2 * Copyright 2006 VMware, Inc.
5 * Permission is hereby granted, free of charge, to any person obtaining a
6 * copy of this software and associated documentation files (the
7 * "Software"), to deal in the Software without restriction, including
8 * without limitation the rights to use, copy, modify, merge, publish,
9 * distribute, sublicense, and/or sell copies of the Software, and to
10 * permit persons to whom the Software is furnished to do so, subject to
11 * the following conditions:
13 * The above copyright notice and this permission notice (including the
14 * next paragraph) shall be included in all copies or substantial portions
17 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
18 * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
19 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
20 * IN NO EVENT SHALL VMWARE AND/OR ITS SUPPLIERS BE LIABLE FOR
21 * ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
22 * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
23 * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
27 #include <GL/internal/dri_interface.h>
29 #include "intel_batchbuffer.h"
30 #include "intel_mipmap_tree.h"
31 #include "intel_resolve_map.h"
32 #include "intel_tex.h"
33 #include "intel_blit.h"
34 #include "intel_fbo.h"
36 #include "brw_blorp.h"
37 #include "brw_context.h"
38 #include "brw_state.h"
40 #include "main/enums.h"
41 #include "main/fbobject.h"
42 #include "main/formats.h"
43 #include "main/glformats.h"
44 #include "main/texcompress_etc.h"
45 #include "main/teximage.h"
46 #include "main/streaming-load-memcpy.h"
47 #include "x86/common_x86_asm.h"
49 #define FILE_DEBUG_FLAG DEBUG_MIPTREE
51 static void *intel_miptree_map_raw(struct brw_context
*brw
,
52 struct intel_mipmap_tree
*mt
);
54 static void intel_miptree_unmap_raw(struct intel_mipmap_tree
*mt
);
57 intel_miptree_alloc_mcs(struct brw_context
*brw
,
58 struct intel_mipmap_tree
*mt
,
62 * Determine which MSAA layout should be used by the MSAA surface being
63 * created, based on the chip generation and the surface type.
65 static enum intel_msaa_layout
66 compute_msaa_layout(struct brw_context
*brw
, mesa_format format
,
67 bool disable_aux_buffers
)
69 /* Prior to Gen7, all MSAA surfaces used IMS layout. */
71 return INTEL_MSAA_LAYOUT_IMS
;
73 /* In Gen7, IMS layout is only used for depth and stencil buffers. */
74 switch (_mesa_get_format_base_format(format
)) {
75 case GL_DEPTH_COMPONENT
:
76 case GL_STENCIL_INDEX
:
77 case GL_DEPTH_STENCIL
:
78 return INTEL_MSAA_LAYOUT_IMS
;
80 /* From the Ivy Bridge PRM, Vol4 Part1 p77 ("MCS Enable"):
82 * This field must be set to 0 for all SINT MSRTs when all RT channels
85 * In practice this means that we have to disable MCS for all signed
86 * integer MSAA buffers. The alternative, to disable MCS only when one
87 * of the render target channels is disabled, is impractical because it
88 * would require converting between CMS and UMS MSAA layouts on the fly,
91 if (brw
->gen
== 7 && _mesa_get_format_datatype(format
) == GL_INT
) {
92 return INTEL_MSAA_LAYOUT_UMS
;
93 } else if (disable_aux_buffers
) {
94 /* We can't use the CMS layout because it uses an aux buffer, the MCS
95 * buffer. So fallback to UMS, which is identical to CMS without the
97 return INTEL_MSAA_LAYOUT_UMS
;
99 return INTEL_MSAA_LAYOUT_CMS
;
106 * For single-sampled render targets ("non-MSRT"), the MCS buffer is a
107 * scaled-down bitfield representation of the color buffer which is capable of
108 * recording when blocks of the color buffer are equal to the clear value.
109 * This function returns the block size that will be used by the MCS buffer
110 * corresponding to a certain color miptree.
112 * From the Ivy Bridge PRM, Vol2 Part1 11.7 "MCS Buffer for Render Target(s)",
113 * beneath the "Fast Color Clear" bullet (p327):
115 * The following table describes the RT alignment
129 * This alignment has the following uses:
131 * - For figuring out the size of the MCS buffer. Each 4k tile in the MCS
132 * buffer contains 128 blocks horizontally and 256 blocks vertically.
134 * - For figuring out alignment restrictions for a fast clear operation. Fast
135 * clear operations must always clear aligned multiples of 16 blocks
136 * horizontally and 32 blocks vertically.
138 * - For scaling down the coordinates sent through the render pipeline during
139 * a fast clear. X coordinates must be scaled down by 8 times the block
140 * width, and Y coordinates by 16 times the block height.
142 * - For scaling down the coordinates sent through the render pipeline during
143 * a "Render Target Resolve" operation. X coordinates must be scaled down
144 * by half the block width, and Y coordinates by half the block height.
147 intel_get_non_msrt_mcs_alignment(struct intel_mipmap_tree
*mt
,
148 unsigned *width_px
, unsigned *height
)
150 switch (mt
->tiling
) {
152 unreachable("Non-MSRT MCS requires X or Y tiling");
153 /* In release builds, fall through */
155 *width_px
= 32 / mt
->cpp
;
159 *width_px
= 64 / mt
->cpp
;
165 intel_tiling_supports_non_msrt_mcs(struct brw_context
*brw
, unsigned tiling
)
167 /* From the Ivy Bridge PRM, Vol2 Part1 11.7 "MCS Buffer for Render
168 * Target(s)", beneath the "Fast Color Clear" bullet (p326):
170 * - Support is limited to tiled render targets.
172 * Gen9 changes the restriction to Y-tile only.
175 return tiling
== I915_TILING_Y
;
176 else if (brw
->gen
>= 7)
177 return tiling
!= I915_TILING_NONE
;
183 * For a single-sampled render target ("non-MSRT"), determine if an MCS buffer
184 * can be used. This doesn't (and should not) inspect any of the properties of
187 * From the Ivy Bridge PRM, Vol2 Part1 11.7 "MCS Buffer for Render Target(s)",
188 * beneath the "Fast Color Clear" bullet (p326):
190 * - Support is for non-mip-mapped and non-array surface types only.
192 * And then later, on p327:
194 * - MCS buffer for non-MSRT is supported only for RT formats 32bpp,
197 * From the Skylake documentation, it is made clear that X-tiling is no longer
200 * - MCS and Lossless compression is supported for TiledY/TileYs/TileYf
204 intel_miptree_supports_non_msrt_fast_clear(struct brw_context
*brw
,
205 struct intel_mipmap_tree
*mt
)
207 /* MCS support does not exist prior to Gen7 */
211 if (mt
->disable_aux_buffers
)
214 /* This function applies only to non-multisampled render targets. */
215 if (mt
->num_samples
> 1)
218 /* MCS is only supported for color buffers */
219 switch (_mesa_get_format_base_format(mt
->format
)) {
220 case GL_DEPTH_COMPONENT
:
221 case GL_DEPTH_STENCIL
:
222 case GL_STENCIL_INDEX
:
226 if (mt
->cpp
!= 4 && mt
->cpp
!= 8 && mt
->cpp
!= 16)
228 if (mt
->first_level
!= 0 || mt
->last_level
!= 0) {
230 perf_debug("Multi-LOD fast clear - giving up (%dx%dx%d).\n",
231 mt
->logical_width0
, mt
->logical_height0
, mt
->last_level
);
237 /* Check for layered surfaces. */
238 if (mt
->physical_depth0
!= 1) {
239 /* Multisample surfaces with the CMS layout are not layered surfaces,
240 * yet still have physical_depth0 > 1. Assert that we don't
241 * accidentally reject a multisampled surface here. We should have
242 * rejected it earlier by explicitly checking the sample count.
244 assert(mt
->num_samples
<= 1);
247 perf_debug("Layered fast clear - giving up. (%dx%d%d)\n",
248 mt
->logical_width0
, mt
->logical_height0
,
249 mt
->physical_depth0
);
255 /* There's no point in using an MCS buffer if the surface isn't in a
258 if (!brw
->format_supported_as_render_target
[mt
->format
])
262 mesa_format linear_format
= _mesa_get_srgb_format_linear(mt
->format
);
263 const uint32_t brw_format
= brw_format_for_mesa_format(linear_format
);
264 return brw_losslessly_compressible_format(brw
, brw_format
);
271 * Determine depth format corresponding to a depth+stencil format,
272 * for separate stencil.
275 intel_depth_format_for_depthstencil_format(mesa_format format
) {
277 case MESA_FORMAT_Z24_UNORM_S8_UINT
:
278 return MESA_FORMAT_Z24_UNORM_X8_UINT
;
279 case MESA_FORMAT_Z32_FLOAT_S8X24_UINT
:
280 return MESA_FORMAT_Z_FLOAT32
;
288 * @param for_bo Indicates that the caller is
289 * intel_miptree_create_for_bo(). If true, then do not create
292 static struct intel_mipmap_tree
*
293 intel_miptree_create_layout(struct brw_context
*brw
,
302 uint32_t layout_flags
)
304 struct intel_mipmap_tree
*mt
= calloc(sizeof(*mt
), 1);
308 DBG("%s target %s format %s level %d..%d slices %d <-- %p\n", __func__
,
309 _mesa_enum_to_string(target
),
310 _mesa_get_format_name(format
),
311 first_level
, last_level
, depth0
, mt
);
313 if (target
== GL_TEXTURE_1D_ARRAY
) {
314 /* For a 1D Array texture the OpenGL API will treat the height0
315 * parameter as the number of array slices. For Intel hardware, we treat
316 * the 1D array as a 2D Array with a height of 1.
318 * So, when we first come through this path to create a 1D Array
319 * texture, height0 stores the number of slices, and depth0 is 1. In
320 * this case, we want to swap height0 and depth0.
322 * Since some miptrees will be created based on the base miptree, we may
323 * come through this path and see height0 as 1 and depth0 being the
324 * number of slices. In this case we don't need to do the swap.
326 assert(height0
== 1 || depth0
== 1);
335 mt
->first_level
= first_level
;
336 mt
->last_level
= last_level
;
337 mt
->logical_width0
= width0
;
338 mt
->logical_height0
= height0
;
339 mt
->logical_depth0
= depth0
;
340 mt
->fast_clear_state
= INTEL_FAST_CLEAR_STATE_NO_MCS
;
341 mt
->disable_aux_buffers
= (layout_flags
& MIPTREE_LAYOUT_DISABLE_AUX
) != 0;
342 exec_list_make_empty(&mt
->hiz_map
);
343 mt
->cpp
= _mesa_get_format_bytes(format
);
344 mt
->num_samples
= num_samples
;
345 mt
->compressed
= _mesa_is_format_compressed(format
);
346 mt
->msaa_layout
= INTEL_MSAA_LAYOUT_NONE
;
349 if (num_samples
> 1) {
350 /* Adjust width/height/depth for MSAA */
351 mt
->msaa_layout
= compute_msaa_layout(brw
, format
,
352 mt
->disable_aux_buffers
);
353 if (mt
->msaa_layout
== INTEL_MSAA_LAYOUT_IMS
) {
354 /* From the Ivybridge PRM, Volume 1, Part 1, page 108:
355 * "If the surface is multisampled and it is a depth or stencil
356 * surface or Multisampled Surface StorageFormat in SURFACE_STATE is
357 * MSFMT_DEPTH_STENCIL, WL and HL must be adjusted as follows before
360 * +----------------------------------------------------------------+
361 * | Num Multisamples | W_l = | H_l = |
362 * +----------------------------------------------------------------+
363 * | 2 | ceiling(W_l / 2) * 4 | H_l (no adjustment) |
364 * | 4 | ceiling(W_l / 2) * 4 | ceiling(H_l / 2) * 4 |
365 * | 8 | ceiling(W_l / 2) * 8 | ceiling(H_l / 2) * 4 |
366 * | 16 | ceiling(W_l / 2) * 8 | ceiling(H_l / 2) * 8 |
367 * +----------------------------------------------------------------+
370 * Note that MSFMT_DEPTH_STENCIL just means the IMS (interleaved)
371 * format rather than UMS/CMS (array slices). The Sandybridge PRM,
372 * Volume 1, Part 1, Page 111 has the same formula for 4x MSAA.
