2 * Copyright 2014 Advanced Micro Devices, Inc.
4 * Permission is hereby granted, free of charge, to any person obtaining a
5 * copy of this software and associated documentation files (the
6 * "Software"), to deal in the Software without restriction, including
7 * without limitation the rights to use, copy, modify, merge, publish,
8 * distribute, sub license, and/or sell copies of the Software, and to
9 * permit persons to whom the Software is furnished to do so, subject to
10 * the following conditions:
12 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
13 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
14 * FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL
15 * THE COPYRIGHT HOLDERS, AUTHORS AND/OR ITS SUPPLIERS BE LIABLE FOR ANY CLAIM,
16 * DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR
17 * OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE
18 * USE OR OTHER DEALINGS IN THE SOFTWARE.
20 * The above copyright notice and this permission notice (including the
21 * next paragraph) shall be included in all copies or substantial portions
25 /* based on pieces from si_pipe.c and radeon_llvm_emit.c */
26 #include "ac_llvm_build.h"
28 #include <llvm-c/Core.h>
29 #include <llvm/Config/llvm-config.h>
31 #include "c11/threads.h"
36 #include "ac_llvm_util.h"
37 #include "ac_shader_util.h"
38 #include "ac_exp_param.h"
39 #include "util/bitscan.h"
40 #include "util/macros.h"
41 #include "util/u_atomic.h"
42 #include "util/u_math.h"
45 #include "shader_enums.h"
47 #define AC_LLVM_INITIAL_CF_DEPTH 4
49 /* Data for if/else/endif and bgnloop/endloop control flow structures.
52 /* Loop exit or next part of if/else/endif. */
53 LLVMBasicBlockRef next_block
;
54 LLVMBasicBlockRef loop_entry_block
;
57 /* Initialize module-independent parts of the context.
59 * The caller is responsible for initializing ctx::module and ctx::builder.
62 ac_llvm_context_init(struct ac_llvm_context
*ctx
,
63 struct ac_llvm_compiler
*compiler
,
64 enum chip_class chip_class
, enum radeon_family family
,
65 enum ac_float_mode float_mode
, unsigned wave_size
,
66 unsigned ballot_mask_bits
)
68 ctx
->context
= LLVMContextCreate();
70 ctx
->chip_class
= chip_class
;
72 ctx
->wave_size
= wave_size
;
73 ctx
->ballot_mask_bits
= ballot_mask_bits
;
74 ctx
->float_mode
= float_mode
;
75 ctx
->module
= ac_create_module(wave_size
== 32 ? compiler
->tm_wave32
78 ctx
->builder
= ac_create_builder(ctx
->context
, float_mode
);
80 ctx
->voidt
= LLVMVoidTypeInContext(ctx
->context
);
81 ctx
->i1
= LLVMInt1TypeInContext(ctx
->context
);
82 ctx
->i8
= LLVMInt8TypeInContext(ctx
->context
);
83 ctx
->i16
= LLVMIntTypeInContext(ctx
->context
, 16);
84 ctx
->i32
= LLVMIntTypeInContext(ctx
->context
, 32);
85 ctx
->i64
= LLVMIntTypeInContext(ctx
->context
, 64);
86 ctx
->i128
= LLVMIntTypeInContext(ctx
->context
, 128);
87 ctx
->intptr
= ctx
->i32
;
88 ctx
->f16
= LLVMHalfTypeInContext(ctx
->context
);
89 ctx
->f32
= LLVMFloatTypeInContext(ctx
->context
);
90 ctx
->f64
= LLVMDoubleTypeInContext(ctx
->context
);
91 ctx
->v2i16
= LLVMVectorType(ctx
->i16
, 2);
92 ctx
->v4i16
= LLVMVectorType(ctx
->i16
, 4);
93 ctx
->v2f16
= LLVMVectorType(ctx
->f16
, 2);
94 ctx
->v4f16
= LLVMVectorType(ctx
->f16
, 4);
95 ctx
->v2i32
= LLVMVectorType(ctx
->i32
, 2);
96 ctx
->v3i32
= LLVMVectorType(ctx
->i32
, 3);
97 ctx
->v4i32
= LLVMVectorType(ctx
->i32
, 4);
98 ctx
->v2f32
= LLVMVectorType(ctx
->f32
, 2);
99 ctx
->v3f32
= LLVMVectorType(ctx
->f32
, 3);
100 ctx
->v4f32
= LLVMVectorType(ctx
->f32
, 4);
101 ctx
->v8i32
= LLVMVectorType(ctx
->i32
, 8);
102 ctx
->iN_wavemask
= LLVMIntTypeInContext(ctx
->context
, ctx
->wave_size
);
103 ctx
->iN_ballotmask
= LLVMIntTypeInContext(ctx
->context
, ballot_mask_bits
);
105 ctx
->i8_0
= LLVMConstInt(ctx
->i8
, 0, false);
106 ctx
->i8_1
= LLVMConstInt(ctx
->i8
, 1, false);
107 ctx
->i16_0
= LLVMConstInt(ctx
->i16
, 0, false);
108 ctx
->i16_1
= LLVMConstInt(ctx
->i16
, 1, false);
109 ctx
->i32_0
= LLVMConstInt(ctx
->i32
, 0, false);
110 ctx
->i32_1
= LLVMConstInt(ctx
->i32
, 1, false);
111 ctx
->i64_0
= LLVMConstInt(ctx
->i64
, 0, false);
112 ctx
->i64_1
= LLVMConstInt(ctx
->i64
, 1, false);
113 ctx
->i128_0
= LLVMConstInt(ctx
->i128
, 0, false);
114 ctx
->i128_1
= LLVMConstInt(ctx
->i128
, 1, false);
115 ctx
->f16_0
= LLVMConstReal(ctx
->f16
, 0.0);
116 ctx
->f16_1
= LLVMConstReal(ctx
->f16
, 1.0);
117 ctx
->f32_0
= LLVMConstReal(ctx
->f32
, 0.0);
118 ctx
->f32_1
= LLVMConstReal(ctx
->f32
, 1.0);
119 ctx
->f64_0
= LLVMConstReal(ctx
->f64
, 0.0);
120 ctx
->f64_1
= LLVMConstReal(ctx
->f64
, 1.0);
122 ctx
->i1false
= LLVMConstInt(ctx
->i1
, 0, false);
123 ctx
->i1true
= LLVMConstInt(ctx
->i1
, 1, false);
125 ctx
->range_md_kind
= LLVMGetMDKindIDInContext(ctx
->context
,
128 ctx
->invariant_load_md_kind
= LLVMGetMDKindIDInContext(ctx
->context
,
129 "invariant.load", 14);
131 ctx
->uniform_md_kind
= LLVMGetMDKindIDInContext(ctx
->context
,
132 "amdgpu.uniform", 14);
134 ctx
->empty_md
= LLVMMDNodeInContext(ctx
->context
, NULL
, 0);
135 ctx
->flow
= calloc(1, sizeof(*ctx
->flow
));
139 ac_llvm_context_dispose(struct ac_llvm_context
*ctx
)
141 free(ctx
->flow
->stack
);
147 ac_get_llvm_num_components(LLVMValueRef value
)
149 LLVMTypeRef type
= LLVMTypeOf(value
);
150 unsigned num_components
= LLVMGetTypeKind(type
) == LLVMVectorTypeKind
151 ? LLVMGetVectorSize(type
)
153 return num_components
;
157 ac_llvm_extract_elem(struct ac_llvm_context
*ac
,
161 if (LLVMGetTypeKind(LLVMTypeOf(value
)) != LLVMVectorTypeKind
) {
166 return LLVMBuildExtractElement(ac
->builder
, value
,
167 LLVMConstInt(ac
->i32
, index
, false), "");
171 ac_get_elem_bits(struct ac_llvm_context
*ctx
, LLVMTypeRef type
)
173 if (LLVMGetTypeKind(type
) == LLVMVectorTypeKind
)
174 type
= LLVMGetElementType(type
);
176 if (LLVMGetTypeKind(type
) == LLVMIntegerTypeKind
)
177 return LLVMGetIntTypeWidth(type
);
179 if (LLVMGetTypeKind(type
) == LLVMPointerTypeKind
) {
180 if (LLVMGetPointerAddressSpace(type
) == AC_ADDR_SPACE_LDS
)
184 if (type
== ctx
->f16
)
186 if (type
== ctx
->f32
)
188 if (type
== ctx
->f64
)
191 unreachable("Unhandled type kind in get_elem_bits");
195 ac_get_type_size(LLVMTypeRef type
)
197 LLVMTypeKind kind
= LLVMGetTypeKind(type
);
200 case LLVMIntegerTypeKind
:
201 return LLVMGetIntTypeWidth(type
) / 8;
202 case LLVMHalfTypeKind
:
204 case LLVMFloatTypeKind
:
206 case LLVMDoubleTypeKind
:
208 case LLVMPointerTypeKind
:
209 if (LLVMGetPointerAddressSpace(type
) == AC_ADDR_SPACE_CONST_32BIT
)
212 case LLVMVectorTypeKind
:
213 return LLVMGetVectorSize(type
) *
214 ac_get_type_size(LLVMGetElementType(type
));
215 case LLVMArrayTypeKind
:
216 return LLVMGetArrayLength(type
) *
217 ac_get_type_size(LLVMGetElementType(type
));
224 static LLVMTypeRef
to_integer_type_scalar(struct ac_llvm_context
*ctx
, LLVMTypeRef t
)
228 else if (t
== ctx
->f16
|| t
== ctx
->i16
)
230 else if (t
== ctx
->f32
|| t
== ctx
->i32
)
232 else if (t
== ctx
->f64
|| t
== ctx
->i64
)
235 unreachable("Unhandled integer size");
239 ac_to_integer_type(struct ac_llvm_context
*ctx
, LLVMTypeRef t
)
241 if (LLVMGetTypeKind(t
) == LLVMVectorTypeKind
) {
242 LLVMTypeRef elem_type
= LLVMGetElementType(t
);
243 return LLVMVectorType(to_integer_type_scalar(ctx
, elem_type
),
244 LLVMGetVectorSize(t
));
246 if (LLVMGetTypeKind(t
) == LLVMPointerTypeKind
) {
247 switch (LLVMGetPointerAddressSpace(t
)) {
248 case AC_ADDR_SPACE_GLOBAL
:
250 case AC_ADDR_SPACE_CONST_32BIT
:
251 case AC_ADDR_SPACE_LDS
:
254 unreachable("unhandled address space");
257 return to_integer_type_scalar(ctx
, t
);
261 ac_to_integer(struct ac_llvm_context
*ctx
, LLVMValueRef v
)
263 LLVMTypeRef type
= LLVMTypeOf(v
);
264 if (LLVMGetTypeKind(type
) == LLVMPointerTypeKind
) {
265 return LLVMBuildPtrToInt(ctx
->builder
, v
, ac_to_integer_type(ctx
, type
), "");
267 return LLVMBuildBitCast(ctx
->builder
, v
, ac_to_integer_type(ctx
, type
), "");
271 ac_to_integer_or_pointer(struct ac_llvm_context
*ctx
, LLVMValueRef v
)
273 LLVMTypeRef type
= LLVMTypeOf(v
);
274 if (LLVMGetTypeKind(type
) == LLVMPointerTypeKind
)
276 return ac_to_integer(ctx
, v
);
279 static LLVMTypeRef
to_float_type_scalar(struct ac_llvm_context
*ctx
, LLVMTypeRef t
)
283 else if (t
== ctx
->i16
|| t
== ctx
->f16
)
285 else if (t
== ctx
->i32
|| t
== ctx
->f32
)
287 else if (t
== ctx
->i64
|| t
== ctx
->f64
)
290 unreachable("Unhandled float size");
294 ac_to_float_type(struct ac_llvm_context
*ctx
, LLVMTypeRef t
)
296 if (LLVMGetTypeKind(t
) == LLVMVectorTypeKind
) {
297 LLVMTypeRef elem_type
= LLVMGetElementType(t
);
298 return LLVMVectorType(to_float_type_scalar(ctx
, elem_type
),
299 LLVMGetVectorSize(t
));
301 return to_float_type_scalar(ctx
, t
);
305 ac_to_float(struct ac_llvm_context
*ctx
, LLVMValueRef v
)
307 LLVMTypeRef type
= LLVMTypeOf(v
);
308 return LLVMBuildBitCast(ctx
->builder
, v
, ac_to_float_type(ctx
, type
), "");
313 ac_build_intrinsic(struct ac_llvm_context
*ctx
, const char *name
,
314 LLVMTypeRef return_type
, LLVMValueRef
*params
,
315 unsigned param_count
, unsigned attrib_mask
)
317 LLVMValueRef function
, call
;
318 bool set_callsite_attrs
= !(attrib_mask
& AC_FUNC_ATTR_LEGACY
);
320 function
= LLVMGetNamedFunction(ctx
->module
, name
);
322 LLVMTypeRef param_types
[32], function_type
;
325 assert(param_count
<= 32);
327 for (i
= 0; i
< param_count
; ++i
) {
329 param_types
[i
] = LLVMTypeOf(params
[i
]);
332 LLVMFunctionType(return_type
, param_types
, param_count
, 0);
333 function
= LLVMAddFunction(ctx
->module
, name
, function_type
);
335 LLVMSetFunctionCallConv(function
, LLVMCCallConv
);
336 LLVMSetLinkage(function
, LLVMExternalLinkage
);
338 if (!set_callsite_attrs
)
339 ac_add_func_attributes(ctx
->context
, function
, attrib_mask
);
342 call
= LLVMBuildCall(ctx
->builder
, function
, params
, param_count
, "");
343 if (set_callsite_attrs
)
344 ac_add_func_attributes(ctx
->context
, call
, attrib_mask
);
349 * Given the i32 or vNi32 \p type, generate the textual name (e.g. for use with
352 void ac_build_type_name_for_intr(LLVMTypeRef type
, char *buf
, unsigned bufsize
)
354 LLVMTypeRef elem_type
= type
;
356 assert(bufsize
>= 8);
358 if (LLVMGetTypeKind(type
) == LLVMVectorTypeKind
) {
359 int ret
= snprintf(buf
, bufsize
, "v%u",
360 LLVMGetVectorSize(type
));
362 char *type_name
= LLVMPrintTypeToString(type
);
363 fprintf(stderr
, "Error building type name for: %s\n",
365 LLVMDisposeMessage(type_name
);
368 elem_type
= LLVMGetElementType(type
);
372 switch (LLVMGetTypeKind(elem_type
)) {
374 case LLVMIntegerTypeKind
:
375 snprintf(buf
, bufsize
, "i%d", LLVMGetIntTypeWidth(elem_type
));
377 case LLVMHalfTypeKind
:
378 snprintf(buf
, bufsize
, "f16");
380 case LLVMFloatTypeKind
:
381 snprintf(buf
, bufsize
, "f32");
383 case LLVMDoubleTypeKind
:
384 snprintf(buf
, bufsize
, "f64");
390 * Helper function that builds an LLVM IR PHI node and immediately adds
394 ac_build_phi(struct ac_llvm_context
*ctx
, LLVMTypeRef type
,
395 unsigned count_incoming
, LLVMValueRef
*values
,
396 LLVMBasicBlockRef
*blocks
)
398 LLVMValueRef phi
= LLVMBuildPhi(ctx
->builder
, type
, "");
399 LLVMAddIncoming(phi
, values
, blocks
, count_incoming
);
403 void ac_build_s_barrier(struct ac_llvm_context
*ctx
)
405 ac_build_intrinsic(ctx
, "llvm.amdgcn.s.barrier", ctx
->voidt
, NULL
,
406 0, AC_FUNC_ATTR_CONVERGENT
);
409 /* Prevent optimizations (at least of memory accesses) across the current
410 * point in the program by emitting empty inline assembly that is marked as
411 * having side effects.
413 * Optionally, a value can be passed through the inline assembly to prevent
414 * LLVM from hoisting calls to ReadNone functions.
417 ac_build_optimization_barrier(struct ac_llvm_context
*ctx
,
420 static int counter
= 0;
422 LLVMBuilderRef builder
= ctx
->builder
;
425 snprintf(code
, sizeof(code
), "; %d", p_atomic_inc_return(&counter
));
428 LLVMTypeRef ftype
= LLVMFunctionType(ctx
->voidt
, NULL
, 0, false);
429 LLVMValueRef inlineasm
= LLVMConstInlineAsm(ftype
, code
, "", true, false);
430 LLVMBuildCall(builder
, inlineasm
, NULL
, 0, "");
432 LLVMTypeRef ftype
= LLVMFunctionType(ctx
->i32
, &ctx
->i32
, 1, false);
433 LLVMValueRef inlineasm
= LLVMConstInlineAsm(ftype
, code
, "=v,0", true, false);
434 LLVMTypeRef type
= LLVMTypeOf(*pvgpr
);
435 unsigned bitsize
= ac_get_elem_bits(ctx
, type
);
436 LLVMValueRef vgpr
= *pvgpr
;
437 LLVMTypeRef vgpr_type
;
442 vgpr
= LLVMBuildZExt(ctx
->builder
, vgpr
, ctx
->i32
, "");
444 vgpr_type
= LLVMTypeOf(vgpr
);
445 vgpr_size
= ac_get_type_size(vgpr_type
);
447 assert(vgpr_size
% 4 == 0);
449 vgpr
= LLVMBuildBitCast(builder
, vgpr
, LLVMVectorType(ctx
->i32
, vgpr_size
/ 4), "");
450 vgpr0
= LLVMBuildExtractElement(builder
, vgpr
, ctx
->i32_0
, "");
451 vgpr0
= LLVMBuildCall(builder
, inlineasm
, &vgpr0
, 1, "");
452 vgpr
= LLVMBuildInsertElement(builder
, vgpr
, vgpr0
, ctx
->i32_0
, "");
453 vgpr
= LLVMBuildBitCast(builder
, vgpr
, vgpr_type
, "");
456 vgpr
= LLVMBuildTrunc(builder
, vgpr
, type
, "");
463 ac_build_shader_clock(struct ac_llvm_context
*ctx
, nir_scope scope
)
465 const char *name
= scope
== NIR_SCOPE_DEVICE
? "llvm.amdgcn.s.memrealtime" : "llvm.amdgcn.s.memtime";
466 LLVMValueRef tmp
= ac_build_intrinsic(ctx
, name
, ctx
->i64
, NULL
, 0, 0);
467 return LLVMBuildBitCast(ctx
->builder
, tmp
, ctx
->v2i32
, "");
471 ac_build_ballot(struct ac_llvm_context
*ctx
,
476 if (LLVM_VERSION_MAJOR
>= 9) {
477 if (ctx
->wave_size
== 64)
478 name
= "llvm.amdgcn.icmp.i64.i32";
480 name
= "llvm.amdgcn.icmp.i32.i32";
482 name
= "llvm.amdgcn.icmp.i32";
484 LLVMValueRef args
[3] = {
487 LLVMConstInt(ctx
->i32
, LLVMIntNE
, 0)
490 /* We currently have no other way to prevent LLVM from lifting the icmp
491 * calls to a dominating basic block.
