2 * Copyright 2003 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.
26 #include <drm_fourcc.h>
30 #include "main/context.h"
31 #include "main/framebuffer.h"
32 #include "main/renderbuffer.h"
33 #include "main/texobj.h"
34 #include "main/hash.h"
35 #include "main/fbobject.h"
36 #include "main/version.h"
37 #include "swrast/s_renderbuffer.h"
38 #include "util/ralloc.h"
39 #include "brw_defines.h"
40 #include "compiler/nir/nir.h"
45 #ifndef DRM_FORMAT_MOD_INVALID
46 #define DRM_FORMAT_MOD_INVALID ((1ULL<<56) - 1)
49 #ifndef DRM_FORMAT_MOD_LINEAR
50 #define DRM_FORMAT_MOD_LINEAR 0
53 static const __DRIconfigOptionsExtension brw_config_options
= {
54 .base
= { __DRI_CONFIG_OPTIONS
, 1 },
57 DRI_CONF_SECTION_PERFORMANCE
58 DRI_CONF_VBLANK_MODE(DRI_CONF_VBLANK_ALWAYS_SYNC
)
59 /* Options correspond to DRI_CONF_BO_REUSE_DISABLED,
60 * DRI_CONF_BO_REUSE_ALL
62 DRI_CONF_OPT_BEGIN_V(bo_reuse
, enum, 1, "0:1")
63 DRI_CONF_DESC_BEGIN(en
, "Buffer object reuse")
64 DRI_CONF_ENUM(0, "Disable buffer object reuse")
65 DRI_CONF_ENUM(1, "Enable reuse of all sizes of buffer objects")
70 DRI_CONF_SECTION_QUALITY
71 DRI_CONF_FORCE_S3TC_ENABLE("false")
73 DRI_CONF_PRECISE_TRIG("false")
75 DRI_CONF_OPT_BEGIN(clamp_max_samples
, int, -1)
76 DRI_CONF_DESC(en
, "Clamp the value of GL_MAX_SAMPLES to the "
77 "given integer. If negative, then do not clamp.")
81 DRI_CONF_SECTION_DEBUG
82 DRI_CONF_NO_RAST("false")
83 DRI_CONF_ALWAYS_FLUSH_BATCH("false")
84 DRI_CONF_ALWAYS_FLUSH_CACHE("false")
85 DRI_CONF_DISABLE_THROTTLING("false")
86 DRI_CONF_FORCE_GLSL_EXTENSIONS_WARN("false")
87 DRI_CONF_FORCE_GLSL_VERSION(0)
88 DRI_CONF_DISABLE_GLSL_LINE_CONTINUATIONS("false")
89 DRI_CONF_DISABLE_BLEND_FUNC_EXTENDED("false")
90 DRI_CONF_DUAL_COLOR_BLEND_BY_LOCATION("false")
91 DRI_CONF_ALLOW_GLSL_EXTENSION_DIRECTIVE_MIDSHADER("false")
92 DRI_CONF_ALLOW_HIGHER_COMPAT_VERSION("false")
93 DRI_CONF_FORCE_GLSL_ABS_SQRT("false")
95 DRI_CONF_OPT_BEGIN_B(shader_precompile
, "true")
96 DRI_CONF_DESC(en
, "Perform code generation at shader link time.")
100 DRI_CONF_SECTION_MISCELLANEOUS
101 DRI_CONF_GLSL_ZERO_INIT("false")
106 #include "intel_batchbuffer.h"
107 #include "intel_buffers.h"
108 #include "intel_bufmgr.h"
109 #include "intel_fbo.h"
110 #include "intel_mipmap_tree.h"
111 #include "intel_screen.h"
112 #include "intel_tex.h"
113 #include "intel_image.h"
115 #include "brw_context.h"
117 #include "i915_drm.h"
120 * For debugging purposes, this returns a time in seconds.
127 clock_gettime(CLOCK_MONOTONIC
, &tp
);
129 return tp
.tv_sec
+ tp
.tv_nsec
/ 1000000000.0;
132 static const __DRItexBufferExtension intelTexBufferExtension
= {
133 .base
= { __DRI_TEX_BUFFER
, 3 },
135 .setTexBuffer
= intelSetTexBuffer
,
136 .setTexBuffer2
= intelSetTexBuffer2
,
137 .releaseTexBuffer
= NULL
,
141 intel_dri2_flush_with_flags(__DRIcontext
*cPriv
,
142 __DRIdrawable
*dPriv
,
144 enum __DRI2throttleReason reason
)
146 struct brw_context
*brw
= cPriv
->driverPrivate
;
151 struct gl_context
*ctx
= &brw
->ctx
;
153 FLUSH_VERTICES(ctx
, 0);
155 if (flags
& __DRI2_FLUSH_DRAWABLE
)
156 intel_resolve_for_dri2_flush(brw
, dPriv
);
158 if (reason
== __DRI2_THROTTLE_SWAPBUFFER
)
159 brw
->need_swap_throttle
= true;
160 if (reason
== __DRI2_THROTTLE_FLUSHFRONT
)
161 brw
->need_flush_throttle
= true;
163 intel_batchbuffer_flush(brw
);
167 * Provides compatibility with loaders that only support the older (version
168 * 1-3) flush interface.
170 * That includes libGL up to Mesa 9.0, and the X Server at least up to 1.13.
173 intel_dri2_flush(__DRIdrawable
*drawable
)
175 intel_dri2_flush_with_flags(drawable
->driContextPriv
, drawable
,
176 __DRI2_FLUSH_DRAWABLE
,
177 __DRI2_THROTTLE_SWAPBUFFER
);
180 static const struct __DRI2flushExtensionRec intelFlushExtension
= {
181 .base
= { __DRI2_FLUSH
, 4 },
183 .flush
= intel_dri2_flush
,
184 .invalidate
= dri2InvalidateDrawable
,
185 .flush_with_flags
= intel_dri2_flush_with_flags
,
188 static struct intel_image_format intel_image_formats
[] = {
189 { __DRI_IMAGE_FOURCC_ARGB8888
, __DRI_IMAGE_COMPONENTS_RGBA
, 1,
190 { { 0, 0, 0, __DRI_IMAGE_FORMAT_ARGB8888
, 4 } } },
192 { __DRI_IMAGE_FOURCC_ABGR8888
, __DRI_IMAGE_COMPONENTS_RGBA
, 1,
193 { { 0, 0, 0, __DRI_IMAGE_FORMAT_ABGR8888
, 4 } } },
195 { __DRI_IMAGE_FOURCC_SARGB8888
, __DRI_IMAGE_COMPONENTS_RGBA
, 1,
196 { { 0, 0, 0, __DRI_IMAGE_FORMAT_SARGB8
, 4 } } },
198 { __DRI_IMAGE_FOURCC_XRGB8888
, __DRI_IMAGE_COMPONENTS_RGB
, 1,
199 { { 0, 0, 0, __DRI_IMAGE_FORMAT_XRGB8888
, 4 }, } },
201 { __DRI_IMAGE_FOURCC_XBGR8888
, __DRI_IMAGE_COMPONENTS_RGB
, 1,
202 { { 0, 0, 0, __DRI_IMAGE_FORMAT_XBGR8888
, 4 }, } },
204 { __DRI_IMAGE_FOURCC_ARGB1555
, __DRI_IMAGE_COMPONENTS_RGBA
, 1,
205 { { 0, 0, 0, __DRI_IMAGE_FORMAT_ARGB1555
, 2 } } },
207 { __DRI_IMAGE_FOURCC_RGB565
, __DRI_IMAGE_COMPONENTS_RGB
, 1,
208 { { 0, 0, 0, __DRI_IMAGE_FORMAT_RGB565
, 2 } } },
210 { __DRI_IMAGE_FOURCC_R8
, __DRI_IMAGE_COMPONENTS_R
, 1,
211 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 }, } },
213 { __DRI_IMAGE_FOURCC_R16
, __DRI_IMAGE_COMPONENTS_R
, 1,
214 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R16
, 1 }, } },
216 { __DRI_IMAGE_FOURCC_GR88
, __DRI_IMAGE_COMPONENTS_RG
, 1,
217 { { 0, 0, 0, __DRI_IMAGE_FORMAT_GR88
, 2 }, } },
219 { __DRI_IMAGE_FOURCC_GR1616
, __DRI_IMAGE_COMPONENTS_RG
, 1,
220 { { 0, 0, 0, __DRI_IMAGE_FORMAT_GR1616
, 2 }, } },
222 { __DRI_IMAGE_FOURCC_YUV410
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
223 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
224 { 1, 2, 2, __DRI_IMAGE_FORMAT_R8
, 1 },
225 { 2, 2, 2, __DRI_IMAGE_FORMAT_R8
, 1 } } },
227 { __DRI_IMAGE_FOURCC_YUV411
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
228 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
229 { 1, 2, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
230 { 2, 2, 0, __DRI_IMAGE_FORMAT_R8
, 1 } } },
232 { __DRI_IMAGE_FOURCC_YUV420
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
233 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
234 { 1, 1, 1, __DRI_IMAGE_FORMAT_R8
, 1 },
235 { 2, 1, 1, __DRI_IMAGE_FORMAT_R8
, 1 } } },
237 { __DRI_IMAGE_FOURCC_YUV422
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
238 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
239 { 1, 1, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
240 { 2, 1, 0, __DRI_IMAGE_FORMAT_R8
, 1 } } },
242 { __DRI_IMAGE_FOURCC_YUV444
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
243 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
244 { 1, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
245 { 2, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 } } },
247 { __DRI_IMAGE_FOURCC_YVU410
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
248 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
249 { 2, 2, 2, __DRI_IMAGE_FORMAT_R8
, 1 },
250 { 1, 2, 2, __DRI_IMAGE_FORMAT_R8
, 1 } } },
252 { __DRI_IMAGE_FOURCC_YVU411
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
253 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
254 { 2, 2, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
255 { 1, 2, 0, __DRI_IMAGE_FORMAT_R8
, 1 } } },
257 { __DRI_IMAGE_FOURCC_YVU420
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
258 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
