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linux/drivers/gpu/drm/i915/gvt/execlist.c
Dave Airlie 305b9eddee Merge tag 'drm-intel-next-2017-06-19' of git://anongit.freedesktop.org/git/drm-intel into drm-next 
Final pile of features for 4.13

New uabi:
- batch bo in first slot, for faster execbuf assembly in userspace
  (Chris Wilson)
- (sub)slice getparam, needed for mesa perf support (Robert Bragg)

First pile of patches for cnl/cfl support, maintained by Rodrigo but
with lots of contributions from others. Still incomplete since public
review still ongoing.

Features/refactoring:
- Make execbuf faster (Chris Wilson), a pile of series to make execbuf
  buffer handling have fewer passes, use less list walking, postpone
  more work to async workers and shuffle buffers less, all to make the
  common case much faster (in some cases at least).
- cold boot support for glk dsi (Madhav Chauhan)
- Clean up pipe A quirk and related old platform hacks (Ville)
- perf sampling support for kbl/glk (Lionel)
- perf cleanups (Robert Bragg)
- wire atomic state to backlight code, to avoid pipe lookup hacks
  (Maarten)
- reduce request waiting latency/overhead to remove the spinning and
  associated cpu cycle wasting (Chris)
- fix 90/270 rotation wm computation (Ville)
- new ddb allocation algo for skl (Kumar Mahesh)
- fix regression due to system suspend optimiazatino (Imre)
- the usual pile of small cleanups and refactors all over

GVT updates contained in this tag:
- optimization for per-VM mmio save/restore (Changbin)
- optimization for mmio hash table (Changbin)
- scheduler optimization with event (Ping)
- vGPU reset refinement (Fred)
- other misc refactor and cleanups, etc.

* tag 'drm-intel-next-2017-06-19' of git://anongit.freedesktop.org/git/drm-intel: (170 commits)
  drm/i915: Update DRIVER_DATE to 20170619
  drm/i915/cfl: Introduce Coffee Lake workarounds.
  drm/i915: Store 9 bits of PCI Device ID for platforms with a LP PCH
  drm/i915: Stash a pointer to the obj's resv in the vma
  drm/i915: Async GPU relocation processing
  drm/i915: Allow execbuffer to use the first object as the batch
  drm/i915: Wait upon userptr get-user-pages within execbuffer
  drm/i915: First try the previous execbuffer location
  drm/i915: Store a persistent reference for an object in the execbuffer cache
  drm/i915: Eliminate lots of iterations over the execobjects array
  drm/i915: Disable EXEC_OBJECT_ASYNC when doing relocations
  drm/i915: Pass vma to relocate entry
  drm/i915: Store a direct lookup from object handle to vma
  drm/i915: Fix retrieval of hangcheck stats
  drm/i915: Store i915_gem_object_is_coherent() as a bit next to cache-dirty
  drm/i915: Mark CPU cache as dirty on every transition for CPU writes
  drm/i915: Make i915_vma_destroy() static
  drm/i915: Actually attach the tv_format property to the SDVO connector
  Revert "drm/i915/skl: New ddb allocation algorithm"
  drm/i915/glk: Add cold boot sequence for GLK DSI
  ...
