0 ] * coefficient ;
output_buffer [ out_pixel_index + 1 ] + = decode_buffer [ in_pixel_index + 1 ] * coefficient ;
output_buffer [ out_pixel_index + 2 ] + = decode_buffer [ in_pixel_index + 2 ] * coefficient ;
output_buffer [ out_pixel_index + 3 ] + = decode_buffer [ in_pixel_index + 3 ] * coefficient ;
}
break ;
default :
for ( k = n0 ; k < = n1 ; k + + )
{
int in_pixel_index = k * channels ;
float coefficient = horizontal_coefficients [ coefficient_group + coefficient_counter + + ] ;
int c ;
STBIR_ASSERT ( coefficient ! = 0 ) ;
for ( c = 0 ; c < channels ; c + + )
output_buffer [ out_pixel_index + c ] + = decode_buffer [ in_pixel_index + c ] * coefficient ;
}
break ;
}
}
}
static void stbir__resample_horizontal_downsample ( stbir__info * stbir_info , float * output_buffer )
{
int x , k ;
int input_w = stbir_info - > input_w ;
int channels = stbir_info - > channels ;
float * decode_buffer = stbir__get_decode_buffer ( stbir_info ) ;
stbir__contributors * horizontal_contributors = stbir_info - > horizontal_contributors ;
float * horizontal_coefficients = stbir_info - > horizontal_coefficients ;
int coefficient_width = stbir_info - > horizontal_coefficient_width ;
int filter_pixel_margin = stbir_info - > horizontal_filter_pixel_margin ;
int max_x = input_w + filter_pixel_margin * 2 ;
STBIR_ASSERT ( ! stbir__use_width_upsampling ( stbir_info ) ) ;
switch ( channels ) {
case 1 :
for ( x = 0 ; x < max_x ; x + + )
{
int n0 = horizontal_contributors [ x ] . n0 ;
int n1 = horizontal_contributors [ x ] . n1 ;
int in_x = x - filter_pixel_margin ;
int in_pixel_index = in_x * 1 ;
int max_n = n1 ;
int coefficient_group = coefficient_width * x ;
for ( k = n0 ; k < = max_n ; k + + )
{
int out_pixel_index = k * 1 ;
float coefficient = horizontal_coefficients [ coefficient_group + k - n0 ] ;
output_buffer [ out_pixel_index + 0 ] + = decode_buffer [ in_pixel_index + 0 ] * coefficient ;
}
}
break ;
case 2 :
for ( x = 0 ; x < max_x ; x + + )
{
int n0 = horizontal_contributors [ x ] . n0 ;
int n1 = horizontal_contributors [ x ] . n1 ;
int in_x = x - filter_pixel_margin ;
int in_pixel_index = in_x * 2 ;
int max_n = n1 ;
int coefficient_group = coefficient_width * x ;
for ( k = n0 ; k < = max_n ; k + + )
{
int out_pixel_index = k * 2 ;
float coefficient = horizontal_coefficients [ coefficient_group + k - n0 ] ;
output_buffer [ out_pixel_index + 0 ] + = decode_buffer [ in_pixel_index + 0 ] * coefficient ;
output_buffer [ out_pixel_index + 1 ] + = decode_buffer [ in_pixel_index + 1 ] * coefficient ;
}
}
break ;
case 3 :
for ( x = 0 ; x < max_x ; x + + )
{
int n0 = horizontal_contributors [ x ] . n0 ;
int n1 = horizontal_contributors [ x ] . n1 ;
int in_x = x - filter_pixel_margin ;
int in_pixel_index = in_x * 3 ;
int max_n = n1 ;
int coefficient_group = coefficient_width * x ;
for ( k = n0 ; k < = max_n ; k + + )
{
int out_pixel_index = k * 3 ;
float coefficient = horizontal_coefficients [ coefficient_group + k - n0 ] ;
output_buffer [ out_pixel_index + 0 ] + = decode_buffer [ in_pixel_index + 0 ] * coefficient ;
output_buffer [ out_pixel_index + 1 ] + = decode_buffer [ in_pixel_index + 1 ] * coefficient ;
output_buffer [ out_pixel_index + 2 ] + = decode_buffer [ in_pixel_index + 2 ] * coefficient ;
}
}
break ;
case 4 :
for ( x = 0 ; x < max_x ; x + + )
{
int n0 = horizontal_contributors [ x ] . n0 ;
int n1 = horizontal_contributors [ x ] . n1 ;
int in_x = x - filter_pixel_margin ;
int in_pixel_index = in_x * 4 ;
int max_n = n1 ;
int coefficient_group = coefficient_width * x ;
for ( k = n0 ; k < = max_n ; k + + )
{
int out_pixel_index = k * 4 ;
float coefficient = horizontal_coefficients [ coefficient_group + k - n0 ] ;
output_buffer [ out_pixel_index + 0 ] + = decode_buffer [ in_pixel_index + 0 ] * coefficient ;
output_buffer [ out_pixel_index + 1 ] + = decode_buffer [ in_pixel_index + 1 ] * coefficient ;
output_buffer [ out_pixel_index + 2 ] + = decode_buffer [ in_pixel_index + 2 ] * coefficient ;
output_buffer [ out_pixel_index + 3 ] + = decode_buffer [ in_pixel_index + 3 ] * coefficient ;
}
}
break ;
default :
for ( x = 0 ; x < max_x ; x + + )
{
int n0 = horizontal_contributors [ x ] . n0 ;
int n1 = horizontal_contributors [ x ] . n1 ;
int in_x = x - filter_pixel_margin ;
int in_pixel_index = in_x * channels ;
int max_n = n1 ;
int coefficient_group = coefficient_width * x ;
for ( k = n0 ; k < = max_n ; k + + )
{
int c ;
int out_pixel_index = k * channels ;
float coefficient = horizontal_coefficients [ coefficient_group + k - n0 ] ;
for ( c = 0 ; c < channels ; c + + )
output_buffer [ out_pixel_index + c ] + = decode_buffer [ in_pixel_index + c ] * coefficient ;
}
}
break ;
}
}
static void stbir__decode_and_resample_upsample ( stbir__info * stbir_info , int n )
{
// Decode the nth scanline from the source image into the decode buffer.
stbir__decode_scanline ( stbir_info , n ) ;
// Now resample it into the ring buffer.
if ( stbir__use_width_upsampling ( stbir_info ) )
stbir__resample_horizontal_upsample ( stbir_info , stbir__add_empty_ring_buffer_entry ( stbir_info , n ) ) ;
else
stbir__resample_horizontal_downsample ( stbir_info , stbir__add_empty_ring_buffer_entry ( stbir_info , n ) ) ;
// Now it's sitting in the ring buffer ready to be used as source for the vertical sampling.
