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8b1bd4ed767c589d786df326b1a5c2b3ac45263d
third_party_mesa3d/src/gallium/drivers/iris/iris_resource.c
Lionel Landwerlin 8b1bd4ed76 anv/iris: leave 4k alignments for clear colors with modifiers 
Signed-off-by: Lionel Landwerlin <lionel.g.landwerlin@intel.com>
Fixes: 17f97a69c1 ("iris: Reduce clear color state alignment to 64B")
Fixes: 063715ed45 ("anv: Reduce clear color state alignment to 64B")
Closes: https://gitlab.freedesktop.org/mesa/mesa/-/issues/12195
Closes: https://gitlab.freedesktop.org/drm/i915/kernel/-/issues/13057
Reviewed-by: Sagar Ghuge <sagar.ghuge@intel.com>
Reviewed-by: Nanley Chery <nanley.g.chery@intel.com>
Part-of: <https://gitlab.freedesktop.org/mesa/mesa/-/merge_requests/32422>
(cherry picked from commit 888f63cf1b)
2024-12-02 10:55:00 -08:00

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/*
* Copyright © 2017 Intel Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice 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.
*/
/**
* @file iris_resource.c
*
* Resources are images, buffers, and other objects used by the GPU.
*
* XXX: explain resources
*/
#include <stdio.h>
#include <errno.h>
#include "pipe/p_defines.h"
#include "pipe/p_state.h"
#include "pipe/p_context.h"
#include "pipe/p_screen.h"
#include "util/detect_os.h"
#include "util/os_memory.h"
#include "util/u_cpu_detect.h"
#include "util/u_inlines.h"
#include "util/format/u_format.h"
#include "util/u_memory.h"
#include "util/u_resource.h"
#include "util/u_threaded_context.h"
#include "util/u_transfer.h"
#include "util/u_transfer_helper.h"
#include "util/u_upload_mgr.h"
#include "util/ralloc.h"
#include "i915/iris_bufmgr.h"
#include "iris_batch.h"
#include "iris_context.h"
#include "iris_resource.h"
#include "iris_screen.h"
#include "intel/common/intel_aux_map.h"
#include "intel/dev/intel_debug.h"
#include "isl/isl.h"
#include "drm-uapi/drm_fourcc.h"
enum modifier_priority {
MODIFIER_PRIORITY_INVALID = 0,
MODIFIER_PRIORITY_LINEAR,
MODIFIER_PRIORITY_X,
MODIFIER_PRIORITY_Y,
MODIFIER_PRIORITY_Y_CCS,
MODIFIER_PRIORITY_Y_GFX12_RC_CCS,
MODIFIER_PRIORITY_Y_GFX12_RC_CCS_CC,
MODIFIER_PRIORITY_4,
MODIFIER_PRIORITY_4_DG2_RC_CCS,
MODIFIER_PRIORITY_4_DG2_RC_CCS_CC,
MODIFIER_PRIORITY_4_MTL_RC_CCS,
MODIFIER_PRIORITY_4_MTL_RC_CCS_CC,
};
static const uint64_t priority_to_modifier[] = {
[MODIFIER_PRIORITY_INVALID] = DRM_FORMAT_MOD_INVALID,
[MODIFIER_PRIORITY_LINEAR] = DRM_FORMAT_MOD_LINEAR,
[MODIFIER_PRIORITY_X] = I915_FORMAT_MOD_X_TILED,
[MODIFIER_PRIORITY_Y] = I915_FORMAT_MOD_Y_TILED,
[MODIFIER_PRIORITY_Y_CCS] = I915_FORMAT_MOD_Y_TILED_CCS,
[MODIFIER_PRIORITY_Y_GFX12_RC_CCS] = I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS,
[MODIFIER_PRIORITY_Y_GFX12_RC_CCS_CC] = I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS_CC,
[MODIFIER_PRIORITY_4] = I915_FORMAT_MOD_4_TILED,
[MODIFIER_PRIORITY_4_DG2_RC_CCS] = I915_FORMAT_MOD_4_TILED_DG2_RC_CCS,
[MODIFIER_PRIORITY_4_DG2_RC_CCS_CC] = I915_FORMAT_MOD_4_TILED_DG2_RC_CCS_CC,
[MODIFIER_PRIORITY_4_MTL_RC_CCS] = I915_FORMAT_MOD_4_TILED_MTL_RC_CCS,
[MODIFIER_PRIORITY_4_MTL_RC_CCS_CC] = I915_FORMAT_MOD_4_TILED_MTL_RC_CCS_CC,
};
static bool
modifier_is_supported(const struct intel_device_info *devinfo,
enum pipe_format pfmt, unsigned bind,
uint64_t modifier)
{
/* Check for basic device support. */
switch (modifier) {
case DRM_FORMAT_MOD_LINEAR:
case I915_FORMAT_MOD_X_TILED:
break;
case I915_FORMAT_MOD_Y_TILED:
if (devinfo->ver <= 8 && (bind & PIPE_BIND_SCANOUT))
return false;
if (devinfo->verx10 >= 125)
return false;
break;
case I915_FORMAT_MOD_Y_TILED_CCS:
if (devinfo->ver <= 8 || devinfo->ver >= 12)
return false;
break;
case I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS:
case I915_FORMAT_MOD_Y_TILED_GEN12_MC_CCS:
case I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS_CC:
if (devinfo->verx10 != 120)
return false;
break;
case I915_FORMAT_MOD_4_TILED:
if (devinfo->verx10 < 125)
return false;
break;
case I915_FORMAT_MOD_4_TILED_DG2_RC_CCS:
case I915_FORMAT_MOD_4_TILED_DG2_MC_CCS:
case I915_FORMAT_MOD_4_TILED_DG2_RC_CCS_CC:
if (!intel_device_info_is_dg2(devinfo))
return false;
break;
case I915_FORMAT_MOD_4_TILED_MTL_RC_CCS:
case I915_FORMAT_MOD_4_TILED_MTL_MC_CCS:
case I915_FORMAT_MOD_4_TILED_MTL_RC_CCS_CC:
if (!intel_device_info_is_mtl_or_arl(devinfo))
return false;
break;
case DRM_FORMAT_MOD_INVALID:
default:
return false;
}
bool no_ccs = INTEL_DEBUG(DEBUG_NO_CCS) || (bind & PIPE_BIND_CONST_BW);
/* Check remaining requirements. */
switch (modifier) {
case I915_FORMAT_MOD_4_TILED_MTL_MC_CCS:
case I915_FORMAT_MOD_4_TILED_DG2_MC_CCS:
case I915_FORMAT_MOD_Y_TILED_GEN12_MC_CCS:
if (no_ccs)
return false;
if (pfmt != PIPE_FORMAT_BGRA8888_UNORM &&
pfmt != PIPE_FORMAT_RGBA8888_UNORM &&
pfmt != PIPE_FORMAT_BGRX8888_UNORM &&
pfmt != PIPE_FORMAT_RGBX8888_UNORM &&
pfmt != PIPE_FORMAT_NV12 &&
pfmt != PIPE_FORMAT_P010 &&
pfmt != PIPE_FORMAT_P012 &&
pfmt != PIPE_FORMAT_P016 &&
pfmt != PIPE_FORMAT_YUYV &&
pfmt != PIPE_FORMAT_UYVY) {
return false;
}
break;
case I915_FORMAT_MOD_4_TILED_MTL_RC_CCS:
case I915_FORMAT_MOD_4_TILED_MTL_RC_CCS_CC:
case I915_FORMAT_MOD_4_TILED_DG2_RC_CCS_CC:
case I915_FORMAT_MOD_4_TILED_DG2_RC_CCS:
case I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS_CC:
case I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS:
case I915_FORMAT_MOD_Y_TILED_CCS: {
if (no_ccs)
return false;
enum isl_format rt_format =
iris_format_for_usage(devinfo, pfmt,
ISL_SURF_USAGE_RENDER_TARGET_BIT).fmt;
if (rt_format == ISL_FORMAT_UNSUPPORTED ||
!isl_format_supports_ccs_e(devinfo, rt_format))
return false;
break;
}
default:
break;
}
return true;
}
static uint64_t
select_best_modifier(const struct intel_device_info *devinfo,
const struct pipe_resource *templ,
const uint64_t *modifiers,
int count)
{
enum modifier_priority prio = MODIFIER_PRIORITY_INVALID;
for (int i = 0; i < count; i++) {
if (!modifier_is_supported(devinfo, templ->format, templ->bind,
modifiers[i]))
continue;
switch (modifiers[i]) {
case I915_FORMAT_MOD_4_TILED_MTL_RC_CCS_CC:
prio = MAX2(prio, MODIFIER_PRIORITY_4_MTL_RC_CCS_CC);
break;
case I915_FORMAT_MOD_4_TILED_MTL_RC_CCS:
prio = MAX2(prio, MODIFIER_PRIORITY_4_MTL_RC_CCS);
break;
case I915_FORMAT_MOD_4_TILED_DG2_RC_CCS_CC:
prio = MAX2(prio, MODIFIER_PRIORITY_4_DG2_RC_CCS_CC);
break;
case I915_FORMAT_MOD_4_TILED_DG2_RC_CCS:
prio = MAX2(prio, MODIFIER_PRIORITY_4_DG2_RC_CCS);
break;
case I915_FORMAT_MOD_4_TILED:
prio = MAX2(prio, MODIFIER_PRIORITY_4);
break;
case I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS_CC:
prio = MAX2(prio, MODIFIER_PRIORITY_Y_GFX12_RC_CCS_CC);
break;
case I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS:
prio = MAX2(prio, MODIFIER_PRIORITY_Y_GFX12_RC_CCS);
break;
case I915_FORMAT_MOD_Y_TILED_CCS:
prio = MAX2(prio, MODIFIER_PRIORITY_Y_CCS);
break;
case I915_FORMAT_MOD_Y_TILED:
prio = MAX2(prio, MODIFIER_PRIORITY_Y);
break;
case I915_FORMAT_MOD_X_TILED:
prio = MAX2(prio, MODIFIER_PRIORITY_X);
break;
case DRM_FORMAT_MOD_LINEAR:
prio = MAX2(prio, MODIFIER_PRIORITY_LINEAR);
break;
case DRM_FORMAT_MOD_INVALID:
default:
break;
}
}
return priority_to_modifier[prio];
}
static inline bool is_modifier_external_only(enum pipe_format pfmt,
uint64_t modifier)
{
/* Only allow external usage for the following cases: YUV formats
* and the media-compression modifier. The render engine lacks
* support for rendering to a media-compressed surface if the
* compression ratio is large enough. By requiring external usage
* of media-compressed surfaces, resolves are avoided.