2017-06-21 08:55:22 +10:00

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/*
* Copyright(c) 2011-2016 Intel Corporation. All rights reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*
* Authors:
* Zhiyuan Lv <zhiyuan.lv@intel.com>
* Zhi Wang <zhi.a.wang@intel.com>
*
* Contributors:
* Min He <min.he@intel.com>
* Bing Niu <bing.niu@intel.com>
* Ping Gao <ping.a.gao@intel.com>
* Tina Zhang <tina.zhang@intel.com>
*
*/
#include "i915_drv.h"
#include "gvt.h"
#define _EL_OFFSET_STATUS 0x234
#define _EL_OFFSET_STATUS_BUF 0x370
#define _EL_OFFSET_STATUS_PTR 0x3A0
#define execlist_ring_mmio(gvt, ring_id, offset) \
(gvt->dev_priv->engine[ring_id]->mmio_base + (offset))
#define valid_context(ctx) ((ctx)->valid)
#define same_context(a, b) (((a)->context_id == (b)->context_id) && \
((a)->lrca == (b)->lrca))
static int context_switch_events[] = {
[RCS] = RCS_AS_CONTEXT_SWITCH,
[BCS] = BCS_AS_CONTEXT_SWITCH,
[VCS] = VCS_AS_CONTEXT_SWITCH,
[VCS2] = VCS2_AS_CONTEXT_SWITCH,
[VECS] = VECS_AS_CONTEXT_SWITCH,
};
static int ring_id_to_context_switch_event(int ring_id)
{
if (WARN_ON(ring_id < RCS ||
ring_id >= ARRAY_SIZE(context_switch_events)))
return -EINVAL;
return context_switch_events[ring_id];
}
static void switch_virtual_execlist_slot(struct intel_vgpu_execlist *execlist)
{
gvt_dbg_el("[before] running slot %d/context %x pending slot %d\n",
execlist->running_slot ?
execlist->running_slot->index : -1,
execlist->running_context ?
execlist->running_context->context_id : 0,
execlist->pending_slot ?
execlist->pending_slot->index : -1);
execlist->running_slot = execlist->pending_slot;
execlist->pending_slot = NULL;
execlist->running_context = execlist->running_context ?
&execlist->running_slot->ctx[0] : NULL;
gvt_dbg_el("[after] running slot %d/context %x pending slot %d\n",
execlist->running_slot ?
execlist->running_slot->index : -1,
execlist->running_context ?
execlist->running_context->context_id : 0,
execlist->pending_slot ?
execlist->pending_slot->index : -1);
}
static void emulate_execlist_status(struct intel_vgpu_execlist *execlist)
{
struct intel_vgpu_execlist_slot *running = execlist->running_slot;
struct intel_vgpu_execlist_slot *pending = execlist->pending_slot;
struct execlist_ctx_descriptor_format *desc = execlist->running_context;
struct intel_vgpu *vgpu = execlist->vgpu;
struct execlist_status_format status;
int ring_id = execlist->ring_id;
u32 status_reg = execlist_ring_mmio(vgpu->gvt,
ring_id, _EL_OFFSET_STATUS);
status.ldw = vgpu_vreg(vgpu, status_reg);
status.udw = vgpu_vreg(vgpu, status_reg + 4);
if (running) {
status.current_execlist_pointer = !!running->index;
status.execlist_write_pointer = !!!running->index;
status.execlist_0_active = status.execlist_0_valid =
!!!(running->index);
status.execlist_1_active = status.execlist_1_valid =
!!(running->index);
} else {
status.context_id = 0;
status.execlist_0_active = status.execlist_0_valid = 0;
status.execlist_1_active = status.execlist_1_valid = 0;
}
status.context_id = desc ? desc->context_id : 0;
status.execlist_queue_full = !!(pending);
vgpu_vreg(vgpu, status_reg) = status.ldw;
vgpu_vreg(vgpu, status_reg + 4) = status.udw;
gvt_dbg_el("vgpu%d: status reg offset %x ldw %x udw %x\n",
vgpu->id, status_reg, status.ldw, status.udw);
}
static void emulate_csb_update(struct intel_vgpu_execlist *execlist,
struct execlist_context_status_format *status,
bool trigger_interrupt_later)
{