493 ac_build_optimization_barrier(ctx
, &args
[0]);
495 args
[0] = ac_to_integer(ctx
, args
[0]);
497 return ac_build_intrinsic(ctx
, name
, ctx
->iN_wavemask
, args
, 3,
498 AC_FUNC_ATTR_NOUNWIND
|
499 AC_FUNC_ATTR_READNONE
|
500 AC_FUNC_ATTR_CONVERGENT
);
503 LLVMValueRef
ac_get_i1_sgpr_mask(struct ac_llvm_context
*ctx
,
508 if (LLVM_VERSION_MAJOR
>= 9) {
509 if (ctx
->wave_size
== 64)
510 name
= "llvm.amdgcn.icmp.i64.i1";
512 name
= "llvm.amdgcn.icmp.i32.i1";
514 name
= "llvm.amdgcn.icmp.i1";
516 LLVMValueRef args
[3] = {
519 LLVMConstInt(ctx
->i32
, LLVMIntNE
, 0),
522 return ac_build_intrinsic(ctx
, name
, ctx
->iN_wavemask
, args
, 3,
523 AC_FUNC_ATTR_NOUNWIND
|
524 AC_FUNC_ATTR_READNONE
|
525 AC_FUNC_ATTR_CONVERGENT
);
529 ac_build_vote_all(struct ac_llvm_context
*ctx
, LLVMValueRef value
)
531 LLVMValueRef active_set
= ac_build_ballot(ctx
, ctx
->i32_1
);
532 LLVMValueRef vote_set
= ac_build_ballot(ctx
, value
);
533 return LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
, vote_set
, active_set
, "");
537 ac_build_vote_any(struct ac_llvm_context
*ctx
, LLVMValueRef value
)
539 LLVMValueRef vote_set
= ac_build_ballot(ctx
, value
);
540 return LLVMBuildICmp(ctx
->builder
, LLVMIntNE
, vote_set
,
541 LLVMConstInt(ctx
->iN_wavemask
, 0, 0), "");
545 ac_build_vote_eq(struct ac_llvm_context
*ctx
, LLVMValueRef value
)
547 LLVMValueRef active_set
= ac_build_ballot(ctx
, ctx
->i32_1
);
548 LLVMValueRef vote_set
= ac_build_ballot(ctx
, value
);
550 LLVMValueRef all
= LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
,
551 vote_set
, active_set
, "");
552 LLVMValueRef none
= LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
,
554 LLVMConstInt(ctx
->iN_wavemask
, 0, 0), "");
555 return LLVMBuildOr(ctx
->builder
, all
, none
, "");
559 ac_build_varying_gather_values(struct ac_llvm_context
*ctx
, LLVMValueRef
*values
,
560 unsigned value_count
, unsigned component
)
562 LLVMValueRef vec
= NULL
;
564 if (value_count
== 1) {
565 return values
[component
];
566 } else if (!value_count
)
567 unreachable("value_count is 0");
569 for (unsigned i
= component
; i
< value_count
+ component
; i
++) {
570 LLVMValueRef value
= values
[i
];
573 vec
= LLVMGetUndef( LLVMVectorType(LLVMTypeOf(value
), value_count
));
574 LLVMValueRef index
= LLVMConstInt(ctx
->i32
, i
- component
, false);
575 vec
= LLVMBuildInsertElement(ctx
->builder
, vec
, value
, index
, "");
581 ac_build_gather_values_extended(struct ac_llvm_context
*ctx
,
582 LLVMValueRef
*values
,
583 unsigned value_count
,
584 unsigned value_stride
,
588 LLVMBuilderRef builder
= ctx
->builder
;
589 LLVMValueRef vec
= NULL
;
592 if (value_count
== 1 && !always_vector
) {
594 return LLVMBuildLoad(builder
, values
[0], "");
596 } else if (!value_count
)
597 unreachable("value_count is 0");
599 for (i
= 0; i
< value_count
; i
++) {
600 LLVMValueRef value
= values
[i
* value_stride
];
602 value
= LLVMBuildLoad(builder
, value
, "");
605 vec
= LLVMGetUndef( LLVMVectorType(LLVMTypeOf(value
), value_count
));
606 LLVMValueRef index
= LLVMConstInt(ctx
->i32
, i
, false);
607 vec
= LLVMBuildInsertElement(builder
, vec
, value
, index
, "");
613 ac_build_gather_values(struct ac_llvm_context
*ctx
,
614 LLVMValueRef
*values
,
615 unsigned value_count
)
617 return ac_build_gather_values_extended(ctx
, values
, value_count
, 1, false, false);
620 /* Expand a scalar or vector to <dst_channels x type> by filling the remaining
621 * channels with undef. Extract at most src_channels components from the input.
624 ac_build_expand(struct ac_llvm_context
*ctx
,
626 unsigned src_channels
,
627 unsigned dst_channels
)
629 LLVMTypeRef elemtype
;
630 LLVMValueRef chan
[dst_channels
];
632 if (LLVMGetTypeKind(LLVMTypeOf(value
)) == LLVMVectorTypeKind
) {
633 unsigned vec_size
= LLVMGetVectorSize(LLVMTypeOf(value
));
635 if (src_channels
== dst_channels
&& vec_size
== dst_channels
)
638 src_channels
= MIN2(src_channels
, vec_size
);
640 for (unsigned i
= 0; i
< src_channels
; i
++)
641 chan
[i
] = ac_llvm_extract_elem(ctx
, value
, i
);
643 elemtype
= LLVMGetElementType(LLVMTypeOf(value
));
646 assert(src_channels
== 1);
649 elemtype
= LLVMTypeOf(value
);
652 for (unsigned i
= src_channels
; i
< dst_channels
; i
++)
653 chan
[i
] = LLVMGetUndef(elemtype
);
655 return ac_build_gather_values(ctx
, chan
, dst_channels
);
658 /* Extract components [start, start + channels) from a vector.
661 ac_extract_components(struct ac_llvm_context
*ctx
,
666 LLVMValueRef chan
[channels
];
668 for (unsigned i
= 0; i
< channels
; i
++)
669 chan
[i
] = ac_llvm_extract_elem(ctx
, value
, i
+ start
);
671 return ac_build_gather_values(ctx
, chan
, channels
);
674 /* Expand a scalar or vector to <4 x type> by filling the remaining channels
675 * with undef. Extract at most num_channels components from the input.
677 LLVMValueRef
ac_build_expand_to_vec4(struct ac_llvm_context
*ctx
,
679 unsigned num_channels
)
681 return ac_build_expand(ctx
, value
, num_channels
, 4);
684 LLVMValueRef
ac_build_round(struct ac_llvm_context
*ctx
, LLVMValueRef value
)
686 unsigned type_size
= ac_get_type_size(LLVMTypeOf(value
));
690 name
= "llvm.rint.f16";
691 else if (type_size
== 4)
692 name
= "llvm.rint.f32";
694 name
= "llvm.rint.f64";
696 return ac_build_intrinsic(ctx
, name
, LLVMTypeOf(value
), &value
, 1,
697 AC_FUNC_ATTR_READNONE
);
701 ac_build_fdiv(struct ac_llvm_context
*ctx
,
705 unsigned type_size
= ac_get_type_size(LLVMTypeOf(den
));
709 name
= "llvm.amdgcn.rcp.f16";
710 else if (type_size
== 4)
711 name
= "llvm.amdgcn.rcp.f32";
713 name
= "llvm.amdgcn.rcp.f64";
715 LLVMValueRef rcp
= ac_build_intrinsic(ctx
, name
, LLVMTypeOf(den
),
716 &den
, 1, AC_FUNC_ATTR_READNONE
);
718 return LLVMBuildFMul(ctx
->builder
, num
, rcp
, "");
721 /* See fast_idiv_by_const.h. */
722 /* Set: increment = util_fast_udiv_info::increment ? multiplier : 0; */
723 LLVMValueRef
ac_build_fast_udiv(struct ac_llvm_context
*ctx
,
725 LLVMValueRef multiplier
,
726 LLVMValueRef pre_shift
,
727 LLVMValueRef post_shift
,
728 LLVMValueRef increment
)
730 LLVMBuilderRef builder
= ctx
->builder
;
732 num
= LLVMBuildLShr(builder
, num
, pre_shift
, "");
733 num
= LLVMBuildMul(builder
,
734 LLVMBuildZExt(builder
, num
, ctx
->i64
, ""),
735 LLVMBuildZExt(builder
, multiplier
, ctx
->i64
, ""), "");
736 num
= LLVMBuildAdd(builder
, num
,
737 LLVMBuildZExt(builder
, increment
, ctx
->i64
, ""), "");
738 num
= LLVMBuildLShr(builder
, num
, LLVMConstInt(ctx
->i64
, 32, 0), "");
739 num
= LLVMBuildTrunc(builder
, num
, ctx
->i32
, "");
740 return LLVMBuildLShr(builder
, num
, post_shift
, "");
743 /* See fast_idiv_by_const.h. */
744 /* If num != UINT_MAX, this more efficient version can be used. */
745 /* Set: increment = util_fast_udiv_info::increment; */
746 LLVMValueRef
ac_build_fast_udiv_nuw(struct ac_llvm_context
*ctx
,
748 LLVMValueRef multiplier
,
749 LLVMValueRef pre_shift
,
750 LLVMValueRef post_shift
,
751 LLVMValueRef increment
)
753 LLVMBuilderRef builder
= ctx
->builder
;
755 num
= LLVMBuildLShr(builder
, num
, pre_shift
, "");
756 num
= LLVMBuildNUWAdd(builder
, num
, increment
, "");
757 num
= LLVMBuildMul(builder
,
758 LLVMBuildZExt(builder
, num
, ctx
->i64
, ""),
759 LLVMBuildZExt(builder
, multiplier
, ctx
->i64
, ""), "");
760 num
= LLVMBuildLShr(builder
, num
, LLVMConstInt(ctx
->i64
, 32, 0), "");
761 num
= LLVMBuildTrunc(builder
, num
, ctx
->i32
, "");
762 return LLVMBuildLShr(builder
, num
, post_shift
, "");
765 /* See fast_idiv_by_const.h. */
766 /* Both operands must fit in 31 bits and the divisor must not be 1. */
767 LLVMValueRef
ac_build_fast_udiv_u31_d_not_one(struct ac_llvm_context
*ctx
,
769 LLVMValueRef multiplier
,
770 LLVMValueRef post_shift
)
772 LLVMBuilderRef builder
= ctx
->builder
;
774 num
= LLVMBuildMul(builder
,
775 LLVMBuildZExt(builder
, num
, ctx
->i64
, ""),
776 LLVMBuildZExt(builder
, multiplier
, ctx
->i64
, ""), "");
777 num
= LLVMBuildLShr(builder
, num
, LLVMConstInt(ctx
->i64
, 32, 0), "");
778 num
= LLVMBuildTrunc(builder
, num
, ctx
->i32
, "");
779 return LLVMBuildLShr(builder
, num
, post_shift
, "");
782 /* Coordinates for cube map selection. sc, tc, and ma are as in Table 8.27
783 * of the OpenGL 4.5 (Compatibility Profile) specification, except ma is
784 * already multiplied by two. id is the cube face number.
786 struct cube_selection_coords
{
793 build_cube_intrinsic(struct ac_llvm_context
*ctx
,
795 struct cube_selection_coords
*out
)
797 LLVMTypeRef f32
= ctx
->f32
;
799 out
->stc
[1] = ac_build_intrinsic(ctx
, "llvm.amdgcn.cubetc",
800 f32
, in
, 3, AC_FUNC_ATTR_READNONE
);
801 out
->stc
[0] = ac_build_intrinsic(ctx
, "llvm.amdgcn.cubesc",
802 f32
, in
, 3, AC_FUNC_ATTR_READNONE
);
803 out
->ma
= ac_build_intrinsic(ctx
, "llvm.amdgcn.cubema",
804 f32
, in
, 3, AC_FUNC_ATTR_READNONE
);
805 out
->id
= ac_build_intrinsic(ctx
, "llvm.amdgcn.cubeid",
806 f32
, in
, 3, AC_FUNC_ATTR_READNONE
);
810 * Build a manual selection sequence for cube face sc/tc coordinates and
811 * major axis vector (multiplied by 2 for consistency) for the given
812 * vec3 \p coords, for the face implied by \p selcoords.
814 * For the major axis, we always adjust the sign to be in the direction of
815 * selcoords.ma; i.e., a positive out_ma means that coords is pointed towards
816 * the selcoords major axis.
818 static void build_cube_select(struct ac_llvm_context
*ctx
,
819 const struct cube_selection_coords
*selcoords
,
820 const LLVMValueRef
*coords
,
821 LLVMValueRef
*out_st
,
822 LLVMValueRef
*out_ma
)
824 LLVMBuilderRef builder
= ctx
->builder
;
825 LLVMTypeRef f32
= LLVMTypeOf(coords
[0]);
826 LLVMValueRef is_ma_positive
;
828 LLVMValueRef is_ma_z
, is_not_ma_z
;
829 LLVMValueRef is_ma_y
;
830 LLVMValueRef is_ma_x
;
834 is_ma_positive
= LLVMBuildFCmp(builder
, LLVMRealUGE
,
835 selcoords
->ma
, LLVMConstReal(f32
, 0.0), "");
836 sgn_ma
= LLVMBuildSelect(builder
, is_ma_positive
,
837 LLVMConstReal(f32
, 1.0), LLVMConstReal(f32
, -1.0), "");
839 is_ma_z
= LLVMBuildFCmp(builder
, LLVMRealUGE
, selcoords
->id
, LLVMConstReal(f32
, 4.0), "");
840 is_not_ma_z
= LLVMBuildNot(builder
, is_ma_z
, "");
841 is_ma_y
= LLVMBuildAnd(builder
, is_not_ma_z
,
842 LLVMBuildFCmp(builder
, LLVMRealUGE
, selcoords
->id
, LLVMConstReal(f32
, 2.0), ""), "");
843 is_ma_x
= LLVMBuildAnd(builder
, is_not_ma_z
, LLVMBuildNot(builder
, is_ma_y
, ""), "");
846 tmp
= LLVMBuildSelect(builder
, is_ma_x
, coords
[2], coords
[0], "");
847 sgn
= LLVMBuildSelect(builder
, is_ma_y
, LLVMConstReal(f32
, 1.0),
848 LLVMBuildSelect(builder
, is_ma_z
, sgn_ma
,
849 LLVMBuildFNeg(builder
, sgn_ma
, ""), ""), "");
850 out_st
[0] = LLVMBuildFMul(builder
, tmp
, sgn
, "");
853 tmp
= LLVMBuildSelect(builder
, is_ma_y
, coords
[2], coords
[1], "");
854 sgn
= LLVMBuildSelect(builder
, is_ma_y
, sgn_ma
,
855 LLVMConstReal(f32
, -1.0), "");
856 out_st
[1] = LLVMBuildFMul(builder
, tmp
, sgn
, "");
859 tmp
= LLVMBuildSelect(builder
, is_ma_z
, coords
[2],
860 LLVMBuildSelect(builder
, is_ma_y
, coords
[1], coords
[0], ""), "");
861 tmp
= ac_build_intrinsic(ctx
, "llvm.fabs.f32",
862 ctx
->f32
, &tmp
, 1, AC_FUNC_ATTR_READNONE
);
863 *out_ma
= LLVMBuildFMul(builder
, tmp
, LLVMConstReal(f32
, 2.0), "");
867 ac_prepare_cube_coords(struct ac_llvm_context
*ctx
,
868 bool is_deriv
, bool is_array
, bool is_lod
,
869 LLVMValueRef
*coords_arg
,
870 LLVMValueRef
*derivs_arg
)
873 LLVMBuilderRef builder
= ctx
->builder
;
874 struct cube_selection_coords selcoords
;
875 LLVMValueRef coords
[3];
878 if (is_array
&& !is_lod
) {
879 LLVMValueRef tmp
= ac_build_round(ctx
, coords_arg
[3]);
881 /* Section 8.9 (Texture Functions) of the GLSL 4.50 spec says:
883 * "For Array forms, the array layer used will be
885 * max(0, min(d−1, floor(layer+0.5)))
887 * where d is the depth of the texture array and layer
888 * comes from the component indicated in the tables below.
889 * Workaroudn for an issue where the layer is taken from a
890 * helper invocation which happens to fall on a different
891 * layer due to extrapolation."
893 * GFX8 and earlier attempt to implement this in hardware by
894 * clamping the value of coords[2] = (8 * layer) + face.
895 * Unfortunately, this means that the we end up with the wrong
896 * face when clamping occurs.
898 * Clamp the layer earlier to work around the issue.
900 if (ctx
->chip_class
<= GFX8
) {
902 ge0
= LLVMBuildFCmp(builder
, LLVMRealOGE
, tmp
, ctx
->f32_0
, "");
903 tmp
= LLVMBuildSelect(builder
, ge0
, tmp
, ctx
->f32_0
, "");
909 build_cube_intrinsic(ctx
, coords_arg
, &selcoords
);
911 invma
= ac_build_intrinsic(ctx
, "llvm.fabs.f32",
912 ctx
->f32
, &selcoords
.ma
, 1, AC_FUNC_ATTR_READNONE
);
913 invma
= ac_build_fdiv(ctx
, LLVMConstReal(ctx
->f32
, 1.0), invma
);
915 for (int i
= 0; i
< 2; ++i
)
916 coords
[i
] = LLVMBuildFMul(builder
, selcoords
.stc
[i
], invma
, "");
918 coords
[2] = selcoords
.id
;
920 if (is_deriv
&& derivs_arg
) {
921 LLVMValueRef derivs
[4];
924 /* Convert cube derivatives to 2D derivatives. */
925 for (axis
= 0; axis
< 2; axis
++) {
926 LLVMValueRef deriv_st
[2];
927 LLVMValueRef deriv_ma
;
929 /* Transform the derivative alongside the texture
930 * coordinate. Mathematically, the correct formula is
931 * as follows. Assume we're projecting onto the +Z face
932 * and denote by dx/dh the derivative of the (original)
933 * X texture coordinate with respect to horizontal
934 * window coordinates. The projection onto the +Z face
939 * Then df/dh = df/dx * dx/dh + df/dz * dz/dh
940 * = 1/z * dx/dh - x/z * 1/z * dz/dh.
942 * This motivatives the implementation below.
944 * Whether this actually gives the expected results for
945 * apps that might feed in derivatives obtained via
946 * finite differences is anyone's guess. The OpenGL spec
947 * seems awfully quiet about how textureGrad for cube
948 * maps should be handled.
950 build_cube_select(ctx
, &selcoords
, &derivs_arg
[axis
* 3],
951 deriv_st
, &deriv_ma
);
953 deriv_ma
= LLVMBuildFMul(builder
, deriv_ma
, invma
, "");
955 for (int i
= 0; i
< 2; ++i
)
956 derivs
[axis
* 2 + i
] =
957 LLVMBuildFSub(builder
,
958 LLVMBuildFMul(builder
, deriv_st
[i
], invma
, ""),
959 LLVMBuildFMul(builder
, deriv_ma
, coords
[i
], ""), "");
962 memcpy(derivs_arg
, derivs
, sizeof(derivs
));
965 /* Shift the texture coordinate. This must be applied after the
966 * derivative calculation.
968 for (int i
= 0; i
< 2; ++i
)
969 coords
[i
] = LLVMBuildFAdd(builder
, coords
[i
], LLVMConstReal(ctx
->f32
, 1.5), "");
972 /* for cube arrays coord.z = coord.w(array_index) * 8 + face */
973 /* coords_arg.w component - array_index for cube arrays */
974 coords
[2] = ac_build_fmad(ctx
, coords_arg
[3], LLVMConstReal(ctx
->f32
, 8.0), coords
[2]);
977 memcpy(coords_arg
, coords
, sizeof(coords
));
982 ac_build_fs_interp(struct ac_llvm_context
*ctx
,
983 LLVMValueRef llvm_chan
,
984 LLVMValueRef attr_number
,
989 LLVMValueRef args
[5];
994 args
[2] = attr_number
;
997 p1
= ac_build_intrinsic(ctx
, "llvm.amdgcn.interp.p1",
998 ctx
->f32
, args
, 4, AC_FUNC_ATTR_READNONE
);
1002 args
[2] = llvm_chan
;
1003 args
[3] = attr_number
;
1006 return ac_build_intrinsic(ctx
, "llvm.amdgcn.interp.p2",
1007 ctx
->f32
, args
, 5, AC_FUNC_ATTR_READNONE
);
1011 ac_build_fs_interp_f16(struct ac_llvm_context
*ctx
,
1012 LLVMValueRef llvm_chan
,
1013 LLVMValueRef attr_number
,
1014 LLVMValueRef params
,
1018 LLVMValueRef args
[6];
1022 args
[1] = llvm_chan
;
1023 args
[2] = attr_number
;
1024 args
[3] = ctx
->i1false
;
1027 p1
= ac_build_intrinsic(ctx
, "llvm.amdgcn.interp.p1.f16",
1028 ctx
->f32
, args
, 5, AC_FUNC_ATTR_READNONE
);
1032 args
[2] = llvm_chan
;
1033 args
[3] = attr_number
;
1034 args
[4] = ctx
->i1false
;
1037 return ac_build_intrinsic(ctx
, "llvm.amdgcn.interp.p2.f16",
1038 ctx
->f16
, args
, 6, AC_FUNC_ATTR_READNONE
);
1042 ac_build_fs_interp_mov(struct ac_llvm_context
*ctx
,
1043 LLVMValueRef parameter
,
1044 LLVMValueRef llvm_chan
,
1045 LLVMValueRef attr_number
,
1046 LLVMValueRef params
)
1048 LLVMValueRef args
[4];
1050 args
[0] = parameter
;
1051 args
[1] = llvm_chan
;
1052 args
[2] = attr_number
;
1055 return ac_build_intrinsic(ctx
, "llvm.amdgcn.interp.mov",
1056 ctx
->f32
, args
, 4, AC_FUNC_ATTR_READNONE
);
1060 ac_build_gep_ptr(struct ac_llvm_context
*ctx
,
1061 LLVMValueRef base_ptr
,
1064 return LLVMBuildGEP(ctx
->builder
, base_ptr
, &index
, 1, "");
1068 ac_build_gep0(struct ac_llvm_context
*ctx
,
1069 LLVMValueRef base_ptr
,
1072 LLVMValueRef indices
[2] = {
1076 return LLVMBuildGEP(ctx
->builder
, base_ptr
, indices
, 2, "");
1079 LLVMValueRef
ac_build_pointer_add(struct ac_llvm_context
*ctx
, LLVMValueRef ptr
,
1082 return LLVMBuildPointerCast(ctx
->builder
,
1083 LLVMBuildGEP(ctx
->builder
, ptr
, &index
, 1, ""),
1084 LLVMTypeOf(ptr
), "");
1088 ac_build_indexed_store(struct ac_llvm_context
*ctx
,
1089 LLVMValueRef base_ptr
, LLVMValueRef index
,
1092 LLVMBuildStore(ctx
->builder
, value
,
1093 ac_build_gep0(ctx
, base_ptr
, index
));
1097 * Build an LLVM bytecode indexed load using LLVMBuildGEP + LLVMBuildLoad.