*/
return util_format_is_yuv(pfmt) ||
isl_drm_modifier_get_info(modifier)->supports_media_compression;
}
static void
iris_query_dmabuf_modifiers(struct pipe_screen *pscreen,
enum pipe_format pfmt,
int max,
uint64_t *modifiers,
unsigned int *external_only,
int *count)
{
struct iris_screen *screen = (void *) pscreen;
const struct intel_device_info *devinfo = screen->devinfo;
uint64_t all_modifiers[] = {
DRM_FORMAT_MOD_LINEAR,
I915_FORMAT_MOD_X_TILED,
I915_FORMAT_MOD_4_TILED,
I915_FORMAT_MOD_4_TILED_DG2_RC_CCS,
I915_FORMAT_MOD_4_TILED_DG2_MC_CCS,
I915_FORMAT_MOD_4_TILED_DG2_RC_CCS_CC,
I915_FORMAT_MOD_4_TILED_MTL_RC_CCS,
I915_FORMAT_MOD_4_TILED_MTL_RC_CCS_CC,
I915_FORMAT_MOD_4_TILED_MTL_MC_CCS,
I915_FORMAT_MOD_Y_TILED,
I915_FORMAT_MOD_Y_TILED_CCS,
I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS,
I915_FORMAT_MOD_Y_TILED_GEN12_MC_CCS,
I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS_CC,
};
int supported_mods = 0;
for (int i = 0; i < ARRAY_SIZE(all_modifiers); i++) {
if (!modifier_is_supported(devinfo, pfmt, 0, all_modifiers[i]))
continue;
if (supported_mods < max) {
if (modifiers)
modifiers[supported_mods] = all_modifiers[i];
if (external_only) {
external_only[supported_mods] =
is_modifier_external_only(pfmt, all_modifiers[i]);
}
}
supported_mods++;
}
*count = supported_mods;
}
static bool
iris_is_dmabuf_modifier_supported(struct pipe_screen *pscreen,
uint64_t modifier, enum pipe_format pfmt,
bool *external_only)
{
struct iris_screen *screen = (void *) pscreen;
const struct intel_device_info *devinfo = screen->devinfo;
if (modifier_is_supported(devinfo, pfmt, 0, modifier)) {
if (external_only)
*external_only = is_modifier_external_only(pfmt, modifier);
return true;
}
return false;
}
static unsigned int
iris_get_dmabuf_modifier_planes(struct pipe_screen *pscreen, uint64_t modifier,
enum pipe_format format)
{
unsigned int planes = util_format_get_num_planes(format);
switch (modifier) {
case I915_FORMAT_MOD_4_TILED_MTL_RC_CCS_CC:
case I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS_CC:
return 3;
case I915_FORMAT_MOD_4_TILED_MTL_RC_CCS:
case I915_FORMAT_MOD_4_TILED_MTL_MC_CCS:
case I915_FORMAT_MOD_4_TILED_DG2_RC_CCS_CC:
case I915_FORMAT_MOD_Y_TILED_GEN12_MC_CCS:
case I915_FORMAT_MOD_Y_TILED_GEN12_RC_CCS:
case I915_FORMAT_MOD_Y_TILED_CCS:
return 2 * planes;
case I915_FORMAT_MOD_4_TILED_DG2_RC_CCS:
case I915_FORMAT_MOD_4_TILED_DG2_MC_CCS:
default:
return planes;
}
}
enum isl_format
iris_image_view_get_format(struct iris_context *ice,
const struct pipe_image_view *img)
{
struct iris_screen *screen = (struct iris_screen *)ice->ctx.screen;
const struct intel_device_info *devinfo = screen->devinfo;
isl_surf_usage_flags_t usage = ISL_SURF_USAGE_STORAGE_BIT;
enum isl_format isl_fmt =
iris_format_for_usage(devinfo, img->format, usage).fmt;
if (img->shader_access & PIPE_IMAGE_ACCESS_READ) {
/* On Gfx8, try to use typed surfaces reads (which support a
* limited number of formats), and if not possible, fall back
* to untyped reads.
*/
if (devinfo->ver == 8 &&
!isl_has_matching_typed_storage_image_format(devinfo, isl_fmt))
return ISL_FORMAT_RAW;
else
return isl_lower_storage_image_format(devinfo, isl_fmt);
}
return isl_fmt;
}
static struct pipe_memory_object *
iris_memobj_create_from_handle(struct pipe_screen *pscreen,
struct winsys_handle *whandle,
bool dedicated)
{
struct iris_screen *screen = (struct iris_screen *)pscreen;
struct iris_memory_object *memobj = CALLOC_STRUCT(iris_memory_object);
if (!memobj)
return NULL;
assert(whandle->type == WINSYS_HANDLE_TYPE_FD);
assert(whandle->modifier == DRM_FORMAT_MOD_INVALID);
struct iris_bo *bo = iris_bo_import_dmabuf(screen->bufmgr, whandle->handle,
DRM_FORMAT_MOD_INVALID);
if (!bo) {
free(memobj);
return NULL;
}
memobj->b.dedicated = dedicated;
memobj->bo = bo;
memobj->format = whandle->format;
memobj->stride = whandle->stride;
return &memobj->b;
}
static void
iris_memobj_destroy(struct pipe_screen *pscreen,
struct pipe_memory_object *pmemobj)
{
struct iris_memory_object *memobj = (struct iris_memory_object *)pmemobj;
iris_bo_unreference(memobj->bo);
free(memobj);
}
struct pipe_resource *
iris_resource_get_separate_stencil(struct pipe_resource *p_res)
{
/* For packed depth-stencil, we treat depth as the primary resource
* and store S8 as the "second plane" resource.
*/
if (p_res->next && p_res->next->format == PIPE_FORMAT_S8_UINT)
return p_res->next;
return NULL;
}
static void
iris_resource_set_separate_stencil(struct pipe_resource *p_res,
struct pipe_resource *stencil)
{
assert(util_format_has_depth(util_format_description(p_res->format)));
pipe_resource_reference(&p_res->next, stencil);
}
void
iris_get_depth_stencil_resources(struct pipe_resource *res,
struct iris_resource **out_z,
struct iris_resource **out_s)
{
if (!res) {
*out_z = NULL;
*out_s = NULL;
return;
}
if (res->format != PIPE_FORMAT_S8_UINT) {
*out_z = (void *) res;
*out_s = (void *) iris_resource_get_separate_stencil(res);
} else {
*out_z = NULL;
*out_s = (void *) res;
}
}
void
iris_resource_disable_aux(struct iris_resource *res)
{
iris_bo_unreference(res->aux.bo);
iris_bo_unreference(res->aux.clear_color_bo);
free(res->aux.state);
res->aux.usage = ISL_AUX_USAGE_NONE;
res->aux.surf.size_B = 0;
res->aux.bo = NULL;
res->aux.clear_color_bo = NULL;
res->aux.state = NULL;
}
static unsigned
iris_resource_alloc_flags(const struct iris_screen *screen,
const struct pipe_resource *templ,
struct iris_resource *res)
{
if (templ->flags & IRIS_RESOURCE_FLAG_DEVICE_MEM)
return BO_ALLOC_PLAIN;
unsigned flags = BO_ALLOC_PLAIN;
switch (templ->usage) {
case PIPE_USAGE_STAGING:
flags |= BO_ALLOC_SMEM | BO_ALLOC_COHERENT;
break;
case PIPE_USAGE_STREAM:
flags |= BO_ALLOC_SMEM;
break;
case PIPE_USAGE_DYNAMIC:
case PIPE_USAGE_DEFAULT:
case PIPE_USAGE_IMMUTABLE:
/* Use LMEM for these if possible */
break;
}
if (templ->bind & PIPE_BIND_SCANOUT)
flags |= BO_ALLOC_SCANOUT;
if (templ->flags & (PIPE_RESOURCE_FLAG_MAP_COHERENT |
PIPE_RESOURCE_FLAG_MAP_PERSISTENT))
flags |= BO_ALLOC_SMEM | BO_ALLOC_COHERENT;
if (screen->devinfo->verx10 >= 125 && screen->devinfo->has_local_mem &&
isl_aux_usage_has_ccs(res->aux.usage)) {
assert((flags & BO_ALLOC_SMEM) == 0);
flags |= BO_ALLOC_LMEM;
/* For displayable surfaces with clear color,
* the KMD will need to access the clear color via CPU.
*/
if (res->mod_info && res->mod_info->supports_clear_color)
flags |= BO_ALLOC_CPU_VISIBLE;
}
if ((templ->bind & PIPE_BIND_SHARED) ||
util_format_get_num_planes(templ->format) > 1)
flags |= BO_ALLOC_NO_SUBALLOC;
if (templ->bind & PIPE_BIND_PROTECTED)
flags |= BO_ALLOC_PROTECTED;
if (templ->bind & PIPE_BIND_SHARED) {
flags |= BO_ALLOC_SHARED;
/* We request that the bufmgr zero because, if a buffer gets re-used
* from the pool, we don't want to leak random garbage from our process
* to some other.
*/
flags |= BO_ALLOC_ZEROED;
}
return flags;
}
static void
iris_resource_destroy(struct pipe_screen *screen,
struct pipe_resource *p_res)
{
struct iris_resource *res = (struct iris_resource *) p_res;
if (p_res->target == PIPE_BUFFER)
util_range_destroy(&res->valid_buffer_range);
iris_resource_disable_aux(res);
threaded_resource_deinit(p_res);
iris_bo_unreference(res->bo);
iris_pscreen_unref(res->orig_screen);
free(res);
}
static struct iris_resource *
iris_alloc_resource(struct pipe_screen *pscreen,
const struct pipe_resource *templ)
{
struct iris_resource *res = calloc(1, sizeof(struct iris_resource));
if (!res)
return NULL;
res->base.b = *templ;
res->base.b.screen = pscreen;
res->orig_screen = iris_pscreen_ref(pscreen);
pipe_reference_init(&res->base.b.reference, 1);
threaded_resource_init(&res->base.b, false);
if (templ->target == PIPE_BUFFER)
util_range_init(&res->valid_buffer_range);
return res;
}
unsigned
iris_get_num_logical_layers(const struct iris_resource *res, unsigned level)
{
if (res->surf.dim == ISL_SURF_DIM_3D)
return u_minify(res->surf.logical_level0_px.depth, level);
else
return res->surf.logical_level0_px.array_len;
}
static enum isl_aux_state **
create_aux_state_map(struct iris_resource *res, enum isl_aux_state initial)
{
assert(res->aux.state == NULL);
uint32_t total_slices = 0;
for (uint32_t level = 0; level < res->surf.levels; level++)
total_slices += iris_get_num_logical_layers(res, level);
const size_t per_level_array_size =
res->surf.levels * sizeof(enum isl_aux_state *);
/* We're going to allocate a single chunk of data for both the per-level
* reference array and the arrays of aux_state. This makes cleanup
* significantly easier.
*/
const size_t total_size =
per_level_array_size + total_slices * sizeof(enum isl_aux_state);
void *data = malloc(total_size);
if (!data)
return NULL;
enum isl_aux_state **per_level_arr = data;
enum isl_aux_state *s = data + per_level_array_size;
for (uint32_t level = 0; level < res->surf.levels; level++) {
per_level_arr[level] = s;
const unsigned level_layers = iris_get_num_logical_layers(res, level);
for (uint32_t a = 0; a < level_layers; a++)
*(s++) = initial;
}
assert((void *)s == data + total_size);
return per_level_arr;
}
static unsigned
iris_get_aux_clear_color_state_size(struct iris_screen *screen,
struct iris_resource *res)
{
if (!isl_aux_usage_has_fast_clears(res->aux.usage))
return 0;
assert(!isl_surf_usage_is_stencil(res->surf.usage));
/* Depth packets can't specify indirect clear values. The only time depth
* buffers can use indirect clear values is when they're accessed by the
* sampler via render surface state objects.
*/
if (isl_surf_usage_is_depth(res->surf.usage) &&
!iris_sample_with_depth_aux(screen->devinfo, res))
return 0;
return screen->isl_dev.ss.clear_color_state_size;
}
static void
map_aux_addresses(struct iris_screen *screen, struct iris_resource *res,
enum pipe_format pfmt, unsigned plane)
{
void *aux_map_ctx = iris_bufmgr_get_aux_map_context(screen->bufmgr);
if (!aux_map_ctx)
return;
if (isl_aux_usage_has_ccs(res->aux.usage)) {
const enum isl_format format =
iris_format_for_usage(screen->devinfo, pfmt, res->surf.usage).fmt;
const uint64_t format_bits =
intel_aux_map_format_bits(res->surf.tiling, format, plane);
const bool mapped =
intel_aux_map_add_mapping(aux_map_ctx,
res->bo->address + res->offset,
res->aux.bo->address +
res->aux.comp_ctrl_surf_offset,
res->surf.size_B, format_bits);
assert(mapped);
res->bo->aux_map_address = res->aux.bo->address;
}
}
static bool
want_ccs_e_for_format(const struct intel_device_info *devinfo,
enum isl_format format)
{
if (!isl_format_supports_ccs_e(devinfo, format))
return false;
const struct isl_format_layout *fmtl = isl_format_get_layout(format);
/* Prior to TGL, CCS_E seems to significantly hurt performance with 32-bit
* floating point formats. For example, Paraview's "Wavelet Volume" case
* uses both R32_FLOAT and R32G32B32A32_FLOAT, and enabling CCS_E for those
* formats causes a 62% FPS drop.
*
* However, many benchmarks seem to use 16-bit float with no issues.
*/
if (devinfo->ver <= 11 &&
fmtl->channels.r.bits == 32 && fmtl->channels.r.type == ISL_SFLOAT)
return false;
return true;
}
static bool
want_hiz_wt_for_res(const struct intel_device_info *devinfo,
const struct iris_resource *res)
{
/* Gen12 only supports single-sampled while Gen20+ supports
* multi-sampled images.
