Google Git
Sign in
nest-open-source / manifest_repos / mali-driver / refs/heads/main / . / bifrost / r32p1 / kernel / drivers / gpu / arm / midgard / mali_kbase_jd.c
blob: 83977f89b5088c710a00318426f1cc07eeb54426 [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0 WITH Linux-syscall-note
/*
*
* (C) COPYRIGHT 2010-2021 ARM Limited. All rights reserved.
*
* This program is free software and is provided to you under the terms of the
* GNU General Public License version 2 as published by the Free Software
* Foundation, and any use by you of this program is subject to the terms
* of such GNU license.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, you can access it online at
* http://www.gnu.org/licenses/gpl-2.0.html.
*
*/
#include <linux/dma-buf.h>
#if IS_ENABLED(CONFIG_COMPAT)
#include <linux/compat.h>
#endif
#include <mali_kbase.h>
#include <linux/random.h>
#include <linux/version.h>
#include <linux/ratelimit.h>
#include <linux/priority_control_manager.h>
#include <mali_kbase_jm.h>
#include <mali_kbase_kinstr_jm.h>
#include <mali_kbase_hwaccess_jm.h>
#include <tl/mali_kbase_tracepoints.h>
#include <mali_linux_trace.h>
#include "mali_kbase_dma_fence.h"
#include <mali_kbase_cs_experimental.h>
#include <mali_kbase_caps.h>
#define beenthere(kctx, f, a...) dev_dbg(kctx->kbdev->dev, "%s:" f, __func__, ##a)
/* Return whether katom will run on the GPU or not. Currently only soft jobs and
* dependency-only atoms do not run on the GPU
*/
#define IS_GPU_ATOM(katom) (!((katom->core_req & BASE_JD_REQ_SOFT_JOB) || \
((katom->core_req & BASE_JD_REQ_ATOM_TYPE) == \
BASE_JD_REQ_DEP)))
/*
* This is the kernel side of the API. Only entry points are:
* - kbase_jd_submit(): Called from userspace to submit a single bag
* - kbase_jd_done(): Called from interrupt context to track the
* completion of a job.
* Callouts:
* - to the job manager (enqueue a job)
* - to the event subsystem (signals the completion/failure of bag/job-chains).
*/
static void __user *
get_compat_pointer(struct kbase_context *kctx, const u64 p)
{
#if IS_ENABLED(CONFIG_COMPAT)
if (kbase_ctx_flag(kctx, KCTX_COMPAT))
return compat_ptr(p);
#endif
return u64_to_user_ptr(p);
}
/* Mark an atom as complete, and trace it in kinstr_jm */
static void jd_mark_atom_complete(struct kbase_jd_atom *katom)
{
katom->status = KBASE_JD_ATOM_STATE_COMPLETED;
kbase_kinstr_jm_atom_complete(katom);
dev_dbg(katom->kctx->kbdev->dev, "Atom %pK status to completed\n",
(void *)katom);
}
/* Runs an atom, either by handing to the JS or by immediately running it in the case of soft-jobs
*
* Returns whether the JS needs a reschedule.
*
* Note that the caller must also check the atom status and
* if it is KBASE_JD_ATOM_STATE_COMPLETED must call jd_done_nolock
*/
static bool jd_run_atom(struct kbase_jd_atom *katom)
{
struct kbase_context *kctx = katom->kctx;
dev_dbg(kctx->kbdev->dev, "JD run atom %pK in kctx %pK\n",
(void *)katom, (void *)kctx);
KBASE_DEBUG_ASSERT(katom->status != KBASE_JD_ATOM_STATE_UNUSED);
if ((katom->core_req & BASE_JD_REQ_ATOM_TYPE) == BASE_JD_REQ_DEP) {
/* Dependency only atom */
trace_sysgraph(SGR_SUBMIT, kctx->id,
kbase_jd_atom_id(katom->kctx, katom));
jd_mark_atom_complete(katom);
return false;
} else if (katom->core_req & BASE_JD_REQ_SOFT_JOB) {
/* Soft-job */
if (katom->will_fail_event_code) {
kbase_finish_soft_job(katom);
jd_mark_atom_complete(katom);
return false;
}
if (kbase_process_soft_job(katom) == 0) {
kbase_finish_soft_job(katom);
jd_mark_atom_complete(katom);
}
return false;
}
katom->status = KBASE_JD_ATOM_STATE_IN_JS;
dev_dbg(kctx->kbdev->dev, "Atom %pK status to in JS\n", (void *)katom);
/* Queue an action about whether we should try scheduling a context */
return kbasep_js_add_job(kctx, katom);
}
void kbase_jd_dep_clear_locked(struct kbase_jd_atom *katom)
{
struct kbase_device *kbdev;
KBASE_DEBUG_ASSERT(katom);
kbdev = katom->kctx->kbdev;
KBASE_DEBUG_ASSERT(kbdev);
/* Check whether the atom's other dependencies were already met. If
* katom is a GPU atom then the job scheduler may be able to represent
* the dependencies, hence we may attempt to submit it before they are
* met. Other atoms must have had both dependencies resolved.
*/
if (IS_GPU_ATOM(katom) ||
(!kbase_jd_katom_dep_atom(&katom->dep[0]) &&
!kbase_jd_katom_dep_atom(&katom->dep[1]))) {
/* katom dep complete, attempt to run it */
bool resched = false;
resched = jd_run_atom(katom);
if (katom->status == KBASE_JD_ATOM_STATE_COMPLETED) {
/* The atom has already finished */
resched |= jd_done_nolock(katom, NULL);
}
if (resched)
kbase_js_sched_all(kbdev);
}
}
void kbase_jd_free_external_resources(struct kbase_jd_atom *katom)
{
#ifdef CONFIG_MALI_DMA_FENCE
/* Flush dma-fence workqueue to ensure that any callbacks that may have
* been queued are done before continuing.
* Any successfully completed atom would have had all it's callbacks
* completed before the atom was run, so only flush for failed atoms.
*/
if (katom->event_code != BASE_JD_EVENT_DONE)
flush_workqueue(katom->kctx->dma_fence.wq);
#endif /* CONFIG_MALI_DMA_FENCE */
}
static void kbase_jd_post_external_resources(struct kbase_jd_atom *katom)
{
KBASE_DEBUG_ASSERT(katom);
KBASE_DEBUG_ASSERT(katom->core_req & BASE_JD_REQ_EXTERNAL_RESOURCES);
#ifdef CONFIG_MALI_DMA_FENCE
kbase_dma_fence_signal(katom);
#endif /* CONFIG_MALI_DMA_FENCE */
kbase_gpu_vm_lock(katom->kctx);
/* only roll back if extres is non-NULL */
if (katom->extres) {
u32 res_no;
res_no = katom->nr_extres;
while (res_no-- > 0) {
struct kbase_mem_phy_alloc *alloc = katom->extres[res_no].alloc;
struct kbase_va_region *reg;
reg = kbase_region_tracker_find_region_base_address(
katom->kctx,
katom->extres[res_no].gpu_address);
kbase_unmap_external_resource(katom->kctx, reg, alloc);
}
kfree(katom->extres);
katom->extres = NULL;
}
kbase_gpu_vm_unlock(katom->kctx);
}
/*
* Set up external resources needed by this job.
*
* jctx.lock must be held when this is called.
*/
static int kbase_jd_pre_external_resources(struct kbase_jd_atom *katom, const struct base_jd_atom *user_atom)
{
int err_ret_val = -EINVAL;
u32 res_no;
#ifdef CONFIG_MALI_DMA_FENCE
struct kbase_dma_fence_resv_info info = {
.resv_objs = NULL,
.dma_fence_resv_count = 0,
.dma_fence_excl_bitmap = NULL
};
#if defined(CONFIG_SYNC) || defined(CONFIG_SYNC_FILE)
/*
* When both dma-buf fence and Android native sync is enabled, we
* disable dma-buf fence for contexts that are using Android native
* fences.
*/
const bool implicit_sync = !kbase_ctx_flag(katom->kctx,
KCTX_NO_IMPLICIT_SYNC);
#else /* CONFIG_SYNC || CONFIG_SYNC_FILE*/
const bool implicit_sync = true;
#endif /* CONFIG_SYNC || CONFIG_SYNC_FILE */
#endif /* CONFIG_MALI_DMA_FENCE */
struct base_external_resource *input_extres;
KBASE_DEBUG_ASSERT(katom);
KBASE_DEBUG_ASSERT(katom->core_req & BASE_JD_REQ_EXTERNAL_RESOURCES);
/* no resources encoded, early out */
if (!katom->nr_extres)
return -EINVAL;
katom->extres = kmalloc_array(katom->nr_extres, sizeof(*katom->extres), GFP_KERNEL);
if (!katom->extres)
return -ENOMEM;
/* copy user buffer to the end of our real buffer.
