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|
/*
* Copyright © 2016 Intel Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* IN THE SOFTWARE.
*/
#include "igt.h"
#include "igt_vgem.h"
#include <sys/ioctl.h>
#include <sys/poll.h>
#include <signal.h>
#include <time.h>
IGT_TEST_DESCRIPTION("Basic check of polling for prime/vgem fences.");
static void test_read(int vgem, int i915)
{
struct vgem_bo scratch;
uint32_t handle;
uint32_t *ptr;
int dmabuf, i;
scratch.width = 1024;
scratch.height = 1024;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
handle = prime_fd_to_handle(i915, dmabuf);
close(dmabuf);
ptr = vgem_mmap(vgem, &scratch, PROT_WRITE);
for (i = 0; i < 1024; i++)
ptr[1024*i] = i;
munmap(ptr, scratch.size);
gem_close(vgem, scratch.handle);
for (i = 0; i < 1024; i++) {
uint32_t tmp;
gem_read(i915, handle, 4096*i, &tmp, sizeof(tmp));
igt_assert_eq(tmp, i);
}
gem_close(i915, handle);
}
static void test_fence_read(int i915, int vgem)
{
struct vgem_bo scratch;
uint32_t handle;
uint32_t *ptr;
uint32_t fence;
int dmabuf, i;
int master[2], slave[2];
igt_assert(pipe(master) == 0);
igt_assert(pipe(slave) == 0);
scratch.width = 1024;
scratch.height = 1024;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
handle = prime_fd_to_handle(i915, dmabuf);
close(dmabuf);
igt_fork(child, 1) {
for (i = 0; i < 1024; i++) {
uint32_t tmp;
gem_read(i915, handle, 4096*i, &tmp, sizeof(tmp));
igt_assert_eq(tmp, 0);
}
write(master[1], &child, sizeof(child));
read(slave[0], &child, sizeof(child));
for (i = 0; i < 1024; i++) {
uint32_t tmp;
gem_read(i915, handle, 4096*i, &tmp, sizeof(tmp));
igt_assert_eq(tmp, i);
}
gem_close(i915, handle);
}
read(master[0], &i, sizeof(i));
fence = vgem_fence_attach(vgem, &scratch, VGEM_FENCE_WRITE);
write(slave[1], &i, sizeof(i));
ptr = vgem_mmap(vgem, &scratch, PROT_WRITE);
for (i = 0; i < 1024; i++)
ptr[1024*i] = i;
munmap(ptr, scratch.size);
vgem_fence_signal(vgem, fence);
gem_close(vgem, scratch.handle);
igt_waitchildren();
close(master[0]);
close(master[1]);
close(slave[0]);
close(slave[1]);
}
static void test_fence_mmap(int i915, int vgem)
{
struct vgem_bo scratch;
uint32_t handle;
uint32_t *ptr;
uint32_t fence;
int dmabuf, i;
int master[2], slave[2];
igt_assert(pipe(master) == 0);
igt_assert(pipe(slave) == 0);
scratch.width = 1024;
scratch.height = 1024;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
handle = prime_fd_to_handle(i915, dmabuf);
close(dmabuf);
igt_fork(child, 1) {
ptr = gem_mmap__gtt(i915, handle, 4096*1024, PROT_READ);
gem_set_domain(i915, handle, I915_GEM_DOMAIN_GTT, 0);
for (i = 0; i < 1024; i++)
igt_assert_eq(ptr[1024*i], 0);
write(master[1], &child, sizeof(child));
read(slave[0], &child, sizeof(child));
gem_set_domain(i915, handle, I915_GEM_DOMAIN_GTT, 0);
for (i = 0; i < 1024; i++)
igt_assert_eq(ptr[1024*i], i);
gem_close(i915, handle);
}
read(master[0], &i, sizeof(i));
fence = vgem_fence_attach(vgem, &scratch, VGEM_FENCE_WRITE);
write(slave[1], &i, sizeof(i));
ptr = vgem_mmap(vgem, &scratch, PROT_WRITE);
for (i = 0; i < 1024; i++)