259 { 2, 1, 1, __DRI_IMAGE_FORMAT_R8
, 1 },
260 { 1, 1, 1, __DRI_IMAGE_FORMAT_R8
, 1 } } },
262 { __DRI_IMAGE_FOURCC_YVU422
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
263 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
264 { 2, 1, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
265 { 1, 1, 0, __DRI_IMAGE_FORMAT_R8
, 1 } } },
267 { __DRI_IMAGE_FOURCC_YVU444
, __DRI_IMAGE_COMPONENTS_Y_U_V
, 3,
268 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
269 { 2, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
270 { 1, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 } } },
272 { __DRI_IMAGE_FOURCC_NV12
, __DRI_IMAGE_COMPONENTS_Y_UV
, 2,
273 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
274 { 1, 1, 1, __DRI_IMAGE_FORMAT_GR88
, 2 } } },
276 { __DRI_IMAGE_FOURCC_NV16
, __DRI_IMAGE_COMPONENTS_Y_UV
, 2,
277 { { 0, 0, 0, __DRI_IMAGE_FORMAT_R8
, 1 },
278 { 1, 1, 0, __DRI_IMAGE_FORMAT_GR88
, 2 } } },
280 /* For YUYV buffers, we set up two overlapping DRI images and treat
281 * them as planar buffers in the compositors. Plane 0 is GR88 and
282 * samples YU or YV pairs and places Y into the R component, while
283 * plane 1 is ARGB and samples YUYV clusters and places pairs and
284 * places U into the G component and V into A. This lets the
285 * texture sampler interpolate the Y components correctly when
286 * sampling from plane 0, and interpolate U and V correctly when
287 * sampling from plane 1. */
288 { __DRI_IMAGE_FOURCC_YUYV
, __DRI_IMAGE_COMPONENTS_Y_XUXV
, 2,
289 { { 0, 0, 0, __DRI_IMAGE_FORMAT_GR88
, 2 },
290 { 0, 1, 0, __DRI_IMAGE_FORMAT_ARGB8888
, 4 } } }
294 intel_image_warn_if_unaligned(__DRIimage
*image
, const char *func
)
296 uint32_t tiling
, swizzle
;
297 drm_intel_bo_get_tiling(image
->bo
, &tiling
, &swizzle
);
299 if (tiling
!= I915_TILING_NONE
&& (image
->offset
& 0xfff)) {
300 _mesa_warning(NULL
, "%s: offset 0x%08x not on tile boundary",
301 func
, image
->offset
);
305 static struct intel_image_format
*
306 intel_image_format_lookup(int fourcc
)
308 struct intel_image_format
*f
= NULL
;
310 for (unsigned i
= 0; i
< ARRAY_SIZE(intel_image_formats
); i
++) {
311 if (intel_image_formats
[i
].fourcc
== fourcc
) {
312 f
= &intel_image_formats
[i
];
320 static boolean
intel_lookup_fourcc(int dri_format
, int *fourcc
)
322 for (unsigned i
= 0; i
< ARRAY_SIZE(intel_image_formats
); i
++) {
323 if (intel_image_formats
[i
].planes
[0].dri_format
== dri_format
) {
324 *fourcc
= intel_image_formats
[i
].fourcc
;
332 intel_allocate_image(struct intel_screen
*screen
, int dri_format
,
337 image
= calloc(1, sizeof *image
);
341 image
->screen
= screen
;
342 image
->dri_format
= dri_format
;
345 image
->format
= driImageFormatToGLFormat(dri_format
);
346 if (dri_format
!= __DRI_IMAGE_FORMAT_NONE
&&
347 image
->format
== MESA_FORMAT_NONE
) {
352 image
->internal_format
= _mesa_get_format_base_format(image
->format
);
353 image
->data
= loaderPrivate
;
359 * Sets up a DRIImage structure to point to a slice out of a miptree.
362 intel_setup_image_from_mipmap_tree(struct brw_context
*brw
, __DRIimage
*image
,
363 struct intel_mipmap_tree
*mt
, GLuint level
,
366 intel_miptree_make_shareable(brw
, mt
);
368 intel_miptree_check_level_layer(mt
, level
, zoffset
);
370 image
->width
= minify(mt
->physical_width0
, level
- mt
->first_level
);
371 image
->height
= minify(mt
->physical_height0
, level
- mt
->first_level
);
372 image
->pitch
= mt
->pitch
;
374 image
->offset
= intel_miptree_get_tile_offsets(mt
, level
, zoffset
,
378 drm_intel_bo_unreference(image
->bo
);
380 drm_intel_bo_reference(mt
->bo
);
384 intel_create_image_from_name(__DRIscreen
*dri_screen
,
385 int width
, int height
, int format
,
386 int name
, int pitch
, void *loaderPrivate
)
388 struct intel_screen
*screen
= dri_screen
->driverPrivate
;
392 image
= intel_allocate_image(screen
, format
, loaderPrivate
);
396 if (image
->format
== MESA_FORMAT_NONE
)
399 cpp
= _mesa_get_format_bytes(image
->format
);
401 image
->width
= width
;
402 image
->height
= height
;
403 image
->pitch
= pitch
* cpp
;
404 image
->bo
= drm_intel_bo_gem_create_from_name(screen
->bufmgr
, "image",
415 intel_create_image_from_renderbuffer(__DRIcontext
*context
,
416 int renderbuffer
, void *loaderPrivate
)
419 struct brw_context
*brw
= context
->driverPrivate
;
420 struct gl_context
*ctx
= &brw
->ctx
;
421 struct gl_renderbuffer
*rb
;
422 struct intel_renderbuffer
*irb
;
424 rb
= _mesa_lookup_renderbuffer(ctx
, renderbuffer
);
426 _mesa_error(ctx
, GL_INVALID_OPERATION
, "glRenderbufferExternalMESA");
430 irb
= intel_renderbuffer(rb
);
431 intel_miptree_make_shareable(brw
, irb
->mt
);
432 image
= calloc(1, sizeof *image
);
436 image
->internal_format
= rb
->InternalFormat
;
437 image
->format
= rb
->Format
;
439 image
->data
= loaderPrivate
;
440 drm_intel_bo_unreference(image
->bo
);
441 image
->bo
= irb
->mt
->bo
;
442 drm_intel_bo_reference(irb
->mt
->bo
);
443 image
->width
= rb
->Width
;
444 image
->height
= rb
->Height
;
445 image
->pitch
= irb
->mt
->pitch
;
446 image
->dri_format
= driGLFormatToImageFormat(image
->format
);
447 image
->has_depthstencil
= irb
->mt
->stencil_mt
? true : false;
449 rb
->NeedsFinishRenderTexture
= true;
454 intel_create_image_from_texture(__DRIcontext
*context
, int target
,
455 unsigned texture
, int zoffset
,
461 struct brw_context
*brw
= context
->driverPrivate
;
462 struct gl_texture_object
*obj
;
463 struct intel_texture_object
*iobj
;
466 obj
= _mesa_lookup_texture(&brw
->ctx
, texture
);
467 if (!obj
|| obj
->Target
!= target
) {
468 *error
= __DRI_IMAGE_ERROR_BAD_PARAMETER
;
472 if (target
== GL_TEXTURE_CUBE_MAP
)
475 _mesa_test_texobj_completeness(&brw
->ctx
, obj
);
476 iobj
= intel_texture_object(obj
);
477 if (!obj
->_BaseComplete
|| (level
> 0 && !obj
->_MipmapComplete
)) {
478 *error
= __DRI_IMAGE_ERROR_BAD_PARAMETER
;
482 if (level
< obj
->BaseLevel
|| level
> obj
->_MaxLevel
) {
483 *error
= __DRI_IMAGE_ERROR_BAD_MATCH
;
487 if (target
== GL_TEXTURE_3D
&& obj
->Image
[face
][level
]->Depth
< zoffset
) {
488 *error
= __DRI_IMAGE_ERROR_BAD_MATCH
;
491 image
= calloc(1, sizeof *image
);
493 *error
= __DRI_IMAGE_ERROR_BAD_ALLOC
;
497 image
->internal_format
= obj
->Image
[face
][level
]->InternalFormat
;
498 image
->format
= obj
->Image
[face
][level
]->TexFormat
;
499 image
->data
= loaderPrivate
;
500 intel_setup_image_from_mipmap_tree(brw
, image
, iobj
->mt
, level
, zoffset
);
501 image
->dri_format
= driGLFormatToImageFormat(image
->format
);
502 image
->has_depthstencil
= iobj
->mt
->stencil_mt
? true : false;
503 if (image
->dri_format
== MESA_FORMAT_NONE
) {
504 *error
= __DRI_IMAGE_ERROR_BAD_PARAMETER
;
509 *error
= __DRI_IMAGE_ERROR_SUCCESS
;
514 intel_destroy_image(__DRIimage
*image
)
516 drm_intel_bo_unreference(image
->bo
);
520 enum modifier_priority
{
521 MODIFIER_PRIORITY_INVALID
= 0,
522 MODIFIER_PRIORITY_LINEAR
,
527 const uint64_t priority_to_modifier
[] = {
528 [MODIFIER_PRIORITY_INVALID
] = DRM_FORMAT_MOD_INVALID
,
529 [MODIFIER_PRIORITY_LINEAR
] = DRM_FORMAT_MOD_LINEAR
,
530 [MODIFIER_PRIORITY_X
] = I915_FORMAT_MOD_X_TILED
,
531 [MODIFIER_PRIORITY_Y
] = I915_FORMAT_MOD_Y_TILED
,
535 select_best_modifier(struct gen_device_info
*devinfo
,
536 const uint64_t *modifiers
,