* Make sure the struct sizes haven't changed in a way
* we don't support
*/
BUILD_BUG_ON(sizeof(*input_extres) > sizeof(*katom->extres));
input_extres = (struct base_external_resource *)
(((unsigned char *)katom->extres) +
(sizeof(*katom->extres) - sizeof(*input_extres)) *
katom->nr_extres);
if (copy_from_user(input_extres,
get_compat_pointer(katom->kctx, user_atom->extres_list),
sizeof(*input_extres) * katom->nr_extres) != 0) {
err_ret_val = -EINVAL;
goto early_err_out;
}
#ifdef CONFIG_MALI_DMA_FENCE
if (implicit_sync) {
info.resv_objs =
kmalloc_array(katom->nr_extres,
#if (KERNEL_VERSION(5, 4, 0) > LINUX_VERSION_CODE)
sizeof(struct reservation_object *),
#else
sizeof(struct dma_resv *),
#endif
GFP_KERNEL);
if (!info.resv_objs) {
err_ret_val = -ENOMEM;
goto early_err_out;
}
info.dma_fence_excl_bitmap =
kcalloc(BITS_TO_LONGS(katom->nr_extres),
sizeof(unsigned long), GFP_KERNEL);
if (!info.dma_fence_excl_bitmap) {
err_ret_val = -ENOMEM;
goto early_err_out;
}
}
#endif /* CONFIG_MALI_DMA_FENCE */
/* Take the processes mmap lock */
down_read(kbase_mem_get_process_mmap_lock());
/* need to keep the GPU VM locked while we set up UMM buffers */
kbase_gpu_vm_lock(katom->kctx);
for (res_no = 0; res_no < katom->nr_extres; res_no++) {
struct base_external_resource *res = &input_extres[res_no];
struct kbase_va_region *reg;
struct kbase_mem_phy_alloc *alloc;
#ifdef CONFIG_MALI_DMA_FENCE
bool exclusive;
exclusive = (res->ext_resource & BASE_EXT_RES_ACCESS_EXCLUSIVE)
? true : false;
#endif
reg = kbase_region_tracker_find_region_enclosing_address(
katom->kctx,
res->ext_resource & ~BASE_EXT_RES_ACCESS_EXCLUSIVE);
/* did we find a matching region object? */
if (kbase_is_region_invalid_or_free(reg)) {
/* roll back */
goto failed_loop;
}
if (!(katom->core_req & BASE_JD_REQ_SOFT_JOB) &&
(reg->flags & KBASE_REG_PROTECTED)) {
katom->atom_flags |= KBASE_KATOM_FLAG_PROTECTED;
}
alloc = kbase_map_external_resource(katom->kctx, reg,
current->mm);
if (!alloc) {
err_ret_val = -EINVAL;
goto failed_loop;
}
#ifdef CONFIG_MALI_DMA_FENCE
if (implicit_sync &&
reg->gpu_alloc->type == KBASE_MEM_TYPE_IMPORTED_UMM) {
#if (KERNEL_VERSION(5, 4, 0) > LINUX_VERSION_CODE)
struct reservation_object *resv;
#else
struct dma_resv *resv;
#endif
resv = reg->gpu_alloc->imported.umm.dma_buf->resv;
if (resv)
kbase_dma_fence_add_reservation(resv, &info,
exclusive);
}
#endif /* CONFIG_MALI_DMA_FENCE */
/* finish with updating out array with the data we found */
/* NOTE: It is important that this is the last thing we do (or
* at least not before the first write) as we overwrite elements
* as we loop and could be overwriting ourself, so no writes
* until the last read for an element.
*/
katom->extres[res_no].gpu_address = reg->start_pfn << PAGE_SHIFT; /* save the start_pfn (as an address, not pfn) to use fast lookup later */
katom->extres[res_no].alloc = alloc;
}
/* successfully parsed the extres array */
/* drop the vm lock now */
kbase_gpu_vm_unlock(katom->kctx);
/* Release the processes mmap lock */
up_read(kbase_mem_get_process_mmap_lock());
#ifdef CONFIG_MALI_DMA_FENCE
if (implicit_sync) {
if (info.dma_fence_resv_count) {
int ret;
ret = kbase_dma_fence_wait(katom, &info);
if (ret < 0)
goto failed_dma_fence_setup;
}
kfree(info.resv_objs);
kfree(info.dma_fence_excl_bitmap);
}
#endif /* CONFIG_MALI_DMA_FENCE */
/* all done OK */
return 0;
/* error handling section */
#ifdef CONFIG_MALI_DMA_FENCE
failed_dma_fence_setup:
/* Lock the processes mmap lock */
down_read(kbase_mem_get_process_mmap_lock());
/* lock before we unmap */
kbase_gpu_vm_lock(katom->kctx);
#endif
failed_loop:
/* undo the loop work */
while (res_no-- > 0) {
struct kbase_mem_phy_alloc *alloc = katom->extres[res_no].alloc;
kbase_unmap_external_resource(katom->kctx, NULL, alloc);
}
kbase_gpu_vm_unlock(katom->kctx);
/* Release the processes mmap lock */
up_read(kbase_mem_get_process_mmap_lock());
early_err_out:
kfree(katom->extres);
katom->extres = NULL;
#ifdef CONFIG_MALI_DMA_FENCE
if (implicit_sync) {
kfree(info.resv_objs);
kfree(info.dma_fence_excl_bitmap);
}
#endif
return err_ret_val;
}
static inline void jd_resolve_dep(struct list_head *out_list,
struct kbase_jd_atom *katom,
u8 d, bool ctx_is_dying)
{
u8 other_d = !d;
while (!list_empty(&katom->dep_head[d])) {
struct kbase_jd_atom *dep_atom;
struct kbase_jd_atom *other_dep_atom;
u8 dep_type;
dep_atom = list_entry(katom->dep_head[d].next,
struct kbase_jd_atom, dep_item[d]);
list_del(katom->dep_head[d].next);
dep_type = kbase_jd_katom_dep_type(&dep_atom->dep[d]);
kbase_jd_katom_dep_clear(&dep_atom->dep[d]);
if (katom->event_code != BASE_JD_EVENT_DONE &&
(dep_type != BASE_JD_DEP_TYPE_ORDER)) {
#ifdef CONFIG_MALI_DMA_FENCE
kbase_dma_fence_cancel_callbacks(dep_atom);
#endif
dep_atom->event_code = katom->event_code;
KBASE_DEBUG_ASSERT(dep_atom->status !=
KBASE_JD_ATOM_STATE_UNUSED);
dep_atom->will_fail_event_code = dep_atom->event_code;
}
other_dep_atom = (struct kbase_jd_atom *)
kbase_jd_katom_dep_atom(&dep_atom->dep[other_d]);
if (!dep_atom->in_jd_list && (!other_dep_atom ||
(IS_GPU_ATOM(dep_atom) && !ctx_is_dying &&
!dep_atom->will_fail_event_code &&
!other_dep_atom->will_fail_event_code))) {
bool dep_satisfied = true;
#ifdef CONFIG_MALI_DMA_FENCE
int dep_count;
dep_count = kbase_fence_dep_count_read(dep_atom);
if (likely(dep_count == -1)) {
dep_satisfied = true;
} else {
/*
* There are either still active callbacks, or
* all fences for this @dep_atom has signaled,
* but the worker that will queue the atom has
* not yet run.
*
* Wait for the fences to signal and the fence
* worker to run and handle @dep_atom. If
* @dep_atom was completed due to error on
* @katom, then the fence worker will pick up
* the complete status and error code set on
* @dep_atom above.
