@ -861,74 +861,441 @@ weston_surface_attach(struct wl_surface *surface, struct wl_buffer *buffer)
}
}
# define max(a, b) (((a) > (b)) ? (a) : (b))
# define min(a, b) (((a) > (b)) ? (b) : (a))
# define clip(x, a, b) min(max(x, a), b)
# define sign(x) ((x) >= 0)
static int
calculate_edges ( struct weston_surface * es , pixman_box32_t * rect ,
pixman_box32_t * surf_rect , GLfloat * ex , GLfloat * ey )
{
int i , n = 0 ;
GLfloat min_x , max_x , min_y , max_y ;
GLfloat x [ 4 ] = {
surf_rect - > x1 , surf_rect - > x2 , surf_rect - > x2 , surf_rect - > x1 ,
} ;
GLfloat y [ 4 ] = {
surf_rect - > y1 , surf_rect - > y1 , surf_rect - > y2 , surf_rect - > y2 ,
} ;
GLfloat cx1 = rect - > x1 ;
GLfloat cx2 = rect - > x2 ;
GLfloat cy1 = rect - > y1 ;
GLfloat cy2 = rect - > y2 ;
GLfloat dist_squared ( GLfloat x1 , GLfloat y1 , GLfloat x2 , GLfloat y2 )
{
GLfloat dx = ( x1 - x2 ) ;
GLfloat dy = ( y1 - y2 ) ;
return dx * dx + dy * dy ;
}
void append_vertex ( GLfloat x , GLfloat y )
{
/* don't emit duplicate vertices: */
if ( ( n > 0 ) & & ( ex [ n - 1 ] = = x ) & & ( ey [ n - 1 ] = = y ) )
return ;
ex [ n ] = x ;
ey [ n ] = y ;
n + + ;
}
/* transform surface to screen space: */
for ( i = 0 ; i < 4 ; i + + )
weston_surface_to_global_float ( es , x [ i ] , y [ i ] , & x [ i ] , & y [ i ] ) ;
/* find bounding box: */
min_x = max_x = x [ 0 ] ;
min_y = max_y = y [ 0 ] ;
for ( i = 1 ; i < 4 ; i + + ) {
min_x = min ( min_x , x [ i ] ) ;
max_x = max ( max_x , x [ i ] ) ;
min_y = min ( min_y , y [ i ] ) ;
max_y = max ( max_y , y [ i ] ) ;
}
/* First, simple bounding box check to discard early transformed
* surface rects that do not intersect with the clip region :
*/
if ( ( min_x > cx2 ) | | ( max_x < cx1 ) | |
( min_y > cy2 ) | | ( max_y < cy1 ) )
return 0 ;
/* Simple case, bounding box edges are parallel to surface edges,
* there will be only four edges . We just need to clip the surface
* vertices to the clip rect bounds :
*/
if ( ! es - > transform . enabled ) {
for ( i = 0 ; i < 4 ; i + + ) {
ex [ n ] = clip ( x [ i ] , cx1 , cx2 ) ;
ey [ n ] = clip ( y [ i ] , cy1 , cy2 ) ;
n + + ;
}
return 4 ;
}
/* Hard case, transformation applied. We need to find the vertices
* of the shape that is the intersection of the clip rect and
* transformed surface . This can be anything from 3 to 8 sides .
*
* Observation : all the resulting vertices will be the intersection
* points of the transformed surface and the clip rect , plus the
* vertices of the clip rect which are enclosed by the transformed
* surface and the vertices of the transformed surface which are
* enclosed by the clip rect .
*
* Observation : there will be zero , one , or two resulting vertices
* for each edge of the src rect .