struct intel_vgpu *vgpu = execlist->vgpu;
int ring_id = execlist->ring_id;
struct execlist_context_status_pointer_format ctx_status_ptr;
u32 write_pointer;
u32 ctx_status_ptr_reg, ctx_status_buf_reg, offset;
ctx_status_ptr_reg = execlist_ring_mmio(vgpu->gvt, ring_id,
_EL_OFFSET_STATUS_PTR);
ctx_status_buf_reg = execlist_ring_mmio(vgpu->gvt, ring_id,
_EL_OFFSET_STATUS_BUF);
ctx_status_ptr.dw = vgpu_vreg(vgpu, ctx_status_ptr_reg);
write_pointer = ctx_status_ptr.write_ptr;
if (write_pointer == 0x7)
write_pointer = 0;
else {
++write_pointer;
write_pointer %= 0x6;
}
offset = ctx_status_buf_reg + write_pointer * 8;
vgpu_vreg(vgpu, offset) = status->ldw;
vgpu_vreg(vgpu, offset + 4) = status->udw;
ctx_status_ptr.write_ptr = write_pointer;
vgpu_vreg(vgpu, ctx_status_ptr_reg) = ctx_status_ptr.dw;
gvt_dbg_el("vgpu%d: w pointer %u reg %x csb l %x csb h %x\n",
vgpu->id, write_pointer, offset, status->ldw, status->udw);
if (trigger_interrupt_later)
return;
intel_vgpu_trigger_virtual_event(vgpu,
ring_id_to_context_switch_event(execlist->ring_id));
}
static int emulate_execlist_ctx_schedule_out(
struct intel_vgpu_execlist *execlist,
struct execlist_ctx_descriptor_format *ctx)
{
struct intel_vgpu *vgpu = execlist->vgpu;
struct intel_vgpu_execlist_slot *running = execlist->running_slot;
struct intel_vgpu_execlist_slot *pending = execlist->pending_slot;
struct execlist_ctx_descriptor_format *ctx0 = &running->ctx[0];
struct execlist_ctx_descriptor_format *ctx1 = &running->ctx[1];
struct execlist_context_status_format status;
memset(&status, 0, sizeof(status));
gvt_dbg_el("schedule out context id %x\n", ctx->context_id);
if (WARN_ON(!same_context(ctx, execlist->running_context))) {
gvt_vgpu_err("schedule out context is not running context,"
"ctx id %x running ctx id %x\n",
ctx->context_id,
execlist->running_context->context_id);
return -EINVAL;
}
/* ctx1 is valid, ctx0/ctx is scheduled-out -> element switch */
if (valid_context(ctx1) && same_context(ctx0, ctx)) {
gvt_dbg_el("ctx 1 valid, ctx/ctx 0 is scheduled-out\n");
execlist->running_context = ctx1;
emulate_execlist_status(execlist);
status.context_complete = status.element_switch = 1;
status.context_id = ctx->context_id;
emulate_csb_update(execlist, &status, false);
/*
* ctx1 is not valid, ctx == ctx0
* ctx1 is valid, ctx1 == ctx
* --> last element is finished
* emulate:
* active-to-idle if there is *no* pending execlist
* context-complete if there *is* pending execlist
*/
} else if ((!valid_context(ctx1) && same_context(ctx0, ctx))
|| (valid_context(ctx1) && same_context(ctx1, ctx))) {
gvt_dbg_el("need to switch virtual execlist slot\n");
switch_virtual_execlist_slot(execlist);
emulate_execlist_status(execlist);
status.context_complete = status.active_to_idle = 1;
status.context_id = ctx->context_id;
if (!pending) {
emulate_csb_update(execlist, &status, false);
} else {
emulate_csb_update(execlist, &status, true);
memset(&status, 0, sizeof(status));
status.idle_to_active = 1;
status.context_id = 0;
emulate_csb_update(execlist, &status, false);
}
} else {
WARN_ON(1);
return -EINVAL;
}
return 0;
}
static struct intel_vgpu_execlist_slot *get_next_execlist_slot(
struct intel_vgpu_execlist *execlist)
{
struct intel_vgpu *vgpu = execlist->vgpu;
int ring_id = execlist->ring_id;
u32 status_reg = execlist_ring_mmio(vgpu->gvt, ring_id,
_EL_OFFSET_STATUS);
struct execlist_status_format status;
status.ldw = vgpu_vreg(vgpu, status_reg);