*/
dep_satisfied = false;
}
#endif /* CONFIG_MALI_DMA_FENCE */
if (dep_satisfied) {
dep_atom->in_jd_list = true;
list_add_tail(&dep_atom->jd_item, out_list);
}
}
}
}
/**
* is_dep_valid - Validate that a dependency is valid for early dependency
* submission
* @katom: Dependency atom to validate
*
* A dependency is valid if any of the following are true :
* - It does not exist (a non-existent dependency does not block submission)
* - It is in the job scheduler
* - It has completed, does not have a failure event code, and has not been
* marked to fail in the future
*
* Return: true if valid, false otherwise
*/
static bool is_dep_valid(struct kbase_jd_atom *katom)
{
/* If there's no dependency then this is 'valid' from the perspective of
* early dependency submission
*/
if (!katom)
return true;
/* Dependency must have reached the job scheduler */
if (katom->status < KBASE_JD_ATOM_STATE_IN_JS)
return false;
/* If dependency has completed and has failed or will fail then it is
* not valid
*/
if (katom->status >= KBASE_JD_ATOM_STATE_HW_COMPLETED &&
(katom->event_code != BASE_JD_EVENT_DONE ||
katom->will_fail_event_code))
return false;
return true;
}
static void jd_try_submitting_deps(struct list_head *out_list,
struct kbase_jd_atom *node)
{
int i;
for (i = 0; i < 2; i++) {
struct list_head *pos;
list_for_each(pos, &node->dep_head[i]) {
struct kbase_jd_atom *dep_atom = list_entry(pos,
struct kbase_jd_atom, dep_item[i]);
if (IS_GPU_ATOM(dep_atom) && !dep_atom->in_jd_list) {
/*Check if atom deps look sane*/
bool dep0_valid = is_dep_valid(
dep_atom->dep[0].atom);
bool dep1_valid = is_dep_valid(
dep_atom->dep[1].atom);
bool dep_satisfied = true;
#ifdef CONFIG_MALI_DMA_FENCE
int dep_count;
dep_count = kbase_fence_dep_count_read(
dep_atom);
if (likely(dep_count == -1)) {
dep_satisfied = true;
} else {
/*
* There are either still active callbacks, or
* all fences for this @dep_atom has signaled,
* but the worker that will queue the atom has
* not yet run.
*
* Wait for the fences to signal and the fence
* worker to run and handle @dep_atom. If
* @dep_atom was completed due to error on
* @katom, then the fence worker will pick up
* the complete status and error code set on
* @dep_atom above.
*/
dep_satisfied = false;
}
#endif /* CONFIG_MALI_DMA_FENCE */
if (dep0_valid && dep1_valid && dep_satisfied) {
dep_atom->in_jd_list = true;
list_add(&dep_atom->jd_item, out_list);
}
}
}
}
}
#if MALI_JIT_PRESSURE_LIMIT_BASE
/**
* jd_update_jit_usage - Update just-in-time physical memory usage for an atom.
*
* @katom: An atom that has just finished.
*
* Read back actual just-in-time memory region usage from atoms that provide
* this information, and update the current physical page pressure.
*
* The caller must hold the kbase_jd_context.lock.
*/
static void jd_update_jit_usage(struct kbase_jd_atom *katom)
{
struct kbase_context *kctx = katom->kctx;
struct kbase_va_region *reg;
struct kbase_vmap_struct mapping;
u64 *ptr;
u64 used_pages;
unsigned int idx;
lockdep_assert_held(&kctx->jctx.lock);
/* If this atom wrote to JIT memory, find out how much it has written
* and update the usage information in the region.
*/
for (idx = 0;
idx < ARRAY_SIZE(katom->jit_ids) && katom->jit_ids[idx];
idx++) {
enum heap_pointer { LOW = 0, HIGH, COUNT };
size_t size_to_read;
u64 read_val;
reg = kctx->jit_alloc[katom->jit_ids[idx]];
if (!reg) {
dev_warn(kctx->kbdev->dev,
"%s: JIT id[%u]=%u has no region\n",
__func__, idx, katom->jit_ids[idx]);
continue;
}
if (reg == KBASE_RESERVED_REG_JIT_ALLOC) {
dev_warn(kctx->kbdev->dev,
"%s: JIT id[%u]=%u has failed to allocate a region\n",
__func__, idx, katom->jit_ids[idx]);
continue;
}
if (!reg->heap_info_gpu_addr)
continue;
size_to_read = sizeof(*ptr);
if (reg->flags & KBASE_REG_HEAP_INFO_IS_SIZE)
size_to_read = sizeof(u32);
else if (reg->flags & KBASE_REG_TILER_ALIGN_TOP)
size_to_read = sizeof(u64[COUNT]);
ptr = kbase_vmap(kctx, reg->heap_info_gpu_addr, size_to_read,
&mapping);
if (!ptr) {
dev_warn(kctx->kbdev->dev,
"%s: JIT id[%u]=%u start=0x%llx unable to map end marker %llx\n",
__func__, idx, katom->jit_ids[idx],
reg->start_pfn << PAGE_SHIFT,
reg->heap_info_gpu_addr);
continue;
}
if (reg->flags & KBASE_REG_HEAP_INFO_IS_SIZE) {
read_val = READ_ONCE(*(u32 *)ptr);
used_pages = PFN_UP(read_val);
} else {
u64 addr_end;
if (reg->flags & KBASE_REG_TILER_ALIGN_TOP) {
const unsigned long extension_bytes =
reg->extension << PAGE_SHIFT;
const u64 low_ptr = ptr[LOW];
const u64 high_ptr = ptr[HIGH];
/* As either the low or high pointer could
* consume their partition and move onto the
* next chunk, we need to account for both.
* In the case where nothing has been allocated
* from the high pointer the whole chunk could
* be backed unnecessarily - but the granularity
* is the chunk size anyway and any non-zero
* offset of low pointer from the start of the
* chunk would result in the whole chunk being
* backed.
*/
read_val = max(high_ptr, low_ptr);
/* kbase_check_alloc_sizes() already satisfies
* this, but here to avoid future maintenance
* hazards
*/
WARN_ON(!is_power_of_2(extension_bytes));
addr_end = ALIGN(read_val, extension_bytes);
} else {
addr_end = read_val = READ_ONCE(*ptr);
}
if (addr_end >= (reg->start_pfn << PAGE_SHIFT))
used_pages = PFN_UP(addr_end) - reg->start_pfn;
else
used_pages = reg->used_pages;
}
trace_mali_jit_report(katom, reg, idx, read_val, used_pages);
kbase_trace_jit_report_gpu_mem(kctx, reg, 0u);
/* We can never have used more pages than the VA size of the
* region
*/
if (used_pages > reg->nr_pages) {
dev_warn(kctx->kbdev->dev,
"%s: JIT id[%u]=%u start=0x%llx used_pages %llx > %zx (read 0x%llx as %s%s)\n",
__func__, idx, katom->jit_ids[idx],
reg->start_pfn << PAGE_SHIFT,
used_pages, reg->nr_pages, read_val,
(reg->flags & KBASE_REG_HEAP_INFO_IS_SIZE) ?
"size" : "addr",
(reg->flags & KBASE_REG_TILER_ALIGN_TOP) ?
" with align" : "");
used_pages = reg->nr_pages;
}
/* Note: one real use case has an atom correctly reporting 0
* pages in use. This happens in normal use-cases but may only
* happen for a few of the application's frames.
*/
kbase_vunmap(kctx, &mapping);
kbase_jit_report_update_pressure(kctx, reg, used_pages, 0u);
}
kbase_jit_retry_pending_alloc(kctx);
}
#endif /* MALI_JIT_PRESSURE_LIMIT_BASE */
/*
* Perform the necessary handling of an atom that has finished running
* on the GPU.
*
* Note that if this is a soft-job that has had kbase_prepare_soft_job called on it then the caller
* is responsible for calling kbase_finish_soft_job *before* calling this function.
*
* The caller must hold the kbase_jd_context.lock.
