xenocara/driver/xf86-video-intel/test/render-trapezoid-image.c
matthieu 07f2f0a5ae Update to xf86-video-intel 2.20.19.
A recent kernel with kernel modesetting support is required.
Thanks to jsg@ and kettenis@ for their work.
2013-03-18 18:38:18 +00:00

618 lines
15 KiB
C

#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <X11/Xutil.h> /* for XDestroyImage */
#include <pixman.h> /* for pixman blt functions */
#include "test.h"
enum trapezoid {
RECT_ALIGN,
RECT_UNALIGN,
GENERAL
};
static const uint8_t ops[] = {
PictOpClear,
PictOpSrc,
PictOpDst,
};
static XRenderPictFormat *mask_format(Display *dpy, enum mask mask)
{
switch (mask) {
default:
case MASK_NONE:
case MASK_NONE_AA:
return NULL;
case MASK_A1:
return XRenderFindStandardFormat(dpy, PictStandardA1);
case MASK_A8:
return XRenderFindStandardFormat(dpy, PictStandardA8);
}
}
static const char *mask_name(enum mask mask)
{
switch (mask) {
default:
case MASK_NONE: return "none";
case MASK_NONE_AA: return "none/aa";
case MASK_A1: return "a1";
case MASK_A8: return "a8";
}
}
static const char *trapezoid_name(enum trapezoid trapezoid)
{
switch (trapezoid) {
default:
case RECT_ALIGN: return "pixel-aligned";
case RECT_UNALIGN: return "rectilinear";
case GENERAL: return "general";
}
}
static void
show_cells(char *buf,
const uint32_t *real, const uint32_t *ref,
int x, int y, int w, int h)
{
int i, j, len = 0;
for (j = y - 2; j <= y + 2; j++) {
if (j < 0 || j >= h)
continue;
for (i = x - 2; i <= x + 2; i++) {
if (i < 0 || i >= w)
continue;
len += sprintf(buf+len, "%08x ", real[j*w+i]);
}
len += sprintf(buf+len, "\t");
for (i = x - 2; i <= x + 2; i++) {
if (i < 0 || i >= w)
continue;
len += sprintf(buf+len, "%08x ", ref[j*w+i]);
}
len += sprintf(buf+len, "\n");
}
}
static void fill_rect(struct test_display *t, Picture p, XRenderPictFormat *format,
uint8_t op, int x, int y, int w, int h,
int dx, int dy, enum mask mask,
int use_window, int tx, int ty,
uint8_t red, uint8_t green, uint8_t blue, uint8_t alpha)
{
XRenderColor color;
XTrapezoid trap;
Drawable tmp;
Picture src;
int w1 = w + (dx!=0);
int h1 = h + (dy!=0);
if (use_window) {
XSetWindowAttributes attr;
attr.override_redirect = 1;
tmp = XCreateWindow(t->dpy, DefaultRootWindow(t->dpy),
tx, ty,
w1, h1,
0, format->depth,
InputOutput,
DefaultVisual(t->dpy,
DefaultScreen(t->dpy)),
CWOverrideRedirect, &attr);
XMapWindow(t->dpy, tmp);
} else
tmp = XCreatePixmap(t->dpy, DefaultRootWindow(t->dpy),
w1, h1, format->depth);
src = XRenderCreatePicture(t->dpy, tmp, format, 0, NULL);
color.red = red * alpha;
color.green = green * alpha;
color.blue = blue * alpha;
color.alpha = alpha << 8 | alpha;
XRenderFillRectangle(t->dpy, PictOpSrc, src, &color, 0, 0, w1, h1);
trap.left.p1.x = trap.left.p2.x = (x << 16) + dx;
trap.top = trap.left.p1.y = trap.right.p1.y = (y << 16) + dy;
trap.right.p1.x = trap.right.p2.x = ((x + w) << 16) + dx;
trap.bottom = trap.left.p2.y = trap.right.p2.y = ((y + h) << 16) + dy;
XRenderCompositeTrapezoids(t->dpy,
op, src, p, mask_format(t->dpy, mask),
0, 0, &trap, 1);
XRenderFreePicture(t->dpy, src);
if (use_window)
XDestroyWindow(t->dpy, tmp);
else
XFreePixmap(t->dpy, tmp);
}
static void pixel_tests(struct test *t, int reps, int sets, enum target target, int use_window)
{
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;
printf("Testing setting of single pixels (%s using %s): ",
test_target_name(target),
use_window ? "window" : "pixmap");
fflush(stdout);
test_target_create_render(&t->real, target, &tt);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int x = rand() % (tt.width - 1);
int y = rand() % (tt.height - 1);
int red = rand() % 0xff;
int green = rand() % 0xff;
int blue = rand() % 0xff;
int alpha = rand() % 0xff;
int tx, ty;
do {
tx = rand() % (tt.width - 1);
ty = rand() % (tt.height - 1);
} while (tx == x && ty == y);
fill_rect(&t->real, tt.picture,
use_window ? t->real.format : tt.format,
PictOpSrc, x, y, 1, 1,