status.udw = vgpu_vreg(vgpu, status_reg + 4);
if (status.execlist_queue_full) {
gvt_vgpu_err("virtual execlist slots are full\n");
return NULL;
}
return &execlist->slot[status.execlist_write_pointer];
}
static int emulate_execlist_schedule_in(struct intel_vgpu_execlist *execlist,
struct execlist_ctx_descriptor_format ctx[2])
{
struct intel_vgpu_execlist_slot *running = execlist->running_slot;
struct intel_vgpu_execlist_slot *slot =
get_next_execlist_slot(execlist);
struct execlist_ctx_descriptor_format *ctx0, *ctx1;
struct execlist_context_status_format status;
struct intel_vgpu *vgpu = execlist->vgpu;
gvt_dbg_el("emulate schedule-in\n");
if (!slot) {
gvt_vgpu_err("no available execlist slot\n");
return -EINVAL;
}
memset(&status, 0, sizeof(status));
memset(slot->ctx, 0, sizeof(slot->ctx));
slot->ctx[0] = ctx[0];
slot->ctx[1] = ctx[1];
gvt_dbg_el("alloc slot index %d ctx 0 %x ctx 1 %x\n",
slot->index, ctx[0].context_id,
ctx[1].context_id);
/*
* no running execlist, make this write bundle as running execlist
* -> idle-to-active
*/
if (!running) {
gvt_dbg_el("no current running execlist\n");
execlist->running_slot = slot;
execlist->pending_slot = NULL;
execlist->running_context = &slot->ctx[0];
gvt_dbg_el("running slot index %d running context %x\n",
execlist->running_slot->index,
execlist->running_context->context_id);
emulate_execlist_status(execlist);
status.idle_to_active = 1;
status.context_id = 0;
emulate_csb_update(execlist, &status, false);
return 0;
}
ctx0 = &running->ctx[0];
ctx1 = &running->ctx[1];
gvt_dbg_el("current running slot index %d ctx 0 %x ctx 1 %x\n",
running->index, ctx0->context_id, ctx1->context_id);
/*
* already has an running execlist
* a. running ctx1 is valid,
* ctx0 is finished, and running ctx1 == new execlist ctx[0]
* b. running ctx1 is not valid,
* ctx0 == new execlist ctx[0]
* ----> lite-restore + preempted
*/
if ((valid_context(ctx1) && same_context(ctx1, &slot->ctx[0]) &&
/* condition a */
(!same_context(ctx0, execlist->running_context))) ||
(!valid_context(ctx1) &&
same_context(ctx0, &slot->ctx[0]))) { /* condition b */
gvt_dbg_el("need to switch virtual execlist slot\n");
execlist->pending_slot = slot;
switch_virtual_execlist_slot(execlist);
emulate_execlist_status(execlist);
status.lite_restore = status.preempted = 1;
status.context_id = ctx[0].context_id;
emulate_csb_update(execlist, &status, false);
} else {
gvt_dbg_el("emulate as pending slot\n");
/*
* otherwise
* --> emulate pending execlist exist + but no preemption case
*/
execlist->pending_slot = slot;
emulate_execlist_status(execlist);
}
return 0;
}
static void free_workload(struct intel_vgpu_workload *workload)
{
intel_vgpu_unpin_mm(workload->shadow_mm);
intel_gvt_mm_unreference(workload->shadow_mm);
kmem_cache_free(workload->vgpu->workloads, workload);
}
#define get_desc_from_elsp_dwords(ed, i) \
((struct execlist_ctx_descriptor_format *)&((ed)->data[i * 2]))
static void prepare_shadow_batch_buffer(struct intel_vgpu_workload *workload)
{
const int gmadr_bytes = workload->vgpu->gvt->device_info.gmadr_bytes_in_cmd;
struct intel_shadow_bb_entry *entry_obj;
/* pin the gem object to ggtt */
list_for_each_entry(entry_obj, &workload->shadow_bb, list) {
struct i915_vma *vma;
vma = i915_gem_object_ggtt_pin(entry_obj->obj, NULL, 0, 4, 0);
if (IS_ERR(vma)) {
return;
}
/* FIXME: we are not tracking our pinned VMA leaving it
* up to the core to fix up the stray pin_count upon
* free.
