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android-kvm / linux / b136f68eb00d898e8f5549d86cc87e8a9e4185f2 / . / drivers / gpu / drm / imagination / pvr_queue.c
blob: 5ed9c98fb599c8a66e959272db89d2b17ab314b4 [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0-only OR MIT
/* Copyright (c) 2023 Imagination Technologies Ltd. */
#include <drm/drm_managed.h>
#include <drm/gpu_scheduler.h>
#include "pvr_cccb.h"
#include "pvr_context.h"
#include "pvr_device.h"
#include "pvr_drv.h"
#include "pvr_job.h"
#include "pvr_queue.h"
#include "pvr_vm.h"
#include "pvr_rogue_fwif_client.h"
#define MAX_DEADLINE_MS 30000
#define CTX_COMPUTE_CCCB_SIZE_LOG2 15
#define CTX_FRAG_CCCB_SIZE_LOG2 15
#define CTX_GEOM_CCCB_SIZE_LOG2 15
#define CTX_TRANSFER_CCCB_SIZE_LOG2 15
static int get_xfer_ctx_state_size(struct pvr_device *pvr_dev)
{
u32 num_isp_store_registers;
if (PVR_HAS_FEATURE(pvr_dev, xe_memory_hierarchy)) {
num_isp_store_registers = 1;
} else {
int err;
err = PVR_FEATURE_VALUE(pvr_dev, num_isp_ipp_pipes, &num_isp_store_registers);
if (WARN_ON(err))
return err;
}
return sizeof(struct rogue_fwif_frag_ctx_state) +
(num_isp_store_registers *
sizeof(((struct rogue_fwif_frag_ctx_state *)0)->frag_reg_isp_store[0]));
}
static int get_frag_ctx_state_size(struct pvr_device *pvr_dev)
{
u32 num_isp_store_registers;
int err;
if (PVR_HAS_FEATURE(pvr_dev, xe_memory_hierarchy)) {
err = PVR_FEATURE_VALUE(pvr_dev, num_raster_pipes, &num_isp_store_registers);
if (WARN_ON(err))
return err;
if (PVR_HAS_FEATURE(pvr_dev, gpu_multicore_support)) {
u32 xpu_max_slaves;
err = PVR_FEATURE_VALUE(pvr_dev, xpu_max_slaves, &xpu_max_slaves);
if (WARN_ON(err))
return err;
num_isp_store_registers *= (1 + xpu_max_slaves);
}
} else {
err = PVR_FEATURE_VALUE(pvr_dev, num_isp_ipp_pipes, &num_isp_store_registers);
if (WARN_ON(err))
return err;
}
return sizeof(struct rogue_fwif_frag_ctx_state) +
(num_isp_store_registers *
sizeof(((struct rogue_fwif_frag_ctx_state *)0)->frag_reg_isp_store[0]));
}
static int get_ctx_state_size(struct pvr_device *pvr_dev, enum drm_pvr_job_type type)
{
switch (type) {
case DRM_PVR_JOB_TYPE_GEOMETRY:
return sizeof(struct rogue_fwif_geom_ctx_state);
case DRM_PVR_JOB_TYPE_FRAGMENT:
return get_frag_ctx_state_size(pvr_dev);
case DRM_PVR_JOB_TYPE_COMPUTE:
return sizeof(struct rogue_fwif_compute_ctx_state);
case DRM_PVR_JOB_TYPE_TRANSFER_FRAG:
return get_xfer_ctx_state_size(pvr_dev);
}
WARN(1, "Invalid queue type");
return -EINVAL;
}
static u32 get_ctx_offset(enum drm_pvr_job_type type)
{
switch (type) {
case DRM_PVR_JOB_TYPE_GEOMETRY:
return offsetof(struct rogue_fwif_fwrendercontext, geom_context);
case DRM_PVR_JOB_TYPE_FRAGMENT:
return offsetof(struct rogue_fwif_fwrendercontext, frag_context);
case DRM_PVR_JOB_TYPE_COMPUTE:
return offsetof(struct rogue_fwif_fwcomputecontext, cdm_context);
case DRM_PVR_JOB_TYPE_TRANSFER_FRAG:
return offsetof(struct rogue_fwif_fwtransfercontext, tq_context);
}
return 0;
}
static const char *
pvr_queue_fence_get_driver_name(struct dma_fence *f)
{
return PVR_DRIVER_NAME;
}
static void pvr_queue_fence_release(struct dma_fence *f)
{
struct pvr_queue_fence *fence = container_of(f, struct pvr_queue_fence, base);
pvr_context_put(fence->queue->ctx);
dma_fence_free(f);
}
static const char *
pvr_queue_job_fence_get_timeline_name(struct dma_fence *f)
{
struct pvr_queue_fence *fence = container_of(f, struct pvr_queue_fence, base);
switch (fence->queue->type) {
case DRM_PVR_JOB_TYPE_GEOMETRY:
return "geometry";
case DRM_PVR_JOB_TYPE_FRAGMENT:
return "fragment";
case DRM_PVR_JOB_TYPE_COMPUTE:
return "compute";
case DRM_PVR_JOB_TYPE_TRANSFER_FRAG:
return "transfer";
}
WARN(1, "Invalid queue type");
return "invalid";
}
static const char *
pvr_queue_cccb_fence_get_timeline_name(struct dma_fence *f)
{
struct pvr_queue_fence *fence = container_of(f, struct pvr_queue_fence, base);
switch (fence->queue->type) {
case DRM_PVR_JOB_TYPE_GEOMETRY:
return "geometry-cccb";
case DRM_PVR_JOB_TYPE_FRAGMENT:
return "fragment-cccb";
case DRM_PVR_JOB_TYPE_COMPUTE:
return "compute-cccb";
case DRM_PVR_JOB_TYPE_TRANSFER_FRAG:
return "transfer-cccb";
}
WARN(1, "Invalid queue type");
return "invalid";
}
static const struct dma_fence_ops pvr_queue_job_fence_ops = {
.get_driver_name = pvr_queue_fence_get_driver_name,
.get_timeline_name = pvr_queue_job_fence_get_timeline_name,
.release = pvr_queue_fence_release,
};
/**
* to_pvr_queue_job_fence() - Return a pvr_queue_fence object if the fence is
* backed by a UFO.
* @f: The dma_fence to turn into a pvr_queue_fence.
