2 * Copyright 2018 Collabora Ltd.
4 * Permission is hereby granted, free of charge, to any person obtaining a
5 * copy of this software and associated documentation files (the "Software"),
6 * to deal in the Software without restriction, including without limitation
7 * on the rights to use, copy, modify, merge, publish, distribute, sub
8 * license, and/or sell copies of the Software, and to permit persons to whom
9 * the Software is furnished to do so, subject to the following conditions:
11 * The above copyright notice and this permission notice (including the next
12 * paragraph) shall be included in all copies or substantial portions of the
15 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
16 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
17 * FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL
18 * THE AUTHOR(S) AND/OR THEIR SUPPLIERS BE LIABLE FOR ANY CLAIM,
19 * DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR
20 * OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE
21 * USE OR OTHER DEALINGS IN THE SOFTWARE.
24 #include "nir_to_spirv.h"
25 #include "spirv_builder.h"
28 #include "pipe/p_state.h"
29 #include "util/u_memory.h"
30 #include "util/hash_table.h"
32 /* this consistently maps slots to a zero-indexed value to avoid wasting slots */
33 static unsigned slot_pack_map
[] = {
34 /* Position is builtin */
35 [VARYING_SLOT_POS
] = UINT_MAX
,
36 [VARYING_SLOT_COL0
] = 0, /* input/output */
37 [VARYING_SLOT_COL1
] = 1, /* input/output */
38 [VARYING_SLOT_FOGC
] = 2, /* input/output */
39 /* TEX0-7 are deprecated, so we put them at the end of the range and hope nobody uses them all */
40 [VARYING_SLOT_TEX0
] = VARYING_SLOT_VAR0
- 1, /* input/output */
41 [VARYING_SLOT_TEX1
] = VARYING_SLOT_VAR0
- 2,
42 [VARYING_SLOT_TEX2
] = VARYING_SLOT_VAR0
- 3,
43 [VARYING_SLOT_TEX3
] = VARYING_SLOT_VAR0
- 4,
44 [VARYING_SLOT_TEX4
] = VARYING_SLOT_VAR0
- 5,
45 [VARYING_SLOT_TEX5
] = VARYING_SLOT_VAR0
- 6,
46 [VARYING_SLOT_TEX6
] = VARYING_SLOT_VAR0
- 7,
47 [VARYING_SLOT_TEX7
] = VARYING_SLOT_VAR0
- 8,
49 /* PointSize is builtin */
50 [VARYING_SLOT_PSIZ
] = UINT_MAX
,
52 [VARYING_SLOT_BFC0
] = 3, /* output only */
53 [VARYING_SLOT_BFC1
] = 4, /* output only */
54 [VARYING_SLOT_EDGE
] = 5, /* output only */
55 [VARYING_SLOT_CLIP_VERTEX
] = 6, /* output only */
57 /* ClipDistance is builtin */
58 [VARYING_SLOT_CLIP_DIST0
] = UINT_MAX
,
59 [VARYING_SLOT_CLIP_DIST1
] = UINT_MAX
,
61 /* CullDistance is builtin */
62 [VARYING_SLOT_CULL_DIST0
] = UINT_MAX
, /* input/output */
63 [VARYING_SLOT_CULL_DIST1
] = UINT_MAX
, /* never actually used */
65 /* PrimitiveId is builtin */
66 [VARYING_SLOT_PRIMITIVE_ID
] = UINT_MAX
,
68 /* Layer is builtin */
69 [VARYING_SLOT_LAYER
] = UINT_MAX
, /* input/output */
71 /* ViewportIndex is builtin */
72 [VARYING_SLOT_VIEWPORT
] = UINT_MAX
, /* input/output */
74 /* FrontFacing is builtin */
75 [VARYING_SLOT_FACE
] = UINT_MAX
,
77 /* PointCoord is builtin */
78 [VARYING_SLOT_PNTC
] = UINT_MAX
, /* input only */
80 /* TessLevelOuter is builtin */
81 [VARYING_SLOT_TESS_LEVEL_OUTER
] = UINT_MAX
,
82 /* TessLevelInner is builtin */
83 [VARYING_SLOT_TESS_LEVEL_INNER
] = UINT_MAX
,
85 [VARYING_SLOT_BOUNDING_BOX0
] = 7, /* Only appears as TCS output. */
86 [VARYING_SLOT_BOUNDING_BOX1
] = 8, /* Only appears as TCS output. */
87 [VARYING_SLOT_VIEW_INDEX
] = 9, /* input/output */
88 [VARYING_SLOT_VIEWPORT_MASK
] = 10, /* output only */
90 #define NTV_MIN_RESERVED_SLOTS 11
95 struct spirv_builder builder
;
99 gl_shader_stage stage
;
103 SpvId image_types
[PIPE_MAX_SAMPLERS
];
104 SpvId samplers
[PIPE_MAX_SAMPLERS
];
105 unsigned samplers_used
: PIPE_MAX_SAMPLERS
;
106 SpvId entry_ifaces
[PIPE_MAX_SHADER_INPUTS
* 4 + PIPE_MAX_SHADER_OUTPUTS
* 4];
107 size_t num_entry_ifaces
;
115 struct hash_table
*vars
; /* nir_variable -> SpvId */
116 struct hash_table
*so_outputs
; /* pipe_stream_output -> SpvId */
117 unsigned outputs
[VARYING_SLOT_MAX
];
118 const struct glsl_type
*so_output_gl_types
[VARYING_SLOT_MAX
];
119 SpvId so_output_types
[VARYING_SLOT_MAX
];
121 const SpvId
*block_ids
;
124 SpvId loop_break
, loop_cont
;
126 SpvId front_face_var
, instance_id_var
, vertex_id_var
;
128 bool seen_texcoord
[8]; //whether we've seen a VARYING_SLOT_TEX[n] this pass
133 get_fvec_constant(struct ntv_context
*ctx
, unsigned bit_size
,
134 unsigned num_components
, float value
);
137 get_uvec_constant(struct ntv_context
*ctx
, unsigned bit_size
,
138 unsigned num_components
, uint32_t value
);
141 get_ivec_constant(struct ntv_context
*ctx
, unsigned bit_size
,
142 unsigned num_components
, int32_t value
);
145 emit_unop(struct ntv_context
*ctx
, SpvOp op
, SpvId type
, SpvId src
);
148 emit_binop(struct ntv_context
*ctx
, SpvOp op
, SpvId type
,
149 SpvId src0
, SpvId src1
);
152 emit_triop(struct ntv_context
*ctx
, SpvOp op
, SpvId type
,
153 SpvId src0
, SpvId src1
, SpvId src2
);
156 get_bvec_type(struct ntv_context
*ctx
, int num_components
)
158 SpvId bool_type
= spirv_builder_type_bool(&ctx
->builder
);
159 if (num_components
> 1)
160 return spirv_builder_type_vector(&ctx
->builder
, bool_type
,
163 assert(num_components
== 1);
168 block_label(struct ntv_context
*ctx
, nir_block
*block
)
170 assert(block
->index
< ctx
->num_blocks
);
171 return ctx
->block_ids
[block
->index
];
175 emit_float_const(struct ntv_context
*ctx
, int bit_size
, float value
)
177 assert(bit_size
== 32);
178 return spirv_builder_const_float(&ctx
->builder
, bit_size
, value
);
182 emit_uint_const(struct ntv_context
*ctx
, int bit_size
, uint32_t value
)
184 assert(bit_size
== 32);
185 return spirv_builder_const_uint(&ctx
->builder
, bit_size
, value
);
189 emit_int_const(struct ntv_context
*ctx
, int bit_size
, int32_t value
)
191 assert(bit_size
== 32);
192 return spirv_builder_const_int(&ctx
->builder
, bit_size
, value
);
196 get_fvec_type(struct ntv_context
*ctx
, unsigned bit_size
, unsigned num_components
)
198 assert(bit_size
== 32); // only 32-bit floats supported so far
200 SpvId float_type
= spirv_builder_type_float(&ctx
->builder
, bit_size
);
201 if (num_components
> 1)
202 return spirv_builder_type_vector(&ctx
->builder
, float_type
,
205 assert(num_components
== 1);
210 get_ivec_type(struct ntv_context
*ctx
, unsigned bit_size
, unsigned num_components
)
212 assert(bit_size
== 32); // only 32-bit ints supported so far
214 SpvId int_type
= spirv_builder_type_int(&ctx
->builder
, bit_size
);
215 if (num_components
> 1)
216 return spirv_builder_type_vector(&ctx
->builder
, int_type
,
219 assert(num_components
== 1);
224 get_uvec_type(struct ntv_context
*ctx
, unsigned bit_size
, unsigned num_components
)
226 assert(bit_size
== 32); // only 32-bit uints supported so far
228 SpvId uint_type
= spirv_builder_type_uint(&ctx
->builder
, bit_size
);
229 if (num_components
> 1)
230 return spirv_builder_type_vector(&ctx
->builder
, uint_type
,
233 assert(num_components
== 1);
238 get_dest_uvec_type(struct ntv_context
*ctx
, nir_dest
*dest
)
240 unsigned bit_size
= MAX2(nir_dest_bit_size(*dest
), 32);
241 return get_uvec_type(ctx
, bit_size
, nir_dest_num_components(*dest
));
245 get_glsl_basetype(struct ntv_context
*ctx
, enum glsl_base_type type
)
249 return spirv_builder_type_bool(&ctx
->builder
);
251 case GLSL_TYPE_FLOAT
:
252 return spirv_builder_type_float(&ctx
->builder
, 32);
255 return spirv_builder_type_int(&ctx
->builder
, 32);
258 return spirv_builder_type_uint(&ctx
->builder
, 32);
259 /* TODO: handle more types */
262 unreachable("unknown GLSL type");
267 get_glsl_type(struct ntv_context
*ctx
, const struct glsl_type
*type
)
270 if (glsl_type_is_scalar(type
))
271 return get_glsl_basetype(ctx
, glsl_get_base_type(type
));
273 if (glsl_type_is_vector(type
))
274 return spirv_builder_type_vector(&ctx
->builder
,
275 get_glsl_basetype(ctx
, glsl_get_base_type(type
)),
276 glsl_get_vector_elements(type
));
278 if (glsl_type_is_array(type
)) {
279 SpvId ret
= spirv_builder_type_array(&ctx
->builder
,
280 get_glsl_type(ctx
, glsl_get_array_element(type
)),
281 emit_uint_const(ctx
, 32, glsl_get_length(type
)));
282 uint32_t stride
= glsl_get_explicit_stride(type
);
284 spirv_builder_emit_array_stride(&ctx
->builder
, ret
, stride
);
289 unreachable("we shouldn't get here, I think...");
292 static inline unsigned
293 handle_slot(struct ntv_context
*ctx
, unsigned slot
)
295 unsigned orig
= slot
;
296 if (slot
< VARYING_SLOT_VAR0
) {
298 if (slot
>= VARYING_SLOT_TEX0
&& slot
<= VARYING_SLOT_TEX7
)
299 ctx
->seen_texcoord
[slot
- VARYING_SLOT_TEX0
] = true;
301 slot
= slot_pack_map
[slot
];
302 if (slot
== UINT_MAX
)
303 debug_printf("unhandled varying slot: %s\n", gl_varying_slot_name(orig