*/
/* update the relocate gma with shadow batch buffer*/
entry_obj->bb_start_cmd_va[1] = i915_ggtt_offset(vma);
if (gmadr_bytes == 8)
entry_obj->bb_start_cmd_va[2] = 0;
}
}
static int update_wa_ctx_2_shadow_ctx(struct intel_shadow_wa_ctx *wa_ctx)
{
struct intel_vgpu_workload *workload = container_of(wa_ctx,
struct intel_vgpu_workload,
wa_ctx);
int ring_id = workload->ring_id;
struct i915_gem_context *shadow_ctx = workload->vgpu->shadow_ctx;
struct drm_i915_gem_object *ctx_obj =
shadow_ctx->engine[ring_id].state->obj;
struct execlist_ring_context *shadow_ring_context;
struct page *page;
page = i915_gem_object_get_page(ctx_obj, LRC_STATE_PN);
shadow_ring_context = kmap_atomic(page);
shadow_ring_context->bb_per_ctx_ptr.val =
(shadow_ring_context->bb_per_ctx_ptr.val &
(~PER_CTX_ADDR_MASK)) | wa_ctx->per_ctx.shadow_gma;
shadow_ring_context->rcs_indirect_ctx.val =
(shadow_ring_context->rcs_indirect_ctx.val &
(~INDIRECT_CTX_ADDR_MASK)) | wa_ctx->indirect_ctx.shadow_gma;
kunmap_atomic(shadow_ring_context);
return 0;
}
static void prepare_shadow_wa_ctx(struct intel_shadow_wa_ctx *wa_ctx)
{
struct i915_vma *vma;
unsigned char *per_ctx_va =
(unsigned char *)wa_ctx->indirect_ctx.shadow_va +
wa_ctx->indirect_ctx.size;
if (wa_ctx->indirect_ctx.size == 0)
return;
vma = i915_gem_object_ggtt_pin(wa_ctx->indirect_ctx.obj, NULL,
0, CACHELINE_BYTES, 0);
if (IS_ERR(vma)) {
return;
}
/* FIXME: we are not tracking our pinned VMA leaving it
* up to the core to fix up the stray pin_count upon
* free.
*/
wa_ctx->indirect_ctx.shadow_gma = i915_ggtt_offset(vma);
wa_ctx->per_ctx.shadow_gma = *((unsigned int *)per_ctx_va + 1);
memset(per_ctx_va, 0, CACHELINE_BYTES);
update_wa_ctx_2_shadow_ctx(wa_ctx);
}
static int prepare_execlist_workload(struct intel_vgpu_workload *workload)
{
struct intel_vgpu *vgpu = workload->vgpu;
struct execlist_ctx_descriptor_format ctx[2];
int ring_id = workload->ring_id;
intel_vgpu_pin_mm(workload->shadow_mm);
intel_vgpu_sync_oos_pages(workload->vgpu);
intel_vgpu_flush_post_shadow(workload->vgpu);
prepare_shadow_batch_buffer(workload);
prepare_shadow_wa_ctx(&workload->wa_ctx);
if (!workload->emulate_schedule_in)
return 0;
ctx[0] = *get_desc_from_elsp_dwords(&workload->elsp_dwords, 1);
ctx[1] = *get_desc_from_elsp_dwords(&workload->elsp_dwords, 0);
return emulate_execlist_schedule_in(&vgpu->execlist[ring_id], ctx);
}
static void release_shadow_batch_buffer(struct intel_vgpu_workload *workload)
{
/* release all the shadow batch buffer */
if (!list_empty(&workload->shadow_bb)) {
struct intel_shadow_bb_entry *entry_obj =
list_first_entry(&workload->shadow_bb,
struct intel_shadow_bb_entry,
list);
struct intel_shadow_bb_entry *temp;
list_for_each_entry_safe(entry_obj, temp, &workload->shadow_bb,
list) {
i915_gem_object_unpin_map(entry_obj->obj);
i915_gem_object_put(entry_obj->obj);
list_del(&entry_obj->list);
kfree(entry_obj);
}
}
}
static void release_shadow_wa_ctx(struct intel_shadow_wa_ctx *wa_ctx)
{
if (!wa_ctx->indirect_ctx.obj)