*/
if (devinfo->ver < 20 && res->surf.samples > 1)
return false;
if (!(res->surf.usage & ISL_SURF_USAGE_TEXTURE_BIT))
return false;
/* If this resource has the maximum number of samples supported by
* running platform and will be used as a texture, put the HiZ surface
* in write-through mode so that we can sample from it.
*/
return true;
}
static enum isl_surf_dim
target_to_isl_surf_dim(enum pipe_texture_target target)
{
switch (target) {
case PIPE_BUFFER:
case PIPE_TEXTURE_1D:
case PIPE_TEXTURE_1D_ARRAY:
return ISL_SURF_DIM_1D;
case PIPE_TEXTURE_2D:
case PIPE_TEXTURE_CUBE:
case PIPE_TEXTURE_RECT:
case PIPE_TEXTURE_2D_ARRAY:
case PIPE_TEXTURE_CUBE_ARRAY:
return ISL_SURF_DIM_2D;
case PIPE_TEXTURE_3D:
return ISL_SURF_DIM_3D;
case PIPE_MAX_TEXTURE_TYPES:
break;
}
unreachable("invalid texture type");
}
static bool
iris_resource_configure_main(const struct iris_screen *screen,
struct iris_resource *res,
const struct pipe_resource *templ,
uint64_t modifier, uint32_t row_pitch_B)
{
res->mod_info = isl_drm_modifier_get_info(modifier);
if (modifier != DRM_FORMAT_MOD_INVALID && res->mod_info == NULL)
return false;
isl_tiling_flags_t tiling_flags = 0;
if (res->mod_info != NULL) {
tiling_flags = 1 << res->mod_info->tiling;
} else if (templ->usage == PIPE_USAGE_STAGING ||
templ->bind & (PIPE_BIND_LINEAR | PIPE_BIND_CURSOR)) {
tiling_flags = ISL_TILING_LINEAR_BIT;
} else if (res->external_format != PIPE_FORMAT_NONE) {
/* This came from iris_resource_from_memobj and didn't have
* PIPE_BIND_LINEAR set, so "optimal" tiling is desired. Let isl
* select the tiling. The implicit contract is that both drivers
* will arrive at the same tiling by using the same code to decide.
*/
assert(modifier == DRM_FORMAT_MOD_INVALID);
tiling_flags = ISL_TILING_ANY_MASK;
} else if (!screen->devinfo->has_tiling_uapi &&
(templ->bind & (PIPE_BIND_SCANOUT | PIPE_BIND_SHARED))) {
tiling_flags = ISL_TILING_LINEAR_BIT;
} else if (templ->bind & PIPE_BIND_SCANOUT) {
tiling_flags = ISL_TILING_X_BIT;
} else {
tiling_flags = ISL_TILING_ANY_MASK;
}
/* We don't support Yf or Ys tiling yet */
tiling_flags &= ~ISL_TILING_STD_Y_MASK;
assert(tiling_flags != 0);
isl_surf_usage_flags_t usage = 0;
if (res->mod_info && !isl_drm_modifier_has_aux(modifier))
usage |= ISL_SURF_USAGE_DISABLE_AUX_BIT;
else if (!res->mod_info && res->external_format != PIPE_FORMAT_NONE)
usage |= ISL_SURF_USAGE_DISABLE_AUX_BIT;
else if (templ->bind & PIPE_BIND_CONST_BW)
usage |= ISL_SURF_USAGE_DISABLE_AUX_BIT;
if (templ->usage == PIPE_USAGE_STAGING)
usage |= ISL_SURF_USAGE_STAGING_BIT;
if (templ->bind & PIPE_BIND_RENDER_TARGET)
usage |= ISL_SURF_USAGE_RENDER_TARGET_BIT;
if (templ->bind & PIPE_BIND_SAMPLER_VIEW)
usage |= ISL_SURF_USAGE_TEXTURE_BIT;
if (templ->bind & PIPE_BIND_SHADER_IMAGE)
usage |= ISL_SURF_USAGE_STORAGE_BIT;
if (templ->bind & PIPE_BIND_SCANOUT)
usage |= ISL_SURF_USAGE_DISPLAY_BIT;
else if (isl_drm_modifier_needs_display_layout(modifier))
usage |= ISL_SURF_USAGE_DISPLAY_BIT;
if (templ->target == PIPE_TEXTURE_CUBE ||
templ->target == PIPE_TEXTURE_CUBE_ARRAY) {
usage |= ISL_SURF_USAGE_CUBE_BIT;
}
if (templ->usage != PIPE_USAGE_STAGING &&
util_format_is_depth_or_stencil(templ->format)) {
/* Should be handled by u_transfer_helper */
assert(!util_format_is_depth_and_stencil(templ->format));
usage |= templ->format == PIPE_FORMAT_S8_UINT ?
ISL_SURF_USAGE_STENCIL_BIT : ISL_SURF_USAGE_DEPTH_BIT;
}
if ((usage & ISL_SURF_USAGE_TEXTURE_BIT) ||
!isl_surf_usage_is_depth_or_stencil(usage)) {
/* Notify ISL that iris may access this image from different engines.
* The reads and writes performed by the engines are guaranteed to be
* sequential with respect to each other. This is due to the
* implementation of flush_for_cross_batch_dependencies().
*/
usage |= ISL_SURF_USAGE_MULTI_ENGINE_SEQ_BIT;
} else {
/* Depth/stencil render buffers are the only surfaces which are not
* accessed by compute shaders. Also, iris does not use the blitter on
* such surfaces.
*/
assert(!(templ->bind & PIPE_BIND_SHADER_IMAGE));
assert(!(templ->bind & PIPE_BIND_PRIME_BLIT_DST));
}
const enum isl_format format =
iris_format_for_usage(screen->devinfo, templ->format, usage).fmt;
const struct isl_surf_init_info init_info = {
.dim = target_to_isl_surf_dim(templ->target),
.format = format,
.width = templ->width0,
.height = templ->height0,
.depth = templ->depth0,
.levels = templ->last_level + 1,
.array_len = templ->array_size,
.samples = MAX2(templ->nr_samples, 1),
.min_alignment_B = 0,
.row_pitch_B = row_pitch_B,
.usage = usage,
.tiling_flags = tiling_flags
};
if (!isl_surf_init_s(&screen->isl_dev, &res->surf, &init_info))
return false;
res->internal_format = templ->format;
return true;
}
/**
* Configure aux for the resource, but don't allocate it. For images which
* might be shared with modifiers, we must allocate the image and aux data in
* a single bo.
*
* Returns false on unexpected error (e.g. allocation failed, or invalid
* configuration result).
*/
static bool
iris_resource_configure_aux(struct iris_screen *screen,
struct iris_resource *res)
{
const struct intel_device_info *devinfo = screen->devinfo;
const bool has_mcs =
isl_surf_get_mcs_surf(&screen->isl_dev, &res->surf, &res->aux.surf);
const bool has_hiz =
isl_surf_get_hiz_surf(&screen->isl_dev, &res->surf, &res->aux.surf);
const bool has_ccs = devinfo->has_aux_map || devinfo->has_flat_ccs ?
isl_surf_supports_ccs(&screen->isl_dev, &res->surf, &res->aux.surf) :
isl_surf_get_ccs_surf(&screen->isl_dev, &res->surf, &res->aux.surf, 0);
if (has_mcs) {
assert(!res->mod_info);
assert(!has_hiz);
/* We are seeing failures with CCS compression on top of MSAA
* compression, so just enable MSAA compression for now on DG2.
*/
if (!intel_device_info_is_dg2(devinfo) && has_ccs) {
res->aux.usage = ISL_AUX_USAGE_MCS_CCS;
} else {
res->aux.usage = ISL_AUX_USAGE_MCS;
}
} else if (has_hiz) {
assert(!res->mod_info);
assert(!has_mcs);
if (!has_ccs) {
res->aux.usage = ISL_AUX_USAGE_HIZ;
} else if (want_hiz_wt_for_res(devinfo, res)) {
res->aux.usage = ISL_AUX_USAGE_HIZ_CCS_WT;
} else {
res->aux.usage = ISL_AUX_USAGE_HIZ_CCS;
}
} else if (has_ccs) {
if (isl_surf_usage_is_stencil(res->surf.usage)) {
assert(!res->mod_info);
res->aux.usage = ISL_AUX_USAGE_STC_CCS;
} else if (res->mod_info && res->mod_info->supports_media_compression) {
res->aux.usage = ISL_AUX_USAGE_MC;
} else if (want_ccs_e_for_format(devinfo, res->surf.format)) {
res->aux.usage = intel_needs_workaround(devinfo, 1607794140) ?
ISL_AUX_USAGE_FCV_CCS_E : ISL_AUX_USAGE_CCS_E;
} else {
assert(isl_format_supports_ccs_d(devinfo, res->surf.format));
res->aux.usage = ISL_AUX_USAGE_CCS_D;
}
}
if (res->mod_info &&
isl_drm_modifier_has_aux(res->mod_info->modifier) != has_ccs) {
return false;
}
return true;
}
/**
* Initialize the aux buffer contents.
*
* Returns false on unexpected error (e.g. mapping a BO failed).
*/
static bool
iris_resource_init_aux_buf(struct iris_screen *screen,
struct iris_resource *res)
{
const struct intel_device_info *devinfo = screen->devinfo;
if (isl_aux_usage_has_ccs(res->aux.usage) && devinfo->ver <= 11) {
/* Initialize the CCS on BDW-ICL to the PASS_THROUGH state. This avoids
* the need to ambiguate in some cases.
*/
void* map = iris_bo_map(NULL, res->bo, MAP_WRITE | MAP_RAW);
if (!map)
return false;
memset((char*)map + res->aux.offset, 0, res->aux.surf.size_B);
iris_bo_unmap(res->bo);
res->aux.state = create_aux_state_map(res, ISL_AUX_STATE_PASS_THROUGH);
} else {
const enum isl_aux_state initial_state =
isl_aux_get_initial_state(devinfo, res->aux.usage, res->bo->zeroed);
res->aux.state = create_aux_state_map(res, initial_state);
}
if (!res->aux.state)
return false;
if (res->aux.offset > 0 || res->aux.comp_ctrl_surf_offset > 0) {
res->aux.bo = res->bo;
iris_bo_reference(res->aux.bo);
map_aux_addresses(screen, res, res->internal_format, 0);
}
if (res->aux.clear_color_offset > 0) {
res->aux.clear_color_bo = res->bo;
iris_bo_reference(res->aux.clear_color_bo);
res->aux.clear_color_unknown = !res->aux.clear_color_bo->zeroed;
}
return true;
}
static uint32_t
iris_buffer_alignment(uint64_t size)
{
/* Some buffer operations want some amount of alignment. The largest
* buffer texture pixel size is 4 * 4 = 16B. OpenCL data is also supposed
* to be aligned and largest OpenCL data type is a double16 which is
* 8 * 16 = 128B. Align to the largest power of 2 which fits in the size,
* up to 128B.