374 * Another more complicated explanation for these adjustments comes
375 * from the Sandybridge PRM, volume 4, part 1, page 31:
377 * "Any of the other messages (sample*, LOD, load4) used with a
378 * (4x) multisampled surface will in-effect sample a surface with
379 * double the height and width as that indicated in the surface
380 * state. Each pixel position on the original-sized surface is
381 * replaced with a 2x2 of samples with the following arrangement:
386 * Thus, when sampling from a multisampled texture, it behaves as
387 * though the layout in memory for (x,y,sample) is:
389 * (0,0,0) (0,0,2) (1,0,0) (1,0,2)
390 * (0,0,1) (0,0,3) (1,0,1) (1,0,3)
392 * (0,1,0) (0,1,2) (1,1,0) (1,1,2)
393 * (0,1,1) (0,1,3) (1,1,1) (1,1,3)
395 * However, the actual layout of multisampled data in memory is:
397 * (0,0,0) (1,0,0) (0,0,1) (1,0,1)
398 * (0,1,0) (1,1,0) (0,1,1) (1,1,1)
400 * (0,0,2) (1,0,2) (0,0,3) (1,0,3)
401 * (0,1,2) (1,1,2) (0,1,3) (1,1,3)
403 * This pattern repeats for each 2x2 pixel block.
405 * As a result, when calculating the size of our 4-sample buffer for
406 * an odd width or height, we have to align before scaling up because
407 * sample 3 is in that bottom right 2x2 block.
409 switch (num_samples
) {
411 assert(brw
->gen
>= 8);
412 width0
= ALIGN(width0
, 2) * 2;
413 height0
= ALIGN(height0
, 2);
416 width0
= ALIGN(width0
, 2) * 2;
417 height0
= ALIGN(height0
, 2) * 2;
420 width0
= ALIGN(width0
, 2) * 4;
421 height0
= ALIGN(height0
, 2) * 2;
424 width0
= ALIGN(width0
, 2) * 4;
425 height0
= ALIGN(height0
, 2) * 4;
428 /* num_samples should already have been quantized to 0, 1, 2, 4, 8
431 unreachable("not reached");
434 /* Non-interleaved */
435 depth0
*= num_samples
;
439 /* Set array_layout to ALL_SLICES_AT_EACH_LOD when array_spacing_lod0 can
440 * be used. array_spacing_lod0 is only used for non-IMS MSAA surfaces on
441 * Gen 7 and 8. On Gen 8 and 9 this layout is not available but it is still
442 * used on Gen8 to make it pick a qpitch value which doesn't include space
443 * for the mipmaps. On Gen9 this is not necessary because it will
444 * automatically pick a packed qpitch value whenever mt->first_level ==
446 * TODO: can we use it elsewhere?
447 * TODO: also disable this on Gen8 and pick the qpitch value like Gen9
450 mt
->array_layout
= ALL_LOD_IN_EACH_SLICE
;
452 switch (mt
->msaa_layout
) {
453 case INTEL_MSAA_LAYOUT_NONE
:
454 case INTEL_MSAA_LAYOUT_IMS
:
455 mt
->array_layout
= ALL_LOD_IN_EACH_SLICE
;
457 case INTEL_MSAA_LAYOUT_UMS
:
458 case INTEL_MSAA_LAYOUT_CMS
:
459 mt
->array_layout
= ALL_SLICES_AT_EACH_LOD
;
464 if (target
== GL_TEXTURE_CUBE_MAP
) {
469 mt
->physical_width0
= width0
;
470 mt
->physical_height0
= height0
;
471 mt
->physical_depth0
= depth0
;
473 if (!(layout_flags
& MIPTREE_LAYOUT_FOR_BO
) &&
474 _mesa_get_format_base_format(format
) == GL_DEPTH_STENCIL
&&
475 (brw
->must_use_separate_stencil
||
476 (brw
->has_separate_stencil
&&
477 intel_miptree_wants_hiz_buffer(brw
, mt
)))) {
478 uint32_t stencil_flags
= MIPTREE_LAYOUT_ACCELERATED_UPLOAD
;
480 stencil_flags
|= MIPTREE_LAYOUT_FORCE_ALL_SLICE_AT_LOD
|
481 MIPTREE_LAYOUT_TILING_ANY
;
484 mt
->stencil_mt
= intel_miptree_create(brw
,
495 if (!mt
->stencil_mt
) {
496 intel_miptree_release(&mt
);
500 /* Fix up the Z miptree format for how we're splitting out separate
501 * stencil. Gen7 expects there to be no stencil bits in its depth buffer.
503 mt
->format
= intel_depth_format_for_depthstencil_format(mt
->format
);
506 if (format
== mt
->format
) {
507 _mesa_problem(NULL
, "Unknown format %s in separate stencil mt\n",
508 _mesa_get_format_name(mt
->format
));
512 if (layout_flags
& MIPTREE_LAYOUT_FORCE_ALL_SLICE_AT_LOD
)
513 mt
->array_layout
= ALL_SLICES_AT_EACH_LOD
;
516 * Obey HALIGN_16 constraints for Gen8 and Gen9 buffers which are
517 * multisampled or have an AUX buffer attached to it.
519 * GEN | MSRT | AUX_CCS_* or AUX_MCS
520 * -------------------------------------------
521 * 9 | HALIGN_16 | HALIGN_16
522 * 8 | HALIGN_ANY | HALIGN_16
526 if (intel_miptree_supports_non_msrt_fast_clear(brw
, mt
)) {
527 if (brw
->gen
>= 9 || (brw
->gen
== 8 && num_samples
<= 1))
528 layout_flags
|= MIPTREE_LAYOUT_FORCE_HALIGN16
;
529 } else if (brw
->gen
>= 9 && num_samples
> 1) {
530 layout_flags
|= MIPTREE_LAYOUT_FORCE_HALIGN16
;
532 /* For now, nothing else has this requirement */
533 assert((layout_flags
& MIPTREE_LAYOUT_FORCE_HALIGN16
) == 0);
536 brw_miptree_layout(brw
, mt
, layout_flags
);
538 if (mt
->disable_aux_buffers
)
539 assert(mt
->msaa_layout
!= INTEL_MSAA_LAYOUT_CMS
);
546 * Choose an appropriate uncompressed format for a requested
547 * compressed format, if unsupported.
550 intel_lower_compressed_format(struct brw_context
*brw
, mesa_format format
)
552 /* No need to lower ETC formats on these platforms,
553 * they are supported natively.
555 if (brw
->gen
>= 8 || brw
->is_baytrail
)
559 case MESA_FORMAT_ETC1_RGB8
:
560 return MESA_FORMAT_R8G8B8X8_UNORM
;
561 case MESA_FORMAT_ETC2_RGB8
:
562 return MESA_FORMAT_R8G8B8X8_UNORM
;
563 case MESA_FORMAT_ETC2_SRGB8
:
564 case MESA_FORMAT_ETC2_SRGB8_ALPHA8_EAC
:
565 case MESA_FORMAT_ETC2_SRGB8_PUNCHTHROUGH_ALPHA1
:
566 return MESA_FORMAT_B8G8R8A8_SRGB
;
567 case MESA_FORMAT_ETC2_RGBA8_EAC
:
568 case MESA_FORMAT_ETC2_RGB8_PUNCHTHROUGH_ALPHA1
:
569 return MESA_FORMAT_R8G8B8A8_UNORM
;
570 case MESA_FORMAT_ETC2_R11_EAC
:
571 return MESA_FORMAT_R_UNORM16
;
572 case MESA_FORMAT_ETC2_SIGNED_R11_EAC
:
573 return MESA_FORMAT_R_SNORM16
;
574 case MESA_FORMAT_ETC2_RG11_EAC
:
575 return MESA_FORMAT_R16G16_UNORM
;
576 case MESA_FORMAT_ETC2_SIGNED_RG11_EAC
:
577 return MESA_FORMAT_R16G16_SNORM
;
579 /* Non ETC1 / ETC2 format */
584 /* This function computes Yf/Ys tiled bo size, alignment and pitch. */
586 intel_get_yf_ys_bo_size(struct intel_mipmap_tree
*mt
, unsigned *alignment
,
587 unsigned long *pitch
)
589 uint32_t tile_width
, tile_height
;
590 unsigned long stride
, size
, aligned_y
;
592 assert(mt
->tr_mode
!= INTEL_MIPTREE_TRMODE_NONE
);
593 intel_get_tile_dims(mt
->tiling
, mt
->tr_mode
, mt
->cpp
,
594 &tile_width
, &tile_height
);
596 aligned_y
= ALIGN(mt
->total_height
, tile_height
);
597 stride
= mt
->total_width
* mt
->cpp
;
598 stride
= ALIGN(stride
, tile_width
);
599 size
= stride
* aligned_y
;
601 if (mt
->tr_mode
== INTEL_MIPTREE_TRMODE_YF
) {
602 assert(size
% 4096 == 0);
605 assert(size
% (64 * 1024) == 0);
606 *alignment
= 64 * 1024;
612 struct intel_mipmap_tree
*
613 intel_miptree_create(struct brw_context
*brw
,
622 uint32_t layout_flags
)
624 struct intel_mipmap_tree
*mt
;
625 mesa_format tex_format
= format
;
626 mesa_format etc_format
= MESA_FORMAT_NONE
;
627 GLuint total_width
, total_height
;
628 uint32_t alloc_flags
= 0;
630 format
= intel_lower_compressed_format(brw
, format
);
632 etc_format
= (format
!= tex_format
) ? tex_format
: MESA_FORMAT_NONE
;
634 assert((layout_flags
& MIPTREE_LAYOUT_DISABLE_AUX
) == 0);
635 assert((layout_flags
& MIPTREE_LAYOUT_FOR_BO
) == 0);
636 mt
= intel_miptree_create_layout(brw
, target
, format
,
637 first_level
, last_level
, width0
,
638 height0
, depth0
, num_samples
,
641 * pitch == 0 || height == 0 indicates the null texture
643 if (!mt
|| !mt
->total_width
|| !mt
->total_height
) {
644 intel_miptree_release(&mt
);
648 total_width
= mt
->total_width
;
649 total_height
= mt
->total_height
;
651 if (format
== MESA_FORMAT_S_UINT8
) {
652 /* Align to size of W tile, 64x64. */
653 total_width
= ALIGN(total_width
, 64);
654 total_height
= ALIGN(total_height
, 64);
659 if (mt
->tiling
== (I915_TILING_Y
| I915_TILING_X
)) {
661 mt
->tiling
= I915_TILING_Y
;
664 if (layout_flags
& MIPTREE_LAYOUT_ACCELERATED_UPLOAD
)
665 alloc_flags
|= BO_ALLOC_FOR_RENDER
;
668 mt
->etc_format
= etc_format
;
670 if (mt
->tr_mode
!= INTEL_MIPTREE_TRMODE_NONE
) {
671 unsigned alignment
= 0;
673 size
= intel_get_yf_ys_bo_size(mt
, &alignment
, &pitch
);
675 mt
->bo
= drm_intel_bo_alloc_for_render(brw
->bufmgr
, "miptree",
678 mt
->bo
= drm_intel_bo_alloc_tiled(brw
->bufmgr
, "miptree",
679 total_width
, total_height
, mt
->cpp
,
686 /* If the BO is too large to fit in the aperture, we need to use the
687 * BLT engine to support it. Prior to Sandybridge, the BLT paths can't
688 * handle Y-tiling, so we need to fall back to X.