ptr[1024*i] = i;
munmap(ptr, scratch.size);
vgem_fence_signal(vgem, fence);
gem_close(vgem, scratch.handle);
igt_waitchildren();
close(master[0]);
close(master[1]);
close(slave[0]);
close(slave[1]);
}
static void test_write(int vgem, int i915)
{
struct vgem_bo scratch;
uint32_t handle;
uint32_t *ptr;
int dmabuf, i;
scratch.width = 1024;
scratch.height = 1024;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
handle = prime_fd_to_handle(i915, dmabuf);
close(dmabuf);
ptr = vgem_mmap(vgem, &scratch, PROT_READ);
gem_close(vgem, scratch.handle);
for (i = 0; i < 1024; i++)
gem_write(i915, handle, 4096*i, &i, sizeof(i));
gem_close(i915, handle);
for (i = 0; i < 1024; i++)
igt_assert_eq(ptr[1024*i], i);
munmap(ptr, scratch.size);
}
static void test_gtt(int vgem, int i915)
{
struct vgem_bo scratch;
uint32_t handle;
uint32_t *ptr;
int dmabuf, i;
scratch.width = 1024;
scratch.height = 1024;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
handle = prime_fd_to_handle(i915, dmabuf);
close(dmabuf);
ptr = gem_mmap__gtt(i915, handle, scratch.size, PROT_WRITE);
for (i = 0; i < 1024; i++)
ptr[1024*i] = i;
munmap(ptr, scratch.size);
ptr = vgem_mmap(vgem, &scratch, PROT_READ | PROT_WRITE);
for (i = 0; i < 1024; i++) {
igt_assert_eq(ptr[1024*i], i);
ptr[1024*i] = ~i;
}
munmap(ptr, scratch.size);
ptr = gem_mmap__gtt(i915, handle, scratch.size, PROT_READ);
for (i = 0; i < 1024; i++)
igt_assert_eq(ptr[1024*i], ~i);
munmap(ptr, scratch.size);
gem_close(i915, handle);
gem_close(vgem, scratch.handle);
}
static void test_shrink(int vgem, int i915)
{
struct vgem_bo scratch = {
.width = 1024,
.height = 1024,
.bpp = 32
};
int dmabuf;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
gem_close(vgem, scratch.handle);
scratch.handle = prime_fd_to_handle(i915, dmabuf);
close(dmabuf);
/* Populate the i915_bo->pages. */
gem_set_domain(i915, scratch.handle, I915_GEM_DOMAIN_GTT, 0);
/* Now evict them, establishing the link from i915:shrinker to vgem. */
igt_drop_caches_set(i915, DROP_SHRINK_ALL);
gem_close(i915, scratch.handle);
}
static bool is_coherent(int i915)
{
int val = 1; /* by default, we assume GTT is coherent, hence the test */
struct drm_i915_getparam gp = {
gp.param = 52, /* GTT_COHERENT */
gp.value = &val,
};
ioctl(i915, DRM_IOCTL_I915_GETPARAM, &gp);
return val;
}
static void test_gtt_interleaved(int vgem, int i915)
{
struct vgem_bo scratch;
uint32_t handle;
uint32_t *ptr, *gtt;
int dmabuf, i;
igt_require(is_coherent(i915));
scratch.width = 1024;
scratch.height = 1024;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
handle = prime_fd_to_handle(i915, dmabuf);
close(dmabuf);
/* This assumes that GTT is perfectedly coherent. On certain machines,
* it is possible for a direct acces to bypass the GTT indirection.
*
* This test may fail. It tells us how far userspace can trust
* concurrent dmabuf/i915 access. In the future, we may have a kernel
* param to indicate whether or not this interleaving is possible.
* However, the mmaps may be passed around to third parties that do
* not know about the shortcommings...
