static void rect_tests(struct test *test, int iterations, enum target target)
{
struct test_target real, ref;
void (* const ops[])(struct test_target *, struct test_target *) = {
copy,
fill,
put,
};
int n;
printf("Running mixed ops stress against %s: ",
test_target_name(target));
fflush(stdout);
test_target_create_render(&test->real, target, &real);
test_target_create_render(&test->ref, target, &ref);
clear(&real);
clear(&ref);
for (n = 0; n < iterations; n++)
ops[rand() % ARRAY_SIZE(ops)](&real, &ref);
test_compare(test,
real.draw, real.format,
ref.draw, ref.format,
0, 0, real.width, real.height,
"");
printf("passed [%d iterations]\n", n);
test_target_destroy_render(&test->real, &real);
test_target_destroy_render(&test->ref, &ref);
}
static void general(struct test *t, enum target target)
{
char buf[1024];
struct test_target out, ref;
int a, b, alu, lw, style, cap;
XSegment seg[NUM_POINTS*NUM_POINTS];
int n = 0;
printf("Testing drawing of general line segments (%s): ",
test_target_name(target));
fflush(stdout);
test_target_create_render(&t->out, target, &out);
test_target_create_render(&t->ref, target, &ref);
style = LineSolid;
for (a = 0; a < NUM_POINTS; a++) {
for (b = 0; b < NUM_POINTS; b++) {
seg[n].x1 = points[a].x + 64;
seg[n].y1 = points[a].y + 64;
seg[n].x2 = points[b].x + 64;
seg[n].y2 = points[b].y + 64;
n++;
}
}
for (alu = 0; alu < 16; alu++) {
for (cap = CapNotLast; cap <= CapProjecting; cap++) {
for (lw = 0; lw <= 4; lw++) {
sprintf(buf,
"width=%d, cap=%d, alu=%d",
lw, cap, alu);
clear(&t->out, &out);
clear(&t->ref, &ref);
draw(&t->out, &out, alu, lw, style, cap,
seg, n);
draw(&t->ref, &ref, alu, lw, style, cap,
seg, n);
test_compare(t,
out.draw, out.format,
ref.draw, ref.format,
0, 0, out.width, out.height,
buf);
}
}
}
test_target_destroy_render(&t->out, &out);
test_target_destroy_render(&t->ref, &ref);
printf("\n");
}
static void glyph_iter_fini(struct glyph_iter *gi)
{
if (gi->out.glyphset)
XRenderFreeGlyphSet (gi->out.dpy->dpy, gi->out.glyphset);
if (gi->ref.glyphset)
XRenderFreeGlyphSet (gi->ref.dpy->dpy, gi->ref.glyphset);
test_target_destroy_render(gi->out.dpy, &gi->out.tt);
test_target_destroy_render(gi->ref.dpy, &gi->ref.tt);
}
static void ref_tests(struct test *t, int reps, int sets, enum target target)
{
struct test_target out, ref;
int r, s;
printf("Testing area fills (%s): ", test_target_name(target));
fflush(stdout);
test_target_create_render(&t->out, target, &out);
clear(&t->out, &out);
test_target_create_render(&t->ref, target, &ref);
clear(&t->ref, &ref);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int x = rand() % (2*out.width) - out.width;
int y = rand() % (2*out.height) - out.height;
int w = rand() % out.width;
int h = rand() % out.height;
int op = ops[rand() % sizeof(ops)];
int s_red = rand() % 0xff;
int s_green = rand() % 0xff;
int s_blue = rand() % 0xff;
int s_alpha = rand() % 0xff;
int m_red = rand() % 0xff;
int m_green = rand() % 0xff;
int m_blue = rand() % 0xff;
int m_alpha = rand() % 0xff;
fill_rect(&t->out, out.picture,
op, x, y, w, h,
s_red, s_green, s_blue, s_alpha,
m_red, m_green, m_blue, m_alpha);
fill_rect(&t->ref, ref.picture,
op, x, y, w, h,
s_red, s_green, s_blue, s_alpha,
m_red, m_green, m_blue, m_alpha);
}
test_compare(t,
out.draw, out.format,
ref.draw, ref.format,
0, 0, out.width, out.height,