*
* Return:
* * A non-NULL pvr_queue_fence object if the dma_fence is backed by a UFO, or
* * NULL otherwise.
*/
static struct pvr_queue_fence *
to_pvr_queue_job_fence(struct dma_fence *f)
{
struct drm_sched_fence *sched_fence = to_drm_sched_fence(f);
if (sched_fence)
f = sched_fence->parent;
if (f && f->ops == &pvr_queue_job_fence_ops)
return container_of(f, struct pvr_queue_fence, base);
return NULL;
}
static const struct dma_fence_ops pvr_queue_cccb_fence_ops = {
.get_driver_name = pvr_queue_fence_get_driver_name,
.get_timeline_name = pvr_queue_cccb_fence_get_timeline_name,
.release = pvr_queue_fence_release,
};
/**
* pvr_queue_fence_put() - Put wrapper for pvr_queue_fence objects.
* @f: The dma_fence object to put.
*
* If the pvr_queue_fence has been initialized, we call dma_fence_put(),
* otherwise we free the object with dma_fence_free(). This allows us
* to do the right thing before and after pvr_queue_fence_init() had been
* called.
*/
static void pvr_queue_fence_put(struct dma_fence *f)
{
if (!f)
return;
if (WARN_ON(f->ops &&
f->ops != &pvr_queue_cccb_fence_ops &&
f->ops != &pvr_queue_job_fence_ops))
return;
/* If the fence hasn't been initialized yet, free the object directly. */
if (f->ops)
dma_fence_put(f);
else
dma_fence_free(f);
}
/**
* pvr_queue_fence_alloc() - Allocate a pvr_queue_fence fence object
*
* Call this function to allocate job CCCB and done fences. This only
* allocates the objects. Initialization happens when the underlying
* dma_fence object is to be returned to drm_sched (in prepare_job() or
* run_job()).
*
* Return:
* * A valid pointer if the allocation succeeds, or
* * NULL if the allocation fails.
*/
static struct dma_fence *
pvr_queue_fence_alloc(void)
{
struct pvr_queue_fence *fence;
fence = kzalloc(sizeof(*fence), GFP_KERNEL);
if (!fence)
return NULL;
return &fence->base;
}
/**
* pvr_queue_fence_init() - Initializes a pvr_queue_fence object.
* @f: The fence to initialize
* @queue: The queue this fence belongs to.
* @fence_ops: The fence operations.
* @fence_ctx: The fence context.
*
* Wrapper around dma_fence_init() that takes care of initializing the
* pvr_queue_fence::queue field too.
*/
static void
pvr_queue_fence_init(struct dma_fence *f,
struct pvr_queue *queue,
const struct dma_fence_ops *fence_ops,
struct pvr_queue_fence_ctx *fence_ctx)
{
struct pvr_queue_fence *fence = container_of(f, struct pvr_queue_fence, base);
pvr_context_get(queue->ctx);
fence->queue = queue;
dma_fence_init(&fence->base, fence_ops,
&fence_ctx->lock, fence_ctx->id,
atomic_inc_return(&fence_ctx->seqno));
}
/**
* pvr_queue_cccb_fence_init() - Initializes a CCCB fence object.
* @fence: The fence to initialize.
* @queue: The queue this fence belongs to.
*
* Initializes a fence that can be used to wait for CCCB space.
*
* Should be called in the ::prepare_job() path, so the fence returned to
* drm_sched is valid.
*/
static void
pvr_queue_cccb_fence_init(struct dma_fence *fence, struct pvr_queue *queue)
{
pvr_queue_fence_init(fence, queue, &pvr_queue_cccb_fence_ops,
&queue->cccb_fence_ctx.base);
}
/**
* pvr_queue_job_fence_init() - Initializes a job done fence object.
* @fence: The fence to initialize.
* @queue: The queue this fence belongs to.
*
* Initializes a fence that will be signaled when the GPU is done executing
* a job.
*
* Should be called *before* the ::run_job() path, so the fence is initialised
* before being placed in the pending_list.
*/
static void
pvr_queue_job_fence_init(struct dma_fence *fence, struct pvr_queue *queue)
{
pvr_queue_fence_init(fence, queue, &pvr_queue_job_fence_ops,
&queue->job_fence_ctx);
}
/**
* pvr_queue_fence_ctx_init() - Queue fence context initialization.
* @fence_ctx: The context to initialize
*/
static void
pvr_queue_fence_ctx_init(struct pvr_queue_fence_ctx *fence_ctx)
{
spin_lock_init(&fence_ctx->lock);
fence_ctx->id = dma_fence_context_alloc(1);
atomic_set(&fence_ctx->seqno, 0);
}
static u32 ufo_cmds_size(u32 elem_count)
{
/* We can pass at most ROGUE_FWIF_CCB_CMD_MAX_UFOS per UFO-related command. */
u32 full_cmd_count = elem_count / ROGUE_FWIF_CCB_CMD_MAX_UFOS;
u32 remaining_elems = elem_count % ROGUE_FWIF_CCB_CMD_MAX_UFOS;
u32 size = full_cmd_count *
pvr_cccb_get_size_of_cmd_with_hdr(ROGUE_FWIF_CCB_CMD_MAX_UFOS *
sizeof(struct rogue_fwif_ufo));
if (remaining_elems) {
size += pvr_cccb_get_size_of_cmd_with_hdr(remaining_elems *
sizeof(struct rogue_fwif_ufo));
}
return size;
}
static u32 job_cmds_size(struct pvr_job *job, u32 ufo_wait_count)
{
/* One UFO cmd for the fence signaling, one UFO cmd per native fence native,
* and a command for the job itself.
*/
return ufo_cmds_size(1) + ufo_cmds_size(ufo_wait_count) +
pvr_cccb_get_size_of_cmd_with_hdr(job->cmd_len);
}
/**
* job_count_remaining_native_deps() - Count the number of non-signaled native dependencies.
* @job: Job to operate on.
*
* Returns: Number of non-signaled native deps remaining.
*/
static unsigned long job_count_remaining_native_deps(struct pvr_job *job)
{
unsigned long remaining_count = 0;
struct dma_fence *fence = NULL;
unsigned long index;
xa_for_each(&job->base.dependencies, index, fence) {
struct pvr_queue_fence *jfence;
jfence = to_pvr_queue_job_fence(fence);
if (!jfence)
continue;
if (!dma_fence_is_signaled(&jfence->base))
remaining_count++;
}
return remaining_count;
}
/**
* pvr_queue_get_job_cccb_fence() - Get the CCCB fence attached to a job.