*
* Loop over four edges of the transformed rect :
*/
for ( i = 0 ; i < 4 ; i + + ) {
GLfloat x1 , y1 , x2 , y2 ;
int last_n = n ;
x1 = x [ i ] ;
y1 = y [ i ] ;
/* if this vertex is contained in the clip rect, use it as-is: */
if ( ( cx1 < = x1 ) & & ( x1 < = cx2 ) & &
( cy1 < = y1 ) & & ( y1 < = cy2 ) )
append_vertex ( x1 , y1 ) ;
/* for remaining, we consider the point as part of a line: */
x2 = x [ ( i + 1 ) % 4 ] ;
y2 = y [ ( i + 1 ) % 4 ] ;
if ( x1 = = x2 ) {
append_vertex ( clip ( x1 , cx1 , cx2 ) , clip ( y1 , cy1 , cy2 ) ) ;
append_vertex ( clip ( x2 , cx1 , cx2 ) , clip ( y2 , cy1 , cy2 ) ) ;
} else if ( y1 = = y2 ) {
append_vertex ( clip ( x1 , cx1 , cx2 ) , clip ( y1 , cy1 , cy2 ) ) ;
append_vertex ( clip ( x2 , cx1 , cx2 ) , clip ( y2 , cy1 , cy2 ) ) ;
} else {
GLfloat m , c , p ;
GLfloat tx [ 2 ] , ty [ 2 ] ;
int tn = 0 ;
int intersect_horiz ( GLfloat y , GLfloat * p )
{
GLfloat x ;
/* if y does not lie between y1 and y2, no
* intersection possible
*/
if ( sign ( y - y1 ) = = sign ( y - y2 ) )
return 0 ;
x = ( y - c ) / m ;
/* if x does not lie between cx1 and cx2, no
* intersection :
*/
if ( sign ( x - cx1 ) = = sign ( x - cx2 ) )
return 0 ;
* p = x ;
return 1 ;
}
int intersect_vert ( GLfloat x , GLfloat * p )
{
GLfloat y ;
if ( sign ( x - x1 ) = = sign ( x - x2 ) )
return 0 ;
y = m * x + c ;
if ( sign ( y - cy1 ) = = sign ( y - cy2 ) )
return 0 ;
* p = y ;
return 1 ;
}
/* y = mx + c */
m = ( y2 - y1 ) / ( x2 - x1 ) ;
c = y1 - m * x1 ;
/* check for up to two intersections with the four edges
* of the clip rect . Note that we don ' t know the orientation
* of the transformed surface wrt . the clip rect . So if when
* there are two intersection points , we need to put the one
* closest to x1 , y1 first :
*/
/* check top clip rect edge: */
if ( intersect_horiz ( cy1 , & p ) ) {
ty [ tn ] = cy1 ;
tx [ tn ] = p ;
tn + + ;
}
/* check right clip rect edge: */
if ( intersect_vert ( cx2 , & p ) ) {
ty [ tn ] = p ;
tx [ tn ] = cx2 ;
tn + + ;
if ( tn = = 2 )
goto edge_check_done ;
}
/* check bottom clip rect edge: */
if ( intersect_horiz ( cy2 , & p ) ) {
ty [ tn ] = cy2 ;
tx [ tn ] = p ;
tn + + ;
if ( tn = = 2 )
goto edge_check_done ;
}
/* check left clip rect edge: */
if ( intersect_vert ( cx1 , & p ) ) {
ty [ tn ] = p ;
tx [ tn ] = cx1 ;
tn + + ;
}
edge_check_done :
if ( tn = = 1 ) {
append_vertex ( tx [ 0 ] , ty [ 0 ] ) ;
} else if ( tn = = 2 ) {
if ( dist_squared ( x1 , y1 , tx [ 0 ] , ty [ 0 ] ) <
dist_squared ( x1 , y1 , tx [ 1 ] , ty [ 1 ] ) ) {
append_vertex ( tx [ 0 ] , ty [ 0 ] ) ;
append_vertex ( tx [ 1 ] , ty [ 1 ] ) ;
} else {
append_vertex ( tx [ 1 ] , ty [ 1 ] ) ;
append_vertex ( tx [ 0 ] , ty [ 0 ] ) ;
}
}
if ( n = = last_n ) {
GLfloat best_x = 0 , best_y = 0 ;
uint32_t d , best_d = ( unsigned int ) - 1 ; /* distance squared */
uint32_t max_d = dist_squared ( x2 , y2 ,
x [ ( i + 2 ) % 4 ] , y [ ( i + 2 ) % 4 ] ) ;
/* if there are no vertices on this line, it could be that
* there is a vertex of the clip rect that is enclosed by
* the transformed surface . Find the vertex of the clip
* rect that is reached by the shortest line perpendicular
* to the current edge , if any .