1098 * It's equivalent to doing a load from &base_ptr[index].
1100 * \param base_ptr Where the array starts.
1101 * \param index The element index into the array.
1102 * \param uniform Whether the base_ptr and index can be assumed to be
1103 * dynamically uniform (i.e. load to an SGPR)
1104 * \param invariant Whether the load is invariant (no other opcodes affect it)
1105 * \param no_unsigned_wraparound
1106 * For all possible re-associations and re-distributions of an expression
1107 * "base_ptr + index * elemsize" into "addr + offset" (excluding GEPs
1108 * without inbounds in base_ptr), this parameter is true if "addr + offset"
1109 * does not result in an unsigned integer wraparound. This is used for
1110 * optimal code generation of 32-bit pointer arithmetic.
1112 * For example, a 32-bit immediate offset that causes a 32-bit unsigned
1113 * integer wraparound can't be an imm offset in s_load_dword, because
1114 * the instruction performs "addr + offset" in 64 bits.
1116 * Expected usage for bindless textures by chaining GEPs:
1117 * // possible unsigned wraparound, don't use InBounds:
1118 * ptr1 = LLVMBuildGEP(base_ptr, index);
1119 * image = load(ptr1); // becomes "s_load ptr1, 0"
1121 * ptr2 = LLVMBuildInBoundsGEP(ptr1, 32 / elemsize);
1122 * sampler = load(ptr2); // becomes "s_load ptr1, 32" thanks to InBounds
1125 ac_build_load_custom(struct ac_llvm_context
*ctx
, LLVMValueRef base_ptr
,
1126 LLVMValueRef index
, bool uniform
, bool invariant
,
1127 bool no_unsigned_wraparound
)
1129 LLVMValueRef pointer
, result
;
1131 if (no_unsigned_wraparound
&&
1132 LLVMGetPointerAddressSpace(LLVMTypeOf(base_ptr
)) == AC_ADDR_SPACE_CONST_32BIT
)
1133 pointer
= LLVMBuildInBoundsGEP(ctx
->builder
, base_ptr
, &index
, 1, "");
1135 pointer
= LLVMBuildGEP(ctx
->builder
, base_ptr
, &index
, 1, "");
1138 LLVMSetMetadata(pointer
, ctx
->uniform_md_kind
, ctx
->empty_md
);
1139 result
= LLVMBuildLoad(ctx
->builder
, pointer
, "");
1141 LLVMSetMetadata(result
, ctx
->invariant_load_md_kind
, ctx
->empty_md
);
1145 LLVMValueRef
ac_build_load(struct ac_llvm_context
*ctx
, LLVMValueRef base_ptr
,
1148 return ac_build_load_custom(ctx
, base_ptr
, index
, false, false, false);
1151 LLVMValueRef
ac_build_load_invariant(struct ac_llvm_context
*ctx
,
1152 LLVMValueRef base_ptr
, LLVMValueRef index
)
1154 return ac_build_load_custom(ctx
, base_ptr
, index
, false, true, false);
1157 /* This assumes that there is no unsigned integer wraparound during the address
1158 * computation, excluding all GEPs within base_ptr. */
1159 LLVMValueRef
ac_build_load_to_sgpr(struct ac_llvm_context
*ctx
,
1160 LLVMValueRef base_ptr
, LLVMValueRef index
)
1162 return ac_build_load_custom(ctx
, base_ptr
, index
, true, true, true);
1165 /* See ac_build_load_custom() documentation. */
1166 LLVMValueRef
ac_build_load_to_sgpr_uint_wraparound(struct ac_llvm_context
*ctx
,
1167 LLVMValueRef base_ptr
, LLVMValueRef index
)
1169 return ac_build_load_custom(ctx
, base_ptr
, index
, true, true, false);
1172 static unsigned get_load_cache_policy(struct ac_llvm_context
*ctx
,
1173 unsigned cache_policy
)
1175 return cache_policy
|
1176 (ctx
->chip_class
>= GFX10
&& cache_policy
& ac_glc
? ac_dlc
: 0);
1180 ac_build_buffer_store_common(struct ac_llvm_context
*ctx
,
1183 LLVMValueRef vindex
,
1184 LLVMValueRef voffset
,
1185 LLVMValueRef soffset
,
1186 unsigned cache_policy
,
1190 LLVMValueRef args
[6];
1193 args
[idx
++] = LLVMBuildBitCast(ctx
->builder
, rsrc
, ctx
->v4i32
, "");
1195 args
[idx
++] = vindex
? vindex
: ctx
->i32_0
;
1196 args
[idx
++] = voffset
? voffset
: ctx
->i32_0
;
1197 args
[idx
++] = soffset
? soffset
: ctx
->i32_0
;
1198 args
[idx
++] = LLVMConstInt(ctx
->i32
, cache_policy
, 0);
1199 const char *indexing_kind
= structurized
? "struct" : "raw";
1200 char name
[256], type_name
[8];
1202 ac_build_type_name_for_intr(LLVMTypeOf(data
), type_name
, sizeof(type_name
));
1205 snprintf(name
, sizeof(name
), "llvm.amdgcn.%s.buffer.store.format.%s",
1206 indexing_kind
, type_name
);
1208 snprintf(name
, sizeof(name
), "llvm.amdgcn.%s.buffer.store.%s",
1209 indexing_kind
, type_name
);
1212 ac_build_intrinsic(ctx
, name
, ctx
->voidt
, args
, idx
,
1213 AC_FUNC_ATTR_INACCESSIBLE_MEM_ONLY
);
1217 ac_build_buffer_store_format(struct ac_llvm_context
*ctx
,
1220 LLVMValueRef vindex
,
1221 LLVMValueRef voffset
,
1222 unsigned cache_policy
)
1224 ac_build_buffer_store_common(ctx
, rsrc
, data
, vindex
, voffset
, NULL
,
1225 cache_policy
, true, true);
1228 /* TBUFFER_STORE_FORMAT_{X,XY,XYZ,XYZW} <- the suffix is selected by num_channels=1..4.
1229 * The type of vdata must be one of i32 (num_channels=1), v2i32 (num_channels=2),
1230 * or v4i32 (num_channels=3,4).
1233 ac_build_buffer_store_dword(struct ac_llvm_context
*ctx
,
1236 unsigned num_channels
,
1237 LLVMValueRef voffset
,
1238 LLVMValueRef soffset
,
1239 unsigned inst_offset
,
1240 unsigned cache_policy
)
1242 /* Split 3 channel stores, because only LLVM 9+ support 3-channel
1244 if (num_channels
== 3 && !ac_has_vec3_support(ctx
->chip_class
, false)) {
1245 LLVMValueRef v
[3], v01
;
1247 for (int i
= 0; i
< 3; i
++) {
1248 v
[i
] = LLVMBuildExtractElement(ctx
->builder
, vdata
,
1249 LLVMConstInt(ctx
->i32
, i
, 0), "");
1251 v01
= ac_build_gather_values(ctx
, v
, 2);
1253 ac_build_buffer_store_dword(ctx
, rsrc
, v01
, 2, voffset
,
1254 soffset
, inst_offset
, cache_policy
);
1255 ac_build_buffer_store_dword(ctx
, rsrc
, v
[2], 1, voffset
,
1256 soffset
, inst_offset
+ 8,
1261 /* SWIZZLE_ENABLE requires that soffset isn't folded into voffset
1262 * (voffset is swizzled, but soffset isn't swizzled).
1263 * llvm.amdgcn.buffer.store doesn't have a separate soffset parameter.
1265 if (!(cache_policy
& ac_swizzled
)) {
1266 LLVMValueRef offset
= soffset
;
1269 offset
= LLVMBuildAdd(ctx
->builder
, offset
,
1270 LLVMConstInt(ctx
->i32
, inst_offset
, 0), "");
1272 ac_build_buffer_store_common(ctx
, rsrc
, ac_to_float(ctx
, vdata
),
1273 ctx
->i32_0
, voffset
, offset
,
1274 cache_policy
, false, false);
1278 static const unsigned dfmts
[] = {
1279 V_008F0C_BUF_DATA_FORMAT_32
,
1280 V_008F0C_BUF_DATA_FORMAT_32_32
,
1281 V_008F0C_BUF_DATA_FORMAT_32_32_32
,
1282 V_008F0C_BUF_DATA_FORMAT_32_32_32_32
1284 unsigned dfmt
= dfmts
[num_channels
- 1];
1285 unsigned nfmt
= V_008F0C_BUF_NUM_FORMAT_UINT
;
1286 LLVMValueRef immoffset
= LLVMConstInt(ctx
->i32
, inst_offset
, 0);
1288 ac_build_raw_tbuffer_store(ctx
, rsrc
, vdata
, voffset
, soffset
,
1289 immoffset
, num_channels
, dfmt
, nfmt
, cache_policy
);
1293 ac_build_buffer_load_common(struct ac_llvm_context
*ctx
,
1295 LLVMValueRef vindex
,
1296 LLVMValueRef voffset
,
1297 LLVMValueRef soffset
,
1298 unsigned num_channels
,
1299 LLVMTypeRef channel_type
,
1300 unsigned cache_policy
,
1305 LLVMValueRef args
[5];
1307 args
[idx
++] = LLVMBuildBitCast(ctx
->builder
, rsrc
, ctx
->v4i32
, "");
1309 args
[idx
++] = vindex
? vindex
: ctx
->i32_0
;
1310 args
[idx
++] = voffset
? voffset
: ctx
->i32_0
;
1311 args
[idx
++] = soffset
? soffset
: ctx
->i32_0
;
1312 args
[idx
++] = LLVMConstInt(ctx
->i32
, get_load_cache_policy(ctx
, cache_policy
), 0);
1313 unsigned func
= !ac_has_vec3_support(ctx
->chip_class
, use_format
) && num_channels
== 3 ? 4 : num_channels
;
1314 const char *indexing_kind
= structurized
? "struct" : "raw";
1315 char name
[256], type_name
[8];
1317 LLVMTypeRef type
= func
> 1 ? LLVMVectorType(channel_type
, func
) : channel_type
;
1318 ac_build_type_name_for_intr(type
, type_name
, sizeof(type_name
));
1321 snprintf(name
, sizeof(name
), "llvm.amdgcn.%s.buffer.load.format.%s",
1322 indexing_kind
, type_name
);
1324 snprintf(name
, sizeof(name
), "llvm.amdgcn.%s.buffer.load.%s",
1325 indexing_kind
, type_name
);
1328 return ac_build_intrinsic(ctx
, name
, type
, args
, idx
,
1329 ac_get_load_intr_attribs(can_speculate
));
1333 ac_build_buffer_load(struct ac_llvm_context
*ctx
,
1336 LLVMValueRef vindex
,
1337 LLVMValueRef voffset
,
1338 LLVMValueRef soffset
,
1339 unsigned inst_offset
,
1340 unsigned cache_policy
,
1344 LLVMValueRef offset
= LLVMConstInt(ctx
->i32
, inst_offset
, 0);
1346 offset
= LLVMBuildAdd(ctx
->builder
, offset
, voffset
, "");
1348 offset
= LLVMBuildAdd(ctx
->builder
, offset
, soffset
, "");
1350 if (allow_smem
&& !(cache_policy
& ac_slc
) &&
1351 (!(cache_policy
& ac_glc
) || ctx
->chip_class
>= GFX8
)) {
1352 assert(vindex
== NULL
);
1354 LLVMValueRef result
[8];
1356 for (int i
= 0; i
< num_channels
; i
++) {
1358 offset
= LLVMBuildAdd(ctx
->builder
, offset
,
1359 LLVMConstInt(ctx
->i32
, 4, 0), "");
1361 LLVMValueRef args
[3] = {
1364 LLVMConstInt(ctx
->i32
, get_load_cache_policy(ctx
, cache_policy
), 0),
1366 result
[i
] = ac_build_intrinsic(ctx
,
1367 "llvm.amdgcn.s.buffer.load.f32",
1369 AC_FUNC_ATTR_READNONE
);
1371 if (num_channels
== 1)
1374 if (num_channels
== 3 && !ac_has_vec3_support(ctx
->chip_class
, false))
1375 result
[num_channels
++] = LLVMGetUndef(ctx
->f32
);
1376 return ac_build_gather_values(ctx
, result
, num_channels
);
1379 return ac_build_buffer_load_common(ctx
, rsrc
, vindex
,
1381 num_channels
, ctx
->f32
,
1383 can_speculate
, false, false);
1386 LLVMValueRef
ac_build_buffer_load_format(struct ac_llvm_context
*ctx
,
1388 LLVMValueRef vindex
,
1389 LLVMValueRef voffset
,
1390 unsigned num_channels
,
1391 unsigned cache_policy
,
1394 return ac_build_buffer_load_common(ctx
, rsrc
, vindex
, voffset
,
1395 ctx
->i32_0
, num_channels
, ctx
->f32
,
1396 cache_policy
, can_speculate
,
1401 ac_build_tbuffer_load(struct ac_llvm_context
*ctx
,
1403 LLVMValueRef vindex
,
1404 LLVMValueRef voffset
,
1405 LLVMValueRef soffset
,
1406 LLVMValueRef immoffset
,
1407 unsigned num_channels
,
1410 unsigned cache_policy
,
1414 voffset
= LLVMBuildAdd(ctx
->builder
, voffset
, immoffset
, "");
1416 LLVMValueRef args
[6];
1418 args
[idx
++] = LLVMBuildBitCast(ctx
->builder
, rsrc
, ctx
->v4i32
, "");
1420 args
[idx
++] = vindex
? vindex
: ctx
->i32_0
;
1421 args
[idx
++] = voffset
? voffset
: ctx
->i32_0
;
1422 args
[idx
++] = soffset
? soffset
: ctx
->i32_0
;
1423 args
[idx
++] = LLVMConstInt(ctx
->i32
, ac_get_tbuffer_format(ctx
->chip_class
, dfmt
, nfmt
), 0);
1424 args
[idx
++] = LLVMConstInt(ctx
->i32
, get_load_cache_policy(ctx
, cache_policy
), 0);
1425 unsigned func
= !ac_has_vec3_support(ctx
->chip_class
, true) && num_channels
== 3 ? 4 : num_channels
;
1426 const char *indexing_kind
= structurized
? "struct" : "raw";
1427 char name
[256], type_name
[8];
1429 LLVMTypeRef type
= func
> 1 ? LLVMVectorType(ctx
->i32
, func
) : ctx
->i32
;
1430 ac_build_type_name_for_intr(type
, type_name
, sizeof(type_name
));
1432 snprintf(name
, sizeof(name
), "llvm.amdgcn.%s.tbuffer.load.%s",
1433 indexing_kind
, type_name
);
1435 return ac_build_intrinsic(ctx
, name
, type
, args
, idx
,
1436 ac_get_load_intr_attribs(can_speculate
));
1440 ac_build_struct_tbuffer_load(struct ac_llvm_context
*ctx
,
1442 LLVMValueRef vindex
,
1443 LLVMValueRef voffset
,
1444 LLVMValueRef soffset
,
1445 LLVMValueRef immoffset
,
1446 unsigned num_channels
,
1449 unsigned cache_policy
,
1452 return ac_build_tbuffer_load(ctx
, rsrc
, vindex
, voffset
, soffset
,
1453 immoffset
, num_channels
, dfmt
, nfmt
,
1454 cache_policy
, can_speculate
, true);
1458 ac_build_raw_tbuffer_load(struct ac_llvm_context
*ctx
,
1460 LLVMValueRef voffset
,
1461 LLVMValueRef soffset
,
1462 LLVMValueRef immoffset
,
1463 unsigned num_channels
,
1466 unsigned cache_policy
,
1469 return ac_build_tbuffer_load(ctx
, rsrc
, NULL
, voffset
, soffset
,
1470 immoffset
, num_channels
, dfmt
, nfmt
,
1471 cache_policy
, can_speculate
, false);
1475 ac_build_tbuffer_load_short(struct ac_llvm_context
*ctx
,
1477 LLVMValueRef voffset
,
1478 LLVMValueRef soffset
,
1479 LLVMValueRef immoffset
,
1480 unsigned cache_policy
)
1484 if (LLVM_VERSION_MAJOR
>= 9) {
1485 voffset
= LLVMBuildAdd(ctx
->builder
, voffset
, immoffset
, "");
1487 /* LLVM 9+ supports i8/i16 with struct/raw intrinsics. */
1488 res
= ac_build_buffer_load_common(ctx
, rsrc
, NULL
,
1490 1, ctx
->i16
, cache_policy
,
1491 false, false, false);
1493 unsigned dfmt
= V_008F0C_BUF_DATA_FORMAT_16
;
1494 unsigned nfmt
= V_008F0C_BUF_NUM_FORMAT_UINT
;
1496 res
= ac_build_raw_tbuffer_load(ctx
, rsrc
, voffset
, soffset
,
1497 immoffset
, 1, dfmt
, nfmt
, cache_policy
,
1500 res
= LLVMBuildTrunc(ctx
->builder
, res
, ctx
->i16
, "");
1507 ac_build_tbuffer_load_byte(struct ac_llvm_context
*ctx
,
1509 LLVMValueRef voffset
,
1510 LLVMValueRef soffset
,
1511 LLVMValueRef immoffset
,
1512 unsigned cache_policy
)
1516 if (LLVM_VERSION_MAJOR
>= 9) {
1517 voffset
= LLVMBuildAdd(ctx
->builder
, voffset
, immoffset
, "");
1519 /* LLVM 9+ supports i8/i16 with struct/raw intrinsics. */
1520 res
= ac_build_buffer_load_common(ctx
, rsrc
, NULL
,
1522 1, ctx
->i8
, cache_policy
,
1523 false, false, false);
1525 unsigned dfmt
= V_008F0C_BUF_DATA_FORMAT_8
;
1526 unsigned nfmt
= V_008F0C_BUF_NUM_FORMAT_UINT
;
1528 res
= ac_build_raw_tbuffer_load(ctx
, rsrc
, voffset
, soffset
,
1529 immoffset
, 1, dfmt
, nfmt
, cache_policy
,
1532 res
= LLVMBuildTrunc(ctx
->builder
, res
, ctx
->i8
, "");
1539 * Convert an 11- or 10-bit unsigned floating point number to an f32.
1541 * The input exponent is expected to be biased analogous to IEEE-754, i.e. by
1542 * 2^(exp_bits-1) - 1 (as defined in OpenGL and other graphics APIs).
1545 ac_ufN_to_float(struct ac_llvm_context
*ctx
, LLVMValueRef src
, unsigned exp_bits
, unsigned mant_bits
)
1547 assert(LLVMTypeOf(src
) == ctx
->i32
);
1550 LLVMValueRef mantissa
;
1551 mantissa
= LLVMBuildAnd(ctx
->builder
, src
, LLVMConstInt(ctx
->i32
, (1 << mant_bits
) - 1, false), "");
1553 /* Converting normal numbers is just a shift + correcting the exponent bias */
1554 unsigned normal_shift
= 23 - mant_bits
;
1555 unsigned bias_shift
= 127 - ((1 << (exp_bits
- 1)) - 1);
1556 LLVMValueRef shifted
, normal
;
1558 shifted
= LLVMBuildShl(ctx
->builder
, src
, LLVMConstInt(ctx
->i32
, normal_shift
, false), "");
1559 normal
= LLVMBuildAdd(ctx
->builder
, shifted
, LLVMConstInt(ctx
->i32
, bias_shift
<< 23, false), "");
1561 /* Converting nan/inf numbers is the same, but with a different exponent update */
1562 LLVMValueRef naninf
;
1563 naninf
= LLVMBuildOr(ctx
->builder
, normal
, LLVMConstInt(ctx
->i32
, 0xff << 23, false), "");
1565 /* Converting denormals is the complex case: determine the leading zeros of the
1566 * mantissa to obtain the correct shift for the mantissa and exponent correction.