));
305 slot
-= VARYING_SLOT_VAR0
- NTV_MIN_RESERVED_SLOTS
;
306 assert(slot
<= VARYING_SLOT_VAR0
- 8 ||
307 !ctx
->seen_texcoord
[VARYING_SLOT_VAR0
- slot
- 1]);
310 assert(slot
< VARYING_SLOT_VAR0
);
314 #define HANDLE_EMIT_BUILTIN(SLOT, BUILTIN) \
315 case VARYING_SLOT_##SLOT: \
316 spirv_builder_emit_builtin(&ctx->builder, var_id, SpvBuiltIn##BUILTIN); \
321 emit_input(struct ntv_context
*ctx
, struct nir_variable
*var
)
323 SpvId var_type
= get_glsl_type(ctx
, var
->type
);
324 SpvId pointer_type
= spirv_builder_type_pointer(&ctx
->builder
,
325 SpvStorageClassInput
,
327 SpvId var_id
= spirv_builder_emit_var(&ctx
->builder
, pointer_type
,
328 SpvStorageClassInput
);
331 spirv_builder_emit_name(&ctx
->builder
, var_id
, var
->name
);
333 if (ctx
->stage
== MESA_SHADER_FRAGMENT
) {
334 unsigned slot
= var
->data
.location
;
336 HANDLE_EMIT_BUILTIN(POS
, FragCoord
);
337 HANDLE_EMIT_BUILTIN(PNTC
, PointCoord
);
338 HANDLE_EMIT_BUILTIN(LAYER
, Layer
);
339 HANDLE_EMIT_BUILTIN(PRIMITIVE_ID
, PrimitiveId
);
340 HANDLE_EMIT_BUILTIN(CLIP_DIST0
, ClipDistance
);
341 HANDLE_EMIT_BUILTIN(CULL_DIST0
, CullDistance
);
342 HANDLE_EMIT_BUILTIN(VIEWPORT
, ViewportIndex
);
343 HANDLE_EMIT_BUILTIN(FACE
, FrontFacing
);
346 slot
= handle_slot(ctx
, slot
);
347 spirv_builder_emit_location(&ctx
->builder
, var_id
, slot
);
350 spirv_builder_emit_location(&ctx
->builder
, var_id
,
351 var
->data
.driver_location
);
354 if (var
->data
.location_frac
)
355 spirv_builder_emit_component(&ctx
->builder
, var_id
,
356 var
->data
.location_frac
);
358 if (var
->data
.interpolation
== INTERP_MODE_FLAT
)
359 spirv_builder_emit_decoration(&ctx
->builder
, var_id
, SpvDecorationFlat
);
361 _mesa_hash_table_insert(ctx
->vars
, var
, (void *)(intptr_t)var_id
);
363 assert(ctx
->num_entry_ifaces
< ARRAY_SIZE(ctx
->entry_ifaces
));
364 ctx
->entry_ifaces
[ctx
->num_entry_ifaces
++] = var_id
;
368 emit_output(struct ntv_context
*ctx
, struct nir_variable
*var
)
370 SpvId var_type
= get_glsl_type(ctx
, var
->type
);
371 SpvId pointer_type
= spirv_builder_type_pointer(&ctx
->builder
,
372 SpvStorageClassOutput
,
374 SpvId var_id
= spirv_builder_emit_var(&ctx
->builder
, pointer_type
,
375 SpvStorageClassOutput
);
377 spirv_builder_emit_name(&ctx
->builder
, var_id
, var
->name
);
380 if (ctx
->stage
== MESA_SHADER_VERTEX
) {
381 unsigned slot
= var
->data
.location
;
383 HANDLE_EMIT_BUILTIN(POS
, Position
);
384 HANDLE_EMIT_BUILTIN(PSIZ
, PointSize
);
385 HANDLE_EMIT_BUILTIN(LAYER
, Layer
);
386 HANDLE_EMIT_BUILTIN(PRIMITIVE_ID
, PrimitiveId
);
387 HANDLE_EMIT_BUILTIN(CULL_DIST0
, CullDistance
);
388 HANDLE_EMIT_BUILTIN(VIEWPORT
, ViewportIndex
);
389 HANDLE_EMIT_BUILTIN(TESS_LEVEL_OUTER
, TessLevelOuter
);
390 HANDLE_EMIT_BUILTIN(TESS_LEVEL_INNER
, TessLevelInner
);
392 case VARYING_SLOT_CLIP_DIST0
:
393 assert(glsl_type_is_array(var
->type
));
394 spirv_builder_emit_builtin(&ctx
->builder
, var_id
, SpvBuiltInClipDistance
);
395 /* this can be as large as 2x vec4, which requires 2 slots */
396 ctx
->outputs
[VARYING_SLOT_CLIP_DIST1
] = var_id
;
397 ctx
->so_output_gl_types
[VARYING_SLOT_CLIP_DIST1
] = var
->type
;
398 ctx
->so_output_types
[VARYING_SLOT_CLIP_DIST1
] = var_type
;
402 slot
= handle_slot(ctx
, slot
);
403 spirv_builder_emit_location(&ctx
->builder
, var_id
, slot
);
405 ctx
->outputs
[var
->data
.location
] = var_id
;
406 ctx
->so_output_gl_types
[var
->data
.location
] = var
->type
;
407 ctx
->so_output_types
[var
->data
.location
] = var_type
;
408 } else if (ctx
->stage
== MESA_SHADER_FRAGMENT
) {
409 if (var
->data
.location
>= FRAG_RESULT_DATA0
) {
410 spirv_builder_emit_location(&ctx
->builder
, var_id
,
411 var
->data
.location
- FRAG_RESULT_DATA0
);
412 spirv_builder_emit_index(&ctx
->builder
, var_id
, var
->data
.index
);
414 switch (var
->data
.location
) {
415 case FRAG_RESULT_COLOR
:
416 unreachable("gl_FragColor should be lowered by now");
418 case FRAG_RESULT_DEPTH
:
419 spirv_builder_emit_builtin(&ctx
->builder
, var_id
, SpvBuiltInFragDepth
);
423 spirv_builder_emit_location(&ctx
->builder
, var_id
,
424 var
->data
.driver_location
);
425 spirv_builder_emit_index(&ctx
->builder
, var_id
, var
->data
.index
);
430 if (var
->data
.location_frac
)
431 spirv_builder_emit_component(&ctx
->builder
, var_id
,
432 var
->data
.location_frac
);
434 switch (var
->data
.interpolation
) {
435 case INTERP_MODE_NONE
:
436 case INTERP_MODE_SMOOTH
: /* XXX spirv doesn't seem to have anything for this */
438 case INTERP_MODE_FLAT
:
439 spirv_builder_emit_decoration(&ctx
->builder
, var_id
, SpvDecorationFlat
);
441 case INTERP_MODE_EXPLICIT
:
442 spirv_builder_emit_decoration(&ctx
->builder
, var_id
, SpvDecorationExplicitInterpAMD
);
444 case INTERP_MODE_NOPERSPECTIVE
:
445 spirv_builder_emit_decoration(&ctx
->builder
, var_id
, SpvDecorationNoPerspective
);
448 unreachable("unknown interpolation value");
451 _mesa_hash_table_insert(ctx
->vars
, var
, (void *)(intptr_t)var_id
);
453 assert(ctx
->num_entry_ifaces
< ARRAY_SIZE(ctx
->entry_ifaces
));
454 ctx
->entry_ifaces
[ctx
->num_entry_ifaces
++] = var_id
;
458 type_to_dim(enum glsl_sampler_dim gdim
, bool *is_ms
)
462 case GLSL_SAMPLER_DIM_1D
:
464 case GLSL_SAMPLER_DIM_2D
:
466 case GLSL_SAMPLER_DIM_3D
:
468 case GLSL_SAMPLER_DIM_CUBE
:
470 case GLSL_SAMPLER_DIM_RECT
:
472 case GLSL_SAMPLER_DIM_BUF
:
474 case GLSL_SAMPLER_DIM_EXTERNAL
:
475 return SpvDim2D
; /* seems dodgy... */
476 case GLSL_SAMPLER_DIM_MS
:
480 fprintf(stderr
, "unknown sampler type %d\n", gdim
);
487 zink_binding(gl_shader_stage stage
, VkDescriptorType type
, int index
)
489 if (stage
== MESA_SHADER_NONE
||
490 stage
>= MESA_SHADER_COMPUTE
) {
491 unreachable("not supported");
493 uint32_t stage_offset
= (uint32_t)stage
* (PIPE_MAX_CONSTANT_BUFFERS
+
494 PIPE_MAX_SHADER_SAMPLER_VIEWS
);
497 case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER
:
498 assert(index
< PIPE_MAX_CONSTANT_BUFFERS
);
499 return stage_offset
+ index
;
501 case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER
:
502 assert(index
< PIPE_MAX_SHADER_SAMPLER_VIEWS
);
503 return stage_offset
+ PIPE_MAX_CONSTANT_BUFFERS
+ index
;
506 unreachable("unexpected type");
512 emit_sampler(struct ntv_context
*ctx
, struct nir_variable
*var
)
514 const struct glsl_type
*type
= glsl_without_array(var
->type
);
517 SpvDim dimension
= type_to_dim(glsl_get_sampler_dim(type
), &is_ms
);
519 SpvId result_type
= get_glsl_basetype(ctx
, glsl_get_sampler_result_type(type
));
520 SpvId image_type
= spirv_builder_type_image(&ctx
->builder
, result_type
,
522 glsl_sampler_type_is_array(type
),
524 SpvImageFormatUnknown
);
526 SpvId sampled_type
= spirv_builder_type_sampled_image(&ctx
->builder
,
528 SpvId pointer_type
= spirv_builder_type_pointer(&ctx
->builder
,
529 SpvStorageClassUniformConstant
,
532 if (glsl_type_is_array(var
->type
)) {
533 for (int i
= 0; i
< glsl_get_length(var
->type
); ++i
) {
534 SpvId var_id
= spirv_builder_emit_var(&ctx
->builder
, pointer_type
,
535 SpvStorageClassUniformConstant
);
538 char element_name
[100];
539 snprintf(element_name
, sizeof(element_name
), "%s_%d", var
->name
, i
);
540 spirv_builder_emit_name(&ctx
->builder
, var_id
, var
->name
);
543 int index
= var
->data
.binding
+ i
;
544 assert(!(ctx
->samplers_used
& (1 << index
)));
545 assert(!ctx
->image_types
[index
]);
546 ctx
->image_types
[index
] = image_type
;
547 ctx
->samplers
[index
] = var_id
;
548 ctx
->samplers_used
|= 1 << index
;
550 spirv_builder_emit_descriptor_set(&ctx
->builder
, var_id
,
551 var
->data
.descriptor_set
);
552 int binding
= zink_binding(ctx
->stage
,
553 VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER
,
554 var
->data
.binding
+ i
);
555 spirv_builder_emit_binding(&ctx
->builder
, var_id
, binding
);
558 SpvId var_id
= spirv_builder_emit_var(&ctx
->builder
, pointer_type
,
559 SpvStorageClassUniformConstant
);
562 spirv_builder_emit_name(&ctx
->builder
, var_id
, var
->name
);
564 int index
= var
->data
.binding
;
565 assert(!(ctx
->samplers_used
& (1 << index
)));
566 assert(!ctx
->image_types
[index
]);
567 ctx
->image_types
[index
] = image_type
;
568 ctx
->samplers
[index
] = var_id
;
569 ctx
->samplers_used
|= 1 << index
;
571 spirv_builder_emit_descriptor_set(&ctx
->builder
, var_id
,
572 var
->data
.descriptor_set
);
573 int binding
= zink_binding(ctx
->stage
,
574 VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER
,
576 spirv_builder_emit_binding(&ctx
->builder
, var_id
, binding
);
581 emit_ubo(struct ntv_context
*ctx
, struct nir_variable
*var
)
583 uint32_t size
= glsl_count_attribute_slots(var
->type
, false);
584 SpvId vec4_type
= get_uvec_type(ctx
, 32, 4);