*/
ptr = vgem_mmap(vgem, &scratch, PROT_WRITE);
gtt = gem_mmap__gtt(i915, handle, scratch.size, PROT_WRITE);
for (i = 0; i < 1024; i++) {
gtt[1024*i] = i;
/* The read from WC should act as a flush for the GTT wcb */
igt_assert_eq(ptr[1024*i], i);
ptr[1024*i] = ~i;
/* The read from GTT should act as a flush for the WC wcb */
igt_assert_eq(gtt[1024*i], ~i);
}
munmap(gtt, scratch.size);
munmap(ptr, scratch.size);
gem_close(i915, handle);
gem_close(vgem, scratch.handle);
}
static bool prime_busy(int fd, bool excl)
{
struct pollfd pfd = { .fd = fd, .events = excl ? POLLOUT : POLLIN };
return poll(&pfd, 1, 0) == 0;
}
static void work(int i915, int dmabuf, unsigned ring, uint32_t flags)
{
const int SCRATCH = 0;
const int BATCH = 1;
const int gen = intel_gen(intel_get_drm_devid(i915));
struct drm_i915_gem_exec_object2 obj[2];
struct drm_i915_gem_relocation_entry store[1024+1];
struct drm_i915_gem_execbuffer2 execbuf;
unsigned size = ALIGN(ARRAY_SIZE(store)*16 + 4, 4096);
bool read_busy, write_busy;
uint32_t *batch, *bbe;
int i, count;
memset(&execbuf, 0, sizeof(execbuf));
execbuf.buffers_ptr = (uintptr_t)obj;
execbuf.buffer_count = 2;
execbuf.flags = ring | flags;
if (gen < 6)
execbuf.flags |= I915_EXEC_SECURE;
memset(obj, 0, sizeof(obj));
obj[SCRATCH].handle = prime_fd_to_handle(i915, dmabuf);
obj[BATCH].handle = gem_create(i915, size);
obj[BATCH].relocs_ptr = (uintptr_t)store;
obj[BATCH].relocation_count = ARRAY_SIZE(store);
memset(store, 0, sizeof(store));
batch = gem_mmap__wc(i915, obj[BATCH].handle, 0, size, PROT_WRITE);
gem_set_domain(i915, obj[BATCH].handle,
I915_GEM_DOMAIN_GTT, I915_GEM_DOMAIN_GTT);
i = 0;
for (count = 0; count < 1024; count++) {
store[count].target_handle = obj[SCRATCH].handle;
store[count].presumed_offset = -1;
store[count].offset = sizeof(uint32_t) * (i + 1);
store[count].delta = sizeof(uint32_t) * count;
store[count].read_domains = I915_GEM_DOMAIN_INSTRUCTION;
store[count].write_domain = I915_GEM_DOMAIN_INSTRUCTION;
batch[i] = MI_STORE_DWORD_IMM | (gen < 6 ? 1 << 22 : 0);
if (gen >= 8) {
batch[++i] = 0;
batch[++i] = 0;
} else if (gen >= 4) {
batch[++i] = 0;
batch[++i] = 0;
store[count].offset += sizeof(uint32_t);
} else {
batch[i]--;
batch[++i] = 0;
}
batch[++i] = count;
i++;
}
bbe = &batch[i];
store[count].target_handle = obj[BATCH].handle; /* recurse */
store[count].presumed_offset = 0;
store[count].offset = sizeof(uint32_t) * (i + 1);
store[count].delta = 0;
store[count].read_domains = I915_GEM_DOMAIN_COMMAND;
store[count].write_domain = 0;
batch[i] = MI_BATCH_BUFFER_START;
if (gen >= 8) {
batch[i] |= 1 << 8 | 1;
batch[++i] = 0;
batch[++i] = 0;
} else if (gen >= 6) {
batch[i] |= 1 << 8;
batch[++i] = 0;
} else {
batch[i] |= 2 << 6;
batch[++i] = 0;
if (gen < 4) {
batch[i] |= 1;
store[count].delta = 1;
}
}
i++;
igt_assert(i < size/sizeof(*batch));