537 const unsigned count
)
539 enum modifier_priority prio
= MODIFIER_PRIORITY_INVALID
;
541 for (int i
= 0; i
< count
; i
++) {
542 switch (modifiers
[i
]) {
543 case I915_FORMAT_MOD_Y_TILED
:
544 prio
= MAX2(prio
, MODIFIER_PRIORITY_Y
);
546 case I915_FORMAT_MOD_X_TILED
:
547 prio
= MAX2(prio
, MODIFIER_PRIORITY_X
);
549 case DRM_FORMAT_MOD_LINEAR
:
550 prio
= MAX2(prio
, MODIFIER_PRIORITY_LINEAR
);
552 case DRM_FORMAT_MOD_INVALID
:
558 return priority_to_modifier
[prio
];
562 intel_create_image_common(__DRIscreen
*dri_screen
,
563 int width
, int height
, int format
,
565 const uint64_t *modifiers
,
570 struct intel_screen
*screen
= dri_screen
->driverPrivate
;
571 /* Historically, X-tiled was the default, and so lack of modifier means
574 uint32_t tiling
= I915_TILING_X
;
578 /* Callers of this may specify a modifier, or a dri usage, but not both. The
579 * newer modifier interface deprecates the older usage flags newer modifier
580 * interface deprecates the older usage flags.
582 assert(!(use
&& count
));
584 uint64_t modifier
= select_best_modifier(&screen
->devinfo
, modifiers
, count
);
586 case I915_FORMAT_MOD_X_TILED
:
587 assert(tiling
== I915_TILING_X
);
589 case DRM_FORMAT_MOD_LINEAR
:
590 tiling
= I915_TILING_NONE
;
592 case I915_FORMAT_MOD_Y_TILED
:
593 tiling
= I915_TILING_Y
;
595 case DRM_FORMAT_MOD_INVALID
:
602 if (use
& __DRI_IMAGE_USE_CURSOR
) {
603 if (width
!= 64 || height
!= 64)
605 tiling
= I915_TILING_NONE
;
608 if (use
& __DRI_IMAGE_USE_LINEAR
)
609 tiling
= I915_TILING_NONE
;
611 image
= intel_allocate_image(screen
, format
, loaderPrivate
);
615 cpp
= _mesa_get_format_bytes(image
->format
);
616 image
->bo
= drm_intel_bo_alloc_tiled(screen
->bufmgr
, "image",
617 width
, height
, cpp
, &tiling
,
619 if (image
->bo
== NULL
) {
623 image
->width
= width
;
624 image
->height
= height
;
625 image
->pitch
= pitch
;
626 image
->modifier
= modifier
;
632 intel_create_image(__DRIscreen
*dri_screen
,
633 int width
, int height
, int format
,
637 return intel_create_image_common(dri_screen
, width
, height
, format
, use
, NULL
, 0,
642 intel_create_image_with_modifiers(__DRIscreen
*dri_screen
,
643 int width
, int height
, int format
,
644 const uint64_t *modifiers
,
645 const unsigned count
,
648 return intel_create_image_common(dri_screen
, width
, height
, format
, 0,
649 modifiers
, count
, loaderPrivate
);
653 intel_query_image(__DRIimage
*image
, int attrib
, int *value
)
656 case __DRI_IMAGE_ATTRIB_STRIDE
:
657 *value
= image
->pitch
;
659 case __DRI_IMAGE_ATTRIB_HANDLE
:
660 *value
= image
->bo
->handle
;
662 case __DRI_IMAGE_ATTRIB_NAME
:
663 return !drm_intel_bo_flink(image
->bo
, (uint32_t *) value
);
664 case __DRI_IMAGE_ATTRIB_FORMAT
:
665 *value
= image
->dri_format
;
667 case __DRI_IMAGE_ATTRIB_WIDTH
:
668 *value
= image
->width
;
670 case __DRI_IMAGE_ATTRIB_HEIGHT
:
671 *value
= image
->height
;
673 case __DRI_IMAGE_ATTRIB_COMPONENTS
:
674 if (image
->planar_format
== NULL
)
676 *value
= image
->planar_format
->components
;
678 case __DRI_IMAGE_ATTRIB_FD
:
679 return !drm_intel_bo_gem_export_to_prime(image
->bo
, value
);
680 case __DRI_IMAGE_ATTRIB_FOURCC
:
681 return intel_lookup_fourcc(image
->dri_format
, value
);
682 case __DRI_IMAGE_ATTRIB_NUM_PLANES
:
685 case __DRI_IMAGE_ATTRIB_OFFSET
:
686 *value
= image
->offset
;
688 case __DRI_IMAGE_ATTRIB_MODIFIER_LOWER
:
689 *value
= (image
->modifier
& 0xffffffff);
691 case __DRI_IMAGE_ATTRIB_MODIFIER_UPPER
:
692 *value
= ((image
->modifier
>> 32) & 0xffffffff);
701 intel_dup_image(__DRIimage
*orig_image
, void *loaderPrivate
)
705 image
= calloc(1, sizeof *image
);
709 drm_intel_bo_reference(orig_image
->bo
);
710 image
->bo
= orig_image
->bo
;
711 image
->internal_format
= orig_image
->internal_format
;
712 image
->planar_format
= orig_image
->planar_format
;
713 image
->dri_format
= orig_image
->dri_format
;
714 image
->format
= orig_image
->format
;
715 image
->offset
= orig_image
->offset
;
716 image
->width
= orig_image
->width
;
717 image
->height
= orig_image
->height
;
718 image
->pitch
= orig_image
->pitch
;
719 image
->tile_x
= orig_image
->tile_x
;
720 image
->tile_y
= orig_image
->tile_y
;
721 image
->has_depthstencil
= orig_image
->has_depthstencil
;
722 image
->data
= loaderPrivate
;
724 memcpy(image
->strides
, orig_image
->strides
, sizeof(image
->strides
));
725 memcpy(image
->offsets
, orig_image
->offsets
, sizeof(image
->offsets
));
731 intel_validate_usage(__DRIimage
*image
, unsigned int use
)
733 if (use
& __DRI_IMAGE_USE_CURSOR
) {
734 if (image
->width
!= 64 || image
->height
!= 64)
742 intel_create_image_from_names(__DRIscreen
*dri_screen
,
743 int width
, int height
, int fourcc
,
744 int *names
, int num_names
,
745 int *strides
, int *offsets
,
748 struct intel_image_format
*f
= NULL
;
752 if (dri_screen
== NULL
|| names
== NULL
|| num_names
!= 1)
755 f
= intel_image_format_lookup(fourcc
);
759 image
= intel_create_image_from_name(dri_screen
, width
, height
,
760 __DRI_IMAGE_FORMAT_NONE
,
761 names
[0], strides
[0],
767 image
->planar_format
= f
;
768 for (i
= 0; i
< f
->nplanes
; i
++) {
769 index
= f
->planes
[i
].buffer_index
;
770 image
->offsets
[index
] = offsets
[index
];
771 image
->strides
[index
] = strides
[index
];
778 intel_create_image_from_fds(__DRIscreen
*dri_screen
,
779 int width
, int height
, int fourcc
,
780 int *fds
, int num_fds
, int *strides
, int *offsets
,
783 struct intel_screen
*screen
= dri_screen
->driverPrivate
;
784 struct intel_image_format
*f
;
788 if (fds
== NULL
|| num_fds
< 1)
791 /* We only support all planes from the same bo */
792 for (i
= 0; i
< num_fds
; i
++)
793 if (fds
[0] != fds
[i
])
796 f
= intel_image_format_lookup(fourcc
);
801 image
= intel_allocate_image(screen
, f
->planes
[0].dri_format
,
804 image
= intel_allocate_image(screen
, __DRI_IMAGE_FORMAT_NONE
,
810 image
->width
= width
;
811 image
->height
= height
;
812 image
->pitch
= strides
[0];
814 image
->planar_format
= f
;
816 for (i
= 0; i
< f
->nplanes
; i
++) {
817 index
= f
->planes
[i
].buffer_index
;
818 image
->offsets
[index
] = offsets
[index
];
819 image
->strides
[index
] = strides
[index
];
821 const int plane_height
= height
>> f
->planes
[i
].height_shift
;
822 const int end
= offsets
[index
] + plane_height
* strides
[index
];
827 image
->bo
= drm_intel_bo_gem_create_from_prime(screen
->bufmgr
,
829 if (image
->bo
== NULL
) {
834 if (f
->nplanes
== 1) {
835 image
->offset
= image
->offsets
[0];
836 intel_image_warn_if_unaligned(image
, __func__
);
843 intel_create_image_from_dma_bufs(__DRIscreen
*dri_screen
,
844 int width
, int height
, int fourcc
,
845 int *fds
, int num_fds
,
846 int *strides
, int *offsets
,
847 enum __DRIYUVColorSpace yuv_color_space
,
848 enum __DRISampleRange sample_range
,
849 enum __DRIChromaSiting horizontal_siting
,
850 enum __DRIChromaSiting vertical_siting
,
855 struct intel_image_format
*f
= intel_image_format_lookup(fourcc
);
858 *error
= __DRI_IMAGE_ERROR_BAD_MATCH
;
862 image
= intel_create_image_from_fds(dri_screen
, width
, height
, fourcc
, fds
,
863 num_fds
, strides
, offsets
,
867 * Invalid parameters and any inconsistencies between are assumed to be
868 * checked by the caller. Therefore besides unsupported formats one can fail
869 * only in allocation.