585 SpvId array_length
= emit_uint_const(ctx
, 32, size
);
586 SpvId array_type
= spirv_builder_type_array(&ctx
->builder
, vec4_type
,
588 spirv_builder_emit_array_stride(&ctx
->builder
, array_type
, 16);
590 // wrap UBO-array in a struct
591 SpvId struct_type
= spirv_builder_type_struct(&ctx
->builder
, &array_type
, 1);
593 char struct_name
[100];
594 snprintf(struct_name
, sizeof(struct_name
), "struct_%s", var
->name
);
595 spirv_builder_emit_name(&ctx
->builder
, struct_type
, struct_name
);
598 spirv_builder_emit_decoration(&ctx
->builder
, struct_type
,
600 spirv_builder_emit_member_offset(&ctx
->builder
, struct_type
, 0, 0);
603 SpvId pointer_type
= spirv_builder_type_pointer(&ctx
->builder
,
604 SpvStorageClassUniform
,
607 SpvId var_id
= spirv_builder_emit_var(&ctx
->builder
, pointer_type
,
608 SpvStorageClassUniform
);
610 spirv_builder_emit_name(&ctx
->builder
, var_id
, var
->name
);
612 assert(ctx
->num_ubos
< ARRAY_SIZE(ctx
->ubos
));
613 ctx
->ubos
[ctx
->num_ubos
++] = var_id
;
615 spirv_builder_emit_descriptor_set(&ctx
->builder
, var_id
,
616 var
->data
.descriptor_set
);
617 int binding
= zink_binding(ctx
->stage
,
618 VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER
,
620 spirv_builder_emit_binding(&ctx
->builder
, var_id
, binding
);
624 emit_uniform(struct ntv_context
*ctx
, struct nir_variable
*var
)
626 if (var
->data
.mode
== nir_var_mem_ubo
)
629 assert(var
->data
.mode
== nir_var_uniform
);
630 if (glsl_type_is_sampler(glsl_without_array(var
->type
)))
631 emit_sampler(ctx
, var
);
636 get_src_ssa(struct ntv_context
*ctx
, const nir_ssa_def
*ssa
)
638 assert(ssa
->index
< ctx
->num_defs
);
639 assert(ctx
->defs
[ssa
->index
] != 0);
640 return ctx
->defs
[ssa
->index
];
644 get_var_from_reg(struct ntv_context
*ctx
, nir_register
*reg
)
646 assert(reg
->index
< ctx
->num_regs
);
647 assert(ctx
->regs
[reg
->index
] != 0);
648 return ctx
->regs
[reg
->index
];
652 get_src_reg(struct ntv_context
*ctx
, const nir_reg_src
*reg
)
655 assert(!reg
->indirect
);
656 assert(!reg
->base_offset
);
658 SpvId var
= get_var_from_reg(ctx
, reg
->reg
);
659 SpvId type
= get_uvec_type(ctx
, reg
->reg
->bit_size
, reg
->reg
->num_components
);
660 return spirv_builder_emit_load(&ctx
->builder
, type
, var
);
664 get_src(struct ntv_context
*ctx
, nir_src
*src
)
667 return get_src_ssa(ctx
, src
->ssa
);
669 return get_src_reg(ctx
, &src
->reg
);
673 get_alu_src_raw(struct ntv_context
*ctx
, nir_alu_instr
*alu
, unsigned src
)
675 assert(!alu
->src
[src
].negate
);
676 assert(!alu
->src
[src
].abs
);
678 SpvId def
= get_src(ctx
, &alu
->src
[src
].src
);
680 unsigned used_channels
= 0;
681 bool need_swizzle
= false;
682 for (unsigned i
= 0; i
< NIR_MAX_VEC_COMPONENTS
; i
++) {
683 if (!nir_alu_instr_channel_used(alu
, src
, i
))
688 if (alu
->src
[src
].swizzle
[i
] != i
)
691 assert(used_channels
!= 0);
693 unsigned live_channels
= nir_src_num_components(alu
->src
[src
].src
);
694 if (used_channels
!= live_channels
)
700 int bit_size
= nir_src_bit_size(alu
->src
[src
].src
);
701 assert(bit_size
== 1 || bit_size
== 32);
703 SpvId raw_type
= bit_size
== 1 ? spirv_builder_type_bool(&ctx
->builder
) :
704 spirv_builder_type_uint(&ctx
->builder
, bit_size
);
706 if (used_channels
== 1) {
707 uint32_t indices
[] = { alu
->src
[src
].swizzle
[0] };
708 return spirv_builder_emit_composite_extract(&ctx
->builder
, raw_type
,
710 ARRAY_SIZE(indices
));
711 } else if (live_channels
== 1) {
712 SpvId raw_vec_type
= spirv_builder_type_vector(&ctx
->builder
,
716 SpvId constituents
[NIR_MAX_VEC_COMPONENTS
] = {0};
717 for (unsigned i
= 0; i
< used_channels
; ++i
)
718 constituents
[i
] = def
;
720 return spirv_builder_emit_composite_construct(&ctx
->builder
,
725 SpvId raw_vec_type
= spirv_builder_type_vector(&ctx
->builder
,
729 uint32_t components
[NIR_MAX_VEC_COMPONENTS
] = {0};
730 size_t num_components
= 0;
731 for (unsigned i
= 0; i
< NIR_MAX_VEC_COMPONENTS
; i
++) {
732 if (!nir_alu_instr_channel_used(alu
, src
, i
))
735 components
[num_components
++] = alu
->src
[src
].swizzle
[i
];
738 return spirv_builder_emit_vector_shuffle(&ctx
->builder
, raw_vec_type
,
739 def
, def
, components
,
745 store_ssa_def(struct ntv_context
*ctx
, nir_ssa_def
*ssa
, SpvId result
)
748 assert(ssa
->index
< ctx
->num_defs
);
749 ctx
->defs
[ssa
->index
] = result
;
753 emit_select(struct ntv_context
*ctx
, SpvId type
, SpvId cond
,
754 SpvId if_true
, SpvId if_false
)
756 return emit_triop(ctx
, SpvOpSelect
, type
, cond
, if_true
, if_false
);
760 uvec_to_bvec(struct ntv_context
*ctx
, SpvId value
, unsigned num_components
)
762 SpvId type
= get_bvec_type(ctx
, num_components
);
763 SpvId zero
= get_uvec_constant(ctx
, 32, num_components
, 0);
764 return emit_binop(ctx
, SpvOpINotEqual
, type
, value
, zero
);
768 emit_bitcast(struct ntv_context
*ctx
, SpvId type
, SpvId value
)
770 return emit_unop(ctx
, SpvOpBitcast
, type
, value
);
774 bitcast_to_uvec(struct ntv_context
*ctx
, SpvId value
, unsigned bit_size
,
775 unsigned num_components
)
777 SpvId type
= get_uvec_type(ctx
, bit_size
, num_components
);
778 return emit_bitcast(ctx
, type
, value
);
782 bitcast_to_ivec(struct ntv_context
*ctx
, SpvId value
, unsigned bit_size
,
783 unsigned num_components
)
785 SpvId type
= get_ivec_type(ctx
, bit_size
, num_components
);
786 return emit_bitcast(ctx
, type
, value
);
790 bitcast_to_fvec(struct ntv_context
*ctx
, SpvId value
, unsigned bit_size
,
791 unsigned num_components
)
793 SpvId type
= get_fvec_type(ctx
, bit_size
, num_components
);
794 return emit_bitcast(ctx
, type
, value
);
798 store_reg_def(struct ntv_context
*ctx
, nir_reg_dest
*reg
, SpvId result
)
800 SpvId var
= get_var_from_reg(ctx
, reg
->reg
);
802 spirv_builder_emit_store(&ctx
->builder
, var
, result
);
806 store_dest_raw(struct ntv_context
*ctx
, nir_dest
*dest
, SpvId result
)
809 store_ssa_def(ctx
, &dest
->ssa
, result
);
811 store_reg_def(ctx
, &dest
->reg
, result
);
815 store_dest(struct ntv_context
*ctx
, nir_dest
*dest
, SpvId result
, nir_alu_type type
)
817 unsigned num_components
= nir_dest_num_components(*dest
);
818 unsigned bit_size
= nir_dest_bit_size(*dest
);
821 switch (nir_alu_type_get_base_type(type
)) {
823 assert("bool should have bit-size 1");
826 break; /* nothing to do! */
830 result
= bitcast_to_uvec(ctx
, result
, bit_size
, num_components
);
834 unreachable("unsupported nir_alu_type");
838 store_dest_raw(ctx
, dest
, result
);
843 emit_unop(struct ntv_context
*ctx
, SpvOp op
, SpvId type
, SpvId src
)
845 return spirv_builder_emit_unop(&ctx
->builder
, op
, type
, src
);
848 /* return the intended xfb output vec type based on base type and vector size */
850 get_output_type(struct ntv_context
*ctx
, unsigned register_index
, unsigned num_components
)
852 const struct glsl_type
*out_type
= ctx
->so_output_gl_types
[register_index
];
853 enum glsl_base_type base_type
= glsl_get_base_type(out_type
);
854 if (base_type
== GLSL_TYPE_ARRAY
)
855 base_type
= glsl_get_base_type(glsl_without_array(out_type
));
859 return get_bvec_type(ctx
, num_components
);
861 case GLSL_TYPE_FLOAT
:
862 return get_fvec_type(ctx
, 32, num_components
);
865 return get_ivec_type(ctx
, 32, num_components
);
868 return get_uvec_type(ctx
, 32, num_components
);
873 unreachable("unknown type");
877 /* for streamout create new outputs, as streamout can be done on individual components,
878 from complete outputs, so we just can't use the created packed outputs */
880 emit_so_info(struct ntv_context
*ctx
, unsigned max_output_location
,
881 const struct pipe_stream_output_info
*so_info
, struct pipe_stream_output_info
*local_so_info
)
883 for (unsigned i
= 0; i
< local_so_info
->num_outputs
; i
++) {
884 struct pipe_stream_output so_output
= local_so_info
->output
[i
];
885 SpvId out_type
= get_output_type(ctx
, so_output
.register_index
, so_output
.num_components
);
886 SpvId pointer_type
= spirv_builder_type_pointer(&ctx
->builder
,
887 SpvStorageClassOutput
,
889 SpvId var_id
= spirv_builder_emit_var(&ctx
->builder
, pointer_type
,
890 SpvStorageClassOutput
);
893 snprintf(name
, 10, "xfb%d", i
);
894 spirv_builder_emit_name(&ctx
->builder
, var_id
, name
);
895 spirv_builder_emit_offset(&ctx
->builder
, var_id
, (so_output
.dst_offset
* 4));
896 spirv_builder_emit_xfb_buffer(&ctx
->builder
, var_id
, so_output
.output_buffer
);
897 spirv_builder_emit_xfb_stride(&ctx
->builder
, var_id
, so_info
->stride
[so_output
.output_buffer
] * 4);
899 /* output location is incremented by VARYING_SLOT_VAR0 for non-builtins in vtn,
900 * so we need to ensure that the new xfb location slot doesn't conflict with any previously-emitted