*/
uint32_t align = MAX2(4 * 4, 8 * 16);
while (align > size)
align >>= 1;
return align;
}
static struct pipe_resource *
iris_resource_create_for_buffer(struct pipe_screen *pscreen,
const struct pipe_resource *templ)
{
struct iris_screen *screen = (struct iris_screen *)pscreen;
struct iris_resource *res = iris_alloc_resource(pscreen, templ);
assert(templ->target == PIPE_BUFFER);
assert(templ->height0 <= 1);
assert(templ->depth0 <= 1);
assert(templ->format == PIPE_FORMAT_NONE ||
util_format_get_blocksize(templ->format) == 1);
res->internal_format = templ->format;
res->surf.tiling = ISL_TILING_LINEAR;
enum iris_memory_zone memzone = IRIS_MEMZONE_OTHER;
const char *name = templ->target == PIPE_BUFFER ? "buffer" : "miptree";
if (templ->flags & IRIS_RESOURCE_FLAG_SHADER_MEMZONE) {
memzone = IRIS_MEMZONE_SHADER;
name = "shader kernels";
} else if (templ->flags & IRIS_RESOURCE_FLAG_SURFACE_MEMZONE) {
memzone = IRIS_MEMZONE_SURFACE;
name = "surface state";
} else if (templ->flags & IRIS_RESOURCE_FLAG_DYNAMIC_MEMZONE) {
memzone = IRIS_MEMZONE_DYNAMIC;
name = "dynamic state";
} else if (templ->flags & IRIS_RESOURCE_FLAG_SCRATCH_MEMZONE) {
memzone = IRIS_MEMZONE_SCRATCH;
name = "scratch surface state";
}
unsigned flags = iris_resource_alloc_flags(screen, templ, res);
res->bo = iris_bo_alloc(screen->bufmgr, name, templ->width0,
iris_buffer_alignment(templ->width0),
memzone, flags);
if (!res->bo) {
iris_resource_destroy(pscreen, &res->base.b);
return NULL;
}
if (templ->bind & PIPE_BIND_SHARED) {
iris_bo_mark_exported(res->bo);
res->base.is_shared = true;
}
return &res->base.b;
}
static bool
iris_resource_image_is_pat_compressible(const struct iris_screen *screen,
const struct pipe_resource *templ,
struct iris_resource *res,
unsigned flags)
{
assert(templ->target != PIPE_BUFFER);
if (INTEL_DEBUG(DEBUG_NO_CCS))
return false;
if (screen->devinfo->ver < 20)
return false;
if (flags & (BO_ALLOC_PROTECTED |
BO_ALLOC_COHERENT |
BO_ALLOC_CPU_VISIBLE))
return false;
struct iris_bufmgr *bufmgr = screen->bufmgr;
if ((iris_bufmgr_vram_size(bufmgr) > 0) && (flags & BO_ALLOC_SMEM))
return false;
/* We don't have modifiers with compression enabled on Xe2 so far. */
if (res->mod_info) {
assert(!isl_drm_modifier_has_aux(res->mod_info->modifier));
return false;
}
/* Bspec 58797 (r58646):
*
* Enabling compression is not legal for TileX surfaces.
*/
if (res->surf.tiling == ISL_TILING_X)
return false;
/* Bspec 71650 (r59764):
*
* 3 SW must disable or resolve compression
* Display: Access to anything except Tile4 Framebuffers...
* Display Page Tables
* Display State Buffers
* Linear/TileX Framebuffers
* Display Write-Back Buffers
* Etc.
*
* So far, we don't support resolving on Xe2 and may not want to enable
* compression under these conditions later, so we only enable it when
* a TILING_4 image is to display.
*/
if ((flags & BO_ALLOC_SCANOUT) && res->surf.tiling != ISL_TILING_4) {
assert(res->surf.tiling == ISL_TILING_LINEAR);
return false;
}
return true;
}
static struct pipe_resource *
iris_resource_create_for_image(struct pipe_screen *pscreen,
const struct pipe_resource *templ,
const uint64_t *modifiers,
int modifiers_count,
unsigned row_pitch_B)
{
struct iris_screen *screen = (struct iris_screen *)pscreen;
const struct intel_device_info *devinfo = screen->devinfo;
struct iris_resource *res = iris_alloc_resource(pscreen, templ);
if (!res)
return NULL;
uint64_t modifier =
select_best_modifier(devinfo, templ, modifiers, modifiers_count);
if (modifier == DRM_FORMAT_MOD_INVALID && modifiers_count > 0) {
fprintf(stderr, "Unsupported modifier, resource creation failed.\n");
goto fail;
}
const bool isl_surf_created_successfully =
iris_resource_configure_main(screen, res, templ, modifier, row_pitch_B);
if (!isl_surf_created_successfully)
goto fail;
/* Don't create staging surfaces that will use over half the sram,
* since staging implies you are copying data to another resource that's
* at least as large, and then both wouldn't fit in system memory.
*
* Skip this for discrete cards, as the destination buffer might be in
* device local memory while the staging buffer would be in system memory,
* so both would fit.
*/
if (templ->usage == PIPE_USAGE_STAGING && !devinfo->has_local_mem &&
res->surf.size_B > (iris_bufmgr_sram_size(screen->bufmgr) / 2))
goto fail;
if (!iris_resource_configure_aux(screen, res))
goto fail;
const char *name = "miptree";
enum iris_memory_zone memzone = IRIS_MEMZONE_OTHER;
unsigned flags = iris_resource_alloc_flags(screen, templ, res);
if (iris_resource_image_is_pat_compressible(screen, templ, res, flags))
flags |= BO_ALLOC_COMPRESSED;
/* These are for u_upload_mgr buffers only */
assert(!(templ->flags & (IRIS_RESOURCE_FLAG_SHADER_MEMZONE |
IRIS_RESOURCE_FLAG_SURFACE_MEMZONE |
IRIS_RESOURCE_FLAG_DYNAMIC_MEMZONE |
IRIS_RESOURCE_FLAG_SCRATCH_MEMZONE)));
/* Modifiers require the aux data to be in the same buffer as the main
* surface, but we combine them even when a modifier is not being used.
*/
uint64_t bo_size = res->surf.size_B;
/* Allocate space for the aux buffer. */
if (res->aux.surf.size_B > 0) {
res->aux.offset = (uint32_t)align64(bo_size, res->aux.surf.alignment_B);
bo_size = res->aux.offset + res->aux.surf.size_B;
}
/* Allocate space for the compression control surface. */
if (devinfo->has_aux_map && isl_aux_usage_has_ccs(res->aux.usage)) {
res->aux.comp_ctrl_surf_offset =
(uint32_t)align64(bo_size, INTEL_AUX_MAP_META_ALIGNMENT_B);
bo_size = res->aux.comp_ctrl_surf_offset +
res->surf.size_B / INTEL_AUX_MAP_MAIN_SIZE_SCALEDOWN;
}
/* Allocate space for the indirect clear color. */
if (iris_get_aux_clear_color_state_size(screen, res) > 0) {
/* Kernel expects a 4k alignment, otherwise the display rejects the
* surface.
*/
const uint64_t clear_color_alignment =
(res->mod_info && res->mod_info->supports_clear_color) ? 4096 : 64;
res->aux.clear_color_offset = align64(bo_size, clear_color_alignment);
bo_size = res->aux.clear_color_offset +
iris_get_aux_clear_color_state_size(screen, res);
}
/* The ISL alignment already includes AUX-TT requirements, so no additional
* attention required here :)
*/
uint32_t alignment = MAX2(4096, res->surf.alignment_B);
res->bo =
iris_bo_alloc(screen->bufmgr, name, bo_size, alignment, memzone, flags);
if (!res->bo)
goto fail;
if (res->aux.usage != ISL_AUX_USAGE_NONE &&
!iris_resource_init_aux_buf(screen, res))
goto fail;
if (templ->bind & PIPE_BIND_SHARED) {
iris_bo_mark_exported(res->bo);
res->base.is_shared = true;
}
return &res->base.b;
fail:
iris_resource_destroy(pscreen, &res->base.b);
return NULL;
}
static struct pipe_resource *
iris_resource_create_with_modifiers(struct pipe_screen *pscreen,
const struct pipe_resource *templ,
const uint64_t *modifiers,
int modifier_count)
{
return iris_resource_create_for_image(pscreen, templ, modifiers,
modifier_count, 0);
}
static struct pipe_resource *
iris_resource_create(struct pipe_screen *pscreen,
const struct pipe_resource *templ)
{
if (templ->target == PIPE_BUFFER)
return iris_resource_create_for_buffer(pscreen, templ);
else
return iris_resource_create_with_modifiers(pscreen, templ, NULL, 0);
}
static uint64_t
tiling_to_modifier(struct iris_bufmgr *bufmgr, uint32_t tiling)
{
if (iris_bufmgr_get_device_info(bufmgr)->kmd_type != INTEL_KMD_TYPE_I915) {
assert(tiling == 0);
return DRM_FORMAT_MOD_LINEAR;
}
return iris_i915_tiling_to_modifier(tiling);
}
static struct pipe_resource *
iris_resource_from_user_memory(struct pipe_screen *pscreen,
const struct pipe_resource *templ,
void *user_memory)
{
if (templ->target != PIPE_BUFFER &&
templ->target != PIPE_TEXTURE_1D &&
templ->target != PIPE_TEXTURE_2D)
return NULL;
if (templ->array_size > 1)
return NULL;
struct iris_screen *screen = (struct iris_screen *)pscreen;
struct iris_bufmgr *bufmgr = screen->bufmgr;
struct iris_resource *res = iris_alloc_resource(pscreen, templ);
if (!res)
return NULL;
size_t res_size = templ->width0;
if (templ->target != PIPE_BUFFER) {
const uint32_t row_pitch_B =
templ->width0 * util_format_get_blocksize(templ->format);
res_size = templ->height0 * row_pitch_B;
if (!iris_resource_configure_main(screen, res, templ,
DRM_FORMAT_MOD_LINEAR,
row_pitch_B)) {
iris_resource_destroy(pscreen, &res->base.b);
return NULL;
}
assert(res->surf.size_B <= res_size);
}
/* The userptr ioctl only works on whole pages. Because we know that
* things will exist in memory at a page granularity, we can expand the
* range given by the client into the whole number of pages and use an
* offset on the resource to make it looks like it starts at the user's
* pointer.
*/
size_t page_size = getpagesize();
assert(util_is_power_of_two_nonzero_uintptr(page_size));
size_t offset = (uintptr_t)user_memory & (page_size - 1);
void *mem_start = (char *)user_memory - offset;
size_t mem_size = offset + res_size;
mem_size = ALIGN_NPOT(mem_size, page_size);
res->internal_format = templ->format;
res->base.is_user_ptr = true;
res->bo = iris_bo_create_userptr(bufmgr, "user", mem_start, mem_size,
IRIS_MEMZONE_OTHER);
res->offset = offset;
if (!res->bo) {
iris_resource_destroy(pscreen, &res->base.b);
return NULL;
}
util_range_add(&res->base.b, &res->valid_buffer_range, 0, templ->width0);
return &res->base.b;
}
static unsigned
get_num_planes(const struct pipe_resource *resource)
{
unsigned count = 0;
for (const struct pipe_resource *cur = resource; cur; cur = cur->next)
count++;
return count;
}
static unsigned
get_main_plane_for_plane(enum pipe_format format,
unsigned plane)
{
if (format == PIPE_FORMAT_NONE) {
/* Created dmabuf resources have this format. */
return 0;
} else if (isl_format_for_pipe_format(format) == ISL_FORMAT_UNSUPPORTED) {
/* This format has been lowered to more planes than are native to it.
* So, compression modifiers are not enabled and the plane index is used
* as-is.
*/
return plane;
} else {
unsigned int n_planes = util_format_get_num_planes(format);
return plane % n_planes;
}
}
static struct pipe_resource *
iris_resource_from_handle(struct pipe_screen *pscreen,
const struct pipe_resource *templ,
struct winsys_handle *whandle,
unsigned usage)
{
struct iris_screen *screen = (struct iris_screen *)pscreen;
const struct intel_device_info *devinfo = screen->devinfo;
struct iris_bufmgr *bufmgr = screen->bufmgr;
/* The gallium dri layer creates a pipe resource for each plane specified
* by the format and modifier. Once all planes are present, we will merge
* the separate parameters into the iris_resource(s) for the main plane(s).
* Save the modifier import information now to reconstruct later.