* @queue: The queue this job will be submitted to.
* @job: The job to get the CCCB fence on.
*
* The CCCB fence is a synchronization primitive allowing us to delay job
* submission until there's enough space in the CCCB to submit the job.
*
* Return:
* * NULL if there's enough space in the CCCB to submit this job, or
* * A valid dma_fence object otherwise.
*/
static struct dma_fence *
pvr_queue_get_job_cccb_fence(struct pvr_queue *queue, struct pvr_job *job)
{
struct pvr_queue_fence *cccb_fence;
unsigned int native_deps_remaining;
/* If the fence is NULL, that means we already checked that we had
* enough space in the cccb for our job.
*/
if (!job->cccb_fence)
return NULL;
mutex_lock(&queue->cccb_fence_ctx.job_lock);
/* Count remaining native dependencies and check if the job fits in the CCCB. */
native_deps_remaining = job_count_remaining_native_deps(job);
if (pvr_cccb_cmdseq_fits(&queue->cccb, job_cmds_size(job, native_deps_remaining))) {
pvr_queue_fence_put(job->cccb_fence);
job->cccb_fence = NULL;
goto out_unlock;
}
/* There should be no job attached to the CCCB fence context:
* drm_sched_entity guarantees that jobs are submitted one at a time.
*/
if (WARN_ON(queue->cccb_fence_ctx.job))
pvr_job_put(queue->cccb_fence_ctx.job);
queue->cccb_fence_ctx.job = pvr_job_get(job);
/* Initialize the fence before returning it. */
cccb_fence = container_of(job->cccb_fence, struct pvr_queue_fence, base);
if (!WARN_ON(cccb_fence->queue))
pvr_queue_cccb_fence_init(job->cccb_fence, queue);
out_unlock:
mutex_unlock(&queue->cccb_fence_ctx.job_lock);
return dma_fence_get(job->cccb_fence);
}
/**
* pvr_queue_get_job_kccb_fence() - Get the KCCB fence attached to a job.
* @queue: The queue this job will be submitted to.
* @job: The job to get the KCCB fence on.
*
* The KCCB fence is a synchronization primitive allowing us to delay job
* submission until there's enough space in the KCCB to submit the job.
*
* Return:
* * NULL if there's enough space in the KCCB to submit this job, or
* * A valid dma_fence object otherwise.
*/
static struct dma_fence *
pvr_queue_get_job_kccb_fence(struct pvr_queue *queue, struct pvr_job *job)
{
struct pvr_device *pvr_dev = queue->ctx->pvr_dev;
struct dma_fence *kccb_fence = NULL;
/* If the fence is NULL, that means we already checked that we had
* enough space in the KCCB for our job.
*/
if (!job->kccb_fence)
return NULL;
if (!WARN_ON(job->kccb_fence->ops)) {
kccb_fence = pvr_kccb_reserve_slot(pvr_dev, job->kccb_fence);
job->kccb_fence = NULL;
}
return kccb_fence;
}
static struct dma_fence *
pvr_queue_get_paired_frag_job_dep(struct pvr_queue *queue, struct pvr_job *job)
{
struct pvr_job *frag_job = job->type == DRM_PVR_JOB_TYPE_GEOMETRY ?
job->paired_job : NULL;
struct dma_fence *f;
unsigned long index;
if (!frag_job)
return NULL;
xa_for_each(&frag_job->base.dependencies, index, f) {
/* Skip already signaled fences. */
if (dma_fence_is_signaled(f))
continue;
/* Skip our own fence. */
if (f == &job->base.s_fence->scheduled)
continue;
return dma_fence_get(f);
}
return frag_job->base.sched->ops->prepare_job(&frag_job->base, &queue->entity);
}
/**
* pvr_queue_prepare_job() - Return the next internal dependencies expressed as a dma_fence.
* @sched_job: The job to query the next internal dependency on
* @s_entity: The entity this job is queue on.
*
* After iterating over drm_sched_job::dependencies, drm_sched let the driver return
* its own internal dependencies. We use this function to return our internal dependencies.
*/
static struct dma_fence *
pvr_queue_prepare_job(struct drm_sched_job *sched_job,
struct drm_sched_entity *s_entity)
{
struct pvr_job *job = container_of(sched_job, struct pvr_job, base);
struct pvr_queue *queue = container_of(s_entity, struct pvr_queue, entity);
struct dma_fence *internal_dep = NULL;
/*
* Initialize the done_fence, so we can signal it. This must be done
* here because otherwise by the time of run_job() the job will end up
* in the pending list without a valid fence.
*/
if (job->type == DRM_PVR_JOB_TYPE_FRAGMENT && job->paired_job) {
/*
* This will be called on a paired fragment job after being
* submitted to firmware. We can tell if this is the case and
* bail early from whether run_job() has been called on the
* geometry job, which would issue a pm ref.
*/
if (job->paired_job->has_pm_ref)
return NULL;
/*
* In this case we need to use the job's own ctx to initialise
* the done_fence. The other steps are done in the ctx of the
* paired geometry job.
*/
pvr_queue_job_fence_init(job->done_fence,
job->ctx->queues.fragment);
} else {
pvr_queue_job_fence_init(job->done_fence, queue);
}
/* CCCB fence is used to make sure we have enough space in the CCCB to
* submit our commands.
*/
internal_dep = pvr_queue_get_job_cccb_fence(queue, job);
/* KCCB fence is used to make sure we have a KCCB slot to queue our
* CMD_KICK.
*/
if (!internal_dep)
internal_dep = pvr_queue_get_job_kccb_fence(queue, job);
/* Any extra internal dependency should be added here, using the following
* pattern:
*
* if (!internal_dep)
* internal_dep = pvr_queue_get_job_xxxx_fence(queue, job);
*/
/* The paired job fence should come last, when everything else is ready. */
if (!internal_dep)
internal_dep = pvr_queue_get_paired_frag_job_dep(queue, job);
return internal_dep;
}
/**
* pvr_queue_update_active_state_locked() - Update the queue active state.
* @queue: Queue to update the state on.
*
* Locked version of pvr_queue_update_active_state(). Must be called with
* pvr_device::queue::lock held.