igt_require(__gem_execbuf(i915, &execbuf) == 0);
gem_close(i915, obj[BATCH].handle);
gem_close(i915, obj[SCRATCH].handle);
write_busy = prime_busy(dmabuf, false);
read_busy = prime_busy(dmabuf, true);
*bbe = MI_BATCH_BUFFER_END;
__sync_synchronize();
munmap(batch, size);
igt_assert(read_busy && write_busy);
}
static void test_busy(int i915, int vgem, unsigned ring, uint32_t flags)
{
struct vgem_bo scratch;
struct timespec tv;
uint32_t *ptr;
int dmabuf;
int i;
scratch.width = 1024;
scratch.height = 1;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
work(i915, dmabuf, ring, flags);
/* Calling busy in a loop should be enough to flush the rendering */
memset(&tv, 0, sizeof(tv));
while (prime_busy(dmabuf, false))
igt_assert(igt_seconds_elapsed(&tv) < 10);
ptr = vgem_mmap(vgem, &scratch, PROT_READ);
for (i = 0; i < 1024; i++)
igt_assert_eq_u32(ptr[i], i);
munmap(ptr, 4096);
gem_close(vgem, scratch.handle);
close(dmabuf);
}
static void test_wait(int i915, int vgem, unsigned ring, uint32_t flags)
{
struct vgem_bo scratch;
struct pollfd pfd;
uint32_t *ptr;
int i;
scratch.width = 1024;
scratch.height = 1;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
pfd.fd = prime_handle_to_fd(vgem, scratch.handle);
work(i915, pfd.fd, ring, flags);
pfd.events = POLLIN;
igt_assert_eq(poll(&pfd, 1, 10000), 1);
ptr = vgem_mmap(vgem, &scratch, PROT_READ);
for (i = 0; i < 1024; i++)
igt_assert_eq_u32(ptr[i], i);
munmap(ptr, 4096);
gem_close(vgem, scratch.handle);
close(pfd.fd);
}
static void test_sync(int i915, int vgem, unsigned ring, uint32_t flags)
{
struct vgem_bo scratch;
uint32_t *ptr;
int dmabuf;
int i;
scratch.width = 1024;
scratch.height = 1;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
ptr = mmap(NULL, scratch.size, PROT_READ, MAP_SHARED, dmabuf, 0);
igt_assert(ptr != MAP_FAILED);
gem_close(vgem, scratch.handle);
work(i915, dmabuf, ring, flags);
prime_sync_start(dmabuf, false);
for (i = 0; i < 1024; i++)
igt_assert_eq_u32(ptr[i], i);
prime_sync_end(dmabuf, false);
close(dmabuf);
munmap(ptr, scratch.size);
}
static void test_fence_wait(int i915, int vgem, unsigned ring, unsigned flags)
{
struct vgem_bo scratch;
uint32_t fence;
uint32_t *ptr;
int dmabuf;
scratch.width = 1024;
scratch.height = 1;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
fence = vgem_fence_attach(vgem, &scratch, VGEM_FENCE_WRITE);
igt_assert(prime_busy(dmabuf, false));
gem_close(vgem, scratch.handle);
ptr = mmap(NULL, scratch.size, PROT_READ, MAP_SHARED, dmabuf, 0);
igt_assert(ptr != MAP_FAILED);
igt_fork(child, 1)
work(i915, dmabuf, ring, flags);
sleep(1);
/* Check for invalidly completing the task early */
for (int i = 0; i < 1024; i++)
igt_assert_eq_u32(ptr[i], 0);
igt_assert(prime_busy(dmabuf, false));
vgem_fence_signal(vgem, fence);
igt_waitchildren();