}
static void stbir__decode_and_resample_downsample ( stbir__info * stbir_info , int n )
{
// Decode the nth scanline from the source image into the decode buffer.
stbir__decode_scanline ( stbir_info , n ) ;
memset ( stbir_info - > horizontal_buffer , 0 , stbir_info - > output_w * stbir_info - > channels * sizeof ( float ) ) ;
// Now resample it into the horizontal buffer.
if ( stbir__use_width_upsampling ( stbir_info ) )
stbir__resample_horizontal_upsample ( stbir_info , stbir_info - > horizontal_buffer ) ;
else
stbir__resample_horizontal_downsample ( stbir_info , stbir_info - > horizontal_buffer ) ;
// Now it's sitting in the horizontal buffer ready to be distributed into the ring buffers.
}
// Get the specified scan line from the ring buffer.
static float * stbir__get_ring_buffer_scanline ( int get_scanline , float * ring_buffer , int begin_index , int first_scanline , int ring_buffer_num_entries , int ring_buffer_length )
{
int ring_buffer_index = ( begin_index + ( get_scanline - first_scanline ) ) % ring_buffer_num_entries ;
return stbir__get_ring_buffer_entry ( ring_buffer , ring_buffer_index , ring_buffer_length ) ;
}
static void stbir__encode_scanline ( stbir__info * stbir_info , int num_pixels , void * output_buffer , float * encode_buffer , int channels , int alpha_channel , int decode )
{
int x ;
int n ;
int num_nonalpha ;
stbir_uint16 nonalpha [ STBIR_MAX_CHANNELS ] ;
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_PREMULTIPLIED ) )
{
for ( x = 0 ; x < num_pixels ; + + x )
{
int pixel_index = x * channels ;
float alpha = encode_buffer [ pixel_index + alpha_channel ] ;
float reciprocal_alpha = alpha ? 1.0f / alpha : 0 ;
// unrolling this produced a 1% slowdown upscaling a large RGBA linear-space image on my machine - stb
for ( n = 0 ; n < channels ; n + + )
if ( n ! = alpha_channel )
encode_buffer [ pixel_index + n ] * = reciprocal_alpha ;
// We added in a small epsilon to prevent the color channel from being deleted with zero alpha.
// Because we only add it for integer types, it will automatically be discarded on integer
// conversion, so we don't need to subtract it back out (which would be problematic for
// numeric precision reasons).
}
}
// build a table of all channels that need colorspace correction, so
// we don't perform colorspace correction on channels that don't need it.
for ( x = 0 , num_nonalpha = 0 ; x < channels ; + + x )
{
if ( x ! = alpha_channel | | ( stbir_info - > flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) )
{
nonalpha [ num_nonalpha + + ] = ( stbir_uint16 ) x ;
}
}
# define STBIR__ROUND_INT(f) ((int) ((f)+0.5))
# define STBIR__ROUND_UINT(f) ((stbir_uint32) ((f)+0.5))
# ifdef STBIR__SATURATE_INT
# define STBIR__ENCODE_LINEAR8(f) stbir__saturate8 (STBIR__ROUND_INT((f) * stbir__max_uint8_as_float ))
# define STBIR__ENCODE_LINEAR16(f) stbir__saturate16(STBIR__ROUND_INT((f) * stbir__max_uint16_as_float))
# else
# define STBIR__ENCODE_LINEAR8(f) (unsigned char ) STBIR__ROUND_INT(stbir__saturate(f) * stbir__max_uint8_as_float )
# define STBIR__ENCODE_LINEAR16(f) (unsigned short) STBIR__ROUND_INT(stbir__saturate(f) * stbir__max_uint16_as_float)
# endif
switch ( decode )
{
case STBIR__DECODE ( STBIR_TYPE_UINT8 , STBIR_COLORSPACE_LINEAR ) :
for ( x = 0 ; x < num_pixels ; + + x )
{
int pixel_index = x * channels ;
for ( n = 0 ; n < channels ; n + + )
{
int index = pixel_index + n ;
( ( unsigned char * ) output_buffer ) [ index ] = STBIR__ENCODE_LINEAR8 ( encode_buffer [ index ] ) ;
}
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT8 , STBIR_COLORSPACE_SRGB ) :
for ( x = 0 ; x < num_pixels ; + + x )
{
int pixel_index = x * channels ;
for ( n = 0 ; n < num_nonalpha ; n + + )
{
int index = pixel_index + nonalpha [ n ] ;
( ( unsigned char * ) output_buffer ) [ index ] = stbir__linear_to_srgb_uchar ( encode_buffer [ index ] ) ;
}
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) )
( ( unsigned char * ) output_buffer ) [ pixel_index + alpha_channel ] = STBIR__ENCODE_LINEAR8 ( encode_buffer [ pixel_index + alpha_channel ] ) ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT16 , STBIR_COLORSPACE_LINEAR ) :
for ( x = 0 ; x < num_pixels ; + + x )
{
int pixel_index = x * channels ;
for ( n = 0 ; n < channels ; n + + )
{
int index = pixel_index + n ;
( ( unsigned short * ) output_buffer ) [ index ] = STBIR__ENCODE_LINEAR16 ( encode_buffer [ index ] ) ;
}
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT16 , STBIR_COLORSPACE_SRGB ) :
for ( x = 0 ; x < num_pixels ; + + x )
{
int pixel_index = x * channels ;
for ( n = 0 ; n < num_nonalpha ; n + + )
{
int index = pixel_index + nonalpha [ n ] ;
( ( unsigned short * ) output_buffer ) [ index ] = ( unsigned short ) STBIR__ROUND_INT ( stbir__linear_to_srgb ( stbir__saturate ( encode_buffer [ index ] ) ) * stbir__max_uint16_as_float ) ;
}
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) )
( ( unsigned short * ) output_buffer ) [ pixel_index + alpha_channel ] = STBIR__ENCODE_LINEAR16 ( encode_buffer [ pixel_index + alpha_channel ] ) ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT32 , STBIR_COLORSPACE_LINEAR ) :
for ( x = 0 ; x < num_pixels ; + + x )
{
int pixel_index = x * channels ;
for ( n = 0 ; n < channels ; n + + )
{
int index = pixel_index + n ;
( ( unsigned int * ) output_buffer ) [ index ] = ( unsigned int ) STBIR__ROUND_UINT ( ( ( double ) stbir__saturate ( encode_buffer [ index ] ) ) * stbir__max_uint32_as_float ) ;
}
}
break ;
case STBIR__DECODE ( STBIR_TYPE_UINT32 , STBIR_COLORSPACE_SRGB ) :