1568 LLVMValueRef denormal
;
1569 LLVMValueRef params
[2] = {
1571 ctx
->i1true
, /* result can be undef when arg is 0 */
1573 LLVMValueRef ctlz
= ac_build_intrinsic(ctx
, "llvm.ctlz.i32", ctx
->i32
,
1574 params
, 2, AC_FUNC_ATTR_READNONE
);
1576 /* Shift such that the leading 1 ends up as the LSB of the exponent field. */
1577 tmp
= LLVMBuildSub(ctx
->builder
, ctlz
, LLVMConstInt(ctx
->i32
, 8, false), "");
1578 denormal
= LLVMBuildShl(ctx
->builder
, mantissa
, tmp
, "");
1580 unsigned denormal_exp
= bias_shift
+ (32 - mant_bits
) - 1;
1581 tmp
= LLVMBuildSub(ctx
->builder
, LLVMConstInt(ctx
->i32
, denormal_exp
, false), ctlz
, "");
1582 tmp
= LLVMBuildShl(ctx
->builder
, tmp
, LLVMConstInt(ctx
->i32
, 23, false), "");
1583 denormal
= LLVMBuildAdd(ctx
->builder
, denormal
, tmp
, "");
1585 /* Select the final result. */
1586 LLVMValueRef result
;
1588 tmp
= LLVMBuildICmp(ctx
->builder
, LLVMIntUGE
, src
,
1589 LLVMConstInt(ctx
->i32
, ((1 << exp_bits
) - 1) << mant_bits
, false), "");
1590 result
= LLVMBuildSelect(ctx
->builder
, tmp
, naninf
, normal
, "");
1592 tmp
= LLVMBuildICmp(ctx
->builder
, LLVMIntUGE
, src
,
1593 LLVMConstInt(ctx
->i32
, 1 << mant_bits
, false), "");
1594 result
= LLVMBuildSelect(ctx
->builder
, tmp
, result
, denormal
, "");
1596 tmp
= LLVMBuildICmp(ctx
->builder
, LLVMIntNE
, src
, ctx
->i32_0
, "");
1597 result
= LLVMBuildSelect(ctx
->builder
, tmp
, result
, ctx
->i32_0
, "");
1599 return ac_to_float(ctx
, result
);
1603 * Generate a fully general open coded buffer format fetch with all required
1604 * fixups suitable for vertex fetch, using non-format buffer loads.
1606 * Some combinations of argument values have special interpretations:
1607 * - size = 8 bytes, format = fixed indicates PIPE_FORMAT_R11G11B10_FLOAT
1608 * - size = 8 bytes, format != {float,fixed} indicates a 2_10_10_10 data format
1610 * \param log_size log(size of channel in bytes)
1611 * \param num_channels number of channels (1 to 4)
1612 * \param format AC_FETCH_FORMAT_xxx value
1613 * \param reverse whether XYZ channels are reversed
1614 * \param known_aligned whether the source is known to be aligned to hardware's
1615 * effective element size for loading the given format
1616 * (note: this means dword alignment for 8_8_8_8, 16_16, etc.)
1617 * \param rsrc buffer resource descriptor
1618 * \return the resulting vector of floats or integers bitcast to <4 x i32>
1621 ac_build_opencoded_load_format(struct ac_llvm_context
*ctx
,
1623 unsigned num_channels
,
1628 LLVMValueRef vindex
,
1629 LLVMValueRef voffset
,
1630 LLVMValueRef soffset
,
1631 unsigned cache_policy
,
1635 unsigned load_log_size
= log_size
;
1636 unsigned load_num_channels
= num_channels
;
1637 if (log_size
== 3) {
1639 if (format
== AC_FETCH_FORMAT_FLOAT
) {
1640 load_num_channels
= 2 * num_channels
;
1642 load_num_channels
= 1; /* 10_11_11 or 2_10_10_10 */
1646 int log_recombine
= 0;
1647 if (ctx
->chip_class
== GFX6
&& !known_aligned
) {
1648 /* Avoid alignment restrictions by loading one byte at a time. */
1649 load_num_channels
<<= load_log_size
;
1650 log_recombine
= load_log_size
;
1652 } else if (load_num_channels
== 2 || load_num_channels
== 4) {
1653 log_recombine
= -util_logbase2(load_num_channels
);
1654 load_num_channels
= 1;
1655 load_log_size
+= -log_recombine
;
1658 assert(load_log_size
>= 2 || LLVM_VERSION_MAJOR
>= 9);
1660 LLVMValueRef loads
[32]; /* up to 32 bytes */
1661 for (unsigned i
= 0; i
< load_num_channels
; ++i
) {
1662 tmp
= LLVMBuildAdd(ctx
->builder
, soffset
,
1663 LLVMConstInt(ctx
->i32
, i
<< load_log_size
, false), "");
1664 LLVMTypeRef channel_type
= load_log_size
== 0 ? ctx
->i8
:
1665 load_log_size
== 1 ? ctx
->i16
: ctx
->i32
;
1666 unsigned num_channels
= 1 << (MAX2(load_log_size
, 2) - 2);
1667 loads
[i
] = ac_build_buffer_load_common(
1668 ctx
, rsrc
, vindex
, voffset
, tmp
,
1669 num_channels
, channel_type
, cache_policy
,
1670 can_speculate
, false, true);
1671 if (load_log_size
>= 2)
1672 loads
[i
] = ac_to_integer(ctx
, loads
[i
]);
1675 if (log_recombine
> 0) {
1676 /* Recombine bytes if necessary (GFX6 only) */
1677 LLVMTypeRef dst_type
= log_recombine
== 2 ? ctx
->i32
: ctx
->i16
;
1679 for (unsigned src
= 0, dst
= 0; src
< load_num_channels
; ++dst
) {
1680 LLVMValueRef accum
= NULL
;
1681 for (unsigned i
= 0; i
< (1 << log_recombine
); ++i
, ++src
) {
1682 tmp
= LLVMBuildZExt(ctx
->builder
, loads
[src
], dst_type
, "");
1686 tmp
= LLVMBuildShl(ctx
->builder
, tmp
,
1687 LLVMConstInt(dst_type
, 8 * i
, false), "");
1688 accum
= LLVMBuildOr(ctx
->builder
, accum
, tmp
, "");
1693 } else if (log_recombine
< 0) {
1694 /* Split vectors of dwords */
1695 if (load_log_size
> 2) {
1696 assert(load_num_channels
== 1);
1697 LLVMValueRef loaded
= loads
[0];
1698 unsigned log_split
= load_log_size
- 2;
1699 log_recombine
+= log_split
;
1700 load_num_channels
= 1 << log_split
;
1702 for (unsigned i
= 0; i
< load_num_channels
; ++i
) {
1703 tmp
= LLVMConstInt(ctx
->i32
, i
, false);
1704 loads
[i
] = LLVMBuildExtractElement(ctx
->builder
, loaded
, tmp
, "");
1708 /* Further split dwords and shorts if required */
1709 if (log_recombine
< 0) {
1710 for (unsigned src
= load_num_channels
,
1711 dst
= load_num_channels
<< -log_recombine
;
1713 unsigned dst_bits
= 1 << (3 + load_log_size
+ log_recombine
);
1714 LLVMTypeRef dst_type
= LLVMIntTypeInContext(ctx
->context
, dst_bits
);
1715 LLVMValueRef loaded
= loads
[src
- 1];
1716 LLVMTypeRef loaded_type
= LLVMTypeOf(loaded
);
1717 for (unsigned i
= 1 << -log_recombine
; i
> 0; --i
, --dst
) {
1718 tmp
= LLVMConstInt(loaded_type
, dst_bits
* (i
- 1), false);
1719 tmp
= LLVMBuildLShr(ctx
->builder
, loaded
, tmp
, "");
1720 loads
[dst
- 1] = LLVMBuildTrunc(ctx
->builder
, tmp
, dst_type
, "");
1726 if (log_size
== 3) {
1727 if (format
== AC_FETCH_FORMAT_FLOAT
) {
1728 for (unsigned i
= 0; i
< num_channels
; ++i
) {
1729 tmp
= ac_build_gather_values(ctx
, &loads
[2 * i
], 2);
1730 loads
[i
] = LLVMBuildBitCast(ctx
->builder
, tmp
, ctx
->f64
, "");
1732 } else if (format
== AC_FETCH_FORMAT_FIXED
) {
1733 /* 10_11_11_FLOAT */
1734 LLVMValueRef data
= loads
[0];
1735 LLVMValueRef i32_2047
= LLVMConstInt(ctx
->i32
, 2047, false);
1736 LLVMValueRef r
= LLVMBuildAnd(ctx
->builder
, data
, i32_2047
, "");
1737 tmp
= LLVMBuildLShr(ctx
->builder
, data
, LLVMConstInt(ctx
->i32
, 11, false), "");
1738 LLVMValueRef g
= LLVMBuildAnd(ctx
->builder
, tmp
, i32_2047
, "");
1739 LLVMValueRef b
= LLVMBuildLShr(ctx
->builder
, data
, LLVMConstInt(ctx
->i32
, 22, false), "");
1741 loads
[0] = ac_to_integer(ctx
, ac_ufN_to_float(ctx
, r
, 5, 6));
1742 loads
[1] = ac_to_integer(ctx
, ac_ufN_to_float(ctx
, g
, 5, 6));
1743 loads
[2] = ac_to_integer(ctx
, ac_ufN_to_float(ctx
, b
, 5, 5));
1747 format
= AC_FETCH_FORMAT_FLOAT
;
1749 /* 2_10_10_10 data formats */
1750 LLVMValueRef data
= loads
[0];
1751 LLVMTypeRef i10
= LLVMIntTypeInContext(ctx
->context
, 10);
1752 LLVMTypeRef i2
= LLVMIntTypeInContext(ctx
->context
, 2);
1753 loads
[0] = LLVMBuildTrunc(ctx
->builder
, data
, i10
, "");
1754 tmp
= LLVMBuildLShr(ctx
->builder
, data
, LLVMConstInt(ctx
->i32
, 10, false), "");
1755 loads
[1] = LLVMBuildTrunc(ctx
->builder
, tmp
, i10
, "");
1756 tmp
= LLVMBuildLShr(ctx
->builder
, data
, LLVMConstInt(ctx
->i32
, 20, false), "");
1757 loads
[2] = LLVMBuildTrunc(ctx
->builder
, tmp
, i10
, "");
1758 tmp
= LLVMBuildLShr(ctx
->builder
, data
, LLVMConstInt(ctx
->i32
, 30, false), "");
1759 loads
[3] = LLVMBuildTrunc(ctx
->builder
, tmp
, i2
, "");
1765 if (format
== AC_FETCH_FORMAT_FLOAT
) {
1766 if (log_size
!= 2) {
1767 for (unsigned chan
= 0; chan
< num_channels
; ++chan
) {
1768 tmp
= ac_to_float(ctx
, loads
[chan
]);
1770 tmp
= LLVMBuildFPTrunc(ctx
->builder
, tmp
, ctx
->f32
, "");
1771 else if (log_size
== 1)
1772 tmp
= LLVMBuildFPExt(ctx
->builder
, tmp
, ctx
->f32
, "");
1773 loads
[chan
] = ac_to_integer(ctx
, tmp
);
1776 } else if (format
== AC_FETCH_FORMAT_UINT
) {
1777 if (log_size
!= 2) {
1778 for (unsigned chan
= 0; chan
< num_channels
; ++chan
)
1779 loads
[chan
] = LLVMBuildZExt(ctx
->builder
, loads
[chan
], ctx
->i32
, "");
1781 } else if (format
== AC_FETCH_FORMAT_SINT
) {
1782 if (log_size
!= 2) {
1783 for (unsigned chan
= 0; chan
< num_channels
; ++chan
)
1784 loads
[chan
] = LLVMBuildSExt(ctx
->builder
, loads
[chan
], ctx
->i32
, "");
1787 bool unsign
= format
== AC_FETCH_FORMAT_UNORM
||
1788 format
== AC_FETCH_FORMAT_USCALED
||
1789 format
== AC_FETCH_FORMAT_UINT
;
1791 for (unsigned chan
= 0; chan
< num_channels
; ++chan
) {
1793 tmp
= LLVMBuildUIToFP(ctx
->builder
, loads
[chan
], ctx
->f32
, "");
1795 tmp
= LLVMBuildSIToFP(ctx
->builder
, loads
[chan
], ctx
->f32
, "");
1798 LLVMValueRef scale
= NULL
;
1799 if (format
== AC_FETCH_FORMAT_FIXED
) {
1800 assert(log_size
== 2);
1801 scale
= LLVMConstReal(ctx
->f32
, 1.0 / 0x10000);
1802 } else if (format
== AC_FETCH_FORMAT_UNORM
) {
1803 unsigned bits
= LLVMGetIntTypeWidth(LLVMTypeOf(loads
[chan
]));
1804 scale
= LLVMConstReal(ctx
->f32
, 1.0 / (((uint64_t)1 << bits
) - 1));
1805 } else if (format
== AC_FETCH_FORMAT_SNORM
) {
1806 unsigned bits
= LLVMGetIntTypeWidth(LLVMTypeOf(loads
[chan
]));
1807 scale
= LLVMConstReal(ctx
->f32
, 1.0 / (((uint64_t)1 << (bits
- 1)) - 1));
1810 tmp
= LLVMBuildFMul(ctx
->builder
, tmp
, scale
, "");
1812 if (format
== AC_FETCH_FORMAT_SNORM
) {
1813 /* Clamp to [-1, 1] */
1814 LLVMValueRef neg_one
= LLVMConstReal(ctx
->f32
, -1.0);
1815 LLVMValueRef clamp
=
1816 LLVMBuildFCmp(ctx
->builder
, LLVMRealULT
, tmp
, neg_one
, "");
1817 tmp
= LLVMBuildSelect(ctx
->builder
, clamp
, neg_one
, tmp
, "");
1820 loads
[chan
] = ac_to_integer(ctx
, tmp
);
1824 while (num_channels
< 4) {
1825 if (format
== AC_FETCH_FORMAT_UINT
|| format
== AC_FETCH_FORMAT_SINT
) {
1826 loads
[num_channels
] = num_channels
== 3 ? ctx
->i32_1
: ctx
->i32_0
;
1828 loads
[num_channels
] = ac_to_integer(ctx
, num_channels
== 3 ? ctx
->f32_1
: ctx
->f32_0
);
1835 loads
[0] = loads
[2];
1839 return ac_build_gather_values(ctx
, loads
, 4);
1843 ac_build_tbuffer_store(struct ac_llvm_context
*ctx
,
1846 LLVMValueRef vindex
,
1847 LLVMValueRef voffset
,
1848 LLVMValueRef soffset
,
1849 LLVMValueRef immoffset
,
1850 unsigned num_channels
,
1853 unsigned cache_policy
,
1856 voffset
= LLVMBuildAdd(ctx
->builder
, voffset
? voffset
: ctx
->i32_0
,
1859 LLVMValueRef args
[7];
1861 args
[idx
++] = vdata
;
1862 args
[idx
++] = LLVMBuildBitCast(ctx
->builder
, rsrc
, ctx
->v4i32
, "");
1864 args
[idx
++] = vindex
? vindex
: ctx
->i32_0
;
1865 args
[idx
++] = voffset
? voffset
: ctx
->i32_0
;
1866 args
[idx
++] = soffset
? soffset
: ctx
->i32_0
;
1867 args
[idx
++] = LLVMConstInt(ctx
->i32
, ac_get_tbuffer_format(ctx
->chip_class
, dfmt
, nfmt
), 0);
1868 args
[idx
++] = LLVMConstInt(ctx
->i32
, cache_policy
, 0);
1869 unsigned func
= !ac_has_vec3_support(ctx
->chip_class
, true) && num_channels
== 3 ? 4 : num_channels
;
1870 const char *indexing_kind
= structurized
? "struct" : "raw";
1871 char name
[256], type_name
[8];
1873 LLVMTypeRef type
= func
> 1 ? LLVMVectorType(ctx
->i32
, func
) : ctx
->i32
;
1874 ac_build_type_name_for_intr(type
, type_name
, sizeof(type_name
));
1876 snprintf(name
, sizeof(name
), "llvm.amdgcn.%s.tbuffer.store.%s",
1877 indexing_kind
, type_name
);
1879 ac_build_intrinsic(ctx
, name
, ctx
->voidt
, args
, idx
,
1880 AC_FUNC_ATTR_INACCESSIBLE_MEM_ONLY
);
1884 ac_build_struct_tbuffer_store(struct ac_llvm_context
*ctx
,
1887 LLVMValueRef vindex
,
1888 LLVMValueRef voffset
,
1889 LLVMValueRef soffset
,
1890 LLVMValueRef immoffset
,
1891 unsigned num_channels
,
1894 unsigned cache_policy
)
1896 ac_build_tbuffer_store(ctx
, rsrc
, vdata
, vindex
, voffset
, soffset
,
1897 immoffset
, num_channels
, dfmt
, nfmt
, cache_policy
,
1902 ac_build_raw_tbuffer_store(struct ac_llvm_context
*ctx
,
1905 LLVMValueRef voffset
,
1906 LLVMValueRef soffset
,
1907 LLVMValueRef immoffset
,
1908 unsigned num_channels
,
1911 unsigned cache_policy
)
1913 ac_build_tbuffer_store(ctx
, rsrc
, vdata
, NULL
, voffset
, soffset
,
1914 immoffset
, num_channels
, dfmt
, nfmt
, cache_policy
,
1919 ac_build_tbuffer_store_short(struct ac_llvm_context
*ctx
,
1922 LLVMValueRef voffset
,
1923 LLVMValueRef soffset
,
1924 unsigned cache_policy
)
1926 vdata
= LLVMBuildBitCast(ctx
->builder
, vdata
, ctx
->i16
, "");
1928 if (LLVM_VERSION_MAJOR
>= 9) {
1929 /* LLVM 9+ supports i8/i16 with struct/raw intrinsics. */
1930 ac_build_buffer_store_common(ctx
, rsrc
, vdata
, NULL
,
1931 voffset
, soffset
, cache_policy
,
1934 unsigned dfmt
= V_008F0C_BUF_DATA_FORMAT_16
;
1935 unsigned nfmt
= V_008F0C_BUF_NUM_FORMAT_UINT
;
1937 vdata
= LLVMBuildZExt(ctx
->builder
, vdata
, ctx
->i32
, "");
1939 ac_build_raw_tbuffer_store(ctx
, rsrc
, vdata
, voffset
, soffset
,
1940 ctx
->i32_0
, 1, dfmt
, nfmt
, cache_policy
);
1945 ac_build_tbuffer_store_byte(struct ac_llvm_context
*ctx
,
1948 LLVMValueRef voffset
,
1949 LLVMValueRef soffset
,
1950 unsigned cache_policy
)
1952 vdata
= LLVMBuildBitCast(ctx
->builder
, vdata
, ctx
->i8
, "");
1954 if (LLVM_VERSION_MAJOR
>= 9) {
1955 /* LLVM 9+ supports i8/i16 with struct/raw intrinsics. */
1956 ac_build_buffer_store_common(ctx
, rsrc
, vdata
, NULL
,
1957 voffset
, soffset
, cache_policy
,
1960 unsigned dfmt
= V_008F0C_BUF_DATA_FORMAT_8
;
1961 unsigned nfmt
= V_008F0C_BUF_NUM_FORMAT_UINT
;
1963 vdata
= LLVMBuildZExt(ctx
->builder
, vdata
, ctx
->i32
, "");
1965 ac_build_raw_tbuffer_store(ctx
, rsrc
, vdata
, voffset
, soffset
,
1966 ctx
->i32_0
, 1, dfmt
, nfmt
, cache_policy
);
1970 * Set range metadata on an instruction. This can only be used on load and
1971 * call instructions. If you know an instruction can only produce the values
1972 * 0, 1, 2, you would do set_range_metadata(value, 0, 3);
1973 * \p lo is the minimum value inclusive.
1974 * \p hi is the maximum value exclusive.