*/
static void pvr_queue_update_active_state_locked(struct pvr_queue *queue)
{
struct pvr_device *pvr_dev = queue->ctx->pvr_dev;
lockdep_assert_held(&pvr_dev->queues.lock);
/* The queue is temporary out of any list when it's being reset,
* we don't want a call to pvr_queue_update_active_state_locked()
* to re-insert it behind our back.
*/
if (list_empty(&queue->node))
return;
if (!atomic_read(&queue->in_flight_job_count))
list_move_tail(&queue->node, &pvr_dev->queues.idle);
else
list_move_tail(&queue->node, &pvr_dev->queues.active);
}
/**
* pvr_queue_update_active_state() - Update the queue active state.
* @queue: Queue to update the state on.
*
* Active state is based on the in_flight_job_count value.
*
* Updating the active state implies moving the queue in or out of the
* active queue list, which also defines whether the queue is checked
* or not when a FW event is received.
*
* This function should be called any time a job is submitted or it done
* fence is signaled.
*/
static void pvr_queue_update_active_state(struct pvr_queue *queue)
{
struct pvr_device *pvr_dev = queue->ctx->pvr_dev;
mutex_lock(&pvr_dev->queues.lock);
pvr_queue_update_active_state_locked(queue);
mutex_unlock(&pvr_dev->queues.lock);
}
static void pvr_queue_submit_job_to_cccb(struct pvr_job *job)
{
struct pvr_queue *queue = container_of(job->base.sched, struct pvr_queue, scheduler);
struct rogue_fwif_ufo ufos[ROGUE_FWIF_CCB_CMD_MAX_UFOS];
struct pvr_cccb *cccb = &queue->cccb;
struct pvr_queue_fence *jfence;
struct dma_fence *fence;
unsigned long index;
u32 ufo_count = 0;
/* We need to add the queue to the active list before updating the CCCB,
* otherwise we might miss the FW event informing us that something
* happened on this queue.
*/
atomic_inc(&queue->in_flight_job_count);
pvr_queue_update_active_state(queue);
xa_for_each(&job->base.dependencies, index, fence) {
jfence = to_pvr_queue_job_fence(fence);
if (!jfence)
continue;
/* Skip the partial render fence, we will place it at the end. */
if (job->type == DRM_PVR_JOB_TYPE_FRAGMENT && job->paired_job &&
&job->paired_job->base.s_fence->scheduled == fence)
continue;
if (dma_fence_is_signaled(&jfence->base))
continue;
pvr_fw_object_get_fw_addr(jfence->queue->timeline_ufo.fw_obj,
&ufos[ufo_count].addr);
ufos[ufo_count++].value = jfence->base.seqno;
if (ufo_count == ARRAY_SIZE(ufos)) {
pvr_cccb_write_command_with_header(cccb, ROGUE_FWIF_CCB_CMD_TYPE_FENCE_PR,
sizeof(ufos), ufos, 0, 0);
ufo_count = 0;
}
}
/* Partial render fence goes last. */
if (job->type == DRM_PVR_JOB_TYPE_FRAGMENT && job->paired_job) {
jfence = to_pvr_queue_job_fence(job->paired_job->done_fence);
if (!WARN_ON(!jfence)) {
pvr_fw_object_get_fw_addr(jfence->queue->timeline_ufo.fw_obj,
&ufos[ufo_count].addr);
ufos[ufo_count++].value = job->paired_job->done_fence->seqno;
}
}
if (ufo_count) {
pvr_cccb_write_command_with_header(cccb, ROGUE_FWIF_CCB_CMD_TYPE_FENCE_PR,
sizeof(ufos[0]) * ufo_count, ufos, 0, 0);
}
if (job->type == DRM_PVR_JOB_TYPE_GEOMETRY && job->paired_job) {
struct rogue_fwif_cmd_geom *cmd = job->cmd;
/* Reference value for the partial render test is the current queue fence
* seqno minus one.
*/
pvr_fw_object_get_fw_addr(queue->timeline_ufo.fw_obj,
&cmd->partial_render_geom_frag_fence.addr);
cmd->partial_render_geom_frag_fence.value = job->done_fence->seqno - 1;
}
/* Submit job to FW */
pvr_cccb_write_command_with_header(cccb, job->fw_ccb_cmd_type, job->cmd_len, job->cmd,
job->id, job->id);
/* Signal the job fence. */
pvr_fw_object_get_fw_addr(queue->timeline_ufo.fw_obj, &ufos[0].addr);
ufos[0].value = job->done_fence->seqno;
pvr_cccb_write_command_with_header(cccb, ROGUE_FWIF_CCB_CMD_TYPE_UPDATE,
sizeof(ufos[0]), ufos, 0, 0);
}
/**
* pvr_queue_run_job() - Submit a job to the FW.
* @sched_job: The job to submit.
*
* This function is called when all non-native dependencies have been met and
* when the commands resulting from this job are guaranteed to fit in the CCCB.
*/
static struct dma_fence *pvr_queue_run_job(struct drm_sched_job *sched_job)
{
struct pvr_job *job = container_of(sched_job, struct pvr_job, base);
struct pvr_device *pvr_dev = job->pvr_dev;
int err;
/* The fragment job is issued along the geometry job when we use combined
* geom+frag kicks. When we get there, we should simply return the
* done_fence that's been initialized earlier.
*/
if (job->paired_job && job->type == DRM_PVR_JOB_TYPE_FRAGMENT &&
job->done_fence->ops) {
return dma_fence_get(job->done_fence);
}
/* The only kind of jobs that can be paired are geometry and fragment, and
* we bail out early if we see a fragment job that's paired with a geomtry
* job.
* Paired jobs must also target the same context and point to the same
* HWRT.