return;
i915_gem_object_unpin_map(wa_ctx->indirect_ctx.obj);
i915_gem_object_put(wa_ctx->indirect_ctx.obj);
}
static int complete_execlist_workload(struct intel_vgpu_workload *workload)
{
struct intel_vgpu *vgpu = workload->vgpu;
struct intel_vgpu_execlist *execlist =
&vgpu->execlist[workload->ring_id];
struct intel_vgpu_workload *next_workload;
struct list_head *next = workload_q_head(vgpu, workload->ring_id)->next;
bool lite_restore = false;
int ret;
gvt_dbg_el("complete workload %p status %d\n", workload,
workload->status);
release_shadow_batch_buffer(workload);
release_shadow_wa_ctx(&workload->wa_ctx);
if (workload->status || vgpu->resetting)
goto out;
if (!list_empty(workload_q_head(vgpu, workload->ring_id))) {
struct execlist_ctx_descriptor_format *this_desc, *next_desc;
next_workload = container_of(next,
struct intel_vgpu_workload, list);
this_desc = &workload->ctx_desc;
next_desc = &next_workload->ctx_desc;
lite_restore = same_context(this_desc, next_desc);
}
if (lite_restore) {
gvt_dbg_el("next context == current - no schedule-out\n");
free_workload(workload);
return 0;
}
ret = emulate_execlist_ctx_schedule_out(execlist, &workload->ctx_desc);
if (ret)
goto err;
out:
free_workload(workload);
return 0;
err:
free_workload(workload);
return ret;
}
#define RING_CTX_OFF(x) \
offsetof(struct execlist_ring_context, x)
static void read_guest_pdps(struct intel_vgpu *vgpu,
u64 ring_context_gpa, u32 pdp[8])
{
u64 gpa;
int i;
gpa = ring_context_gpa + RING_CTX_OFF(pdp3_UDW.val);
for (i = 0; i < 8; i++)
intel_gvt_hypervisor_read_gpa(vgpu,
gpa + i * 8, &pdp[7 - i], 4);
}
static int prepare_mm(struct intel_vgpu_workload *workload)
{
struct execlist_ctx_descriptor_format *desc = &workload->ctx_desc;
struct intel_vgpu_mm *mm;
struct intel_vgpu *vgpu = workload->vgpu;
int page_table_level;
u32 pdp[8];
if (desc->addressing_mode == 1) { /* legacy 32-bit */
page_table_level = 3;
} else if (desc->addressing_mode == 3) { /* legacy 64 bit */
page_table_level = 4;
} else {
gvt_vgpu_err("Advanced Context mode(SVM) is not supported!\n");
return -EINVAL;
}
read_guest_pdps(workload->vgpu, workload->ring_context_gpa, pdp);
mm = intel_vgpu_find_ppgtt_mm(workload->vgpu, page_table_level, pdp);
if (mm) {
intel_gvt_mm_reference(mm);
} else {
mm = intel_vgpu_create_mm(workload->vgpu, INTEL_GVT_MM_PPGTT,
pdp, page_table_level, 0);
if (IS_ERR(mm)) {
gvt_vgpu_err("fail to create mm object.\n");
return PTR_ERR(mm);
}
}
workload->shadow_mm = mm;
return 0;
}
#define get_last_workload(q) \
(list_empty(q) ? NULL : container_of(q->prev, \
struct intel_vgpu_workload, list))
static int submit_context(struct intel_vgpu *vgpu, int ring_id,
struct execlist_ctx_descriptor_format *desc,
bool emulate_schedule_in)
{
struct list_head *q = workload_q_head(vgpu, ring_id);
struct intel_vgpu_workload *last_workload = get_last_workload(q);
struct intel_vgpu_workload *workload = NULL;
u64 ring_context_gpa;
u32 head, tail, start, ctl, ctx_ctl, per_ctx, indirect_ctx;