*
* slope of perpendicular is 1 / m , so
*
* cy = - cx / m + c2
* c2 = cy + cx / m
*
*/
int perp_intersect ( GLfloat cx , GLfloat cy , uint32_t * d )
{
GLfloat c2 = cy + cx / m ;
GLfloat x = ( c2 - c ) / ( m + 1 / m ) ;
/* if the x position of the intersection of the
* perpendicular with the transformed edge does
* not lie within the bounds of the edge , then
* no intersection :
*/
if ( sign ( x - x1 ) = = sign ( x - x2 ) )
return 0 ;
* d = dist_squared ( cx , cy , x , ( m * x ) + c ) ;
/* if intersection distance is further away than
* opposite edge of surface region , it is invalid :
*/
if ( * d > max_d )
return 0 ;
return 1 ;
}
if ( perp_intersect ( cx1 , cy1 , & d ) ) {
best_x = cx1 ;
best_y = cy1 ;
best_d = d ;
}
if ( perp_intersect ( cx1 , cy2 , & d ) & & ( d < best_d ) ) {
best_x = cx1 ;
best_y = cy2 ;
best_d = d ;
}
if ( perp_intersect ( cx2 , cy2 , & d ) & & ( d < best_d ) ) {
best_x = cx2 ;
best_y = cy2 ;
best_d = d ;
}
if ( perp_intersect ( cx2 , cy1 , & d ) & & ( d < best_d ) ) {
best_x = cx2 ;
best_y = cy1 ;
best_d = d ;
}
if ( best_d ! = ( unsigned int ) - 1 ) // XXX can this happen?
append_vertex ( best_x , best_y ) ;
}
}
}
return n ;
}
static int
texture_region ( struct weston_surface * es , pixman_region32_t * region )
texture_region ( struct weston_surface * es , pixman_region32_t * region ,
pixman_region32_t * surf_region )
{
struct weston_compositor * ec = es - > compositor ;
GLfloat * v , inv_width , inv_height ;
GLfloat sx , sy ;
pixman_box32_t * rectangles ;
unsigned int * p ;
int i , n ;
unsigned int * vtxcnt , nvtx = 0 ;
pixman_box32_t * rects , * surf_rects ;
int i , j , k , nrects , nsurf ;
rects = pixman_region32_rectangles ( region , & nrects ) ;
surf_rects = pixman_region32_rectangles ( surf_region , & nsurf ) ;
/* worst case we can have 10 vertices per rect (ie. clipped into
* an octagon ) :
*/
v = wl_array_add ( & ec - > vertices , nrects * nsurf * 10 * 4 * sizeof * v ) ;
vtxcnt = wl_array_add ( & ec - > vtxcnt , nrects * nsurf * sizeof * vtxcnt ) ;
rectangles = pixman_region32_rectangles ( region , & n ) ;
v = wl_array_add ( & ec - > vertices , n * 16 * sizeof * v ) ;
p = wl_array_add ( & ec - > indices , n * 6 * sizeof * p ) ;
inv_width = 1.0 / es - > pitch ;
inv_height = 1.0 / es - > geometry . height ;
for ( i = 0 ; i < n ; i + + , v + = 16 , p + = 6 ) {
surface_from_global_float ( es , rectangles [ i ] . x1 ,
rectangles [ i ] . y1 , & sx , & sy ) ;
v [ 0 ] = rectangles [ i ] . x1 ;
v [ 1 ] = rectangles [ i ] . y1 ;
v [ 2 ] = sx * inv_width ;
v [ 3 ] = sy * inv_height ;
surface_from_global_float ( es , rectangles [ i ] . x1 ,
rectangles [ i ] . y2 , & sx , & sy ) ;
v [ 4 ] = rectangles [ i ] . x1 ;
v [ 5 ] = rectangles [ i ] . y2 ;
v [ 6 ] = sx * inv_width ;
v [ 7 ] = sy * inv_height ;
surface_from_global_float ( es , rectangles [ i ] . x2 ,
rectangles [ i ] . y1 , & sx , & sy ) ;