/* But after signaling and waiting, it should be done */
prime_sync_start(dmabuf, false);
for (int i = 0; i < 1024; i++)
igt_assert_eq_u32(ptr[i], i);
prime_sync_end(dmabuf, false);
close(dmabuf);
munmap(ptr, scratch.size);
}
static void test_fence_hang(int i915, int vgem, unsigned flags)
{
struct vgem_bo scratch;
uint32_t *ptr;
int dmabuf;
int i;
scratch.width = 1024;
scratch.height = 1;
scratch.bpp = 32;
vgem_create(vgem, &scratch);
dmabuf = prime_handle_to_fd(vgem, scratch.handle);
vgem_fence_attach(vgem, &scratch, flags | WIP_VGEM_FENCE_NOTIMEOUT);
ptr = mmap(NULL, scratch.size, PROT_READ, MAP_SHARED, dmabuf, 0);
igt_assert(ptr != MAP_FAILED);
gem_close(vgem, scratch.handle);
work(i915, dmabuf, I915_EXEC_DEFAULT, 0);
/* The work should have been cancelled */
prime_sync_start(dmabuf, false);
for (i = 0; i < 1024; i++)
igt_assert_eq_u32(ptr[i], 0);
prime_sync_end(dmabuf, false);
close(dmabuf);
munmap(ptr, scratch.size);
}
static bool has_prime_export(int fd)
{
uint64_t value;
if (drmGetCap(fd, DRM_CAP_PRIME, &value))
return false;
return value & DRM_PRIME_CAP_EXPORT;
}
static bool has_prime_import(int fd)
{
uint64_t value;
if (drmGetCap(fd, DRM_CAP_PRIME, &value))
return false;
return value & DRM_PRIME_CAP_IMPORT;
}
static uint32_t set_fb_on_crtc(int fd, int pipe, struct vgem_bo *bo, uint32_t fb_id)
{
drmModeRes *resources = drmModeGetResources(fd);
struct drm_mode_modeinfo *modes = malloc(4096*sizeof(*modes));
uint32_t encoders[32];
for (int o = 0; o < resources->count_connectors; o++) {
struct drm_mode_get_connector conn;
struct drm_mode_crtc set;
int e, m;
memset(&conn, 0, sizeof(conn));
conn.connector_id = resources->connectors[o];
drmIoctl(fd, DRM_IOCTL_MODE_GETCONNECTOR, &conn);
if (!conn.count_modes)
continue;
igt_assert(conn.count_modes <= 4096);
igt_assert(conn.count_encoders <= 32);
conn.modes_ptr = (uintptr_t)modes;
conn.encoders_ptr = (uintptr_t)encoders;
conn.count_props = 0;
do_or_die(drmIoctl(fd, DRM_IOCTL_MODE_GETCONNECTOR, &conn));
for (e = 0; e < conn.count_encoders; e++) {
struct drm_mode_get_encoder enc;
memset(&enc, 0, sizeof(enc));
enc.encoder_id = encoders[e];
drmIoctl(fd, DRM_IOCTL_MODE_GETENCODER, &enc);
if (enc.possible_crtcs & (1 << pipe))
break;
}
if (e == conn.count_encoders)
continue;
for (m = 0; m < conn.count_modes; m++) {
if (modes[m].hdisplay <= bo->width &&
modes[m].vdisplay <= bo->height)
break;
}
if (m == conn.count_modes)
continue;
memset(&set, 0, sizeof(set));
set.crtc_id = resources->crtcs[pipe];
set.fb_id = fb_id;
set.set_connectors_ptr = (uintptr_t)&conn.connector_id;
set.count_connectors = 1;
set.mode = modes[m];
set.mode_valid = 1;
if (drmIoctl(fd, DRM_IOCTL_MODE_SETCRTC, &set) == 0) {
drmModeFreeResources(resources);
return set.crtc_id;
}
}
drmModeFreeResources(resources);
return 0;
}
static inline uint32_t pipe_select(int pipe)
