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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 <time.h>
#include <signal.h>
#include <pthread.h>
#include <sys/poll.h>
#include <i915_drm.h>
#include "igt_core.h"
#include "drmtest.h"
#include "igt_device.h"
#include "igt_dummyload.h"
#include "igt_gt.h"
#include "intel_chipset.h"
#include "intel_reg.h"
#include "ioctl_wrappers.h"
#include "sw_sync.h"
#include "igt_vgem.h"
/**
* SECTION:igt_dummyload
* @short_description: Library for submitting GPU workloads
* @title: Dummyload
* @include: igt.h
*
* A lot of igt testcases need some GPU workload to make sure a race window is
* big enough. Unfortunately having a fixed amount of workload leads to
* spurious test failures or overly long runtimes on some fast/slow platforms.
* This library contains functionality to submit GPU workloads that should
* consume exactly a specific amount of time.
*/
#define LOCAL_I915_EXEC_BSD_SHIFT (13)
#define LOCAL_I915_EXEC_BSD_MASK (3 << LOCAL_I915_EXEC_BSD_SHIFT)
#define ENGINE_MASK (I915_EXEC_RING_MASK | LOCAL_I915_EXEC_BSD_MASK)
#define MI_ARB_CHK (0x5 << 23)
static const int BATCH_SIZE = 4096;
static IGT_LIST(spin_list);
static pthread_mutex_t list_lock = PTHREAD_MUTEX_INITIALIZER;
static void
fill_reloc(struct drm_i915_gem_relocation_entry *reloc,
uint32_t gem_handle, uint32_t offset,
uint32_t read_domains, uint32_t write_domains)
{
reloc->target_handle = gem_handle;
reloc->offset = offset * sizeof(uint32_t);
reloc->read_domains = read_domains;
reloc->write_domain = write_domains;
}
static int
emit_recursive_batch(igt_spin_t *spin,
int fd, const struct igt_spin_factory *opts)
{
#define SCRATCH 0
#define BATCH 1
const int gen = intel_gen(intel_get_drm_devid(fd));
struct drm_i915_gem_relocation_entry relocs[2], *r;
struct drm_i915_gem_execbuffer2 *execbuf;
struct drm_i915_gem_exec_object2 *obj;
unsigned int engines[16];
unsigned int nengine;
int fence_fd = -1;
uint32_t *batch, *batch_start;
int i;
nengine = 0;
if (opts->engine == ALL_ENGINES) {
unsigned int engine;
for_each_physical_engine(fd, engine) {
if (opts->flags & IGT_SPIN_POLL_RUN &&
!gem_can_store_dword(fd, engine))
continue;
engines[nengine++] = engine;
}
} else {
engines[nengine++] = opts->engine;
}
igt_require(nengine);
memset(&spin->execbuf, 0, sizeof(spin->execbuf));
execbuf = &spin->execbuf;
memset(spin->obj, 0, sizeof(spin->obj));
obj = spin->obj;
memset(relocs, 0, sizeof(relocs));
obj[BATCH].handle = gem_create(fd, BATCH_SIZE);
batch = __gem_mmap__wc(fd, obj[BATCH].handle,
0, BATCH_SIZE, PROT_WRITE);
if (!batch)
batch = gem_mmap__gtt(fd, obj[BATCH].handle,
BATCH_SIZE, PROT_WRITE);
gem_set_domain(fd, obj[BATCH].handle,
I915_GEM_DOMAIN_GTT, I915_GEM_DOMAIN_GTT);
execbuf->buffer_count++;
batch_start = batch;
if (opts->dependency) {
igt_assert(!(opts->flags & IGT_SPIN_POLL_RUN));
/* dummy write to dependency */
obj[SCRATCH].handle = opts->dependency;
fill_reloc(&relocs[obj[BATCH].relocation_count++],
opts->dependency, 1020,
I915_GEM_DOMAIN_RENDER,
I915_GEM_DOMAIN_RENDER);