v [ 8 ] = rectangles [ i ] . x2 ;
v [ 9 ] = rectangles [ i ] . y1 ;
v [ 10 ] = sx * inv_width ;
v [ 11 ] = sy * inv_height ;
surface_from_global_float ( es , rectangles [ i ] . x2 ,
rectangles [ i ] . y2 , & sx , & sy ) ;
v [ 12 ] = rectangles [ i ] . x2 ;
v [ 13 ] = rectangles [ i ] . y2 ;
v [ 14 ] = sx * inv_width ;
v [ 15 ] = sy * inv_height ;
p [ 0 ] = i * 4 + 0 ;
p [ 1 ] = i * 4 + 1 ;
p [ 2 ] = i * 4 + 2 ;
p [ 3 ] = i * 4 + 2 ;
p [ 4 ] = i * 4 + 1 ;
p [ 5 ] = i * 4 + 3 ;
for ( i = 0 ; i < nrects ; i + + ) {
pixman_box32_t * rect = & rects [ i ] ;
for ( j = 0 ; j < nsurf ; j + + ) {
pixman_box32_t * surf_rect = & surf_rects [ j ] ;
GLfloat cx , cy ;
GLfloat ex [ 8 ] , ey [ 8 ] ; /* edge points in screen space */
int n ;
void emit_vertex ( GLfloat gx , GLfloat gy )
{
GLfloat sx , sy ;
surface_from_global_float ( es , gx , gy , & sx , & sy ) ;
/* In groups of 4 attributes, first two are 'position', 2nd two
* are ' texcoord ' .
*/
* ( v + + ) = gx ;
* ( v + + ) = gy ;
* ( v + + ) = sx * inv_width ;
* ( v + + ) = sy * inv_height ;
}
return n ;
/* The transformed surface, after clipping to the clip region,
* can have as many as eight sides , emitted as a triangle - fan .
* The first vertex is the center , followed by each corner .
*
* If a corner of the transformed surface falls outside of the
* clip region , instead of emitting one vertex for the corner
* of the surface , up to two are emitted for two corresponding
* intersection point ( s ) between the surface and the clip region .
*
* To do this , we first calculate the ( up to eight ) points that
* form the intersection of the clip rect and the transformed
* surface . After that we calculate the average to determine
* the center point , and emit the center and edge vertices of
* the fan .
*/
n = calculate_edges ( es , rect , surf_rect , ex , ey ) ;
if ( n < 3 )
continue ;
/* calculate/emit center point: */
cx = 0 ;
cy = 0 ;
for ( k = 0 ; k < n ; k + + ) {
cx + = ex [ k ] ;
cy + = ey [ k ] ;
}
cx / = n ;
cy / = n ;
emit_vertex ( cx , cy ) ;
/* then emit edge points: */
for ( k = 0 ; k < n ; k + + )
emit_vertex ( ex [ k ] , ey [ k ] ) ;
/* and close the fan: */
emit_vertex ( ex [ 0 ] , ey [ 0 ] ) ;
vtxcnt [ nvtx + + ] = n + 2 ;
}
}
return nvtx ;
}
static void
repaint_region ( struct weston_surface * es , pixman_region32_t * region ,
pixman_region32_t * surf_region )
{
struct weston_compositor * ec = es - > compositor ;
GLfloat * v ;
unsigned int * vtxcnt ;
int i , first , nfans ;
/* The final region to be painted is the intersection of
* ' region ' and ' surf_region ' . However , ' region ' is in the global
* coordinates , and ' surf_region ' is in the surface - local
* corodinates . texture_region ( ) will iterate over all pairs of
* rectangles from both regions , compute the intersection
* polygon for each pair , and store it as a triangle fan if
* it has a non - zero area .