*/
struct iris_resource *res = iris_alloc_resource(pscreen, templ);
if (!res)
return NULL;
switch (whandle->type) {
case WINSYS_HANDLE_TYPE_FD:
res->bo = iris_bo_import_dmabuf(bufmgr, whandle->handle,
whandle->modifier);
break;
case WINSYS_HANDLE_TYPE_SHARED:
res->bo = iris_bo_gem_create_from_name(bufmgr, "winsys image",
whandle->handle);
break;
default:
unreachable("invalid winsys handle type");
}
if (!res->bo)
goto fail;
res->offset = whandle->offset;
res->surf.row_pitch_B = whandle->stride;
if (whandle->plane == 0) {
/* All planes are present. Fill out the main plane resource(s). */
for (unsigned plane = 0; plane < util_resource_num(templ); plane++) {
const unsigned main_plane =
get_main_plane_for_plane(whandle->format, plane);
struct iris_resource *main_res = (struct iris_resource *)
util_resource_at_index(&res->base.b, main_plane);
const struct iris_resource *plane_res = (struct iris_resource *)
util_resource_at_index(&res->base.b, plane);
if (isl_drm_modifier_plane_is_clear_color(whandle->modifier,
plane)) {
/* Fill out the clear color fields. */
assert(plane_res->bo->size >= plane_res->offset +
screen->isl_dev.ss.clear_color_state_size);
iris_bo_reference(plane_res->bo);
main_res->aux.clear_color_bo = plane_res->bo;
main_res->aux.clear_color_offset = plane_res->offset;
main_res->aux.clear_color_unknown = true;
} else if (plane > main_plane) {
/* Fill out some aux surface fields. */
assert(isl_drm_modifier_has_aux(whandle->modifier));
assert(!devinfo->has_flat_ccs);
iris_bo_reference(plane_res->bo);
res->aux.bo = plane_res->bo;
if (devinfo->has_aux_map) {
assert(plane_res->surf.row_pitch_B ==
main_res->surf.row_pitch_B /
INTEL_AUX_MAP_MAIN_PITCH_SCALEDOWN);
assert(plane_res->bo->size >= plane_res->offset +
main_res->surf.size_B /
INTEL_AUX_MAP_MAIN_SIZE_SCALEDOWN);
main_res->aux.comp_ctrl_surf_offset = plane_res->offset;
map_aux_addresses(screen, main_res, whandle->format,
main_plane);
} else {
assert(plane_res->surf.row_pitch_B ==
main_res->aux.surf.row_pitch_B);
assert(plane_res->bo->size >= plane_res->offset +
main_res->aux.surf.size_B);
main_res->aux.offset = plane_res->offset;
}
} else {
/* Fill out fields that are convenient to initialize now. */
assert(plane == main_plane);
main_res->external_format = whandle->format;
if (templ->target == PIPE_BUFFER) {
main_res->surf.tiling = ISL_TILING_LINEAR;
return &main_res->base.b;
}
uint64_t modifier;
if (whandle->modifier == DRM_FORMAT_MOD_INVALID) {
/* We have no modifier; match whatever GEM_GET_TILING says */
uint32_t tiling;
iris_gem_get_tiling(main_res->bo, &tiling);
modifier = tiling_to_modifier(bufmgr, tiling);
} else {
modifier = whandle->modifier;
}
const bool isl_surf_created_successfully =
iris_resource_configure_main(screen, main_res,
&main_res->base.b, modifier,
main_res->surf.row_pitch_B);
if (!isl_surf_created_successfully)
goto fail;
assert(main_res->bo->size >= main_res->offset +
main_res->surf.size_B);
if (!iris_resource_configure_aux(screen, main_res))
goto fail;
if (res->aux.usage != ISL_AUX_USAGE_NONE) {
const enum isl_aux_state aux_state =
isl_drm_modifier_get_default_aux_state(modifier);
main_res->aux.state =
create_aux_state_map(main_res, aux_state);
if (!main_res->aux.state)
goto fail;
}
/* Add on a clear color BO if needed. */
if (!main_res->mod_info->supports_clear_color &&
iris_get_aux_clear_color_state_size(screen, main_res) > 0) {
main_res->aux.clear_color_bo =
iris_bo_alloc(screen->bufmgr, "clear color buffer",
screen->isl_dev.ss.clear_color_state_size,
64, IRIS_MEMZONE_OTHER, BO_ALLOC_ZEROED);
if (!main_res->aux.clear_color_bo)
goto fail;
}
}
}
}
return &res->base.b;
fail:
iris_resource_destroy(pscreen, &res->base.b);
return NULL;
}
static struct pipe_resource *
iris_resource_from_memobj(struct pipe_screen *pscreen,
const struct pipe_resource *templ,
struct pipe_memory_object *pmemobj,
uint64_t offset)
{
struct iris_screen *screen = (struct iris_screen *)pscreen;
struct iris_memory_object *memobj = (struct iris_memory_object *)pmemobj;
struct iris_resource *res = iris_alloc_resource(pscreen, templ);
if (!res)
return NULL;
res->bo = memobj->bo;
res->offset = offset;
res->external_format = templ->format;
res->internal_format = templ->format;
if (templ->flags & PIPE_RESOURCE_FLAG_TEXTURING_MORE_LIKELY) {
UNUSED const bool isl_surf_created_successfully =
iris_resource_configure_main(screen, res, templ, DRM_FORMAT_MOD_INVALID, 0);
assert(isl_surf_created_successfully);
}
iris_bo_reference(memobj->bo);
return &res->base.b;
}
/* Handle combined depth/stencil with memory objects.
*
* This function is modeled after u_transfer_helper_resource_create.
*/
static struct pipe_resource *
iris_resource_from_memobj_wrapper(struct pipe_screen *pscreen,
const struct pipe_resource *templ,
struct pipe_memory_object *pmemobj,
uint64_t offset)
{
enum pipe_format format = templ->format;
/* Normal case, no special handling: */
if (!(util_format_is_depth_and_stencil(format)))
return iris_resource_from_memobj(pscreen, templ, pmemobj, offset);
struct pipe_resource t = *templ;
t.format = util_format_get_depth_only(format);
struct pipe_resource *prsc =
iris_resource_from_memobj(pscreen, &t, pmemobj, offset);
if (!prsc)
return NULL;
struct iris_resource *res = (struct iris_resource *) prsc;
/* Stencil offset in the buffer without aux. */
uint64_t s_offset = offset +
align64(res->surf.size_B, res->surf.alignment_B);
prsc->format = format; /* frob the format back to the "external" format */
t.format = PIPE_FORMAT_S8_UINT;
struct pipe_resource *stencil =
iris_resource_from_memobj(pscreen, &t, pmemobj, s_offset);
if (!stencil) {
iris_resource_destroy(pscreen, prsc);
return NULL;
}
iris_resource_set_separate_stencil(prsc, stencil);
return prsc;
}
/**
* Reallocate a (non-external) resource into new storage, copying the data
* and modifying the original resource to point at the new storage.
*
* This is useful for e.g. moving a suballocated internal resource to a
* dedicated allocation that can be exported by itself.
*/
static void
iris_reallocate_resource_inplace(struct iris_context *ice,
struct iris_resource *old_res,
unsigned new_bind_flag)
{
struct pipe_screen *pscreen = ice->ctx.screen;
if (iris_bo_is_external(old_res->bo))
return;
assert(old_res->mod_info == NULL);
assert(old_res->bo == old_res->aux.bo || old_res->aux.bo == NULL);
assert(old_res->bo == old_res->aux.clear_color_bo ||
old_res->aux.clear_color_bo == NULL);
assert(old_res->external_format == PIPE_FORMAT_NONE);
struct pipe_resource templ = old_res->base.b;
templ.bind |= new_bind_flag;
struct iris_resource *new_res =
(void *) pscreen->resource_create(pscreen, &templ);
assert(iris_bo_is_real(new_res->bo));
struct iris_batch *batch = &ice->batches[IRIS_BATCH_RENDER];
if (old_res->base.b.target == PIPE_BUFFER) {
struct pipe_box box = (struct pipe_box) {
.width = old_res->base.b.width0,
.height = 1,
};
iris_copy_region(&ice->blorp, batch, &new_res->base.b, 0, 0, 0, 0,
&old_res->base.b, 0, &box);
} else {
for (unsigned l = 0; l <= templ.last_level; l++) {
struct pipe_box box = (struct pipe_box) {
.width = u_minify(templ.width0, l),
.height = u_minify(templ.height0, l),
.depth = util_num_layers(&templ, l),
};
iris_copy_region(&ice->blorp, batch, &new_res->base.b, l, 0, 0, 0,
&old_res->base.b, l, &box);
}
}
struct iris_bo *old_bo = old_res->bo;
struct iris_bo *old_aux_bo = old_res->aux.bo;
struct iris_bo *old_clear_color_bo = old_res->aux.clear_color_bo;
/* Replace the structure fields with the new ones */
old_res->base.b.bind = templ.bind;
old_res->surf = new_res->surf;
old_res->bo = new_res->bo;
old_res->aux.surf = new_res->aux.surf;
old_res->aux.bo = new_res->aux.bo;
old_res->aux.offset = new_res->aux.offset;
old_res->aux.comp_ctrl_surf_offset = new_res->aux.comp_ctrl_surf_offset;
old_res->aux.clear_color_bo = new_res->aux.clear_color_bo;
old_res->aux.clear_color_offset = new_res->aux.clear_color_offset;
old_res->aux.usage = new_res->aux.usage;
if (new_res->aux.state) {
assert(old_res->aux.state);
for (unsigned l = 0; l <= templ.last_level; l++) {
unsigned layers = util_num_layers(&templ, l);
for (unsigned z = 0; z < layers; z++) {
enum isl_aux_state aux =
iris_resource_get_aux_state(new_res, l, z);
iris_resource_set_aux_state(ice, old_res, l, z, 1, aux);
}
}
}
/* old_res now points at the new BOs, make new_res point at the old ones
* so they'll be freed when we unreference the resource below.
*/
new_res->bo = old_bo;
new_res->aux.bo = old_aux_bo;
new_res->aux.clear_color_bo = old_clear_color_bo;
pipe_resource_reference((struct pipe_resource **)&new_res, NULL);
}
static void
iris_flush_resource(struct pipe_context *ctx, struct pipe_resource *resource)
{
struct iris_context *ice = (struct iris_context *)ctx;
struct iris_resource *res = (void *) resource;
const struct isl_drm_modifier_info *mod = res->mod_info;
bool newly_external = false;
/* flush_resource() may be used to prepare an image for sharing externally
* with other clients (e.g. via eglCreateImage). To account for this, we
* make sure to eliminate suballocation and any compression that a consumer
* wouldn't know how to handle.
*/
if (!iris_bo_is_real(res->bo)) {
assert(!(res->base.b.bind & PIPE_BIND_SHARED));
iris_reallocate_resource_inplace(ice, res, PIPE_BIND_SHARED);
assert(res->base.b.bind & PIPE_BIND_SHARED);
newly_external = true;
}
iris_resource_prepare_access(ice, res,
0, INTEL_REMAINING_LEVELS,
0, INTEL_REMAINING_LAYERS,
mod ? res->aux.usage : ISL_AUX_USAGE_NONE,
mod ? mod->supports_clear_color : false);
bool disable_aux = !res->mod_info && res->aux.usage != ISL_AUX_USAGE_NONE;
if (newly_external || disable_aux) {
iris_foreach_batch(ice, batch) {
if (iris_batch_references(batch, res->bo))
iris_batch_flush(batch);
}
}
if (disable_aux)
iris_resource_disable_aux(res);
}
static void
iris_resource_disable_aux_on_first_query(struct pipe_resource *resource,
unsigned usage)
{
struct iris_resource *res = (struct iris_resource *)resource;
bool mod_with_aux =
res->mod_info && isl_drm_modifier_has_aux(res->mod_info->modifier);
/* Disable aux usage if explicit flush not set and this is the first time
* we are dealing with this resource and the resource was not created with
* a modifier with aux.
*/
if (!mod_with_aux &&
(!(usage & PIPE_HANDLE_USAGE_EXPLICIT_FLUSH) && res->aux.usage != 0) &&
p_atomic_read(&resource->reference.count) == 1) {
iris_resource_disable_aux(res);
}
}
static bool
iris_resource_get_param(struct pipe_screen *pscreen,
struct pipe_context *ctx,
struct pipe_resource *resource,
unsigned plane,
unsigned layer,
unsigned level,
enum pipe_resource_param param,
unsigned handle_usage,
uint64_t *value)
{
struct iris_screen *screen = (struct iris_screen *)pscreen;
struct iris_resource *base_res = (struct iris_resource *)resource;
unsigned main_plane = get_main_plane_for_plane(base_res->external_format,
plane);
struct iris_resource *res =
(struct iris_resource *)util_resource_at_index(resource, main_plane);
assert(res);
bool mod_with_aux =
res->mod_info && isl_drm_modifier_has_aux(res->mod_info->modifier);
bool wants_aux = mod_with_aux && plane != main_plane;
bool wants_cc = mod_with_aux &&
isl_drm_modifier_plane_is_clear_color(res->mod_info->modifier, plane);
bool result;
unsigned handle;
iris_resource_disable_aux_on_first_query(resource, handle_usage);
struct iris_bo *bo = wants_cc ? res->aux.clear_color_bo :
wants_aux ? res->aux.bo : res->bo;
assert(iris_bo_is_real(bo));
switch (param) {
case PIPE_RESOURCE_PARAM_NPLANES:
if (mod_with_aux) {
*value = iris_get_dmabuf_modifier_planes(pscreen,
res->mod_info->modifier,
res->external_format);
} else {
*value = get_num_planes(&res->base.b);
}
return true;
case PIPE_RESOURCE_PARAM_STRIDE:
if (wants_cc) {
*value = ISL_DRM_CC_PLANE_PITCH_B;
} else if (wants_aux) {
*value = screen->devinfo->has_aux_map ?
res->surf.row_pitch_B / INTEL_AUX_MAP_MAIN_PITCH_SCALEDOWN :
res->aux.surf.row_pitch_B;
} else {
*value = res->surf.row_pitch_B;
}
/* Mesa's implementation of eglCreateImage rejects strides of zero (see
* dri2_check_dma_buf_attribs). Ensure we return a non-zero stride as
* this value may be queried from GBM and passed into EGL.