1976 static void set_range_metadata(struct ac_llvm_context
*ctx
,
1977 LLVMValueRef value
, unsigned lo
, unsigned hi
)
1979 LLVMValueRef range_md
, md_args
[2];
1980 LLVMTypeRef type
= LLVMTypeOf(value
);
1981 LLVMContextRef context
= LLVMGetTypeContext(type
);
1983 md_args
[0] = LLVMConstInt(type
, lo
, false);
1984 md_args
[1] = LLVMConstInt(type
, hi
, false);
1985 range_md
= LLVMMDNodeInContext(context
, md_args
, 2);
1986 LLVMSetMetadata(value
, ctx
->range_md_kind
, range_md
);
1990 ac_get_thread_id(struct ac_llvm_context
*ctx
)
1994 LLVMValueRef tid_args
[2];
1995 tid_args
[0] = LLVMConstInt(ctx
->i32
, 0xffffffff, false);
1996 tid_args
[1] = ctx
->i32_0
;
1997 tid_args
[1] = ac_build_intrinsic(ctx
,
1998 "llvm.amdgcn.mbcnt.lo", ctx
->i32
,
1999 tid_args
, 2, AC_FUNC_ATTR_READNONE
);
2001 if (ctx
->wave_size
== 32) {
2004 tid
= ac_build_intrinsic(ctx
, "llvm.amdgcn.mbcnt.hi",
2006 2, AC_FUNC_ATTR_READNONE
);
2008 set_range_metadata(ctx
, tid
, 0, ctx
->wave_size
);
2013 * AMD GCN implements derivatives using the local data store (LDS)
2014 * All writes to the LDS happen in all executing threads at
2015 * the same time. TID is the Thread ID for the current
2016 * thread and is a value between 0 and 63, representing
2017 * the thread's position in the wavefront.
2019 * For the pixel shader threads are grouped into quads of four pixels.
2020 * The TIDs of the pixels of a quad are:
2028 * So, masking the TID with 0xfffffffc yields the TID of the top left pixel
2029 * of the quad, masking with 0xfffffffd yields the TID of the top pixel of
2030 * the current pixel's column, and masking with 0xfffffffe yields the TID
2031 * of the left pixel of the current pixel's row.
2033 * Adding 1 yields the TID of the pixel to the right of the left pixel, and
2034 * adding 2 yields the TID of the pixel below the top pixel.
2037 ac_build_ddxy(struct ac_llvm_context
*ctx
,
2042 unsigned tl_lanes
[4], trbl_lanes
[4];
2043 char name
[32], type
[8];
2044 LLVMValueRef tl
, trbl
;
2045 LLVMTypeRef result_type
;
2046 LLVMValueRef result
;
2048 result_type
= ac_to_float_type(ctx
, LLVMTypeOf(val
));
2050 if (result_type
== ctx
->f16
)
2051 val
= LLVMBuildZExt(ctx
->builder
, val
, ctx
->i32
, "");
2053 for (unsigned i
= 0; i
< 4; ++i
) {
2054 tl_lanes
[i
] = i
& mask
;
2055 trbl_lanes
[i
] = (i
& mask
) + idx
;
2058 tl
= ac_build_quad_swizzle(ctx
, val
,
2059 tl_lanes
[0], tl_lanes
[1],
2060 tl_lanes
[2], tl_lanes
[3]);
2061 trbl
= ac_build_quad_swizzle(ctx
, val
,
2062 trbl_lanes
[0], trbl_lanes
[1],
2063 trbl_lanes
[2], trbl_lanes
[3]);
2065 if (result_type
== ctx
->f16
) {
2066 tl
= LLVMBuildTrunc(ctx
->builder
, tl
, ctx
->i16
, "");
2067 trbl
= LLVMBuildTrunc(ctx
->builder
, trbl
, ctx
->i16
, "");
2070 tl
= LLVMBuildBitCast(ctx
->builder
, tl
, result_type
, "");
2071 trbl
= LLVMBuildBitCast(ctx
->builder
, trbl
, result_type
, "");
2072 result
= LLVMBuildFSub(ctx
->builder
, trbl
, tl
, "");
2074 ac_build_type_name_for_intr(result_type
, type
, sizeof(type
));
2075 snprintf(name
, sizeof(name
), "llvm.amdgcn.wqm.%s", type
);
2077 return ac_build_intrinsic(ctx
, name
, result_type
, &result
, 1, 0);
2081 ac_build_sendmsg(struct ac_llvm_context
*ctx
,
2083 LLVMValueRef wave_id
)
2085 LLVMValueRef args
[2];
2086 args
[0] = LLVMConstInt(ctx
->i32
, msg
, false);
2088 ac_build_intrinsic(ctx
, "llvm.amdgcn.s.sendmsg", ctx
->voidt
, args
, 2, 0);
2092 ac_build_imsb(struct ac_llvm_context
*ctx
,
2094 LLVMTypeRef dst_type
)
2096 LLVMValueRef msb
= ac_build_intrinsic(ctx
, "llvm.amdgcn.sffbh.i32",
2098 AC_FUNC_ATTR_READNONE
);
2100 /* The HW returns the last bit index from MSB, but NIR/TGSI wants
2101 * the index from LSB. Invert it by doing "31 - msb". */
2102 msb
= LLVMBuildSub(ctx
->builder
, LLVMConstInt(ctx
->i32
, 31, false),
2105 LLVMValueRef all_ones
= LLVMConstInt(ctx
->i32
, -1, true);
2106 LLVMValueRef cond
= LLVMBuildOr(ctx
->builder
,
2107 LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
,
2108 arg
, ctx
->i32_0
, ""),
2109 LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
,
2110 arg
, all_ones
, ""), "");
2112 return LLVMBuildSelect(ctx
->builder
, cond
, all_ones
, msb
, "");
2116 ac_build_umsb(struct ac_llvm_context
*ctx
,
2118 LLVMTypeRef dst_type
)
2120 const char *intrin_name
;
2122 LLVMValueRef highest_bit
;
2126 bitsize
= ac_get_elem_bits(ctx
, LLVMTypeOf(arg
));
2129 intrin_name
= "llvm.ctlz.i64";
2131 highest_bit
= LLVMConstInt(ctx
->i64
, 63, false);
2135 intrin_name
= "llvm.ctlz.i32";
2137 highest_bit
= LLVMConstInt(ctx
->i32
, 31, false);
2141 intrin_name
= "llvm.ctlz.i16";
2143 highest_bit
= LLVMConstInt(ctx
->i16
, 15, false);
2147 intrin_name
= "llvm.ctlz.i8";
2149 highest_bit
= LLVMConstInt(ctx
->i8
, 7, false);
2153 unreachable(!"invalid bitsize");
2157 LLVMValueRef params
[2] = {
2162 LLVMValueRef msb
= ac_build_intrinsic(ctx
, intrin_name
, type
,
2164 AC_FUNC_ATTR_READNONE
);
2166 /* The HW returns the last bit index from MSB, but TGSI/NIR wants
2167 * the index from LSB. Invert it by doing "31 - msb". */
2168 msb
= LLVMBuildSub(ctx
->builder
, highest_bit
, msb
, "");
2170 if (bitsize
== 64) {
2171 msb
= LLVMBuildTrunc(ctx
->builder
, msb
, ctx
->i32
, "");
2172 } else if (bitsize
< 32) {
2173 msb
= LLVMBuildSExt(ctx
->builder
, msb
, ctx
->i32
, "");
2176 /* check for zero */
2177 return LLVMBuildSelect(ctx
->builder
,
2178 LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
, arg
, zero
, ""),
2179 LLVMConstInt(ctx
->i32
, -1, true), msb
, "");
2182 LLVMValueRef
ac_build_fmin(struct ac_llvm_context
*ctx
, LLVMValueRef a
,
2185 char name
[64], type
[64];
2187 ac_build_type_name_for_intr(LLVMTypeOf(a
), type
, sizeof(type
));
2188 snprintf(name
, sizeof(name
), "llvm.minnum.%s", type
);
2189 LLVMValueRef args
[2] = {a
, b
};
2190 return ac_build_intrinsic(ctx
, name
, LLVMTypeOf(a
), args
, 2,
2191 AC_FUNC_ATTR_READNONE
);
2194 LLVMValueRef
ac_build_fmax(struct ac_llvm_context
*ctx
, LLVMValueRef a
,
2197 char name
[64], type
[64];
2199 ac_build_type_name_for_intr(LLVMTypeOf(a
), type
, sizeof(type
));
2200 snprintf(name
, sizeof(name
), "llvm.maxnum.%s", type
);
2201 LLVMValueRef args
[2] = {a
, b
};
2202 return ac_build_intrinsic(ctx
, name
, LLVMTypeOf(a
), args
, 2,
2203 AC_FUNC_ATTR_READNONE
);
2206 LLVMValueRef
ac_build_imin(struct ac_llvm_context
*ctx
, LLVMValueRef a
,
2209 LLVMValueRef cmp
= LLVMBuildICmp(ctx
->builder
, LLVMIntSLE
, a
, b
, "");
2210 return LLVMBuildSelect(ctx
->builder
, cmp
, a
, b
, "");
2213 LLVMValueRef
ac_build_imax(struct ac_llvm_context
*ctx
, LLVMValueRef a
,
2216 LLVMValueRef cmp
= LLVMBuildICmp(ctx
->builder
, LLVMIntSGT
, a
, b
, "");
2217 return LLVMBuildSelect(ctx
->builder
, cmp
, a
, b
, "");
2220 LLVMValueRef
ac_build_umin(struct ac_llvm_context
*ctx
, LLVMValueRef a
,
2223 LLVMValueRef cmp
= LLVMBuildICmp(ctx
->builder
, LLVMIntULE
, a
, b
, "");
2224 return LLVMBuildSelect(ctx
->builder
, cmp
, a
, b
, "");
2227 LLVMValueRef
ac_build_umax(struct ac_llvm_context
*ctx
, LLVMValueRef a
,
2230 LLVMValueRef cmp
= LLVMBuildICmp(ctx
->builder
, LLVMIntUGE
, a
, b
, "");
2231 return LLVMBuildSelect(ctx
->builder
, cmp
, a
, b
, "");
2234 LLVMValueRef
ac_build_clamp(struct ac_llvm_context
*ctx
, LLVMValueRef value
)
2236 LLVMTypeRef t
= LLVMTypeOf(value
);
2237 return ac_build_fmin(ctx
, ac_build_fmax(ctx
, value
, LLVMConstReal(t
, 0.0)),
2238 LLVMConstReal(t
, 1.0));
2241 void ac_build_export(struct ac_llvm_context
*ctx
, struct ac_export_args
*a
)
2243 LLVMValueRef args
[9];
2245 args
[0] = LLVMConstInt(ctx
->i32
, a
->target
, 0);
2246 args
[1] = LLVMConstInt(ctx
->i32
, a
->enabled_channels
, 0);
2249 args
[2] = LLVMBuildBitCast(ctx
->builder
, a
->out
[0],
2251 args
[3] = LLVMBuildBitCast(ctx
->builder
, a
->out
[1],
2253 args
[4] = LLVMConstInt(ctx
->i1
, a
->done
, 0);
2254 args
[5] = LLVMConstInt(ctx
->i1
, a
->valid_mask
, 0);
2256 ac_build_intrinsic(ctx
, "llvm.amdgcn.exp.compr.v2i16",
2257 ctx
->voidt
, args
, 6, 0);
2259 args
[2] = a
->out
[0];
2260 args
[3] = a
->out
[1];
2261 args
[4] = a
->out
[2];
2262 args
[5] = a
->out
[3];
2263 args
[6] = LLVMConstInt(ctx
->i1
, a
->done
, 0);
2264 args
[7] = LLVMConstInt(ctx
->i1
, a
->valid_mask
, 0);
2266 ac_build_intrinsic(ctx
, "llvm.amdgcn.exp.f32",
2267 ctx
->voidt
, args
, 8, 0);
2271 void ac_build_export_null(struct ac_llvm_context
*ctx
)
2273 struct ac_export_args args
;
2275 args
.enabled_channels
= 0x0; /* enabled channels */
2276 args
.valid_mask
= 1; /* whether the EXEC mask is valid */
2277 args
.done
= 1; /* DONE bit */
2278 args
.target
= V_008DFC_SQ_EXP_NULL
;
2279 args
.compr
= 0; /* COMPR flag (0 = 32-bit export) */
2280 args
.out
[0] = LLVMGetUndef(ctx
->f32
); /* R */
2281 args
.out
[1] = LLVMGetUndef(ctx
->f32
); /* G */
2282 args
.out
[2] = LLVMGetUndef(ctx
->f32
); /* B */
2283 args
.out
[3] = LLVMGetUndef(ctx
->f32
); /* A */
2285 ac_build_export(ctx
, &args
);
2288 static unsigned ac_num_coords(enum ac_image_dim dim
)
2294 case ac_image_1darray
:
2298 case ac_image_2darray
:
2299 case ac_image_2dmsaa
:
2301 case ac_image_2darraymsaa
:
2304 unreachable("ac_num_coords: bad dim");
2308 static unsigned ac_num_derivs(enum ac_image_dim dim
)
2312 case ac_image_1darray
:
2315 case ac_image_2darray
:
2320 case ac_image_2dmsaa
:
2321 case ac_image_2darraymsaa
:
2323 unreachable("derivatives not supported");
2327 static const char *get_atomic_name(enum ac_atomic_op op
)
2330 case ac_atomic_swap
: return "swap";
2331 case ac_atomic_add
: return "add";
2332 case ac_atomic_sub
: return "sub";
2333 case ac_atomic_smin
: return "smin";
2334 case ac_atomic_umin
: return "umin";
2335 case ac_atomic_smax
: return "smax";
2336 case ac_atomic_umax
: return "umax";
2337 case ac_atomic_and
: return "and";
2338 case ac_atomic_or
: return "or";
2339 case ac_atomic_xor
: return "xor";
2340 case ac_atomic_inc_wrap
: return "inc";
2341 case ac_atomic_dec_wrap
: return "dec";
2343 unreachable("bad atomic op");
2346 LLVMValueRef
ac_build_image_opcode(struct ac_llvm_context
*ctx
,
2347 struct ac_image_args
*a
)
2349 const char *overload
[3] = { "", "", "" };
2350 unsigned num_overloads
= 0;
2351 LLVMValueRef args
[18];
2352 unsigned num_args
= 0;
2353 enum ac_image_dim dim
= a
->dim
;
2355 assert(!a
->lod
|| a
->lod
== ctx
->i32_0
|| a
->lod
== ctx
->f32_0
||
2357 assert((a
->opcode
!= ac_image_get_resinfo
&& a
->opcode
!= ac_image_load_mip
&&
2358 a
->opcode
!= ac_image_store_mip
) ||
2360 assert(a
->opcode
== ac_image_sample
|| a
->opcode
== ac_image_gather4
||
2361 (!a
->compare
&& !a
->offset
));
2362 assert((a
->opcode
== ac_image_sample
|| a
->opcode
== ac_image_gather4
||
2363 a
->opcode
== ac_image_get_lod
) ||
2365 assert((a
->bias
? 1 : 0) +
2367 (a
->level_zero
? 1 : 0) +
2368 (a
->derivs
[0] ? 1 : 0) <= 1);
2369 assert((a
->min_lod
? 1 : 0) +
2371 (a
->level_zero
? 1 : 0) <= 1);
2373 if (a
->opcode
== ac_image_get_lod
) {
2375 case ac_image_1darray
:
2378 case ac_image_2darray
:
2387 bool sample
= a
->opcode
== ac_image_sample
||
2388 a
->opcode
== ac_image_gather4
||
2389 a
->opcode
== ac_image_get_lod
;
2390 bool atomic
= a
->opcode
== ac_image_atomic
||
2391 a
->opcode
== ac_image_atomic_cmpswap
;
2392 bool load
= a
->opcode
== ac_image_sample
||
2393 a
->opcode
== ac_image_gather4
||
2394 a
->opcode
== ac_image_load
||
2395 a
->opcode
== ac_image_load_mip
;
2396 LLVMTypeRef coord_type
= sample
? ctx
->f32
: ctx
->i32
;
2398 if (atomic
|| a
->opcode
== ac_image_store
|| a
->opcode
== ac_image_store_mip
) {
2399 args
[num_args
++] = a
->data
[0];
2400 if (a
->opcode
== ac_image_atomic_cmpswap
)
2401 args
[num_args
++] = a
->data
[1];
2405 args
[num_args
++] = LLVMConstInt(ctx
->i32
, a
->dmask
, false);
2408 args
[num_args
++] = ac_to_integer(ctx
, a
->offset
);
2410 args
[num_args
++] = ac_to_float(ctx
, a
->bias
);
2411 overload
[num_overloads
++] = ".f32";
2414 args
[num_args
++] = ac_to_float(ctx
, a
->compare
);
2416 unsigned count
= ac_num_derivs(dim
);
2417 for (unsigned i
= 0; i
< count
; ++i
)
2418 args
[num_args
++] = ac_to_float(ctx
, a
->derivs
[i
]);
2419 overload
[num_overloads
++] = ".f32";
2421 unsigned num_coords
=
2422 a
->opcode
!= ac_image_get_resinfo
? ac_num_coords(dim
) : 0;
2423 for (unsigned i
= 0; i
< num_coords
; ++i
)
2424 args
[num_args
++] = LLVMBuildBitCast(ctx
->builder
, a
->coords
[i
], coord_type
, "");
2426 args
[num_args
++] = LLVMBuildBitCast(ctx
->builder
, a
->lod
, coord_type
, "");
2428 args
[num_args
++] = LLVMBuildBitCast(ctx
->builder
, a
->min_lod
, coord_type
, "");
2430 overload
[num_overloads
++] = sample
? ".f32" : ".i32";
2432 args
[num_args
++] = a
->resource
;
2434 args
[num_args
++] = a
->sampler
;
2435 args
[num_args
++] = LLVMConstInt(ctx
->i1
, a
->unorm
, false);
2438 args
[num_args
++] = ctx
->i32_0
; /* texfailctrl */
2439 args
[num_args
++] = LLVMConstInt(ctx
->i32
,
2440 load
? get_load_cache_policy(ctx
, a
->cache_policy
) :
2441 a
->cache_policy
, false);
2444 const char *atomic_subop
= "";
2445 switch (a
->opcode
) {
2446 case ac_image_sample
: name
= "sample"; break;
2447 case ac_image_gather4
: name
= "gather4"; break;
2448 case ac_image_load
: name
= "load"; break;
2449 case ac_image_load_mip
: name
= "load.mip"; break;
2450 case ac_image_store
: name
= "store"; break;
2451 case ac_image_store_mip
: name
= "store.mip"; break;
2452 case ac_image_atomic
:
2454 atomic_subop
= get_atomic_name(a
->atomic
);
2456 case ac_image_atomic_cmpswap
:
2458 atomic_subop
= "cmpswap";
2460 case ac_image_get_lod
: name
= "getlod"; break;
2461 case ac_image_get_resinfo
: name
= "getresinfo"; break;
2462 default: unreachable("invalid image opcode");
2465 const char *dimname
;
2467 case ac_image_1d
: dimname
= "1d"; break;
2468 case ac_image_2d
: dimname
= "2d"; break;
2469 case ac_image_3d
: dimname
= "3d"; break;
2470 case ac_image_cube
: dimname
= "cube"; break;
2471 case ac_image_1darray
: dimname
= "1darray"; break;
2472 case ac_image_2darray
: dimname
= "2darray"; break;
2473 case ac_image_2dmsaa
: dimname
= "2dmsaa"; break;
2474 case ac_image_2darraymsaa
: dimname
= "2darraymsaa"; break;
2475 default: unreachable("invalid dim");
2479 a
->lod
&& (a
->opcode
== ac_image_sample
|| a
->opcode
== ac_image_gather4
);
2481 snprintf(intr_name
, sizeof(intr_name
),
2482 "llvm.amdgcn.image.%s%s" /* base name */
2483 "%s%s%s%s" /* sample/gather modifiers */
2484 ".%s.%s%s%s%s", /* dimension and type overloads */
2486 a
->compare
? ".c" : "",
2489 a
->derivs
[0] ? ".d" :
2490 a
->level_zero
? ".lz" : "",
2491 a
->min_lod
? ".cl" : "",
2492 a
->offset
? ".o" : "",
2494 atomic
? "i32" : "v4f32",
2495 overload
[0], overload
[1], overload
[2]);
2500 else if (a
->opcode
== ac_image_store
|| a
->opcode
== ac_image_store_mip
)
2505 LLVMValueRef result
=
2506 ac_build_intrinsic(ctx
, intr_name
, retty
, args
, num_args
,
2508 if (!sample
&& retty
== ctx
->v4f32
) {
2509 result
= LLVMBuildBitCast(ctx
->builder
, result
,
2515 LLVMValueRef
ac_build_image_get_sample_count(struct ac_llvm_context
*ctx
,
2518 LLVMValueRef samples
;
2520 /* Read the samples from the descriptor directly.