*/
nfans = texture_region ( es , region , surf_region ) ;
v = ec - > vertices . data ;
vtxcnt = ec - > vtxcnt . data ;
/* position: */
glVertexAttribPointer ( 0 , 2 , GL_FLOAT , GL_FALSE , 4 * sizeof * v , & v [ 0 ] ) ;
glEnableVertexAttribArray ( 0 ) ;
/* texcoord: */
glVertexAttribPointer ( 1 , 2 , GL_FLOAT , GL_FALSE , 4 * sizeof * v , & v [ 2 ] ) ;
glEnableVertexAttribArray ( 1 ) ;
for ( i = 0 , first = 0 ; i < nfans ; i + + ) {
glDrawArrays ( GL_TRIANGLE_FAN , first , vtxcnt [ i ] ) ;
first + = vtxcnt [ i ] ;
}
glDisableVertexAttribArray ( 1 ) ;
glDisableVertexAttribArray ( 0 ) ;
ec - > vertices . size = 0 ;
ec - > vtxcnt . size = 0 ;
}
WL_EXPORT void
weston_surface_draw ( struct weston_surface * es , struct weston_output * output ,
pixman_region32_t * damage )
{
GLfloat surface_rect [ 4 ] = { 0.0 , 1.0 , 0.0 , 1.0 } ;
struct weston_compositor * ec = es - > compositor ;
GLfloat * v ;
/* repaint bounding region in global coordinates: */
pixman_region32_t repaint ;
/* regions of surface to draw opaque/blended in surface coordinates: */
pixman_region32_t surface_opaque , surface_blend ;
GLint filter ;
int i , n ;
int i ;
pixman_region32_init ( & repaint ) ;
pixman_region32_init ( & surface_opaque ) ;
pixman_region32_init ( & surface_blend ) ;
pixman_region32_intersect ( & repaint ,
& es - > transform . boundingbox , damage ) ;
pixman_region32_subtract ( & repaint , & repaint , & es - > clip ) ;
@ -940,10 +1307,20 @@ weston_surface_draw(struct weston_surface *es, struct weston_output *output,
& ec - > primary_plane . damage , & repaint ) ;
glBlendFunc ( GL_ONE , GL_ONE_MINUS_SRC_ALPHA ) ;
if ( es - > blend | | es - > alpha < 1.0 )
glEnable ( GL_BLEND ) ;
else
glDisable ( GL_BLEND ) ;
if ( es - > blend | | es - > alpha < 1.0 ) {
/* blended region is whole surface minus opaque region: */
pixman_region32_init_rect ( & surface_blend , 0 , 0 ,
es - > geometry . width , es - > geometry . height ) ;
pixman_region32_init ( & surface_opaque ) ;
pixman_region32_copy ( & surface_opaque , & es - > opaque ) ;
pixman_region32_subtract ( & surface_blend , & surface_blend ,
& surface_opaque ) ;
} else {
/* whole surface is opaque: */
pixman_region32_init_rect ( & surface_opaque , 0 , 0 ,
es - > geometry . width , es - > geometry . height ) ;
pixman_region32_init ( & surface_blend ) ;
}
if ( ec - > current_shader ! = es - > shader ) {
glUseProgram ( es - > shader - > program ) ;
@ -954,20 +1331,12 @@ weston_surface_draw(struct weston_surface *es, struct weston_output *output,
1 , GL_FALSE , output - > matrix . d ) ;
glUniform4fv ( es - > shader - > color_uniform , 1 , es - > color ) ;
glUniform1f ( es - > shader - > alpha_uniform , es - > alpha ) ;
glUniform1f ( es - > shader - > texwidth_uniform ,
( GLfloat ) es - > geometry . width / es - > pitch ) ;
if ( es - > blend )
glUniform4fv ( es - > shader - > opaque_uniform , 1 , es - > opaque_rect ) ;
else