872 *error
= __DRI_IMAGE_ERROR_BAD_ALLOC
;
876 image
->dma_buf_imported
= true;
877 image
->yuv_color_space
= yuv_color_space
;
878 image
->sample_range
= sample_range
;
879 image
->horizontal_siting
= horizontal_siting
;
880 image
->vertical_siting
= vertical_siting
;
882 *error
= __DRI_IMAGE_ERROR_SUCCESS
;
887 intel_from_planar(__DRIimage
*parent
, int plane
, void *loaderPrivate
)
889 int width
, height
, offset
, stride
, dri_format
, index
;
890 struct intel_image_format
*f
;
893 if (parent
== NULL
|| parent
->planar_format
== NULL
)
896 f
= parent
->planar_format
;
898 if (plane
>= f
->nplanes
)
901 width
= parent
->width
>> f
->planes
[plane
].width_shift
;
902 height
= parent
->height
>> f
->planes
[plane
].height_shift
;
903 dri_format
= f
->planes
[plane
].dri_format
;
904 index
= f
->planes
[plane
].buffer_index
;
905 offset
= parent
->offsets
[index
];
906 stride
= parent
->strides
[index
];
908 image
= intel_allocate_image(parent
->screen
, dri_format
, loaderPrivate
);
912 if (offset
+ height
* stride
> parent
->bo
->size
) {
913 _mesa_warning(NULL
, "intel_create_sub_image: subimage out of bounds");
918 image
->bo
= parent
->bo
;
919 drm_intel_bo_reference(parent
->bo
);
921 image
->width
= width
;
922 image
->height
= height
;
923 image
->pitch
= stride
;
924 image
->offset
= offset
;
926 intel_image_warn_if_unaligned(image
, __func__
);
931 static const __DRIimageExtension intelImageExtension
= {
932 .base
= { __DRI_IMAGE
, 14 },
934 .createImageFromName
= intel_create_image_from_name
,
935 .createImageFromRenderbuffer
= intel_create_image_from_renderbuffer
,
936 .destroyImage
= intel_destroy_image
,
937 .createImage
= intel_create_image
,
938 .queryImage
= intel_query_image
,
939 .dupImage
= intel_dup_image
,
940 .validateUsage
= intel_validate_usage
,
941 .createImageFromNames
= intel_create_image_from_names
,
942 .fromPlanar
= intel_from_planar
,
943 .createImageFromTexture
= intel_create_image_from_texture
,
944 .createImageFromFds
= intel_create_image_from_fds
,
945 .createImageFromDmaBufs
= intel_create_image_from_dma_bufs
,
947 .getCapabilities
= NULL
,
950 .createImageWithModifiers
= intel_create_image_with_modifiers
,
954 brw_query_renderer_integer(__DRIscreen
*dri_screen
,
955 int param
, unsigned int *value
)
957 const struct intel_screen
*const screen
=
958 (struct intel_screen
*) dri_screen
->driverPrivate
;
961 case __DRI2_RENDERER_VENDOR_ID
:
964 case __DRI2_RENDERER_DEVICE_ID
:
965 value
[0] = screen
->deviceID
;
967 case __DRI2_RENDERER_ACCELERATED
:
970 case __DRI2_RENDERER_VIDEO_MEMORY
: {
971 /* Once a batch uses more than 75% of the maximum mappable size, we
972 * assume that there's some fragmentation, and we start doing extra
973 * flushing, etc. That's the big cliff apps will care about.
976 size_t mappable_size
;
978 drm_intel_get_aperture_sizes(dri_screen
->fd
, &mappable_size
, &aper_size
);
980 const unsigned gpu_mappable_megabytes
=
981 (aper_size
/ (1024 * 1024)) * 3 / 4;
983 const long system_memory_pages
= sysconf(_SC_PHYS_PAGES
);
984 const long system_page_size
= sysconf(_SC_PAGE_SIZE
);
986 if (system_memory_pages
<= 0 || system_page_size
<= 0)
989 const uint64_t system_memory_bytes
= (uint64_t) system_memory_pages
990 * (uint64_t) system_page_size
;
992 const unsigned system_memory_megabytes
=
993 (unsigned) (system_memory_bytes
/ (1024 * 1024));
995 value
[0] = MIN2(system_memory_megabytes
, gpu_mappable_megabytes
);
998 case __DRI2_RENDERER_UNIFIED_MEMORY_ARCHITECTURE
:
1001 case __DRI2_RENDERER_HAS_TEXTURE_3D
:
1005 return driQueryRendererIntegerCommon(dri_screen
, param
, value
);
1012 brw_query_renderer_string(__DRIscreen
*dri_screen
,
1013 int param
, const char **value
)
1015 const struct intel_screen
*screen
=
1016 (struct intel_screen
*) dri_screen
->driverPrivate
;
1019 case __DRI2_RENDERER_VENDOR_ID
:
1020 value
[0] = brw_vendor_string
;
1022 case __DRI2_RENDERER_DEVICE_ID
:
1023 value
[0] = brw_get_renderer_string(screen
);
1032 static const __DRI2rendererQueryExtension intelRendererQueryExtension
= {
1033 .base
= { __DRI2_RENDERER_QUERY
, 1 },
1035 .queryInteger
= brw_query_renderer_integer
,
1036 .queryString
= brw_query_renderer_string
1039 static const __DRIrobustnessExtension dri2Robustness
= {
1040 .base
= { __DRI2_ROBUSTNESS
, 1 }
1043 static const __DRIextension
*screenExtensions
[] = {
1044 &intelTexBufferExtension
.base
,
1045 &intelFenceExtension
.base
,
1046 &intelFlushExtension
.base
,
1047 &intelImageExtension
.base
,
1048 &intelRendererQueryExtension
.base
,
1049 &dri2ConfigQueryExtension
.base
,
1053 static const __DRIextension
*intelRobustScreenExtensions
[] = {
1054 &intelTexBufferExtension
.base
,
1055 &intelFenceExtension
.base
,
1056 &intelFlushExtension
.base
,
1057 &intelImageExtension
.base
,
1058 &intelRendererQueryExtension
.base
,
1059 &dri2ConfigQueryExtension
.base
,
1060 &dri2Robustness
.base
,
1065 intel_get_param(struct intel_screen
*screen
, int param
, int *value
)
1068 struct drm_i915_getparam gp
;
1070 memset(&gp
, 0, sizeof(gp
));
1074 if (drmIoctl(screen
->driScrnPriv
->fd
, DRM_IOCTL_I915_GETPARAM
, &gp
) == -1) {
1077 _mesa_warning(NULL
, "drm_i915_getparam: %d", ret
);
1084 intel_get_boolean(struct intel_screen
*screen
, int param
)
1087 return (intel_get_param(screen
, param
, &value
) == 0) && value
;
1091 intel_get_integer(struct intel_screen
*screen
, int param
)
1095 if (intel_get_param(screen
, param
, &value
) == 0)
1102 intelDestroyScreen(__DRIscreen
* sPriv
)
1104 struct intel_screen
*screen
= sPriv
->driverPrivate
;
1106 drm_intel_bufmgr_destroy(screen
->bufmgr
);
1107 driDestroyOptionInfo(&screen
->optionCache
);
1109 ralloc_free(screen
);
1110 sPriv
->driverPrivate
= NULL
;
1115 * This is called when we need to set up GL rendering to a new X window.