*/
if (WARN_ON(job->paired_job &&
(job->type != DRM_PVR_JOB_TYPE_GEOMETRY ||
job->paired_job->type != DRM_PVR_JOB_TYPE_FRAGMENT ||
job->hwrt != job->paired_job->hwrt ||
job->ctx != job->paired_job->ctx)))
return ERR_PTR(-EINVAL);
err = pvr_job_get_pm_ref(job);
if (WARN_ON(err))
return ERR_PTR(err);
if (job->paired_job) {
err = pvr_job_get_pm_ref(job->paired_job);
if (WARN_ON(err))
return ERR_PTR(err);
}
/* Submit our job to the CCCB */
pvr_queue_submit_job_to_cccb(job);
if (job->paired_job) {
struct pvr_job *geom_job = job;
struct pvr_job *frag_job = job->paired_job;
struct pvr_queue *geom_queue = job->ctx->queues.geometry;
struct pvr_queue *frag_queue = job->ctx->queues.fragment;
/* Submit the fragment job along the geometry job and send a combined kick. */
pvr_queue_submit_job_to_cccb(frag_job);
pvr_cccb_send_kccb_combined_kick(pvr_dev,
&geom_queue->cccb, &frag_queue->cccb,
pvr_context_get_fw_addr(geom_job->ctx) +
geom_queue->ctx_offset,
pvr_context_get_fw_addr(frag_job->ctx) +
frag_queue->ctx_offset,
job->hwrt,
frag_job->fw_ccb_cmd_type ==
ROGUE_FWIF_CCB_CMD_TYPE_FRAG_PR);
} else {
struct pvr_queue *queue = container_of(job->base.sched,
struct pvr_queue, scheduler);
pvr_cccb_send_kccb_kick(pvr_dev, &queue->cccb,
pvr_context_get_fw_addr(job->ctx) + queue->ctx_offset,
job->hwrt);
}
return dma_fence_get(job->done_fence);
}
static void pvr_queue_stop(struct pvr_queue *queue, struct pvr_job *bad_job)
{
drm_sched_stop(&queue->scheduler, bad_job ? &bad_job->base : NULL);
}
static void pvr_queue_start(struct pvr_queue *queue)
{
struct pvr_job *job;
/* Make sure we CPU-signal the UFO object, so other queues don't get
* blocked waiting on it.
*/
*queue->timeline_ufo.value = atomic_read(&queue->job_fence_ctx.seqno);
list_for_each_entry(job, &queue->scheduler.pending_list, base.list) {
if (dma_fence_is_signaled(job->done_fence)) {
/* Jobs might have completed after drm_sched_stop() was called.
* In that case, re-assign the parent field to the done_fence.
*/
WARN_ON(job->base.s_fence->parent);
job->base.s_fence->parent = dma_fence_get(job->done_fence);
} else {
/* If we had unfinished jobs, flag the entity as guilty so no
* new job can be submitted.
*/
atomic_set(&queue->ctx->faulty, 1);
}
}
drm_sched_start(&queue->scheduler, true);
}
/**
* pvr_queue_timedout_job() - Handle a job timeout event.
* @s_job: The job this timeout occurred on.
*
* FIXME: We don't do anything here to unblock the situation, we just stop+start
* the scheduler, and re-assign parent fences in the middle.
*
* Return:
* * DRM_GPU_SCHED_STAT_NOMINAL.
*/
static enum drm_gpu_sched_stat
pvr_queue_timedout_job(struct drm_sched_job *s_job)
{
struct drm_gpu_scheduler *sched = s_job->sched;
struct pvr_queue *queue = container_of(sched, struct pvr_queue, scheduler);
struct pvr_device *pvr_dev = queue->ctx->pvr_dev;
struct pvr_job *job;
u32 job_count = 0;
dev_err(sched->dev, "Job timeout\n");
/* Before we stop the scheduler, make sure the queue is out of any list, so
* any call to pvr_queue_update_active_state_locked() that might happen
* until the scheduler is really stopped doesn't end up re-inserting the
* queue in the active list. This would cause
* pvr_queue_signal_done_fences() and drm_sched_stop() to race with each
* other when accessing the pending_list, since drm_sched_stop() doesn't
* grab the job_list_lock when modifying the list (it's assuming the
* only other accessor is the scheduler, and it's safe to not grab the
* lock since it's stopped).
*/
mutex_lock(&pvr_dev->queues.lock);
list_del_init(&queue->node);
mutex_unlock(&pvr_dev->queues.lock);
drm_sched_stop(sched, s_job);
/* Re-assign job parent fences. */
list_for_each_entry(job, &sched->pending_list, base.list) {
job->base.s_fence->parent = dma_fence_get(job->done_fence);
job_count++;
}
WARN_ON(atomic_read(&queue->in_flight_job_count) != job_count);
/* Re-insert the queue in the proper list, and kick a queue processing
* operation if there were jobs pending.
*/
mutex_lock(&pvr_dev->queues.lock);
if (!job_count) {
list_move_tail(&queue->node, &pvr_dev->queues.idle);
} else {
atomic_set(&queue->in_flight_job_count, job_count);
list_move_tail(&queue->node, &pvr_dev->queues.active);
pvr_queue_process(queue);
}
mutex_unlock(&pvr_dev->queues.lock);
drm_sched_start(sched, true);
return DRM_GPU_SCHED_STAT_NOMINAL;
}
/**
* pvr_queue_free_job() - Release the reference the scheduler had on a job object.
* @sched_job: Job object to free.
*/
static void pvr_queue_free_job(struct drm_sched_job *sched_job)
{
struct pvr_job *job = container_of(sched_job, struct pvr_job, base);
drm_sched_job_cleanup(sched_job);
job->paired_job = NULL;
pvr_job_put(job);
}
static const struct drm_sched_backend_ops pvr_queue_sched_ops = {
.prepare_job = pvr_queue_prepare_job,
.run_job = pvr_queue_run_job,
.timedout_job = pvr_queue_timedout_job,
.free_job = pvr_queue_free_job,
};
/**
* pvr_queue_fence_is_ufo_backed() - Check if a dma_fence is backed by a UFO object
* @f: Fence to test.
*
* A UFO-backed fence is a fence that can be signaled or waited upon FW-side.
* pvr_job::done_fence objects are backed by the timeline UFO attached to the queue
* they are pushed to, but those fences are not directly exposed to the outside
* world, so we also need to check if the fence we're being passed is a
* drm_sched_fence that was coming from our driver.
*/
bool pvr_queue_fence_is_ufo_backed(struct dma_fence *f)
{
struct drm_sched_fence *sched_fence = f ? to_drm_sched_fence(f) : NULL;
if (sched_fence &&
sched_fence->sched->ops == &pvr_queue_sched_ops)
return true;
if (f && f->ops == &pvr_queue_job_fence_ops)
return true;
return false;
}
/**
* pvr_queue_signal_done_fences() - Signal done fences.
* @queue: Queue to check.