*
* We make an exception for buffers. For OpenCL gl_sharing we have to
* support exporting buffers, for which we report a stride of 0 here.
*/
assert(*value != 0 || resource->target == PIPE_BUFFER);
return true;
case PIPE_RESOURCE_PARAM_OFFSET:
if (wants_cc) {
*value = res->aux.clear_color_offset;
} else if (wants_aux) {
*value = screen->devinfo->has_aux_map ?
res->aux.comp_ctrl_surf_offset :
res->aux.offset;
} else {
*value = res->offset;
}
return true;
case PIPE_RESOURCE_PARAM_MODIFIER:
if (res->mod_info) {
*value = res->mod_info->modifier;
} else {
/* We restrict ourselves to modifiers without CCS for several
* reasons:
*
* - Mesa's implementation of EGL_MESA_image_dma_buf_export
* currently only exports a single plane (see
* dri2_export_dma_buf_image_mesa), but for some modifiers,
* CCS exists in a second plane.
*
* - Even if we returned CCS modifiers, iris currently
* resolves away compression during the export/flushing process
* (see iris_flush_resource). So, only uncompressed data is
* exposed anyways.
*/
switch (res->surf.tiling) {
case ISL_TILING_4: *value = I915_FORMAT_MOD_4_TILED; break;
case ISL_TILING_Y0: *value = I915_FORMAT_MOD_Y_TILED; break;
case ISL_TILING_X: *value = I915_FORMAT_MOD_X_TILED; break;
case ISL_TILING_LINEAR: *value = DRM_FORMAT_MOD_LINEAR; break;
default:
assert("no modifier mapped for resource's tiling");
return false;
}
}
return true;
case PIPE_RESOURCE_PARAM_HANDLE_TYPE_SHARED:
if (!wants_aux)
iris_gem_set_tiling(bo, &res->surf);
result = iris_bo_flink(bo, &handle) == 0;
if (result)
*value = handle;
return result;
case PIPE_RESOURCE_PARAM_HANDLE_TYPE_KMS: {
if (!wants_aux)
iris_gem_set_tiling(bo, &res->surf);
/* Because we share the same drm file across multiple iris_screen, when
* we export a GEM handle we must make sure it is valid in the DRM file
* descriptor the caller is using (this is the FD given at screen
* creation).
*/
uint32_t handle;
if (iris_bo_export_gem_handle_for_device(bo, screen->winsys_fd, &handle))
return false;
*value = handle;
return true;
}
case PIPE_RESOURCE_PARAM_HANDLE_TYPE_FD:
if (!wants_aux)
iris_gem_set_tiling(bo, &res->surf);
result = iris_bo_export_dmabuf(bo, (int *) &handle) == 0;
if (result)
*value = handle;
return result;
default:
return false;
}
}
static bool
iris_resource_get_handle(struct pipe_screen *pscreen,
struct pipe_context *ctx,
struct pipe_resource *resource,
struct winsys_handle *whandle,
unsigned usage)
{
struct iris_screen *screen = (struct iris_screen *) pscreen;
struct iris_resource *res = (struct iris_resource *)resource;
bool mod_with_aux =
res->mod_info && isl_drm_modifier_has_aux(res->mod_info->modifier);
iris_resource_disable_aux_on_first_query(resource, usage);
assert(iris_bo_is_real(res->bo));
struct iris_bo *bo;
if (res->mod_info &&
isl_drm_modifier_plane_is_clear_color(res->mod_info->modifier,
whandle->plane)) {
bo = res->aux.clear_color_bo;
} else if (mod_with_aux && whandle->plane > 0) {
bo = res->aux.bo;
} else {
bo = res->bo;
}
uint64_t stride;
iris_resource_get_param(pscreen, ctx, resource, whandle->plane, 0, 0,
PIPE_RESOURCE_PARAM_STRIDE, usage, &stride);
uint64_t offset;
iris_resource_get_param(pscreen, ctx, resource, whandle->plane, 0, 0,
PIPE_RESOURCE_PARAM_OFFSET, usage, &offset);
uint64_t modifier;
iris_resource_get_param(pscreen, ctx, resource, whandle->plane, 0, 0,
PIPE_RESOURCE_PARAM_MODIFIER, usage, &modifier);
whandle->stride = stride;
whandle->offset = offset;
whandle->modifier = modifier;
whandle->format = res->external_format;
#ifndef NDEBUG
enum isl_aux_usage allowed_usage =
(usage & PIPE_HANDLE_USAGE_EXPLICIT_FLUSH) || mod_with_aux ?
res->aux.usage : ISL_AUX_USAGE_NONE;
if (res->aux.usage != allowed_usage) {
enum isl_aux_state aux_state = iris_resource_get_aux_state(res, 0, 0);
assert(aux_state == ISL_AUX_STATE_RESOLVED ||
aux_state == ISL_AUX_STATE_PASS_THROUGH);
}
#endif
switch (whandle->type) {
case WINSYS_HANDLE_TYPE_SHARED:
iris_gem_set_tiling(bo, &res->surf);
return iris_bo_flink(bo, &whandle->handle) == 0;
case WINSYS_HANDLE_TYPE_KMS: {
iris_gem_set_tiling(bo, &res->surf);
/* Because we share the same drm file across multiple iris_screen, when
* we export a GEM handle we must make sure it is valid in the DRM file
* descriptor the caller is using (this is the FD given at screen
* creation).
*/
uint32_t handle;
if (iris_bo_export_gem_handle_for_device(bo, screen->winsys_fd, &handle))
return false;
whandle->handle = handle;
return true;
}
case WINSYS_HANDLE_TYPE_FD:
iris_gem_set_tiling(bo, &res->surf);
return iris_bo_export_dmabuf(bo, (int *) &whandle->handle) == 0;
}
return false;
}
static bool
resource_is_busy(struct iris_context *ice,
struct iris_resource *res)
{
bool busy = iris_bo_busy(res->bo);
iris_foreach_batch(ice, batch)
busy |= iris_batch_references(batch, res->bo);
return busy;
}
void
iris_replace_buffer_storage(struct pipe_context *ctx,
struct pipe_resource *p_dst,
struct pipe_resource *p_src,
unsigned num_rebinds,
uint32_t rebind_mask,
uint32_t delete_buffer_id)
{
struct iris_screen *screen = (void *) ctx->screen;
struct iris_context *ice = (void *) ctx;
struct iris_resource *dst = (void *) p_dst;
struct iris_resource *src = (void *) p_src;
assert(memcmp(&dst->surf, &src->surf, sizeof(dst->surf)) == 0);
struct iris_bo *old_bo = dst->bo;
/* Swap out the backing storage */
iris_bo_reference(src->bo);
dst->bo = src->bo;
/* Rebind the buffer, replacing any state referring to the old BO's
* address, and marking state dirty so it's reemitted.
*/
screen->vtbl.rebind_buffer(ice, dst);
iris_bo_unreference(old_bo);
}
/**
* Discard a buffer's contents and replace it's backing storage with a
* fresh, idle buffer if necessary.
*
* Returns true if the storage can be considered idle.
*/
static bool
iris_invalidate_buffer(struct iris_context *ice, struct iris_resource *res)
{
struct iris_screen *screen = (void *) ice->ctx.screen;
if (res->base.b.target != PIPE_BUFFER)
return false;
/* If it's already invalidated, don't bother doing anything.
* We consider the storage to be idle, because either it was freshly
* allocated (and not busy), or a previous call here was what cleared
* the range, and that call replaced the storage with an idle buffer.
*/
if (res->valid_buffer_range.start > res->valid_buffer_range.end)
return true;
if (!resource_is_busy(ice, res)) {
/* The resource is idle, so just mark that it contains no data and
* keep using the same underlying buffer object.
*/
util_range_set_empty(&res->valid_buffer_range);
return true;
}
/* Otherwise, try and replace the backing storage with a new BO. */
/* We can't reallocate memory we didn't allocate in the first place. */
if (res->bo->gem_handle && res->bo->real.userptr)
return false;
/* Nor can we allocate buffers we imported or exported. */
if (iris_bo_is_external(res->bo))
return false;
struct iris_bo *old_bo = res->bo;
unsigned flags = old_bo->real.protected ? BO_ALLOC_PROTECTED : BO_ALLOC_PLAIN;
struct iris_bo *new_bo =
iris_bo_alloc(screen->bufmgr, res->bo->name, res->base.b.width0,
iris_buffer_alignment(res->base.b.width0),
iris_memzone_for_address(old_bo->address),
flags);
if (!new_bo)
return false;
/* Swap out the backing storage */
res->bo = new_bo;
/* Rebind the buffer, replacing any state referring to the old BO's
* address, and marking state dirty so it's reemitted.
*/
screen->vtbl.rebind_buffer(ice, res);
util_range_set_empty(&res->valid_buffer_range);
iris_bo_unreference(old_bo);
/* The new buffer is idle. */
return true;
}
static void
iris_invalidate_resource(struct pipe_context *ctx,
struct pipe_resource *resource)
{
struct iris_context *ice = (void *) ctx;
struct iris_resource *res = (void *) resource;
iris_invalidate_buffer(ice, res);
}
static void
iris_flush_staging_region(struct pipe_transfer *xfer,
const struct pipe_box *flush_box)
{
if (!(xfer->usage & PIPE_MAP_WRITE))
return;
struct iris_transfer *map = (void *) xfer;
struct pipe_box src_box = *flush_box;
/* Account for extra alignment padding in staging buffer */
if (xfer->resource->target == PIPE_BUFFER)
src_box.x += xfer->box.x % IRIS_MAP_BUFFER_ALIGNMENT;
struct pipe_box dst_box = (struct pipe_box) {
.x = xfer->box.x + flush_box->x,
.y = xfer->box.y + flush_box->y,
.z = xfer->box.z + flush_box->z,
.width = flush_box->width,
.height = flush_box->height,
.depth = flush_box->depth,
};
iris_copy_region(map->blorp, map->batch, xfer->resource, xfer->level,
dst_box.x, dst_box.y, dst_box.z, map->staging, 0,
&src_box);
}
static void
iris_unmap_copy_region(struct iris_transfer *map)
{
iris_resource_destroy(map->staging->screen, map->staging);
map->ptr = NULL;
}
static void
iris_map_copy_region(struct iris_transfer *map)
{
struct pipe_screen *pscreen = &map->batch->screen->base;
struct pipe_transfer *xfer = &map->base.b;
struct pipe_box *box = &xfer->box;
struct iris_resource *res = (void *) xfer->resource;
unsigned extra = xfer->resource->target == PIPE_BUFFER ?
box->x % IRIS_MAP_BUFFER_ALIGNMENT : 0;
struct pipe_resource templ = (struct pipe_resource) {
.usage = PIPE_USAGE_STAGING,
.width0 = box->width + extra,
.height0 = box->height,
.depth0 = 1,
.nr_samples = xfer->resource->nr_samples,
.nr_storage_samples = xfer->resource->nr_storage_samples,
.array_size = box->depth,
.format = res->internal_format,
};
if (xfer->resource->target == PIPE_BUFFER) {
templ.target = PIPE_BUFFER;
map->staging = iris_resource_create_for_buffer(pscreen, &templ);
} else {
templ.target = templ.array_size > 1 ? PIPE_TEXTURE_2D_ARRAY
: PIPE_TEXTURE_2D;
unsigned row_pitch_B = 0;
#if DETECT_OS_ANDROID
/* Staging buffers for stall-avoidance blits don't always have the
* same restrictions on stride as the original buffer. For example,
* the original buffer may be used for scanout, while the staging
* buffer will not be. So we may compute a smaller stride for the
* staging buffer than the original.