execbuf->buffer_count++;
} else if (opts->flags & IGT_SPIN_POLL_RUN) {
unsigned int offset;
igt_assert(!opts->dependency);
if (gen == 4 || gen == 5) {
execbuf->flags |= I915_EXEC_SECURE;
igt_require(__igt_device_set_master(fd) == 0);
}
spin->poll_handle = gem_create(fd, 4096);
if (__gem_set_caching(fd, spin->poll_handle,
I915_CACHING_CACHED) == 0)
spin->running = __gem_mmap__cpu(fd, spin->poll_handle,
0, 4096,
PROT_READ | PROT_WRITE);
else
spin->running = __gem_mmap__wc(fd, spin->poll_handle,
0, 4096,
PROT_READ | PROT_WRITE);
igt_assert(spin->running);
igt_assert_eq(*spin->running, 0);
*batch++ = MI_STORE_DWORD_IMM | (gen < 6 ? 1 << 22 : 0);
if (gen >= 8) {
offset = 1;
*batch++ = 0;
*batch++ = 0;
} else if (gen >= 4) {
offset = 2;
*batch++ = 0;
*batch++ = 0;
} else {
offset = 1;
batch[-1]--;
*batch++ = 0;
}
*batch++ = 1;
obj[SCRATCH].handle = spin->poll_handle;
fill_reloc(&relocs[obj[BATCH].relocation_count++],
spin->poll_handle, offset, 0, 0);
execbuf->buffer_count++;
}
spin->batch = batch = batch_start + 64 / sizeof(*batch);
spin->handle = obj[BATCH].handle;
/* Allow ourselves to be preempted */
if (!(opts->flags & IGT_SPIN_NO_PREEMPTION))
*batch++ = MI_ARB_CHK;
/* Pad with a few nops so that we do not completely hog the system.
*
* Part of the attraction of using a recursive batch is that it is
* hard on the system (executing the "function" call is apparently
* quite expensive). However, the GPU may hog the entire system for
* a few minutes, preventing even NMI. Quite why this is so is unclear,
* but presumably it relates to the PM_INTRMSK workaround on gen6/gen7.
* If we give the system a break by having the GPU execute a few nops
* between function calls, that appears enough to keep SNB out of
* trouble. See https://bugs.freedesktop.org/show_bug.cgi?id=102262
*/
if (!(opts->flags & IGT_SPIN_FAST))
batch += 1000;
/* recurse */
r = &relocs[obj[BATCH].relocation_count++];
r->target_handle = obj[BATCH].handle;
r->offset = (batch + 1 - batch_start) * sizeof(*batch);
r->read_domains = I915_GEM_DOMAIN_COMMAND;
r->delta = 64;
if (gen >= 8) {
*batch++ = MI_BATCH_BUFFER_START | 1 << 8 | 1;
*batch++ = r->delta;
*batch++ = 0;
} else if (gen >= 6) {
*batch++ = MI_BATCH_BUFFER_START | 1 << 8;
*batch++ = r->delta;
} else {
*batch++ = MI_BATCH_BUFFER_START | 2 << 6;
if (gen < 4)
r->delta |= 1;
*batch = r->delta;
batch++;
}
obj[BATCH].relocs_ptr = to_user_pointer(relocs);
execbuf->buffers_ptr = to_user_pointer(obj +
(2 - execbuf->buffer_count));
execbuf->rsvd1 = opts->ctx;
if (opts->flags & IGT_SPIN_FENCE_OUT)
execbuf->flags |= I915_EXEC_FENCE_OUT;
for (i = 0; i < nengine; i++) {
execbuf->flags &= ~ENGINE_MASK;
execbuf->flags |= engines[i];
gem_execbuf_wr(fd, execbuf);
if (opts->flags & IGT_SPIN_FENCE_OUT) {
int _fd = execbuf->rsvd2 >> 32;
igt_assert(_fd >= 0);
if (fence_fd == -1) {
fence_fd = _fd;
} else {
int old_fd = fence_fd;
fence_fd = sync_fence_merge(old_fd, _fd);
close(old_fd);
close(_fd);
}
igt_assert(fence_fd >= 0);
}
}
/* Make it easier for callers to resubmit. */