1118 intelCreateBuffer(__DRIscreen
*dri_screen
,
1119 __DRIdrawable
* driDrawPriv
,
1120 const struct gl_config
* mesaVis
, GLboolean isPixmap
)
1122 struct intel_renderbuffer
*rb
;
1123 struct intel_screen
*screen
= (struct intel_screen
*)
1124 dri_screen
->driverPrivate
;
1125 mesa_format rgbFormat
;
1126 unsigned num_samples
=
1127 intel_quantize_num_samples(screen
, mesaVis
->samples
);
1128 struct gl_framebuffer
*fb
;
1133 fb
= CALLOC_STRUCT(gl_framebuffer
);
1137 _mesa_initialize_window_framebuffer(fb
, mesaVis
);
1139 if (screen
->winsys_msaa_samples_override
!= -1) {
1140 num_samples
= screen
->winsys_msaa_samples_override
;
1141 fb
->Visual
.samples
= num_samples
;
1144 if (mesaVis
->redBits
== 5) {
1145 rgbFormat
= mesaVis
->redMask
== 0x1f ? MESA_FORMAT_R5G6B5_UNORM
1146 : MESA_FORMAT_B5G6R5_UNORM
;
1147 } else if (mesaVis
->sRGBCapable
) {
1148 rgbFormat
= mesaVis
->redMask
== 0xff ? MESA_FORMAT_R8G8B8A8_SRGB
1149 : MESA_FORMAT_B8G8R8A8_SRGB
;
1150 } else if (mesaVis
->alphaBits
== 0) {
1151 rgbFormat
= mesaVis
->redMask
== 0xff ? MESA_FORMAT_R8G8B8X8_UNORM
1152 : MESA_FORMAT_B8G8R8X8_UNORM
;
1154 rgbFormat
= mesaVis
->redMask
== 0xff ? MESA_FORMAT_R8G8B8A8_SRGB
1155 : MESA_FORMAT_B8G8R8A8_SRGB
;
1156 fb
->Visual
.sRGBCapable
= true;
1159 /* setup the hardware-based renderbuffers */
1160 rb
= intel_create_renderbuffer(rgbFormat
, num_samples
);
1161 _mesa_add_renderbuffer_without_ref(fb
, BUFFER_FRONT_LEFT
, &rb
->Base
.Base
);
1163 if (mesaVis
->doubleBufferMode
) {
1164 rb
= intel_create_renderbuffer(rgbFormat
, num_samples
);
1165 _mesa_add_renderbuffer_without_ref(fb
, BUFFER_BACK_LEFT
, &rb
->Base
.Base
);
1169 * Assert here that the gl_config has an expected depth/stencil bit
1170 * combination: one of d24/s8, d16/s0, d0/s0. (See intelInitScreen2(),
1171 * which constructs the advertised configs.)
1173 if (mesaVis
->depthBits
== 24) {
1174 assert(mesaVis
->stencilBits
== 8);
1176 if (screen
->devinfo
.has_hiz_and_separate_stencil
) {
1177 rb
= intel_create_private_renderbuffer(MESA_FORMAT_Z24_UNORM_X8_UINT
,
1179 _mesa_add_renderbuffer_without_ref(fb
, BUFFER_DEPTH
, &rb
->Base
.Base
);
1180 rb
= intel_create_private_renderbuffer(MESA_FORMAT_S_UINT8
,
1182 _mesa_add_renderbuffer_without_ref(fb
, BUFFER_STENCIL
,
1186 * Use combined depth/stencil. Note that the renderbuffer is
1187 * attached to two attachment points.
1189 rb
= intel_create_private_renderbuffer(MESA_FORMAT_Z24_UNORM_S8_UINT
,
1191 _mesa_add_renderbuffer_without_ref(fb
, BUFFER_DEPTH
, &rb
->Base
.Base
);
1192 _mesa_add_renderbuffer(fb
, BUFFER_STENCIL
, &rb
->Base
.Base
);
1195 else if (mesaVis
->depthBits
== 16) {
1196 assert(mesaVis
->stencilBits
== 0);
1197 rb
= intel_create_private_renderbuffer(MESA_FORMAT_Z_UNORM16
,
1199 _mesa_add_renderbuffer_without_ref(fb
, BUFFER_DEPTH
, &rb
->Base
.Base
);
1202 assert(mesaVis
->depthBits
== 0);
1203 assert(mesaVis
->stencilBits
== 0);
1206 /* now add any/all software-based renderbuffers we may need */
1207 _swrast_add_soft_renderbuffers(fb
,
1208 false, /* never sw color */
1209 false, /* never sw depth */
1210 false, /* never sw stencil */
1211 mesaVis
->accumRedBits
> 0,
1212 false, /* never sw alpha */
1213 false /* never sw aux */ );
1214 driDrawPriv
->driverPrivate
= fb
;
1220 intelDestroyBuffer(__DRIdrawable
* driDrawPriv
)
1222 struct gl_framebuffer
*fb
= driDrawPriv
->driverPrivate
;
1224 _mesa_reference_framebuffer(&fb
, NULL
);
1228 intel_detect_sseu(struct intel_screen
*screen
)
1230 assert(screen
->devinfo
.gen
>= 8);
1233 screen
->subslice_total
= -1;
1234 screen
->eu_total
= -1;
1236 ret
= intel_get_param(screen
, I915_PARAM_SUBSLICE_TOTAL
,
1237 &screen
->subslice_total
);
1238 if (ret
< 0 && ret
!= -EINVAL
)
1241 ret
= intel_get_param(screen
,
1242 I915_PARAM_EU_TOTAL
, &screen
->eu_total
);
1243 if (ret
< 0 && ret
!= -EINVAL
)
1246 /* Without this information, we cannot get the right Braswell brandstrings,
1247 * and we have to use conservative numbers for GPGPU on many platforms, but
1248 * otherwise, things will just work.
1250 if (screen
->subslice_total
< 1 || screen
->eu_total
< 1)
1252 "Kernel 4.1 required to properly query GPU properties.\n");
1257 screen
->subslice_total
= -1;
1258 screen
->eu_total
= -1;
1259 _mesa_warning(NULL
, "Failed to query GPU properties (%s).\n", strerror(-ret
));
1263 intel_init_bufmgr(struct intel_screen
*screen
)
1265 __DRIscreen
*dri_screen
= screen
->driScrnPriv
;
1267 screen
->no_hw
= getenv("INTEL_NO_HW") != NULL
;
1269 screen
->bufmgr
= drm_intel_bufmgr_gem_init(dri_screen
->fd
, BATCH_SZ
);
1270 if (screen
->bufmgr
== NULL
) {
1271 fprintf(stderr
, "[%s:%u] Error initializing buffer manager.\n",
1272 __func__
, __LINE__
);
1276 drm_intel_bufmgr_gem_enable_fenced_relocs(screen
->bufmgr
);
1278 if (!intel_get_boolean(screen
, I915_PARAM_HAS_WAIT_TIMEOUT
)) {
1279 fprintf(stderr
, "[%s: %u] Kernel 3.6 required.\n", __func__
, __LINE__
);
1287 intel_detect_swizzling(struct intel_screen
*screen
)
1289 drm_intel_bo
*buffer
;
1290 unsigned long flags
= 0;
1291 unsigned long aligned_pitch
;
1292 uint32_t tiling
= I915_TILING_X
;
1293 uint32_t swizzle_mode
= 0;
1295 buffer
= drm_intel_bo_alloc_tiled(screen
->bufmgr
, "swizzle test",
1297 &tiling
, &aligned_pitch
, flags
);
1301 drm_intel_bo_get_tiling(buffer
, &tiling
, &swizzle_mode
);
1302 drm_intel_bo_unreference(buffer
);
1304 if (swizzle_mode
== I915_BIT_6_SWIZZLE_NONE
)
1311 intel_detect_timestamp(struct intel_screen
*screen
)
1313 uint64_t dummy
= 0, last
= 0;
1314 int upper
, lower
, loops
;
1316 /* On 64bit systems, some old kernels trigger a hw bug resulting in the
1317 * TIMESTAMP register being shifted and the low 32bits always zero.
1319 * More recent kernels offer an interface to read the full 36bits
1322 if (drm_intel_reg_read(screen
->bufmgr
, TIMESTAMP
| 1, &dummy
) == 0)
1325 /* Determine if we have a 32bit or 64bit kernel by inspecting the
1326 * upper 32bits for a rapidly changing timestamp.
1328 if (drm_intel_reg_read(screen
->bufmgr
, TIMESTAMP
, &last
))
1332 for (loops
= 0; loops
< 10; loops
++) {
1333 /* The TIMESTAMP should change every 80ns, so several round trips
1334 * through the kernel should be enough to advance it.
1336 if (drm_intel_reg_read(screen
->bufmgr
, TIMESTAMP
, &dummy
))
1339 upper
+= (dummy
>> 32) != (last
>> 32);
1340 if (upper
> 1) /* beware 32bit counter overflow */
1341 return 2; /* upper dword holds the low 32bits of the timestamp */
1343 lower
+= (dummy
& 0xffffffff) != (last
& 0xffffffff);
1345 return 1; /* timestamp is unshifted */
1350 /* No advancement? No timestamp! */
1355 * Test if we can use MI_LOAD_REGISTER_MEM from an untrusted batchbuffer.