"");
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->out, &out);
test_target_destroy_render(&t->ref, &ref);
}
static void rect_tests(struct test *t,
int dx, int dy,
enum mask mask,
int reps, int sets,
enum target target)
{
struct test_target real, ref;
int r, s;
printf("Testing area fills (offset %dx%d, mask %s) (%s): ",
dx, dy, mask_name(mask), test_target_name(target));
fflush(stdout);
test_target_create_render(&t->real, target, &real);
clear(&t->real, &real);
test_target_create_render(&t->ref, target, &ref);
clear(&t->ref, &ref);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int x = rand() % (2*real.width) - real.width;
int y = rand() % (2*real.height) - real.height;
int w = rand() % real.width;
int h = rand() % real.height;
int op = ops[rand() % sizeof(ops)];
int red = rand() % 0xff;
int green = rand() % 0xff;
int blue = rand() % 0xff;
int alpha = rand() % 0xff;
fill_rect(&t->real, real.picture, op,
x, y, w, h, dx, dy, mask,
red, green, blue, alpha);
fill_rect(&t->ref, ref.picture, op,
x, y, w, h, dx, dy, mask,
red, green, blue, alpha);
}
test_compare(t,
real.draw, real.format,
ref.draw, ref.format,
0, 0, real.width, real.height,
"");
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->real, &real);
test_target_destroy_render(&t->ref, &ref);
}
static void pixel_tests(struct test *t, int reps, int sets, enum target target)
{
struct test_target tt;
XImage image;
uint32_t *cells = malloc(t->real.width*t->real.height*4);
struct {
uint16_t x, y;
} *pixels = malloc(reps*sizeof(*pixels));
int r, s;
test_target_create_render(&t->real, target, &tt);
printf("Testing setting of single pixels (%s): ",
test_target_name(target));
fflush(stdout);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int x = rand() % (tt.width - 1);
int y = rand() % (tt.height - 1);
uint32_t fg = rand();
fill_rect(&t->real, tt.draw, GXcopy,
x, y, 1, 1, fg);
pixels[r].x = x;
pixels[r].y = y;
cells[y*tt.width+x] = fg;
}
test_init_image(&image, &t->real.shm, tt.format, 1, 1);
for (r = 0; r < reps; r++) {
uint32_t x = pixels[r].x;
uint32_t y = pixels[r].y;
uint32_t result;
XShmGetImage(t->real.dpy, tt.draw, &image,
x, y, AllPlanes);
result = *(uint32_t *)image.data;
if (!pixel_equal(image.depth, result,
cells[y*tt.width+x])) {
uint32_t mask = depth_mask(image.depth);
die("failed to set pixel (%d,%d) to %08x [%08x], found %08x [%08x] instead\n",
x, y,
cells[y*tt.width+x] & mask,
cells[y*tt.width+x],
result & mask,
result);
}
}
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->real, &tt);
free(pixels);
free(cells);
}
static double _bench_source(struct test_display *t, enum target target_type,
int op, int src, int loops)
{
XRenderColor render_color = { 0x8000, 0x8000, 0x8000, 0x8000 };
struct test_target target;
Picture picture;
struct timespec tv;
double elapsed;
test_target_create_render(t, target_type, &target);
XRenderFillRectangle(t->dpy, PictOpClear, target.picture, &render_color,
0, 0, target.width, target.height);
picture = source[src].create(t, &target);
if (picture) {
test_timer_start(t, &tv);
while (loops--)
XRenderComposite(t->dpy, op,
picture, 0, target.picture,
0, 0,
0, 0,
0, 0,
target.width, target.height);
elapsed = test_timer_stop(t, &tv);
XRenderFreePicture(t->dpy, picture);
} else
elapsed = -1;
test_target_destroy_render(t, &target);
return elapsed;
