@ -1,5 +1,6 @@
/*
/*
* Copyright 2021 Advanced Micro Devices , Inc .
* Copyright 2021 Advanced Micro Devices , Inc .
* Copyright 2020 , 2022 Collabora , Ltd .
*
*
* Permission is hereby granted , free of charge , to any person obtaining
* Permission is hereby granted , free of charge , to any person obtaining
* a copy of this software and associated documentation files ( the
* a copy of this software and associated documentation files ( the
@ -624,3 +625,223 @@ TEST(opaque_pixel_conversion)
buffer_destroy ( buf ) ;
buffer_destroy ( buf ) ;
client_destroy ( client ) ;
client_destroy ( client ) ;
}
}
static struct color_float
convert_to_blending_space ( const struct lcms_pipeline * pip ,
struct color_float cf )
{
/* Blending space is the linearized output space,
* or simply output space without the non - linear encoding
*/
cf = color_float_apply_curve ( pip - > pre_fn , cf ) ;
return color_float_apply_matrix ( & pip - > mat , cf ) ;
}
static void
compare_blend ( const struct lcms_pipeline * pip ,
struct color_float bg ,
struct color_float fg ,
const struct color_float * shot ,
struct rgb_diff_stat * diffstat )
{
struct color_float ref ;
unsigned i ;
/* convert sources to straight alpha */
assert ( bg . a = = 1.0f ) ;
fg = color_float_unpremult ( fg ) ;
bg = convert_to_blending_space ( pip , bg ) ;
fg = convert_to_blending_space ( pip , fg ) ;
/* blend */
for ( i = 0 ; i < COLOR_CHAN_NUM ; i + + )
ref . rgb [ i ] = ( 1.0f - fg . a ) * bg . rgb [ i ] + fg . a * fg . rgb [ i ] ;
/* non-linear encoding for output */
ref = color_float_apply_curve ( pip - > post_fn , ref ) ;
rgb_diff_stat_update ( diffstat , & ref , shot , & fg ) ;
}
/* Alpha blending test pattern parameters */
static const int ALPHA_STEPS = 256 ;
static const int BLOCK_WIDTH = 1 ;
static void *
get_middle_row ( struct buffer * buf )
{
struct image_header ih = image_header_from ( buf - > image ) ;
assert ( ih . width > = BLOCK_WIDTH * ALPHA_STEPS ) ;
assert ( ih . height > = BLOCK_WIDTH ) ;
return image_header_get_row_u32 ( & ih , ( BLOCK_WIDTH - 1 ) / 2 ) ;
}
static bool
check_blend_pattern ( struct buffer * bg_buf ,
struct buffer * fg_buf ,
struct buffer * shot_buf ,
const struct setup_args * arg )
{
FILE * dump = NULL ;
#if 0
/*
* This file can be loaded in Octave for visualization . Find the script
* in tests / visualization / weston_plot_rgb_diff_stat . m and call it with
*
* weston_plot_rgb_diff_stat ( ' output_icc_alpha_blend - f01 - dump . txt ' , 255 , 8 )
*/
dump = fopen_dump_file ( " dump " ) ;
# endif
uint32_t * bg_row = get_middle_row ( bg_buf ) ;
uint32_t * fg_row = get_middle_row ( fg_buf ) ;
uint32_t * shot_row = get_middle_row ( shot_buf ) ;
struct rgb_diff_stat diffstat = { . dump = dump } ;
int x ;
for ( x = 0 ; x < BLOCK_WIDTH * ALPHA_STEPS ; x + + ) {
struct color_float bg = a8r8g8b8_to_float ( bg_row [ x ] ) ;
struct color_float fg = a8r8g8b8_to_float ( fg_row [ x ] ) ;
struct color_float shot = a8r8g8b8_to_float ( shot_row [ x ] ) ;
compare_blend ( arg - > pipeline , bg , fg , & shot , & diffstat ) ;
}
rgb_diff_stat_print ( & diffstat , " Blending " , 8 ) ;
if ( dump )
fclose ( dump ) ;
/* Test success condition: */
return diffstat . two_norm . max < 1.5f / 255.0f ;
}
static uint32_t
premult_color ( uint32_t a , uint32_t r , uint32_t g , uint32_t b )
{
uint32_t c = 0 ;
c | = a < < 24 ;
c | = ( a * r / 255 ) < < 16 ;
c | = ( a * g / 255 ) < < 8 ;
c | = a * b / 255 ;
return c ;
}
static void
fill_alpha_pattern ( struct buffer * buf )
{
struct image_header ih = image_header_from ( buf - > image ) ;
int y ;
assert ( ih . pixman_format = = PIXMAN_a8r8g8b8 ) ;
assert ( ih . width = = BLOCK_WIDTH * ALPHA_STEPS ) ;
for ( y = 0 ; y < ih . height ; y + + ) {
uint32_t * row = image_header_get_row_u32 ( & ih , y ) ;
uint32_t step ;
for ( step = 0 ; step < ( uint32_t ) ALPHA_STEPS ; step + + ) {
uint32_t alpha = step * 255 / ( ALPHA_STEPS - 1 ) ;
uint32_t color ;
int i ;
color = premult_color ( alpha , 0 , 255 - alpha , 255 ) ;
for ( i = 0 ; i < BLOCK_WIDTH ; i + + )
* row + + = color ;
}
}
}
/*
* Test that alpha blending is correct when an output ICC profile is installed .