1357 * Some combinations of hardware and kernel versions allow this feature,
1358 * while others don't. Instead of trying to enumerate every case, just
1359 * try and write a register and see if works.
1362 intel_detect_pipelined_register(struct intel_screen
*screen
,
1363 int reg
, uint32_t expected_value
, bool reset
)
1365 drm_intel_bo
*results
, *bo
;
1367 uint32_t offset
= 0;
1368 bool success
= false;
1370 /* Create a zero'ed temporary buffer for reading our results */
1371 results
= drm_intel_bo_alloc(screen
->bufmgr
, "registers", 4096, 0);
1372 if (results
== NULL
)
1375 bo
= drm_intel_bo_alloc(screen
->bufmgr
, "batchbuffer", 4096, 0);
1379 if (drm_intel_bo_map(bo
, 1))
1382 batch
= bo
->virtual;
1384 /* Write the register. */
1385 *batch
++ = MI_LOAD_REGISTER_IMM
| (3 - 2);
1387 *batch
++ = expected_value
;
1389 /* Save the register's value back to the buffer. */
1390 *batch
++ = MI_STORE_REGISTER_MEM
| (3 - 2);
1392 drm_intel_bo_emit_reloc(bo
, (char *)batch
-(char *)bo
->virtual,
1393 results
, offset
*sizeof(uint32_t),
1394 I915_GEM_DOMAIN_INSTRUCTION
,
1395 I915_GEM_DOMAIN_INSTRUCTION
);
1396 *batch
++ = results
->offset
+ offset
*sizeof(uint32_t);
1398 /* And afterwards clear the register */
1400 *batch
++ = MI_LOAD_REGISTER_IMM
| (3 - 2);
1405 *batch
++ = MI_BATCH_BUFFER_END
;
1407 drm_intel_bo_mrb_exec(bo
, ALIGN((char *)batch
- (char *)bo
->virtual, 8),
1411 /* Check whether the value got written. */
1412 if (drm_intel_bo_map(results
, false) == 0) {
1413 success
= *((uint32_t *)results
->virtual + offset
) == expected_value
;
1414 drm_intel_bo_unmap(results
);
1418 drm_intel_bo_unreference(bo
);
1420 drm_intel_bo_unreference(results
);
1426 intel_detect_pipelined_so(struct intel_screen
*screen
)
1428 const struct gen_device_info
*devinfo
= &screen
->devinfo
;
1430 /* Supposedly, Broadwell just works. */
1431 if (devinfo
->gen
>= 8)
1434 if (devinfo
->gen
<= 6)
1437 /* See the big explanation about command parser versions below */
1438 if (screen
->cmd_parser_version
>= (devinfo
->is_haswell
? 7 : 2))
1441 /* We use SO_WRITE_OFFSET0 since you're supposed to write it (unlike the
1442 * statistics registers), and we already reset it to zero before using it.
1444 return intel_detect_pipelined_register(screen
,
1445 GEN7_SO_WRITE_OFFSET(0),
1451 * Return array of MSAA modes supported by the hardware. The array is
1452 * zero-terminated and sorted in decreasing order.
1455 intel_supported_msaa_modes(const struct intel_screen
*screen
)
1457 static const int gen9_modes
[] = {16, 8, 4, 2, 0, -1};
1458 static const int gen8_modes
[] = {8, 4, 2, 0, -1};
1459 static const int gen7_modes
[] = {8, 4, 0, -1};
1460 static const int gen6_modes
[] = {4, 0, -1};
1461 static const int gen4_modes
[] = {0, -1};
1463 if (screen
->devinfo
.gen
>= 9) {
1465 } else if (screen
->devinfo
.gen
>= 8) {
1467 } else if (screen
->devinfo
.gen
>= 7) {
1469 } else if (screen
->devinfo
.gen
== 6) {
1476 static __DRIconfig
**
1477 intel_screen_make_configs(__DRIscreen
*dri_screen
)
1479 static const mesa_format formats
[] = {
1480 MESA_FORMAT_B5G6R5_UNORM
,
1481 MESA_FORMAT_B8G8R8A8_UNORM
,
1482 MESA_FORMAT_B8G8R8X8_UNORM
1485 /* GLX_SWAP_COPY_OML is not supported due to page flipping. */
1486 static const GLenum back_buffer_modes
[] = {
1487 GLX_SWAP_UNDEFINED_OML
, GLX_NONE
,
1490 static const uint8_t singlesample_samples
[1] = {0};
1491 static const uint8_t multisample_samples
[2] = {4, 8};
1493 struct intel_screen
*screen
= dri_screen
->driverPrivate
;
1494 const struct gen_device_info
*devinfo
= &screen
->devinfo
;
1495 uint8_t depth_bits
[4], stencil_bits
[4];
1496 __DRIconfig
**configs
= NULL
;
1498 /* Generate singlesample configs without accumulation buffer. */
1499 for (unsigned i
= 0; i
< ARRAY_SIZE(formats
); i
++) {
1500 __DRIconfig
**new_configs
;
1501 int num_depth_stencil_bits
= 2;
1503 /* Starting with DRI2 protocol version 1.1 we can request a depth/stencil
1504 * buffer that has a different number of bits per pixel than the color
1505 * buffer, gen >= 6 supports this.
1508 stencil_bits
[0] = 0;
1510 if (formats
[i
] == MESA_FORMAT_B5G6R5_UNORM
) {
1512 stencil_bits
[1] = 0;
1513 if (devinfo
->gen
>= 6) {
1515 stencil_bits
[2] = 8;
1516 num_depth_stencil_bits
= 3;
1520 stencil_bits
[1] = 8;
1523 new_configs
= driCreateConfigs(formats
[i
],
1526 num_depth_stencil_bits
,
1527 back_buffer_modes
, 2,
1528 singlesample_samples
, 1,
1530 configs
= driConcatConfigs(configs
, new_configs
);
1533 /* Generate the minimum possible set of configs that include an
1534 * accumulation buffer.
1536 for (unsigned i
= 0; i
< ARRAY_SIZE(formats
); i
++) {
1537 __DRIconfig
**new_configs
;
1539 if (formats
[i
] == MESA_FORMAT_B5G6R5_UNORM
) {
1541 stencil_bits
[0] = 0;
1544 stencil_bits
[0] = 8;
1547 new_configs
= driCreateConfigs(formats
[i
],
1548 depth_bits
, stencil_bits
, 1,
1549 back_buffer_modes
, 1,
1550 singlesample_samples
, 1,
1552 configs
= driConcatConfigs(configs
, new_configs
);
1555 /* Generate multisample configs.
1557 * This loop breaks early, and hence is a no-op, on gen < 6.
1559 * Multisample configs must follow the singlesample configs in order to
1560 * work around an X server bug present in 1.12. The X server chooses to
1561 * associate the first listed RGBA888-Z24S8 config, regardless of its
1562 * sample count, with the 32-bit depth visual used for compositing.
1564 * Only doublebuffer configs with GLX_SWAP_UNDEFINED_OML behavior are
1565 * supported. Singlebuffer configs are not supported because no one wants
1568 for (unsigned i
= 0; i
< ARRAY_SIZE(formats
); i
++) {
1569 if (devinfo
->gen
< 6)
1572 __DRIconfig
**new_configs
;
1573 const int num_depth_stencil_bits
= 2;
1574 int num_msaa_modes
= 0;
1577 stencil_bits
[0] = 0;
1579 if (formats
[i
] == MESA_FORMAT_B5G6R5_UNORM
) {
1581 stencil_bits
[1] = 0;
1584 stencil_bits
[1] = 8;
1587 if (devinfo
->gen
>= 7)
1589 else if (devinfo
->gen
== 6)
1592 new_configs
= driCreateConfigs(formats
[i
],
1595 num_depth_stencil_bits
,
1596 back_buffer_modes
, 1,
1597 multisample_samples
,
1600 configs
= driConcatConfigs(configs
, new_configs
);
1603 if (configs
== NULL
) {
1604 fprintf(stderr
, "[%s:%u] Error creating FBConfig!\n", __func__
,
1613 set_max_gl_versions(struct intel_screen
*screen
)
1615 __DRIscreen
*dri_screen
= screen
->driScrnPriv
;
1616 const bool has_astc
= screen
->devinfo
.gen
>= 9;
1618 switch (screen
->devinfo
.gen
) {
1621 dri_screen
->max_gl_core_version
= 45;
1622 dri_screen
->max_gl_compat_version
= 30;
1623 dri_screen
->max_gl_es1_version
= 11;
1624 dri_screen
->max_gl_es2_version
= has_astc
? 32 : 31;
1627 dri_screen
->max_gl_core_version
= 33;
1628 if (screen
->devinfo
.is_haswell
&&
1629 can_do_pipelined_register_writes(screen
)) {
1630 dri_screen
->max_gl_core_version
= 42;
1631 if (can_do_compute_dispatch(screen
))
1632 dri_screen
->max_gl_core_version
= 43;
1633 if (can_do_mi_math_and_lrr(screen
))
1634 dri_screen
->max_gl_core_version
= 45;
1636 dri_screen
->max_gl_compat_version
= 30;
1637 dri_screen
->max_gl_es1_version
= 11;
1638 dri_screen
->max_gl_es2_version
= screen
->devinfo
.is_haswell
? 31 : 30;
1641 dri_screen
->max_gl_core_version
= 33;
1642 dri_screen
->max_gl_compat_version
= 30;
1643 dri_screen
->max_gl_es1_version
= 11;
1644 dri_screen
->max_gl_es2_version
= 30;
1648 dri_screen
->max_gl_core_version
= 0;
1649 dri_screen
->max_gl_compat_version
= 21;
1650 dri_screen
->max_gl_es1_version
= 11;
1651 dri_screen
->max_gl_es2_version
= 20;
1654 unreachable("unrecognized intel_screen::gen");
1659 * Return the revision (generally the revid field of the PCI header) of the
1662 * XXX: This function is useful to keep around even if it is not currently in
1663 * use. It is necessary for new platforms and revision specific workarounds or
1664 * features. Please don't remove it so that we know it at least continues to
1667 static __attribute__((__unused__
)) int
1668 brw_get_revision(int fd
)
1670 struct drm_i915_getparam gp
;
1674 memset(&gp
, 0, sizeof(gp
));
1675 gp
.param
= I915_PARAM_REVISION
;
1676 gp
.value
= &revision
;
1678 ret
= drmCommandWriteRead(fd
, DRM_I915_GETPARAM
, &gp
, sizeof(gp
));
1686 shader_debug_log_mesa(void *data
, const char *fmt
, ...)