}
static void rect_tests(struct test *t, int reps, int sets, enum target target, int use_window)
{
struct test_target out, ref;
int r, s;
printf("Testing area fills (%s, using %s source): ",
test_target_name(target), use_window ? "window" : "pixmap");
fflush(stdout);
test_target_create_render(&t->out, target, &out);
clear(&t->out, &out);
test_target_create_render(&t->ref, target, &ref);
clear(&t->ref, &ref);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int x, y, w, h;
uint8_t red = rand();
uint8_t green = rand();
uint8_t blue = rand();
x = rand() % (out.width - 1);
y = rand() % (out.height - 1);
w = 1 + rand() % (out.width - x - 1);
h = 1 + rand() % (out.height - y - 1);
fill_rect(&t->out, out.picture,
x, y, w, h,
red, green, blue);
fill_rect(&t->ref, ref.picture,
x, y, w, h,
red, green, blue);
}
test_compare(t,
out.draw, out.format,
ref.draw, ref.format,
0, 0, out.width, out.height,
"");
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->out, &out);
test_target_destroy_render(&t->ref, &ref);
}
static void rect_tests(struct test *t, int reps, int sets, enum target target, int use_window)
{
struct test_target real, ref;
int r, s;
printf("Testing area fills (%s, using %s source): ",
test_target_name(target), use_window ? "window" : "pixmap");
fflush(stdout);
test_target_create_render(&t->real, target, &real);
clear(&t->real, &real);
test_target_create_render(&t->ref, target, &ref);
clear(&t->ref, &ref);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int x = rand() % (real.width - 1);
int y = rand() % (real.height - 1);
int w = 1 + rand() % (real.width - x - 1);
int h = 1 + rand() % (real.height - y - 1);
int tmpx = w == real.width ? 0 : rand() % (real.width - w);
int tmpy = h == real.height ? 0 : rand() % (real.height - h);
uint8_t alu = rand() % (GXset + 1);
uint32_t fg = rand();
fill_rect(&t->real, real.draw, real.format,
use_window, tmpx, tmpy,
alu, x, y, w, h, fg);
fill_rect(&t->ref, ref.draw, ref.format,
use_window, tmpx, tmpy,
alu, x, y, w, h, fg);
}
test_compare(t,
real.draw, real.format,
ref.draw, ref.format,
0, 0, real.width, real.height,
"");
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->real, &real);
test_target_destroy_render(&t->ref, &ref);
}
static void rect_tests(struct test *t, int reps, int sets, enum target target, int use_shm)
{
struct test_target real, ref;
int r, s;
printf("Testing area fills (%s): ", test_target_name(target));
fflush(stdout);
test_target_create_render(&t->real, target, &real);
clear(&t->real, &real);
test_target_create_render(&t->ref, target, &ref);
clear(&t->ref, &ref);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int x = rand() % real.width;
int y = rand() % real.height;
int w = rand() % (real.width - x);
int h = rand() % (real.height - y);
uint8_t alu = rand() % (GXset + 1);
int red = rand() % 0xff;
int green = rand() % 0xff;
int blue = rand() % 0xff;
int alpha = rand() % 0xff;
uint8_t fg = color(red, green, blue, alpha);
fill_rect(&t->real, real.draw, real.format, use_shm,
alu, x, y, w, h, fg);
fill_rect(&t->ref, ref.draw, ref.format, use_shm,
alu, x, y, w, h, fg);
}
test_compare(t,
real.draw, real.format,
ref.draw, ref.format,
0, 0, real.width, real.height,
"");
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->real, &real);
test_target_destroy_render(&t->ref, &ref);
}