*
* Normally, this is good, as it saves memory. Unfortunately, for
* Android, gbm_gralloc incorrectly asserts that the stride returned
* by gbm_bo_map() must equal the result of gbm_bo_get_stride(),
* which simply isn't always the case.
*
* Because gralloc is unlikely to be fixed, we hack around it in iris
* by forcing the staging buffer to have a matching stride.
*/
if (iris_bo_is_external(res->bo))
row_pitch_B = res->surf.row_pitch_B;
#endif
map->staging =
iris_resource_create_for_image(pscreen, &templ, NULL, 0, row_pitch_B);
}
/* If we fail to create a staging resource, the caller will fallback
* to mapping directly on the CPU.
*/
if (!map->staging)
return;
if (templ.target != PIPE_BUFFER) {
struct isl_surf *surf = &((struct iris_resource *) map->staging)->surf;
xfer->stride = isl_surf_get_row_pitch_B(surf);
xfer->layer_stride = isl_surf_get_array_pitch(surf);
}
if ((xfer->usage & PIPE_MAP_READ) ||
(res->base.b.target == PIPE_BUFFER &&
!(xfer->usage & PIPE_MAP_DISCARD_RANGE))) {
iris_copy_region(map->blorp, map->batch, map->staging, 0, extra, 0, 0,
xfer->resource, xfer->level, box);
/* Ensure writes to the staging BO land before we map it below. */
iris_emit_pipe_control_flush(map->batch,
"transfer read: flush before mapping",
PIPE_CONTROL_RENDER_TARGET_FLUSH |
PIPE_CONTROL_TILE_CACHE_FLUSH |
PIPE_CONTROL_CS_STALL);
}
struct iris_bo *staging_bo = iris_resource_bo(map->staging);
if (iris_batch_references(map->batch, staging_bo))
iris_batch_flush(map->batch);
assert(((struct iris_resource *)map->staging)->offset == 0);
map->ptr =
iris_bo_map(map->dbg, staging_bo, xfer->usage & MAP_FLAGS) + extra;
map->unmap = iris_unmap_copy_region;
}
static void
get_image_offset_el(const struct isl_surf *surf, unsigned level, unsigned z,
unsigned *out_x0_el, unsigned *out_y0_el)
{
ASSERTED uint32_t z0_el, a0_el;
if (surf->dim == ISL_SURF_DIM_3D) {
isl_surf_get_image_offset_el(surf, level, 0, z,
out_x0_el, out_y0_el, &z0_el, &a0_el);
} else {
isl_surf_get_image_offset_el(surf, level, z, 0,
out_x0_el, out_y0_el, &z0_el, &a0_el);
}
assert(z0_el == 0 && a0_el == 0);
}
/* Compute extent parameters for use with tiled_memcpy functions.
* xs are in units of bytes and ys are in units of strides.
*/
static inline void
tile_extents(const struct isl_surf *surf,
const struct pipe_box *box,
unsigned level, int z,
unsigned *x1_B, unsigned *x2_B,
unsigned *y1_el, unsigned *y2_el)
{
const struct isl_format_layout *fmtl = isl_format_get_layout(surf->format);
const unsigned cpp = fmtl->bpb / 8;
assert(box->x % fmtl->bw == 0);
assert(box->y % fmtl->bh == 0);
unsigned x0_el, y0_el;
get_image_offset_el(surf, level, box->z + z, &x0_el, &y0_el);
*x1_B = (box->x / fmtl->bw + x0_el) * cpp;
*y1_el = box->y / fmtl->bh + y0_el;
*x2_B = (DIV_ROUND_UP(box->x + box->width, fmtl->bw) + x0_el) * cpp;
*y2_el = DIV_ROUND_UP(box->y + box->height, fmtl->bh) + y0_el;
}
static void
iris_unmap_tiled_memcpy(struct iris_transfer *map)
{
struct pipe_transfer *xfer = &map->base.b;
const struct pipe_box *box = &xfer->box;
struct iris_resource *res = (struct iris_resource *) xfer->resource;
struct isl_surf *surf = &res->surf;
const bool has_swizzling = false;
if (xfer->usage & PIPE_MAP_WRITE) {
char *dst = res->offset +
iris_bo_map(map->dbg, res->bo, (xfer->usage | MAP_RAW) & MAP_FLAGS);
for (int s = 0; s < box->depth; s++) {
unsigned x1, x2, y1, y2;
tile_extents(surf, box, xfer->level, s, &x1, &x2, &y1, &y2);
void *ptr = map->ptr + s * xfer->layer_stride;
isl_memcpy_linear_to_tiled(x1, x2, y1, y2, dst, ptr,
surf->row_pitch_B, xfer->stride,
has_swizzling, surf->tiling, ISL_MEMCPY);
}
}
os_free_aligned(map->buffer);
map->buffer = map->ptr = NULL;
}
static void
iris_map_tiled_memcpy(struct iris_transfer *map)
{
struct pipe_transfer *xfer = &map->base.b;
const struct pipe_box *box = &xfer->box;
struct iris_resource *res = (struct iris_resource *) xfer->resource;
struct isl_surf *surf = &res->surf;
xfer->stride = ALIGN(surf->row_pitch_B, 16);
xfer->layer_stride = xfer->stride * box->height;
unsigned x1, x2, y1, y2;
tile_extents(surf, box, xfer->level, 0, &x1, &x2, &y1, &y2);
/* The tiling and detiling functions require that the linear buffer has
* a 16-byte alignment (that is, its `x0` is 16-byte aligned). Here we
* over-allocate the linear buffer to get the proper alignment.
*/
map->buffer =
os_malloc_aligned(xfer->layer_stride * box->depth, 16);
assert(map->buffer);
map->ptr = (char *)map->buffer + (x1 & 0xf);
const bool has_swizzling = false;
if (xfer->usage & PIPE_MAP_READ) {
char *src = res->offset +
iris_bo_map(map->dbg, res->bo, (xfer->usage | MAP_RAW) & MAP_FLAGS);
for (int s = 0; s < box->depth; s++) {
unsigned x1, x2, y1, y2;
tile_extents(surf, box, xfer->level, s, &x1, &x2, &y1, &y2);
/* Use 's' rather than 'box->z' to rebase the first slice to 0. */
void *ptr = map->ptr + s * xfer->layer_stride;
isl_memcpy_tiled_to_linear(x1, x2, y1, y2, ptr, src, xfer->stride,
surf->row_pitch_B, has_swizzling,
surf->tiling,
#if defined(USE_SSE41)
util_get_cpu_caps()->has_sse4_1 ?
ISL_MEMCPY_STREAMING_LOAD :
#endif
ISL_MEMCPY);
}
}
map->unmap = iris_unmap_tiled_memcpy;
}
static void
iris_map_direct(struct iris_transfer *map)
{
struct pipe_transfer *xfer = &map->base.b;
struct pipe_box *box = &xfer->box;
struct iris_resource *res = (struct iris_resource *) xfer->resource;
void *ptr = res->offset +
iris_bo_map(map->dbg, res->bo, xfer->usage & MAP_FLAGS);
if (res->base.b.target == PIPE_BUFFER) {
xfer->stride = 0;
xfer->layer_stride = 0;
map->ptr = ptr + box->x;
} else {
struct isl_surf *surf = &res->surf;
const struct isl_format_layout *fmtl =
isl_format_get_layout(surf->format);
const unsigned cpp = fmtl->bpb / 8;
unsigned x0_el, y0_el;
assert(box->x % fmtl->bw == 0);
assert(box->y % fmtl->bh == 0);
get_image_offset_el(surf, xfer->level, box->z, &x0_el, &y0_el);
x0_el += box->x / fmtl->bw;
y0_el += box->y / fmtl->bh;
xfer->stride = isl_surf_get_row_pitch_B(surf);
xfer->layer_stride = isl_surf_get_array_pitch(surf);
map->ptr = ptr + y0_el * xfer->stride + x0_el * cpp;
}
}
static bool
can_promote_to_async(const struct iris_resource *res,
const struct pipe_box *box,
enum pipe_map_flags usage)
{
/* If we're writing to a section of the buffer that hasn't even been
* initialized with useful data, then we can safely promote this write
* to be unsynchronized. This helps the common pattern of appending data.
*/
return res->base.b.target == PIPE_BUFFER && (usage & PIPE_MAP_WRITE) &&
!(usage & TC_TRANSFER_MAP_NO_INFER_UNSYNCHRONIZED) &&
!util_ranges_intersect(&res->valid_buffer_range, box->x,
box->x + box->width);
}
static bool
prefer_cpu_access(const struct iris_resource *res,
const struct pipe_box *box,
enum pipe_map_flags usage,
unsigned level,
bool map_would_stall)
{
const enum iris_mmap_mode mmap_mode = iris_bo_mmap_mode(res->bo);
/* We must be able to map it. */
if (mmap_mode == IRIS_MMAP_NONE)
return false;
const bool write = usage & PIPE_MAP_WRITE;
const bool read = usage & PIPE_MAP_READ;
const bool preserve =
res->base.b.target == PIPE_BUFFER && !(usage & PIPE_MAP_DISCARD_RANGE);
/* We want to avoid uncached reads because they are slow. */
if (read && mmap_mode != IRIS_MMAP_WB)
return false;
/* We want to avoid stalling. We can't avoid stalling for reads, though,
* because the destination of a GPU staging copy would be busy and stall
* in the exact same manner. So don't consider it for those.
*
* For buffer maps which aren't invalidating the destination, the GPU
* staging copy path would have to read the existing buffer contents in
* order to preserve them, effectively making it a read. But a direct
* mapping would be able to just write the necessary parts without the
* overhead of the copy. It may stall, but we would anyway.
*/
if (map_would_stall && !read && !preserve)
return false;
/* Use the GPU for writes if it would compress the data. */
if (write && isl_aux_usage_has_compression(res->aux.usage))
return false;
/* Writes & Cached CPU reads are fine as long as the primary is valid. */
return !iris_has_invalid_primary(res, level, 1, box->z, box->depth);
}
static void *
iris_transfer_map(struct pipe_context *ctx,
struct pipe_resource *resource,
unsigned level,
enum pipe_map_flags usage,
const struct pipe_box *box,
struct pipe_transfer **ptransfer)
{
struct iris_context *ice = (struct iris_context *)ctx;
struct iris_resource *res = (struct iris_resource *)resource;
struct isl_surf *surf = &res->surf;
/* From GL_AMD_pinned_memory issues:
*
* 4) Is glMapBuffer on a shared buffer guaranteed to return the
* same system address which was specified at creation time?
*
* RESOLVED: NO. The GL implementation might return a different
* virtual mapping of that memory, although the same physical
* page will be used.
*
* So don't ever use staging buffers.
*/
if (res->base.is_user_ptr)
usage |= PIPE_MAP_PERSISTENT;
/* Promote discarding a range to discarding the entire buffer where
* possible. This may allow us to replace the backing storage entirely
* and let us do an unsynchronized map when we otherwise wouldn't.
*/
if (resource->target == PIPE_BUFFER &&
(usage & PIPE_MAP_DISCARD_RANGE) &&
box->x == 0 && box->width == resource->width0) {
usage |= PIPE_MAP_DISCARD_WHOLE_RESOURCE;
}
if (usage & PIPE_MAP_DISCARD_WHOLE_RESOURCE) {
/* Replace the backing storage with a fresh buffer for non-async maps */
if (!(usage & (PIPE_MAP_UNSYNCHRONIZED | TC_TRANSFER_MAP_NO_INVALIDATE))
&& iris_invalidate_buffer(ice, res))
usage |= PIPE_MAP_UNSYNCHRONIZED;
/* If we can discard the whole resource, we can discard the range. */
usage |= PIPE_MAP_DISCARD_RANGE;
}
if (!(usage & PIPE_MAP_UNSYNCHRONIZED) &&
can_promote_to_async(res, box, usage)) {
usage |= PIPE_MAP_UNSYNCHRONIZED;
}
/* We are dealing with external memory object PIPE_BUFFER, disable
* async mapping because of sync issues.
*/
if (!res->mod_info &&
res->external_format != PIPE_FORMAT_NONE &&
resource->target == PIPE_BUFFER) {
usage &= ~PIPE_MAP_UNSYNCHRONIZED;
}
/* Avoid using GPU copies for persistent/coherent buffers, as the idea
* there is to access them simultaneously on the CPU & GPU. This also
* avoids trying to use GPU copies for our u_upload_mgr buffers which
* contain state we're constructing for a GPU draw call, which would
* kill us with infinite stack recursion.