*/
bool jd_done_nolock(struct kbase_jd_atom *katom,
struct list_head *completed_jobs_ctx)
{
struct kbase_context *kctx = katom->kctx;
struct list_head completed_jobs;
struct list_head runnable_jobs;
bool need_to_try_schedule_context = false;
int i;
INIT_LIST_HEAD(&completed_jobs);
INIT_LIST_HEAD(&runnable_jobs);
KBASE_DEBUG_ASSERT(katom->status != KBASE_JD_ATOM_STATE_UNUSED);
#if MALI_JIT_PRESSURE_LIMIT_BASE
if (kbase_ctx_flag(kctx, KCTX_JPL_ENABLED))
jd_update_jit_usage(katom);
#endif /* MALI_JIT_PRESSURE_LIMIT_BASE */
/* This is needed in case an atom is failed due to being invalid, this
* can happen *before* the jobs that the atom depends on have completed
*/
for (i = 0; i < 2; i++) {
if (kbase_jd_katom_dep_atom(&katom->dep[i])) {
list_del(&katom->dep_item[i]);
kbase_jd_katom_dep_clear(&katom->dep[i]);
}
}
jd_mark_atom_complete(katom);
list_add_tail(&katom->jd_item, &completed_jobs);
while (!list_empty(&completed_jobs)) {
katom = list_entry(completed_jobs.prev, struct kbase_jd_atom, jd_item);
list_del(completed_jobs.prev);
KBASE_DEBUG_ASSERT(katom->status == KBASE_JD_ATOM_STATE_COMPLETED);
for (i = 0; i < 2; i++)
jd_resolve_dep(&runnable_jobs, katom, i,
kbase_ctx_flag(kctx, KCTX_DYING));
if (katom->core_req & BASE_JD_REQ_EXTERNAL_RESOURCES)
kbase_jd_post_external_resources(katom);
while (!list_empty(&runnable_jobs)) {
struct kbase_jd_atom *node;
node = list_entry(runnable_jobs.next,
struct kbase_jd_atom, jd_item);
list_del(runnable_jobs.next);
node->in_jd_list = false;
dev_dbg(kctx->kbdev->dev, "List node %pK has status %d\n",
node, node->status);
KBASE_DEBUG_ASSERT(node->status != KBASE_JD_ATOM_STATE_UNUSED);
if (node->status == KBASE_JD_ATOM_STATE_IN_JS)
continue;
if (node->status != KBASE_JD_ATOM_STATE_COMPLETED &&
!kbase_ctx_flag(kctx, KCTX_DYING)) {
need_to_try_schedule_context |= jd_run_atom(node);
} else {
node->event_code = katom->event_code;
if (node->core_req &
BASE_JD_REQ_SOFT_JOB) {
WARN_ON(!list_empty(&node->queue));
kbase_finish_soft_job(node);
}
node->status = KBASE_JD_ATOM_STATE_COMPLETED;
}
if (node->status == KBASE_JD_ATOM_STATE_COMPLETED) {
list_add_tail(&node->jd_item, &completed_jobs);
} else if (node->status == KBASE_JD_ATOM_STATE_IN_JS &&
!node->will_fail_event_code) {
/* Node successfully submitted, try submitting
* dependencies as they may now be representable
* in JS
*/
jd_try_submitting_deps(&runnable_jobs, node);
}
}
/* Register a completed job as a disjoint event when the GPU
* is in a disjoint state (ie. being reset).
*/
kbase_disjoint_event_potential(kctx->kbdev);
if (completed_jobs_ctx)
list_add_tail(&katom->jd_item, completed_jobs_ctx);
else
kbase_event_post(kctx, katom);
/* Decrement and check the TOTAL number of jobs. This includes
* those not tracked by the scheduler: 'not ready to run' and
* 'dependency-only' jobs.
*/
if (--kctx->jctx.job_nr == 0)
/* All events are safely queued now, and we can signal
* any waiter that we've got no more jobs (so we can be
* safely terminated)
*/
wake_up(&kctx->jctx.zero_jobs_wait);
}
return need_to_try_schedule_context;
}
KBASE_EXPORT_TEST_API(jd_done_nolock);
#if IS_ENABLED(CONFIG_GPU_TRACEPOINTS)
enum {
CORE_REQ_DEP_ONLY,
CORE_REQ_SOFT,
CORE_REQ_COMPUTE,
CORE_REQ_FRAGMENT,
CORE_REQ_VERTEX,
CORE_REQ_TILER,
CORE_REQ_FRAGMENT_VERTEX,
CORE_REQ_FRAGMENT_VERTEX_TILER,
CORE_REQ_FRAGMENT_TILER,
CORE_REQ_VERTEX_TILER,
CORE_REQ_UNKNOWN
};
static const char * const core_req_strings[] = {
"Dependency Only Job",
"Soft Job",
"Compute Shader Job",
"Fragment Shader Job",
"Vertex/Geometry Shader Job",
"Tiler Job",
"Fragment Shader + Vertex/Geometry Shader Job",
"Fragment Shader + Vertex/Geometry Shader Job + Tiler Job",
"Fragment Shader + Tiler Job",
"Vertex/Geometry Shader Job + Tiler Job",
"Unknown Job"
};
static const char *kbasep_map_core_reqs_to_string(base_jd_core_req core_req)
{
if (core_req & BASE_JD_REQ_SOFT_JOB)
return core_req_strings[CORE_REQ_SOFT];
if (core_req & BASE_JD_REQ_ONLY_COMPUTE)
return core_req_strings[CORE_REQ_COMPUTE];
switch (core_req & (BASE_JD_REQ_FS | BASE_JD_REQ_CS | BASE_JD_REQ_T)) {
case BASE_JD_REQ_DEP:
return core_req_strings[CORE_REQ_DEP_ONLY];
case BASE_JD_REQ_FS:
return core_req_strings[CORE_REQ_FRAGMENT];
case BASE_JD_REQ_CS:
return core_req_strings[CORE_REQ_VERTEX];
case BASE_JD_REQ_T:
return core_req_strings[CORE_REQ_TILER];
case (BASE_JD_REQ_FS | BASE_JD_REQ_CS):
return core_req_strings[CORE_REQ_FRAGMENT_VERTEX];
case (BASE_JD_REQ_FS | BASE_JD_REQ_T):
return core_req_strings[CORE_REQ_FRAGMENT_TILER];
case (BASE_JD_REQ_CS | BASE_JD_REQ_T):
return core_req_strings[CORE_REQ_VERTEX_TILER];
case (BASE_JD_REQ_FS | BASE_JD_REQ_CS | BASE_JD_REQ_T):
return core_req_strings[CORE_REQ_FRAGMENT_VERTEX_TILER];
}
return core_req_strings[CORE_REQ_UNKNOWN];
}
#endif
/* Trace an atom submission. */
static void jd_trace_atom_submit(struct kbase_context *const kctx,
struct kbase_jd_atom *const katom,
int *priority)
{
struct kbase_device *const kbdev = kctx->kbdev;
KBASE_TLSTREAM_TL_NEW_ATOM(kbdev, katom, kbase_jd_atom_id(kctx, katom));
KBASE_TLSTREAM_TL_RET_ATOM_CTX(kbdev, katom, kctx);
if (priority)
KBASE_TLSTREAM_TL_ATTRIB_ATOM_PRIORITY(kbdev, katom, *priority);
KBASE_TLSTREAM_TL_ATTRIB_ATOM_STATE(kbdev, katom, TL_ATOM_STATE_IDLE);
kbase_kinstr_jm_atom_queue(katom);
}
static bool jd_submit_atom(struct kbase_context *const kctx,
const struct base_jd_atom *const user_atom,
const struct base_jd_fragment *const user_jc_incr,
struct kbase_jd_atom *const katom)
{
struct kbase_device *kbdev = kctx->kbdev;
struct kbase_jd_context *jctx = &kctx->jctx;
int queued = 0;
int i;
int sched_prio;
bool will_fail = false;
unsigned long flags;
enum kbase_jd_atom_state status;
dev_dbg(kbdev->dev, "User did JD submit atom %pK\n", (void *)katom);
/* Update the TOTAL number of jobs. This includes those not tracked by
* the scheduler: 'not ready to run' and 'dependency-only' jobs.
*/
jctx->job_nr++;
#if KERNEL_VERSION(4, 10, 0) > LINUX_VERSION_CODE
katom->start_timestamp.tv64 = 0;
#else
katom->start_timestamp = 0;
#endif
katom->udata = user_atom->udata;
katom->kctx = kctx;
katom->nr_extres = user_atom->nr_extres;
katom->extres = NULL;
katom->device_nr = user_atom->device_nr;
katom->jc = user_atom->jc;
katom->core_req = user_atom->core_req;
katom->jobslot = user_atom->jobslot;
katom->seq_nr = user_atom->seq_nr;
katom->atom_flags = 0;
katom->retry_count = 0;
katom->need_cache_flush_cores_retained = 0;
katom->pre_dep = NULL;
katom->post_dep = NULL;
katom->x_pre_dep = NULL;
katom->x_post_dep = NULL;
katom->will_fail_event_code = BASE_JD_EVENT_NOT_STARTED;
katom->softjob_data = NULL;
trace_sysgraph(SGR_ARRIVE, kctx->id, user_atom->atom_number);
#if MALI_JIT_PRESSURE_LIMIT_BASE
/* Older API version atoms might have random values where jit_id now
* lives, but we must maintain backwards compatibility - handle the
* issue.