static void rect_tests(struct test *t, int reps, int sets, enum target target)
{
struct test_target real, ref;
int r, s;
printf("Testing general (%s): ", test_target_name(target));
fflush(stdout);
test_target_create_render(&t->real, target, &real);
clear(&t->real, &real);
test_target_create_render(&t->ref, target, &ref);
clear(&t->ref, &ref);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int x = rand() % (2*real.width) - real.width;
int y = rand() % (2*real.height) - real.height;
int w = rand() % (2*real.width);
int h = rand() % (2*real.height);
uint8_t alu = rand() % (GXset + 1);
uint32_t fg = rand();
uint32_t lw = rand() % 4;
draw_rect(&t->real, real.draw, alu,
x, y, w, h, fg, lw);
draw_rect(&t->ref, ref.draw, alu,
x, y, w, h, fg, lw);
}
test_compare(t,
real.draw, real.format,
ref.draw, ref.format,
0, 0, real.width, real.height,
"");
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->real, &real);
test_target_destroy_render(&t->ref, &ref);
}
static void area_tests(struct test *t, int reps, int sets, enum target target)
{
struct test_target tt;
XImage image;
uint32_t *cells = calloc(sizeof(uint32_t), t->real.width*t->real.height);
int r, s, x, y;
printf("Testing area sets (%s): ", test_target_name(target));
fflush(stdout);
test_target_create_render(&t->real, target, &tt);
clear(&t->real, &tt);
test_init_image(&image, &t->real.shm, tt.format, tt.width, tt.height);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int w = rand() % tt.width;
int h = rand() % tt.height;
uint32_t fg = rand();
x = rand() % (2*tt.width) - tt.width;
y = rand() % (2*tt.height) - tt.height;
fill_rect(&t->real, tt.draw, GXcopy,
x, y, w, h, fg);
if (x < 0)
w += x, x = 0;
if (y < 0)
h += y, y = 0;
if (x >= tt.width || y >= tt.height)
continue;
if (x + w > tt.width)
w = tt.width - x;
if (y + h > tt.height)
h = tt.height - y;
if (w <= 0 || h <= 0)
continue;
pixman_fill(cells, tt.width, 32, x, y, w, h, fg);
}
XShmGetImage(t->real.dpy, tt.draw, &image, 0, 0, AllPlanes);
for (y = 0; y < tt.height; y++) {
for (x = 0; x < tt.width; x++) {
uint32_t result = *(uint32_t *)
(image.data +
y*image.bytes_per_line +
x*image.bits_per_pixel/8);
if (!pixel_equal(image.depth, result, cells[y*tt.width+x])) {
char buf[600];
uint32_t mask = depth_mask(image.depth);
show_cells(buf,
(uint32_t*)image.data, cells,
x, y, tt.width, tt.height);
die("failed to set pixel (%d,%d) to %08x [%08x], found %08x [%08x] instead\n%s",
x, y,
cells[y*tt.width+x] & mask,
cells[y*tt.width+x],
result & mask,
result, buf);
}
}
}
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->real, &tt);
free(cells);
}
static void edge_test(struct test *t,
enum mask mask,
enum edge edge,
enum target target)
{
struct test_target out, ref;
XRenderColor white = { 0xffff, 0xffff, 0xffff, 0xffff };
Picture src_ref, src_out;
XTriangle tri;
unsigned step, max;
test_target_create_render(&t->out, target, &out);
set_edge(t->out.dpy, out.picture, edge);
src_out = XRenderCreateSolidFill(t->out.dpy, &white);
test_target_create_render(&t->ref, target, &ref);
set_edge(t->ref.dpy, ref.picture, edge);
src_ref = XRenderCreateSolidFill(t->ref.dpy, &white);
printf("Testing edges (with mask %s and %s edges) (%s): ",
mask_name(mask),
edge_name(edge),
test_target_name(target));
fflush(stdout);
max = 2*(out.width + 128 + out.height+128);
step = 0;