for ( x = 0 ; x < num_pixels ; + + x )
{
int pixel_index = x * channels ;
for ( n = 0 ; n < num_nonalpha ; n + + )
{
int index = pixel_index + nonalpha [ n ] ;
( ( unsigned int * ) output_buffer ) [ index ] = ( unsigned int ) STBIR__ROUND_UINT ( ( ( double ) stbir__linear_to_srgb ( stbir__saturate ( encode_buffer [ index ] ) ) ) * stbir__max_uint32_as_float ) ;
}
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) )
( ( unsigned int * ) output_buffer ) [ pixel_index + alpha_channel ] = ( unsigned int ) STBIR__ROUND_INT ( ( ( double ) stbir__saturate ( encode_buffer [ pixel_index + alpha_channel ] ) ) * stbir__max_uint32_as_float ) ;
}
break ;
case STBIR__DECODE ( STBIR_TYPE_FLOAT , STBIR_COLORSPACE_LINEAR ) :
for ( x = 0 ; x < num_pixels ; + + x )
{
int pixel_index = x * channels ;
for ( n = 0 ; n < channels ; n + + )
{
int index = pixel_index + n ;
( ( float * ) output_buffer ) [ index ] = encode_buffer [ index ] ;
}
}
break ;
case STBIR__DECODE ( STBIR_TYPE_FLOAT , STBIR_COLORSPACE_SRGB ) :
for ( x = 0 ; x < num_pixels ; + + x )
{
int pixel_index = x * channels ;
for ( n = 0 ; n < num_nonalpha ; n + + )
{
int index = pixel_index + nonalpha [ n ] ;
( ( float * ) output_buffer ) [ index ] = stbir__linear_to_srgb ( encode_buffer [ index ] ) ;
}
if ( ! ( stbir_info - > flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) )
( ( float * ) output_buffer ) [ pixel_index + alpha_channel ] = encode_buffer [ pixel_index + alpha_channel ] ;
}
break ;
default :
STBIR_ASSERT ( ! " Unknown type/colorspace/channels combination. " ) ;
break ;
}
}
static void stbir__resample_vertical_upsample ( stbir__info * stbir_info , int n )
{
int x , k ;
int output_w = stbir_info - > output_w ;
stbir__contributors * vertical_contributors = stbir_info - > vertical_contributors ;
float * vertical_coefficients = stbir_info - > vertical_coefficients ;
int channels = stbir_info - > channels ;
int alpha_channel = stbir_info - > alpha_channel ;
int type = stbir_info - > type ;
int colorspace = stbir_info - > colorspace ;
int ring_buffer_entries = stbir_info - > ring_buffer_num_entries ;
void * output_data = stbir_info - > output_data ;
float * encode_buffer = stbir_info - > encode_buffer ;
int decode = STBIR__DECODE ( type , colorspace ) ;
int coefficient_width = stbir_info - > vertical_coefficient_width ;
int coefficient_counter ;
int contributor = n ;
float * ring_buffer = stbir_info - > ring_buffer ;
int ring_buffer_begin_index = stbir_info - > ring_buffer_begin_index ;
int ring_buffer_first_scanline = stbir_info - > ring_buffer_first_scanline ;
int ring_buffer_length = stbir_info - > ring_buffer_length_bytes / sizeof ( float ) ;
int n0 , n1 , output_row_start ;
int coefficient_group = coefficient_width * contributor ;
n0 = vertical_contributors [ contributor ] . n0 ;
n1 = vertical_contributors [ contributor ] . n1 ;
output_row_start = n * stbir_info - > output_stride_bytes ;
STBIR_ASSERT ( stbir__use_height_upsampling ( stbir_info ) ) ;
memset ( encode_buffer , 0 , output_w * sizeof ( float ) * channels ) ;
// I tried reblocking this for better cache usage of encode_buffer
// (using x_outer, k, x_inner), but it lost speed. -- stb
coefficient_counter = 0 ;
switch ( channels ) {
case 1 :
for ( k = n0 ; k < = n1 ; k + + )
{
int coefficient_index = coefficient_counter + + ;
float * ring_buffer_entry = stbir__get_ring_buffer_scanline ( k , ring_buffer , ring_buffer_begin_index , ring_buffer_first_scanline , ring_buffer_entries , ring_buffer_length ) ;
float coefficient = vertical_coefficients [ coefficient_group + coefficient_index ] ;
for ( x = 0 ; x < output_w ; + + x )
{
int in_pixel_index = x * 1 ;
encode_buffer [ in_pixel_index + 0 ] + = ring_buffer_entry [ in_pixel_index + 0 ] * coefficient ;
}
}
break ;
case 2 :
for ( k = n0 ; k < = n1 ; k + + )
{
int coefficient_index = coefficient_counter + + ;
float * ring_buffer_entry = stbir__get_ring_buffer_scanline ( k , ring_buffer , ring_buffer_begin_index , ring_buffer_first_scanline , ring_buffer_entries , ring_buffer_length ) ;
float coefficient = vertical_coefficients [ coefficient_group + coefficient_index ] ;
for ( x = 0 ; x < output_w ; + + x )
{
int in_pixel_index = x * 2 ;
encode_buffer [ in_pixel_index + 0 ] + = ring_buffer_entry [ in_pixel_index + 0 ] * coefficient ;
encode_buffer [ in_pixel_index + 1 ] + = ring_buffer_entry [ in_pixel_index + 1 ] * coefficient ;
}
}
break ;
case 3 :
for ( k = n0 ; k < = n1 ; k + + )
{
int coefficient_index = coefficient_counter + + ;
float * ring_buffer_entry = stbir__get_ring_buffer_scanline ( k , ring_buffer , ring_buffer_begin_index , ring_buffer_first_scanline , ring_buffer_entries , ring_buffer_length ) ;
float coefficient = vertical_coefficients [ coefficient_group + coefficient_index ] ;
for ( x = 0 ; x < output_w ; + + x )
{
int in_pixel_index = x * 3 ;
encode_buffer [ in_pixel_index + 0 ] + = ring_buffer_entry [ in_pixel_index + 0 ] * coefficient ;
encode_buffer [ in_pixel_index + 1 ] + = ring_buffer_entry [ in_pixel_index + 1 ] * coefficient ;
encode_buffer [ in_pixel_index + 2 ] + = ring_buffer_entry [ in_pixel_index + 2 ] * coefficient ;
}
}
break ;
case 4 :
for ( k = n0 ; k < = n1 ; k + + )
{
int coefficient_index = coefficient_counter + + ;
float * ring_buffer_entry = stbir__get_ring_buffer_scanline ( k , ring_buffer , ring_buffer_begin_index , ring_buffer_first_scanline , ring_buffer_entries , ring_buffer_length ) ;
float coefficient = vertical_coefficients [ coefficient_group + coefficient_index ] ;