690 if (brw
->gen
< 6 && y_or_x
&& mt
->bo
->size
>= brw
->max_gtt_map_object_size
) {
691 perf_debug("%dx%d miptree larger than aperture; falling back to X-tiled\n",
692 mt
->total_width
, mt
->total_height
);
694 mt
->tiling
= I915_TILING_X
;
695 drm_intel_bo_unreference(mt
->bo
);
696 mt
->bo
= drm_intel_bo_alloc_tiled(brw
->bufmgr
, "miptree",
697 total_width
, total_height
, mt
->cpp
,
698 &mt
->tiling
, &pitch
, alloc_flags
);
705 intel_miptree_release(&mt
);
710 if (mt
->msaa_layout
== INTEL_MSAA_LAYOUT_CMS
) {
711 assert(mt
->num_samples
> 1);
712 if (!intel_miptree_alloc_mcs(brw
, mt
, num_samples
)) {
713 intel_miptree_release(&mt
);
718 /* If this miptree is capable of supporting fast color clears, set
719 * fast_clear_state appropriately to ensure that fast clears will occur.
720 * Allocation of the MCS miptree will be deferred until the first fast
721 * clear actually occurs.
723 if (intel_tiling_supports_non_msrt_mcs(brw
, mt
->tiling
) &&
724 intel_miptree_supports_non_msrt_fast_clear(brw
, mt
)) {
725 mt
->fast_clear_state
= INTEL_FAST_CLEAR_STATE_RESOLVED
;
726 assert(brw
->gen
< 8 || mt
->halign
== 16 || num_samples
<= 1);
732 struct intel_mipmap_tree
*
733 intel_miptree_create_for_bo(struct brw_context
*brw
,
741 uint32_t layout_flags
)
743 struct intel_mipmap_tree
*mt
;
744 uint32_t tiling
, swizzle
;
747 drm_intel_bo_get_tiling(bo
, &tiling
, &swizzle
);
749 /* Nothing will be able to use this miptree with the BO if the offset isn't
752 if (tiling
!= I915_TILING_NONE
)
753 assert(offset
% 4096 == 0);
755 /* miptrees can't handle negative pitch. If you need flipping of images,
756 * that's outside of the scope of the mt.
760 target
= depth
> 1 ? GL_TEXTURE_2D_ARRAY
: GL_TEXTURE_2D
;
762 /* The BO already has a tiling format and we shouldn't confuse the lower
763 * layers by making it try to find a tiling format again.
765 assert((layout_flags
& MIPTREE_LAYOUT_TILING_ANY
) == 0);
766 assert((layout_flags
& MIPTREE_LAYOUT_TILING_NONE
) == 0);
768 layout_flags
|= MIPTREE_LAYOUT_FOR_BO
;
769 mt
= intel_miptree_create_layout(brw
, target
, format
,
771 width
, height
, depth
, 0,
776 drm_intel_bo_reference(bo
);
786 * For a singlesample renderbuffer, this simply wraps the given BO with a
789 * For a multisample renderbuffer, this wraps the window system's
790 * (singlesample) BO with a singlesample miptree attached to the
791 * intel_renderbuffer, then creates a multisample miptree attached to irb->mt
792 * that will contain the actual rendering (which is lazily resolved to
793 * irb->singlesample_mt).
796 intel_update_winsys_renderbuffer_miptree(struct brw_context
*intel
,
797 struct intel_renderbuffer
*irb
,
799 uint32_t width
, uint32_t height
,
802 struct intel_mipmap_tree
*singlesample_mt
= NULL
;
803 struct intel_mipmap_tree
*multisample_mt
= NULL
;
804 struct gl_renderbuffer
*rb
= &irb
->Base
.Base
;
805 mesa_format format
= rb
->Format
;
806 int num_samples
= rb
->NumSamples
;
808 /* Only the front and back buffers, which are color buffers, are allocated
809 * through the image loader.
811 assert(_mesa_get_format_base_format(format
) == GL_RGB
||
812 _mesa_get_format_base_format(format
) == GL_RGBA
);
814 singlesample_mt
= intel_miptree_create_for_bo(intel
,
823 if (!singlesample_mt
)
826 /* If this miptree is capable of supporting fast color clears, set
827 * mcs_state appropriately to ensure that fast clears will occur.
828 * Allocation of the MCS miptree will be deferred until the first fast
829 * clear actually occurs.
831 if (intel_tiling_supports_non_msrt_mcs(intel
, singlesample_mt
->tiling
) &&
832 intel_miptree_supports_non_msrt_fast_clear(intel
, singlesample_mt
)) {
833 singlesample_mt
->fast_clear_state
= INTEL_FAST_CLEAR_STATE_RESOLVED
;
836 if (num_samples
== 0) {
837 intel_miptree_release(&irb
->mt
);
838 irb
->mt
= singlesample_mt
;
840 assert(!irb
->singlesample_mt
);
842 intel_miptree_release(&irb
->singlesample_mt
);
843 irb
->singlesample_mt
= singlesample_mt
;
846 irb
->mt
->logical_width0
!= width
||
847 irb
->mt
->logical_height0
!= height
) {
848 multisample_mt
= intel_miptree_create_for_renderbuffer(intel
,
856 irb
->need_downsample
= false;
857 intel_miptree_release(&irb
->mt
);
858 irb
->mt
= multisample_mt
;
864 intel_miptree_release(&irb
->singlesample_mt
);
865 intel_miptree_release(&irb
->mt
);
869 struct intel_mipmap_tree
*
870 intel_miptree_create_for_renderbuffer(struct brw_context
*brw
,
874 uint32_t num_samples
)
876 struct intel_mipmap_tree
*mt
;
879 GLenum target
= num_samples
> 1 ? GL_TEXTURE_2D_MULTISAMPLE
: GL_TEXTURE_2D
;
880 const uint32_t layout_flags
= MIPTREE_LAYOUT_ACCELERATED_UPLOAD
|
881 MIPTREE_LAYOUT_TILING_ANY
;
884 mt
= intel_miptree_create(brw
, target
, format
, 0, 0,
885 width
, height
, depth
, num_samples
,
890 if (intel_miptree_wants_hiz_buffer(brw
, mt
)) {
891 ok
= intel_miptree_alloc_hiz(brw
, mt
);
899 intel_miptree_release(&mt
);
904 intel_miptree_reference(struct intel_mipmap_tree
**dst
,
905 struct intel_mipmap_tree
*src
)
910 intel_miptree_release(dst
);
914 DBG("%s %p refcount now %d\n", __func__
, src
, src
->refcount
);
922 intel_miptree_release(struct intel_mipmap_tree
**mt
)
927 DBG("%s %p refcount will be %d\n", __func__
, *mt
, (*mt
)->refcount
- 1);
928 if (--(*mt
)->refcount
<= 0) {
931 DBG("%s deleting %p\n", __func__
, *mt
);
933 drm_intel_bo_unreference((*mt
)->bo
);
934 intel_miptree_release(&(*mt
)->stencil_mt
);
935 if ((*mt
)->hiz_buf
) {
936 if ((*mt
)->hiz_buf
->mt
)
937 intel_miptree_release(&(*mt
)->hiz_buf
->mt
);
939 drm_intel_bo_unreference((*mt
)->hiz_buf
->bo
);
940 free((*mt
)->hiz_buf
);
942 intel_miptree_release(&(*mt
)->mcs_mt
);
943 intel_resolve_map_clear(&(*mt
)->hiz_map
);
945 for (i
= 0; i
< MAX_TEXTURE_LEVELS
; i
++) {
946 free((*mt
)->level
[i
].slice
);
956 intel_get_image_dims(struct gl_texture_image
*image
,
957 int *width
, int *height
, int *depth
)
959 switch (image
->TexObject
->Target
) {
960 case GL_TEXTURE_1D_ARRAY
:
961 /* For a 1D Array texture the OpenGL API will treat the image height as
962 * the number of array slices. For Intel hardware, we treat the 1D array
963 * as a 2D Array with a height of 1. So, here we want to swap image
966 *width
= image
->Width
;
968 *depth
= image
->Height
;
971 *width
= image
->Width
;
972 *height
= image
->Height
;
973 *depth
= image
->Depth
;
979 * Can the image be pulled into a unified mipmap tree? This mirrors
980 * the completeness test in a lot of ways.
982 * Not sure whether I want to pass gl_texture_image here.
985 intel_miptree_match_image(struct intel_mipmap_tree
*mt
,
986 struct gl_texture_image
*image
)
988 struct intel_texture_image
*intelImage
= intel_texture_image(image
);
989 GLuint level
= intelImage
->base
.Base
.Level
;
990 int width
, height
, depth
;
992 /* glTexImage* choose the texture object based on the target passed in, and
993 * objects can't change targets over their lifetimes, so this should be
996 assert(image
->TexObject
->Target
== mt
->target
);
998 mesa_format mt_format
= mt
->format
;
999 if (mt
->format
== MESA_FORMAT_Z24_UNORM_X8_UINT
&& mt
->stencil_mt
)
1000 mt_format
= MESA_FORMAT_Z24_UNORM_S8_UINT
;
1001 if (mt
->format
== MESA_FORMAT_Z_FLOAT32
&& mt
->stencil_mt
)
1002 mt_format
= MESA_FORMAT_Z32_FLOAT_S8X24_UINT
;
1003 if (mt
->etc_format
!= MESA_FORMAT_NONE
)
1004 mt_format
= mt
->etc_format
;
1006 if (image
->TexFormat
!= mt_format
)
1009 intel_get_image_dims(image
, &width
, &height
, &depth
);
1011 if (mt
->target
== GL_TEXTURE_CUBE_MAP
)
1014 int level_depth
= mt
->level
[level
].depth
;
1015 if (mt
->num_samples
> 1) {
1016 switch (mt
->msaa_layout
) {
1017 case INTEL_MSAA_LAYOUT_NONE
:
1018 case INTEL_MSAA_LAYOUT_IMS
:
1020 case INTEL_MSAA_LAYOUT_UMS
:
1021 case INTEL_MSAA_LAYOUT_CMS
:
1022 level_depth
/= mt
->num_samples
;
1027 /* Test image dimensions against the base level image adjusted for
1028 * minification. This will also catch images not present in the
1029 * tree, changed targets, etc.
1031 if (width
!= minify(mt
->logical_width0
, level
- mt
->first_level
) ||
1032 height
!= minify(mt
->logical_height0
, level
- mt
->first_level
) ||
1033 depth
!= level_depth
) {
1037 if (image
->NumSamples
!= mt
->num_samples
)
1045 intel_miptree_set_level_info(struct intel_mipmap_tree
*mt
,
1047 GLuint x
, GLuint y
, GLuint d
)
1049 mt
->level
[level
].depth
= d
;
1050 mt
->level
[level
].level_x
= x
;
1051 mt
->level
[level
].level_y
= y
;
1053 DBG("%s level %d, depth %d, offset %d,%d\n", __func__
,
1056 assert(mt
->level
[level
].slice
== NULL
);
1058 mt
->level
[level
].slice
= calloc(d
, sizeof(*mt
->level
[0].slice
));
1059 mt
->level
[level
].slice
[0].x_offset
= mt
->level
[level
].level_x
;
1060 mt
->level
[level
].slice
[0].y_offset
= mt
->level
[level
].level_y
;
1065 intel_miptree_set_image_offset(struct intel_mipmap_tree
*mt
,
1066 GLuint level
, GLuint img
,
1069 if (img
== 0 && level
== 0)
1070 assert(x
== 0 && y
== 0);
1072 assert(img
< mt
->level
[level
].depth
);
1074 mt
->level
[level
].slice
[img
].x_offset
= mt
->level
[level
].level_x
+ x
;
1075 mt
->level
[level
].slice
[img
].y_offset
= mt
->level
[level
].level_y
+ y
;
1077 DBG("%s level %d img %d pos %d,%d\n",
1078 __func__
, level
, img
,
1079 mt
->level
[level
].slice
[img
].x_offset
,
1080 mt
->level
[level
].slice
[img
].y_offset
);
1084 intel_miptree_get_image_offset(const struct intel_mipmap_tree
*mt
,
1085 GLuint level
, GLuint slice
,
1086 GLuint
*x
, GLuint
*y
)
1088 assert(slice
< mt
->level
[level
].depth
);
1090 *x
= mt
->level
[level
].slice
[slice
].x_offset
;
1091 *y
= mt
->level
[level
].slice
[slice
].y_offset
;
1096 * This function computes the tile_w (in bytes) and tile_h (in rows) of
1097 * different tiling patterns. If the BO is untiled, tile_w is set to cpp
1098 * and tile_h is set to 1.