903 * if there's no previous outputs that take up user slots (VAR0+) then we can start right after the
904 * glsl builtin reserved slots, otherwise we start just after the adjusted user output slot
906 uint32_t location
= NTV_MIN_RESERVED_SLOTS
+ i
;
907 if (max_output_location
>= VARYING_SLOT_VAR0
)
908 location
= max_output_location
- VARYING_SLOT_VAR0
+ 1 + i
;
909 assert(location
< VARYING_SLOT_VAR0
);
910 assert(location
<= VARYING_SLOT_VAR0
- 8 ||
911 !ctx
->seen_texcoord
[VARYING_SLOT_VAR0
- location
- 1]);
912 spirv_builder_emit_location(&ctx
->builder
, var_id
, location
);
914 /* note: gl_ClipDistance[4] can the 0-indexed member of VARYING_SLOT_CLIP_DIST1 here,
915 * so this is still the 0 component
917 if (so_output
.start_component
)
918 spirv_builder_emit_component(&ctx
->builder
, var_id
, so_output
.start_component
);
920 uint32_t *key
= ralloc_size(ctx
->mem_ctx
, sizeof(uint32_t));
921 *key
= (uint32_t)so_output
.register_index
<< 2 | so_output
.start_component
;
922 _mesa_hash_table_insert(ctx
->so_outputs
, key
, (void *)(intptr_t)var_id
);
924 assert(ctx
->num_entry_ifaces
< ARRAY_SIZE(ctx
->entry_ifaces
));
925 ctx
->entry_ifaces
[ctx
->num_entry_ifaces
++] = var_id
;
930 emit_so_outputs(struct ntv_context
*ctx
,
931 const struct pipe_stream_output_info
*so_info
, struct pipe_stream_output_info
*local_so_info
)
933 SpvId loaded_outputs
[VARYING_SLOT_MAX
] = {};
934 for (unsigned i
= 0; i
< local_so_info
->num_outputs
; i
++) {
935 uint32_t components
[NIR_MAX_VEC_COMPONENTS
];
936 struct pipe_stream_output so_output
= local_so_info
->output
[i
];
937 uint32_t so_key
= (uint32_t) so_output
.register_index
<< 2 | so_output
.start_component
;
938 struct hash_entry
*he
= _mesa_hash_table_search(ctx
->so_outputs
, &so_key
);
940 SpvId so_output_var_id
= (SpvId
)(intptr_t)he
->data
;
942 SpvId type
= get_output_type(ctx
, so_output
.register_index
, so_output
.num_components
);
943 SpvId output
= ctx
->outputs
[so_output
.register_index
];
944 SpvId output_type
= ctx
->so_output_types
[so_output
.register_index
];
945 const struct glsl_type
*out_type
= ctx
->so_output_gl_types
[so_output
.register_index
];
947 if (!loaded_outputs
[so_output
.register_index
])
948 loaded_outputs
[so_output
.register_index
] = spirv_builder_emit_load(&ctx
->builder
, output_type
, output
);
949 SpvId src
= loaded_outputs
[so_output
.register_index
];
953 for (unsigned c
= 0; c
< so_output
.num_components
; c
++) {
954 components
[c
] = so_output
.start_component
+ c
;
955 /* this is the second half of a 2 * vec4 array */
956 if (ctx
->stage
== MESA_SHADER_VERTEX
&& so_output
.register_index
== VARYING_SLOT_CLIP_DIST1
)
960 /* if we're emitting a scalar or the type we're emitting matches the output's original type and we're
961 * emitting the same number of components, then we can skip any sort of conversion here
963 if (glsl_type_is_scalar(out_type
) || (type
== output_type
&& glsl_get_length(out_type
) == so_output
.num_components
))
966 /* OpCompositeExtract can only extract scalars for our use here */
967 if (so_output
.num_components
== 1) {
968 result
= spirv_builder_emit_composite_extract(&ctx
->builder
, type
, src
, components
, so_output
.num_components
);
969 } else if (glsl_type_is_vector(out_type
)) {
970 /* OpVectorShuffle can select vector members into a differently-sized vector */
971 result
= spirv_builder_emit_vector_shuffle(&ctx
->builder
, type
,
973 components
, so_output
.num_components
);
974 result
= emit_unop(ctx
, SpvOpBitcast
, type
, result
);
976 /* for arrays, we need to manually extract each desired member
977 * and re-pack them into the desired output type
979 for (unsigned c
= 0; c
< so_output
.num_components
; c
++) {
980 uint32_t member
[] = { so_output
.start_component
+ c
};
981 SpvId base_type
= get_glsl_type(ctx
, glsl_without_array(out_type
));
983 if (ctx
->stage
== MESA_SHADER_VERTEX
&& so_output
.register_index
== VARYING_SLOT_CLIP_DIST1
)
985 components
[c
] = spirv_builder_emit_composite_extract(&ctx
->builder
, base_type
, src
, member
, 1);
987 result
= spirv_builder_emit_composite_construct(&ctx
->builder
, type
, components
, so_output
.num_components
);
991 spirv_builder_emit_store(&ctx
->builder
, so_output_var_id
, result
);
996 emit_binop(struct ntv_context
*ctx
, SpvOp op
, SpvId type
,
997 SpvId src0
, SpvId src1
)
999 return spirv_builder_emit_binop(&ctx
->builder
, op
, type
, src0
, src1
);
1003 emit_triop(struct ntv_context
*ctx
, SpvOp op
, SpvId type
,
1004 SpvId src0
, SpvId src1
, SpvId src2
)
1006 return spirv_builder_emit_triop(&ctx
->builder
, op
, type
, src0
, src1
, src2
);
1010 emit_builtin_unop(struct ntv_context
*ctx
, enum GLSLstd450 op
, SpvId type
,
1013 SpvId args
[] = { src
};
1014 return spirv_builder_emit_ext_inst(&ctx
->builder
, type
, ctx
->GLSL_std_450
,
1015 op
, args
, ARRAY_SIZE(args
));
1019 emit_builtin_binop(struct ntv_context
*ctx
, enum GLSLstd450 op
, SpvId type
,
1020 SpvId src0
, SpvId src1
)
1022 SpvId args
[] = { src0
, src1
};
1023 return spirv_builder_emit_ext_inst(&ctx
->builder
, type
, ctx
->GLSL_std_450
,
1024 op
, args
, ARRAY_SIZE(args
));
1028 emit_builtin_triop(struct ntv_context
*ctx
, enum GLSLstd450 op
, SpvId type
,
1029 SpvId src0
, SpvId src1
, SpvId src2
)
1031 SpvId args
[] = { src0
, src1
, src2
};
1032 return spirv_builder_emit_ext_inst(&ctx
->builder
, type
, ctx
->GLSL_std_450
,
1033 op
, args
, ARRAY_SIZE(args
));
1037 get_fvec_constant(struct ntv_context
*ctx
, unsigned bit_size
,
1038 unsigned num_components
, float value
)
1040 assert(bit_size
== 32);
1042 SpvId result
= emit_float_const(ctx
, bit_size
, value
);
1043 if (num_components
== 1)
1046 assert(num_components
> 1);
1047 SpvId components
[num_components
];
1048 for (int i
= 0; i
< num_components
; i
++)
1049 components
[i
] = result
;
1051 SpvId type
= get_fvec_type(ctx
, bit_size
, num_components
);
1052 return spirv_builder_const_composite(&ctx
->builder
, type
, components
,
1057 get_uvec_constant(struct ntv_context
*ctx
, unsigned bit_size
,
1058 unsigned num_components
, uint32_t value
)
1060 assert(bit_size
== 32);
1062 SpvId result
= emit_uint_const(ctx
, bit_size
, value
);
1063 if (num_components
== 1)
1066 assert(num_components
> 1);
1067 SpvId components
[num_components
];
1068 for (int i
= 0; i
< num_components
; i
++)
1069 components
[i
] = result
;
1071 SpvId type
= get_uvec_type(ctx
, bit_size
, num_components
);
1072 return spirv_builder_const_composite(&ctx
->builder
, type
, components
,
1077 get_ivec_constant(struct ntv_context
*ctx
, unsigned bit_size
,
1078 unsigned num_components
, int32_t value
)
1080 assert(bit_size
== 32);
1082 SpvId result
= emit_int_const(ctx
, bit_size
, value
);
1083 if (num_components
== 1)
1086 assert(num_components
> 1);
1087 SpvId components
[num_components
];
1088 for (int i
= 0; i
< num_components
; i
++)
1089 components
[i
] = result
;
1091 SpvId type
= get_ivec_type(ctx
, bit_size
, num_components
);
1092 return spirv_builder_const_composite(&ctx
->builder
, type
, components
,
1096 static inline unsigned
1097 alu_instr_src_components(const nir_alu_instr
*instr
, unsigned src
)
1099 if (nir_op_infos
[instr
->op
].input_sizes
[src
] > 0)
1100 return nir_op_infos
[instr
->op
].input_sizes
[src
];
1102 if (instr
->dest
.dest
.is_ssa
)
1103 return instr
->dest
.dest
.ssa
.num_components
;
1105 return instr
->dest
.dest
.reg
.reg
->num_components
;
1109 get_alu_src(struct ntv_context
*ctx
, nir_alu_instr
*alu
, unsigned src
)
1111 SpvId raw_value
= get_alu_src_raw(ctx
, alu
, src
);
1113 unsigned num_components
= alu_instr_src_components(alu
, src
);
1114 unsigned bit_size
= nir_src_bit_size(alu
->src
[src
].src
);
1115 nir_alu_type type
= nir_op_infos
[alu
->op
].input_types
[src
];
1120 switch (nir_alu_type_get_base_type(type
)) {
1122 unreachable("bool should have bit-size 1");
1125 return bitcast_to_ivec(ctx
, raw_value
, bit_size
, num_components
);
1130 case nir_type_float
:
1131 return bitcast_to_fvec(ctx
, raw_value
, bit_size
, num_components
);
1134 unreachable("unknown nir_alu_type");
1140 store_alu_result(struct ntv_context
*ctx
, nir_alu_instr
*alu
, SpvId result
)
1142 assert(!alu
->dest
.saturate
);
1143 return store_dest(ctx
, &alu
->dest
.dest
, result
,
1144 nir_op_infos
[alu
->op
].output_type
);
1148 get_dest_type(struct ntv_context
*ctx
, nir_dest
*dest
, nir_alu_type type
)
1150 unsigned num_components
= nir_dest_num_components(*dest
);
1151 unsigned bit_size
= nir_dest_bit_size(*dest
);
1154 return get_bvec_type(ctx
, num_components
);
1156 switch (nir_alu_type_get_base_type(type
)) {
1158 unreachable("bool should have bit-size 1");
1161 return get_ivec_type(ctx