*/
if (!mali_kbase_supports_jit_pressure_limit(kctx->api_version)) {
katom->jit_ids[0] = 0;
katom->jit_ids[1] = 0;
} else {
katom->jit_ids[0] = user_atom->jit_id[0];
katom->jit_ids[1] = user_atom->jit_id[1];
}
#endif /* MALI_JIT_PRESSURE_LIMIT_BASE */
katom->renderpass_id = user_atom->renderpass_id;
/* Implicitly sets katom->protected_state.enter as well. */
katom->protected_state.exit = KBASE_ATOM_EXIT_PROTECTED_CHECK;
katom->age = kctx->age_count++;
INIT_LIST_HEAD(&katom->queue);
INIT_LIST_HEAD(&katom->jd_item);
#ifdef CONFIG_MALI_DMA_FENCE
kbase_fence_dep_count_set(katom, -1);
#endif
/* Don't do anything if there is a mess up with dependencies.
This is done in a separate cycle to check both the dependencies at ones, otherwise
it will be extra complexity to deal with 1st dependency ( just added to the list )
if only the 2nd one has invalid config.
*/
for (i = 0; i < 2; i++) {
int dep_atom_number = user_atom->pre_dep[i].atom_id;
base_jd_dep_type dep_atom_type = user_atom->pre_dep[i].dependency_type;
if (dep_atom_number) {
if (dep_atom_type != BASE_JD_DEP_TYPE_ORDER &&
dep_atom_type != BASE_JD_DEP_TYPE_DATA) {
katom->event_code = BASE_JD_EVENT_JOB_CONFIG_FAULT;
katom->status = KBASE_JD_ATOM_STATE_COMPLETED;
dev_dbg(kbdev->dev,
"Atom %pK status to completed\n",
(void *)katom);
/* Wrong dependency setup. Atom will be sent
* back to user space. Do not record any
* dependencies.
*/
jd_trace_atom_submit(kctx, katom, NULL);
return jd_done_nolock(katom, NULL);
}
}
}
/* Add dependencies */
for (i = 0; i < 2; i++) {
int dep_atom_number = user_atom->pre_dep[i].atom_id;
base_jd_dep_type dep_atom_type;
struct kbase_jd_atom *dep_atom = &jctx->atoms[dep_atom_number];
dep_atom_type = user_atom->pre_dep[i].dependency_type;
kbase_jd_katom_dep_clear(&katom->dep[i]);
if (!dep_atom_number)
continue;
if (dep_atom->status == KBASE_JD_ATOM_STATE_UNUSED ||
dep_atom->status == KBASE_JD_ATOM_STATE_COMPLETED) {
if (dep_atom->event_code == BASE_JD_EVENT_DONE)
continue;
/* don't stop this atom if it has an order dependency
* only to the failed one, try to submit it through
* the normal path
*/
if (dep_atom_type == BASE_JD_DEP_TYPE_ORDER &&
dep_atom->event_code > BASE_JD_EVENT_ACTIVE) {
continue;
}
/* Atom has completed, propagate the error code if any */
katom->event_code = dep_atom->event_code;
katom->status = KBASE_JD_ATOM_STATE_QUEUED;
dev_dbg(kbdev->dev, "Atom %pK status to queued\n",
(void *)katom);
/* This atom will be sent back to user space.
* Do not record any dependencies.
*/
jd_trace_atom_submit(kctx, katom, NULL);
will_fail = true;
} else {
/* Atom is in progress, add this atom to the list */
list_add_tail(&katom->dep_item[i], &dep_atom->dep_head[i]);
kbase_jd_katom_dep_set(&katom->dep[i], dep_atom, dep_atom_type);
queued = 1;
}
}
if (will_fail) {
if (!queued) {
if (katom->core_req & BASE_JD_REQ_SOFT_JOB) {
/* This softjob has failed due to a previous
* dependency, however we should still run the
* prepare & finish functions
*/
int err = kbase_prepare_soft_job(katom);
if (err >= 0)
kbase_finish_soft_job(katom);
}
return jd_done_nolock(katom, NULL);
}
katom->will_fail_event_code = katom->event_code;
}
/* These must occur after the above loop to ensure that an atom
* that depends on a previous atom with the same number behaves
* as expected
*/
katom->event_code = BASE_JD_EVENT_DONE;
katom->status = KBASE_JD_ATOM_STATE_QUEUED;
dev_dbg(kbdev->dev, "Atom %pK status to queued\n", (void *)katom);
/* For invalid priority, be most lenient and choose the default */
sched_prio = kbasep_js_atom_prio_to_sched_prio(user_atom->prio);
if (sched_prio == KBASE_JS_ATOM_SCHED_PRIO_INVALID)
sched_prio = KBASE_JS_ATOM_SCHED_PRIO_DEFAULT;
/* Cap the priority to jctx.max_priority */
katom->sched_priority = (sched_prio < kctx->jctx.max_priority) ?
kctx->jctx.max_priority : sched_prio;
/* Create a new atom. */
jd_trace_atom_submit(kctx, katom, &katom->sched_priority);
#if !MALI_INCREMENTAL_RENDERING
/* Reject atoms for incremental rendering if not supported */
if (katom->core_req &
(BASE_JD_REQ_START_RENDERPASS|BASE_JD_REQ_END_RENDERPASS)) {
dev_err(kctx->kbdev->dev,
"Rejecting atom with unsupported core_req 0x%x\n",
katom->core_req);
katom->event_code = BASE_JD_EVENT_JOB_INVALID;
return jd_done_nolock(katom, NULL);
}
#endif /* !MALI_INCREMENTAL_RENDERING */
if (katom->core_req & BASE_JD_REQ_END_RENDERPASS) {
WARN_ON(katom->jc != 0);
katom->jc_fragment = *user_jc_incr;
} else if (!katom->jc &&
(katom->core_req & BASE_JD_REQ_ATOM_TYPE) != BASE_JD_REQ_DEP) {
/* Reject atoms with job chain = NULL, as these cause issues
* with soft-stop
*/
dev_err(kctx->kbdev->dev, "Rejecting atom with jc = NULL\n");
katom->event_code = BASE_JD_EVENT_JOB_INVALID;
return jd_done_nolock(katom, NULL);
}
/* Reject atoms with an invalid device_nr */
if ((katom->core_req & BASE_JD_REQ_SPECIFIC_COHERENT_GROUP) &&
(katom->device_nr >= kctx->kbdev->gpu_props.num_core_groups)) {
dev_err(kctx->kbdev->dev,
"Rejecting atom with invalid device_nr %d\n",
katom->device_nr);
katom->event_code = BASE_JD_EVENT_JOB_INVALID;
return jd_done_nolock(katom, NULL);
}
/* Reject atoms with invalid core requirements */
if ((katom->core_req & BASE_JD_REQ_EXTERNAL_RESOURCES) &&
(katom->core_req & BASE_JD_REQ_EVENT_COALESCE)) {
dev_err(kctx->kbdev->dev,
"Rejecting atom with invalid core requirements\n");
katom->event_code = BASE_JD_EVENT_JOB_INVALID;
katom->core_req &= ~BASE_JD_REQ_EVENT_COALESCE;
return jd_done_nolock(katom, NULL);
}
/* Reject soft-job atom of certain types from accessing external resources */
if ((katom->core_req & BASE_JD_REQ_EXTERNAL_RESOURCES) &&
(((katom->core_req & BASE_JD_REQ_SOFT_JOB_TYPE) == BASE_JD_REQ_SOFT_FENCE_WAIT) ||
((katom->core_req & BASE_JD_REQ_SOFT_JOB_TYPE) == BASE_JD_REQ_SOFT_JIT_ALLOC) ||
((katom->core_req & BASE_JD_REQ_SOFT_JOB_TYPE) == BASE_JD_REQ_SOFT_JIT_FREE))) {
dev_err(kctx->kbdev->dev,
"Rejecting soft-job atom accessing external resources\n");
katom->event_code = BASE_JD_EVENT_JOB_INVALID;
return jd_done_nolock(katom, NULL);
}
if (katom->core_req & BASE_JD_REQ_EXTERNAL_RESOURCES) {
/* handle what we need to do to access the external resources */
if (kbase_jd_pre_external_resources(katom, user_atom) != 0) {
/* setup failed (no access, bad resource, unknown resource types, etc.) */
katom->event_code = BASE_JD_EVENT_JOB_INVALID;
return jd_done_nolock(katom, NULL);
}
}
#if !MALI_JIT_PRESSURE_LIMIT_BASE
if (mali_kbase_supports_jit_pressure_limit(kctx->api_version) &&
(user_atom->jit_id[0] || user_atom->jit_id[1])) {
/* JIT pressure limit is disabled, but we are receiving non-0
* JIT IDs - atom is invalid.