2521 * Hardware doesn't have any instruction for this.
2523 samples
= LLVMBuildExtractElement(ctx
->builder
, rsrc
,
2524 LLVMConstInt(ctx
->i32
, 3, 0), "");
2525 samples
= LLVMBuildLShr(ctx
->builder
, samples
,
2526 LLVMConstInt(ctx
->i32
, 16, 0), "");
2527 samples
= LLVMBuildAnd(ctx
->builder
, samples
,
2528 LLVMConstInt(ctx
->i32
, 0xf, 0), "");
2529 samples
= LLVMBuildShl(ctx
->builder
, ctx
->i32_1
,
2534 LLVMValueRef
ac_build_cvt_pkrtz_f16(struct ac_llvm_context
*ctx
,
2535 LLVMValueRef args
[2])
2537 return ac_build_intrinsic(ctx
, "llvm.amdgcn.cvt.pkrtz", ctx
->v2f16
,
2538 args
, 2, AC_FUNC_ATTR_READNONE
);
2541 LLVMValueRef
ac_build_cvt_pknorm_i16(struct ac_llvm_context
*ctx
,
2542 LLVMValueRef args
[2])
2545 ac_build_intrinsic(ctx
, "llvm.amdgcn.cvt.pknorm.i16",
2546 ctx
->v2i16
, args
, 2,
2547 AC_FUNC_ATTR_READNONE
);
2548 return LLVMBuildBitCast(ctx
->builder
, res
, ctx
->i32
, "");
2551 LLVMValueRef
ac_build_cvt_pknorm_u16(struct ac_llvm_context
*ctx
,
2552 LLVMValueRef args
[2])
2555 ac_build_intrinsic(ctx
, "llvm.amdgcn.cvt.pknorm.u16",
2556 ctx
->v2i16
, args
, 2,
2557 AC_FUNC_ATTR_READNONE
);
2558 return LLVMBuildBitCast(ctx
->builder
, res
, ctx
->i32
, "");
2561 /* The 8-bit and 10-bit clamping is for HW workarounds. */
2562 LLVMValueRef
ac_build_cvt_pk_i16(struct ac_llvm_context
*ctx
,
2563 LLVMValueRef args
[2], unsigned bits
, bool hi
)
2565 assert(bits
== 8 || bits
== 10 || bits
== 16);
2567 LLVMValueRef max_rgb
= LLVMConstInt(ctx
->i32
,
2568 bits
== 8 ? 127 : bits
== 10 ? 511 : 32767, 0);
2569 LLVMValueRef min_rgb
= LLVMConstInt(ctx
->i32
,
2570 bits
== 8 ? -128 : bits
== 10 ? -512 : -32768, 0);
2571 LLVMValueRef max_alpha
=
2572 bits
!= 10 ? max_rgb
: ctx
->i32_1
;
2573 LLVMValueRef min_alpha
=
2574 bits
!= 10 ? min_rgb
: LLVMConstInt(ctx
->i32
, -2, 0);
2578 for (int i
= 0; i
< 2; i
++) {
2579 bool alpha
= hi
&& i
== 1;
2580 args
[i
] = ac_build_imin(ctx
, args
[i
],
2581 alpha
? max_alpha
: max_rgb
);
2582 args
[i
] = ac_build_imax(ctx
, args
[i
],
2583 alpha
? min_alpha
: min_rgb
);
2588 ac_build_intrinsic(ctx
, "llvm.amdgcn.cvt.pk.i16",
2589 ctx
->v2i16
, args
, 2,
2590 AC_FUNC_ATTR_READNONE
);
2591 return LLVMBuildBitCast(ctx
->builder
, res
, ctx
->i32
, "");
2594 /* The 8-bit and 10-bit clamping is for HW workarounds. */
2595 LLVMValueRef
ac_build_cvt_pk_u16(struct ac_llvm_context
*ctx
,
2596 LLVMValueRef args
[2], unsigned bits
, bool hi
)
2598 assert(bits
== 8 || bits
== 10 || bits
== 16);
2600 LLVMValueRef max_rgb
= LLVMConstInt(ctx
->i32
,
2601 bits
== 8 ? 255 : bits
== 10 ? 1023 : 65535, 0);
2602 LLVMValueRef max_alpha
=
2603 bits
!= 10 ? max_rgb
: LLVMConstInt(ctx
->i32
, 3, 0);
2607 for (int i
= 0; i
< 2; i
++) {
2608 bool alpha
= hi
&& i
== 1;
2609 args
[i
] = ac_build_umin(ctx
, args
[i
],
2610 alpha
? max_alpha
: max_rgb
);
2615 ac_build_intrinsic(ctx
, "llvm.amdgcn.cvt.pk.u16",
2616 ctx
->v2i16
, args
, 2,
2617 AC_FUNC_ATTR_READNONE
);
2618 return LLVMBuildBitCast(ctx
->builder
, res
, ctx
->i32
, "");
2621 LLVMValueRef
ac_build_wqm_vote(struct ac_llvm_context
*ctx
, LLVMValueRef i1
)
2623 return ac_build_intrinsic(ctx
, "llvm.amdgcn.wqm.vote", ctx
->i1
,
2624 &i1
, 1, AC_FUNC_ATTR_READNONE
);
2627 void ac_build_kill_if_false(struct ac_llvm_context
*ctx
, LLVMValueRef i1
)
2629 ac_build_intrinsic(ctx
, "llvm.amdgcn.kill", ctx
->voidt
,
2633 LLVMValueRef
ac_build_bfe(struct ac_llvm_context
*ctx
, LLVMValueRef input
,
2634 LLVMValueRef offset
, LLVMValueRef width
,
2637 LLVMValueRef args
[] = {
2643 return ac_build_intrinsic(ctx
, is_signed
? "llvm.amdgcn.sbfe.i32" :
2644 "llvm.amdgcn.ubfe.i32",
2645 ctx
->i32
, args
, 3, AC_FUNC_ATTR_READNONE
);
2649 LLVMValueRef
ac_build_imad(struct ac_llvm_context
*ctx
, LLVMValueRef s0
,
2650 LLVMValueRef s1
, LLVMValueRef s2
)
2652 return LLVMBuildAdd(ctx
->builder
,
2653 LLVMBuildMul(ctx
->builder
, s0
, s1
, ""), s2
, "");
2656 LLVMValueRef
ac_build_fmad(struct ac_llvm_context
*ctx
, LLVMValueRef s0
,
2657 LLVMValueRef s1
, LLVMValueRef s2
)
2659 /* FMA is better on GFX10, because it has FMA units instead of MUL-ADD units. */
2660 if (ctx
->chip_class
>= GFX10
) {
2661 return ac_build_intrinsic(ctx
, "llvm.fma.f32", ctx
->f32
,
2662 (LLVMValueRef
[]) {s0
, s1
, s2
}, 3,
2663 AC_FUNC_ATTR_READNONE
);
2666 return LLVMBuildFAdd(ctx
->builder
,
2667 LLVMBuildFMul(ctx
->builder
, s0
, s1
, ""), s2
, "");
2670 void ac_build_waitcnt(struct ac_llvm_context
*ctx
, unsigned wait_flags
)
2675 unsigned lgkmcnt
= 63;
2676 unsigned vmcnt
= ctx
->chip_class
>= GFX9
? 63 : 15;
2677 unsigned vscnt
= 63;
2679 if (wait_flags
& AC_WAIT_LGKM
)
2681 if (wait_flags
& AC_WAIT_VLOAD
)
2684 if (wait_flags
& AC_WAIT_VSTORE
) {
2685 if (ctx
->chip_class
>= GFX10
)
2691 /* There is no intrinsic for vscnt(0), so use a fence. */
2692 if ((wait_flags
& AC_WAIT_LGKM
&&
2693 wait_flags
& AC_WAIT_VLOAD
&&
2694 wait_flags
& AC_WAIT_VSTORE
) ||
2696 LLVMBuildFence(ctx
->builder
, LLVMAtomicOrderingRelease
, false, "");
2700 unsigned simm16
= (lgkmcnt
<< 8) |
2701 (7 << 4) | /* expcnt */
2703 ((vmcnt
>> 4) << 14);
2705 LLVMValueRef args
[1] = {
2706 LLVMConstInt(ctx
->i32
, simm16
, false),
2708 ac_build_intrinsic(ctx
, "llvm.amdgcn.s.waitcnt",
2709 ctx
->voidt
, args
, 1, 0);
2712 LLVMValueRef
ac_build_fmed3(struct ac_llvm_context
*ctx
, LLVMValueRef src0
,
2713 LLVMValueRef src1
, LLVMValueRef src2
,
2716 LLVMValueRef result
;
2718 if (bitsize
== 64 || (bitsize
== 16 && ctx
->chip_class
<= GFX8
)) {
2719 /* Lower 64-bit fmed because LLVM doesn't expose an intrinsic,
2720 * or lower 16-bit fmed because it's only supported on GFX9+.
2722 LLVMValueRef min1
, min2
, max1
;
2724 min1
= ac_build_fmin(ctx
, src0
, src1
);
2725 max1
= ac_build_fmax(ctx
, src0
, src1
);
2726 min2
= ac_build_fmin(ctx
, max1
, src2
);
2728 result
= ac_build_fmax(ctx
, min2
, min1
);
2733 if (bitsize
== 16) {
2734 intr
= "llvm.amdgcn.fmed3.f16";
2737 assert(bitsize
== 32);
2738 intr
= "llvm.amdgcn.fmed3.f32";
2742 LLVMValueRef params
[] = {
2748 result
= ac_build_intrinsic(ctx
, intr
, type
, params
, 3,
2749 AC_FUNC_ATTR_READNONE
);
2752 if (ctx
->chip_class
< GFX9
&& bitsize
== 32) {
2753 /* Only pre-GFX9 chips do not flush denorms. */
2754 result
= ac_build_canonicalize(ctx
, result
, bitsize
);
2760 LLVMValueRef
ac_build_fract(struct ac_llvm_context
*ctx
, LLVMValueRef src0
,
2766 if (bitsize
== 16) {
2767 intr
= "llvm.amdgcn.fract.f16";
2769 } else if (bitsize
== 32) {
2770 intr
= "llvm.amdgcn.fract.f32";
2773 intr
= "llvm.amdgcn.fract.f64";
2777 LLVMValueRef params
[] = {
2780 return ac_build_intrinsic(ctx
, intr
, type
, params
, 1,
2781 AC_FUNC_ATTR_READNONE
);
2784 LLVMValueRef
ac_build_isign(struct ac_llvm_context
*ctx
, LLVMValueRef src0
,
2787 LLVMTypeRef type
= LLVMIntTypeInContext(ctx
->context
, bitsize
);
2788 LLVMValueRef zero
= LLVMConstInt(type
, 0, false);
2789 LLVMValueRef one
= LLVMConstInt(type
, 1, false);
2791 LLVMValueRef cmp
, val
;
2792 cmp
= LLVMBuildICmp(ctx
->builder
, LLVMIntSGT
, src0
, zero
, "");
2793 val
= LLVMBuildSelect(ctx
->builder
, cmp
, one
, src0
, "");
2794 cmp
= LLVMBuildICmp(ctx
->builder
, LLVMIntSGE
, val
, zero
, "");
2795 val
= LLVMBuildSelect(ctx
->builder
, cmp
, val
, LLVMConstInt(type
, -1, true), "");
2799 LLVMValueRef
ac_build_fsign(struct ac_llvm_context
*ctx
, LLVMValueRef src0
,
2802 LLVMValueRef cmp
, val
, zero
, one
;
2805 if (bitsize
== 16) {
2809 } else if (bitsize
== 32) {
2819 cmp
= LLVMBuildFCmp(ctx
->builder
, LLVMRealOGT
, src0
, zero
, "");
2820 val
= LLVMBuildSelect(ctx
->builder
, cmp
, one
, src0
, "");
2821 cmp
= LLVMBuildFCmp(ctx
->builder
, LLVMRealOGE
, val
, zero
, "");
2822 val
= LLVMBuildSelect(ctx
->builder
, cmp
, val
, LLVMConstReal(type
, -1.0), "");
2826 LLVMValueRef
ac_build_bit_count(struct ac_llvm_context
*ctx
, LLVMValueRef src0
)
2828 LLVMValueRef result
;
2831 bitsize
= ac_get_elem_bits(ctx
, LLVMTypeOf(src0
));
2835 result
= ac_build_intrinsic(ctx
, "llvm.ctpop.i128", ctx
->i128
,
2836 (LLVMValueRef
[]) { src0
}, 1,
2837 AC_FUNC_ATTR_READNONE
);
2838 result
= LLVMBuildTrunc(ctx
->builder
, result
, ctx
->i32
, "");
2841 result
= ac_build_intrinsic(ctx
, "llvm.ctpop.i64", ctx
->i64
,
2842 (LLVMValueRef
[]) { src0
}, 1,
2843 AC_FUNC_ATTR_READNONE
);
2845 result
= LLVMBuildTrunc(ctx
->builder
, result
, ctx
->i32
, "");
2848 result
= ac_build_intrinsic(ctx
, "llvm.ctpop.i32", ctx
->i32
,
2849 (LLVMValueRef
[]) { src0
}, 1,
2850 AC_FUNC_ATTR_READNONE
);
2853 result
= ac_build_intrinsic(ctx
, "llvm.ctpop.i16", ctx
->i16
,
2854 (LLVMValueRef
[]) { src0
}, 1,
2855 AC_FUNC_ATTR_READNONE
);
2857 result
= LLVMBuildZExt(ctx
->builder
, result
, ctx
->i32
, "");
2860 result
= ac_build_intrinsic(ctx
, "llvm.ctpop.i8", ctx
->i8
,
2861 (LLVMValueRef
[]) { src0
}, 1,
2862 AC_FUNC_ATTR_READNONE
);
2864 result
= LLVMBuildZExt(ctx
->builder
, result
, ctx
->i32
, "");
2867 unreachable(!"invalid bitsize");
2874 LLVMValueRef
ac_build_bitfield_reverse(struct ac_llvm_context
*ctx
,
2877 LLVMValueRef result
;
2880 bitsize
= ac_get_elem_bits(ctx
, LLVMTypeOf(src0
));
2884 result
= ac_build_intrinsic(ctx
, "llvm.bitreverse.i64", ctx
->i64
,
2885 (LLVMValueRef
[]) { src0
}, 1,
2886 AC_FUNC_ATTR_READNONE
);
2888 result
= LLVMBuildTrunc(ctx
->builder
, result
, ctx
->i32
, "");
2891 result
= ac_build_intrinsic(ctx
, "llvm.bitreverse.i32", ctx
->i32
,
2892 (LLVMValueRef
[]) { src0
}, 1,
2893 AC_FUNC_ATTR_READNONE
);
2896 result
= ac_build_intrinsic(ctx
, "llvm.bitreverse.i16", ctx
->i16
,
2897 (LLVMValueRef
[]) { src0
}, 1,
2898 AC_FUNC_ATTR_READNONE
);
2900 result
= LLVMBuildZExt(ctx
->builder
, result
, ctx
->i32
, "");
2903 result
= ac_build_intrinsic(ctx
, "llvm.bitreverse.i8", ctx
->i8
,
2904 (LLVMValueRef
[]) { src0
}, 1,
2905 AC_FUNC_ATTR_READNONE
);
2907 result
= LLVMBuildZExt(ctx
->builder
, result
, ctx
->i32
, "");
2910 unreachable(!"invalid bitsize");
2917 #define AC_EXP_TARGET 0
2918 #define AC_EXP_ENABLED_CHANNELS 1
2919 #define AC_EXP_OUT0 2
2927 struct ac_vs_exp_chan
2931 enum ac_ir_type type
;
2934 struct ac_vs_exp_inst
{
2937 struct ac_vs_exp_chan chan
[4];
2940 struct ac_vs_exports
{
2942 struct ac_vs_exp_inst exp
[VARYING_SLOT_MAX
];
2945 /* Return true if the PARAM export has been eliminated. */
2946 static bool ac_eliminate_const_output(uint8_t *vs_output_param_offset
,
2947 uint32_t num_outputs
,
2948 struct ac_vs_exp_inst
*exp
)
2950 unsigned i
, default_val
; /* SPI_PS_INPUT_CNTL_i.DEFAULT_VAL */
2951 bool is_zero
[4] = {}, is_one
[4] = {};
2953 for (i
= 0; i
< 4; i
++) {
2954 /* It's a constant expression. Undef outputs are eliminated too. */
2955 if (exp
->chan
[i
].type
== AC_IR_UNDEF
) {
2958 } else if (exp
->chan
[i
].type
== AC_IR_CONST
) {
2959 if (exp
->chan
[i
].const_float
== 0)
2961 else if (exp
->chan
[i
].const_float
== 1)
2964 return false; /* other constant */
2969 /* Only certain combinations of 0 and 1 can be eliminated. */
2970 if (is_zero
[0] && is_zero
[1] && is_zero
[2])
2971 default_val
= is_zero
[3] ? 0 : 1;
2972 else if (is_one
[0] && is_one
[1] && is_one
[2])
2973 default_val
= is_zero
[3] ? 2 : 3;
2977 /* The PARAM export can be represented as DEFAULT_VAL. Kill it. */
2978 LLVMInstructionEraseFromParent(exp
->inst
);
2980 /* Change OFFSET to DEFAULT_VAL. */
2981 for (i
= 0; i
< num_outputs
; i
++) {
2982 if (vs_output_param_offset
[i
] == exp
->offset
) {
2983 vs_output_param_offset
[i
] =
2984 AC_EXP_PARAM_DEFAULT_VAL_0000
+ default_val
;
2991 static bool ac_eliminate_duplicated_output(struct ac_llvm_context
*ctx
,
2992 uint8_t *vs_output_param_offset
,
2993 uint32_t num_outputs
,
2994 struct ac_vs_exports
*processed
,
2995 struct ac_vs_exp_inst
*exp
)
2997 unsigned p
, copy_back_channels
= 0;
2999 /* See if the output is already in the list of processed outputs.
3000 * The LLVMValueRef comparison relies on SSA.
3002 for (p
= 0; p
< processed
->num
; p
++) {
3003 bool different
= false;
3005 for (unsigned j
= 0; j
< 4; j
++) {
3006 struct ac_vs_exp_chan
*c1
= &processed
->exp
[p
].chan
[j
];
3007 struct ac_vs_exp_chan
*c2
= &exp
->chan
[j
];
3009 /* Treat undef as a match. */
3010 if (c2
->type
== AC_IR_UNDEF
)
3013 /* If c1 is undef but c2 isn't, we can copy c2 to c1
3014 * and consider the instruction duplicated.
3016 if (c1
->type
== AC_IR_UNDEF
) {
3017 copy_back_channels
|= 1 << j
;
3021 /* Test whether the channels are not equal. */
3022 if (c1
->type
!= c2
->type
||
3023 (c1
->type
== AC_IR_CONST
&&
3024 c1
->const_float
!= c2
->const_float
) ||
3025 (c1
->type
== AC_IR_VALUE
&&
3026 c1
->value
!= c2
->value
)) {
3034 copy_back_channels
= 0;
3036 if (p
== processed
->num
)
3039 /* If a match was found, but the matching export has undef where the new
3040 * one has a normal value, copy the normal value to the undef channel.
3042 struct ac_vs_exp_inst
*match
= &processed
->exp
[p
];
3044 /* Get current enabled channels mask. */
3045 LLVMValueRef arg
= LLVMGetOperand(match
->inst
, AC_EXP_ENABLED_CHANNELS
);
3046 unsigned enabled_channels
= LLVMConstIntGetZExtValue(arg
);
3048 while (copy_back_channels
) {
3049 unsigned chan
= u_bit_scan(©_back_channels
);
3051 assert(match
->chan
[chan
].type
== AC_IR_UNDEF
);
3052 LLVMSetOperand(match
->inst
, AC_EXP_OUT0
+ chan
,
3053 exp
->chan
[chan
].value
);
3054 match
->chan
[chan
] = exp
->chan
[chan
];
3056 /* Update number of enabled channels because the original mask
3057 * is not always 0xf.