, bit_size
, num_components
);
1164 return get_uvec_type(ctx
, bit_size
, num_components
);
1166 case nir_type_float
:
1167 return get_fvec_type(ctx
, bit_size
, num_components
);
1170 unreachable("unsupported nir_alu_type");
1175 emit_alu(struct ntv_context
*ctx
, nir_alu_instr
*alu
)
1177 SpvId src
[nir_op_infos
[alu
->op
].num_inputs
];
1178 unsigned in_bit_sizes
[nir_op_infos
[alu
->op
].num_inputs
];
1179 for (unsigned i
= 0; i
< nir_op_infos
[alu
->op
].num_inputs
; i
++) {
1180 src
[i
] = get_alu_src(ctx
, alu
, i
);
1181 in_bit_sizes
[i
] = nir_src_bit_size(alu
->src
[i
].src
);
1184 SpvId dest_type
= get_dest_type(ctx
, &alu
->dest
.dest
,
1185 nir_op_infos
[alu
->op
].output_type
);
1186 unsigned bit_size
= nir_dest_bit_size(alu
->dest
.dest
);
1187 unsigned num_components
= nir_dest_num_components(alu
->dest
.dest
);
1192 assert(nir_op_infos
[alu
->op
].num_inputs
== 1);
1196 #define UNOP(nir_op, spirv_op) \
1198 assert(nir_op_infos[alu->op].num_inputs == 1); \
1199 result = emit_unop(ctx, spirv_op, dest_type, src[0]); \
1202 UNOP(nir_op_ineg
, SpvOpSNegate
)
1203 UNOP(nir_op_fneg
, SpvOpFNegate
)
1204 UNOP(nir_op_fddx
, SpvOpDPdx
)
1205 UNOP(nir_op_fddx_coarse
, SpvOpDPdxCoarse
)
1206 UNOP(nir_op_fddx_fine
, SpvOpDPdxFine
)
1207 UNOP(nir_op_fddy
, SpvOpDPdy
)
1208 UNOP(nir_op_fddy_coarse
, SpvOpDPdyCoarse
)
1209 UNOP(nir_op_fddy_fine
, SpvOpDPdyFine
)
1210 UNOP(nir_op_f2i32
, SpvOpConvertFToS
)
1211 UNOP(nir_op_f2u32
, SpvOpConvertFToU
)
1212 UNOP(nir_op_i2f32
, SpvOpConvertSToF
)
1213 UNOP(nir_op_u2f32
, SpvOpConvertUToF
)
1214 UNOP(nir_op_bitfield_reverse
, SpvOpBitReverse
)
1219 result
= emit_unop(ctx
, SpvOpLogicalNot
, dest_type
, src
[0]);
1221 result
= emit_unop(ctx
, SpvOpNot
, dest_type
, src
[0]);
1225 assert(nir_op_infos
[alu
->op
].num_inputs
== 1);
1226 result
= emit_select(ctx
, dest_type
, src
[0],
1227 get_ivec_constant(ctx
, 32, num_components
, 1),
1228 get_ivec_constant(ctx
, 32, num_components
, 0));
1232 assert(nir_op_infos
[alu
->op
].num_inputs
== 1);
1233 result
= emit_select(ctx
, dest_type
, src
[0],
1234 get_fvec_constant(ctx
, 32, num_components
, 1),
1235 get_fvec_constant(ctx
, 32, num_components
, 0));
1238 #define BUILTIN_UNOP(nir_op, spirv_op) \
1240 assert(nir_op_infos[alu->op].num_inputs == 1); \
1241 result = emit_builtin_unop(ctx, spirv_op, dest_type, src[0]); \
1244 BUILTIN_UNOP(nir_op_iabs
, GLSLstd450SAbs
)
1245 BUILTIN_UNOP(nir_op_fabs
, GLSLstd450FAbs
)
1246 BUILTIN_UNOP(nir_op_fsqrt
, GLSLstd450Sqrt
)
1247 BUILTIN_UNOP(nir_op_frsq
, GLSLstd450InverseSqrt
)
1248 BUILTIN_UNOP(nir_op_flog2
, GLSLstd450Log2
)
1249 BUILTIN_UNOP(nir_op_fexp2
, GLSLstd450Exp2
)
1250 BUILTIN_UNOP(nir_op_ffract
, GLSLstd450Fract
)
1251 BUILTIN_UNOP(nir_op_ffloor
, GLSLstd450Floor
)
1252 BUILTIN_UNOP(nir_op_fceil
, GLSLstd450Ceil
)
1253 BUILTIN_UNOP(nir_op_ftrunc
, GLSLstd450Trunc
)
1254 BUILTIN_UNOP(nir_op_fround_even
, GLSLstd450RoundEven
)
1255 BUILTIN_UNOP(nir_op_fsign
, GLSLstd450FSign
)
1256 BUILTIN_UNOP(nir_op_isign
, GLSLstd450SSign
)
1257 BUILTIN_UNOP(nir_op_fsin
, GLSLstd450Sin
)
1258 BUILTIN_UNOP(nir_op_fcos
, GLSLstd450Cos
)
1262 assert(nir_op_infos
[alu
->op
].num_inputs
== 1);
1263 result
= emit_binop(ctx
, SpvOpFDiv
, dest_type
,
1264 get_fvec_constant(ctx
, bit_size
, num_components
, 1),
1269 assert(nir_op_infos
[alu
->op
].num_inputs
== 1);
1270 result
= emit_binop(ctx
, SpvOpFOrdNotEqual
, dest_type
, src
[0],
1271 get_fvec_constant(ctx
,
1272 nir_src_bit_size(alu
->src
[0].src
),
1273 num_components
, 0));
1276 assert(nir_op_infos
[alu
->op
].num_inputs
== 1);
1277 result
= emit_binop(ctx
, SpvOpINotEqual
, dest_type
, src
[0],
1278 get_ivec_constant(ctx
,
1279 nir_src_bit_size(alu
->src
[0].src
),
1280 num_components
, 0));
1284 #define BINOP(nir_op, spirv_op) \
1286 assert(nir_op_infos[alu->op].num_inputs == 2); \
1287 result = emit_binop(ctx, spirv_op, dest_type, src[0], src[1]); \
1290 BINOP(nir_op_iadd
, SpvOpIAdd
)
1291 BINOP(nir_op_isub
, SpvOpISub
)
1292 BINOP(nir_op_imul
, SpvOpIMul
)
1293 BINOP(nir_op_idiv
, SpvOpSDiv
)
1294 BINOP(nir_op_udiv
, SpvOpUDiv
)
1295 BINOP(nir_op_umod
, SpvOpUMod
)
1296 BINOP(nir_op_fadd
, SpvOpFAdd
)
1297 BINOP(nir_op_fsub
, SpvOpFSub
)
1298 BINOP(nir_op_fmul
, SpvOpFMul
)
1299 BINOP(nir_op_fdiv
, SpvOpFDiv
)
1300 BINOP(nir_op_fmod
, SpvOpFMod
)
1301 BINOP(nir_op_ilt
, SpvOpSLessThan
)
1302 BINOP(nir_op_ige
, SpvOpSGreaterThanEqual
)
1303 BINOP(nir_op_ult
, SpvOpULessThan
)
1304 BINOP(nir_op_uge
, SpvOpUGreaterThanEqual
)
1305 BINOP(nir_op_flt
, SpvOpFOrdLessThan
)
1306 BINOP(nir_op_fge
, SpvOpFOrdGreaterThanEqual
)
1307 BINOP(nir_op_feq
, SpvOpFOrdEqual
)
1308 BINOP(nir_op_fne
, SpvOpFUnordNotEqual
)
1309 BINOP(nir_op_ishl
, SpvOpShiftLeftLogical
)
1310 BINOP(nir_op_ishr
, SpvOpShiftRightArithmetic
)
1311 BINOP(nir_op_ushr
, SpvOpShiftRightLogical
)
1312 BINOP(nir_op_ixor
, SpvOpBitwiseXor
)
1315 #define BINOP_LOG(nir_op, spv_op, spv_log_op) \
1317 assert(nir_op_infos[alu->op].num_inputs == 2); \
1318 if (nir_src_bit_size(alu->src[0].src) == 1) \
1319 result = emit_binop(ctx, spv_log_op, dest_type, src[0], src[1]); \
1321 result = emit_binop(ctx, spv_op, dest_type, src[0], src[1]); \
1324 BINOP_LOG(nir_op_iand
, SpvOpBitwiseAnd
, SpvOpLogicalAnd
)
1325 BINOP_LOG(nir_op_ior
, SpvOpBitwiseOr
, SpvOpLogicalOr
)
1326 BINOP_LOG(nir_op_ieq
, SpvOpIEqual
, SpvOpLogicalEqual
)
1327 BINOP_LOG(nir_op_ine
, SpvOpINotEqual
, SpvOpLogicalNotEqual
)
1330 #define BUILTIN_BINOP(nir_op, spirv_op) \
1332 assert(nir_op_infos[alu->op].num_inputs == 2); \
1333 result = emit_builtin_binop(ctx, spirv_op, dest_type, src[0], src[1]); \
1336 BUILTIN_BINOP(nir_op_fmin
, GLSLstd450FMin
)
1337 BUILTIN_BINOP(nir_op_fmax
, GLSLstd450FMax
)
1338 BUILTIN_BINOP(nir_op_imin
, GLSLstd450SMin
)
1339 BUILTIN_BINOP(nir_op_imax
, GLSLstd450SMax
)
1340 BUILTIN_BINOP(nir_op_umin
, GLSLstd450UMin
)
1341 BUILTIN_BINOP(nir_op_umax
, GLSLstd450UMax
)
1342 #undef BUILTIN_BINOP
1347 assert(nir_op_infos
[alu
->op
].num_inputs
== 2);
1348 result
= emit_binop(ctx
, SpvOpDot
, dest_type
, src
[0], src
[1]);
1352 unreachable("should already be lowered away");
1358 assert(nir_op_infos
[alu
->op
].num_inputs
== 2);
1359 int num_components
= nir_dest_num_components(alu
->dest
.dest
);
1360 SpvId bool_type
= get_bvec_type(ctx
, num_components
);
1362 SpvId zero
= emit_float_const(ctx
, bit_size
, 0.0f
);
1363 SpvId one
= emit_float_const(ctx
, bit_size
, 1.0f
);
1364 if (num_components
> 1) {
1365 SpvId zero_comps
[num_components
], one_comps
[num_components
];
1366 for (int i
= 0; i
< num_components
; i
++) {
1367 zero_comps
[i
] = zero
;
1371 zero
= spirv_builder_const_composite(&ctx
->builder
, dest_type
,
1372 zero_comps
, num_components
);
1373 one
= spirv_builder_const_composite(&ctx
->builder
, dest_type
,
1374 one_comps
, num_components
);
1379 case nir_op_seq
: op
= SpvOpFOrdEqual
; break;
1380 case nir_op_sne
: op
= SpvOpFOrdNotEqual
; break;
1381 case nir_op_slt
: op
= SpvOpFOrdLessThan
; break;
1382 case nir_op_sge
: op
= SpvOpFOrdGreaterThanEqual
; break;
1383 default: unreachable("unexpected op");
1386 result
= emit_binop(ctx
, op
, bool_type
, src
[0], src
[1]);
1387 result
= emit_select(ctx
, dest_type
, result
, one
, zero
);
1392 assert(nir_op_infos
[alu
->op
].num_inputs
== 3);
1393 result
= emit_builtin_triop(ctx
, GLSLstd450FMix
, dest_type
,
1394 src
[0], src
[1], src
[2]);
1398 result
= emit_binop(ctx
, SpvOpFOrdGreaterThan
,
1399 get_bvec_type(ctx
, num_components
),
1401 get_fvec_constant(ctx
,
1402 nir_src_bit_size(alu
->src
[0].src
),
1403 num_components
, 0));
1404 result
= emit_select(ctx
, dest_type
, result
, src
[1], src
[2]);
1408 assert(nir_op_infos
[alu
->op
].num_inputs
== 3);
1409 result
= emit_select(ctx
, dest_type
, src
[0], src
[1], src
[2]);
1412 case nir_op_bany_fnequal2
:
1413 case nir_op_bany_fnequal3
:
1414 case nir_op_bany_fnequal4
: {
1415 assert(nir_op_infos
[alu
->op
].num_inputs
== 2);
1416 assert(alu_instr_src_components(alu
, 0) ==
1417 alu_instr_src_components(alu
, 1));
1418 assert(in_bit_sizes
[0] == in_bit_sizes
[1]);
1419 /* The type of Operand 1 and Operand 2 must be a scalar or vector of floating-point type. */
1420 SpvOp op
= in_bit_sizes
[0] == 1 ? SpvOpLogicalNotEqual
: SpvOpFOrdNotEqual
;
1421 result
= emit_binop(ctx
, op
,
1422 get_bvec_type(ctx
, alu_instr_src_components(alu
, 0)),
1424 result
= emit_unop(ctx
, SpvOpAny
, dest_type
, result
);
1428 case nir_op_ball_fequal2
:
1429 case nir_op_ball_fequal3
:
1430 case nir_op_ball_fequal4
: {
1431 assert(nir_op_infos
[alu
->op
].num_inputs
== 2);
1432 assert(alu_instr_src_components(alu
, 0) ==
1433 alu_instr_src_components(alu
, 1));
1434 assert(in_bit_sizes