*
* Signal done fences of jobs whose seqno is less than the current value of
* the UFO object attached to the queue.
*/
static void
pvr_queue_signal_done_fences(struct pvr_queue *queue)
{
struct pvr_job *job, *tmp_job;
u32 cur_seqno;
spin_lock(&queue->scheduler.job_list_lock);
cur_seqno = *queue->timeline_ufo.value;
list_for_each_entry_safe(job, tmp_job, &queue->scheduler.pending_list, base.list) {
if ((int)(cur_seqno - lower_32_bits(job->done_fence->seqno)) < 0)
break;
if (!dma_fence_is_signaled(job->done_fence)) {
dma_fence_signal(job->done_fence);
pvr_job_release_pm_ref(job);
atomic_dec(&queue->in_flight_job_count);
}
}
spin_unlock(&queue->scheduler.job_list_lock);
}
/**
* pvr_queue_check_job_waiting_for_cccb_space() - Check if the job waiting for CCCB space
* can be unblocked
* pushed to the CCCB
* @queue: Queue to check
*
* If we have a job waiting for CCCB, and this job now fits in the CCCB, we signal
* its CCCB fence, which should kick drm_sched.
*/
static void
pvr_queue_check_job_waiting_for_cccb_space(struct pvr_queue *queue)
{
struct pvr_queue_fence *cccb_fence;
u32 native_deps_remaining;
struct pvr_job *job;
mutex_lock(&queue->cccb_fence_ctx.job_lock);
job = queue->cccb_fence_ctx.job;
if (!job)
goto out_unlock;
/* If we have a job attached to the CCCB fence context, its CCCB fence
* shouldn't be NULL.
*/
if (WARN_ON(!job->cccb_fence)) {
job = NULL;
goto out_unlock;
}
/* If we get there, CCCB fence has to be initialized. */
cccb_fence = container_of(job->cccb_fence, struct pvr_queue_fence, base);
if (WARN_ON(!cccb_fence->queue)) {
job = NULL;
goto out_unlock;
}
/* Evict signaled dependencies before checking for CCCB space.
* If the job fits, signal the CCCB fence, this should unblock
* the drm_sched_entity.
*/
native_deps_remaining = job_count_remaining_native_deps(job);
if (!pvr_cccb_cmdseq_fits(&queue->cccb, job_cmds_size(job, native_deps_remaining))) {
job = NULL;
goto out_unlock;
}
dma_fence_signal(job->cccb_fence);
pvr_queue_fence_put(job->cccb_fence);
job->cccb_fence = NULL;
queue->cccb_fence_ctx.job = NULL;
out_unlock:
mutex_unlock(&queue->cccb_fence_ctx.job_lock);
pvr_job_put(job);
}
/**
* pvr_queue_process() - Process events that happened on a queue.
* @queue: Queue to check
*
* Signal job fences and check if jobs waiting for CCCB space can be unblocked.
*/
void pvr_queue_process(struct pvr_queue *queue)
{
lockdep_assert_held(&queue->ctx->pvr_dev->queues.lock);
pvr_queue_check_job_waiting_for_cccb_space(queue);
pvr_queue_signal_done_fences(queue);
pvr_queue_update_active_state_locked(queue);
}
static u32 get_dm_type(struct pvr_queue *queue)
{
switch (queue->type) {
case DRM_PVR_JOB_TYPE_GEOMETRY:
return PVR_FWIF_DM_GEOM;
case DRM_PVR_JOB_TYPE_TRANSFER_FRAG:
case DRM_PVR_JOB_TYPE_FRAGMENT:
return PVR_FWIF_DM_FRAG;
case DRM_PVR_JOB_TYPE_COMPUTE:
return PVR_FWIF_DM_CDM;
}
return ~0;
}
/**
* init_fw_context() - Initializes the queue part of a FW context.
* @queue: Queue object to initialize the FW context for.
* @fw_ctx_map: The FW context CPU mapping.
*
* FW contexts are containing various states, one of them being a per-queue state
* that needs to be initialized for each queue being exposed by a context. This
* function takes care of that.
*/
static void init_fw_context(struct pvr_queue *queue, void *fw_ctx_map)
{
struct pvr_context *ctx = queue->ctx;
struct pvr_fw_object *fw_mem_ctx_obj = pvr_vm_get_fw_mem_context(ctx->vm_ctx);
struct rogue_fwif_fwcommoncontext *cctx_fw;
struct pvr_cccb *cccb = &queue->cccb;
cctx_fw = fw_ctx_map + queue->ctx_offset;
cctx_fw->ccbctl_fw_addr = cccb->ctrl_fw_addr;
cctx_fw->ccb_fw_addr = cccb->cccb_fw_addr;
cctx_fw->dm = get_dm_type(queue);
cctx_fw->priority = ctx->priority;
cctx_fw->priority_seq_num = 0;
cctx_fw->max_deadline_ms = MAX_DEADLINE_MS;
cctx_fw->pid = task_tgid_nr(current);
cctx_fw->server_common_context_id = ctx->ctx_id;
pvr_fw_object_get_fw_addr(fw_mem_ctx_obj, &cctx_fw->fw_mem_context_fw_addr);
pvr_fw_object_get_fw_addr(queue->reg_state_obj, &cctx_fw->context_state_addr);
}
/**
* pvr_queue_cleanup_fw_context() - Wait for the FW context to be idle and clean it up.
* @queue: Queue on FW context to clean up.
*
* Return:
* * 0 on success,
* * Any error returned by pvr_fw_structure_cleanup() otherwise.
*/
static int pvr_queue_cleanup_fw_context(struct pvr_queue *queue)
{
if (!queue->ctx->fw_obj)
return 0;
return pvr_fw_structure_cleanup(queue->ctx->pvr_dev,
ROGUE_FWIF_CLEANUP_FWCOMMONCONTEXT,
queue->ctx->fw_obj, queue->ctx_offset);
}
/**
* pvr_queue_job_init() - Initialize queue related fields in a pvr_job object.
* @job: The job to initialize.
*
* Bind the job to a queue and allocate memory to guarantee pvr_queue_job_arm()
* and pvr_queue_job_push() can't fail. We also make sure the context type is
* valid and the job can fit in the CCCB.
*
* Return:
* * 0 on success, or
* * An error code if something failed.