for ( x = 0 ; x < output_w ; + + x )
{
int in_pixel_index = x * 4 ;
encode_buffer [ in_pixel_index + 0 ] + = ring_buffer_entry [ in_pixel_index + 0 ] * coefficient ;
encode_buffer [ in_pixel_index + 1 ] + = ring_buffer_entry [ in_pixel_index + 1 ] * coefficient ;
encode_buffer [ in_pixel_index + 2 ] + = ring_buffer_entry [ in_pixel_index + 2 ] * coefficient ;
encode_buffer [ in_pixel_index + 3 ] + = ring_buffer_entry [ in_pixel_index + 3 ] * coefficient ;
}
}
break ;
default :
for ( k = n0 ; k < = n1 ; k + + )
{
int coefficient_index = coefficient_counter + + ;
float * ring_buffer_entry = stbir__get_ring_buffer_scanline ( k , ring_buffer , ring_buffer_begin_index , ring_buffer_first_scanline , ring_buffer_entries , ring_buffer_length ) ;
float coefficient = vertical_coefficients [ coefficient_group + coefficient_index ] ;
for ( x = 0 ; x < output_w ; + + x )
{
int in_pixel_index = x * channels ;
int c ;
for ( c = 0 ; c < channels ; c + + )
encode_buffer [ in_pixel_index + c ] + = ring_buffer_entry [ in_pixel_index + c ] * coefficient ;
}
}
break ;
}
stbir__encode_scanline ( stbir_info , output_w , ( char * ) output_data + output_row_start , encode_buffer , channels , alpha_channel , decode ) ;
}
static void stbir__resample_vertical_downsample ( stbir__info * stbir_info , int n )
{
int x , k ;
int output_w = stbir_info - > output_w ;
stbir__contributors * vertical_contributors = stbir_info - > vertical_contributors ;
float * vertical_coefficients = stbir_info - > vertical_coefficients ;
int channels = stbir_info - > channels ;
int ring_buffer_entries = stbir_info - > ring_buffer_num_entries ;
float * horizontal_buffer = stbir_info - > horizontal_buffer ;
int coefficient_width = stbir_info - > vertical_coefficient_width ;
int contributor = n + stbir_info - > vertical_filter_pixel_margin ;
float * ring_buffer = stbir_info - > ring_buffer ;
int ring_buffer_begin_index = stbir_info - > ring_buffer_begin_index ;
int ring_buffer_first_scanline = stbir_info - > ring_buffer_first_scanline ;
int ring_buffer_length = stbir_info - > ring_buffer_length_bytes / sizeof ( float ) ;
int n0 , n1 ;
n0 = vertical_contributors [ contributor ] . n0 ;
n1 = vertical_contributors [ contributor ] . n1 ;
STBIR_ASSERT ( ! stbir__use_height_upsampling ( stbir_info ) ) ;
for ( k = n0 ; k < = n1 ; k + + )
{
int coefficient_index = k - n0 ;
int coefficient_group = coefficient_width * contributor ;
float coefficient = vertical_coefficients [ coefficient_group + coefficient_index ] ;
float * ring_buffer_entry = stbir__get_ring_buffer_scanline ( k , ring_buffer , ring_buffer_begin_index , ring_buffer_first_scanline , ring_buffer_entries , ring_buffer_length ) ;
switch ( channels ) {
case 1 :
for ( x = 0 ; x < output_w ; x + + )
{
int in_pixel_index = x * 1 ;
ring_buffer_entry [ in_pixel_index + 0 ] + = horizontal_buffer [ in_pixel_index + 0 ] * coefficient ;
}
break ;
case 2 :
for ( x = 0 ; x < output_w ; x + + )
{
int in_pixel_index = x * 2 ;
ring_buffer_entry [ in_pixel_index + 0 ] + = horizontal_buffer [ in_pixel_index + 0 ] * coefficient ;
ring_buffer_entry [ in_pixel_index + 1 ] + = horizontal_buffer [ in_pixel_index + 1 ] * coefficient ;
}
break ;
case 3 :
for ( x = 0 ; x < output_w ; x + + )
{
int in_pixel_index = x * 3 ;
ring_buffer_entry [ in_pixel_index + 0 ] + = horizontal_buffer [ in_pixel_index + 0 ] * coefficient ;
ring_buffer_entry [ in_pixel_index + 1 ] + = horizontal_buffer [ in_pixel_index + 1 ] * coefficient ;
ring_buffer_entry [ in_pixel_index + 2 ] + = horizontal_buffer [ in_pixel_index + 2 ] * coefficient ;
}
break ;
case 4 :
for ( x = 0 ; x < output_w ; x + + )
{
int in_pixel_index = x * 4 ;
ring_buffer_entry [ in_pixel_index + 0 ] + = horizontal_buffer [ in_pixel_index + 0 ] * coefficient ;
ring_buffer_entry [ in_pixel_index + 1 ] + = horizontal_buffer [ in_pixel_index + 1 ] * coefficient ;
ring_buffer_entry [ in_pixel_index + 2 ] + = horizontal_buffer [ in_pixel_index + 2 ] * coefficient ;
ring_buffer_entry [ in_pixel_index + 3 ] + = horizontal_buffer [ in_pixel_index + 3 ] * coefficient ;
}
break ;
default :
for ( x = 0 ; x < output_w ; x + + )
{
int in_pixel_index = x * channels ;
int c ;
for ( c = 0 ; c < channels ; c + + )
ring_buffer_entry [ in_pixel_index + c ] + = horizontal_buffer [ in_pixel_index + c ] * coefficient ;
}
break ;
}
}
}
static void stbir__buffer_loop_upsample ( stbir__info * stbir_info )
{
int y ;
float scale_ratio = stbir_info - > vertical_scale ;
float out_scanlines_radius = stbir__filter_info_table [ stbir_info - > vertical_filter ] . support ( 1 / scale_ratio ) * scale_ratio ;
STBIR_ASSERT ( stbir__use_height_upsampling ( stbir_info ) ) ;
for ( y = 0 ; y < stbir_info - > output_h ; y + + )
{
float in_center_of_out = 0 ; // Center of the current out scanline in the in scanline space
int in_first_scanline = 0 , in_last_scanline = 0 ;
stbir__calculate_sample_range_upsample ( y , out_scanlines_radius , scale_ratio , stbir_info - > vertical_shift , & in_first_scanline , & in_last_scanline , & in_center_of_out ) ;
STBIR_ASSERT ( in_last_scanline - in_first_scanline + 1 < = stbir_info - > ring_buffer_num_entries ) ;
if ( stbir_info - > ring_buffer_begin_index > = 0 )
{
// Get rid of whatever we don't need anymore.
while ( in_first_scanline > stbir_info - > ring_buffer_first_scanline )
{
if ( stbir_info - > ring_buffer_first_scanline = = stbir_info - > ring_buffer_last_scanline )
{
// We just popped the last scanline off the ring buffer.
