static void ricochet(int tiled, int sprite_w, int sprite_h,
int out_w, int out_h, int dump_info)
{
int ret;
int gfx_fd;
int keep_moving;
const int num_surfaces = 3;
uint32_t sprite_handles[num_surfaces];
uint32_t sprite_fb_id[num_surfaces];
int *sprite_x = NULL;
int *sprite_y = NULL;
uint32_t sprite_stride;
uint32_t sprite_size;
uint32_t handles[4],
pitches[4],
offsets[4]; /* we only use [0] */
uint32_t prim_width,
prim_height,
prim_handle,
prim_stride,
prim_size,
prim_fb_id;
struct drm_intel_sprite_colorkey set;
struct connector curr_connector;
drmModeRes *gfx_resources;
struct termios orig_term,
curr_term;
int c_index;
int sprite_index;
unsigned int *sprite_plane_id = NULL;
uint32_t plane_flags = 0;
int *delta_x = NULL,
*delta_y = NULL;
struct timeval stTimeVal;
long long currTime,
prevFlipTime,
prevMoveTime,
deltaFlipTime,
deltaMoveTime,
SleepTime;
char key;
int sprite_plane_count = 0;
int i;
// Open up I915 graphics device
gfx_fd = drmOpen("i915", NULL);
if (gfx_fd < 0) {
printf("Failed to load i915 driver: %s\n", strerror(errno));
return;
}
// Obtain pointer to struct containing graphics resources
gfx_resources = drmModeGetResources(gfx_fd);
if (!gfx_resources) {
printf("drmModeGetResources failed: %s\n", strerror(errno));
return;
}
if (dump_info != 0) {
dump_connectors(gfx_fd, gfx_resources);
dump_crtcs(gfx_fd, gfx_resources);
dump_planes(gfx_fd, gfx_resources);
}
// Save previous terminal settings
if (tcgetattr( 0, &orig_term) != 0) {
printf("tcgetattr failure: %s\n",
strerror(errno));
return;
}
// Set up input to return characters immediately
curr_term = orig_term;
curr_term.c_lflag &= ~(ICANON | ECHO | ECHONL);
curr_term.c_cc[VMIN] = 0; // No minimum number of characters
curr_term.c_cc[VTIME] = 0 ; // Return immediately, even if
// nothing has been entered.
if (tcsetattr( 0, TCSANOW, &curr_term) != 0) {
printf("tcgetattr failure: %s\n", strerror(errno));
return;
}
// Cycle through all connectors and display the flying sprite
// where there are displays attached and the hardware will support it.
for (c_index = 0; c_index < gfx_resources->count_connectors; c_index++) {
curr_connector.id = gfx_resources->connectors[c_index];
// Find the native (preferred) display mode
connector_find_preferred_mode(gfx_fd, gfx_resources, &curr_connector);
if (curr_connector.mode_valid == 0) {
printf("No valid preferred mode detected\n");
goto out;
}
// Determine if sprite hardware is available on pipe
// associated with this connector.
sprite_plane_count = connector_find_plane(gfx_fd, &curr_connector,
&sprite_plane_id);
if (!sprite_plane_count) {
printf("Failed to find sprite plane on crtc\n");
goto out;
}
// Width and height of preferred mode
prim_width = curr_connector.mode.hdisplay;
prim_height = curr_connector.mode.vdisplay;
// Allocate and fill memory for primary surface
ret = prepare_primary_surface(
gfx_fd,
prim_width,
prim_height,
&prim_handle,
&prim_stride,
&prim_size,
tiled);
if (ret != 0) {
printf("Failed to add primary fb (%dx%d): %s\n",
prim_width, prim_height, strerror(errno));
goto out;
}
// Add the primary surface framebuffer
ret = drmModeAddFB(gfx_fd, prim_width, prim_height, 24, 32,
prim_stride, prim_handle, &prim_fb_id);
gem_close(gfx_fd, prim_handle);
if (ret != 0) {
printf("Failed to add primary fb (%dx%d): %s\n",
prim_width, prim_height, strerror(errno));
goto out;
}
// Allocate and fill sprite surfaces
ret = prepare_sprite_surfaces(gfx_fd, sprite_w, sprite_h, num_surfaces,
&sprite_handles[0],
&sprite_stride, &sprite_size,
tiled);
if (ret != 0) {
printf("Preparation of sprite surfaces failed %dx%d\n",
sprite_w, sprite_h);
goto out;
}
// Add the sprite framebuffers
for (sprite_index = 0; sprite_index < num_surfaces; sprite_index++) {
handles[0] = sprite_handles[sprite_index];