[0] == in_bit_sizes
[1]);
1435 /* The type of Operand 1 and Operand 2 must be a scalar or vector of floating-point type. */
1436 SpvOp op
= in_bit_sizes
[0] == 1 ? SpvOpLogicalEqual
: SpvOpFOrdEqual
;
1437 result
= emit_binop(ctx
, op
,
1438 get_bvec_type(ctx
, alu_instr_src_components(alu
, 0)),
1440 result
= emit_unop(ctx
, SpvOpAll
, dest_type
, result
);
1444 case nir_op_bany_inequal2
:
1445 case nir_op_bany_inequal3
:
1446 case nir_op_bany_inequal4
: {
1447 assert(nir_op_infos
[alu
->op
].num_inputs
== 2);
1448 assert(alu_instr_src_components(alu
, 0) ==
1449 alu_instr_src_components(alu
, 1));
1450 assert(in_bit_sizes
[0] == in_bit_sizes
[1]);
1451 /* The type of Operand 1 and Operand 2 must be a scalar or vector of integer type. */
1452 SpvOp op
= in_bit_sizes
[0] == 1 ? SpvOpLogicalNotEqual
: SpvOpINotEqual
;
1453 result
= emit_binop(ctx
, op
,
1454 get_bvec_type(ctx
, alu_instr_src_components(alu
, 0)),
1456 result
= emit_unop(ctx
, SpvOpAny
, dest_type
, result
);
1460 case nir_op_ball_iequal2
:
1461 case nir_op_ball_iequal3
:
1462 case nir_op_ball_iequal4
: {
1463 assert(nir_op_infos
[alu
->op
].num_inputs
== 2);
1464 assert(alu_instr_src_components(alu
, 0) ==
1465 alu_instr_src_components(alu
, 1));
1466 assert(in_bit_sizes
[0] == in_bit_sizes
[1]);
1467 /* The type of Operand 1 and Operand 2 must be a scalar or vector of integer type. */
1468 SpvOp op
= in_bit_sizes
[0] == 1 ? SpvOpLogicalEqual
: SpvOpIEqual
;
1469 result
= emit_binop(ctx
, op
,
1470 get_bvec_type(ctx
, alu_instr_src_components(alu
, 0)),
1472 result
= emit_unop(ctx
, SpvOpAll
, dest_type
, result
);
1479 int num_inputs
= nir_op_infos
[alu
->op
].num_inputs
;
1480 assert(2 <= num_inputs
&& num_inputs
<= 4);
1481 result
= spirv_builder_emit_composite_construct(&ctx
->builder
, dest_type
,
1487 fprintf(stderr
, "emit_alu: not implemented (%s)\n",
1488 nir_op_infos
[alu
->op
].name
);
1490 unreachable("unsupported opcode");
1494 store_alu_result(ctx
, alu
, result
);
1498 emit_load_const(struct ntv_context
*ctx
, nir_load_const_instr
*load_const
)
1500 unsigned bit_size
= load_const
->def
.bit_size
;
1501 unsigned num_components
= load_const
->def
.num_components
;
1504 if (num_components
> 1) {
1505 SpvId components
[num_components
];
1507 if (bit_size
== 1) {
1508 for (int i
= 0; i
< num_components
; i
++)
1509 components
[i
] = spirv_builder_const_bool(&ctx
->builder
,
1510 load_const
->value
[i
].b
);
1512 type
= get_bvec_type(ctx
, num_components
);
1514 for (int i
= 0; i
< num_components
; i
++)
1515 components
[i
] = emit_uint_const(ctx
, bit_size
,
1516 load_const
->value
[i
].u32
);
1518 type
= get_uvec_type(ctx
, bit_size
, num_components
);
1520 constant
= spirv_builder_const_composite(&ctx
->builder
, type
,
1521 components
, num_components
);
1523 assert(num_components
== 1);
1525 constant
= spirv_builder_const_bool(&ctx
->builder
,
1526 load_const
->value
[0].b
);
1528 constant
= emit_uint_const(ctx
, bit_size
, load_const
->value
[0].u32
);
1531 store_ssa_def(ctx
, &load_const
->def
, constant
);
1535 emit_load_ubo(struct ntv_context
*ctx
, nir_intrinsic_instr
*intr
)
1537 nir_const_value
*const_block_index
= nir_src_as_const_value(intr
->src
[0]);
1538 assert(const_block_index
); // no dynamic indexing for now
1539 assert(const_block_index
->u32
== 0); // we only support the default UBO for now
1541 nir_const_value
*const_offset
= nir_src_as_const_value(intr
->src
[1]);
1543 SpvId uvec4_type
= get_uvec_type(ctx
, 32, 4);
1544 SpvId pointer_type
= spirv_builder_type_pointer(&ctx
->builder
,
1545 SpvStorageClassUniform
,
1548 unsigned idx
= const_offset
->u32
;
1549 SpvId member
= emit_uint_const(ctx
, 32, 0);
1550 SpvId offset
= emit_uint_const(ctx
, 32, idx
);
1551 SpvId offsets
[] = { member
, offset
};
1552 SpvId ptr
= spirv_builder_emit_access_chain(&ctx
->builder
, pointer_type
,
1553 ctx
->ubos
[0], offsets
,
1554 ARRAY_SIZE(offsets
));
1555 SpvId result
= spirv_builder_emit_load(&ctx
->builder
, uvec4_type
, ptr
);
1557 SpvId type
= get_dest_uvec_type(ctx
, &intr
->dest
);
1558 unsigned num_components
= nir_dest_num_components(intr
->dest
);
1559 if (num_components
== 1) {
1560 uint32_t components
[] = { 0 };
1561 result
= spirv_builder_emit_composite_extract(&ctx
->builder
,
1565 } else if (num_components
< 4) {
1566 SpvId constituents
[num_components
];
1567 SpvId uint_type
= spirv_builder_type_uint(&ctx
->builder
, 32);
1568 for (uint32_t i
= 0; i
< num_components
; ++i
)
1569 constituents
[i
] = spirv_builder_emit_composite_extract(&ctx
->builder
,
1574 result
= spirv_builder_emit_composite_construct(&ctx
->builder
,
1580 if (nir_dest_bit_size(intr
->dest
) == 1)
1581 result
= uvec_to_bvec(ctx
, result
, num_components
);
1583 store_dest(ctx
, &intr
->dest
, result
, nir_type_uint
);
1585 unreachable("uniform-addressing not yet supported");
1589 emit_discard(struct ntv_context
*ctx
, nir_intrinsic_instr
*intr
)
1591 assert(ctx
->block_started
);
1592 spirv_builder_emit_kill(&ctx
->builder
);
1593 /* discard is weird in NIR, so let's just create an unreachable block after
1594 it and hope that the vulkan driver will DCE any instructinos in it. */
1595 spirv_builder_label(&ctx
->builder
, spirv_builder_new_id(&ctx
->builder
));
1599 emit_load_deref(struct ntv_context
*ctx
, nir_intrinsic_instr
*intr
)
1601 SpvId ptr
= get_src(ctx
, intr
->src
);
1603 SpvId result
= spirv_builder_emit_load(&ctx
->builder
,
1604 get_glsl_type(ctx
, nir_src_as_deref(intr
->src
[0])->type
),
1606 unsigned num_components
= nir_dest_num_components(intr
->dest
);
1607 unsigned bit_size
= nir_dest_bit_size(intr
->dest
);
1608 result
= bitcast_to_uvec(ctx
, result
, bit_size
, num_components
);
1609 store_dest(ctx
, &intr
->dest
, result
, nir_type_uint
);
1613 emit_store_deref(struct ntv_context
*ctx
, nir_intrinsic_instr
*intr
)
1615 SpvId ptr
= get_src(ctx
, &intr
->src
[0]);
1616 SpvId src
= get_src(ctx
, &intr
->src
[1]);
1618 SpvId type
= get_glsl_type(ctx
, nir_src_as_deref(intr
->src
[0])->type
);
1619 SpvId result
= emit_bitcast(ctx
, type
, src
);
1620 spirv_builder_emit_store(&ctx
->builder
, ptr
, result
);
1624 create_builtin_var(struct ntv_context
*ctx
, SpvId var_type
,
1625 SpvStorageClass storage_class
,
1626 const char *name
, SpvBuiltIn builtin
)
1628 SpvId pointer_type
= spirv_builder_type_pointer(&ctx
->builder
,
1631 SpvId var
= spirv_builder_emit_var(&ctx
->builder
, pointer_type
,
1633 spirv_builder_emit_name(&ctx
->builder
, var
, name
);
1634 spirv_builder_emit_builtin(&ctx
->builder
, var
, builtin
);
1636 assert(ctx
->num_entry_ifaces
< ARRAY_SIZE(ctx
->entry_ifaces
));
1637 ctx
->entry_ifaces
[ctx
->num_entry_ifaces
++] = var
;
1642 emit_load_front_face(struct ntv_context
*ctx
, nir_intrinsic_instr
*intr
)
1644 SpvId var_type
= spirv_builder_type_bool(&ctx
->builder
);
1645 if (!ctx
->front_face_var
)
1646 ctx
->front_face_var
= create_builtin_var(ctx
, var_type
,
1647 SpvStorageClassInput
,
1649 SpvBuiltInFrontFacing
);
1651 SpvId result
= spirv_builder_emit_load(&ctx
->builder
, var_type
,
1652 ctx
->front_face_var
);
1653 assert(1 == nir_dest_num_components(intr
->dest
));
1654 store_dest(ctx
, &intr
->dest
, result
, nir_type_bool
);
1658 emit_load_instance_id(struct ntv_context
*ctx
, nir_intrinsic_instr
*intr
)
1660 SpvId var_type
= spirv_builder_type_uint(&ctx
->builder
, 32);
1661 if (!ctx
->instance_id_var
)
1662 ctx
->instance_id_var
= create_builtin_var(ctx
, var_type
,
1663 SpvStorageClassInput
,
1665 SpvBuiltInInstanceIndex
);
1667 SpvId result
= spirv_builder_emit_load(&ctx
->builder
, var_type
,
1668 ctx
->instance_id_var
);
1669 assert(1 == nir_dest_num_components(intr
->dest
));
1670 store_dest(ctx
, &intr
->dest
, result
, nir_type_uint
);
1674 emit_load_vertex_id(struct ntv_context
*ctx
, nir_intrinsic_instr
*intr
)
1676 SpvId var_type
= spirv_builder_type_uint(&ctx
->builder
, 32);
1677 if (!ctx
->vertex_id_var
)
1678 ctx
->vertex_id_var
= create_builtin_var(ctx
, var_type
,
1679 SpvStorageClassInput
,
1681 SpvBuiltInVertexIndex
);
1683 SpvId result
= spirv_builder_emit_load(&ctx
->builder
, var_type
,
1684 ctx
->vertex_id_var
);
1685 assert(1 == nir_dest_num_components(intr
->dest
));
1686 store_dest(ctx
, &intr
->dest
, result
, nir_type_uint
);
1690 emit_intrinsic(struct ntv_context
*ctx
, nir_intrinsic_instr
*intr
)
1692 switch (intr
->intrinsic
) {
1693 case nir_intrinsic_load_ubo
:
1694 emit_load_ubo(ctx
, intr
);
1697 case nir_intrinsic_discard
:
1698 emit_discard(ctx
, intr
);
1701 case nir_intrinsic_load_deref
:
1702 emit_load_deref(ctx
, intr
);
1705 case nir_intrinsic_store_deref
:
1706 emit_store_deref(ctx
, intr
);
1709 case nir_intrinsic_load_front_face