// Reset it to the empty state.
stbir_info - > ring_buffer_begin_index = - 1 ;
stbir_info - > ring_buffer_first_scanline = 0 ;
stbir_info - > ring_buffer_last_scanline = 0 ;
break ;
}
else
{
stbir_info - > ring_buffer_first_scanline + + ;
stbir_info - > ring_buffer_begin_index = ( stbir_info - > ring_buffer_begin_index + 1 ) % stbir_info - > ring_buffer_num_entries ;
}
}
}
// Load in new ones.
if ( stbir_info - > ring_buffer_begin_index < 0 )
stbir__decode_and_resample_upsample ( stbir_info , in_first_scanline ) ;
while ( in_last_scanline > stbir_info - > ring_buffer_last_scanline )
stbir__decode_and_resample_upsample ( stbir_info , stbir_info - > ring_buffer_last_scanline + 1 ) ;
// Now all buffers should be ready to write a row of vertical sampling.
stbir__resample_vertical_upsample ( stbir_info , y ) ;
STBIR_PROGRESS_REPORT ( ( float ) y / stbir_info - > output_h ) ;
}
}
static void stbir__empty_ring_buffer ( stbir__info * stbir_info , int first_necessary_scanline )
{
int output_stride_bytes = stbir_info - > output_stride_bytes ;
int channels = stbir_info - > channels ;
int alpha_channel = stbir_info - > alpha_channel ;
int type = stbir_info - > type ;
int colorspace = stbir_info - > colorspace ;
int output_w = stbir_info - > output_w ;
void * output_data = stbir_info - > output_data ;
int decode = STBIR__DECODE ( type , colorspace ) ;
float * ring_buffer = stbir_info - > ring_buffer ;
int ring_buffer_length = stbir_info - > ring_buffer_length_bytes / sizeof ( float ) ;
if ( stbir_info - > ring_buffer_begin_index > = 0 )
{
// Get rid of whatever we don't need anymore.
while ( first_necessary_scanline > stbir_info - > ring_buffer_first_scanline )
{
if ( stbir_info - > ring_buffer_first_scanline > = 0 & & stbir_info - > ring_buffer_first_scanline < stbir_info - > output_h )
{
int output_row_start = stbir_info - > ring_buffer_first_scanline * output_stride_bytes ;
float * ring_buffer_entry = stbir__get_ring_buffer_entry ( ring_buffer , stbir_info - > ring_buffer_begin_index , ring_buffer_length ) ;
stbir__encode_scanline ( stbir_info , output_w , ( char * ) output_data + output_row_start , ring_buffer_entry , channels , alpha_channel , decode ) ;
STBIR_PROGRESS_REPORT ( ( float ) stbir_info - > ring_buffer_first_scanline / stbir_info - > output_h ) ;
}
if ( stbir_info - > ring_buffer_first_scanline = = stbir_info - > ring_buffer_last_scanline )
{
// We just popped the last scanline off the ring buffer.
// Reset it to the empty state.
stbir_info - > ring_buffer_begin_index = - 1 ;
stbir_info - > ring_buffer_first_scanline = 0 ;
stbir_info - > ring_buffer_last_scanline = 0 ;
break ;
}
else
{
stbir_info - > ring_buffer_first_scanline + + ;
stbir_info - > ring_buffer_begin_index = ( stbir_info - > ring_buffer_begin_index + 1 ) % stbir_info - > ring_buffer_num_entries ;
}
}
}
}
static void stbir__buffer_loop_downsample ( stbir__info * stbir_info )
{
int y ;
float scale_ratio = stbir_info - > vertical_scale ;
int output_h = stbir_info - > output_h ;
float in_pixels_radius = stbir__filter_info_table [ stbir_info - > vertical_filter ] . support ( scale_ratio ) / scale_ratio ;
int pixel_margin = stbir_info - > vertical_filter_pixel_margin ;
int max_y = stbir_info - > input_h + pixel_margin ;
STBIR_ASSERT ( ! stbir__use_height_upsampling ( stbir_info ) ) ;
for ( y = - pixel_margin ; y < max_y ; y + + )
{
float out_center_of_in ; // Center of the current out scanline in the in scanline space
int out_first_scanline , out_last_scanline ;
stbir__calculate_sample_range_downsample ( y , in_pixels_radius , scale_ratio , stbir_info - > vertical_shift , & out_first_scanline , & out_last_scanline , & out_center_of_in ) ;
STBIR_ASSERT ( out_last_scanline - out_first_scanline + 1 < = stbir_info - > ring_buffer_num_entries ) ;
if ( out_last_scanline < 0 | | out_first_scanline > = output_h )
continue ;
stbir__empty_ring_buffer ( stbir_info , out_first_scanline ) ;
stbir__decode_and_resample_downsample ( stbir_info , y ) ;
// Load in new ones.
if ( stbir_info - > ring_buffer_begin_index < 0 )
stbir__add_empty_ring_buffer_entry ( stbir_info , out_first_scanline ) ;
while ( out_last_scanline > stbir_info - > ring_buffer_last_scanline )
stbir__add_empty_ring_buffer_entry ( stbir_info , stbir_info - > ring_buffer_last_scanline + 1 ) ;
// Now the horizontal buffer is ready to write to all ring buffer rows.
stbir__resample_vertical_downsample ( stbir_info , y ) ;
}
stbir__empty_ring_buffer ( stbir_info , stbir_info - > output_h ) ;
}
static void stbir__setup ( stbir__info * info , int input_w , int input_h , int output_w , int output_h , int channels )
{
info - > input_w = input_w ;
info - > input_h = input_h ;
info - > output_w = output_w ;
info - > output_h = output_h ;
info - > channels = channels ;
}
static void stbir__calculate_transform ( stbir__info * info , float s0 , float t0 , float s1 , float t1 , float * transform )
{
info - > s0 = s0 ;
info - > t0 = t0 ;
info - > s1 = s1 ;
info - > t1 = t1 ;
if ( transform )
{
info - > horizontal_scale = transform [ 0 ] ;
info - > vertical_scale = transform [ 1 ] ;
info - > horizontal_shift = transform [ 2 ] ;
info - > vertical_shift = transform [ 3 ] ;
}
else
{
info - > horizontal_scale = ( ( float ) info - > output_w / info - > input_w ) / ( s1 - s0 ) ;
info - > vertical_scale = ( ( float ) info - > output_h / info - > input_h ) / ( t1 - t0 ) ;
info - > horizontal_shift = s0 * info - > output_w / ( s1 - s0 ) ;
info - > vertical_shift = t0 * info - > output_h / ( t1 - t0 ) ;
}
}
static void stbir__choose_filter ( stbir__info * info , stbir_filter h_filter , stbir_filter v_filter )
{
if ( h_filter = = 0 )
h_filter = stbir__use_upsampling ( info - > horizontal_scale ) ? STBIR_DEFAULT_FILTER_UPSAMPLE : STBIR_DEFAULT_FILTER_DOWNSAMPLE ;
if ( v_filter = = 0 )
v_filter = stbir__use_upsampling ( info - > vertical_scale ) ? STBIR_DEFAULT_FILTER_UPSAMPLE : STBIR_DEFAULT_FILTER_DOWNSAMPLE ;
info - > horizontal_filter = h_filter ;
info - > vertical_filter = v_filter ;
}
static stbir_uint32 stbir__calculate_memory ( stbir__info * info )
{
int pixel_margin = stbir__get_filter_pixel_margin ( info - > horizontal_filter , info - > horizontal_scale ) ;
int filter_height = stbir__get_filter_pixel_width ( info - > vertical_filter , info - > vertical_scale ) ;
info - > horizontal_num_contributors = stbir__get_contributors ( info - > horizontal_scale , info - > horizontal_filter , info - > input_w , info - > output_w ) ;
info - > vertical_num_contributors = stbir__get_contributors ( info - > vertical_scale , info - > vertical_filter , info - > input_h , info - > output_h ) ;
// One extra entry because floating point precision problems sometimes cause an extra to be necessary.