1688 struct brw_context
*brw
= (struct brw_context
*)data
;
1691 va_start(args
, fmt
);
1693 _mesa_gl_vdebug(&brw
->ctx
, &msg_id
,
1694 MESA_DEBUG_SOURCE_SHADER_COMPILER
,
1695 MESA_DEBUG_TYPE_OTHER
,
1696 MESA_DEBUG_SEVERITY_NOTIFICATION
, fmt
, args
);
1701 shader_perf_log_mesa(void *data
, const char *fmt
, ...)
1703 struct brw_context
*brw
= (struct brw_context
*)data
;
1706 va_start(args
, fmt
);
1708 if (unlikely(INTEL_DEBUG
& DEBUG_PERF
)) {
1710 va_copy(args_copy
, args
);
1711 vfprintf(stderr
, fmt
, args_copy
);
1715 if (brw
->perf_debug
) {
1717 _mesa_gl_vdebug(&brw
->ctx
, &msg_id
,
1718 MESA_DEBUG_SOURCE_SHADER_COMPILER
,
1719 MESA_DEBUG_TYPE_PERFORMANCE
,
1720 MESA_DEBUG_SEVERITY_MEDIUM
, fmt
, args
);
1726 * This is the driver specific part of the createNewScreen entry point.
1727 * Called when using DRI2.
1729 * \return the struct gl_config supported by this driver
1732 __DRIconfig
**intelInitScreen2(__DRIscreen
*dri_screen
)
1734 struct intel_screen
*screen
;
1736 if (dri_screen
->image
.loader
) {
1737 } else if (dri_screen
->dri2
.loader
->base
.version
<= 2 ||
1738 dri_screen
->dri2
.loader
->getBuffersWithFormat
== NULL
) {
1740 "\nERROR! DRI2 loader with getBuffersWithFormat() "
1741 "support required\n");
1745 /* Allocate the private area */
1746 screen
= rzalloc(NULL
, struct intel_screen
);
1748 fprintf(stderr
, "\nERROR! Allocating private area failed\n");
1751 /* parse information in __driConfigOptions */
1752 driParseOptionInfo(&screen
->optionCache
, brw_config_options
.xml
);
1754 screen
->driScrnPriv
= dri_screen
;
1755 dri_screen
->driverPrivate
= (void *) screen
;
1757 if (!intel_init_bufmgr(screen
))
1760 screen
->deviceID
= drm_intel_bufmgr_gem_get_devid(screen
->bufmgr
);
1761 if (!gen_get_device_info(screen
->deviceID
, &screen
->devinfo
))
1764 const struct gen_device_info
*devinfo
= &screen
->devinfo
;
1766 brw_process_intel_debug_variable();
1768 if (INTEL_DEBUG
& DEBUG_BUFMGR
)
1769 drm_intel_bufmgr_set_debug(screen
->bufmgr
, true);
1771 if ((INTEL_DEBUG
& DEBUG_SHADER_TIME
) && devinfo
->gen
< 7) {
1773 "shader_time debugging requires gen7 (Ivybridge) or better.\n");
1774 INTEL_DEBUG
&= ~DEBUG_SHADER_TIME
;
1777 if (intel_get_integer(screen
, I915_PARAM_MMAP_GTT_VERSION
) >= 1) {
1778 /* Theorectically unlimited! At least for individual objects...
1780 * Currently the entire (global) address space for all GTT maps is
1781 * limited to 64bits. That is all objects on the system that are
1782 * setup for GTT mmapping must fit within 64bits. An attempt to use
1783 * one that exceeds the limit with fail in drm_intel_bo_map_gtt().
1785 * Long before we hit that limit, we will be practically limited by
1786 * that any single object must fit in physical memory (RAM). The upper
1787 * limit on the CPU's address space is currently 48bits (Skylake), of
1788 * which only 39bits can be physical memory. (The GPU itself also has
1789 * a 48bit addressable virtual space.) We can fit over 32 million
1790 * objects of the current maximum allocable size before running out
1793 screen
->max_gtt_map_object_size
= UINT64_MAX
;
1795 /* Estimate the size of the mappable aperture into the GTT. There's an
1796 * ioctl to get the whole GTT size, but not one to get the mappable subset.
1797 * It turns out it's basically always 256MB, though some ancient hardware
1800 uint32_t gtt_size
= 256 * 1024 * 1024;
1802 /* We don't want to map two objects such that a memcpy between them would
1803 * just fault one mapping in and then the other over and over forever. So
1804 * we would need to divide the GTT size by 2. Additionally, some GTT is
1805 * taken up by things like the framebuffer and the ringbuffer and such, so
1806 * be more conservative.
1808 screen
->max_gtt_map_object_size
= gtt_size
/ 4;
1811 screen
->hw_has_swizzling
= intel_detect_swizzling(screen
);
1812 screen
->hw_has_timestamp
= intel_detect_timestamp(screen
);
1814 /* GENs prior to 8 do not support EU/Subslice info */
1815 if (devinfo
->gen
>= 8) {
1816 intel_detect_sseu(screen
);
1817 } else if (devinfo
->gen
== 7) {
1818 screen
->subslice_total
= 1 << (devinfo
->gt
- 1);
1821 /* Gen7-7.5 kernel requirements / command parser saga:
1824 * Haswell and Baytrail cannot use any privileged batchbuffer features.
1826 * Ivybridge has aliasing PPGTT on by default, which accidentally marks
1827 * all batches secure, allowing them to use any feature with no checking.
1828 * This is effectively equivalent to a command parser version of
1829 * \infinity - everything is possible.
1831 * The command parser does not exist, and querying the version will
1835 * The kernel enables the command parser by default, for systems with
1836 * aliasing PPGTT enabled (Ivybridge and Haswell). However, the
1837 * hardware checker is still enabled, so Haswell and Baytrail cannot
1840 * Ivybridge goes from "everything is possible" to "only what the
1841 * command parser allows" (if the user boots with i915.cmd_parser=0,
1842 * then everything is possible again). We can only safely use features
1843 * allowed by the supported command parser version.
1845 * Annoyingly, I915_PARAM_CMD_PARSER_VERSION reports the static version
1846 * implemented by the kernel, even if it's turned off. So, checking
1847 * for version > 0 does not mean that you can write registers. We have
1848 * to try it and see. The version does, however, indicate the age of
1851 * Instead of matching the hardware checker's behavior of converting
1852 * privileged commands to MI_NOOP, it makes execbuf2 start returning
1853 * -EINVAL, making it dangerous to try and use privileged features.
1855 * Effective command parser versions:
1856 * - Haswell: 0 (reporting 1, writes don't work)
1857 * - Baytrail: 0 (reporting 1, writes don't work)
1858 * - Ivybridge: 1 (enabled) or infinite (disabled)
1861 * Baytrail aliasing PPGTT is enabled, making it like Ivybridge:
1862 * effectively version 1 (enabled) or infinite (disabled).
1864 * - v3.19: f1f55cc0556031c8ee3fe99dae7251e78b9b653b
1865 * Command parser v2 supports predicate writes.
1867 * - Haswell: 0 (reporting 1, writes don't work)
1868 * - Baytrail: 2 (enabled) or infinite (disabled)
1869 * - Ivybridge: 2 (enabled) or infinite (disabled)
1871 * So version >= 2 is enough to know that Ivybridge and Baytrail
1872 * will work. Haswell still can't do anything.
1874 * - v4.0: Version 3 happened. Largely not relevant.