*
* The background is a constant color . On top of that , there is an
* alpha - blended gradient with ramps in both alpha and color . Sub - surface
* ensures the correct positioning and stacking .
*
* The gradient consists of ALPHA_STEPS number of blocks . Block size is
* BLOCK_WIDTH x BLOCK_WIDTH and a block has a uniform color .
*
* In the blending result over x axis :
* - red goes from 1.0 to 0.0 , monotonic
* - green is not monotonic
* - blue goes from 0.0 to 1.0 , monotonic
*
* The test has sRGB encoded input pixels ( non - linear ) . These are converted to
* linear light ( optical ) values in output color space , blended , and converted
* to non - linear ( electrical ) values according to the output ICC profile .
*
* Specifically , this test exercises the linearization of output ICC profiles ,
* retrieve_eotf_and_output_inv_eotf ( ) .
*/
TEST ( output_icc_alpha_blend )
{
const int width = BLOCK_WIDTH * ALPHA_STEPS ;
const int height = BLOCK_WIDTH ;
const pixman_color_t background_color = {
. red = 0xffff ,
. green = 0x8080 ,
. blue = 0x0000 ,
. alpha = 0xffff
} ;
int seq_no = get_test_fixture_index ( ) ;
const struct setup_args * arg = & my_setup_args [ seq_no ] ;
struct client * client ;
struct buffer * bg ;
struct buffer * fg ;
struct wl_subcompositor * subco ;
struct wl_surface * surf ;
struct wl_subsurface * sub ;
struct buffer * shot ;
bool match ;
client = create_client ( ) ;
subco = bind_to_singleton_global ( client , & wl_subcompositor_interface , 1 ) ;
/* background window content */
bg = create_shm_buffer_a8r8g8b8 ( client , width , height ) ;
fill_image_with_color ( bg - > image , & background_color ) ;
/* background window, main surface */
client - > surface = create_test_surface ( client ) ;
client - > surface - > width = width ;
client - > surface - > height = height ;
client - > surface - > buffer = bg ; /* pass ownership */
surface_set_opaque_rect ( client - > surface ,
& ( struct rectangle ) { 0 , 0 , width , height } ) ;
/* foreground blended content */
fg = create_shm_buffer_a8r8g8b8 ( client , width , height ) ;
fill_alpha_pattern ( fg ) ;
/* foreground window, sub-surface */
surf = wl_compositor_create_surface ( client - > wl_compositor ) ;
sub = wl_subcompositor_get_subsurface ( subco , surf , client - > surface - > wl_surface ) ;
/* sub-surface defaults to position 0, 0, top-most, synchronized */
wl_surface_attach ( surf , fg - > proxy , 0 , 0 ) ;
wl_surface_damage ( surf , 0 , 0 , width , height ) ;
wl_surface_commit ( surf ) ;
/* attach, damage, commit background window */
move_client ( client , 0 , 0 ) ;
shot = capture_screenshot_of_output ( client ) ;
assert ( shot ) ;
match = verify_image ( shot , " output_icc_alpha_blend " , arg - > ref_image_index ,
NULL , seq_no ) ;
assert ( check_blend_pattern ( bg , fg , shot , arg ) ) ;
assert ( match ) ;
buffer_destroy ( shot ) ;
wl_subsurface_destroy ( sub ) ;
wl_surface_destroy ( surf ) ;
buffer_destroy ( fg ) ;
wl_subcompositor_destroy ( subco ) ;
client_destroy ( client ) ; /* destroys bg */
}