obj[BATCH].relocation_count = 0;
obj[BATCH].relocs_ptr = 0;
obj[SCRATCH].flags = EXEC_OBJECT_PINNED;
obj[BATCH].flags = EXEC_OBJECT_PINNED;
return fence_fd;
}
static igt_spin_t *
spin_batch_create(int fd, const struct igt_spin_factory *opts)
{
igt_spin_t *spin;
spin = calloc(1, sizeof(struct igt_spin));
igt_assert(spin);
spin->out_fence = emit_recursive_batch(spin, fd, opts);
pthread_mutex_lock(&list_lock);
igt_list_add(&spin->link, &spin_list);
pthread_mutex_unlock(&list_lock);
return spin;
}
igt_spin_t *
__igt_spin_batch_factory(int fd, const struct igt_spin_factory *opts)
{
return spin_batch_create(fd, opts);
}
/**
* igt_spin_batch_factory:
* @fd: open i915 drm file descriptor
* @opts: controlling options such as context, engine, dependencies etc
*
* Start a recursive batch on a ring. Immediately returns a #igt_spin_t that
* contains the batch's handle that can be waited upon. The returned structure
* must be passed to igt_spin_batch_free() for post-processing.
*
* Returns:
* Structure with helper internal state for igt_spin_batch_free().
*/
igt_spin_t *
igt_spin_batch_factory(int fd, const struct igt_spin_factory *opts)
{
igt_spin_t *spin;
igt_require_gem(fd);
if (opts->engine != ALL_ENGINES) {
gem_require_ring(fd, opts->engine);
if (opts->flags & IGT_SPIN_POLL_RUN)
igt_require(gem_can_store_dword(fd, opts->engine));
}
spin = spin_batch_create(fd, opts);
igt_assert(gem_bo_busy(fd, spin->handle));
if (opts->flags & IGT_SPIN_FENCE_OUT) {
struct pollfd pfd = { spin->out_fence, POLLIN };
igt_assert(poll(&pfd, 1, 0) == 0);
}
return spin;
}
static void notify(union sigval arg)
{
igt_spin_t *spin = arg.sival_ptr;
igt_spin_batch_end(spin);
}
/**
* igt_spin_batch_set_timeout:
* @spin: spin batch state from igt_spin_batch_new()
* @ns: amount of time in nanoseconds the batch continues to execute
* before finishing.
*
* Specify a timeout. This ends the recursive batch associated with @spin after
* the timeout has elapsed.
*/
void igt_spin_batch_set_timeout(igt_spin_t *spin, int64_t ns)
{
timer_t timer;
struct sigevent sev;
struct itimerspec its;
igt_assert(ns > 0);
if (!spin)
return;
igt_assert(!spin->timer);
memset(&sev, 0, sizeof(sev));
sev.sigev_notify = SIGEV_THREAD;
sev.sigev_value.sival_ptr = spin;
sev.sigev_notify_function = notify;
igt_assert(timer_create(CLOCK_MONOTONIC, &sev, &timer) == 0);
igt_assert(timer);
memset(&its, 0, sizeof(its));
its.it_value.tv_sec = ns / NSEC_PER_SEC;
its.it_value.tv_nsec = ns % NSEC_PER_SEC;
igt_assert(timer_settime(timer, 0, &its, NULL) == 0);
spin->timer = timer;
}
/**
* igt_spin_batch_end:
* @spin: spin batch state from igt_spin_batch_new()
*
* End the recursive batch associated with @spin manually.
*/
void igt_spin_batch_end(igt_spin_t *spin)
{
if (!spin)
return;
*spin->batch = MI_BATCH_BUFFER_END;
__sync_synchronize();
}
/**
* igt_spin_batch_free:
* @fd: open i915 drm file descriptor
* @spin: spin batch state from igt_spin_batch_new()
*
* This function does the necessary post-processing after starting a recursive
* batch with igt_spin_batch_new().