for (step = 0; step <= max; step++) {
char buf[80];
step_to_point(step, out.width, out.height, &tri.p1);
step_to_point(step + out.width + 128,
out.width, out.height,
&tri.p2);
step_to_point(step + out.height + 128 + 2*(out.width + 128),
out.width, out.height,
&tri.p3);
sprintf(buf,
"tri=((%d, %d), (%d, %d), (%d, %d))\n",
tri.p1.x >> 16, tri.p1.y >> 16,
tri.p2.x >> 16, tri.p2.y >> 16,
tri.p3.x >> 16, tri.p3.y >> 16);
clear(&t->out, &out);
XRenderCompositeTriangles(t->out.dpy,
PictOpSrc,
src_out,
out.picture,
mask_format(t->out.dpy, mask),
0, 0,
&tri, 1);
clear(&t->ref, &ref);
XRenderCompositeTriangles(t->ref.dpy,
PictOpSrc,
src_ref,
ref.picture,
mask_format(t->ref.dpy, mask),
0, 0,
&tri, 1);
test_compare(t,
out.draw, out.format,
ref.draw, ref.format,
0, 0, out.width, out.height,
buf);
}
XRenderFreePicture(t->out.dpy, src_out);
test_target_destroy_render(&t->out, &out);
XRenderFreePicture(t->ref.dpy, src_ref);
test_target_destroy_render(&t->ref, &ref);
printf("pass\n");
}
static void area_tests(struct test *t, int reps, int sets, enum target target, int use_shm)
{
struct test_target tt;
XImage image;
uint32_t *cells = calloc(sizeof(uint32_t), t->real.width*t->real.height);
int r, s, x, y;
printf("Testing area sets (%s %s shm): ",
test_target_name(target), use_shm ? "with" : "without" );
fflush(stdout);
test_target_create_render(&t->real, target, &tt);
clear(&t->real, &tt);
test_init_image(&image, &t->real.shm, tt.format, tt.width, tt.height);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int red = rand() % 0xff;
int green = rand() % 0xff;
int blue = rand() % 0xff;
int alpha = rand() % 0xff;
uint32_t fg = color(red, green, blue, alpha);
int w, h;
x = rand() % tt.width;
y = rand() % tt.height;
w = rand() % (tt.width - x);
h = rand() % (tt.height - y);
fill_rect(&t->real, tt.draw, tt.format, use_shm,
GXcopy, x, y, w, h, fg);
pixman_fill(cells, tt.width, 32, x, y, w, h, fg);
}
XShmGetImage(t->real.dpy, tt.draw, &image, 0, 0, AllPlanes);
for (y = 0; y < tt.height; y++) {
for (x = 0; x < tt.width; x++) {
uint32_t result =
*(uint32_t *)(image.data +
y*image.bytes_per_line +
image.bits_per_pixel*x/8);
if (!pixel_equal(image.depth, result, cells[y*tt.width+x])) {
uint32_t mask = depth_mask(image.depth);
char buf[600];
show_cells(buf,
(uint32_t*)image.data, cells,
x, y, tt.width, tt.height);
die("failed to set pixel (%d,%d) to %08x[%08x], found %08x [%08x] instead\n%s",
x, y,
cells[y*tt.width+x] & mask,
cells[y*tt.width+x],
result & mask, result,
buf);
}
}
}
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->real, &tt);
free(cells);
}
static void hv0(struct test *t, enum target target)
{
char buf[1024];
struct test_target out, ref;
int a, alu, cap;
XSegment seg[(NUM_POINTS+1)*8];
int n, x, y, nseg;
printf("Testing drawing of zero-width line segments (%s): ",
test_target_name(target));
fflush(stdout);
test_target_create_render(&t->out, target, &out);
test_target_create_render(&t->ref, target, &ref);
y = x = n = 0;
for (a = 0; a <= NUM_POINTS; a++) {
seg[n].x1 = a + 64;
seg[n].y1 = y + 64;
seg[n].x2 = NUM_POINTS + 64;
seg[n].y2 = y + 64;
n++; y++;
seg[n].x1 = NUM_POINTS - a + 64;
seg[n].y1 = y + 64;
seg[n].x2 = 0 + 64;
seg[n].y2 = y + 64;
n++; y++;
seg[n].x2 = a + 64;
seg[n].y2 = y + 64;
seg[n].x1 = NUM_POINTS + 64;
seg[n].y1 = y + 64;
n++; y++;