info - > ring_buffer_num_entries = filter_height + 1 ;
info - > horizontal_contributors_size = info - > horizontal_num_contributors * sizeof ( stbir__contributors ) ;
info - > horizontal_coefficients_size = stbir__get_total_horizontal_coefficients ( info ) * sizeof ( float ) ;
info - > vertical_contributors_size = info - > vertical_num_contributors * sizeof ( stbir__contributors ) ;
info - > vertical_coefficients_size = stbir__get_total_vertical_coefficients ( info ) * sizeof ( float ) ;
info - > decode_buffer_size = ( info - > input_w + pixel_margin * 2 ) * info - > channels * sizeof ( float ) ;
info - > horizontal_buffer_size = info - > output_w * info - > channels * sizeof ( float ) ;
info - > ring_buffer_size = info - > output_w * info - > channels * info - > ring_buffer_num_entries * sizeof ( float ) ;
info - > encode_buffer_size = info - > output_w * info - > channels * sizeof ( float ) ;
STBIR_ASSERT ( info - > horizontal_filter ! = 0 ) ;
STBIR_ASSERT ( info - > horizontal_filter < STBIR__ARRAY_SIZE ( stbir__filter_info_table ) ) ; // this now happens too late
STBIR_ASSERT ( info - > vertical_filter ! = 0 ) ;
STBIR_ASSERT ( info - > vertical_filter < STBIR__ARRAY_SIZE ( stbir__filter_info_table ) ) ; // this now happens too late
if ( stbir__use_height_upsampling ( info ) )
// The horizontal buffer is for when we're downsampling the height and we
// can't output the result of sampling the decode buffer directly into the
// ring buffers.
info - > horizontal_buffer_size = 0 ;
else
// The encode buffer is to retain precision in the height upsampling method
// and isn't used when height downsampling.
info - > encode_buffer_size = 0 ;
return info - > horizontal_contributors_size + info - > horizontal_coefficients_size
+ info - > vertical_contributors_size + info - > vertical_coefficients_size
+ info - > decode_buffer_size + info - > horizontal_buffer_size
+ info - > ring_buffer_size + info - > encode_buffer_size ;
}
static int stbir__resize_allocated ( stbir__info * info ,
const void * input_data , int input_stride_in_bytes ,
void * output_data , int output_stride_in_bytes ,
int alpha_channel , stbir_uint32 flags , stbir_datatype type ,
stbir_edge edge_horizontal , stbir_edge edge_vertical , stbir_colorspace colorspace ,
void * tempmem , size_t tempmem_size_in_bytes )
{
size_t memory_required = stbir__calculate_memory ( info ) ;
int width_stride_input = input_stride_in_bytes ? input_stride_in_bytes : info - > channels * info - > input_w * stbir__type_size [ type ] ;
int width_stride_output = output_stride_in_bytes ? output_stride_in_bytes : info - > channels * info - > output_w * stbir__type_size [ type ] ;
# ifdef STBIR_DEBUG_OVERWRITE_TEST
# define OVERWRITE_ARRAY_SIZE 8
unsigned char overwrite_output_before_pre [ OVERWRITE_ARRAY_SIZE ] ;
unsigned char overwrite_tempmem_before_pre [ OVERWRITE_ARRAY_SIZE ] ;
unsigned char overwrite_output_after_pre [ OVERWRITE_ARRAY_SIZE ] ;
unsigned char overwrite_tempmem_after_pre [ OVERWRITE_ARRAY_SIZE ] ;
size_t begin_forbidden = width_stride_output * ( info - > output_h - 1 ) + info - > output_w * info - > channels * stbir__type_size [ type ] ;
memcpy ( overwrite_output_before_pre , & ( ( unsigned char * ) output_data ) [ - OVERWRITE_ARRAY_SIZE ] , OVERWRITE_ARRAY_SIZE ) ;
memcpy ( overwrite_output_after_pre , & ( ( unsigned char * ) output_data ) [ begin_forbidden ] , OVERWRITE_ARRAY_SIZE ) ;
memcpy ( overwrite_tempmem_before_pre , & ( ( unsigned char * ) tempmem ) [ - OVERWRITE_ARRAY_SIZE ] , OVERWRITE_ARRAY_SIZE ) ;
memcpy ( overwrite_tempmem_after_pre , & ( ( unsigned char * ) tempmem ) [ tempmem_size_in_bytes ] , OVERWRITE_ARRAY_SIZE ) ;
# endif
STBIR_ASSERT ( info - > channels > = 0 ) ;
STBIR_ASSERT ( info - > channels < = STBIR_MAX_CHANNELS ) ;
if ( info - > channels < 0 | | info - > channels > STBIR_MAX_CHANNELS )
return 0 ;
STBIR_ASSERT ( info - > horizontal_filter < STBIR__ARRAY_SIZE ( stbir__filter_info_table ) ) ;
STBIR_ASSERT ( info - > vertical_filter < STBIR__ARRAY_SIZE ( stbir__filter_info_table ) ) ;
if ( info - > horizontal_filter > = STBIR__ARRAY_SIZE ( stbir__filter_info_table ) )
return 0 ;
if ( info - > vertical_filter > = STBIR__ARRAY_SIZE ( stbir__filter_info_table ) )
return 0 ;
if ( alpha_channel < 0 )
flags | = STBIR_FLAG_ALPHA_USES_COLORSPACE | STBIR_FLAG_ALPHA_PREMULTIPLIED ;
if ( ! ( flags & STBIR_FLAG_ALPHA_USES_COLORSPACE ) | | ! ( flags & STBIR_FLAG_ALPHA_PREMULTIPLIED ) ) {
STBIR_ASSERT ( alpha_channel > = 0 & & alpha_channel < info - > channels ) ;
}
if ( alpha_channel > = info - > channels )
return 0 ;
STBIR_ASSERT ( tempmem ) ;
if ( ! tempmem )
return 0 ;
STBIR_ASSERT ( tempmem_size_in_bytes > = memory_required ) ;
if ( tempmem_size_in_bytes < memory_required )
return 0 ;
memset ( tempmem , 0 , tempmem_size_in_bytes ) ;
info - > input_data = input_data ;
info - > input_stride_bytes = width_stride_input ;
info - > output_data = output_data ;
info - > output_stride_bytes = width_stride_output ;
info - > alpha_channel = alpha_channel ;
info - > flags = flags ;
info - > type = type ;
info - > edge_horizontal = edge_horizontal ;
info - > edge_vertical = edge_vertical ;
info - > colorspace = colorspace ;
info - > horizontal_coefficient_width = stbir__get_coefficient_width ( info - > horizontal_filter , info - > horizontal_scale ) ;
info - > vertical_coefficient_width = stbir__get_coefficient_width ( info - > vertical_filter , info - > vertical_scale ) ;
info - > horizontal_filter_pixel_width = stbir__get_filter_pixel_width ( info - > horizontal_filter , info - > horizontal_scale ) ;
info - > vertical_filter_pixel_width = stbir__get_filter_pixel_width ( info - > vertical_filter , info - > vertical_scale ) ;
info - > horizontal_filter_pixel_margin = stbir__get_filter_pixel_margin ( info - > horizontal_filter , info - > horizontal_scale ) ;
info - > vertical_filter_pixel_margin = stbir__get_filter_pixel_margin ( info - > vertical_filter , info - > vertical_scale ) ;
info - > ring_buffer_length_bytes = info - > output_w * info - > channels * sizeof ( float ) ;