*/
katom->event_code = BASE_JD_EVENT_JOB_INVALID;
return jd_done_nolock(katom, NULL);
}
#endif /* MALI_JIT_PRESSURE_LIMIT_BASE */
/* Validate the atom. Function will return error if the atom is
* malformed.
*
* Soft-jobs never enter the job scheduler but have their own initialize method.
*
* If either fail then we immediately complete the atom with an error.
*/
if ((katom->core_req & BASE_JD_REQ_SOFT_JOB) == 0) {
if (!kbase_js_is_atom_valid(kctx->kbdev, katom)) {
katom->event_code = BASE_JD_EVENT_JOB_INVALID;
return jd_done_nolock(katom, NULL);
}
} else {
/* Soft-job */
if (kbase_prepare_soft_job(katom) != 0) {
katom->event_code = BASE_JD_EVENT_JOB_INVALID;
return jd_done_nolock(katom, NULL);
}
}
#if IS_ENABLED(CONFIG_GPU_TRACEPOINTS)
katom->work_id = atomic_inc_return(&jctx->work_id);
trace_gpu_job_enqueue(kctx->id, katom->work_id,
kbasep_map_core_reqs_to_string(katom->core_req));
#endif
if (queued && !IS_GPU_ATOM(katom))
return false;
#ifdef CONFIG_MALI_DMA_FENCE
if (kbase_fence_dep_count_read(katom) != -1)
return false;
#endif /* CONFIG_MALI_DMA_FENCE */
if (katom->core_req & BASE_JD_REQ_SOFT_JOB) {
if (kbase_process_soft_job(katom) == 0) {
kbase_finish_soft_job(katom);
return jd_done_nolock(katom, NULL);
}
return false;
}
if ((katom->core_req & BASE_JD_REQ_ATOM_TYPE) != BASE_JD_REQ_DEP) {
bool need_to_try_schedule_context;
katom->status = KBASE_JD_ATOM_STATE_IN_JS;
dev_dbg(kctx->kbdev->dev, "Atom %pK status to in JS\n",
(void *)katom);
need_to_try_schedule_context = kbasep_js_add_job(kctx, katom);
/* If job was cancelled then resolve immediately */
if (katom->event_code != BASE_JD_EVENT_JOB_CANCELLED)
return need_to_try_schedule_context;
/* Synchronize with backend reset */
spin_lock_irqsave(&kbdev->hwaccess_lock, flags);
status = katom->status;
spin_unlock_irqrestore(&kbdev->hwaccess_lock, flags);
if (status == KBASE_JD_ATOM_STATE_HW_COMPLETED) {
dev_dbg(kctx->kbdev->dev,
"Atom %d cancelled on HW\n",
kbase_jd_atom_id(katom->kctx, katom));
return need_to_try_schedule_context;
}
}
/* This is a pure dependency. Resolve it immediately */
return jd_done_nolock(katom, NULL);
}
int kbase_jd_submit(struct kbase_context *kctx,
void __user *user_addr, u32 nr_atoms, u32 stride,
bool uk6_atom)
{
struct kbase_jd_context *jctx = &kctx->jctx;
int err = 0;
int i;
bool need_to_try_schedule_context = false;
struct kbase_device *kbdev;
u32 latest_flush;
bool jd_atom_is_v2 = (stride == sizeof(struct base_jd_atom_v2) ||
stride == offsetof(struct base_jd_atom_v2, renderpass_id));
/*
* kbase_jd_submit isn't expected to fail and so all errors with the
* jobs are reported by immediately failing them (through event system)
*/
kbdev = kctx->kbdev;
beenthere(kctx, "%s", "Enter");
if (kbase_ctx_flag(kctx, KCTX_SUBMIT_DISABLED)) {
dev_err(kbdev->dev, "Attempt to submit to a context that has SUBMIT_DISABLED set on it\n");
return -EINVAL;
}
if (stride != offsetof(struct base_jd_atom_v2, renderpass_id) &&
stride != sizeof(struct base_jd_atom_v2) &&
stride != offsetof(struct base_jd_atom, renderpass_id) &&
stride != sizeof(struct base_jd_atom)) {
dev_err(kbdev->dev,
"Stride %u passed to job_submit isn't supported by the kernel\n",
stride);
return -EINVAL;
}
/* All atoms submitted in this call have the same flush ID */
latest_flush = kbase_backend_get_current_flush_id(kbdev);
for (i = 0; i < nr_atoms; i++) {
struct base_jd_atom user_atom;
struct base_jd_fragment user_jc_incr;
struct kbase_jd_atom *katom;
if (unlikely(jd_atom_is_v2)) {
if (copy_from_user(&user_atom.jc, user_addr, sizeof(struct base_jd_atom_v2)) != 0) {
dev_dbg(kbdev->dev,
"Invalid atom address %p passed to job_submit\n",
user_addr);
err = -EFAULT;
break;
}
/* no seq_nr in v2 */
user_atom.seq_nr = 0;
} else {
if (copy_from_user(&user_atom, user_addr, stride) != 0) {
dev_dbg(kbdev->dev,
"Invalid atom address %p passed to job_submit\n",
user_addr);
err = -EFAULT;
break;
}
}
if (stride == offsetof(struct base_jd_atom_v2, renderpass_id)) {
dev_dbg(kbdev->dev, "No renderpass ID: use 0\n");
user_atom.renderpass_id = 0;
} else {
/* Ensure all padding bytes are 0 for potential future
* extension
*/
size_t j;
dev_dbg(kbdev->dev, "Renderpass ID is %d\n",
user_atom.renderpass_id);
for (j = 0; j < sizeof(user_atom.padding); j++) {
if (user_atom.padding[j]) {
dev_err(kbdev->dev,
"Bad padding byte %zu: %d\n",
j, user_atom.padding[j]);
err = -EINVAL;
break;
}
}
if (err)
break;
}
/* In this case 'jc' is the CPU address of a struct
* instead of a GPU address of a job chain.
*/
if (user_atom.core_req & BASE_JD_REQ_END_RENDERPASS) {
if (copy_from_user(&user_jc_incr,
u64_to_user_ptr(user_atom.jc),
sizeof(user_jc_incr))) {
dev_err(kbdev->dev,
"Invalid jc address 0x%llx passed to job_submit\n",
user_atom.jc);
err = -EFAULT;
break;
}
dev_dbg(kbdev->dev, "Copied IR jobchain addresses\n");
user_atom.jc = 0;
}
user_addr = (void __user *)((uintptr_t) user_addr + stride);
mutex_lock(&jctx->lock);
#ifndef compiletime_assert
#define compiletime_assert_defined
#define compiletime_assert(x, msg) do { switch (0) { case 0: case (x):; } } \
while (false)
#endif
compiletime_assert((1 << (8*sizeof(user_atom.atom_number))) ==
BASE_JD_ATOM_COUNT,
"BASE_JD_ATOM_COUNT and base_atom_id type out of sync");
compiletime_assert(sizeof(user_atom.pre_dep[0].atom_id) ==
sizeof(user_atom.atom_number),
"BASE_JD_ATOM_COUNT and base_atom_id type out of sync");
#ifdef compiletime_assert_defined
#undef compiletime_assert
#undef compiletime_assert_defined
#endif
katom = &jctx->atoms[user_atom.atom_number];
/* Record the flush ID for the cache flush optimisation */
katom->flush_id = latest_flush;
while (katom->status != KBASE_JD_ATOM_STATE_UNUSED) {
/* Atom number is already in use, wait for the atom to
* complete
*/
mutex_unlock(&jctx->lock);
/* This thread will wait for the atom to complete. Due
* to thread scheduling we are not sure that the other
* thread that owns the atom will also schedule the
* context, so we force the scheduler to be active and
* hence eventually schedule this context at some point
* later.
*/
kbase_js_sched_all(kbdev);
if (wait_event_killable(katom->completed,
katom->status ==
KBASE_JD_ATOM_STATE_UNUSED) != 0) {
/* We're being killed so the result code
* doesn't really matter
*/
return 0;
}
mutex_lock(&jctx->lock);
}
need_to_try_schedule_context |= jd_submit_atom(kctx, &user_atom,
&user_jc_incr, katom);
/* Register a completed job as a disjoint event when the GPU is in a disjoint state
* (ie. being reset).