int ret;
ring_context_gpa = intel_vgpu_gma_to_gpa(vgpu->gtt.ggtt_mm,
(u32)((desc->lrca + 1) << GTT_PAGE_SHIFT));
if (ring_context_gpa == INTEL_GVT_INVALID_ADDR) {
gvt_vgpu_err("invalid guest context LRCA: %x\n", desc->lrca);
return -EINVAL;
}
intel_gvt_hypervisor_read_gpa(vgpu, ring_context_gpa +
RING_CTX_OFF(ring_header.val), &head, 4);
intel_gvt_hypervisor_read_gpa(vgpu, ring_context_gpa +
RING_CTX_OFF(ring_tail.val), &tail, 4);
head &= RB_HEAD_OFF_MASK;
tail &= RB_TAIL_OFF_MASK;
if (last_workload && same_context(&last_workload->ctx_desc, desc)) {
gvt_dbg_el("ring id %d cur workload == last\n", ring_id);
gvt_dbg_el("ctx head %x real head %lx\n", head,
last_workload->rb_tail);
/*
* cannot use guest context head pointer here,
* as it might not be updated at this time
*/
head = last_workload->rb_tail;
}
gvt_dbg_el("ring id %d begin a new workload\n", ring_id);
workload = kmem_cache_zalloc(vgpu->workloads, GFP_KERNEL);
if (!workload)
return -ENOMEM;
/* record some ring buffer register values for scan and shadow */
intel_gvt_hypervisor_read_gpa(vgpu, ring_context_gpa +
RING_CTX_OFF(rb_start.val), &start, 4);
intel_gvt_hypervisor_read_gpa(vgpu, ring_context_gpa +
RING_CTX_OFF(rb_ctrl.val), &ctl, 4);
intel_gvt_hypervisor_read_gpa(vgpu, ring_context_gpa +
RING_CTX_OFF(ctx_ctrl.val), &ctx_ctl, 4);
INIT_LIST_HEAD(&workload->list);
INIT_LIST_HEAD(&workload->shadow_bb);
init_waitqueue_head(&workload->shadow_ctx_status_wq);
atomic_set(&workload->shadow_ctx_active, 0);
workload->vgpu = vgpu;
workload->ring_id = ring_id;
workload->ctx_desc = *desc;
workload->ring_context_gpa = ring_context_gpa;
workload->rb_head = head;
workload->rb_tail = tail;
workload->rb_start = start;
workload->rb_ctl = ctl;
workload->prepare = prepare_execlist_workload;
workload->complete = complete_execlist_workload;
workload->status = -EINPROGRESS;
workload->emulate_schedule_in = emulate_schedule_in;
if (ring_id == RCS) {
intel_gvt_hypervisor_read_gpa(vgpu, ring_context_gpa +
RING_CTX_OFF(bb_per_ctx_ptr.val), &per_ctx, 4);
intel_gvt_hypervisor_read_gpa(vgpu, ring_context_gpa +
RING_CTX_OFF(rcs_indirect_ctx.val), &indirect_ctx, 4);
workload->wa_ctx.indirect_ctx.guest_gma =
indirect_ctx & INDIRECT_CTX_ADDR_MASK;
workload->wa_ctx.indirect_ctx.size =
(indirect_ctx & INDIRECT_CTX_SIZE_MASK) *
CACHELINE_BYTES;
workload->wa_ctx.per_ctx.guest_gma =
per_ctx & PER_CTX_ADDR_MASK;
WARN_ON(workload->wa_ctx.indirect_ctx.size && !(per_ctx & 0x1));
}
if (emulate_schedule_in)
workload->elsp_dwords = vgpu->execlist[ring_id].elsp_dwords;
gvt_dbg_el("workload %p ring id %d head %x tail %x start %x ctl %x\n",
workload, ring_id, head, tail, start, ctl);
gvt_dbg_el("workload %p emulate schedule_in %d\n", workload,
emulate_schedule_in);
ret = prepare_mm(workload);
if (ret) {
kmem_cache_free(vgpu->workloads, workload);
return ret;
}
queue_workload(workload);
return 0;
}
int intel_vgpu_submit_execlist(struct intel_vgpu *vgpu, int ring_id)
{