*/
void igt_spin_batch_free(int fd, igt_spin_t *spin)
{
if (!spin)
return;
pthread_mutex_lock(&list_lock);
igt_list_del(&spin->link);
pthread_mutex_unlock(&list_lock);
if (spin->timer)
timer_delete(spin->timer);
igt_spin_batch_end(spin);
gem_munmap((void *)((unsigned long)spin->batch & (~4095UL)),
BATCH_SIZE);
if (spin->running) {
gem_munmap(spin->running, 4096);
gem_close(fd, spin->poll_handle);
}
gem_close(fd, spin->handle);
if (spin->out_fence >= 0)
close(spin->out_fence);
free(spin);
}
void igt_terminate_spin_batches(void)
{
struct igt_spin *iter;
pthread_mutex_lock(&list_lock);
igt_list_for_each(iter, &spin_list, link)
igt_spin_batch_end(iter);
pthread_mutex_unlock(&list_lock);
}
static uint32_t plug_vgem_handle(struct igt_cork *cork, int fd)
{
struct vgem_bo bo;
int dmabuf;
uint32_t handle;
cork->vgem.device = drm_open_driver(DRIVER_VGEM);
igt_require(vgem_has_fences(cork->vgem.device));
bo.width = bo.height = 1;
bo.bpp = 4;
vgem_create(cork->vgem.device, &bo);
cork->vgem.fence = vgem_fence_attach(cork->vgem.device, &bo, VGEM_FENCE_WRITE);
dmabuf = prime_handle_to_fd(cork->vgem.device, bo.handle);
handle = prime_fd_to_handle(fd, dmabuf);
close(dmabuf);
return handle;
}
static void unplug_vgem_handle(struct igt_cork *cork)
{
vgem_fence_signal(cork->vgem.device, cork->vgem.fence);
close(cork->vgem.device);
}
static uint32_t plug_sync_fd(struct igt_cork *cork)
{
int fence;
igt_require_sw_sync();
cork->sw_sync.timeline = sw_sync_timeline_create();
fence = sw_sync_timeline_create_fence(cork->sw_sync.timeline, 1);
return fence;
}
static void unplug_sync_fd(struct igt_cork *cork)
{
sw_sync_timeline_inc(cork->sw_sync.timeline, 1);
close(cork->sw_sync.timeline);
}
/**
* igt_cork_plug:
* @fd: open drm file descriptor
* @method: method to utilize for corking.
* @cork: structure that will be filled with the state of the cork bo.
* Note: this has to match the corking method.
*
* This function provides a mechanism to stall submission. It provides two
* blocking methods:
*
* VGEM_BO.
* Imports a vgem bo with a fence attached to it. This bo can be used as a
* dependency during submission to stall execution until the fence is signaled.
*
* SW_SYNC:
* Creates a timeline and then a fence on that timeline. The fence can be used
* as an input fence to a request, the request will be stalled until the fence
* is signaled.
*
* The parameters required to unblock the execution and to cleanup are stored in
* the provided cork structure.
*
* Returns:
* Handle of the imported BO / Sw sync fence FD.
*/
uint32_t igt_cork_plug(struct igt_cork *cork, int fd)
{
igt_assert(cork->fd == -1);
switch (cork->type) {
case CORK_SYNC_FD:
return plug_sync_fd(cork);
case CORK_VGEM_HANDLE:
return plug_vgem_handle(cork, fd);
default:
igt_assert_f(0, "Invalid cork type!\n");
return 0;
}
}
/**
* igt_cork_unplug:
* @method: method to utilize for corking.
* @cork: cork state from igt_cork_plug()
*
* This function unblocks the execution by signaling the fence attached to the
* imported bo and does the necessary post-processing.
*
* NOTE: the handle returned by igt_cork_plug is not closed during this phase.
*/
void igt_cork_unplug(struct igt_cork *cork)
{
igt_assert(cork->fd != -1);
switch (cork->type) {
case CORK_SYNC_FD:
unplug_sync_fd(cork);
break;
case CORK_VGEM_HANDLE:
unplug_vgem_handle(cork);
break;
default:
igt_assert_f(0, "Invalid cork type!\n");
}
cork->fd = -1; /* Reset cork */
}
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