1101 intel_get_tile_dims(uint32_t tiling
, uint32_t tr_mode
, uint32_t cpp
,
1102 uint32_t *tile_w
, uint32_t *tile_h
)
1104 if (tr_mode
== INTEL_MIPTREE_TRMODE_NONE
) {
1114 case I915_TILING_NONE
:
1119 unreachable("not reached");
1122 uint32_t aspect_ratio
= 1;
1123 assert(_mesa_is_pow_two(cpp
));
1138 unreachable("not reached");
1141 if (cpp
== 2 || cpp
== 8)
1144 if (tr_mode
== INTEL_MIPTREE_TRMODE_YS
)
1147 *tile_w
= *tile_h
* aspect_ratio
* cpp
;
1153 * This function computes masks that may be used to select the bits of the X
1154 * and Y coordinates that indicate the offset within a tile. If the BO is
1155 * untiled, the masks are set to 0.
1158 intel_get_tile_masks(uint32_t tiling
, uint32_t tr_mode
, uint32_t cpp
,
1159 bool map_stencil_as_y_tiled
,
1160 uint32_t *mask_x
, uint32_t *mask_y
)
1162 uint32_t tile_w_bytes
, tile_h
;
1163 if (map_stencil_as_y_tiled
)
1164 tiling
= I915_TILING_Y
;
1166 intel_get_tile_dims(tiling
, tr_mode
, cpp
, &tile_w_bytes
, &tile_h
);
1168 *mask_x
= tile_w_bytes
/ cpp
- 1;
1169 *mask_y
= tile_h
- 1;
1173 * Compute the offset (in bytes) from the start of the BO to the given x
1174 * and y coordinate. For tiled BOs, caller must ensure that x and y are
1175 * multiples of the tile size.
1178 intel_miptree_get_aligned_offset(const struct intel_mipmap_tree
*mt
,
1179 uint32_t x
, uint32_t y
,
1180 bool map_stencil_as_y_tiled
)
1183 uint32_t pitch
= mt
->pitch
;
1184 uint32_t tiling
= mt
->tiling
;
1186 if (map_stencil_as_y_tiled
) {
1187 tiling
= I915_TILING_Y
;
1189 /* When mapping a W-tiled stencil buffer as Y-tiled, each 64-high W-tile
1190 * gets transformed into a 32-high Y-tile. Accordingly, the pitch of
1191 * the resulting surface is twice the pitch of the original miptree,
1192 * since each row in the Y-tiled view corresponds to two rows in the
1193 * actual W-tiled surface. So we need to correct the pitch before
1194 * computing the offsets.
1201 unreachable("not reached");
1202 case I915_TILING_NONE
:
1203 return y
* pitch
+ x
* cpp
;
1205 assert((x
% (512 / cpp
)) == 0);
1206 assert((y
% 8) == 0);
1207 return y
* pitch
+ x
/ (512 / cpp
) * 4096;
1209 assert((x
% (128 / cpp
)) == 0);
1210 assert((y
% 32) == 0);
1211 return y
* pitch
+ x
/ (128 / cpp
) * 4096;
1216 * Rendering with tiled buffers requires that the base address of the buffer
1217 * be aligned to a page boundary. For renderbuffers, and sometimes with
1218 * textures, we may want the surface to point at a texture image level that
1219 * isn't at a page boundary.
1221 * This function returns an appropriately-aligned base offset
1222 * according to the tiling restrictions, plus any required x/y offset
1226 intel_miptree_get_tile_offsets(const struct intel_mipmap_tree
*mt
,
1227 GLuint level
, GLuint slice
,
1232 uint32_t mask_x
, mask_y
;
1234 intel_get_tile_masks(mt
->tiling
, mt
->tr_mode
, mt
->cpp
, false, &mask_x
, &mask_y
);
1235 intel_miptree_get_image_offset(mt
, level
, slice
, &x
, &y
);
1237 *tile_x
= x
& mask_x
;
1238 *tile_y
= y
& mask_y
;
1240 return intel_miptree_get_aligned_offset(mt
, x
& ~mask_x
, y
& ~mask_y
, false);
1244 intel_miptree_copy_slice_sw(struct brw_context
*brw
,
1245 struct intel_mipmap_tree
*dst_mt
,
1246 struct intel_mipmap_tree
*src_mt
,
1253 ptrdiff_t src_stride
, dst_stride
;
1254 int cpp
= dst_mt
->cpp
;
1256 intel_miptree_map(brw
, src_mt
,
1260 GL_MAP_READ_BIT
| BRW_MAP_DIRECT_BIT
,
1263 intel_miptree_map(brw
, dst_mt
,
1267 GL_MAP_WRITE_BIT
| GL_MAP_INVALIDATE_RANGE_BIT
|
1271 DBG("sw blit %s mt %p %p/%"PRIdPTR
" -> %s mt %p %p/%"PRIdPTR
" (%dx%d)\n",
1272 _mesa_get_format_name(src_mt
->format
),
1273 src_mt
, src
, src_stride
,
1274 _mesa_get_format_name(dst_mt
->format
),
1275 dst_mt
, dst
, dst_stride
,
1278 int row_size
= cpp
* width
;
1279 if (src_stride
== row_size
&&
1280 dst_stride
== row_size
) {
1281 memcpy(dst
, src
, row_size
* height
);
1283 for (int i
= 0; i
< height
; i
++) {
1284 memcpy(dst
, src
, row_size
);
1290 intel_miptree_unmap(brw
, dst_mt
, level
, slice
);
1291 intel_miptree_unmap(brw
, src_mt
, level
, slice
);
1293 /* Don't forget to copy the stencil data over, too. We could have skipped
1294 * passing BRW_MAP_DIRECT_BIT, but that would have meant intel_miptree_map
1295 * shuffling the two data sources in/out of temporary storage instead of
1296 * the direct mapping we get this way.
1298 if (dst_mt
->stencil_mt
) {
1299 assert(src_mt
->stencil_mt
);
1300 intel_miptree_copy_slice_sw(brw
, dst_mt
->stencil_mt
, src_mt
->stencil_mt
,
1301 level
, slice
, width
, height
);
1306 intel_miptree_copy_slice(struct brw_context
*brw
,
1307 struct intel_mipmap_tree
*dst_mt
,
1308 struct intel_mipmap_tree
*src_mt
,
1314 mesa_format format
= src_mt
->format
;
1315 uint32_t width
= minify(src_mt
->physical_width0
, level
- src_mt
->first_level
);
1316 uint32_t height
= minify(src_mt
->physical_height0
, level
- src_mt
->first_level
);
1324 assert(depth
< src_mt
->level
[level
].depth
);
1325 assert(src_mt
->format
== dst_mt
->format
);
1327 if (dst_mt
->compressed
) {
1329 _mesa_get_format_block_size(dst_mt
->format
, &i
, &j
);
1330 height
= ALIGN_NPOT(height
, j
) / j
;
1331 width
= ALIGN_NPOT(width
, i
) / i
;
1334 /* If it's a packed depth/stencil buffer with separate stencil, the blit
1335 * below won't apply since we can't do the depth's Y tiling or the
1336 * stencil's W tiling in the blitter.
1338 if (src_mt
->stencil_mt
) {
1339 intel_miptree_copy_slice_sw(brw
,
1346 uint32_t dst_x
, dst_y
, src_x
, src_y
;
1347 intel_miptree_get_image_offset(dst_mt
, level
, slice
, &dst_x
, &dst_y
);
1348 intel_miptree_get_image_offset(src_mt
, level
, slice
, &src_x
, &src_y
);
1350 DBG("validate blit mt %s %p %d,%d/%d -> mt %s %p %d,%d/%d (%dx%d)\n",
1351 _mesa_get_format_name(src_mt
->format
),
1352 src_mt
, src_x
, src_y
, src_mt
->pitch
,
1353 _mesa_get_format_name(dst_mt
->format
),
1354 dst_mt
, dst_x
, dst_y
, dst_mt
->pitch
,
1357 if (!intel_miptree_blit(brw
,
1358 src_mt
, level
, slice
, 0, 0, false,
1359 dst_mt
, level
, slice
, 0, 0, false,
1360 width
, height
, GL_COPY
)) {
1361 perf_debug("miptree validate blit for %s failed\n",
1362 _mesa_get_format_name(format
));
1364 intel_miptree_copy_slice_sw(brw
, dst_mt
, src_mt
, level
, slice
,
1370 * Copies the image's current data to the given miptree, and associates that
1371 * miptree with the image.
1373 * If \c invalidate is true, then the actual image data does not need to be
1374 * copied, but the image still needs to be associated to the new miptree (this
1375 * is set to true if we're about to clear the image).
1378 intel_miptree_copy_teximage(struct brw_context
*brw
,
1379 struct intel_texture_image
*intelImage
,
1380 struct intel_mipmap_tree
*dst_mt
,
1383 struct intel_mipmap_tree
*src_mt
= intelImage
->mt
;
1384 struct intel_texture_object
*intel_obj
=
1385 intel_texture_object(intelImage
->base
.Base
.TexObject
);
1386 int level
= intelImage
->base
.Base
.Level
;
1387 int face
= intelImage
->base
.Base
.Face
;
1390 if (intel_obj
->base
.Target
== GL_TEXTURE_1D_ARRAY
)
1391 depth
= intelImage
->base
.Base
.Height
;
1393 depth
= intelImage
->base
.Base
.Depth
;
1396 for (int slice
= 0; slice
< depth
; slice
++) {
1397 intel_miptree_copy_slice(brw
, dst_mt
, src_mt
, level
, face
, slice
);
1401 intel_miptree_reference(&intelImage
->mt
, dst_mt
);
1402 intel_obj
->needs_validate
= true;
1406 intel_miptree_alloc_mcs(struct brw_context
*brw
,
1407 struct intel_mipmap_tree
*mt
,
1410 assert(brw
->gen
>= 7); /* MCS only used on Gen7+ */
1411 assert(mt
->mcs_mt
== NULL
);
1412 assert(!mt
->disable_aux_buffers
);
1414 /* Choose the correct format for the MCS buffer. All that really matters
1415 * is that we allocate the right buffer size, since we'll always be
1416 * accessing this miptree using MCS-specific hardware mechanisms, which
1417 * infer the correct format based on num_samples.
1420 switch (num_samples
) {
1423 /* 8 bits/pixel are required for MCS data when using 4x MSAA (2 bits for
1426 format
= MESA_FORMAT_R_UNORM8
;
1429 /* 32 bits/pixel are required for MCS data when using 8x MSAA (3 bits
1430 * for each sample, plus 8 padding bits).
1432 format
= MESA_FORMAT_R_UINT32
;
1435 /* 64 bits/pixel are required for MCS data when using 16x MSAA (4 bits
1438 format
= MESA_FORMAT_RG_UINT32
;
1441 unreachable("Unrecognized sample count in intel_miptree_alloc_mcs");
1444 /* From the Ivy Bridge PRM, Vol4 Part1 p76, "MCS Base Address":
1446 * "The MCS surface must be stored as Tile Y."
1448 const uint32_t mcs_flags
= MIPTREE_LAYOUT_ACCELERATED_UPLOAD
|
1449 MIPTREE_LAYOUT_TILING_Y
;
1450 mt
->mcs_mt
= intel_miptree_create(brw
,
1456 mt
->logical_height0
,
1458 0 /* num_samples */,
1461 /* From the Ivy Bridge PRM, Vol 2 Part 1 p326:
1463 * When MCS buffer is enabled and bound to MSRT, it is required that it
1464 * is cleared prior to any rendering.
1466 * Since we don't use the MCS buffer for any purpose other than rendering,
1467 * it makes sense to just clear it immediately upon allocation.
1469 * Note: the clear value for MCS buffers is all 1's, so we memset to 0xff.