3059 enabled_channels
|= (1 << chan
);
3060 LLVMSetOperand(match
->inst
, AC_EXP_ENABLED_CHANNELS
,
3061 LLVMConstInt(ctx
->i32
, enabled_channels
, 0));
3064 /* The PARAM export is duplicated. Kill it. */
3065 LLVMInstructionEraseFromParent(exp
->inst
);
3067 /* Change OFFSET to the matching export. */
3068 for (unsigned i
= 0; i
< num_outputs
; i
++) {
3069 if (vs_output_param_offset
[i
] == exp
->offset
) {
3070 vs_output_param_offset
[i
] = match
->offset
;
3077 void ac_optimize_vs_outputs(struct ac_llvm_context
*ctx
,
3078 LLVMValueRef main_fn
,
3079 uint8_t *vs_output_param_offset
,
3080 uint32_t num_outputs
,
3081 uint32_t skip_output_mask
,
3082 uint8_t *num_param_exports
)
3084 LLVMBasicBlockRef bb
;
3085 bool removed_any
= false;
3086 struct ac_vs_exports exports
;
3090 /* Process all LLVM instructions. */
3091 bb
= LLVMGetFirstBasicBlock(main_fn
);
3093 LLVMValueRef inst
= LLVMGetFirstInstruction(bb
);
3096 LLVMValueRef cur
= inst
;
3097 inst
= LLVMGetNextInstruction(inst
);
3098 struct ac_vs_exp_inst exp
;
3100 if (LLVMGetInstructionOpcode(cur
) != LLVMCall
)
3103 LLVMValueRef callee
= ac_llvm_get_called_value(cur
);
3105 if (!ac_llvm_is_function(callee
))
3108 const char *name
= LLVMGetValueName(callee
);
3109 unsigned num_args
= LLVMCountParams(callee
);
3111 /* Check if this is an export instruction. */
3112 if ((num_args
!= 9 && num_args
!= 8) ||
3113 (strcmp(name
, "llvm.SI.export") &&
3114 strcmp(name
, "llvm.amdgcn.exp.f32")))
3117 LLVMValueRef arg
= LLVMGetOperand(cur
, AC_EXP_TARGET
);
3118 unsigned target
= LLVMConstIntGetZExtValue(arg
);
3120 if (target
< V_008DFC_SQ_EXP_PARAM
)
3123 target
-= V_008DFC_SQ_EXP_PARAM
;
3125 /* Parse the instruction. */
3126 memset(&exp
, 0, sizeof(exp
));
3127 exp
.offset
= target
;
3130 for (unsigned i
= 0; i
< 4; i
++) {
3131 LLVMValueRef v
= LLVMGetOperand(cur
, AC_EXP_OUT0
+ i
);
3133 exp
.chan
[i
].value
= v
;
3135 if (LLVMIsUndef(v
)) {
3136 exp
.chan
[i
].type
= AC_IR_UNDEF
;
3137 } else if (LLVMIsAConstantFP(v
)) {
3138 LLVMBool loses_info
;
3139 exp
.chan
[i
].type
= AC_IR_CONST
;
3140 exp
.chan
[i
].const_float
=
3141 LLVMConstRealGetDouble(v
, &loses_info
);
3143 exp
.chan
[i
].type
= AC_IR_VALUE
;
3147 /* Eliminate constant and duplicated PARAM exports. */
3148 if (!((1u << target
) & skip_output_mask
) &&
3149 (ac_eliminate_const_output(vs_output_param_offset
,
3150 num_outputs
, &exp
) ||
3151 ac_eliminate_duplicated_output(ctx
,
3152 vs_output_param_offset
,
3153 num_outputs
, &exports
,
3157 exports
.exp
[exports
.num
++] = exp
;
3160 bb
= LLVMGetNextBasicBlock(bb
);
3163 /* Remove holes in export memory due to removed PARAM exports.
3164 * This is done by renumbering all PARAM exports.
3167 uint8_t old_offset
[VARYING_SLOT_MAX
];
3170 /* Make a copy of the offsets. We need the old version while
3171 * we are modifying some of them. */
3172 memcpy(old_offset
, vs_output_param_offset
,
3173 sizeof(old_offset
));
3175 for (i
= 0; i
< exports
.num
; i
++) {
3176 unsigned offset
= exports
.exp
[i
].offset
;
3178 /* Update vs_output_param_offset. Multiple outputs can
3179 * have the same offset.
3181 for (out
= 0; out
< num_outputs
; out
++) {
3182 if (old_offset
[out
] == offset
)
3183 vs_output_param_offset
[out
] = i
;
3186 /* Change the PARAM offset in the instruction. */
3187 LLVMSetOperand(exports
.exp
[i
].inst
, AC_EXP_TARGET
,
3188 LLVMConstInt(ctx
->i32
,
3189 V_008DFC_SQ_EXP_PARAM
+ i
, 0));
3191 *num_param_exports
= exports
.num
;
3195 void ac_init_exec_full_mask(struct ac_llvm_context
*ctx
)
3197 LLVMValueRef full_mask
= LLVMConstInt(ctx
->i64
, ~0ull, 0);
3198 ac_build_intrinsic(ctx
,
3199 "llvm.amdgcn.init.exec", ctx
->voidt
,
3200 &full_mask
, 1, AC_FUNC_ATTR_CONVERGENT
);
3203 void ac_declare_lds_as_pointer(struct ac_llvm_context
*ctx
)
3205 unsigned lds_size
= ctx
->chip_class
>= GFX7
? 65536 : 32768;
3206 ctx
->lds
= LLVMBuildIntToPtr(ctx
->builder
, ctx
->i32_0
,
3207 LLVMPointerType(LLVMArrayType(ctx
->i32
, lds_size
/ 4), AC_ADDR_SPACE_LDS
),
3211 LLVMValueRef
ac_lds_load(struct ac_llvm_context
*ctx
,
3212 LLVMValueRef dw_addr
)
3214 return LLVMBuildLoad(ctx
->builder
, ac_build_gep0(ctx
, ctx
->lds
, dw_addr
), "");
3217 void ac_lds_store(struct ac_llvm_context
*ctx
,
3218 LLVMValueRef dw_addr
,
3221 value
= ac_to_integer(ctx
, value
);
3222 ac_build_indexed_store(ctx
, ctx
->lds
,
3226 LLVMValueRef
ac_find_lsb(struct ac_llvm_context
*ctx
,
3227 LLVMTypeRef dst_type
,
3230 unsigned src0_bitsize
= ac_get_elem_bits(ctx
, LLVMTypeOf(src0
));
3231 const char *intrin_name
;
3235 switch (src0_bitsize
) {
3237 intrin_name
= "llvm.cttz.i64";
3242 intrin_name
= "llvm.cttz.i32";
3247 intrin_name
= "llvm.cttz.i16";
3252 intrin_name
= "llvm.cttz.i8";
3257 unreachable(!"invalid bitsize");
3260 LLVMValueRef params
[2] = {
3263 /* The value of 1 means that ffs(x=0) = undef, so LLVM won't
3264 * add special code to check for x=0. The reason is that
3265 * the LLVM behavior for x=0 is different from what we
3266 * need here. However, LLVM also assumes that ffs(x) is
3267 * in [0, 31], but GLSL expects that ffs(0) = -1, so
3268 * a conditional assignment to handle 0 is still required.
3270 * The hardware already implements the correct behavior.
3275 LLVMValueRef lsb
= ac_build_intrinsic(ctx
, intrin_name
, type
,
3277 AC_FUNC_ATTR_READNONE
);
3279 if (src0_bitsize
== 64) {
3280 lsb
= LLVMBuildTrunc(ctx
->builder
, lsb
, ctx
->i32
, "");
3281 } else if (src0_bitsize
< 32) {
3282 lsb
= LLVMBuildSExt(ctx
->builder
, lsb
, ctx
->i32
, "");
3285 /* TODO: We need an intrinsic to skip this conditional. */
3286 /* Check for zero: */
3287 return LLVMBuildSelect(ctx
->builder
, LLVMBuildICmp(ctx
->builder
,
3290 LLVMConstInt(ctx
->i32
, -1, 0), lsb
, "");
3293 LLVMTypeRef
ac_array_in_const_addr_space(LLVMTypeRef elem_type
)
3295 return LLVMPointerType(elem_type
, AC_ADDR_SPACE_CONST
);
3298 LLVMTypeRef
ac_array_in_const32_addr_space(LLVMTypeRef elem_type
)
3300 return LLVMPointerType(elem_type
, AC_ADDR_SPACE_CONST_32BIT
);
3303 static struct ac_llvm_flow
*
3304 get_current_flow(struct ac_llvm_context
*ctx
)
3306 if (ctx
->flow
->depth
> 0)
3307 return &ctx
->flow
->stack
[ctx
->flow
->depth
- 1];
3311 static struct ac_llvm_flow
*
3312 get_innermost_loop(struct ac_llvm_context
*ctx
)
3314 for (unsigned i
= ctx
->flow
->depth
; i
> 0; --i
) {
3315 if (ctx
->flow
->stack
[i
- 1].loop_entry_block
)
3316 return &ctx
->flow
->stack
[i
- 1];
3321 static struct ac_llvm_flow
*
3322 push_flow(struct ac_llvm_context
*ctx
)
3324 struct ac_llvm_flow
*flow
;
3326 if (ctx
->flow
->depth
>= ctx
->flow
->depth_max
) {
3327 unsigned new_max
= MAX2(ctx
->flow
->depth
<< 1,
3328 AC_LLVM_INITIAL_CF_DEPTH
);
3330 ctx
->flow
->stack
= realloc(ctx
->flow
->stack
, new_max
* sizeof(*ctx
->flow
->stack
));
3331 ctx
->flow
->depth_max
= new_max
;
3334 flow
= &ctx
->flow
->stack
[ctx
->flow
->depth
];
3337 flow
->next_block
= NULL
;
3338 flow
->loop_entry_block
= NULL
;
3342 static void set_basicblock_name(LLVMBasicBlockRef bb
, const char *base
,
3346 snprintf(buf
, sizeof(buf
), "%s%d", base
, label_id
);
3347 LLVMSetValueName(LLVMBasicBlockAsValue(bb
), buf
);
3350 /* Append a basic block at the level of the parent flow.
3352 static LLVMBasicBlockRef
append_basic_block(struct ac_llvm_context
*ctx
,
3355 assert(ctx
->flow
->depth
>= 1);
3357 if (ctx
->flow
->depth
>= 2) {
3358 struct ac_llvm_flow
*flow
= &ctx
->flow
->stack
[ctx
->flow
->depth
- 2];
3360 return LLVMInsertBasicBlockInContext(ctx
->context
,
3361 flow
->next_block
, name
);
3364 LLVMValueRef main_fn
=
3365 LLVMGetBasicBlockParent(LLVMGetInsertBlock(ctx
->builder
));
3366 return LLVMAppendBasicBlockInContext(ctx
->context
, main_fn
, name
);
3369 /* Emit a branch to the given default target for the current block if
3370 * applicable -- that is, if the current block does not already contain a
3371 * branch from a break or continue.
3373 static void emit_default_branch(LLVMBuilderRef builder
,
3374 LLVMBasicBlockRef target
)
3376 if (!LLVMGetBasicBlockTerminator(LLVMGetInsertBlock(builder
)))
3377 LLVMBuildBr(builder
, target
);
3380 void ac_build_bgnloop(struct ac_llvm_context
*ctx
, int label_id
)
3382 struct ac_llvm_flow
*flow
= push_flow(ctx
);
3383 flow
->loop_entry_block
= append_basic_block(ctx
, "LOOP");
3384 flow
->next_block
= append_basic_block(ctx
, "ENDLOOP");
3385 set_basicblock_name(flow
->loop_entry_block
, "loop", label_id
);
3386 LLVMBuildBr(ctx
->builder
, flow
->loop_entry_block
);
3387 LLVMPositionBuilderAtEnd(ctx
->builder
, flow
->loop_entry_block
);
3390 void ac_build_break(struct ac_llvm_context
*ctx
)
3392 struct ac_llvm_flow
*flow
= get_innermost_loop(ctx
);
3393 LLVMBuildBr(ctx
->builder
, flow
->next_block
);
3396 void ac_build_continue(struct ac_llvm_context
*ctx
)
3398 struct ac_llvm_flow
*flow
= get_innermost_loop(ctx
);
3399 LLVMBuildBr(ctx
->builder
, flow
->loop_entry_block
);
3402 void ac_build_else(struct ac_llvm_context
*ctx
, int label_id
)
3404 struct ac_llvm_flow
*current_branch
= get_current_flow(ctx
);
3405 LLVMBasicBlockRef endif_block
;
3407 assert(!current_branch
->loop_entry_block
);
3409 endif_block
= append_basic_block(ctx
, "ENDIF");
3410 emit_default_branch(ctx
->builder
, endif_block
);
3412 LLVMPositionBuilderAtEnd(ctx
->builder
, current_branch
->next_block
);
3413 set_basicblock_name(current_branch
->next_block
, "else", label_id
);
3415 current_branch
->next_block
= endif_block
;
3418 void ac_build_endif(struct ac_llvm_context
*ctx
, int label_id
)
3420 struct ac_llvm_flow
*current_branch
= get_current_flow(ctx
);
3422 assert(!current_branch
->loop_entry_block
);
3424 emit_default_branch(ctx
->builder
, current_branch
->next_block
);
3425 LLVMPositionBuilderAtEnd(ctx
->builder
, current_branch
->next_block
);
3426 set_basicblock_name(current_branch
->next_block
, "endif", label_id
);
3431 void ac_build_endloop(struct ac_llvm_context
*ctx
, int label_id
)
3433 struct ac_llvm_flow
*current_loop
= get_current_flow(ctx
);
3435 assert(current_loop
->loop_entry_block
);
3437 emit_default_branch(ctx
->builder
, current_loop
->loop_entry_block
);
3439 LLVMPositionBuilderAtEnd(ctx
->builder
, current_loop
->next_block
);
3440 set_basicblock_name(current_loop
->next_block
, "endloop", label_id
);
3444 void ac_build_ifcc(struct ac_llvm_context
*ctx
, LLVMValueRef cond
, int label_id
)
3446 struct ac_llvm_flow
*flow
= push_flow(ctx
);
3447 LLVMBasicBlockRef if_block
;
3449 if_block
= append_basic_block(ctx
, "IF");
3450 flow
->next_block
= append_basic_block(ctx
, "ELSE");
3451 set_basicblock_name(if_block
, "if", label_id
);
3452 LLVMBuildCondBr(ctx
->builder
, cond
, if_block
, flow
->next_block
);
3453 LLVMPositionBuilderAtEnd(ctx
->builder
, if_block
);
3456 void ac_build_if(struct ac_llvm_context
*ctx
, LLVMValueRef value
,
3459 LLVMValueRef cond
= LLVMBuildFCmp(ctx
->builder
, LLVMRealUNE
,
3460 value
, ctx
->f32_0
, "");
3461 ac_build_ifcc(ctx
, cond
, label_id
);
3464 void ac_build_uif(struct ac_llvm_context
*ctx
, LLVMValueRef value
,
3467 LLVMValueRef cond
= LLVMBuildICmp(ctx
->builder
, LLVMIntNE
,
3468 ac_to_integer(ctx
, value
),
3470 ac_build_ifcc(ctx
, cond
, label_id
);
3473 LLVMValueRef
ac_build_alloca_undef(struct ac_llvm_context
*ac
, LLVMTypeRef type
,
3476 LLVMBuilderRef builder
= ac
->builder
;
3477 LLVMBasicBlockRef current_block
= LLVMGetInsertBlock(builder
);
3478 LLVMValueRef function
= LLVMGetBasicBlockParent(current_block
);
3479 LLVMBasicBlockRef first_block
= LLVMGetEntryBasicBlock(function
);
3480 LLVMValueRef first_instr
= LLVMGetFirstInstruction(first_block
);
3481 LLVMBuilderRef first_builder
= LLVMCreateBuilderInContext(ac
->context
);
3485 LLVMPositionBuilderBefore(first_builder
, first_instr
);
3487 LLVMPositionBuilderAtEnd(first_builder
, first_block
);
3490 res
= LLVMBuildAlloca(first_builder
, type
, name
);
3491 LLVMDisposeBuilder(first_builder
);
3495 LLVMValueRef
ac_build_alloca(struct ac_llvm_context
*ac
,
3496 LLVMTypeRef type
, const char *name
)
3498 LLVMValueRef ptr
= ac_build_alloca_undef(ac
, type
, name
);
3499 LLVMBuildStore(ac
->builder
, LLVMConstNull(type
), ptr
);
3503 LLVMValueRef
ac_cast_ptr(struct ac_llvm_context
*ctx
, LLVMValueRef ptr
,
3506 int addr_space
= LLVMGetPointerAddressSpace(LLVMTypeOf(ptr
));
3507 return LLVMBuildBitCast(ctx
->builder
, ptr
,
3508 LLVMPointerType(type
, addr_space
), "");
3511 LLVMValueRef
ac_trim_vector(struct ac_llvm_context
*ctx
, LLVMValueRef value
,
3514 unsigned num_components
= ac_get_llvm_num_components(value
);
3515 if (count
== num_components
)
3518 LLVMValueRef masks
[MAX2(count
, 2)];
3519 masks
[0] = ctx
->i32_0
;
3520 masks
[1] = ctx
->i32_1
;
3521 for (unsigned i
= 2; i
< count
; i
++)
3522 masks
[i
] = LLVMConstInt(ctx
->i32
, i
, false);
3525 return LLVMBuildExtractElement(ctx
->builder
, value
, masks
[0],
3528 LLVMValueRef swizzle
= LLVMConstVector(masks
, count
);
3529 return LLVMBuildShuffleVector(ctx
->builder
, value
, value
, swizzle
, "");
3532 LLVMValueRef
ac_unpack_param(struct ac_llvm_context
*ctx
, LLVMValueRef param
,
3533 unsigned rshift
, unsigned bitwidth
)
3535 LLVMValueRef value
= param
;
3537 value
= LLVMBuildLShr(ctx
->builder
, value
,
3538 LLVMConstInt(ctx
->i32
, rshift
, false), "");
3540 if (rshift
+ bitwidth
< 32) {
3541 unsigned mask
= (1 << bitwidth
) - 1;
3542 value
= LLVMBuildAnd(ctx
->builder
, value
,
3543 LLVMConstInt(ctx
->i32
, mask
, false), "");
3548 /* Adjust the sample index according to FMASK.
3550 * For uncompressed MSAA surfaces, FMASK should return 0x76543210,
3551 * which is the identity mapping. Each nibble says which physical sample
3552 * should be fetched to get that sample.
3554 * For example, 0x11111100 means there are only 2 samples stored and
3555 * the second sample covers 3/4 of the pixel. When reading samples 0
3556 * and 1, return physical sample 0 (determined by the first two 0s
3557 * in FMASK), otherwise return physical sample 1.
3559 * The sample index should be adjusted as follows:
3560 * addr[sample_index] = (fmask >> (addr[sample_index] * 4)) & 0xF;
3562 void ac_apply_fmask_to_sample(struct ac_llvm_context
*ac
, LLVMValueRef fmask
,
3563 LLVMValueRef
*addr
, bool is_array_tex
)
3565 struct ac_image_args fmask_load
= {};
3566 fmask_load
.opcode
= ac_image_load
;
3567 fmask_load
.resource
= fmask
;
3568 fmask_load
.dmask
= 0xf;
3569 fmask_load
.dim
= is_array_tex
? ac_image_2darray
: ac_image_2d
;
3570 fmask_load
.attributes
= AC_FUNC_ATTR_READNONE
;
3572 fmask_load
.coords
[0] = addr
[0];
3573 fmask_load
.coords
[1] = addr
[1];
3575 fmask_load
.coords
[2] = addr
[2];
3577 LLVMValueRef fmask_value
= ac_build_image_opcode(ac
, &fmask_load
);
3578 fmask_value
= LLVMBuildExtractElement(ac
->builder
, fmask_value
,
3581 /* Apply the formula. */
3582 unsigned sample_chan
= is_array_tex
? 3 : 2;
3583 LLVMValueRef final_sample
;
3584 final_sample
= LLVMBuildMul(ac
->builder
, addr
[sample_chan
],
3585 LLVMConstInt(ac
->i32
, 4, 0), "");
3586 final_sample
= LLVMBuildLShr(ac
->builder
, fmask_value
, final_sample
, "");
3587 /* Mask the sample index by 0x7, because 0x8 means an unknown value
3588 * with EQAA, so those will map to 0. */
3589 final_sample
= LLVMBuildAnd(ac
->builder
, final_sample
,
3590 LLVMConstInt(ac
->i32
, 0x7, 0), "");
3592 /* Don't rewrite the sample index if WORD1.DATA_FORMAT of the FMASK
3593 * resource descriptor is 0 (invalid).