info - > decode_buffer_pixels = info - > input_w + info - > horizontal_filter_pixel_margin * 2 ;
# define STBIR__NEXT_MEMPTR(current, newtype) (newtype*)(((unsigned char*)current) + current##_size)
info - > horizontal_contributors = ( stbir__contributors * ) tempmem ;
info - > horizontal_coefficients = STBIR__NEXT_MEMPTR ( info - > horizontal_contributors , float ) ;
info - > vertical_contributors = STBIR__NEXT_MEMPTR ( info - > horizontal_coefficients , stbir__contributors ) ;
info - > vertical_coefficients = STBIR__NEXT_MEMPTR ( info - > vertical_contributors , float ) ;
info - > decode_buffer = STBIR__NEXT_MEMPTR ( info - > vertical_coefficients , float ) ;
if ( stbir__use_height_upsampling ( info ) )
{
info - > horizontal_buffer = NULL ;
info - > ring_buffer = STBIR__NEXT_MEMPTR ( info - > decode_buffer , float ) ;
info - > encode_buffer = STBIR__NEXT_MEMPTR ( info - > ring_buffer , float ) ;
STBIR_ASSERT ( ( size_t ) STBIR__NEXT_MEMPTR ( info - > encode_buffer , unsigned char ) = = ( size_t ) tempmem + tempmem_size_in_bytes ) ;
}
else
{
info - > horizontal_buffer = STBIR__NEXT_MEMPTR ( info - > decode_buffer , float ) ;
info - > ring_buffer = STBIR__NEXT_MEMPTR ( info - > horizontal_buffer , float ) ;
info - > encode_buffer = NULL ;
STBIR_ASSERT ( ( size_t ) STBIR__NEXT_MEMPTR ( info - > ring_buffer , unsigned char ) = = ( size_t ) tempmem + tempmem_size_in_bytes ) ;
}
# undef STBIR__NEXT_MEMPTR
// This signals that the ring buffer is empty
info - > ring_buffer_begin_index = - 1 ;
stbir__calculate_filters ( info - > horizontal_contributors , info - > horizontal_coefficients , info - > horizontal_filter , info - > horizontal_scale , info - > horizontal_shift , info - > input_w , info - > output_w ) ;
stbir__calculate_filters ( info - > vertical_contributors , info - > vertical_coefficients , info - > vertical_filter , info - > vertical_scale , info - > vertical_shift , info - > input_h , info - > output_h ) ;
STBIR_PROGRESS_REPORT ( 0 ) ;
if ( stbir__use_height_upsampling ( info ) )
stbir__buffer_loop_upsample ( info ) ;
else
stbir__buffer_loop_downsample ( info ) ;
STBIR_PROGRESS_REPORT ( 1 ) ;
# ifdef STBIR_DEBUG_OVERWRITE_TEST
STBIR_ASSERT ( memcmp ( overwrite_output_before_pre , & ( ( unsigned char * ) output_data ) [ - OVERWRITE_ARRAY_SIZE ] , OVERWRITE_ARRAY_SIZE ) = = 0 ) ;
STBIR_ASSERT ( memcmp ( overwrite_output_after_pre , & ( ( unsigned char * ) output_data ) [ begin_forbidden ] , OVERWRITE_ARRAY_SIZE ) = = 0 ) ;
STBIR_ASSERT ( memcmp ( overwrite_tempmem_before_pre , & ( ( unsigned char * ) tempmem ) [ - OVERWRITE_ARRAY_SIZE ] , OVERWRITE_ARRAY_SIZE ) = = 0 ) ;
STBIR_ASSERT ( memcmp ( overwrite_tempmem_after_pre , & ( ( unsigned char * ) tempmem ) [ tempmem_size_in_bytes ] , OVERWRITE_ARRAY_SIZE ) = = 0 ) ;
# endif
return 1 ;
}
static int stbir__resize_arbitrary (
void * alloc_context ,
const void * input_data , int input_w , int input_h , int input_stride_in_bytes ,
void * output_data , int output_w , int output_h , int output_stride_in_bytes ,
float s0 , float t0 , float s1 , float t1 , float * transform ,
int channels , int alpha_channel , stbir_uint32 flags , stbir_datatype type ,
stbir_filter h_filter , stbir_filter v_filter ,
stbir_edge edge_horizontal , stbir_edge edge_vertical , stbir_colorspace colorspace )
{
stbir__info info ;
int result ;
size_t memory_required ;
void * extra_memory ;
stbir__setup ( & info , input_w , input_h , output_w , output_h , channels ) ;
stbir__calculate_transform ( & info , s0 , t0 , s1 , t1 , transform ) ;
stbir__choose_filter ( & info , h_filter , v_filter ) ;
memory_required = stbir__calculate_memory ( & info ) ;
extra_memory = STBIR_MALLOC ( memory_required , alloc_context ) ;
if ( ! extra_memory )
return 0 ;
result = stbir__resize_allocated ( & info , input_data , input_stride_in_bytes ,
output_data , output_stride_in_bytes ,
alpha_channel , flags , type ,
edge_horizontal , edge_vertical ,
colorspace , extra_memory , memory_required ) ;
STBIR_FREE ( extra_memory , alloc_context ) ;
return result ;
}
STBIRDEF int stbir_resize_uint8 ( const unsigned char * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
unsigned char * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels )
{
return stbir__resize_arbitrary ( NULL , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
0 , 0 , 1 , 1 , NULL , num_channels , - 1 , 0 , STBIR_TYPE_UINT8 , STBIR_FILTER_DEFAULT , STBIR_FILTER_DEFAULT ,
STBIR_EDGE_CLAMP , STBIR_EDGE_CLAMP , STBIR_COLORSPACE_LINEAR ) ;
}
STBIRDEF int stbir_resize_float ( const float * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
float * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels )
{
return stbir__resize_arbitrary ( NULL , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
0 , 0 , 1 , 1 , NULL , num_channels , - 1 , 0 , STBIR_TYPE_FLOAT , STBIR_FILTER_DEFAULT , STBIR_FILTER_DEFAULT ,
STBIR_EDGE_CLAMP , STBIR_EDGE_CLAMP , STBIR_COLORSPACE_LINEAR ) ;
}
STBIRDEF int stbir_resize_uint8_srgb ( const unsigned char * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
unsigned char * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags )
{
return stbir__resize_arbitrary ( NULL , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
0 , 0 , 1 , 1 , NULL , num_channels , alpha_channel , flags , STBIR_TYPE_UINT8 , STBIR_FILTER_DEFAULT , STBIR_FILTER_DEFAULT ,
STBIR_EDGE_CLAMP , STBIR_EDGE_CLAMP , STBIR_COLORSPACE_SRGB ) ;
}
STBIRDEF int stbir_resize_uint8_srgb_edgemode ( const unsigned char * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
unsigned char * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_wrap_mode )
{
return stbir__resize_arbitrary ( NULL , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
0 , 0 , 1 , 1 , NULL , num_channels , alpha_channel , flags , STBIR_TYPE_UINT8 , STBIR_FILTER_DEFAULT , STBIR_FILTER_DEFAULT ,
edge_wrap_mode , edge_wrap_mode , STBIR_COLORSPACE_SRGB ) ;
}
STBIRDEF int stbir_resize_uint8_generic ( const unsigned char * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