:
1710 emit_load_front_face(ctx
, intr
);
1713 case nir_intrinsic_load_instance_id
:
1714 emit_load_instance_id(ctx
, intr
);
1717 case nir_intrinsic_load_vertex_id
:
1718 emit_load_vertex_id(ctx
, intr
);
1722 fprintf(stderr
, "emit_intrinsic: not implemented (%s)\n",
1723 nir_intrinsic_infos
[intr
->intrinsic
].name
);
1724 unreachable("unsupported intrinsic");
1729 emit_undef(struct ntv_context
*ctx
, nir_ssa_undef_instr
*undef
)
1731 SpvId type
= get_uvec_type(ctx
, undef
->def
.bit_size
,
1732 undef
->def
.num_components
);
1734 store_ssa_def(ctx
, &undef
->def
,
1735 spirv_builder_emit_undef(&ctx
->builder
, type
));
1739 get_src_float(struct ntv_context
*ctx
, nir_src
*src
)
1741 SpvId def
= get_src(ctx
, src
);
1742 unsigned num_components
= nir_src_num_components(*src
);
1743 unsigned bit_size
= nir_src_bit_size(*src
);
1744 return bitcast_to_fvec(ctx
, def
, bit_size
, num_components
);
1748 get_src_int(struct ntv_context
*ctx
, nir_src
*src
)
1750 SpvId def
= get_src(ctx
, src
);
1751 unsigned num_components
= nir_src_num_components(*src
);
1752 unsigned bit_size
= nir_src_bit_size(*src
);
1753 return bitcast_to_ivec(ctx
, def
, bit_size
, num_components
);
1757 emit_tex(struct ntv_context
*ctx
, nir_tex_instr
*tex
)
1759 assert(tex
->op
== nir_texop_tex
||
1760 tex
->op
== nir_texop_txb
||
1761 tex
->op
== nir_texop_txl
||
1762 tex
->op
== nir_texop_txd
||
1763 tex
->op
== nir_texop_txf
||
1764 tex
->op
== nir_texop_txf_ms
||
1765 tex
->op
== nir_texop_txs
);
1766 assert(tex
->texture_index
== tex
->sampler_index
);
1768 SpvId coord
= 0, proj
= 0, bias
= 0, lod
= 0, dref
= 0, dx
= 0, dy
= 0,
1769 offset
= 0, sample
= 0;
1770 unsigned coord_components
= 0;
1771 for (unsigned i
= 0; i
< tex
->num_srcs
; i
++) {
1772 switch (tex
->src
[i
].src_type
) {
1773 case nir_tex_src_coord
:
1774 if (tex
->op
== nir_texop_txf
||
1775 tex
->op
== nir_texop_txf_ms
)
1776 coord
= get_src_int(ctx
, &tex
->src
[i
].src
);
1778 coord
= get_src_float(ctx
, &tex
->src
[i
].src
);
1779 coord_components
= nir_src_num_components(tex
->src
[i
].src
);
1782 case nir_tex_src_projector
:
1783 assert(nir_src_num_components(tex
->src
[i
].src
) == 1);
1784 proj
= get_src_float(ctx
, &tex
->src
[i
].src
);
1788 case nir_tex_src_offset
:
1789 offset
= get_src_int(ctx
, &tex
->src
[i
].src
);
1792 case nir_tex_src_bias
:
1793 assert(tex
->op
== nir_texop_txb
);
1794 bias
= get_src_float(ctx
, &tex
->src
[i
].src
);
1798 case nir_tex_src_lod
:
1799 assert(nir_src_num_components(tex
->src
[i
].src
) == 1);
1800 if (tex
->op
== nir_texop_txf
||
1801 tex
->op
== nir_texop_txf_ms
||
1802 tex
->op
== nir_texop_txs
)
1803 lod
= get_src_int(ctx
, &tex
->src
[i
].src
);
1805 lod
= get_src_float(ctx
, &tex
->src
[i
].src
);
1809 case nir_tex_src_ms_index
:
1810 assert(nir_src_num_components(tex
->src
[i
].src
) == 1);
1811 sample
= get_src_int(ctx
, &tex
->src
[i
].src
);
1814 case nir_tex_src_comparator
:
1815 assert(nir_src_num_components(tex
->src
[i
].src
) == 1);
1816 dref
= get_src_float(ctx
, &tex
->src
[i
].src
);
1820 case nir_tex_src_ddx
:
1821 dx
= get_src_float(ctx
, &tex
->src
[i
].src
);
1825 case nir_tex_src_ddy
:
1826 dy
= get_src_float(ctx
, &tex
->src
[i
].src
);
1831 fprintf(stderr
, "texture source: %d\n", tex
->src
[i
].src_type
);
1832 unreachable("unknown texture source");
1836 if (lod
== 0 && ctx
->stage
!= MESA_SHADER_FRAGMENT
) {
1837 lod
= emit_float_const(ctx
, 32, 0.0f
);
1841 SpvId image_type
= ctx
->image_types
[tex
->texture_index
];
1842 SpvId sampled_type
= spirv_builder_type_sampled_image(&ctx
->builder
,
1845 assert(ctx
->samplers_used
& (1u << tex
->texture_index
));
1846 SpvId load
= spirv_builder_emit_load(&ctx
->builder
, sampled_type
,
1847 ctx
->samplers
[tex
->texture_index
]);
1849 SpvId dest_type
= get_dest_type(ctx
, &tex
->dest
, tex
->dest_type
);
1851 if (tex
->op
== nir_texop_txs
) {
1852 SpvId image
= spirv_builder_emit_image(&ctx
->builder
, image_type
, load
);
1853 SpvId result
= spirv_builder_emit_image_query_size(&ctx
->builder
,
1856 store_dest(ctx
, &tex
->dest
, result
, tex
->dest_type
);
1860 if (proj
&& coord_components
> 0) {
1861 SpvId constituents
[coord_components
+ 1];
1862 if (coord_components
== 1)
1863 constituents
[0] = coord
;
1865 assert(coord_components
> 1);
1866 SpvId float_type
= spirv_builder_type_float(&ctx
->builder
, 32);
1867 for (uint32_t i
= 0; i
< coord_components
; ++i
)
1868 constituents
[i
] = spirv_builder_emit_composite_extract(&ctx
->builder
,
1874 constituents
[coord_components
++] = proj
;
1876 SpvId vec_type
= get_fvec_type(ctx
, 32, coord_components
);
1877 coord
= spirv_builder_emit_composite_construct(&ctx
->builder
,
1883 SpvId actual_dest_type
= dest_type
;
1885 actual_dest_type
= spirv_builder_type_float(&ctx
->builder
, 32);
1888 if (tex
->op
== nir_texop_txf
||
1889 tex
->op
== nir_texop_txf_ms
) {
1890 SpvId image
= spirv_builder_emit_image(&ctx
->builder
, image_type
, load
);
1891 result
= spirv_builder_emit_image_fetch(&ctx
->builder
, dest_type
,
1892 image
, coord
, lod
, sample
);
1894 result
= spirv_builder_emit_image_sample(&ctx
->builder
,
1895 actual_dest_type
, load
,
1898 lod
, bias
, dref
, dx
, dy
,
1902 spirv_builder_emit_decoration(&ctx
->builder
, result
,
1903 SpvDecorationRelaxedPrecision
);
1905 if (dref
&& nir_dest_num_components(tex
->dest
) > 1) {
1906 SpvId components
[4] = { result
, result
, result
, result
};
1907 result
= spirv_builder_emit_composite_construct(&ctx
->builder
,
1913 store_dest(ctx
, &tex
->dest
, result
, tex
->dest_type
);
1917 start_block(struct ntv_context
*ctx
, SpvId label
)
1919 /* terminate previous block if needed */
1920 if (ctx
->block_started
)
1921 spirv_builder_emit_branch(&ctx
->builder
, label
);
1923 /* start new block */
1924 spirv_builder_label(&ctx
->builder
, label
);
1925 ctx
->block_started
= true;
1929 branch(struct ntv_context
*ctx
, SpvId label
)
1931 assert(ctx
->block_started
);
1932 spirv_builder_emit_branch(&ctx
->builder
, label
);
1933 ctx
->block_started
= false;
1937 branch_conditional(struct ntv_context
*ctx
, SpvId condition
, SpvId then_id
,
1940 assert(ctx
->block_started
);
1941 spirv_builder_emit_branch_conditional(&ctx
->builder
, condition
,
1943 ctx
->block_started
= false;
1947 emit_jump(struct ntv_context
*ctx
, nir_jump_instr
*jump
)
1949 switch (jump
->type
) {
1950 case nir_jump_break
:
1951 assert(ctx
->loop_break
);
1952 branch(ctx
, ctx
->loop_break
);
1955 case nir_jump_continue
:
1956 assert(ctx
->loop_cont
);
1957 branch(ctx
, ctx
->loop_cont
);
1961 unreachable("Unsupported jump type\n");
1966 emit_deref_var(struct ntv_context
*ctx
, nir_deref_instr
*deref
)
1968 assert(deref
->deref_type
== nir_deref_type_var
);
1970 struct hash_entry
*he
= _mesa_hash_table_search(ctx
->vars
, deref
->var
);
1972 SpvId result
= (SpvId
)(intptr_t)he
->data
;
1973 store_dest_raw(ctx
, &deref
->dest
, result
);
1977 emit_deref_array(struct ntv_context
*ctx
, nir_deref_instr
*deref
)
1979 assert(deref
->deref_type
== nir_deref_type_array
);
1980 nir_variable
*var
= nir_deref_instr_get_variable(deref
);
1982 SpvStorageClass storage_class
;
1983 switch (var
->data
.mode
) {
1984 case nir_var_shader_in
:
1985 storage_class
= SpvStorageClassInput
;
1988 case nir_var_shader_out
:
1989 storage_class
= SpvStorageClassOutput
;
1993 unreachable("Unsupported nir_variable_mode\n");
1996 SpvId index
= get_src(ctx
, &deref
->arr
.index
);
1998 SpvId ptr_type
= spirv_builder_type_pointer(&ctx
->builder
,
2000 get_glsl_type(ctx
, deref
->type
));
2002 SpvId result
= spirv_builder_emit_access_chain(&ctx
->builder
,
2004 get_src(ctx
, &deref
->parent
),
2006 /* uint is a bit of a lie here, it's really just an opaque type */
2007 store_dest(ctx
, &deref
->dest
, result
, nir_type_uint
);
2011 emit_deref(struct ntv_context
*ctx
, nir_deref_instr
*deref
)
2013 switch (deref
->deref_type
) {
2014 case nir_deref_type_var
:
2015 emit_deref_var(ctx
, deref
);
2018 case nir_deref_type_array
:
2019 emit_deref_array(ctx
, deref
);
2023 unreachable("unexpected deref_type");
2028 emit_block(struct ntv_context
*ctx
, struct nir_block
*block
)
2030 start_block(ctx
, block_label(ctx
, block
));
2031 nir_foreach_instr(instr
, block
) {
2032 switch (instr
->type
) {
2033 case nir_instr_type_alu
:
2034 emit_alu(ctx
, nir_instr_as_alu(instr
));
2036 case nir_instr_type_intrinsic
:
2037 emit_intrinsic(ctx
, nir_instr_as_intrinsic(instr
));
2039 case nir_instr_type_load_const
:
2040 emit_load_const(ctx
, nir_instr_as_load_const(instr
));
2042 case nir_instr_type_ssa_undef
:
2043 emit_undef(ctx
, nir_instr_as_ssa_undef(instr
));
2045 case nir_instr_type_tex
:
2046 emit_tex(ctx