glUniform4fv ( es - > shader - > opaque_uniform , 1 , surface_rect ) ;
if ( es - > transform . enabled | | output - > zoom . active )
filter = GL_LINEAR ;
else
filter = GL_NEAREST ;
n = texture_region ( es , & repaint ) ;
for ( i = 0 ; i < es - > num_textures ; i + + ) {
glUniform1i ( es - > shader - > tex_uniforms [ i ] , i ) ;
glActiveTexture ( GL_TEXTURE0 + i ) ;
@ -976,22 +1345,20 @@ weston_surface_draw(struct weston_surface *es, struct weston_output *output,
glTexParameteri ( es - > target , GL_TEXTURE_MAG_FILTER , filter ) ;
}
v = ec - > vertices . data ;
glVertexAttribPointer ( 0 , 2 , GL_FLOAT , GL_FALSE , 4 * sizeof * v , & v [ 0 ] ) ;
glVertexAttribPointer ( 1 , 2 , GL_FLOAT , GL_FALSE , 4 * sizeof * v , & v [ 2 ] ) ;
glEnableVertexAttribArray ( 0 ) ;
glEnableVertexAttribArray ( 1 ) ;
glDrawElements ( GL_TRIANGLES , n * 6 , GL_UNSIGNED_INT , ec - > indices . data ) ;
glDisableVertexAttribArray ( 1 ) ;
glDisableVertexAttribArray ( 0 ) ;
if ( pixman_region32_not_empty ( & surface_opaque ) ) {
glDisable ( GL_BLEND ) ;
repaint_region ( es , & repaint , & surface_opaque ) ;
}
ec - > vertices . size = 0 ;
ec - > indices . size = 0 ;
if ( pixman_region32_not_empty ( & surface_blend ) ) {
glEnable ( GL_BLEND ) ;
repaint_region ( es , & repaint , & surface_blend ) ;
}
out :
pixman_region32_fini ( & repaint ) ;
pixman_region32_fini ( & surface_opaque ) ;
pixman_region32_fini ( & surface_blend ) ;
}
WL_EXPORT void
@ -2819,39 +3186,23 @@ static const char vertex_shader[] =
" } \n " ;
/* Declare common fragment shader uniforms */
# define FRAGMENT_SHADER_UNIFORMS \
" uniform float alpha; \n " \
" uniform float texwidth; \n " \
" uniform vec4 opaque; \n "
/* Common fragment shader init code (check texture bounds) */
# define FRAGMENT_SHADER_INIT \
" if (v_texcoord.x < 0.0 || v_texcoord.x > texwidth || \n " \
" v_texcoord.y < 0.0 || v_texcoord.y > 1.0) \n " \
" discard; \n "
# define FRAGMENT_SHADER_EXIT \
" if (opaque.x <= v_texcoord.x && v_texcoord.x < opaque.y && \n " \
" opaque.z <= v_texcoord.y && v_texcoord.y < opaque.w) \n " \
" gl_FragColor.a = 1.0; \n " \
" gl_FragColor = alpha * gl_FragColor; \n "
# define FRAGMENT_CONVERT_YUV \
" y *= alpha; \n " \
" u *= alpha; \n " \
" v *= alpha; \n " \
" gl_FragColor.r = y + 1.59602678 * v; \n " \
" gl_FragColor.g = y - 0.39176229 * u - 0.81296764 * v; \n " \
" gl_FragColor.b = y + 2.01723214 * u; \n " \
" gl_FragColor.a = 1.0 ; \n "
" gl_FragColor.a = alpha; \n "
static const char texture_fragment_shader_rgba [ ] =
" precision mediump float; \n "
" varying vec2 v_texcoord; \n "
" uniform sampler2D tex; \n "
FRAGMENT_SHADER_UNIFORMS
" uniform float alpha; \n "
" void main() \n "
" { \n "
FRAGMENT_SHADER_INIT
" gl_FragColor = texture2D(tex, v_texcoord) \n ; "
FRAGMENT_SHADER_EXIT
" gl_FragColor = alpha * texture2D(tex, v_texcoord) \n ; "
" } \n " ;
static const char texture_fragment_shader_egl_external [ ] =