handles[1] = handles[0];
handles[2] = handles[0];
handles[3] = handles[0];
pitches[0] = sprite_stride;
pitches[1] = sprite_stride;
pitches[2] = sprite_stride;
pitches[3] = sprite_stride;
memset(offsets, 0, sizeof(offsets));
ret = drmModeAddFB2(gfx_fd, sprite_w, sprite_h,
DRM_FORMAT_XRGB8888,
handles, pitches, offsets,
&sprite_fb_id[sprite_index], plane_flags);
gem_close(gfx_fd, sprite_handles[sprite_index]);
if (ret) {
printf("Failed to add sprite fb (%dx%d): %s\n",
sprite_w, sprite_h, strerror(errno));
sprite_index--;
while (sprite_index >= 0) {
drmModeRmFB(gfx_fd, sprite_fb_id[sprite_index]);
sprite_index--;
}
goto out;
}
}
if (dump_info != 0) {
printf("Displayed Mode Connector struct:\n"
" .id = %d\n"
" .mode_valid = %d\n"
" .crtc = %d\n"
" .pipe = %d\n"
" drmModeModeInfo ...\n"
" .name = %s\n"
" .type = %d\n"
" .flags = %08x\n"
" drmModeEncoder ...\n"
" .encoder_id = %d\n"
" .encoder_type = %d (%s)\n"
" .crtc_id = %d\n"
" .possible_crtcs = %d\n"
" .possible_clones = %d\n"
" drmModeConnector ...\n"
" .connector_id = %d\n"
" .encoder_id = %d\n"
" .connector_type = %d (%s)\n"
" .connector_type_id = %d\n\n",
curr_connector.id,
curr_connector.mode_valid,
curr_connector.crtc,
curr_connector.pipe,
curr_connector.mode.name,
curr_connector.mode.type,
curr_connector.mode.flags,
curr_connector.encoder->encoder_id,
curr_connector.encoder->encoder_type,
kmstest_encoder_type_str(curr_connector.encoder->encoder_type),
curr_connector.encoder->crtc_id,
curr_connector.encoder->possible_crtcs,
curr_connector.encoder->possible_clones,
curr_connector.connector->connector_id,
curr_connector.connector->encoder_id,
curr_connector.connector->connector_type,
kmstest_connector_type_str(curr_connector.connector->connector_type),
curr_connector.connector->connector_type_id);
printf("Sprite surface dimensions = %dx%d\n"
"Sprite output dimensions = %dx%d\n"
"Press any key to continue >\n",
sprite_w, sprite_h, out_w, out_h);
// Wait for a key-press
while( read(0, &key, 1) == 0);
// Purge unread characters
tcflush(0, TCIFLUSH);
}
// Set up the primary display mode
ret = drmModeSetCrtc(gfx_fd, curr_connector.crtc, prim_fb_id,
0, 0, &curr_connector.id, 1, &curr_connector.mode);
if (ret != 0) {
printf("Failed to set mode (%dx%d@%dHz): %s\n",
prim_width, prim_height, curr_connector.mode.vrefresh,
strerror(errno));
continue;
}
// Set the sprite colorkey state
for(i = 0; i < sprite_plane_count; i++) {
set.plane_id = sprite_plane_id[i];
set.min_value = 0;
set.max_value = 0;
set.flags = I915_SET_COLORKEY_NONE;
ret = drmCommandWrite(gfx_fd, DRM_I915_SET_SPRITE_COLORKEY, &set,
sizeof(set));
assert(ret == 0);
}
// Set up sprite output dimensions, initial position, etc.
if (out_w > prim_width / 2)
out_w = prim_width / 2;
if (out_h > prim_height / 2)
out_h = prim_height / 2;
delta_x = (int *) malloc(sprite_plane_count * sizeof(int));
delta_y = (int *) malloc(sprite_plane_count * sizeof(int));
sprite_x = (int *) malloc(sprite_plane_count * sizeof(int));
sprite_y = (int *) malloc(sprite_plane_count * sizeof(int));
/* Initializing the coordinates (x,y) of the available sprites on the
* connector, equally spaced along the diagonal of the rectangle
* {(0,0),(prim_width/2, prim_height/2)}.
*/
for(i = 0; i < sprite_plane_count; i++) {
delta_x[i] = 3;
delta_y[i] = 4;
sprite_x[i] = i * (prim_width / (2 * sprite_plane_count));
sprite_y[i] = i * (prim_height / (2 * sprite_plane_count));
}
currTime = 0;
prevFlipTime = 0; // Will force immediate sprite flip
prevMoveTime = 0; // Will force immediate sprite move
deltaFlipTime = 500000; // Flip sprite surface every 1/2 second
deltaMoveTime = 100000; // Move sprite every 100 ms
sprite_index = num_surfaces - 1;
keep_moving = 1;
// Bounce sprite off the walls
while (keep_moving) {
// Obtain system time in usec.