, nir_instr_as_tex(instr
));
2048 case nir_instr_type_phi
:
2049 unreachable("nir_instr_type_phi not supported");
2051 case nir_instr_type_jump
:
2052 emit_jump(ctx
, nir_instr_as_jump(instr
));
2054 case nir_instr_type_call
:
2055 unreachable("nir_instr_type_call not supported");
2057 case nir_instr_type_parallel_copy
:
2058 unreachable("nir_instr_type_parallel_copy not supported");
2060 case nir_instr_type_deref
:
2061 emit_deref(ctx
, nir_instr_as_deref(instr
));
2068 emit_cf_list(struct ntv_context
*ctx
, struct exec_list
*list
);
2071 get_src_bool(struct ntv_context
*ctx
, nir_src
*src
)
2073 assert(nir_src_bit_size(*src
) == 1);
2074 return get_src(ctx
, src
);
2078 emit_if(struct ntv_context
*ctx
, nir_if
*if_stmt
)
2080 SpvId condition
= get_src_bool(ctx
, &if_stmt
->condition
);
2082 SpvId header_id
= spirv_builder_new_id(&ctx
->builder
);
2083 SpvId then_id
= block_label(ctx
, nir_if_first_then_block(if_stmt
));
2084 SpvId endif_id
= spirv_builder_new_id(&ctx
->builder
);
2085 SpvId else_id
= endif_id
;
2087 bool has_else
= !exec_list_is_empty(&if_stmt
->else_list
);
2089 assert(nir_if_first_else_block(if_stmt
)->index
< ctx
->num_blocks
);
2090 else_id
= block_label(ctx
, nir_if_first_else_block(if_stmt
));
2093 /* create a header-block */
2094 start_block(ctx
, header_id
);
2095 spirv_builder_emit_selection_merge(&ctx
->builder
, endif_id
,
2096 SpvSelectionControlMaskNone
);
2097 branch_conditional(ctx
, condition
, then_id
, else_id
);
2099 emit_cf_list(ctx
, &if_stmt
->then_list
);
2102 if (ctx
->block_started
)
2103 branch(ctx
, endif_id
);
2105 emit_cf_list(ctx
, &if_stmt
->else_list
);
2108 start_block(ctx
, endif_id
);
2112 emit_loop(struct ntv_context
*ctx
, nir_loop
*loop
)
2114 SpvId header_id
= spirv_builder_new_id(&ctx
->builder
);
2115 SpvId begin_id
= block_label(ctx
, nir_loop_first_block(loop
));
2116 SpvId break_id
= spirv_builder_new_id(&ctx
->builder
);
2117 SpvId cont_id
= spirv_builder_new_id(&ctx
->builder
);
2119 /* create a header-block */
2120 start_block(ctx
, header_id
);
2121 spirv_builder_loop_merge(&ctx
->builder
, break_id
, cont_id
, SpvLoopControlMaskNone
);
2122 branch(ctx
, begin_id
);
2124 SpvId save_break
= ctx
->loop_break
;
2125 SpvId save_cont
= ctx
->loop_cont
;
2126 ctx
->loop_break
= break_id
;
2127 ctx
->loop_cont
= cont_id
;
2129 emit_cf_list(ctx
, &loop
->body
);
2131 ctx
->loop_break
= save_break
;
2132 ctx
->loop_cont
= save_cont
;
2134 /* loop->body may have already ended our block */
2135 if (ctx
->block_started
)
2136 branch(ctx
, cont_id
);
2137 start_block(ctx
, cont_id
);
2138 branch(ctx
, header_id
);
2140 start_block(ctx
, break_id
);
2144 emit_cf_list(struct ntv_context
*ctx
, struct exec_list
*list
)
2146 foreach_list_typed(nir_cf_node
, node
, node
, list
) {
2147 switch (node
->type
) {
2148 case nir_cf_node_block
:
2149 emit_block(ctx
, nir_cf_node_as_block(node
));
2152 case nir_cf_node_if
:
2153 emit_if(ctx
, nir_cf_node_as_if(node
));
2156 case nir_cf_node_loop
:
2157 emit_loop(ctx
, nir_cf_node_as_loop(node
));
2160 case nir_cf_node_function
:
2161 unreachable("nir_cf_node_function not supported");
2167 struct spirv_shader
*
2168 nir_to_spirv(struct nir_shader
*s
, const struct pipe_stream_output_info
*so_info
, struct pipe_stream_output_info
*local_so_info
)
2170 struct spirv_shader
*ret
= NULL
;
2172 struct ntv_context ctx
= {};
2173 ctx
.mem_ctx
= ralloc_context(NULL
);
2174 ctx
.builder
.mem_ctx
= ctx
.mem_ctx
;
2176 switch (s
->info
.stage
) {
2177 case MESA_SHADER_VERTEX
:
2178 case MESA_SHADER_FRAGMENT
:
2179 case MESA_SHADER_COMPUTE
:
2180 spirv_builder_emit_cap(&ctx
.builder
, SpvCapabilityShader
);
2183 case MESA_SHADER_TESS_CTRL
:
2184 case MESA_SHADER_TESS_EVAL
:
2185 spirv_builder_emit_cap(&ctx
.builder
, SpvCapabilityTessellation
);
2188 case MESA_SHADER_GEOMETRY
:
2189 spirv_builder_emit_cap(&ctx
.builder
, SpvCapabilityGeometry
);
2193 unreachable("invalid stage");
2196 // TODO: only enable when needed
2197 if (s
->info
.stage
== MESA_SHADER_FRAGMENT
) {
2198 spirv_builder_emit_cap(&ctx
.builder
, SpvCapabilitySampled1D
);
2199 spirv_builder_emit_cap(&ctx
.builder
, SpvCapabilityImageQuery
);
2200 spirv_builder_emit_cap(&ctx
.builder
, SpvCapabilityDerivativeControl
);
2203 ctx
.stage
= s
->info
.stage
;
2204 ctx
.GLSL_std_450
= spirv_builder_import(&ctx
.builder
, "GLSL.std.450");
2205 spirv_builder_emit_source(&ctx
.builder
, SpvSourceLanguageGLSL
, 450);
2207 spirv_builder_emit_mem_model(&ctx
.builder
, SpvAddressingModelLogical
,
2208 SpvMemoryModelGLSL450
);
2210 SpvExecutionModel exec_model
;
2211 switch (s
->info
.stage
) {
2212 case MESA_SHADER_VERTEX
:
2213 exec_model
= SpvExecutionModelVertex
;
2215 case MESA_SHADER_TESS_CTRL
:
2216 exec_model
= SpvExecutionModelTessellationControl
;
2218 case MESA_SHADER_TESS_EVAL
:
2219 exec_model
= SpvExecutionModelTessellationEvaluation
;
2221 case MESA_SHADER_GEOMETRY
:
2222 exec_model
= SpvExecutionModelGeometry
;
2224 case MESA_SHADER_FRAGMENT
:
2225 exec_model
= SpvExecutionModelFragment
;
2227 case MESA_SHADER_COMPUTE
:
2228 exec_model
= SpvExecutionModelGLCompute
;
2231 unreachable("invalid stage");
2234 SpvId type_void
= spirv_builder_type_void(&ctx
.builder
);
2235 SpvId type_main
= spirv_builder_type_function(&ctx
.builder
, type_void
,
2237 SpvId entry_point
= spirv_builder_new_id(&ctx
.builder
);
2238 spirv_builder_emit_name(&ctx
.builder
, entry_point
, "main");
2240 ctx
.vars
= _mesa_hash_table_create(ctx
.mem_ctx
, _mesa_hash_pointer
,
2241 _mesa_key_pointer_equal
);
2243 ctx
.so_outputs
= _mesa_hash_table_create(ctx
.mem_ctx
, _mesa_hash_u32
,
2244 _mesa_key_u32_equal
);
2246 nir_foreach_variable(var
, &s
->inputs
)
2247 emit_input(&ctx
, var
);
2249 nir_foreach_variable(var
, &s
->outputs
)
2250 emit_output(&ctx
, var
);
2253 emit_so_info(&ctx
, util_last_bit64(s
->info
.outputs_written
), so_info
, local_so_info
);
2254 nir_foreach_variable(var
, &s
->uniforms
)
2255 emit_uniform(&ctx
, var
);
2257 if (s
->info
.stage
== MESA_SHADER_FRAGMENT
) {
2258 spirv_builder_emit_exec_mode(&ctx
.builder
, entry_point
,
2259 SpvExecutionModeOriginUpperLeft
);
2260 if (s
->info
.outputs_written
& BITFIELD64_BIT(FRAG_RESULT_DEPTH
))
2261 spirv_builder_emit_exec_mode(&ctx
.builder
, entry_point
,
2262 SpvExecutionModeDepthReplacing
);
2265 if (so_info
&& so_info
->num_outputs
) {
2266 spirv_builder_emit_cap(&ctx
.builder
, SpvCapabilityTransformFeedback
);
2267 spirv_builder_emit_exec_mode(&ctx
.builder
, entry_point
,
2268 SpvExecutionModeXfb
);
2271 spirv_builder_function(&ctx
.builder
, entry_point
, type_void
,
2272 SpvFunctionControlMaskNone
,
2275 nir_function_impl
*entry
= nir_shader_get_entrypoint(s
);
2276 nir_metadata_require(entry
, nir_metadata_block_index
);
2278 ctx
.defs
= ralloc_array_size(ctx
.mem_ctx
,
2279 sizeof(SpvId
), entry
->ssa_alloc
);
2282 ctx
.num_defs
= entry
->ssa_alloc
;
2284 nir_index_local_regs(entry
);
2285 ctx
.regs
= ralloc_array_size(ctx
.mem_ctx
,
2286 sizeof(SpvId
), entry
->reg_alloc
);
2289 ctx
.num_regs
= entry
->reg_alloc
;
2291 SpvId
*block_ids
= ralloc_array_size(ctx
.mem_ctx
,
2292 sizeof(SpvId
), entry
->num_blocks
);
2296 for (int i
= 0; i
< entry
->num_blocks
; ++i
)
2297 block_ids
[i
] = spirv_builder_new_id(&ctx
.builder
);
2299 ctx
.block_ids
= block_ids
;
2300 ctx
.num_blocks
= entry
->num_blocks
;
2302 /* emit a block only for the variable declarations */
2303 start_block(&ctx
, spirv_builder_new_id(&ctx
.builder
));
2304 foreach_list_typed(nir_register
, reg
, node
, &entry
->registers
) {
2305 SpvId type
= get_uvec_type(&ctx
, reg
->bit_size
, reg
->num_components
);
2306 SpvId pointer_type
= spirv_builder_type_pointer(&ctx
.builder
,
2307 SpvStorageClassFunction
,
2309 SpvId var
= spirv_builder_emit_var(&ctx
.builder
, pointer_type
,
2310 SpvStorageClassFunction
);
2312 ctx
.regs
[reg
->index
] = var
;
2315 emit_cf_list(&ctx
, &entry
->body
);
2318 emit_so_outputs(&ctx
, so_info
, local_so_info
);
2320 spirv_builder_return(&ctx
.builder
); // doesn't belong here, but whatevz
2321 spirv_builder_function_end(&ctx
.builder
);
2323 spirv_builder_emit_entry_point(&ctx
.builder
, exec_model
, entry_point
,
2324 "main", ctx
.entry_ifaces
,
2325 ctx
.num_entry_ifaces
);
2327 size_t num_words
= spirv_builder_get_num_words(&ctx
.builder
);
2329 ret
= CALLOC_STRUCT(spirv_shader
);
2333 ret
->words
= MALLOC(sizeof(uint32_t) * num_words
);
2337 ret
->num_words
= spirv_builder_get_words(&ctx
.builder
, ret
->words
, num_words
);
2338 assert(ret
->num_words
== num_words
);
2340 ralloc_free(ctx
.mem_ctx
);
2345 ralloc_free(ctx
.mem_ctx
);
2348 spirv_shader_delete(ret
);
2354 spirv_shader_delete(struct spirv_shader
*s
)