1471 void *data
= intel_miptree_map_raw(brw
, mt
->mcs_mt
);
1472 memset(data
, 0xff, mt
->mcs_mt
->total_height
* mt
->mcs_mt
->pitch
);
1473 intel_miptree_unmap_raw(mt
->mcs_mt
);
1474 mt
->fast_clear_state
= INTEL_FAST_CLEAR_STATE_CLEAR
;
1481 intel_miptree_alloc_non_msrt_mcs(struct brw_context
*brw
,
1482 struct intel_mipmap_tree
*mt
)
1484 assert(mt
->mcs_mt
== NULL
);
1485 assert(!mt
->disable_aux_buffers
);
1487 /* The format of the MCS buffer is opaque to the driver; all that matters
1488 * is that we get its size and pitch right. We'll pretend that the format
1489 * is R32. Since an MCS tile covers 128 blocks horizontally, and a Y-tiled
1490 * R32 buffer is 32 pixels across, we'll need to scale the width down by
1491 * the block width and then a further factor of 4. Since an MCS tile
1492 * covers 256 blocks vertically, and a Y-tiled R32 buffer is 32 rows high,
1493 * we'll need to scale the height down by the block height and then a
1494 * further factor of 8.
1496 const mesa_format format
= MESA_FORMAT_R_UINT32
;
1497 unsigned block_width_px
;
1498 unsigned block_height
;
1499 intel_get_non_msrt_mcs_alignment(mt
, &block_width_px
, &block_height
);
1500 unsigned width_divisor
= block_width_px
* 4;
1501 unsigned height_divisor
= block_height
* 8;
1503 /* The Skylake MCS is twice as tall as the Broadwell MCS.
1505 * In pre-Skylake, each bit in the MCS contained the state of 2 cachelines
1506 * in the main surface. In Skylake, it's two bits. The extra bit
1507 * doubles the MCS height, not width, because in Skylake the MCS is always
1511 height_divisor
/= 2;
1513 unsigned mcs_width
=
1514 ALIGN(mt
->logical_width0
, width_divisor
) / width_divisor
;
1515 unsigned mcs_height
=
1516 ALIGN(mt
->logical_height0
, height_divisor
) / height_divisor
;
1517 assert(mt
->logical_depth0
== 1);
1518 uint32_t layout_flags
= MIPTREE_LAYOUT_ACCELERATED_UPLOAD
|
1519 MIPTREE_LAYOUT_TILING_Y
;
1520 if (brw
->gen
>= 8) {
1521 layout_flags
|= MIPTREE_LAYOUT_FORCE_HALIGN16
;
1523 mt
->mcs_mt
= intel_miptree_create(brw
,
1531 0 /* num_samples */,
1539 * Helper for intel_miptree_alloc_hiz() that sets
1540 * \c mt->level[level].has_hiz. Return true if and only if
1541 * \c has_hiz was set.
1544 intel_miptree_level_enable_hiz(struct brw_context
*brw
,
1545 struct intel_mipmap_tree
*mt
,
1548 assert(mt
->hiz_buf
);
1550 if (brw
->gen
>= 8 || brw
->is_haswell
) {
1551 uint32_t width
= minify(mt
->physical_width0
, level
);
1552 uint32_t height
= minify(mt
->physical_height0
, level
);
1554 /* Disable HiZ for LOD > 0 unless the width is 8 aligned
1555 * and the height is 4 aligned. This allows our HiZ support
1556 * to fulfill Haswell restrictions for HiZ ops. For LOD == 0,
1557 * we can grow the width & height to allow the HiZ op to
1558 * force the proper size alignments.
1560 if (level
> 0 && ((width
& 7) || (height
& 3))) {
1561 DBG("mt %p level %d: HiZ DISABLED\n", mt
, level
);
1566 DBG("mt %p level %d: HiZ enabled\n", mt
, level
);
1567 mt
->level
[level
].has_hiz
= true;
1573 * Helper for intel_miptree_alloc_hiz() that determines the required hiz
1574 * buffer dimensions and allocates a bo for the hiz buffer.
1576 static struct intel_miptree_aux_buffer
*
1577 intel_gen7_hiz_buf_create(struct brw_context
*brw
,
1578 struct intel_mipmap_tree
*mt
)
1580 unsigned z_width
= mt
->logical_width0
;
1581 unsigned z_height
= mt
->logical_height0
;
1582 const unsigned z_depth
= MAX2(mt
->logical_depth0
, 1);
1583 unsigned hz_width
, hz_height
;
1584 struct intel_miptree_aux_buffer
*buf
= calloc(sizeof(*buf
), 1);
1589 /* Gen7 PRM Volume 2, Part 1, 11.5.3 "Hierarchical Depth Buffer" documents
1590 * adjustments required for Z_Height and Z_Width based on multisampling.
1592 switch (mt
->num_samples
) {
1606 unreachable("unsupported sample count");
1609 const unsigned vertical_align
= 8; /* 'j' in the docs */
1610 const unsigned H0
= z_height
;
1611 const unsigned h0
= ALIGN(H0
, vertical_align
);
1612 const unsigned h1
= ALIGN(minify(H0
, 1), vertical_align
);
1613 const unsigned Z0
= z_depth
;
1615 /* HZ_Width (bytes) = ceiling(Z_Width / 16) * 16 */
1616 hz_width
= ALIGN(z_width
, 16);
1618 if (mt
->target
== GL_TEXTURE_3D
) {
1622 for (unsigned level
= mt
->first_level
; level
<= mt
->last_level
; ++level
) {
1623 unsigned h_i
= ALIGN(H_i
, vertical_align
);
1624 /* sum(i=0 to m; h_i * max(1, floor(Z_Depth/2**i))) */
1625 hz_height
+= h_i
* Z_i
;
1626 H_i
= minify(H_i
, 1);
1627 Z_i
= minify(Z_i
, 1);
1630 * (1/2) * sum(i=0 to m; h_i * max(1, floor(Z_Depth/2**i)))
1632 hz_height
= DIV_ROUND_UP(hz_height
, 2);
1634 const unsigned hz_qpitch
= h0
+ h1
+ (12 * vertical_align
);
1635 if (mt
->target
== GL_TEXTURE_CUBE_MAP_ARRAY
||
1636 mt
->target
== GL_TEXTURE_CUBE_MAP
) {
1637 /* HZ_Height (rows) = Ceiling ( ( Q_pitch * Z_depth * 6/2) /8 ) * 8 */
1638 hz_height
= DIV_ROUND_UP(hz_qpitch
* Z0
* 6, 2 * 8) * 8;
1640 /* HZ_Height (rows) = Ceiling ( ( Q_pitch * Z_depth/2) /8 ) * 8 */
1641 hz_height
= DIV_ROUND_UP(hz_qpitch
* Z0
, 2 * 8) * 8;
1645 unsigned long pitch
;
1646 uint32_t tiling
= I915_TILING_Y
;
1647 buf
->bo
= drm_intel_bo_alloc_tiled(brw
->bufmgr
, "hiz",
1648 hz_width
, hz_height
, 1,
1650 BO_ALLOC_FOR_RENDER
);
1654 } else if (tiling
!= I915_TILING_Y
) {
1655 drm_intel_bo_unreference(buf
->bo
);
1667 * Helper for intel_miptree_alloc_hiz() that determines the required hiz
1668 * buffer dimensions and allocates a bo for the hiz buffer.
1670 static struct intel_miptree_aux_buffer
*
1671 intel_gen8_hiz_buf_create(struct brw_context
*brw
,
1672 struct intel_mipmap_tree
*mt
)
1674 unsigned z_width
= mt
->logical_width0
;
1675 unsigned z_height
= mt
->logical_height0
;
1676 const unsigned z_depth
= MAX2(mt
->logical_depth0
, 1);
1677 unsigned hz_width
, hz_height
;
1678 struct intel_miptree_aux_buffer
*buf
= calloc(sizeof(*buf
), 1);
1683 /* Gen7 PRM Volume 2, Part 1, 11.5.3 "Hierarchical Depth Buffer" documents
1684 * adjustments required for Z_Height and Z_Width based on multisampling.
1687 switch (mt
->num_samples
) {
1701 unreachable("unsupported sample count");
1705 const unsigned vertical_align
= 8; /* 'j' in the docs */
1706 const unsigned H0
= z_height
;
1707 const unsigned h0
= ALIGN(H0
, vertical_align
);
1708 const unsigned h1
= ALIGN(minify(H0
, 1), vertical_align
);
1709 const unsigned Z0
= z_depth
;
1711 /* HZ_Width (bytes) = ceiling(Z_Width / 16) * 16 */
1712 hz_width
= ALIGN(z_width
, 16);
1716 unsigned sum_h_i
= 0;
1717 unsigned hz_height_3d_sum
= 0;
1718 for (unsigned level
= mt
->first_level
; level
<= mt
->last_level
; ++level
) {
1719 unsigned i
= level
- mt
->first_level
;
1720 unsigned h_i
= ALIGN(H_i
, vertical_align
);
1721 /* sum(i=2 to m; h_i) */
1725 /* sum(i=0 to m; h_i * max(1, floor(Z_Depth/2**i))) */
1726 hz_height_3d_sum
+= h_i
* Z_i
;
1727 H_i
= minify(H_i
, 1);
1728 Z_i
= minify(Z_i
, 1);
1730 /* HZ_QPitch = h0 + max(h1, sum(i=2 to m; h_i)) */
1731 buf
->qpitch
= h0
+ MAX2(h1
, sum_h_i
);
1733 if (mt
->target
== GL_TEXTURE_3D
) {
1734 /* (1/2) * sum(i=0 to m; h_i * max(1, floor(Z_Depth/2**i))) */
1735 hz_height
= DIV_ROUND_UP(hz_height_3d_sum
, 2);
1737 /* HZ_Height (rows) = ceiling( (HZ_QPitch/2)/8) *8 * Z_Depth */
1738 hz_height
= DIV_ROUND_UP(buf
->qpitch
, 2 * 8) * 8 * Z0
;
1739 if (mt
->target
== GL_TEXTURE_CUBE_MAP_ARRAY
||
1740 mt
->target
== GL_TEXTURE_CUBE_MAP
) {
1741 /* HZ_Height (rows) = ceiling( (HZ_QPitch/2)/8) *8 * 6 * Z_Depth
1743 * We can can just take our hz_height calculation from above, and
1744 * multiply by 6 for the cube map and cube map array types.
1750 unsigned long pitch
;
1751 uint32_t tiling
= I915_TILING_Y
;
1752 buf
->bo
= drm_intel_bo_alloc_tiled(brw
->bufmgr
, "hiz",
1753 hz_width
, hz_height
, 1,
1755 BO_ALLOC_FOR_RENDER
);
1759 } else if (tiling
!= I915_TILING_Y
) {
1760 drm_intel_bo_unreference(buf
->bo
);
1771 static struct intel_miptree_aux_buffer
*
1772 intel_hiz_miptree_buf_create(struct brw_context
*brw
,
1773 struct intel_mipmap_tree
*mt
)
1775 struct intel_miptree_aux_buffer
*buf
= calloc(sizeof(*buf
), 1);
1776 uint32_t layout_flags
= MIPTREE_LAYOUT_ACCELERATED_UPLOAD
;
1779 layout_flags
|= MIPTREE_LAYOUT_FORCE_ALL_SLICE_AT_LOD
;
1784 layout_flags
|= MIPTREE_LAYOUT_TILING_ANY
;
1785 buf
->mt
= intel_miptree_create(brw
,
1791 mt
->logical_height0
,
1800 buf
->bo
= buf
->mt
->bo
;
1801 buf
->pitch
= buf
->mt
->pitch
;
1802 buf
->qpitch
= buf
->mt
->qpitch
;
1808 intel_miptree_wants_hiz_buffer(struct brw_context
*brw
,
1809 struct intel_mipmap_tree
*mt
)
1814 if (mt
->hiz_buf
!= NULL
)
1817 if (mt
->disable_aux_buffers
)
1820 switch (mt
->format
) {
1821 case MESA_FORMAT_Z_FLOAT32
:
1822 case MESA_FORMAT_Z32_FLOAT_S8X24_UINT
:
1823 case MESA_FORMAT_Z24_UNORM_X8_UINT
:
1824 case MESA_FORMAT_Z24_UNORM_S8_UINT
:
1825 case MESA_FORMAT_Z_UNORM16
:
1833 intel_miptree_alloc_hiz(struct brw_context
*brw
,
1834 struct intel_mipmap_tree
*mt
)
1836 assert(mt
->hiz_buf
== NULL
);
1837 assert(!mt
->disable_aux_buffers
);
1839 if (brw
->gen
== 7) {
1840 mt
->hiz_buf
= intel_gen7_hiz_buf_create(brw
, mt
);
1841 } else if (brw
->gen
>= 8) {
1842 mt
->hiz_buf
= intel_gen8_hiz_buf_create(brw
, mt
);
1844 mt
->hiz_buf
= intel_hiz_miptree_buf_create(brw
, mt
);
1850 /* Mark that all slices need a HiZ resolve. */
1851 for (unsigned level
= mt
->first_level
; level
<= mt
->last_level
; ++level
) {
1852 if (!intel_miptree_level_enable_hiz(brw
, mt
, level
))
1855 for (unsigned layer
= 0; layer
< mt
->level
[level
].depth
; ++layer
) {
1856 struct intel_resolve_map
*m
= malloc(sizeof(struct intel_resolve_map
));
1857 exec_node_init(&m
->link
);
1860 m
->need
= GEN6_HIZ_OP_HIZ_RESOLVE
;
1862 exec_list_push_tail(&mt
->hiz_map
, &m
->link
);
1870 * Does the miptree slice have hiz enabled?