{
if (pipe > 1)
return pipe << DRM_VBLANK_HIGH_CRTC_SHIFT;
else if (pipe > 0)
return DRM_VBLANK_SECONDARY;
else
return 0;
}
static unsigned get_vblank(int fd, int pipe, unsigned flags)
{
union drm_wait_vblank vbl;
memset(&vbl, 0, sizeof(vbl));
vbl.request.type = DRM_VBLANK_RELATIVE | pipe_select(pipe) | flags;
if (drmIoctl(fd, DRM_IOCTL_WAIT_VBLANK, &vbl))
return 0;
return vbl.reply.sequence;
}
static void sighandler(int sig)
{
}
static void flip_to_vgem(int i915, int vgem,
struct vgem_bo *bo,
uint32_t fb_id,
uint32_t crtc_id,
unsigned hang,
const char *name)
{
const struct timespec tv = { 1, 0 };
struct pollfd pfd = { i915, POLLIN };
struct drm_event_vblank vbl;
uint32_t fence;
fence = vgem_fence_attach(vgem, bo, VGEM_FENCE_WRITE | hang);
igt_fork(child, 1) {
do_or_die(drmModePageFlip(i915, crtc_id, fb_id,
DRM_MODE_PAGE_FLIP_EVENT, &fb_id));
kill(getppid(), SIGHUP);
/* Check we don't flip before the fence is ready */
for (int n = 0; n < 5; n++) {
igt_assert_f(poll(&pfd, 1, 0) == 0,
"flip to %s completed whilst busy\n",
name);
get_vblank(i915, 0, DRM_VBLANK_NEXTONMISS);
}
}
igt_assert_f(nanosleep(&tv, NULL) == -1,
"flip to busy %s blocked\n", name);
/* And then the flip is completed as soon as it is ready */
if (!hang) {
union drm_wait_vblank wait;
memset(&wait, 0, sizeof(wait));
wait.request.type = DRM_VBLANK_RELATIVE | pipe_select(0);
wait.request.sequence = 10;
do_or_die(drmIoctl(i915, DRM_IOCTL_WAIT_VBLANK, &wait));
vgem_fence_signal(vgem, fence);
get_vblank(i915, 0, DRM_VBLANK_NEXTONMISS);
igt_assert_eq(poll(&pfd, 1, 0), 1);
}
/* Even if hung, the flip must complete *eventually* */
igt_set_timeout(20, "Ignored hang"); /* XXX lower fail threshold? */
igt_assert_eq(read(i915, &vbl, sizeof(vbl)), sizeof(vbl));
igt_reset_timeout();
igt_waitchildren();
}
static void test_flip(int i915, int vgem, unsigned hang)
{
struct vgem_bo bo[2];
uint32_t fb_id[2], handle[2], crtc_id;
signal(SIGHUP, sighandler);
for (int i = 0; i < 2; i++) {
int fd;
bo[i].width = 1024;
bo[i].height = 768;
bo[i].bpp = 32;
vgem_create(vgem, &bo[i]);
fd = prime_handle_to_fd(vgem, bo[i].handle);
handle[i] = prime_fd_to_handle(i915, fd);
igt_assert(handle[i]);
close(fd);
do_or_die(__kms_addfb(i915, handle[i],
bo[i].width, bo[i].height, bo[i].pitch,
DRM_FORMAT_XRGB8888, I915_TILING_NONE, NULL,
LOCAL_DRM_MODE_FB_MODIFIERS, &fb_id[i]));
igt_assert(fb_id[i]);
}
igt_require((crtc_id = set_fb_on_crtc(i915, 0, &bo[0], fb_id[0])));
/* Bind both fb for use by flipping */
for (int i = 1; i >= 0; i--) {
struct drm_event_vblank vbl;
do_or_die(drmModePageFlip(i915, crtc_id, fb_id[i],
DRM_MODE_PAGE_FLIP_EVENT, &fb_id[i]));
igt_assert_eq(read(i915, &vbl, sizeof(vbl)), sizeof(vbl));
}
/* Schedule a flip to wait upon the frontbuffer vgem being written */
flip_to_vgem(i915, vgem, &bo[0], fb_id[0], crtc_id, hang, "front");