seg[n].x2 = NUM_POINTS - a + 64;
seg[n].y2 = y + 64;
seg[n].x1 = 0 + 64;
seg[n].y1 = y + 64;
n++; y++;
seg[n].y1 = a + 64;
seg[n].x1 = x + 64;
seg[n].y2 = NUM_POINTS + 64;
seg[n].x2 = x + 64;
n++; x++;
seg[n].y1 = NUM_POINTS - a + 64;
seg[n].x1 = x + 64;
seg[n].y2 = 0 + 64;
seg[n].x2 = x + 64;
n++; x++;
seg[n].y2 = a + 64;
seg[n].x2 = x + 64;
seg[n].y1 = NUM_POINTS + 64;
seg[n].x1 = x + 64;
n++; x++;
seg[n].y2 = NUM_POINTS - a + 64;
seg[n].x2 = x + 64;
seg[n].y1 = 0 + 64;
seg[n].x1 = x + 64;
n++; x++;
}
for (alu = 0; alu < 16; alu++) {
for (cap = CapNotLast; cap <= CapProjecting; cap++) {
for (nseg = 0; nseg < n; nseg++) {
sprintf(buf,
"cap=%d, alu=%d, nseg=%d",
cap, alu, nseg);
clear(&t->out, &out);
clear(&t->ref, &ref);
draw(&t->out, &out, alu, 0, LineSolid, cap,
seg, nseg);
draw(&t->ref, &ref, alu, 0, LineSolid, cap,
seg, nseg);
test_compare(t,
out.draw, out.format,
ref.draw, ref.format,
0, 0, out.width, out.height,
buf);
}
}
}
test_target_destroy_render(&t->out, &out);
test_target_destroy_render(&t->ref, &ref);
printf("\n");
}
static void trap_tests(struct test *t,
enum mask mask,
enum trapezoid trapezoid,
int reps, int sets,
enum target target)
{
struct test_target real, ref;
XTrapezoid *traps;
int max_traps = 65536;
int r, s, n;
traps = malloc(sizeof(*traps) * max_traps);
if (traps == NULL)
return;
printf("Testing trapezoids (%s with mask %s) (%s): ",
trapezoid_name(trapezoid),
mask_name(mask),
test_target_name(target));
fflush(stdout);
test_target_create_render(&t->real, target, &real);
clear(&t->real, &real);
test_target_create_render(&t->ref, target, &ref);
clear(&t->ref, &ref);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
XRenderColor render_color;
int op = ops[rand() % sizeof(ops)];
int red = rand() % 0xff;
int green = rand() % 0xff;
int blue = rand() % 0xff;
int alpha = rand() % 0xff;
int num_traps = rand() % max_traps;
Picture src;
for (n = 0; n < num_traps; n++)
random_trapezoid(&traps[n], 0,
0, 0, real.width, real.height);
render_color.red = red * alpha;
render_color.green = green * alpha;
render_color.blue = blue * alpha;
render_color.alpha = alpha << 8;
src = XRenderCreateSolidFill(t->real.dpy,
&render_color);
XRenderCompositeTrapezoids(t->real.dpy,
op, src, real.picture,
mask_format(t->real.dpy, mask),
0, 0, traps, num_traps);
XRenderFreePicture(t->real.dpy, src);
src = XRenderCreateSolidFill(t->ref.dpy,
&render_color);
XRenderCompositeTrapezoids(t->ref.dpy,
op, src, ref.picture,
mask_format(t->ref.dpy, mask),
0, 0, traps, num_traps);
XRenderFreePicture(t->ref.dpy, src);
}
test_compare(t,
real.draw, real.format,
ref.draw, ref.format,
0, 0, real.width, real.height,
"");
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->real, &real);
test_target_destroy_render(&t->ref, &ref);
free(traps);
}
static void area_tests(struct test *t, int reps, int sets, enum target target)
{
struct test_target tt;
XImage image;
uint32_t *cells = calloc(sizeof(uint32_t), t->real.width*t->real.height);
int r, s, x, y;
printf("Testing area sets (%s): ", test_target_name(target));
fflush(stdout);
test_target_create_render(&t->real, target, &tt);
clear(&t->real, &tt);
test_init_image(&image, &t->real.shm, tt.format, tt.width, tt.height);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int w = rand() % tt.width;
int h = rand() % tt.height;
int red = rand() % 0xff;