1873 intel_miptree_level_has_hiz(struct intel_mipmap_tree
*mt
, uint32_t level
)
1875 intel_miptree_check_level_layer(mt
, level
, 0);
1876 return mt
->level
[level
].has_hiz
;
1880 intel_miptree_slice_set_needs_hiz_resolve(struct intel_mipmap_tree
*mt
,
1884 if (!intel_miptree_level_has_hiz(mt
, level
))
1887 intel_resolve_map_set(&mt
->hiz_map
,
1888 level
, layer
, GEN6_HIZ_OP_HIZ_RESOLVE
);
1893 intel_miptree_slice_set_needs_depth_resolve(struct intel_mipmap_tree
*mt
,
1897 if (!intel_miptree_level_has_hiz(mt
, level
))
1900 intel_resolve_map_set(&mt
->hiz_map
,
1901 level
, layer
, GEN6_HIZ_OP_DEPTH_RESOLVE
);
1905 intel_miptree_set_all_slices_need_depth_resolve(struct intel_mipmap_tree
*mt
,
1909 uint32_t end_layer
= mt
->level
[level
].depth
;
1911 for (layer
= 0; layer
< end_layer
; layer
++) {
1912 intel_miptree_slice_set_needs_depth_resolve(mt
, level
, layer
);
1917 intel_miptree_slice_resolve(struct brw_context
*brw
,
1918 struct intel_mipmap_tree
*mt
,
1921 enum gen6_hiz_op need
)
1923 intel_miptree_check_level_layer(mt
, level
, layer
);
1925 struct intel_resolve_map
*item
=
1926 intel_resolve_map_get(&mt
->hiz_map
, level
, layer
);
1928 if (!item
|| item
->need
!= need
)
1931 intel_hiz_exec(brw
, mt
, level
, layer
, need
);
1932 intel_resolve_map_remove(item
);
1937 intel_miptree_slice_resolve_hiz(struct brw_context
*brw
,
1938 struct intel_mipmap_tree
*mt
,
1942 return intel_miptree_slice_resolve(brw
, mt
, level
, layer
,
1943 GEN6_HIZ_OP_HIZ_RESOLVE
);
1947 intel_miptree_slice_resolve_depth(struct brw_context
*brw
,
1948 struct intel_mipmap_tree
*mt
,
1952 return intel_miptree_slice_resolve(brw
, mt
, level
, layer
,
1953 GEN6_HIZ_OP_DEPTH_RESOLVE
);
1957 intel_miptree_all_slices_resolve(struct brw_context
*brw
,
1958 struct intel_mipmap_tree
*mt
,
1959 enum gen6_hiz_op need
)
1961 bool did_resolve
= false;
1963 foreach_list_typed_safe(struct intel_resolve_map
, map
, link
, &mt
->hiz_map
) {
1964 if (map
->need
!= need
)
1967 intel_hiz_exec(brw
, mt
, map
->level
, map
->layer
, need
);
1968 intel_resolve_map_remove(map
);
1976 intel_miptree_all_slices_resolve_hiz(struct brw_context
*brw
,
1977 struct intel_mipmap_tree
*mt
)
1979 return intel_miptree_all_slices_resolve(brw
, mt
,
1980 GEN6_HIZ_OP_HIZ_RESOLVE
);
1984 intel_miptree_all_slices_resolve_depth(struct brw_context
*brw
,
1985 struct intel_mipmap_tree
*mt
)
1987 return intel_miptree_all_slices_resolve(brw
, mt
,
1988 GEN6_HIZ_OP_DEPTH_RESOLVE
);
1993 intel_miptree_resolve_color(struct brw_context
*brw
,
1994 struct intel_mipmap_tree
*mt
)
1996 switch (mt
->fast_clear_state
) {
1997 case INTEL_FAST_CLEAR_STATE_NO_MCS
:
1998 case INTEL_FAST_CLEAR_STATE_RESOLVED
:
1999 /* No resolve needed */
2001 case INTEL_FAST_CLEAR_STATE_UNRESOLVED
:
2002 case INTEL_FAST_CLEAR_STATE_CLEAR
:
2003 /* Fast color clear resolves only make sense for non-MSAA buffers. */
2004 if (mt
->msaa_layout
== INTEL_MSAA_LAYOUT_NONE
)
2005 brw_meta_resolve_color(brw
, mt
);
2012 * Make it possible to share the BO backing the given miptree with another
2013 * process or another miptree.
2015 * Fast color clears are unsafe with shared buffers, so we need to resolve and
2016 * then discard the MCS buffer, if present. We also set the fast_clear_state
2017 * to INTEL_FAST_CLEAR_STATE_NO_MCS to ensure that no MCS buffer gets
2018 * allocated in the future.
2021 intel_miptree_make_shareable(struct brw_context
*brw
,
2022 struct intel_mipmap_tree
*mt
)
2024 /* MCS buffers are also used for multisample buffers, but we can't resolve
2025 * away a multisample MCS buffer because it's an integral part of how the
2026 * pixel data is stored. Fortunately this code path should never be
2027 * reached for multisample buffers.
2029 assert(mt
->msaa_layout
== INTEL_MSAA_LAYOUT_NONE
);
2032 intel_miptree_resolve_color(brw
, mt
);
2033 intel_miptree_release(&mt
->mcs_mt
);
2034 mt
->fast_clear_state
= INTEL_FAST_CLEAR_STATE_NO_MCS
;
2040 * \brief Get pointer offset into stencil buffer.
2042 * The stencil buffer is W tiled. Since the GTT is incapable of W fencing, we
2043 * must decode the tile's layout in software.
2046 * - PRM, 2011 Sandy Bridge, Volume 1, Part 2, Section 4.5.2.1 W-Major Tile
2048 * - PRM, 2011 Sandy Bridge, Volume 1, Part 2, Section 4.5.3 Tiling Algorithm
2050 * Even though the returned offset is always positive, the return type is
2052 * commit e8b1c6d6f55f5be3bef25084fdd8b6127517e137
2053 * mesa: Fix return type of _mesa_get_format_bytes() (#37351)
2056 intel_offset_S8(uint32_t stride
, uint32_t x
, uint32_t y
, bool swizzled
)
2058 uint32_t tile_size
= 4096;
2059 uint32_t tile_width
= 64;
2060 uint32_t tile_height
= 64;
2061 uint32_t row_size
= 64 * stride
;
2063 uint32_t tile_x
= x
/ tile_width
;
2064 uint32_t tile_y
= y
/ tile_height
;
2066 /* The byte's address relative to the tile's base addres. */
2067 uint32_t byte_x
= x
% tile_width
;
2068 uint32_t byte_y
= y
% tile_height
;
2070 uintptr_t u
= tile_y
* row_size
2071 + tile_x
* tile_size
2072 + 512 * (byte_x
/ 8)
2074 + 32 * ((byte_y
/ 4) % 2)
2075 + 16 * ((byte_x
/ 4) % 2)
2076 + 8 * ((byte_y
/ 2) % 2)
2077 + 4 * ((byte_x
/ 2) % 2)
2082 /* adjust for bit6 swizzling */
2083 if (((byte_x
/ 8) % 2) == 1) {
2084 if (((byte_y
/ 8) % 2) == 0) {
2096 intel_miptree_updownsample(struct brw_context
*brw
,
2097 struct intel_mipmap_tree
*src
,
2098 struct intel_mipmap_tree
*dst
)
2101 brw_blorp_blit_miptrees(brw
,
2102 src
, 0 /* level */, 0 /* layer */, src
->format
,
2103 dst
, 0 /* level */, 0 /* layer */, dst
->format
,
2105 src
->logical_width0
, src
->logical_height0
,
2107 dst
->logical_width0
, dst
->logical_height0
,
2108 GL_NEAREST
, false, false /*mirror x, y*/);
2109 } else if (src
->format
== MESA_FORMAT_S_UINT8
) {
2110 brw_meta_stencil_updownsample(brw
, src
, dst
);
2112 brw_meta_updownsample(brw
, src
, dst
);
2115 if (src
->stencil_mt
) {
2116 if (brw
->gen
>= 8) {
2117 brw_meta_stencil_updownsample(brw
, src
->stencil_mt
, dst
);
2121 brw_blorp_blit_miptrees(brw
,
2122 src
->stencil_mt
, 0 /* level */, 0 /* layer */,
2123 src
->stencil_mt
->format
,
2124 dst
->stencil_mt
, 0 /* level */, 0 /* layer */,
2125 dst
->stencil_mt
->format
,
2127 src
->logical_width0
, src
->logical_height0
,
2129 dst
->logical_width0
, dst
->logical_height0
,
2130 GL_NEAREST
, false, false /*mirror x, y*/);
2135 intel_miptree_map_raw(struct brw_context
*brw
, struct intel_mipmap_tree
*mt
)
2137 /* CPU accesses to color buffers don't understand fast color clears, so
2138 * resolve any pending fast color clears before we map.
2140 intel_miptree_resolve_color(brw
, mt
);
2142 drm_intel_bo
*bo
= mt
->bo
;
2144 if (drm_intel_bo_references(brw
->batch
.bo
, bo
))
2145 intel_batchbuffer_flush(brw
);
2147 if (mt
->tiling
!= I915_TILING_NONE
)
2148 brw_bo_map_gtt(brw
, bo
, "miptree");
2150 brw_bo_map(brw
, bo
, true, "miptree");
2156 intel_miptree_unmap_raw(struct intel_mipmap_tree
*mt
)
2158 drm_intel_bo_unmap(mt
->bo
);
2162 intel_miptree_map_gtt(struct brw_context
*brw
,
2163 struct intel_mipmap_tree
*mt
,
2164 struct intel_miptree_map
*map
,
2165 unsigned int level
, unsigned int slice
)
2167 unsigned int bw
, bh
;
2169 unsigned int image_x
, image_y
;
2170 intptr_t x
= map
->x
;
2171 intptr_t y
= map
->y
;
2173 /* For compressed formats, the stride is the number of bytes per
2174 * row of blocks. intel_miptree_get_image_offset() already does
2177 _mesa_get_format_block_size(mt
->format
, &bw
, &bh
);
2178 assert(y
% bh
== 0);
2179 assert(x
% bw
== 0);
2183 base
= intel_miptree_map_raw(brw
, mt
) + mt
->offset
;
2188 /* Note that in the case of cube maps, the caller must have passed the
2189 * slice number referencing the face.