0, 0, MASK_NONE,
use_window, tx, ty,
red, green, blue, alpha);
pixels[r].x = x;
pixels[r].y = y;
cells[y*t->real.width+x] = color(red, green, blue, alpha);
}
test_init_image(&image, &t->real.shm, tt.format, 1, 1);
for (r = 0; r < reps; r++) {
uint32_t result;
uint32_t x = pixels[r].x;
uint32_t y = pixels[r].y;
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 void clear(struct test_display *dpy, struct test_target *tt)
{
XRenderColor render_color = {0};
XRenderFillRectangle(dpy->dpy, PictOpClear, tt->picture, &render_color,
0, 0, tt->width, tt->height);
}
static void set_mask(struct test_display *t, struct test_target *tt, enum mask mask)
{
XRenderPictureAttributes pa;
switch (mask) {
case MASK_NONE:
pa.poly_edge = PolyEdgeSharp;
break;
default:
pa.poly_edge = PolyEdgeSmooth;
break;
}
XRenderChangePicture(t->dpy, tt->picture, CPPolyEdge, &pa);
}
static void fill(uint32_t *cells,
int x, int y,
int w, int h,
int max_width, int max_height,
uint32_t pixel)
{
if (x < 0)
w += x, x = 0;
if (y < 0)
h += y, y = 0;
if (x >= max_width || y >= max_height)
return;
if (x + w > max_width)
w = max_width - x;
if (y + h > max_height)
h = max_height - y;
if (w <= 0 || h <= 0)
return;
pixman_fill(cells, max_width, 32, x, y, w, h, pixel);
}
static void area_tests(struct test *t, int reps, int sets, enum target target, int use_window)
{
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 using %s source): ",
test_target_name(target),
use_window ? "window" : "pixmap");
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;
int tx, ty, try = 50;
int w, h;
x = rand() % (2*tt.width) - tt.width;
y = rand() % (2*tt.height) - tt.height;
if (use_window) {
do {
w = 1 + rand() % (tt.width - 1);
h = 1 + rand() % (tt.height - 1);
tx = w == tt.width ? 0 : rand() % (tt.width - w);
ty = h == tt.height ? 0 : rand() % (tt.height - h);
} while (((tx+w > x && tx < x+w) &&
(ty+h > y && ty < y+h)) &&
--try);
if (!try)
continue;
} else {
w = 1 + rand() % (2*tt.width);
h = 1 + rand() % (2*tt.height);
tx = ty = 0;
}
fill_rect(&t->real, tt.picture,
use_window ? t->real.format : tt.format,
PictOpSrc, x, y, w, h,
0, 0, MASK_NONE,
use_window, tx, ty,
red, green, blue, alpha);
if (use_window)
fill(cells, tx, ty, w, h, tt.width, tt.height,
color(red, green, blue, alpha));
fill(cells, x, y, w, h, tt.width, tt.height,
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])) {
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 rect_tests(struct test *t,
int dx, int dy,
enum mask mask,
int reps, int sets,
enum target target,
int use_window)
{
struct test_target real, ref;
int r, s;
printf("Testing area fills (offset %dx%d, mask %s) (%s using %s source): ",
dx, dy, mask_name(mask), test_target_name(target),
use_window ? "window" : "pixmap");
fflush(stdout);
test_target_create_render(&t->real, target, &real);
clear(&t->real, &real);
set_mask(&t->real, &real, mask);
test_target_create_render(&t->ref, target, &ref);
clear(&t->ref, &ref);
set_mask(&t->ref, &ref, mask);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
int x, y, w, h;
int op = ops[rand() % sizeof(ops)];
int red = rand() % 0xff;
int green = rand() % 0xff;
int blue = rand() % 0xff;
int alpha = rand() % 0xff;
int tx, ty, try = 50;
do {
x = rand() % (real.width - 1);
y = rand() % (real.height - 1);
w = 1 + rand() % (real.width - x - 1);
h = 1 + rand() % (real.height - y - 1);
tx = w == real.width ? 0 : rand() % (real.width - w);
ty = h == real.height ? 0 : rand() % (real.height - h);
} while (((tx+w > x && tx < x+w) &&
(ty+h > y && ty < y+h)) &&
--try);
if (try) {
fill_rect(&t->real, real.picture,
use_window ? t->real.format : real.format,
op, x, y, w, h,
dx, dy, mask,
use_window, tx, ty,
red, green, blue, alpha);
fill_rect(&t->ref, ref.picture,
use_window ? t->ref.format : ref.format,
op, x, y, w, h,
dx, dy, mask,
use_window, tx, ty,
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 random_trapezoid(XTrapezoid *trap, enum trapezoid trapezoid,