int green = rand() % 0xff;
int blue = rand() % 0xff;
int alpha = rand() % 0xff;
x = rand() % (2*tt.width) - tt.width;
y = rand() % (2*tt.height) - tt.height;
fill_rect(&t->real, tt.picture, PictOpSrc,
x, y, w, h, red, green, blue, alpha);
if (x < 0)
w += x, x = 0;
if (y < 0)
h += y, y = 0;
if (x >= tt.width || y >= tt.height)
continue;
if (x + w > tt.width)
w = tt.width - x;
if (y + h > tt.height)
h = tt.height - y;
if (w <= 0 || h <= 0)
continue;
pixman_fill(cells, tt.width, 32, x, y, w, h,
color(red, green, blue, alpha));
}
XShmGetImage(t->real.dpy, tt.draw, &image, 0, 0, AllPlanes);
for (y = 0; y < tt.height; y++) {
for (x = 0; x < tt.width; x++) {
uint32_t result =
*(uint32_t *)(image.data +
y*image.bytes_per_line +
image.bits_per_pixel*x/8);
if (!pixel_equal(image.depth, result, cells[y*tt.width+x])) {
uint32_t mask;
if (image.depth == 32)
mask = 0xffffffff;
else
mask = (1 << image.depth) - 1;
die("failed to set pixel (%d,%d) to %08x[%08x], found %08x instead\n",
x, y,
cells[y*tt.width+x] & mask,
cells[y*tt.width+x],
result & mask);
}
}
}
}
printf("passed [%d iterations x %d]\n", reps, sets);
test_target_destroy_render(&t->real, &tt);
free(cells);
}
static void edge_test(struct test *t,
enum mask mask,
enum edge edge,
enum target target)
{
struct test_target out, ref;
XRenderColor white = { 0xffff, 0xffff, 0xffff, 0xffff };
Picture src_ref, src_out;
XTrapezoid trap;
int left_or_right, p;
test_target_create_render(&t->out, target, &out);
set_edge(t->out.dpy, out.picture, edge);
src_out = XRenderCreateSolidFill(t->out.dpy, &white);
test_target_create_render(&t->ref, target, &ref);
set_edge(t->ref.dpy, ref.picture, edge);
src_ref = XRenderCreateSolidFill(t->ref.dpy, &white);
printf("Testing edges (with mask %s and %s edges) (%s): ",
mask_name(mask),
edge_name(edge),
test_target_name(target));
fflush(stdout);
for (left_or_right = 0; left_or_right <= 1; left_or_right++) {
for (p = -64; p <= out.width + 64; p++) {
char buf[80];
if (left_or_right) {
trap.left.p1.x = 0;
trap.left.p1.y = 0;
trap.left.p2.x = 0;
trap.left.p2.y = out.height << 16;
trap.right.p1.x = p << 16;
trap.right.p1.y = 0;
trap.right.p2.x = out.width << 16;
trap.right.p2.y = out.height << 16;
} else {
trap.right.p1.x = out.width << 16;
trap.right.p1.y = 0;
trap.right.p2.x = out.width << 16;
trap.right.p2.y = out.height << 16;
trap.left.p1.x = 0;
trap.left.p1.y = 0;
trap.left.p2.x = p << 16;
trap.left.p2.y = out.height << 16;
}
trap.top = 0;
trap.bottom = out.height << 16;
sprintf(buf,
"trap=((%d, %d), (%d, %d)), ((%d, %d), (%d, %d))\n",
trap.left.p1.x >> 16, trap.left.p1.y >> 16,
trap.left.p2.x >> 16, trap.left.p2.y >> 16,
trap.right.p1.x >> 16, trap.right.p1.y >> 16,
trap.right.p2.x >> 16, trap.right.p2.y >> 16);
clear(&t->out, &out);
XRenderCompositeTrapezoids(t->out.dpy,
PictOpSrc,
src_out,
out.picture,
mask_format(t->out.dpy, mask),
0, 0,
&trap, 1);
clear(&t->ref, &ref);
XRenderCompositeTrapezoids(t->ref.dpy,
PictOpSrc,
src_ref,
ref.picture,
mask_format(t->ref.dpy, mask),
0, 0,
&trap, 1);
test_compare(t,
out.draw, out.format,
ref.draw, ref.format,
0, 0, out.width, out.height,
buf);
}
}
XRenderFreePicture(t->out.dpy, src_out);
test_target_destroy_render(&t->out, &out);
XRenderFreePicture(t->ref.dpy, src_ref);
test_target_destroy_render(&t->ref, &ref);
printf("pass\n");
}