struct intel_vgpu_execlist *execlist = &vgpu->execlist[ring_id];
struct execlist_ctx_descriptor_format desc[2];
int i, ret;
desc[0] = *get_desc_from_elsp_dwords(&execlist->elsp_dwords, 1);
desc[1] = *get_desc_from_elsp_dwords(&execlist->elsp_dwords, 0);
if (!desc[0].valid) {
gvt_vgpu_err("invalid elsp submission, desc0 is invalid\n");
goto inv_desc;
}
for (i = 0; i < ARRAY_SIZE(desc); i++) {
if (!desc[i].valid)
continue;
if (!desc[i].privilege_access) {
gvt_vgpu_err("unexpected GGTT elsp submission\n");
goto inv_desc;
}
}
/* submit workload */
for (i = 0; i < ARRAY_SIZE(desc); i++) {
if (!desc[i].valid)
continue;
ret = submit_context(vgpu, ring_id, &desc[i], i == 0);
if (ret) {
gvt_vgpu_err("failed to submit desc %d\n", i);
return ret;
}
}
return 0;
inv_desc:
gvt_vgpu_err("descriptors content: desc0 %08x %08x desc1 %08x %08x\n",
desc[0].udw, desc[0].ldw, desc[1].udw, desc[1].ldw);
return -EINVAL;
}
static void init_vgpu_execlist(struct intel_vgpu *vgpu, int ring_id)
{
struct intel_vgpu_execlist *execlist = &vgpu->execlist[ring_id];
struct execlist_context_status_pointer_format ctx_status_ptr;
u32 ctx_status_ptr_reg;
memset(execlist, 0, sizeof(*execlist));
execlist->vgpu = vgpu;
execlist->ring_id = ring_id;
execlist->slot[0].index = 0;
execlist->slot[1].index = 1;
ctx_status_ptr_reg = execlist_ring_mmio(vgpu->gvt, ring_id,
_EL_OFFSET_STATUS_PTR);
ctx_status_ptr.dw = vgpu_vreg(vgpu, ctx_status_ptr_reg);
ctx_status_ptr.read_ptr = 0;
ctx_status_ptr.write_ptr = 0x7;
vgpu_vreg(vgpu, ctx_status_ptr_reg) = ctx_status_ptr.dw;
}
static void clean_workloads(struct intel_vgpu *vgpu, unsigned long engine_mask)
{
struct drm_i915_private *dev_priv = vgpu->gvt->dev_priv;
struct intel_engine_cs *engine;
struct intel_vgpu_workload *pos, *n;
unsigned int tmp;
/* free the unsubmited workloads in the queues. */
for_each_engine_masked(engine, dev_priv, engine_mask, tmp) {
list_for_each_entry_safe(pos, n,
&vgpu->workload_q_head[engine->id], list) {
list_del_init(&pos->list);
free_workload(pos);
}
}
}
void intel_vgpu_clean_execlist(struct intel_vgpu *vgpu)
{
clean_workloads(vgpu, ALL_ENGINES);
kmem_cache_destroy(vgpu->workloads);
}
int intel_vgpu_init_execlist(struct intel_vgpu *vgpu)
{
enum intel_engine_id i;
struct intel_engine_cs *engine;
/* each ring has a virtual execlist engine */
for_each_engine(engine, vgpu->gvt->dev_priv, i) {
init_vgpu_execlist(vgpu, i);
INIT_LIST_HEAD(&vgpu->workload_q_head[i]);
}
vgpu->workloads = kmem_cache_create("gvt-g_vgpu_workload",
sizeof(struct intel_vgpu_workload), 0,
SLAB_HWCACHE_ALIGN,
NULL);
if (!vgpu->workloads)
return -ENOMEM;
return 0;
}
void intel_vgpu_reset_execlist(struct intel_vgpu *vgpu,
unsigned long engine_mask)
{
struct drm_i915_private *dev_priv = vgpu->gvt->dev_priv;
struct intel_engine_cs *engine;
unsigned int tmp;
clean_workloads(vgpu, engine_mask);
for_each_engine_masked(engine, dev_priv, engine_mask, tmp)
init_vgpu_execlist(vgpu, engine->id);
}
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