1876 * - v4.1: 6702cf16e0ba8b0129f5aa1b6609d4e9c70bc13b
1877 * L3 config registers are properly saved and restored as part
1878 * of the hardware context. We can approximately detect this point
1879 * in time by checking if I915_PARAM_REVISION is recognized - it
1880 * landed in a later commit, but in the same release cycle.
1882 * - v4.2: 245054a1fe33c06ad233e0d58a27ec7b64db9284
1883 * Command parser finally gains secure batch promotion. On Haswell,
1884 * the hardware checker gets disabled, which finally allows it to do
1885 * privileged commands.
1887 * I915_PARAM_CMD_PARSER_VERSION reports 3. Effective versions:
1888 * - Haswell: 3 (enabled) or 0 (disabled)
1889 * - Baytrail: 3 (enabled) or infinite (disabled)
1890 * - Ivybridge: 3 (enabled) or infinite (disabled)
1892 * Unfortunately, detecting this point in time is tricky, because
1893 * no version bump happened when this important change occurred.
1894 * On Haswell, if we can write any register, then the kernel is at
1895 * least this new, and we can start trusting the version number.
1897 * - v4.4: 2bbe6bbb0dc94fd4ce287bdac9e1bd184e23057b and
1898 * Command parser reaches version 4, allowing access to Haswell
1899 * atomic scratch and chicken3 registers. If version >= 4, we know
1900 * the kernel is new enough to support privileged features on all
1901 * hardware. However, the user might have disabled it...and the
1902 * kernel will still report version 4. So we still have to guess
1905 * - v4.4: 7b9748cb513a6bef4af87b79f0da3ff7e8b56cd8
1906 * Command parser v5 whitelists indirect compute shader dispatch
1907 * registers, needed for OpenGL 4.3 and later.
1910 * Command parser v7 lets us use MI_MATH on Haswell.
1912 * Additionally, the kernel begins reporting version 0 when
1913 * the command parser is disabled, allowing us to skip the
1914 * guess-and-check step on Haswell. Unfortunately, this also
1915 * means that we can no longer use it as an indicator of the
1916 * age of the kernel.
1918 if (intel_get_param(screen
, I915_PARAM_CMD_PARSER_VERSION
,
1919 &screen
->cmd_parser_version
) < 0) {
1920 /* Command parser does not exist - getparam is unrecognized */
1921 screen
->cmd_parser_version
= 0;
1924 if (!intel_detect_pipelined_so(screen
)) {
1925 /* We can't do anything, so the effective version is 0. */
1926 screen
->cmd_parser_version
= 0;
1928 screen
->kernel_features
|= KERNEL_ALLOWS_SOL_OFFSET_WRITES
;
1931 const char *force_msaa
= getenv("INTEL_FORCE_MSAA");
1933 screen
->winsys_msaa_samples_override
=
1934 intel_quantize_num_samples(screen
, atoi(force_msaa
));
1935 printf("Forcing winsys sample count to %d\n",
1936 screen
->winsys_msaa_samples_override
);
1938 screen
->winsys_msaa_samples_override
= -1;
1941 set_max_gl_versions(screen
);
1943 /* Notification of GPU resets requires hardware contexts and a kernel new
1944 * enough to support DRM_IOCTL_I915_GET_RESET_STATS. If the ioctl is
1945 * supported, calling it with a context of 0 will either generate EPERM or
1946 * no error. If the ioctl is not supported, it always generate EINVAL.
1947 * Use this to determine whether to advertise the __DRI2_ROBUSTNESS
1948 * extension to the loader.
1950 * Don't even try on pre-Gen6, since we don't attempt to use contexts there.
1952 if (devinfo
->gen
>= 6) {
1953 struct drm_i915_reset_stats stats
;
1954 memset(&stats
, 0, sizeof(stats
));
1956 const int ret
= drmIoctl(dri_screen
->fd
, DRM_IOCTL_I915_GET_RESET_STATS
, &stats
);
1958 screen
->has_context_reset_notification
=
1959 (ret
!= -1 || errno
!= EINVAL
);
1962 if (devinfo
->gen
>= 8 || screen
->cmd_parser_version
>= 2)
1963 screen
->kernel_features
|= KERNEL_ALLOWS_PREDICATE_WRITES
;
1965 /* Haswell requires command parser version 4 in order to have L3
1966 * atomic scratch1 and chicken3 bits
1968 if (devinfo
->is_haswell
&& screen
->cmd_parser_version
>= 4) {
1969 screen
->kernel_features
|=
1970 KERNEL_ALLOWS_HSW_SCRATCH1_AND_ROW_CHICKEN3
;
1973 /* Haswell requires command parser version 6 in order to write to the
1974 * MI_MATH GPR registers, and version 7 in order to use
1975 * MI_LOAD_REGISTER_REG (which all users of MI_MATH use).
1977 if (devinfo
->gen
>= 8 ||
1978 (devinfo
->is_haswell
&& screen
->cmd_parser_version
>= 7)) {
1979 screen
->kernel_features
|= KERNEL_ALLOWS_MI_MATH_AND_LRR
;
1982 /* Gen7 needs at least command parser version 5 to support compute */
1983 if (devinfo
->gen
>= 8 || screen
->cmd_parser_version
>= 5)
1984 screen
->kernel_features
|= KERNEL_ALLOWS_COMPUTE_DISPATCH
;
1986 dri_screen
->extensions
= !screen
->has_context_reset_notification
1987 ? screenExtensions
: intelRobustScreenExtensions
;
1989 screen
->compiler
= brw_compiler_create(screen
, devinfo
);
1990 screen
->compiler
->shader_debug_log
= shader_debug_log_mesa
;
1991 screen
->compiler
->shader_perf_log
= shader_perf_log_mesa
;
1992 screen
->program_id
= 1;
1994 screen
->has_exec_fence
=
1995 intel_get_boolean(screen
, I915_PARAM_HAS_EXEC_FENCE
);
1997 return (const __DRIconfig
**) intel_screen_make_configs(dri_screen
);
2000 struct intel_buffer
{
2005 static __DRIbuffer
*
2006 intelAllocateBuffer(__DRIscreen
*dri_screen
,
2007 unsigned attachment
, unsigned format
,
2008 int width
, int height
)
2010 struct intel_buffer
*intelBuffer
;
2011 struct intel_screen
*screen
= dri_screen
->driverPrivate
;
2013 assert(attachment
== __DRI_BUFFER_FRONT_LEFT
||
2014 attachment
== __DRI_BUFFER_BACK_LEFT
);
2016 intelBuffer
= calloc(1, sizeof *intelBuffer
);
2017 if (intelBuffer
== NULL
)
2020 /* The front and back buffers are color buffers, which are X tiled. GEN9+
2021 * supports Y tiled and compressed buffers, but there is no way to plumb that
2022 * through to here. */
2023 uint32_t tiling
= I915_TILING_X
;
2024 unsigned long pitch
;
2025 int cpp
= format
/ 8;
2026 intelBuffer
->bo
= drm_intel_bo_alloc_tiled(screen
->bufmgr
,
2027 "intelAllocateBuffer",
2032 BO_ALLOC_FOR_RENDER
);
2034 if (intelBuffer
->bo
== NULL
) {
2039 drm_intel_bo_flink(intelBuffer
->bo
, &intelBuffer
->base
.name
);
2041 intelBuffer
->base
.attachment
= attachment
;
2042 intelBuffer
->base
.cpp
= cpp
;
2043 intelBuffer
->base
.pitch
= pitch
;
2045 return &intelBuffer
->base
;
2049 intelReleaseBuffer(__DRIscreen
*dri_screen
, __DRIbuffer
*buffer
)
2051 struct intel_buffer
*intelBuffer
= (struct intel_buffer
*) buffer
;
2053 drm_intel_bo_unreference(intelBuffer
->bo
);
2057 static const struct __DriverAPIRec brw_driver_api
= {
2058 .InitScreen
= intelInitScreen2
,
2059 .DestroyScreen
= intelDestroyScreen
,
2060 .CreateContext
= brwCreateContext
,
2061 .DestroyContext
= intelDestroyContext
,
2062 .CreateBuffer
= intelCreateBuffer
,
2063 .DestroyBuffer
= intelDestroyBuffer
,
2064 .MakeCurrent
= intelMakeCurrent
,
2065 .UnbindContext
= intelUnbindContext
,
2066 .AllocateBuffer
= intelAllocateBuffer
,
2067 .ReleaseBuffer
= intelReleaseBuffer
2070 static const struct __DRIDriverVtableExtensionRec brw_vtable
= {
2071 .base
= { __DRI_DRIVER_VTABLE
, 1 },
2072 .vtable
= &brw_driver_api
,
2075 static const __DRIextension
*brw_driver_extensions
[] = {
2076 &driCoreExtension
.base
,
2077 &driImageDriverExtension
.base
,
2078 &driDRI2Extension
.base
,
2080 &brw_config_options
.base
,
2084 PUBLIC
const __DRIextension
**__driDriverGetExtensions_i965(void)
2086 globalDriverAPI
= &brw_driver_api
;
2088 return brw_driver_extensions
;