int x1, int y1, int x2, int y2)
{
switch (trapezoid) {
case RECT_ALIGN:
x1 = x1 + rand() % (x2 - x1);
x2 = x1 + rand() % (x2 - x1);
y1 = y1 + rand() % (y2 - y1);
y2 = y1 + rand() % (y2 - y1);
trap->left.p1.x = trap->left.p2.x = x1 << 16;
trap->top = trap->left.p1.y = trap->right.p1.y = y1 << 16;
trap->right.p1.x = trap->right.p2.x = x2 << 16;
trap->bottom = trap->left.p2.y = trap->right.p2.y = y2 << 16;
break;
case RECT_UNALIGN:
x1 <<= 16; x2 <<= 16;
y1 <<= 16; y2 <<= 16;
x1 = x1 + rand() % (x2 - x1);
x2 = x1 + rand() % (x2 - x1);
y1 = y1 + rand() % (y2 - y1);
y2 = y1 + rand() % (y2 - y1);
trap->left.p1.x = trap->left.p2.x = x1;
trap->top = trap->left.p1.y = trap->right.p1.y = y1;
trap->right.p1.x = trap->right.p2.x = x2;
trap->bottom = trap->left.p2.y = trap->right.p2.y = y2;
break;
case GENERAL:
x1 <<= 16; x2 <<= 16;
y1 <<= 16; y2 <<= 16;
trap->top = y1 + rand() % (y2 - y1);
trap->bottom = y1 + rand() % (y2 - y1);
trap->left.p1.x = x1 + rand() % (x2 - x1);
trap->left.p2.x = x1 + rand() % (x2 - x1);
trap->right.p1.x = x1 + rand() % (x2 - x1);
trap->right.p2.x = x1 + rand() % (x2 - x1);
break;
}
}
static void fill_traps(struct test_display *t, Picture p, XRenderPictFormat *format,
uint8_t op, XTrapezoid *traps, int ntraps, enum mask mask,
int srcx, int srcy, int srcw, int srch,
uint8_t red, uint8_t green, uint8_t blue, uint8_t alpha)
{
XRenderColor color;
Drawable tmp;
Picture src;
tmp = XCreatePixmap(t->dpy, DefaultRootWindow(t->dpy),
srcw, srch, format->depth);
src = XRenderCreatePicture(t->dpy, tmp, format, 0, NULL);
color.red = red * alpha;
color.green = green * alpha;
color.blue = blue * alpha;
color.alpha = alpha << 8 | alpha;
XRenderFillRectangle(t->dpy, PictOpSrc, src, &color, 0, 0, srcw, srch);
XRenderCompositeTrapezoids(t->dpy,
op, src, p, mask_format(t->dpy, mask),
srcx, srcy, traps, ntraps);
XRenderFreePicture(t->dpy, src);
XFreePixmap(t->dpy, tmp);
}
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);
set_mask(&t->real, &real, mask);
test_target_create_render(&t->ref, target, &ref);
clear(&t->ref, &ref);
set_mask(&t->ref, &ref, mask);
for (s = 0; s < sets; s++) {
for (r = 0; r < reps; r++) {
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;
int srcx = rand() % 2*real.width - real.width;
int srcy = rand() % 2*real.height - real.height;
int srcw = rand() % real.width;
int srch = rand() % real.height;
for (n = 0; n < num_traps; n++)
random_trapezoid(&traps[n], 0,
0, 0, real.width, real.height);
fill_traps(&t->real, real.picture, real.format,
op, traps, num_traps, mask,
srcx, srcy, srcw, srch,
red, green, blue, alpha);
fill_traps(&t->ref, ref.picture, ref.format,
op, traps, num_traps, mask,
srcx, srcy, srcw, srch,
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);
free(traps);
}
int main(int argc, char **argv)
{
struct test test;
int i, dx, dy;
enum target target;
enum mask mask;
enum trapezoid trapezoid;
test_init(&test, argc, argv);
for (i = 0; i <= DEFAULT_ITERATIONS; i++) {
int reps = 1 << i;
int sets = 1 << (12 - i);
if (sets < 2)
sets = 2;
for (target = TARGET_FIRST; target <= TARGET_LAST; target++) {
pixel_tests(&test, reps, sets, target, 0);
area_tests(&test, reps, sets, target, 0);
for (dy = 0; dy < 1 << 16; dy += 1 << 14)
for (dx = 0; dx < 1 << 16; dx += 1 << 14)
for (mask = MASK_NONE; mask <= MASK_A8; mask++)
rect_tests(&test, dx, dy, mask, reps, sets, target, 0);
if (target != CHILD) {
pixel_tests(&test, reps, sets, target, 1);
area_tests(&test, reps, sets, target, 1);
for (dy = 0; dy < 1 << 16; dy += 1 << 14)
for (dx = 0; dx < 1 << 16; dx += 1 << 14)
for (mask = MASK_NONE; mask <= MASK_A8; mask++)
rect_tests(&test, dx, dy, mask, reps, sets, target, 1);
}
}
for (target = TARGET_FIRST; target <= TARGET_LAST; target++)
for (trapezoid = RECT_ALIGN; trapezoid <= GENERAL; trapezoid++)
trap_tests(&test, mask, trapezoid, reps, sets, target);
}
return 0;
}