*/
kbase_disjoint_event_potential(kbdev);
mutex_unlock(&jctx->lock);
}
if (need_to_try_schedule_context)
kbase_js_sched_all(kbdev);
return err;
}
KBASE_EXPORT_TEST_API(kbase_jd_submit);
void kbase_jd_done_worker(struct work_struct *data)
{
struct kbase_jd_atom *katom = container_of(data, struct kbase_jd_atom, work);
struct kbase_jd_context *jctx;
struct kbase_context *kctx;
struct kbasep_js_kctx_info *js_kctx_info;
struct kbase_device *kbdev;
struct kbasep_js_device_data *js_devdata;
u64 cache_jc = katom->jc;
struct kbasep_js_atom_retained_state katom_retained_state;
bool context_idle;
base_jd_core_req core_req = katom->core_req;
/* Soft jobs should never reach this function */
KBASE_DEBUG_ASSERT((katom->core_req & BASE_JD_REQ_SOFT_JOB) == 0);
kctx = katom->kctx;
jctx = &kctx->jctx;
kbdev = kctx->kbdev;
js_kctx_info = &kctx->jctx.sched_info;
js_devdata = &kbdev->js_data;
dev_dbg(kbdev->dev, "Enter atom %pK done worker for kctx %pK\n",
(void *)katom, (void *)kctx);
KBASE_KTRACE_ADD_JM(kbdev, JD_DONE_WORKER, kctx, katom, katom->jc, 0);
kbase_backend_complete_wq(kbdev, katom);
/*
* Begin transaction on JD context and JS context
*/
mutex_lock(&jctx->lock);
KBASE_TLSTREAM_TL_ATTRIB_ATOM_STATE(kbdev, katom, TL_ATOM_STATE_DONE);
mutex_lock(&js_devdata->queue_mutex);
mutex_lock(&js_kctx_info->ctx.jsctx_mutex);
/* This worker only gets called on contexts that are scheduled *in*. This is
* because it only happens in response to an IRQ from a job that was
* running.
*/
KBASE_DEBUG_ASSERT(kbase_ctx_flag(kctx, KCTX_SCHEDULED));
if (katom->event_code == BASE_JD_EVENT_STOPPED) {
unsigned long flags;
dev_dbg(kbdev->dev, "Atom %pK has been promoted to stopped\n",
(void *)katom);
mutex_unlock(&js_kctx_info->ctx.jsctx_mutex);
mutex_unlock(&js_devdata->queue_mutex);
spin_lock_irqsave(&kbdev->hwaccess_lock, flags);
katom->status = KBASE_JD_ATOM_STATE_IN_JS;
dev_dbg(kctx->kbdev->dev, "Atom %pK status to in JS\n",
(void *)katom);
kbase_js_unpull(kctx, katom);
spin_unlock_irqrestore(&kbdev->hwaccess_lock, flags);
mutex_unlock(&jctx->lock);
return;
}
if ((katom->event_code != BASE_JD_EVENT_DONE) &&
(!kbase_ctx_flag(katom->kctx, KCTX_DYING))) {
meson_gpu_fault ++;
dev_err(kbdev->dev,
"t6xx: GPU fault 0x%02lx from job slot %d\n",
(unsigned long)katom->event_code,
katom->slot_nr);
}
/* Retain state before the katom disappears */
kbasep_js_atom_retained_state_copy(&katom_retained_state, katom);
context_idle = kbase_js_complete_atom_wq(kctx, katom);
KBASE_DEBUG_ASSERT(kbasep_js_has_atom_finished(&katom_retained_state));
kbasep_js_remove_job(kbdev, kctx, katom);
mutex_unlock(&js_kctx_info->ctx.jsctx_mutex);
mutex_unlock(&js_devdata->queue_mutex);
katom->atom_flags &= ~KBASE_KATOM_FLAG_HOLDING_CTX_REF;
/* jd_done_nolock() requires the jsctx_mutex lock to be dropped */
jd_done_nolock(katom, &kctx->completed_jobs);
/* katom may have been freed now, do not use! */
if (context_idle) {
unsigned long flags;
context_idle = false;
mutex_lock(&js_devdata->queue_mutex);
spin_lock_irqsave(&kbdev->hwaccess_lock, flags);
/* If kbase_sched() has scheduled this context back in then
* KCTX_ACTIVE will have been set after we marked it as
* inactive, and another pm reference will have been taken, so
* drop our reference. But do not call kbase_jm_idle_ctx(), as
* the context is active and fast-starting is allowed.
*
* If an atom has been fast-started then kctx->atoms_pulled will
* be non-zero but KCTX_ACTIVE will still be false (as the
* previous pm reference has been inherited). Do NOT drop our
* reference, as it has been re-used, and leave the context as
* active.
*
* If no new atoms have been started then KCTX_ACTIVE will still
* be false and atoms_pulled will be zero, so drop the reference
* and call kbase_jm_idle_ctx().
*
* As the checks are done under both the queue_mutex and
* hwaccess_lock is should be impossible for this to race
* with the scheduler code.
*/
if (kbase_ctx_flag(kctx, KCTX_ACTIVE) ||
!atomic_read(&kctx->atoms_pulled)) {
/* Calling kbase_jm_idle_ctx() here will ensure that
* atoms are not fast-started when we drop the
* hwaccess_lock. This is not performed if
* KCTX_ACTIVE is set as in that case another pm
* reference has been taken and a fast-start would be
* valid.
*/
if (!kbase_ctx_flag(kctx, KCTX_ACTIVE))
kbase_jm_idle_ctx(kbdev, kctx);
context_idle = true;
} else {
kbase_ctx_flag_set(kctx, KCTX_ACTIVE);
}
spin_unlock_irqrestore(&kbdev->hwaccess_lock, flags);
mutex_unlock(&js_devdata->queue_mutex);
}
/*
* Transaction complete
*/
mutex_unlock(&jctx->lock);
/* Job is now no longer running, so can now safely release the context
* reference, and handle any actions that were logged against the
* atom's retained state
*/
kbasep_js_runpool_release_ctx_and_katom_retained_state(kbdev, kctx, &katom_retained_state);
kbase_js_sched_all(kbdev);
if (!atomic_dec_return(&kctx->work_count)) {
/* If worker now idle then post all events that jd_done_nolock()
* has queued
*/
mutex_lock(&jctx->lock);
while (!list_empty(&kctx->completed_jobs)) {
struct kbase_jd_atom *atom = list_entry(
kctx->completed_jobs.next,
struct kbase_jd_atom, jd_item);
list_del(kctx->completed_jobs.next);
kbase_event_post(kctx, atom);
}
mutex_unlock(&jctx->lock);
}
kbase_backend_complete_wq_post_sched(kbdev, core_req);
if (context_idle)
kbase_pm_context_idle(kbdev);
KBASE_KTRACE_ADD_JM(kbdev, JD_DONE_WORKER_END, kctx, NULL, cache_jc, 0);
dev_dbg(kbdev->dev, "Leave atom %pK done worker for kctx %pK\n",
(void *)katom, (void *)kctx);
}
/**
* jd_cancel_worker - Work queue job cancel function.
* @data: a &struct work_struct
*
* Only called as part of 'Zapping' a context (which occurs on termination).
* Operates serially with the kbase_jd_done_worker() on the work queue.
*
* This can only be called on contexts that aren't scheduled.
*
* We don't need to release most of the resources that would occur on
* kbase_jd_done() or kbase_jd_done_worker(), because the atoms here must not be
* running (by virtue of only being called on contexts that aren't
* scheduled).
*/
static void jd_cancel_worker(struct work_struct *data)
{
struct kbase_jd_atom *katom = container_of(data, struct kbase_jd_atom, work);
struct kbase_jd_context *jctx;
struct kbase_context *kctx;
struct kbasep_js_kctx_info *js_kctx_info;
bool need_to_try_schedule_context;
bool attr_state_changed;
struct kbase_device *kbdev;
/* Soft jobs should never reach this function */
KBASE_DEBUG_ASSERT((katom->core_req & BASE_JD_REQ_SOFT_JOB) == 0);
kctx = katom->kctx;
kbdev = kctx->kbdev;
jctx = &kctx->jctx;
js_kctx_info = &kctx->jctx.sched_info;
KBASE_KTRACE_ADD_JM(kbdev, JD_CANCEL_WORKER, kctx, katom, katom->jc, 0);
/* This only gets called on contexts that are scheduled out. Hence, we must
* make sure we don't de-ref the number of running jobs (there aren't
* any), nor must we try to schedule out the context (it's already
* scheduled out).