2191 intel_miptree_get_image_offset(mt
, level
, slice
, &image_x
, &image_y
);
2195 map
->stride
= mt
->pitch
;
2196 map
->ptr
= base
+ y
* map
->stride
+ x
* mt
->cpp
;
2199 DBG("%s: %d,%d %dx%d from mt %p (%s) "
2200 "%"PRIiPTR
",%"PRIiPTR
" = %p/%d\n", __func__
,
2201 map
->x
, map
->y
, map
->w
, map
->h
,
2202 mt
, _mesa_get_format_name(mt
->format
),
2203 x
, y
, map
->ptr
, map
->stride
);
2207 intel_miptree_unmap_gtt(struct intel_mipmap_tree
*mt
)
2209 intel_miptree_unmap_raw(mt
);
2213 intel_miptree_map_blit(struct brw_context
*brw
,
2214 struct intel_mipmap_tree
*mt
,
2215 struct intel_miptree_map
*map
,
2216 unsigned int level
, unsigned int slice
)
2218 map
->linear_mt
= intel_miptree_create(brw
, GL_TEXTURE_2D
, mt
->format
,
2219 /* first_level */ 0,
2223 MIPTREE_LAYOUT_TILING_NONE
);
2225 if (!map
->linear_mt
) {
2226 fprintf(stderr
, "Failed to allocate blit temporary\n");
2229 map
->stride
= map
->linear_mt
->pitch
;
2231 /* One of either READ_BIT or WRITE_BIT or both is set. READ_BIT implies no
2232 * INVALIDATE_RANGE_BIT. WRITE_BIT needs the original values read in unless
2233 * invalidate is set, since we'll be writing the whole rectangle from our
2234 * temporary buffer back out.
2236 if (!(map
->mode
& GL_MAP_INVALIDATE_RANGE_BIT
)) {
2237 if (!intel_miptree_blit(brw
,
2239 map
->x
, map
->y
, false,
2240 map
->linear_mt
, 0, 0,
2242 map
->w
, map
->h
, GL_COPY
)) {
2243 fprintf(stderr
, "Failed to blit\n");
2248 map
->ptr
= intel_miptree_map_raw(brw
, map
->linear_mt
);
2250 DBG("%s: %d,%d %dx%d from mt %p (%s) %d,%d = %p/%d\n", __func__
,
2251 map
->x
, map
->y
, map
->w
, map
->h
,
2252 mt
, _mesa_get_format_name(mt
->format
),
2253 level
, slice
, map
->ptr
, map
->stride
);
2258 intel_miptree_release(&map
->linear_mt
);
2264 intel_miptree_unmap_blit(struct brw_context
*brw
,
2265 struct intel_mipmap_tree
*mt
,
2266 struct intel_miptree_map
*map
,
2270 struct gl_context
*ctx
= &brw
->ctx
;
2272 intel_miptree_unmap_raw(map
->linear_mt
);
2274 if (map
->mode
& GL_MAP_WRITE_BIT
) {
2275 bool ok
= intel_miptree_blit(brw
,
2276 map
->linear_mt
, 0, 0,
2279 map
->x
, map
->y
, false,
2280 map
->w
, map
->h
, GL_COPY
);
2281 WARN_ONCE(!ok
, "Failed to blit from linear temporary mapping");
2284 intel_miptree_release(&map
->linear_mt
);
2288 * "Map" a buffer by copying it to an untiled temporary using MOVNTDQA.
2290 #if defined(USE_SSE41)
2292 intel_miptree_map_movntdqa(struct brw_context
*brw
,
2293 struct intel_mipmap_tree
*mt
,
2294 struct intel_miptree_map
*map
,
2295 unsigned int level
, unsigned int slice
)
2297 assert(map
->mode
& GL_MAP_READ_BIT
);
2298 assert(!(map
->mode
& GL_MAP_WRITE_BIT
));
2300 DBG("%s: %d,%d %dx%d from mt %p (%s) %d,%d = %p/%d\n", __func__
,
2301 map
->x
, map
->y
, map
->w
, map
->h
,
2302 mt
, _mesa_get_format_name(mt
->format
),
2303 level
, slice
, map
->ptr
, map
->stride
);
2305 /* Map the original image */
2308 intel_miptree_get_image_offset(mt
, level
, slice
, &image_x
, &image_y
);
2312 void *src
= intel_miptree_map_raw(brw
, mt
);
2315 src
+= image_y
* mt
->pitch
;
2316 src
+= image_x
* mt
->cpp
;
2318 /* Due to the pixel offsets for the particular image being mapped, our
2319 * src pointer may not be 16-byte aligned. However, if the pitch is
2320 * divisible by 16, then the amount by which it's misaligned will remain
2321 * consistent from row to row.
2323 assert((mt
->pitch
% 16) == 0);
2324 const int misalignment
= ((uintptr_t) src
) & 15;
2326 /* Create an untiled temporary buffer for the mapping. */
2327 const unsigned width_bytes
= _mesa_format_row_stride(mt
->format
, map
->w
);
2329 map
->stride
= ALIGN(misalignment
+ width_bytes
, 16);
2331 map
->buffer
= _mesa_align_malloc(map
->stride
* map
->h
, 16);
2332 /* Offset the destination so it has the same misalignment as src. */
2333 map
->ptr
= map
->buffer
+ misalignment
;
2335 assert((((uintptr_t) map
->ptr
) & 15) == misalignment
);
2337 for (uint32_t y
= 0; y
< map
->h
; y
++) {
2338 void *dst_ptr
= map
->ptr
+ y
* map
->stride
;
2339 void *src_ptr
= src
+ y
* mt
->pitch
;
2341 _mesa_streaming_load_memcpy(dst_ptr
, src_ptr
, width_bytes
);
2344 intel_miptree_unmap_raw(mt
);
2348 intel_miptree_unmap_movntdqa(struct brw_context
*brw
,
2349 struct intel_mipmap_tree
*mt
,
2350 struct intel_miptree_map
*map
,
2354 _mesa_align_free(map
->buffer
);
2361 intel_miptree_map_s8(struct brw_context
*brw
,
2362 struct intel_mipmap_tree
*mt
,
2363 struct intel_miptree_map
*map
,
2364 unsigned int level
, unsigned int slice
)
2366 map
->stride
= map
->w
;
2367 map
->buffer
= map
->ptr
= malloc(map
->stride
* map
->h
);
2371 /* One of either READ_BIT or WRITE_BIT or both is set. READ_BIT implies no
2372 * INVALIDATE_RANGE_BIT. WRITE_BIT needs the original values read in unless
2373 * invalidate is set, since we'll be writing the whole rectangle from our
2374 * temporary buffer back out.
2376 if (!(map
->mode
& GL_MAP_INVALIDATE_RANGE_BIT
)) {
2377 uint8_t *untiled_s8_map
= map
->ptr
;
2378 uint8_t *tiled_s8_map
= intel_miptree_map_raw(brw
, mt
);
2379 unsigned int image_x
, image_y
;
2381 intel_miptree_get_image_offset(mt
, level
, slice
, &image_x
, &image_y
);
2383 for (uint32_t y
= 0; y
< map
->h
; y
++) {
2384 for (uint32_t x
= 0; x
< map
->w
; x
++) {
2385 ptrdiff_t offset
= intel_offset_S8(mt
->pitch
,
2386 x
+ image_x
+ map
->x
,
2387 y
+ image_y
+ map
->y
,
2388 brw
->has_swizzling
);
2389 untiled_s8_map
[y
* map
->w
+ x
] = tiled_s8_map
[offset
];
2393 intel_miptree_unmap_raw(mt
);
2395 DBG("%s: %d,%d %dx%d from mt %p %d,%d = %p/%d\n", __func__
,
2396 map
->x
, map
->y
, map
->w
, map
->h
,
2397 mt
, map
->x
+ image_x
, map
->y
+ image_y
, map
->ptr
, map
->stride
);
2399 DBG("%s: %d,%d %dx%d from mt %p = %p/%d\n", __func__
,
2400 map
->x
, map
->y
, map
->w
, map
->h
,
2401 mt
, map
->ptr
, map
->stride
);
2406 intel_miptree_unmap_s8(struct brw_context
*brw
,
2407 struct intel_mipmap_tree
*mt
,
2408 struct intel_miptree_map
*map
,
2412 if (map
->mode
& GL_MAP_WRITE_BIT
) {
2413 unsigned int image_x
, image_y
;
2414 uint8_t *untiled_s8_map
= map
->ptr
;
2415 uint8_t *tiled_s8_map
= intel_miptree_map_raw(brw
, mt
);
2417 intel_miptree_get_image_offset(mt
, level
, slice
, &image_x
, &image_y
);
2419 for (uint32_t y
= 0; y
< map
->h
; y
++) {
2420 for (uint32_t x
= 0; x
< map
->w
; x
++) {
2421 ptrdiff_t offset
= intel_offset_S8(mt
->pitch
,
2424 brw
->has_swizzling
);
2425 tiled_s8_map
[offset
] = untiled_s8_map
[y
* map
->w
+ x
];
2429 intel_miptree_unmap_raw(mt
);
2436 intel_miptree_map_etc(struct brw_context
*brw
,
2437 struct intel_mipmap_tree
*mt
,
2438 struct intel_miptree_map
*map
,
2442 assert(mt
->etc_format
!= MESA_FORMAT_NONE
);
2443 if (mt
->etc_format
== MESA_FORMAT_ETC1_RGB8
) {
2444 assert(mt
->format
== MESA_FORMAT_R8G8B8X8_UNORM
);
2447 assert(map
->mode
& GL_MAP_WRITE_BIT
);
2448 assert(map
->mode
& GL_MAP_INVALIDATE_RANGE_BIT
);
2450 map
->stride
= _mesa_format_row_stride(mt
->etc_format
, map
->w
);
2451 map
->buffer
= malloc(_mesa_format_image_size(mt
->etc_format
,
2452 map
->w
, map
->h
, 1));
2453 map
->ptr
= map
->buffer
;
2457 intel_miptree_unmap_etc(struct brw_context
*brw
,
2458 struct intel_mipmap_tree
*mt
,
2459 struct intel_miptree_map
*map
,
2465 intel_miptree_get_image_offset(mt
, level
, slice
, &image_x
, &image_y
);
2470 uint8_t *dst
= intel_miptree_map_raw(brw
, mt
)
2471 + image_y
* mt
->pitch
2472 + image_x
* mt
->cpp
;
2474 if (mt
->etc_format
== MESA_FORMAT_ETC1_RGB8
)
2475 _mesa_etc1_unpack_rgba8888(dst
, mt
->pitch
,
2476 map
->ptr
, map
->stride
,
2479 _mesa_unpack_etc2_format(dst
, mt
->pitch
,
2480 map
->ptr
, map
->stride
,
2481 map
->w
, map
->h
, mt
->etc_format
);
2483 intel_miptree_unmap_raw(mt
);
2488 * Mapping function for packed depth/stencil miptrees backed by real separate
2489 * miptrees for depth and stencil.
2491 * On gen7, and to support HiZ pre-gen7, we have to have the stencil buffer
2492 * separate from the depth buffer. Yet at the GL API level, we have to expose
2493 * packed depth/stencil textures and FBO attachments, and Mesa core expects to
2494 * be able to map that memory for texture storage and glReadPixels-type
2495 * operations. We give Mesa core that access by mallocing a temporary and
2496 * copying the data between the actual backing store and the temporary.
2499 intel_miptree_map_depthstencil(struct brw_context
*brw
,
2500 struct intel_mipmap_tree
*mt
,
2501 struct intel_miptree_map
*map
,
2502 unsigned int level
, unsigned int slice
)
2504 struct intel_mipmap_tree
*z_mt
= mt
;
2505 struct intel_mipmap_tree
*s_mt
= mt
->stencil_mt
;
2506 bool map_z32f_x24s8
= mt
->format
== MESA_FORMAT_Z_FLOAT32
;
2507 int packed_bpp
= map_z32f_x24s8
? 8 : 4;
2509 map
->stride
= map
->w
* packed_bpp
;
2510 map
->buffer
= map
->ptr
= malloc(map
->stride
* map
->h
);
2514 /* One of either READ_BIT or WRITE_BIT or both is set. READ_BIT implies no
2515 * INVALIDATE_RANGE_BIT. WRITE_BIT needs the original values read in unless
2516 * invalidate is set, since we'll be writing the whole rectangle from our
2517 * temporary buffer back out.