unsigned char * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_wrap_mode , stbir_filter filter , stbir_colorspace space ,
void * alloc_context )
{
return stbir__resize_arbitrary ( alloc_context , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
0 , 0 , 1 , 1 , NULL , num_channels , alpha_channel , flags , STBIR_TYPE_UINT8 , filter , filter ,
edge_wrap_mode , edge_wrap_mode , space ) ;
}
STBIRDEF int stbir_resize_uint16_generic ( const stbir_uint16 * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
stbir_uint16 * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_wrap_mode , stbir_filter filter , stbir_colorspace space ,
void * alloc_context )
{
return stbir__resize_arbitrary ( alloc_context , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
0 , 0 , 1 , 1 , NULL , num_channels , alpha_channel , flags , STBIR_TYPE_UINT16 , filter , filter ,
edge_wrap_mode , edge_wrap_mode , space ) ;
}
STBIRDEF int stbir_resize_float_generic ( const float * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
float * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_wrap_mode , stbir_filter filter , stbir_colorspace space ,
void * alloc_context )
{
return stbir__resize_arbitrary ( alloc_context , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
0 , 0 , 1 , 1 , NULL , num_channels , alpha_channel , flags , STBIR_TYPE_FLOAT , filter , filter ,
edge_wrap_mode , edge_wrap_mode , space ) ;
}
STBIRDEF int stbir_resize ( const void * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
void * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
stbir_datatype datatype ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_mode_horizontal , stbir_edge edge_mode_vertical ,
stbir_filter filter_horizontal , stbir_filter filter_vertical ,
stbir_colorspace space , void * alloc_context )
{
return stbir__resize_arbitrary ( alloc_context , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
0 , 0 , 1 , 1 , NULL , num_channels , alpha_channel , flags , datatype , filter_horizontal , filter_vertical ,
edge_mode_horizontal , edge_mode_vertical , space ) ;
}
STBIRDEF int stbir_resize_subpixel ( const void * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
void * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
stbir_datatype datatype ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_mode_horizontal , stbir_edge edge_mode_vertical ,
stbir_filter filter_horizontal , stbir_filter filter_vertical ,
stbir_colorspace space , void * alloc_context ,
float x_scale , float y_scale ,
float x_offset , float y_offset )
{
float transform [ 4 ] ;
transform [ 0 ] = x_scale ;
transform [ 1 ] = y_scale ;
transform [ 2 ] = x_offset ;
transform [ 3 ] = y_offset ;
return stbir__resize_arbitrary ( alloc_context , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
0 , 0 , 1 , 1 , transform , num_channels , alpha_channel , flags , datatype , filter_horizontal , filter_vertical ,
edge_mode_horizontal , edge_mode_vertical , space ) ;
}
STBIRDEF int stbir_resize_region ( const void * input_pixels , int input_w , int input_h , int input_stride_in_bytes ,
void * output_pixels , int output_w , int output_h , int output_stride_in_bytes ,
stbir_datatype datatype ,
int num_channels , int alpha_channel , int flags ,
stbir_edge edge_mode_horizontal , stbir_edge edge_mode_vertical ,
stbir_filter filter_horizontal , stbir_filter filter_vertical ,
stbir_colorspace space , void * alloc_context ,
float s0 , float t0 , float s1 , float t1 )
{
return stbir__resize_arbitrary ( alloc_context , input_pixels , input_w , input_h , input_stride_in_bytes ,
output_pixels , output_w , output_h , output_stride_in_bytes ,
s0 , t0 , s1 , t1 , NULL , num_channels , alpha_channel , flags , datatype , filter_horizontal , filter_vertical ,
edge_mode_horizontal , edge_mode_vertical , space ) ;
}
# endif // STB_IMAGE_RESIZE_IMPLEMENTATION
2023-10-02 05:23:24 -04:00
/*
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
This software is available under 2 licenses - - choose whichever you prefer .
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALTERNATIVE A - MIT License
Copyright ( c ) 2017 Sean Barrett
Permission is hereby granted , free of charge , to any person obtaining a copy of
this software and associated documentation files ( the " Software " ) , to deal in
the Software without restriction , including without limitation the rights to
use , copy , modify , merge , publish , distribute , sublicense , and / or sell copies
of the Software , and to permit persons to whom the Software is furnished to do
so , subject to the following conditions :
The above copyright notice and this permission notice shall be included in all
copies or substantial portions of the Software .
THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM , DAMAGES OR OTHER
LIABILITY , WHETHER IN AN ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING FROM ,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE .
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALTERNATIVE B - Public Domain ( www . unlicense . org )
This is free and unencumbered software released into the public domain .
Anyone is free to copy , modify , publish , use , compile , sell , or distribute this
software , either in source code form or as a compiled binary , for any purpose ,
commercial or non - commercial , and by any means .
In jurisdictions that recognize copyright laws , the author or authors of this
software dedicate any and all copyright interest in the software to the public
domain . We make this dedication for the benefit of the public at large and to
the detriment of our heirs and successors . We intend this dedication to be an
overt act of relinquishment in perpetuity of all present and future rights to
this software under copyright law .
THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL THE
AUTHORS BE LIABLE FOR ANY CLAIM , DAMAGES OR OTHER LIABILITY , WHETHER IN AN
ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING FROM , OUT OF OR IN CONNECTION
WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE .
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
*/