/* Schedule a flip to wait upon the backbuffer vgem being written */
flip_to_vgem(i915, vgem, &bo[1], fb_id[1], crtc_id, hang, "back");
for (int i = 0; i < 2; i++) {
do_or_die(drmModeRmFB(i915, fb_id[i]));
gem_close(i915, handle[i]);
gem_close(vgem, bo[i].handle);
}
signal(SIGHUP, SIG_DFL);
}
igt_main
{
const struct intel_execution_engine *e;
int i915 = -1;
int vgem = -1;
igt_fixture {
vgem = drm_open_driver(DRIVER_VGEM);
igt_require(has_prime_export(vgem));
i915 = drm_open_driver_master(DRIVER_INTEL);
igt_require_gem(i915);
igt_require(has_prime_import(i915));
gem_require_mmap_wc(i915);
}
igt_subtest("basic-read")
test_read(vgem, i915);
igt_subtest("basic-write")
test_write(vgem, i915);
igt_subtest("basic-gtt")
test_gtt(vgem, i915);
igt_subtest("shrink")
test_shrink(vgem, i915);
igt_subtest("coherency-gtt")
test_gtt_interleaved(vgem, i915);
for (e = intel_execution_engines; e->name; e++) {
igt_subtest_f("%ssync-%s",
e->exec_id == 0 ? "basic-" : "",
e->name) {
gem_require_ring(i915, e->exec_id | e->flags);
igt_require(gem_can_store_dword(i915, e->exec_id) | e->flags);
gem_quiescent_gpu(i915);
test_sync(i915, vgem, e->exec_id, e->flags);
}
}
for (e = intel_execution_engines; e->name; e++) {
igt_subtest_f("%sbusy-%s",
e->exec_id == 0 ? "basic-" : "",
e->name) {
gem_require_ring(i915, e->exec_id | e->flags);
igt_require(gem_can_store_dword(i915, e->exec_id) | e->flags);
gem_quiescent_gpu(i915);
test_busy(i915, vgem, e->exec_id, e->flags);
}
}
for (e = intel_execution_engines; e->name; e++) {
igt_subtest_f("%swait-%s",
e->exec_id == 0 ? "basic-" : "",
e->name) {
gem_require_ring(i915, e->exec_id | e->flags);
igt_require(gem_can_store_dword(i915, e->exec_id) | e->flags);
gem_quiescent_gpu(i915);
test_wait(i915, vgem, e->exec_id, e->flags);
}
}
/* Fence testing */
igt_subtest_group {
igt_fixture {
igt_require(vgem_has_fences(vgem));
}
igt_subtest("basic-fence-read")
test_fence_read(i915, vgem);
igt_subtest("basic-fence-mmap")
test_fence_mmap(i915, vgem);
for (e = intel_execution_engines; e->name; e++) {
igt_subtest_f("%sfence-wait-%s",
e->exec_id == 0 ? "basic-" : "",
e->name) {
gem_require_ring(i915, e->exec_id | e->flags);
igt_require(gem_can_store_dword(i915, e->exec_id) | e->flags);
gem_quiescent_gpu(i915);
test_fence_wait(i915, vgem, e->exec_id, e->flags);
}
}
igt_subtest("basic-fence-flip")
test_flip(i915, vgem, 0);
igt_subtest_group {
igt_fixture {
igt_require(vgem_fence_has_flag(vgem, WIP_VGEM_FENCE_NOTIMEOUT));
}
igt_subtest("fence-read-hang")
test_fence_hang(i915, vgem, 0);
igt_subtest("fence-write-hang")
test_fence_hang(i915, vgem, VGEM_FENCE_WRITE);
igt_subtest("fence-flip-hang")
test_flip(i915, vgem, WIP_VGEM_FENCE_NOTIMEOUT);
}
}
igt_fixture {
close(i915);
close(vgem);
}
}
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