@ -2859,12 +3210,10 @@ static const char texture_fragment_shader_egl_external[] =
" precision mediump float; \n "
" varying vec2 v_texcoord; \n "
" uniform samplerExternalOES tex; \n "
FRAGMENT_SHADER_UNIFORMS
" uniform float alpha; \n "
" void main() \n "
" { \n "
FRAGMENT_SHADER_INIT
" gl_FragColor = texture2D(tex, v_texcoord) \n ; "
FRAGMENT_SHADER_EXIT
" gl_FragColor = alpha * texture2D(tex, v_texcoord) \n ; "
" } \n " ;
static const char texture_fragment_shader_y_uv [ ] =
@ -2872,14 +3221,12 @@ static const char texture_fragment_shader_y_uv[] =
" uniform sampler2D tex; \n "
" uniform sampler2D tex1; \n "
" varying vec2 v_texcoord; \n "
FRAGMENT_SHADER_UNIFORMS
" uniform float alpha; \n "
" void main() { \n "
FRAGMENT_SHADER_INIT
" float y = 1.16438356 * (texture2D(tex, v_texcoord).x - 0.0625); \n "
" float u = texture2D(tex1, v_texcoord).r - 0.5; \n "
" float v = texture2D(tex1, v_texcoord).g - 0.5; \n "
FRAGMENT_CONVERT_YUV
FRAGMENT_SHADER_EXIT
" } \n " ;
static const char texture_fragment_shader_y_u_v [ ] =
@ -2888,14 +3235,12 @@ static const char texture_fragment_shader_y_u_v[] =
" uniform sampler2D tex1; \n "
" uniform sampler2D tex2; \n "
" varying vec2 v_texcoord; \n "
FRAGMENT_SHADER_UNIFORMS
" uniform float alpha; \n "
" void main() { \n "
FRAGMENT_SHADER_INIT
" float y = 1.16438356 * (texture2D(tex, v_texcoord).x - 0.0625); \n "
" float u = texture2D(tex1, v_texcoord).x - 0.5; \n "
" float v = texture2D(tex2, v_texcoord).x - 0.5; \n "
FRAGMENT_CONVERT_YUV
FRAGMENT_SHADER_EXIT
" } \n " ;
static const char texture_fragment_shader_y_xuxv [ ] =
@ -2903,14 +3248,12 @@ static const char texture_fragment_shader_y_xuxv[] =
" uniform sampler2D tex; \n "
" uniform sampler2D tex1; \n "
" varying vec2 v_texcoord; \n "
FRAGMENT_SHADER_UNIFORMS
" uniform float alpha; \n "
" void main() { \n "
FRAGMENT_SHADER_INIT
" float y = 1.16438356 * (texture2D(tex, v_texcoord).x - 0.0625); \n "
" float u = texture2D(tex1, v_texcoord).g - 0.5; \n "
" float v = texture2D(tex1, v_texcoord).a - 0.5; \n "
FRAGMENT_CONVERT_YUV
FRAGMENT_SHADER_EXIT
" } \n " ;
static const char solid_fragment_shader [ ] =
@ -2974,8 +3317,6 @@ weston_shader_init(struct weston_shader *shader,
shader - > tex_uniforms [ 2 ] = glGetUniformLocation ( shader - > program , " tex2 " ) ;
shader - > alpha_uniform = glGetUniformLocation ( shader - > program , " alpha " ) ;
shader - > color_uniform = glGetUniformLocation ( shader - > program , " color " ) ;
shader - > texwidth_uniform = glGetUniformLocation ( shader - > program , " texwidth " ) ;
shader - > opaque_uniform = glGetUniformLocation ( shader - > program , " opaque " ) ;
return 0 ;
}
@ -3411,6 +3752,7 @@ weston_compositor_shutdown(struct weston_compositor *ec)
wl_array_release ( & ec - > vertices ) ;
wl_array_release ( & ec - > indices ) ;
wl_array_release ( & ec - > vtxcnt ) ;
wl_event_loop_destroy ( ec - > input_loop ) ;
}