*/
int pvr_queue_job_init(struct pvr_job *job)
{
/* Fragment jobs need at least one native fence wait on the geometry job fence. */
u32 min_native_dep_count = job->type == DRM_PVR_JOB_TYPE_FRAGMENT ? 1 : 0;
struct pvr_queue *queue;
int err;
if (atomic_read(&job->ctx->faulty))
return -EIO;
queue = pvr_context_get_queue_for_job(job->ctx, job->type);
if (!queue)
return -EINVAL;
if (!pvr_cccb_cmdseq_can_fit(&queue->cccb, job_cmds_size(job, min_native_dep_count)))
return -E2BIG;
err = drm_sched_job_init(&job->base, &queue->entity, 1, THIS_MODULE);
if (err)
return err;
job->cccb_fence = pvr_queue_fence_alloc();
job->kccb_fence = pvr_kccb_fence_alloc();
job->done_fence = pvr_queue_fence_alloc();
if (!job->cccb_fence || !job->kccb_fence || !job->done_fence)
return -ENOMEM;
return 0;
}
/**
* pvr_queue_job_arm() - Arm a job object.
* @job: The job to arm.
*
* Initializes fences and return the drm_sched finished fence so it can
* be exposed to the outside world. Once this function is called, you should
* make sure the job is pushed using pvr_queue_job_push(), or guarantee that
* no one grabbed a reference to the returned fence. The latter can happen if
* we do multi-job submission, and something failed when creating/initializing
* a job. In that case, we know the fence didn't leave the driver, and we
* can thus guarantee nobody will wait on an dead fence object.
*
* Return:
* * A dma_fence object.
*/
struct dma_fence *pvr_queue_job_arm(struct pvr_job *job)
{
drm_sched_job_arm(&job->base);
return &job->base.s_fence->finished;
}
/**
* pvr_queue_job_cleanup() - Cleanup fence/scheduler related fields in the job object.
* @job: The job to cleanup.
*
* Should be called in the job release path.
*/
void pvr_queue_job_cleanup(struct pvr_job *job)
{
pvr_queue_fence_put(job->done_fence);
pvr_queue_fence_put(job->cccb_fence);
pvr_kccb_fence_put(job->kccb_fence);
if (job->base.s_fence)
drm_sched_job_cleanup(&job->base);
}
/**
* pvr_queue_job_push() - Push a job to its queue.
* @job: The job to push.
*
* Must be called after pvr_queue_job_init() and after all dependencies
* have been added to the job. This will effectively queue the job to
* the drm_sched_entity attached to the queue. We grab a reference on
* the job object, so the caller is free to drop its reference when it's
* done accessing the job object.
*/
void pvr_queue_job_push(struct pvr_job *job)
{
struct pvr_queue *queue = container_of(job->base.sched, struct pvr_queue, scheduler);
/* Keep track of the last queued job scheduled fence for combined submit. */
dma_fence_put(queue->last_queued_job_scheduled_fence);
queue->last_queued_job_scheduled_fence = dma_fence_get(&job->base.s_fence->scheduled);
pvr_job_get(job);
drm_sched_entity_push_job(&job->base);
}
static void reg_state_init(void *cpu_ptr, void *priv)
{
struct pvr_queue *queue = priv;
if (queue->type == DRM_PVR_JOB_TYPE_GEOMETRY) {
struct rogue_fwif_geom_ctx_state *geom_ctx_state_fw = cpu_ptr;
geom_ctx_state_fw->geom_core[0].geom_reg_vdm_call_stack_pointer_init =
queue->callstack_addr;
}
}
/**
* pvr_queue_create() - Create a queue object.
* @ctx: The context this queue will be attached to.
* @type: The type of jobs being pushed to this queue.
* @args: The arguments passed to the context creation function.
* @fw_ctx_map: CPU mapping of the FW context object.
*
* Create a queue object that will be used to queue and track jobs.
*
* Return:
* * A valid pointer to a pvr_queue object, or
* * An error pointer if the creation/initialization failed.
*/
struct pvr_queue *pvr_queue_create(struct pvr_context *ctx,
enum drm_pvr_job_type type,
struct drm_pvr_ioctl_create_context_args *args,
void *fw_ctx_map)
{
static const struct {
u32 cccb_size;
const char *name;
} props[] = {
[DRM_PVR_JOB_TYPE_GEOMETRY] = {
.cccb_size = CTX_GEOM_CCCB_SIZE_LOG2,
.name = "geometry",
},
[DRM_PVR_JOB_TYPE_FRAGMENT] = {
.cccb_size = CTX_FRAG_CCCB_SIZE_LOG2,
.name = "fragment"
},
[DRM_PVR_JOB_TYPE_COMPUTE] = {
.cccb_size = CTX_COMPUTE_CCCB_SIZE_LOG2,
.name = "compute"
},
[DRM_PVR_JOB_TYPE_TRANSFER_FRAG] = {
.cccb_size = CTX_TRANSFER_CCCB_SIZE_LOG2,
.name = "transfer_frag"
},
};
struct pvr_device *pvr_dev = ctx->pvr_dev;
struct drm_gpu_scheduler *sched;
struct pvr_queue *queue;
int ctx_state_size, err;
void *cpu_map;
if (WARN_ON(type >= sizeof(props)))
return ERR_PTR(-EINVAL);
switch (ctx->type) {
case DRM_PVR_CTX_TYPE_RENDER:
if (type != DRM_PVR_JOB_TYPE_GEOMETRY &&
type != DRM_PVR_JOB_TYPE_FRAGMENT)
return ERR_PTR(-EINVAL);
break;
case DRM_PVR_CTX_TYPE_COMPUTE:
if (type != DRM_PVR_JOB_TYPE_COMPUTE)
return ERR_PTR(-EINVAL);
break;
case DRM_PVR_CTX_TYPE_TRANSFER_FRAG:
if (type != DRM_PVR_JOB_TYPE_TRANSFER_FRAG)
return ERR_PTR(-EINVAL);
break;
default:
return ERR_PTR(-EINVAL);
}
ctx_state_size = get_ctx_state_size(pvr_dev, type);
if (ctx_state_size < 0)
return ERR_PTR(ctx_state_size);