2519 if (!(map
->mode
& GL_MAP_INVALIDATE_RANGE_BIT
)) {
2520 uint32_t *packed_map
= map
->ptr
;
2521 uint8_t *s_map
= intel_miptree_map_raw(brw
, s_mt
);
2522 uint32_t *z_map
= intel_miptree_map_raw(brw
, z_mt
);
2523 unsigned int s_image_x
, s_image_y
;
2524 unsigned int z_image_x
, z_image_y
;
2526 intel_miptree_get_image_offset(s_mt
, level
, slice
,
2527 &s_image_x
, &s_image_y
);
2528 intel_miptree_get_image_offset(z_mt
, level
, slice
,
2529 &z_image_x
, &z_image_y
);
2531 for (uint32_t y
= 0; y
< map
->h
; y
++) {
2532 for (uint32_t x
= 0; x
< map
->w
; x
++) {
2533 int map_x
= map
->x
+ x
, map_y
= map
->y
+ y
;
2534 ptrdiff_t s_offset
= intel_offset_S8(s_mt
->pitch
,
2537 brw
->has_swizzling
);
2538 ptrdiff_t z_offset
= ((map_y
+ z_image_y
) *
2540 (map_x
+ z_image_x
));
2541 uint8_t s
= s_map
[s_offset
];
2542 uint32_t z
= z_map
[z_offset
];
2544 if (map_z32f_x24s8
) {
2545 packed_map
[(y
* map
->w
+ x
) * 2 + 0] = z
;
2546 packed_map
[(y
* map
->w
+ x
) * 2 + 1] = s
;
2548 packed_map
[y
* map
->w
+ x
] = (s
<< 24) | (z
& 0x00ffffff);
2553 intel_miptree_unmap_raw(s_mt
);
2554 intel_miptree_unmap_raw(z_mt
);
2556 DBG("%s: %d,%d %dx%d from z mt %p %d,%d, s mt %p %d,%d = %p/%d\n",
2558 map
->x
, map
->y
, map
->w
, map
->h
,
2559 z_mt
, map
->x
+ z_image_x
, map
->y
+ z_image_y
,
2560 s_mt
, map
->x
+ s_image_x
, map
->y
+ s_image_y
,
2561 map
->ptr
, map
->stride
);
2563 DBG("%s: %d,%d %dx%d from mt %p = %p/%d\n", __func__
,
2564 map
->x
, map
->y
, map
->w
, map
->h
,
2565 mt
, map
->ptr
, map
->stride
);
2570 intel_miptree_unmap_depthstencil(struct brw_context
*brw
,
2571 struct intel_mipmap_tree
*mt
,
2572 struct intel_miptree_map
*map
,
2576 struct intel_mipmap_tree
*z_mt
= mt
;
2577 struct intel_mipmap_tree
*s_mt
= mt
->stencil_mt
;
2578 bool map_z32f_x24s8
= mt
->format
== MESA_FORMAT_Z_FLOAT32
;
2580 if (map
->mode
& GL_MAP_WRITE_BIT
) {
2581 uint32_t *packed_map
= map
->ptr
;
2582 uint8_t *s_map
= intel_miptree_map_raw(brw
, s_mt
);
2583 uint32_t *z_map
= intel_miptree_map_raw(brw
, z_mt
);
2584 unsigned int s_image_x
, s_image_y
;
2585 unsigned int z_image_x
, z_image_y
;
2587 intel_miptree_get_image_offset(s_mt
, level
, slice
,
2588 &s_image_x
, &s_image_y
);
2589 intel_miptree_get_image_offset(z_mt
, level
, slice
,
2590 &z_image_x
, &z_image_y
);
2592 for (uint32_t y
= 0; y
< map
->h
; y
++) {
2593 for (uint32_t x
= 0; x
< map
->w
; x
++) {
2594 ptrdiff_t s_offset
= intel_offset_S8(s_mt
->pitch
,
2595 x
+ s_image_x
+ map
->x
,
2596 y
+ s_image_y
+ map
->y
,
2597 brw
->has_swizzling
);
2598 ptrdiff_t z_offset
= ((y
+ z_image_y
+ map
->y
) *
2600 (x
+ z_image_x
+ map
->x
));
2602 if (map_z32f_x24s8
) {
2603 z_map
[z_offset
] = packed_map
[(y
* map
->w
+ x
) * 2 + 0];
2604 s_map
[s_offset
] = packed_map
[(y
* map
->w
+ x
) * 2 + 1];
2606 uint32_t packed
= packed_map
[y
* map
->w
+ x
];
2607 s_map
[s_offset
] = packed
>> 24;
2608 z_map
[z_offset
] = packed
;
2613 intel_miptree_unmap_raw(s_mt
);
2614 intel_miptree_unmap_raw(z_mt
);
2616 DBG("%s: %d,%d %dx%d from z mt %p (%s) %d,%d, s mt %p %d,%d = %p/%d\n",
2618 map
->x
, map
->y
, map
->w
, map
->h
,
2619 z_mt
, _mesa_get_format_name(z_mt
->format
),
2620 map
->x
+ z_image_x
, map
->y
+ z_image_y
,
2621 s_mt
, map
->x
+ s_image_x
, map
->y
+ s_image_y
,
2622 map
->ptr
, map
->stride
);
2629 * Create and attach a map to the miptree at (level, slice). Return the
2632 static struct intel_miptree_map
*
2633 intel_miptree_attach_map(struct intel_mipmap_tree
*mt
,
2642 struct intel_miptree_map
*map
= calloc(1, sizeof(*map
));
2647 assert(mt
->level
[level
].slice
[slice
].map
== NULL
);
2648 mt
->level
[level
].slice
[slice
].map
= map
;
2660 * Release the map at (level, slice).
2663 intel_miptree_release_map(struct intel_mipmap_tree
*mt
,
2667 struct intel_miptree_map
**map
;
2669 map
= &mt
->level
[level
].slice
[slice
].map
;
2675 can_blit_slice(struct intel_mipmap_tree
*mt
,
2676 unsigned int level
, unsigned int slice
)
2680 intel_miptree_get_image_offset(mt
, level
, slice
, &image_x
, &image_y
);
2681 if (image_x
>= 32768 || image_y
>= 32768)
2684 /* See intel_miptree_blit() for details on the 32k pitch limit. */
2685 if (mt
->pitch
>= 32768)
2692 use_intel_mipree_map_blit(struct brw_context
*brw
,
2693 struct intel_mipmap_tree
*mt
,
2699 /* It's probably not worth swapping to the blit ring because of
2700 * all the overhead involved. But, we must use blitter for the
2701 * surfaces with INTEL_MIPTREE_TRMODE_{YF,YS}.
2703 (!(mode
& GL_MAP_WRITE_BIT
) ||
2704 mt
->tr_mode
!= INTEL_MIPTREE_TRMODE_NONE
) &&
2706 (mt
->tiling
== I915_TILING_X
||
2707 /* Prior to Sandybridge, the blitter can't handle Y tiling */
2708 (brw
->gen
>= 6 && mt
->tiling
== I915_TILING_Y
) ||
2709 /* Fast copy blit on skl+ supports all tiling formats. */
2711 can_blit_slice(mt
, level
, slice
))
2714 if (mt
->tiling
!= I915_TILING_NONE
&&
2715 mt
->bo
->size
>= brw
->max_gtt_map_object_size
) {
2716 assert(can_blit_slice(mt
, level
, slice
));
2724 * Parameter \a out_stride has type ptrdiff_t not because the buffer stride may
2725 * exceed 32 bits but to diminish the likelihood subtle bugs in pointer
2726 * arithmetic overflow.
2728 * If you call this function and use \a out_stride, then you're doing pointer
2729 * arithmetic on \a out_ptr. The type of \a out_stride doesn't prevent all
2730 * bugs. The caller must still take care to avoid 32-bit overflow errors in
2731 * all arithmetic expressions that contain buffer offsets and pixel sizes,
2732 * which usually have type uint32_t or GLuint.
2735 intel_miptree_map(struct brw_context
*brw
,
2736 struct intel_mipmap_tree
*mt
,
2745 ptrdiff_t *out_stride
)
2747 struct intel_miptree_map
*map
;
2749 assert(mt
->num_samples
<= 1);
2751 map
= intel_miptree_attach_map(mt
, level
, slice
, x
, y
, w
, h
, mode
);
2758 intel_miptree_slice_resolve_depth(brw
, mt
, level
, slice
);
2759 if (map
->mode
& GL_MAP_WRITE_BIT
) {
2760 intel_miptree_slice_set_needs_hiz_resolve(mt
, level
, slice
);
2763 if (mt
->format
== MESA_FORMAT_S_UINT8
) {
2764 intel_miptree_map_s8(brw
, mt
, map
, level
, slice
);
2765 } else if (mt
->etc_format
!= MESA_FORMAT_NONE
&&
2766 !(mode
& BRW_MAP_DIRECT_BIT
)) {
2767 intel_miptree_map_etc(brw
, mt
, map
, level
, slice
);
2768 } else if (mt
->stencil_mt
&& !(mode
& BRW_MAP_DIRECT_BIT
)) {
2769 intel_miptree_map_depthstencil(brw
, mt
, map
, level
, slice
);
2770 } else if (use_intel_mipree_map_blit(brw
, mt
, mode
, level
, slice
)) {
2771 intel_miptree_map_blit(brw
, mt
, map
, level
, slice
);
2772 #if defined(USE_SSE41)
2773 } else if (!(mode
& GL_MAP_WRITE_BIT
) &&
2774 !mt
->compressed
&& cpu_has_sse4_1
&&
2775 (mt
->pitch
% 16 == 0)) {
2776 intel_miptree_map_movntdqa(brw
, mt
, map
, level
, slice
);
2779 /* intel_miptree_map_gtt() doesn't support surfaces with Yf/Ys tiling. */
2780 assert(mt
->tr_mode
== INTEL_MIPTREE_TRMODE_NONE
);
2781 intel_miptree_map_gtt(brw
, mt
, map
, level
, slice
);
2784 *out_ptr
= map
->ptr
;
2785 *out_stride
= map
->stride
;
2787 if (map
->ptr
== NULL
)
2788 intel_miptree_release_map(mt
, level
, slice
);
2792 intel_miptree_unmap(struct brw_context
*brw
,
2793 struct intel_mipmap_tree
*mt
,
2797 struct intel_miptree_map
*map
= mt
->level
[level
].slice
[slice
].map
;
2799 assert(mt
->num_samples
<= 1);
2804 DBG("%s: mt %p (%s) level %d slice %d\n", __func__
,
2805 mt
, _mesa_get_format_name(mt
->format
), level
, slice
);
2807 if (mt
->format
== MESA_FORMAT_S_UINT8
) {
2808 intel_miptree_unmap_s8(brw
, mt
, map
, level
, slice
);
2809 } else if (mt
->etc_format
!= MESA_FORMAT_NONE
&&
2810 !(map
->mode
& BRW_MAP_DIRECT_BIT
)) {
2811 intel_miptree_unmap_etc(brw
, mt
, map
, level
, slice
);
2812 } else if (mt
->stencil_mt
&& !(map
->mode
& BRW_MAP_DIRECT_BIT
)) {
2813 intel_miptree_unmap_depthstencil(brw
, mt
, map
, level
, slice
);
2814 } else if (map
->linear_mt
) {
2815 intel_miptree_unmap_blit(brw
, mt
, map
, level
, slice
);
2816 #if defined(USE_SSE41)
2817 } else if (map
->buffer
&& cpu_has_sse4_1
) {
2818 intel_miptree_unmap_movntdqa(brw
, mt
, map
, level
, slice
);
2821 intel_miptree_unmap_gtt(mt
);
2824 intel_miptree_release_map(mt
, level
, slice
);