*/
KBASE_DEBUG_ASSERT(!kbase_ctx_flag(kctx, KCTX_SCHEDULED));
/* Scheduler: Remove the job from the system */
mutex_lock(&js_kctx_info->ctx.jsctx_mutex);
attr_state_changed = kbasep_js_remove_cancelled_job(kbdev, kctx, katom);
mutex_unlock(&js_kctx_info->ctx.jsctx_mutex);
mutex_lock(&jctx->lock);
need_to_try_schedule_context = jd_done_nolock(katom, NULL);
/* Because we're zapping, we're not adding any more jobs to this ctx, so no need to
* schedule the context. There's also no need for the jsctx_mutex to have been taken
* around this too.
*/
KBASE_DEBUG_ASSERT(!need_to_try_schedule_context);
/* katom may have been freed now, do not use! */
mutex_unlock(&jctx->lock);
if (attr_state_changed)
kbase_js_sched_all(kbdev);
}
/**
* kbase_jd_done - Complete a job that has been removed from the Hardware
* @katom: atom which has been completed
* @slot_nr: slot the atom was on
* @end_timestamp: completion time
* @done_code: completion code
*
* This must be used whenever a job has been removed from the Hardware, e.g.:
* An IRQ indicates that the job finished (for both error and 'done' codes), or
* the job was evicted from the JS_HEAD_NEXT registers during a Soft/Hard stop.
*
* Some work is carried out immediately, and the rest is deferred onto a
* workqueue
*
* Context:
* This can be called safely from atomic context.
* The caller must hold kbdev->hwaccess_lock
*/
void kbase_jd_done(struct kbase_jd_atom *katom, int slot_nr,
ktime_t *end_timestamp, kbasep_js_atom_done_code done_code)
{
struct kbase_context *kctx;
struct kbase_device *kbdev;
KBASE_DEBUG_ASSERT(katom);
kctx = katom->kctx;
KBASE_DEBUG_ASSERT(kctx);
kbdev = kctx->kbdev;
KBASE_DEBUG_ASSERT(kbdev);
if (done_code & KBASE_JS_ATOM_DONE_EVICTED_FROM_NEXT)
katom->event_code = BASE_JD_EVENT_REMOVED_FROM_NEXT;
KBASE_KTRACE_ADD_JM(kbdev, JD_DONE, kctx, katom, katom->jc, 0);
kbase_job_check_leave_disjoint(kbdev, katom);
katom->slot_nr = slot_nr;
atomic_inc(&kctx->work_count);
#if IS_ENABLED(CONFIG_DEBUG_FS)
/* a failed job happened and is waiting for dumping*/
if (!katom->will_fail_event_code &&
kbase_debug_job_fault_process(katom, katom->event_code))
return;
#endif
WARN_ON(work_pending(&katom->work));
INIT_WORK(&katom->work, kbase_jd_done_worker);
queue_work(kctx->jctx.job_done_wq, &katom->work);
}
KBASE_EXPORT_TEST_API(kbase_jd_done);
void kbase_jd_cancel(struct kbase_device *kbdev, struct kbase_jd_atom *katom)
{
struct kbase_context *kctx;
KBASE_DEBUG_ASSERT(kbdev != NULL);
KBASE_DEBUG_ASSERT(katom != NULL);
kctx = katom->kctx;
KBASE_DEBUG_ASSERT(kctx != NULL);
dev_dbg(kbdev->dev, "JD: cancelling atom %pK\n", (void *)katom);
KBASE_KTRACE_ADD_JM(kbdev, JD_CANCEL, kctx, katom, katom->jc, 0);
/* This should only be done from a context that is not scheduled */
KBASE_DEBUG_ASSERT(!kbase_ctx_flag(kctx, KCTX_SCHEDULED));
WARN_ON(work_pending(&katom->work));
katom->event_code = BASE_JD_EVENT_JOB_CANCELLED;
INIT_WORK(&katom->work, jd_cancel_worker);
queue_work(kctx->jctx.job_done_wq, &katom->work);
}
void kbase_jd_zap_context(struct kbase_context *kctx)
{
struct kbase_jd_atom *katom;
struct list_head *entry, *tmp;
struct kbase_device *kbdev;
KBASE_DEBUG_ASSERT(kctx);
kbdev = kctx->kbdev;
KBASE_KTRACE_ADD_JM(kbdev, JD_ZAP_CONTEXT, kctx, NULL, 0u, 0u);
kbase_js_zap_context(kctx);
mutex_lock(&kctx->jctx.lock);
/*
* While holding the struct kbase_jd_context lock clean up jobs which are known to kbase but are
* queued outside the job scheduler.
*/
del_timer_sync(&kctx->soft_job_timeout);
list_for_each_safe(entry, tmp, &kctx->waiting_soft_jobs) {
katom = list_entry(entry, struct kbase_jd_atom, queue);
kbase_cancel_soft_job(katom);
}
#ifdef CONFIG_MALI_DMA_FENCE
kbase_dma_fence_cancel_all_atoms(kctx);
#endif
mutex_unlock(&kctx->jctx.lock);
#ifdef CONFIG_MALI_DMA_FENCE
/* Flush dma-fence workqueue to ensure that any callbacks that may have
* been queued are done before continuing.
*/
flush_workqueue(kctx->dma_fence.wq);
#endif
#if IS_ENABLED(CONFIG_DEBUG_FS)
kbase_debug_job_fault_kctx_unblock(kctx);
#endif
kbase_jm_wait_for_zero_jobs(kctx);
}
KBASE_EXPORT_TEST_API(kbase_jd_zap_context);
int kbase_jd_init(struct kbase_context *kctx)
{
int i;
int mali_err = 0;
struct priority_control_manager_device *pcm_device = NULL;
KBASE_DEBUG_ASSERT(kctx);
pcm_device = kctx->kbdev->pcm_dev;
kctx->jctx.max_priority = KBASE_JS_ATOM_SCHED_PRIO_REALTIME;
kctx->jctx.job_done_wq = alloc_workqueue("mali_jd",
WQ_HIGHPRI | WQ_UNBOUND, 1);
if (kctx->jctx.job_done_wq == NULL) {
mali_err = -ENOMEM;
goto out1;
}
for (i = 0; i < BASE_JD_ATOM_COUNT; i++) {
init_waitqueue_head(&kctx->jctx.atoms[i].completed);
INIT_LIST_HEAD(&kctx->jctx.atoms[i].dep_head[0]);
INIT_LIST_HEAD(&kctx->jctx.atoms[i].dep_head[1]);
/* Catch userspace attempting to use an atom which doesn't exist as a pre-dependency */
kctx->jctx.atoms[i].event_code = BASE_JD_EVENT_JOB_INVALID;
kctx->jctx.atoms[i].status = KBASE_JD_ATOM_STATE_UNUSED;
#if defined(CONFIG_MALI_DMA_FENCE) || defined(CONFIG_SYNC_FILE)
kctx->jctx.atoms[i].dma_fence.context =
dma_fence_context_alloc(1);
atomic_set(&kctx->jctx.atoms[i].dma_fence.seqno, 0);
INIT_LIST_HEAD(&kctx->jctx.atoms[i].dma_fence.callbacks);
#endif
}
for (i = 0; i < BASE_JD_RP_COUNT; i++)
kctx->jctx.renderpasses[i].state = KBASE_JD_RP_COMPLETE;
mutex_init(&kctx->jctx.lock);
init_waitqueue_head(&kctx->jctx.zero_jobs_wait);
spin_lock_init(&kctx->jctx.tb_lock);
kctx->jctx.job_nr = 0;
INIT_LIST_HEAD(&kctx->completed_jobs);
atomic_set(&kctx->work_count, 0);
/* Check if there are platform rules for maximum priority */
if (pcm_device)
kctx->jctx.max_priority = pcm_device->ops.pcm_scheduler_priority_check(
pcm_device, current, KBASE_JS_ATOM_SCHED_PRIO_REALTIME);
return 0;
out1:
return mali_err;
}
KBASE_EXPORT_TEST_API(kbase_jd_init);
void kbase_jd_exit(struct kbase_context *kctx)
{
KBASE_DEBUG_ASSERT(kctx);
/* Work queue is emptied by this */
destroy_workqueue(kctx->jctx.job_done_wq);
}
KBASE_EXPORT_TEST_API(kbase_jd_exit);