queue = kzalloc(sizeof(*queue), GFP_KERNEL);
if (!queue)
return ERR_PTR(-ENOMEM);
queue->type = type;
queue->ctx_offset = get_ctx_offset(type);
queue->ctx = ctx;
queue->callstack_addr = args->callstack_addr;
sched = &queue->scheduler;
INIT_LIST_HEAD(&queue->node);
mutex_init(&queue->cccb_fence_ctx.job_lock);
pvr_queue_fence_ctx_init(&queue->cccb_fence_ctx.base);
pvr_queue_fence_ctx_init(&queue->job_fence_ctx);
err = pvr_cccb_init(pvr_dev, &queue->cccb, props[type].cccb_size, props[type].name);
if (err)
goto err_free_queue;
err = pvr_fw_object_create(pvr_dev, ctx_state_size,
PVR_BO_FW_FLAGS_DEVICE_UNCACHED,
reg_state_init, queue, &queue->reg_state_obj);
if (err)
goto err_cccb_fini;
init_fw_context(queue, fw_ctx_map);
if (type != DRM_PVR_JOB_TYPE_GEOMETRY && type != DRM_PVR_JOB_TYPE_FRAGMENT &&
args->callstack_addr) {
err = -EINVAL;
goto err_release_reg_state;
}
cpu_map = pvr_fw_object_create_and_map(pvr_dev, sizeof(*queue->timeline_ufo.value),
PVR_BO_FW_FLAGS_DEVICE_UNCACHED,
NULL, NULL, &queue->timeline_ufo.fw_obj);
if (IS_ERR(cpu_map)) {
err = PTR_ERR(cpu_map);
goto err_release_reg_state;
}
queue->timeline_ufo.value = cpu_map;
err = drm_sched_init(&queue->scheduler,
&pvr_queue_sched_ops,
pvr_dev->sched_wq, 1, 64 * 1024, 1,
msecs_to_jiffies(500),
pvr_dev->sched_wq, NULL, "pvr-queue",
pvr_dev->base.dev);
if (err)
goto err_release_ufo;
err = drm_sched_entity_init(&queue->entity,
DRM_SCHED_PRIORITY_KERNEL,
&sched, 1, &ctx->faulty);
if (err)
goto err_sched_fini;
mutex_lock(&pvr_dev->queues.lock);
list_add_tail(&queue->node, &pvr_dev->queues.idle);
mutex_unlock(&pvr_dev->queues.lock);
return queue;
err_sched_fini:
drm_sched_fini(&queue->scheduler);
err_release_ufo:
pvr_fw_object_unmap_and_destroy(queue->timeline_ufo.fw_obj);
err_release_reg_state:
pvr_fw_object_destroy(queue->reg_state_obj);
err_cccb_fini:
pvr_cccb_fini(&queue->cccb);
err_free_queue:
mutex_destroy(&queue->cccb_fence_ctx.job_lock);
kfree(queue);
return ERR_PTR(err);
}
void pvr_queue_device_pre_reset(struct pvr_device *pvr_dev)
{
struct pvr_queue *queue;
mutex_lock(&pvr_dev->queues.lock);
list_for_each_entry(queue, &pvr_dev->queues.idle, node)
pvr_queue_stop(queue, NULL);
list_for_each_entry(queue, &pvr_dev->queues.active, node)
pvr_queue_stop(queue, NULL);
mutex_unlock(&pvr_dev->queues.lock);
}
void pvr_queue_device_post_reset(struct pvr_device *pvr_dev)
{
struct pvr_queue *queue;
mutex_lock(&pvr_dev->queues.lock);
list_for_each_entry(queue, &pvr_dev->queues.active, node)
pvr_queue_start(queue);
list_for_each_entry(queue, &pvr_dev->queues.idle, node)
pvr_queue_start(queue);
mutex_unlock(&pvr_dev->queues.lock);
}
/**
* pvr_queue_kill() - Kill a queue.
* @queue: The queue to kill.
*
* Kill the queue so no new jobs can be pushed. Should be called when the
* context handle is destroyed. The queue object might last longer if jobs
* are still in flight and holding a reference to the context this queue
* belongs to.
*/
void pvr_queue_kill(struct pvr_queue *queue)
{
drm_sched_entity_destroy(&queue->entity);
dma_fence_put(queue->last_queued_job_scheduled_fence);
queue->last_queued_job_scheduled_fence = NULL;
}
/**
* pvr_queue_destroy() - Destroy a queue.
* @queue: The queue to destroy.
*
* Cleanup the queue and free the resources attached to it. Should be
* called from the context release function.
*/
void pvr_queue_destroy(struct pvr_queue *queue)
{
if (!queue)
return;
mutex_lock(&queue->ctx->pvr_dev->queues.lock);
list_del_init(&queue->node);
mutex_unlock(&queue->ctx->pvr_dev->queues.lock);
drm_sched_fini(&queue->scheduler);
drm_sched_entity_fini(&queue->entity);
if (WARN_ON(queue->last_queued_job_scheduled_fence))
dma_fence_put(queue->last_queued_job_scheduled_fence);
pvr_queue_cleanup_fw_context(queue);
pvr_fw_object_unmap_and_destroy(queue->timeline_ufo.fw_obj);
pvr_fw_object_destroy(queue->reg_state_obj);
pvr_cccb_fini(&queue->cccb);
mutex_destroy(&queue->cccb_fence_ctx.job_lock);
kfree(queue);
}
/**
* pvr_queue_device_init() - Device-level initialization of queue related fields.
* @pvr_dev: The device to initialize.
*
* Initializes all fields related to queue management in pvr_device.
*
* Return:
* * 0 on success, or
* * An error code on failure.
*/
int pvr_queue_device_init(struct pvr_device *pvr_dev)
{
int err;
INIT_LIST_HEAD(&pvr_dev->queues.active);
INIT_LIST_HEAD(&pvr_dev->queues.idle);
err = drmm_mutex_init(from_pvr_device(pvr_dev), &pvr_dev->queues.lock);
if (err)
return err;
pvr_dev->sched_wq = alloc_workqueue("powervr-sched", WQ_UNBOUND, 0);
if (!pvr_dev->sched_wq)
return -ENOMEM;
return 0;
}
/**
* pvr_queue_device_fini() - Device-level cleanup of queue related fields.
* @pvr_dev: The device to cleanup.
*
* Cleanup/free all queue-related resources attached to a pvr_device object.
*/
void pvr_queue_device_fini(struct pvr_device *pvr_dev)
{
destroy_workqueue(pvr_dev->sched_wq);
}