*/
if (usage & (PIPE_MAP_PERSISTENT | PIPE_MAP_COHERENT))
usage |= PIPE_MAP_DIRECTLY;
/* We cannot provide a direct mapping of tiled resources, and we
* may not be able to mmap imported BOs since they may come from
* other devices that I915_GEM_MMAP cannot work with.
*/
if ((usage & PIPE_MAP_DIRECTLY) &&
(surf->tiling != ISL_TILING_LINEAR || iris_bo_is_imported(res->bo)))
return NULL;
bool map_would_stall = false;
if (!(usage & PIPE_MAP_UNSYNCHRONIZED)) {
map_would_stall =
resource_is_busy(ice, res) ||
iris_has_invalid_primary(res, level, 1, box->z, box->depth);
if (map_would_stall && (usage & PIPE_MAP_DONTBLOCK) &&
(usage & PIPE_MAP_DIRECTLY))
return NULL;
}
struct iris_transfer *map;
if (usage & PIPE_MAP_THREAD_SAFE)
map = CALLOC_STRUCT(iris_transfer);
else if (usage & TC_TRANSFER_MAP_THREADED_UNSYNC)
map = slab_zalloc(&ice->transfer_pool_unsync);
else
map = slab_zalloc(&ice->transfer_pool);
if (!map)
return NULL;
struct pipe_transfer *xfer = &map->base.b;
map->dbg = &ice->dbg;
pipe_resource_reference(&xfer->resource, resource);
xfer->level = level;
xfer->usage = usage;
xfer->box = *box;
*ptransfer = xfer;
if (usage & PIPE_MAP_WRITE)
util_range_add(&res->base.b, &res->valid_buffer_range, box->x, box->x + box->width);
if (prefer_cpu_access(res, box, usage, level, map_would_stall))
usage |= PIPE_MAP_DIRECTLY;
/* TODO: Teach iris_map_tiled_memcpy about Tile64... */
if (isl_tiling_is_64(res->surf.tiling))
usage &= ~PIPE_MAP_DIRECTLY;
if (!(usage & PIPE_MAP_DIRECTLY)) {
/* If we need a synchronous mapping and the resource is busy, or needs
* resolving, we copy to/from a linear temporary buffer using the GPU.
*/
map->batch = &ice->batches[IRIS_BATCH_RENDER];
map->blorp = &ice->blorp;
iris_map_copy_region(map);
}
/* If we've requested a direct mapping, or iris_map_copy_region failed
* to create a staging resource, then map it directly on the CPU.
*/
if (!map->ptr) {
if (resource->target != PIPE_BUFFER) {
iris_resource_access_raw(ice, res, level, box->z, box->depth,
usage & PIPE_MAP_WRITE);
}
if (!(usage & PIPE_MAP_UNSYNCHRONIZED)) {
iris_foreach_batch(ice, batch) {
if (iris_batch_references(batch, res->bo))
iris_batch_flush(batch);
}
}
if (surf->tiling != ISL_TILING_LINEAR) {
iris_map_tiled_memcpy(map);
} else {
iris_map_direct(map);
}
}
return map->ptr;
}
static void
iris_transfer_flush_region(struct pipe_context *ctx,
struct pipe_transfer *xfer,
const struct pipe_box *box)
{
struct iris_context *ice = (struct iris_context *)ctx;
struct iris_resource *res = (struct iris_resource *) xfer->resource;
struct iris_transfer *map = (void *) xfer;
if (map->staging)
iris_flush_staging_region(xfer, box);
if (res->base.b.target == PIPE_BUFFER) {
util_range_add(&res->base.b, &res->valid_buffer_range, box->x, box->x + box->width);
}
/* Make sure we flag constants dirty even if there's no need to emit
* any PIPE_CONTROLs to a batch.
*/
iris_dirty_for_history(ice, res);
}
static void
iris_transfer_unmap(struct pipe_context *ctx, struct pipe_transfer *xfer)
{
struct iris_context *ice = (struct iris_context *)ctx;
struct iris_transfer *map = (void *) xfer;
if (!(xfer->usage & (PIPE_MAP_FLUSH_EXPLICIT |
PIPE_MAP_COHERENT))) {
struct pipe_box flush_box = {
.x = 0, .y = 0, .z = 0,
.width = xfer->box.width,
.height = xfer->box.height,
.depth = xfer->box.depth,
};
iris_transfer_flush_region(ctx, xfer, &flush_box);
}
if (map->unmap)
map->unmap(map);
pipe_resource_reference(&xfer->resource, NULL);
if (xfer->usage & PIPE_MAP_THREAD_SAFE) {
free(map);
} else {
/* transfer_unmap is called from the driver thread, so we have to use
* transfer_pool, not transfer_pool_unsync. Freeing an object into a
* different pool is allowed, however.
*/
slab_free(&ice->transfer_pool, map);
}
}
/**
* The pipe->texture_subdata() driver hook.
*
* Mesa's state tracker takes this path whenever possible, even with
* PIPE_CAP_TEXTURE_TRANSFER_MODES set.
*/
static void
iris_texture_subdata(struct pipe_context *ctx,
struct pipe_resource *resource,
unsigned level,
unsigned usage,
const struct pipe_box *box,
const void *data,
unsigned stride,
uintptr_t layer_stride)
{
struct iris_context *ice = (struct iris_context *)ctx;
struct iris_resource *res = (struct iris_resource *)resource;
const struct isl_surf *surf = &res->surf;
assert(resource->target != PIPE_BUFFER);
/* Just use the transfer-based path for linear buffers - it will already
* do a direct mapping, or a simple linear staging buffer.
*
* Linear staging buffers appear to be better than tiled ones, too, so
* take that path if we need the GPU to perform color compression, or
* stall-avoidance blits.
*
* TODO: Teach isl_memcpy_linear_to_tiled about Tile64...
*/
if (surf->tiling == ISL_TILING_LINEAR ||
isl_tiling_is_64(res->surf.tiling) ||
isl_aux_usage_has_compression(res->aux.usage) ||
resource_is_busy(ice, res) ||
iris_bo_mmap_mode(res->bo) == IRIS_MMAP_NONE) {
return u_default_texture_subdata(ctx, resource, level, usage, box,
data, stride, layer_stride);
}
/* No state trackers pass any flags other than PIPE_MAP_WRITE */
iris_resource_access_raw(ice, res, level, box->z, box->depth, true);
iris_foreach_batch(ice, batch) {
if (iris_batch_references(batch, res->bo))
iris_batch_flush(batch);
}
uint8_t *dst = iris_bo_map(&ice->dbg, res->bo, MAP_WRITE | MAP_RAW);
for (int s = 0; s < box->depth; s++) {
const uint8_t *src = data + s * layer_stride;
unsigned x1, x2, y1, y2;
tile_extents(surf, box, level, s, &x1, &x2, &y1, &y2);
isl_memcpy_linear_to_tiled(x1, x2, y1, y2,
(void *)dst, (void *)src,
surf->row_pitch_B, stride,
false, surf->tiling, ISL_MEMCPY);
}
}
/**
* Mark state dirty that needs to be re-emitted when a resource is written.
*/
void
iris_dirty_for_history(struct iris_context *ice,
struct iris_resource *res)
{
const uint64_t stages = res->bind_stages;
uint64_t dirty = 0ull;
uint64_t stage_dirty = 0ull;
if (res->bind_history & PIPE_BIND_CONSTANT_BUFFER) {
for (unsigned stage = 0; stage < MESA_SHADER_STAGES; stage++) {
if (stages & (1u << stage)) {
struct iris_shader_state *shs = &ice->state.shaders[stage];
shs->dirty_cbufs |= ~0u;
}
}
dirty |= IRIS_DIRTY_RENDER_MISC_BUFFER_FLUSHES |
IRIS_DIRTY_COMPUTE_MISC_BUFFER_FLUSHES;
stage_dirty |= (stages << IRIS_SHIFT_FOR_STAGE_DIRTY_CONSTANTS);
}
if (res->bind_history & (PIPE_BIND_SAMPLER_VIEW |
PIPE_BIND_SHADER_IMAGE)) {
dirty |= IRIS_DIRTY_RENDER_RESOLVES_AND_FLUSHES |
IRIS_DIRTY_COMPUTE_RESOLVES_AND_FLUSHES;
stage_dirty |= (stages << IRIS_SHIFT_FOR_STAGE_DIRTY_BINDINGS);
}
if (res->bind_history & PIPE_BIND_SHADER_BUFFER) {
dirty |= IRIS_DIRTY_RENDER_MISC_BUFFER_FLUSHES |
IRIS_DIRTY_COMPUTE_MISC_BUFFER_FLUSHES;
stage_dirty |= (stages << IRIS_SHIFT_FOR_STAGE_DIRTY_BINDINGS);
}
if (res->bind_history & PIPE_BIND_VERTEX_BUFFER)
dirty |= IRIS_DIRTY_VERTEX_BUFFER_FLUSHES;
if (ice->state.streamout_active && (res->bind_history & PIPE_BIND_STREAM_OUTPUT))
dirty |= IRIS_DIRTY_SO_BUFFERS;
ice->state.dirty |= dirty;
ice->state.stage_dirty |= stage_dirty;
}
bool
iris_resource_set_clear_color(struct iris_context *ice,
struct iris_resource *res,
union isl_color_value color)
{
if (res->aux.clear_color_unknown ||
memcmp(&res->aux.clear_color, &color, sizeof(color)) != 0) {
res->aux.clear_color = color;
res->aux.clear_color_unknown = false;
return true;
}
return false;
}
static enum pipe_format
iris_resource_get_internal_format(struct pipe_resource *p_res)
{
struct iris_resource *res = (void *) p_res;
return res->internal_format;
}
static const struct u_transfer_vtbl transfer_vtbl = {
.resource_create = iris_resource_create,
.resource_destroy = iris_resource_destroy,
.transfer_map = iris_transfer_map,
.transfer_unmap = iris_transfer_unmap,
.transfer_flush_region = iris_transfer_flush_region,
.get_internal_format = iris_resource_get_internal_format,
.set_stencil = iris_resource_set_separate_stencil,
.get_stencil = iris_resource_get_separate_stencil,
};
void
iris_init_screen_resource_functions(struct pipe_screen *pscreen)
{
pscreen->query_dmabuf_modifiers = iris_query_dmabuf_modifiers;
pscreen->is_dmabuf_modifier_supported = iris_is_dmabuf_modifier_supported;
pscreen->get_dmabuf_modifier_planes = iris_get_dmabuf_modifier_planes;
pscreen->resource_create_with_modifiers =
iris_resource_create_with_modifiers;
pscreen->resource_create = u_transfer_helper_resource_create;
pscreen->resource_from_user_memory = iris_resource_from_user_memory;
pscreen->resource_from_handle = iris_resource_from_handle;
pscreen->resource_from_memobj = iris_resource_from_memobj_wrapper;
pscreen->resource_get_handle = iris_resource_get_handle;
pscreen->resource_get_param = iris_resource_get_param;
pscreen->resource_destroy = u_transfer_helper_resource_destroy;
pscreen->memobj_create_from_handle = iris_memobj_create_from_handle;
pscreen->memobj_destroy = iris_memobj_destroy;
pscreen->transfer_helper =
u_transfer_helper_create(&transfer_vtbl,
U_TRANSFER_HELPER_SEPARATE_Z32S8 |
U_TRANSFER_HELPER_SEPARATE_STENCIL |
U_TRANSFER_HELPER_MSAA_MAP);
}
void
iris_init_resource_functions(struct pipe_context *ctx)
{
ctx->flush_resource = iris_flush_resource;
ctx->invalidate_resource = iris_invalidate_resource;
ctx->buffer_map = u_transfer_helper_transfer_map;
ctx->texture_map = u_transfer_helper_transfer_map;
ctx->transfer_flush_region = u_transfer_helper_transfer_flush_region;
ctx->buffer_unmap = u_transfer_helper_transfer_unmap;
ctx->texture_unmap = u_transfer_helper_transfer_unmap;
ctx->buffer_subdata = u_default_buffer_subdata;
ctx->clear_buffer = u_default_clear_buffer;
ctx->texture_subdata = iris_texture_subdata;
}
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