if (gettimeofday( &stTimeVal, NULL ) != 0)
printf("gettimeofday error: %s\n", strerror(errno));
else
currTime = ((long long)stTimeVal.tv_sec * 1000000) + stTimeVal.tv_usec;
// Check if it's time to flip the sprite surface
if (currTime - prevFlipTime > deltaFlipTime) {
sprite_index = (sprite_index + 1) % num_surfaces;
prevFlipTime = currTime;
}
// Move the sprite on the screen and flip
// the surface if the index has changed
// NB: sprite_w and sprite_h must be 16.16 fixed point, herego << 16
for(i = 0; i < sprite_plane_count; i++) {
if (drmModeSetPlane(gfx_fd, sprite_plane_id[i],
curr_connector.crtc,
sprite_fb_id[sprite_index],
plane_flags,
sprite_x[i], sprite_y[i],
out_w, out_h,
0, 0,
sprite_w << 16, sprite_h << 16))
printf("Failed to enable sprite plane: %s\n",
strerror(errno));
}
// Check if it's time to move the sprite surface
if (currTime - prevMoveTime > deltaMoveTime) {
// Compute the next position for sprite
for(i = 0; i < sprite_plane_count; i++) {
sprite_x[i] += delta_x[i];
sprite_y[i] += delta_y[i];
if (sprite_x[i] < 0) {
sprite_x[i] = 0;
delta_x[i] = -delta_x[i];
}
else if (sprite_x[i] > prim_width - out_w) {
sprite_x[i] = prim_width - out_w;
delta_x[i] = -delta_x[i];
}
if (sprite_y[i] < 0) {
sprite_y[i] = 0;
delta_y[i] = -delta_y[i];
}
else if (sprite_y[i] > prim_height - out_h) {
sprite_y[i] = prim_height - out_h;
delta_y[i] = -delta_y[i];
}
}
prevMoveTime = currTime;
}
// Fetch a key from input (non-blocking)
if (read(0, &key, 1) == 1) {
switch (key) {
case 'q': // Kill the program
case 'Q':
goto out;
break;
case 's': // Slow down sprite movement;
deltaMoveTime = (deltaMoveTime * 100) / 90;
if (deltaMoveTime > 800000) {
deltaMoveTime = 800000;
}
break;
case 'S': // Speed up sprite movement;
deltaMoveTime = (deltaMoveTime * 100) / 110;
if (deltaMoveTime < 2000) {
deltaMoveTime = 2000;
}
break;
case 'f': // Slow down sprite flipping;
deltaFlipTime = (deltaFlipTime * 100) / 90;
if (deltaFlipTime > 1000000)
deltaFlipTime = 1000000;
break;
case 'F': // Speed up sprite flipping;
deltaFlipTime = (deltaFlipTime * 100) / 110;
if (deltaFlipTime < 20000)
deltaFlipTime = 20000;
break;
case 'n': // Next connector
case 'N':
keep_moving = 0;
break;
default:
break;
}
// Purge unread characters
tcflush(0, TCIFLUSH);
}
// Wait for min of flip or move deltas
SleepTime = (deltaFlipTime < deltaMoveTime) ?
deltaFlipTime : deltaMoveTime;
usleep(SleepTime);
}
free(sprite_plane_id);
free(sprite_x);
free(sprite_y);
free(delta_x);
free(delta_y);
sprite_plane_id = NULL;
sprite_plane_count = 0;
sprite_x = sprite_y = delta_x = delta_y = NULL;
}
out:
// Purge unread characters
tcflush(0, TCIFLUSH);
// Restore previous terminal settings
if (tcsetattr( 0, TCSANOW, &orig_term) != 0) {
printf("tcgetattr failure: %s\n", strerror(errno));
return;
}
drmModeFreeResources(gfx_resources);
}
/*
* Re-probe outputs and light up as many as possible.
*
* On Intel, we have two CRTCs that we can drive independently with
* different timings and scanout buffers.
*
* Each connector has a corresponding encoder, except in the SDVO case
* where an encoder may have multiple connectors.
*/
int update_display(void)
{
struct connector *connectors;
int c;
resources = drmModeGetResources(drm_fd);
if (!resources) {
igt_warn("drmModeGetResources failed: %s\n", strerror(errno));
return 0;
}
connectors = calloc(resources->count_connectors,
sizeof(struct connector));
if (!connectors)
return 0;
if (test_preferred_mode || test_all_modes ||
force_mode || specified_disp_id != -1) {
unsigned long crtc_idx_mask = -1UL;
/* Find any connected displays */
for (c = 0; c < resources->count_connectors; c++) {
struct connector *connector = &connectors[c];
connector->id = resources->connectors[c];
if (specified_disp_id != -1 &&
connector->id != specified_disp_id)
continue;
connector_find_preferred_mode(connector->id,
crtc_idx_mask,
specified_mode_num,
connector);
if (!connector->mode_valid)
continue;
set_mode(connector);
if (test_preferred_mode || force_mode ||
specified_mode_num != -1)
crtc_idx_mask &= ~(1 << connector->crtc_idx);
}
}
if (test_stereo_modes) {
for (c = 0; c < resources->count_connectors; c++) {
struct connector *connector = &connectors[c];
connector->id = resources->connectors[c];
if (specified_disp_id != -1 &&
connector->id != specified_disp_id)
continue;
connector_find_preferred_mode(connector->id,
-1UL,
specified_mode_num,
connector);
if (!connector->mode_valid)
continue;
set_stereo_mode(connector);
}
}
free(connectors);
drmModeFreeResources(resources);
return 1;
}