3596 tmp
= LLVMBuildBitCast(ac
->builder
, fmask
, ac
->v8i32
, "");
3597 tmp
= LLVMBuildExtractElement(ac
->builder
, tmp
, ac
->i32_1
, "");
3598 tmp
= LLVMBuildICmp(ac
->builder
, LLVMIntNE
, tmp
, ac
->i32_0
, "");
3600 /* Replace the MSAA sample index. */
3601 addr
[sample_chan
] = LLVMBuildSelect(ac
->builder
, tmp
, final_sample
,
3602 addr
[sample_chan
], "");
3606 _ac_build_readlane(struct ac_llvm_context
*ctx
, LLVMValueRef src
,
3607 LLVMValueRef lane
, bool with_opt_barrier
)
3609 LLVMTypeRef type
= LLVMTypeOf(src
);
3610 LLVMValueRef result
;
3612 if (with_opt_barrier
)
3613 ac_build_optimization_barrier(ctx
, &src
);
3615 src
= LLVMBuildZExt(ctx
->builder
, src
, ctx
->i32
, "");
3617 lane
= LLVMBuildZExt(ctx
->builder
, lane
, ctx
->i32
, "");
3619 result
= ac_build_intrinsic(ctx
,
3620 lane
== NULL
? "llvm.amdgcn.readfirstlane" : "llvm.amdgcn.readlane",
3621 ctx
->i32
, (LLVMValueRef
[]) { src
, lane
},
3622 lane
== NULL
? 1 : 2,
3623 AC_FUNC_ATTR_READNONE
|
3624 AC_FUNC_ATTR_CONVERGENT
);
3626 return LLVMBuildTrunc(ctx
->builder
, result
, type
, "");
3630 ac_build_readlane_common(struct ac_llvm_context
*ctx
,
3631 LLVMValueRef src
, LLVMValueRef lane
,
3632 bool with_opt_barrier
)
3634 LLVMTypeRef src_type
= LLVMTypeOf(src
);
3635 src
= ac_to_integer(ctx
, src
);
3636 unsigned bits
= LLVMGetIntTypeWidth(LLVMTypeOf(src
));
3640 assert(bits
% 32 == 0);
3641 LLVMTypeRef vec_type
= LLVMVectorType(ctx
->i32
, bits
/ 32);
3642 LLVMValueRef src_vector
=
3643 LLVMBuildBitCast(ctx
->builder
, src
, vec_type
, "");
3644 ret
= LLVMGetUndef(vec_type
);
3645 for (unsigned i
= 0; i
< bits
/ 32; i
++) {
3646 LLVMValueRef ret_comp
;
3648 src
= LLVMBuildExtractElement(ctx
->builder
, src_vector
,
3649 LLVMConstInt(ctx
->i32
, i
, 0), "");
3651 ret_comp
= _ac_build_readlane(ctx
, src
, lane
,
3654 ret
= LLVMBuildInsertElement(ctx
->builder
, ret
, ret_comp
,
3655 LLVMConstInt(ctx
->i32
, i
, 0), "");
3658 ret
= _ac_build_readlane(ctx
, src
, lane
, with_opt_barrier
);
3661 if (LLVMGetTypeKind(src_type
) == LLVMPointerTypeKind
)
3662 return LLVMBuildIntToPtr(ctx
->builder
, ret
, src_type
, "");
3663 return LLVMBuildBitCast(ctx
->builder
, ret
, src_type
, "");
3667 * Builds the "llvm.amdgcn.readlane" or "llvm.amdgcn.readfirstlane" intrinsic.
3669 * The optimization barrier is not needed if the value is the same in all lanes
3670 * or if this is called in the outermost block.
3674 * @param lane - id of the lane or NULL for the first active lane
3675 * @return value of the lane
3677 LLVMValueRef
ac_build_readlane_no_opt_barrier(struct ac_llvm_context
*ctx
,
3678 LLVMValueRef src
, LLVMValueRef lane
)
3680 return ac_build_readlane_common(ctx
, src
, lane
, false);
3685 ac_build_readlane(struct ac_llvm_context
*ctx
, LLVMValueRef src
, LLVMValueRef lane
)
3687 return ac_build_readlane_common(ctx
, src
, lane
, true);
3691 ac_build_writelane(struct ac_llvm_context
*ctx
, LLVMValueRef src
, LLVMValueRef value
, LLVMValueRef lane
)
3693 return ac_build_intrinsic(ctx
, "llvm.amdgcn.writelane", ctx
->i32
,
3694 (LLVMValueRef
[]) {value
, lane
, src
}, 3,
3695 AC_FUNC_ATTR_READNONE
| AC_FUNC_ATTR_CONVERGENT
);
3699 ac_build_mbcnt(struct ac_llvm_context
*ctx
, LLVMValueRef mask
)
3701 if (ctx
->wave_size
== 32) {
3702 return ac_build_intrinsic(ctx
, "llvm.amdgcn.mbcnt.lo", ctx
->i32
,
3703 (LLVMValueRef
[]) { mask
, ctx
->i32_0
},
3704 2, AC_FUNC_ATTR_READNONE
);
3706 LLVMValueRef mask_vec
= LLVMBuildBitCast(ctx
->builder
, mask
, ctx
->v2i32
, "");
3707 LLVMValueRef mask_lo
= LLVMBuildExtractElement(ctx
->builder
, mask_vec
,
3709 LLVMValueRef mask_hi
= LLVMBuildExtractElement(ctx
->builder
, mask_vec
,
3712 ac_build_intrinsic(ctx
, "llvm.amdgcn.mbcnt.lo", ctx
->i32
,
3713 (LLVMValueRef
[]) { mask_lo
, ctx
->i32_0
},
3714 2, AC_FUNC_ATTR_READNONE
);
3715 val
= ac_build_intrinsic(ctx
, "llvm.amdgcn.mbcnt.hi", ctx
->i32
,
3716 (LLVMValueRef
[]) { mask_hi
, val
},
3717 2, AC_FUNC_ATTR_READNONE
);
3722 _dpp_quad_perm
= 0x000,
3723 _dpp_row_sl
= 0x100,
3724 _dpp_row_sr
= 0x110,
3725 _dpp_row_rr
= 0x120,
3730 dpp_row_mirror
= 0x140,
3731 dpp_row_half_mirror
= 0x141,
3732 dpp_row_bcast15
= 0x142,
3733 dpp_row_bcast31
= 0x143
3736 static inline enum dpp_ctrl
3737 dpp_quad_perm(unsigned lane0
, unsigned lane1
, unsigned lane2
, unsigned lane3
)
3739 assert(lane0
< 4 && lane1
< 4 && lane2
< 4 && lane3
< 4);
3740 return _dpp_quad_perm
| lane0
| (lane1
<< 2) | (lane2
<< 4) | (lane3
<< 6);
3743 static inline enum dpp_ctrl
3744 dpp_row_sl(unsigned amount
)
3746 assert(amount
> 0 && amount
< 16);
3747 return _dpp_row_sl
| amount
;
3750 static inline enum dpp_ctrl
3751 dpp_row_sr(unsigned amount
)
3753 assert(amount
> 0 && amount
< 16);
3754 return _dpp_row_sr
| amount
;
3758 _ac_build_dpp(struct ac_llvm_context
*ctx
, LLVMValueRef old
, LLVMValueRef src
,
3759 enum dpp_ctrl dpp_ctrl
, unsigned row_mask
, unsigned bank_mask
,
3762 LLVMTypeRef type
= LLVMTypeOf(src
);
3765 old
= LLVMBuildZExt(ctx
->builder
, old
, ctx
->i32
, "");
3766 src
= LLVMBuildZExt(ctx
->builder
, src
, ctx
->i32
, "");
3768 res
= ac_build_intrinsic(ctx
, "llvm.amdgcn.update.dpp.i32", ctx
->i32
,
3771 LLVMConstInt(ctx
->i32
, dpp_ctrl
, 0),
3772 LLVMConstInt(ctx
->i32
, row_mask
, 0),
3773 LLVMConstInt(ctx
->i32
, bank_mask
, 0),
3774 LLVMConstInt(ctx
->i1
, bound_ctrl
, 0) },
3775 6, AC_FUNC_ATTR_READNONE
| AC_FUNC_ATTR_CONVERGENT
);
3777 return LLVMBuildTrunc(ctx
->builder
, res
, type
, "");
3781 ac_build_dpp(struct ac_llvm_context
*ctx
, LLVMValueRef old
, LLVMValueRef src
,
3782 enum dpp_ctrl dpp_ctrl
, unsigned row_mask
, unsigned bank_mask
,
3785 LLVMTypeRef src_type
= LLVMTypeOf(src
);
3786 src
= ac_to_integer(ctx
, src
);
3787 old
= ac_to_integer(ctx
, old
);
3788 unsigned bits
= LLVMGetIntTypeWidth(LLVMTypeOf(src
));
3791 assert(bits
% 32 == 0);
3792 LLVMTypeRef vec_type
= LLVMVectorType(ctx
->i32
, bits
/ 32);
3793 LLVMValueRef src_vector
=
3794 LLVMBuildBitCast(ctx
->builder
, src
, vec_type
, "");
3795 LLVMValueRef old_vector
=
3796 LLVMBuildBitCast(ctx
->builder
, old
, vec_type
, "");
3797 ret
= LLVMGetUndef(vec_type
);
3798 for (unsigned i
= 0; i
< bits
/ 32; i
++) {
3799 src
= LLVMBuildExtractElement(ctx
->builder
, src_vector
,
3800 LLVMConstInt(ctx
->i32
, i
,
3802 old
= LLVMBuildExtractElement(ctx
->builder
, old_vector
,
3803 LLVMConstInt(ctx
->i32
, i
,
3805 LLVMValueRef ret_comp
= _ac_build_dpp(ctx
, old
, src
,
3810 ret
= LLVMBuildInsertElement(ctx
->builder
, ret
,
3812 LLVMConstInt(ctx
->i32
, i
,
3816 ret
= _ac_build_dpp(ctx
, old
, src
, dpp_ctrl
, row_mask
,
3817 bank_mask
, bound_ctrl
);
3819 return LLVMBuildBitCast(ctx
->builder
, ret
, src_type
, "");
3823 _ac_build_permlane16(struct ac_llvm_context
*ctx
, LLVMValueRef src
, uint64_t sel
,
3824 bool exchange_rows
, bool bound_ctrl
)
3826 LLVMTypeRef type
= LLVMTypeOf(src
);
3827 LLVMValueRef result
;
3829 src
= LLVMBuildZExt(ctx
->builder
, src
, ctx
->i32
, "");
3831 LLVMValueRef args
[6] = {
3834 LLVMConstInt(ctx
->i32
, sel
, false),
3835 LLVMConstInt(ctx
->i32
, sel
>> 32, false),
3836 ctx
->i1true
, /* fi */
3837 bound_ctrl
? ctx
->i1true
: ctx
->i1false
,
3840 result
= ac_build_intrinsic(ctx
, exchange_rows
? "llvm.amdgcn.permlanex16"
3841 : "llvm.amdgcn.permlane16",
3843 AC_FUNC_ATTR_READNONE
| AC_FUNC_ATTR_CONVERGENT
);
3845 return LLVMBuildTrunc(ctx
->builder
, result
, type
, "");
3849 ac_build_permlane16(struct ac_llvm_context
*ctx
, LLVMValueRef src
, uint64_t sel
,
3850 bool exchange_rows
, bool bound_ctrl
)
3852 LLVMTypeRef src_type
= LLVMTypeOf(src
);
3853 src
= ac_to_integer(ctx
, src
);
3854 unsigned bits
= LLVMGetIntTypeWidth(LLVMTypeOf(src
));
3857 assert(bits
% 32 == 0);
3858 LLVMTypeRef vec_type
= LLVMVectorType(ctx
->i32
, bits
/ 32);
3859 LLVMValueRef src_vector
=
3860 LLVMBuildBitCast(ctx
->builder
, src
, vec_type
, "");
3861 ret
= LLVMGetUndef(vec_type
);
3862 for (unsigned i
= 0; i
< bits
/ 32; i
++) {
3863 src
= LLVMBuildExtractElement(ctx
->builder
, src_vector
,
3864 LLVMConstInt(ctx
->i32
, i
,
3866 LLVMValueRef ret_comp
=
3867 _ac_build_permlane16(ctx
, src
, sel
,
3870 ret
= LLVMBuildInsertElement(ctx
->builder
, ret
,
3872 LLVMConstInt(ctx
->i32
, i
,
3876 ret
= _ac_build_permlane16(ctx
, src
, sel
, exchange_rows
,
3879 return LLVMBuildBitCast(ctx
->builder
, ret
, src_type
, "");
3882 static inline unsigned
3883 ds_pattern_bitmode(unsigned and_mask
, unsigned or_mask
, unsigned xor_mask
)
3885 assert(and_mask
< 32 && or_mask
< 32 && xor_mask
< 32);
3886 return and_mask
| (or_mask
<< 5) | (xor_mask
<< 10);
3890 _ac_build_ds_swizzle(struct ac_llvm_context
*ctx
, LLVMValueRef src
, unsigned mask
)
3892 LLVMTypeRef src_type
= LLVMTypeOf(src
);
3895 src
= LLVMBuildZExt(ctx
->builder
, src
, ctx
->i32
, "");
3897 ret
= ac_build_intrinsic(ctx
, "llvm.amdgcn.ds.swizzle", ctx
->i32
,
3899 src
, LLVMConstInt(ctx
->i32
, mask
, 0) },
3900 2, AC_FUNC_ATTR_READNONE
| AC_FUNC_ATTR_CONVERGENT
);
3902 return LLVMBuildTrunc(ctx
->builder
, ret
, src_type
, "");
3906 ac_build_ds_swizzle(struct ac_llvm_context
*ctx
, LLVMValueRef src
, unsigned mask
)
3908 LLVMTypeRef src_type
= LLVMTypeOf(src
);
3909 src
= ac_to_integer(ctx
, src
);
3910 unsigned bits
= LLVMGetIntTypeWidth(LLVMTypeOf(src
));
3913 assert(bits
% 32 == 0);
3914 LLVMTypeRef vec_type
= LLVMVectorType(ctx
->i32
, bits
/ 32);
3915 LLVMValueRef src_vector
=
3916 LLVMBuildBitCast(ctx
->builder
, src
, vec_type
, "");
3917 ret
= LLVMGetUndef(vec_type
);
3918 for (unsigned i
= 0; i
< bits
/ 32; i
++) {
3919 src
= LLVMBuildExtractElement(ctx
->builder
, src_vector
,
3920 LLVMConstInt(ctx
->i32
, i
,
3922 LLVMValueRef ret_comp
= _ac_build_ds_swizzle(ctx
, src
,
3924 ret
= LLVMBuildInsertElement(ctx
->builder
, ret
,
3926 LLVMConstInt(ctx
->i32
, i
,
3930 ret
= _ac_build_ds_swizzle(ctx
, src
, mask
);
3932 return LLVMBuildBitCast(ctx
->builder
, ret
, src_type
, "");
3936 ac_build_wwm(struct ac_llvm_context
*ctx
, LLVMValueRef src
)
3938 LLVMTypeRef src_type
= LLVMTypeOf(src
);
3939 unsigned bitsize
= ac_get_elem_bits(ctx
, src_type
);
3940 char name
[32], type
[8];
3943 src
= ac_to_integer(ctx
, src
);
3946 src
= LLVMBuildZExt(ctx
->builder
, src
, ctx
->i32
, "");
3948 ac_build_type_name_for_intr(LLVMTypeOf(src
), type
, sizeof(type
));
3949 snprintf(name
, sizeof(name
), "llvm.amdgcn.wwm.%s", type
);
3950 ret
= ac_build_intrinsic(ctx
, name
, LLVMTypeOf(src
),
3951 (LLVMValueRef
[]) { src
}, 1,
3952 AC_FUNC_ATTR_READNONE
);
3955 ret
= LLVMBuildTrunc(ctx
->builder
, ret
,
3956 ac_to_integer_type(ctx
, src_type
), "");
3958 return LLVMBuildBitCast(ctx
->builder
, ret
, src_type
, "");
3962 ac_build_set_inactive(struct ac_llvm_context
*ctx
, LLVMValueRef src
,
3963 LLVMValueRef inactive
)
3965 char name
[33], type
[8];
3966 LLVMTypeRef src_type
= LLVMTypeOf(src
);
3967 unsigned bitsize
= ac_get_elem_bits(ctx
, src_type
);
3968 src
= ac_to_integer(ctx
, src
);
3969 inactive
= ac_to_integer(ctx
, inactive
);
3972 src
= LLVMBuildZExt(ctx
->builder
, src
, ctx
->i32
, "");
3973 inactive
= LLVMBuildZExt(ctx
->builder
, inactive
, ctx
->i32
, "");
3976 ac_build_type_name_for_intr(LLVMTypeOf(src
), type
, sizeof(type
));
3977 snprintf(name
, sizeof(name
), "llvm.amdgcn.set.inactive.%s", type
);
3979 ac_build_intrinsic(ctx
, name
,
3980 LLVMTypeOf(src
), (LLVMValueRef
[]) {
3982 AC_FUNC_ATTR_READNONE
|
3983 AC_FUNC_ATTR_CONVERGENT
);
3985 ret
= LLVMBuildTrunc(ctx
->builder
, ret
, src_type
, "");
3991 get_reduction_identity(struct ac_llvm_context
*ctx
, nir_op op
, unsigned type_size
)
3993 if (type_size
== 1) {
3995 case nir_op_iadd
: return ctx
->i8_0
;
3996 case nir_op_imul
: return ctx
->i8_1
;
3997 case nir_op_imin
: return LLVMConstInt(ctx
->i8
, INT8_MAX
, 0);
3998 case nir_op_umin
: return LLVMConstInt(ctx
->i8
, UINT8_MAX
, 0);
3999 case nir_op_imax
: return LLVMConstInt(ctx
->i8
, INT8_MIN
, 0);
4000 case nir_op_umax
: return ctx
->i8_0
;
4001 case nir_op_iand
: return LLVMConstInt(ctx
->i8
, -1, 0);
4002 case nir_op_ior
: return ctx
->i8_0
;
4003 case nir_op_ixor
: return ctx
->i8_0
;
4005 unreachable("bad reduction intrinsic");
4007 } else if (type_size
== 2) {
4009 case nir_op_iadd
: return ctx
->i16_0
;
4010 case nir_op_fadd
: return ctx
->f16_0
;
4011 case nir_op_imul
: return ctx
->i16_1
;
4012 case nir_op_fmul
: return ctx
->f16_1
;
4013 case nir_op_imin
: return LLVMConstInt(ctx
->i16
, INT16_MAX
, 0);
4014 case nir_op_umin
: return LLVMConstInt(ctx
->i16
, UINT16_MAX
, 0);
4015 case nir_op_fmin
: return LLVMConstReal(ctx
->f16
, INFINITY
);
4016 case nir_op_imax
: return LLVMConstInt(ctx
->i16
, INT16_MIN
, 0);
4017 case nir_op_umax
: return ctx
->i16_0
;
4018 case nir_op_fmax
: return LLVMConstReal(ctx
->f16
, -INFINITY
);
4019 case nir_op_iand
: return LLVMConstInt(ctx
->i16
, -1, 0);
4020 case nir_op_ior
: return ctx
->i16_0
;
4021 case nir_op_ixor
: return ctx
->i16_0
;
4023 unreachable("bad reduction intrinsic");
4025 } else if (type_size
== 4) {
4027 case nir_op_iadd
: return ctx
->i32_0
;
4028 case nir_op_fadd
: return ctx
->f32_0
;
4029 case nir_op_imul
: return ctx
->i32_1
;
4030 case nir_op_fmul
: return ctx
->f32_1
;
4031 case nir_op_imin
: return LLVMConstInt(ctx
->i32
, INT32_MAX
, 0);
4032 case nir_op_umin
: return LLVMConstInt(ctx
->i32
, UINT32_MAX
, 0);
4033 case nir_op_fmin
: return LLVMConstReal(ctx
->f32
, INFINITY
);
4034 case nir_op_imax
: return LLVMConstInt(ctx
->i32
, INT32_MIN
, 0);
4035 case nir_op_umax
: return ctx
->i32_0
;
4036 case nir_op_fmax
: return LLVMConstReal(ctx
->f32
, -INFINITY
);
4037 case nir_op_iand
: return LLVMConstInt(ctx
->i32
, -1, 0);
4038 case nir_op_ior
: return ctx
->i32_0
;
4039 case nir_op_ixor
: return ctx
->i32_0
;
4041 unreachable("bad reduction intrinsic");
4043 } else { /* type_size == 64bit */
4045 case nir_op_iadd
: return ctx
->i64_0
;
4046 case nir_op_fadd
: return ctx
->f64_0
;
4047 case nir_op_imul
: return ctx
->i64_1
;
4048 case nir_op_fmul
: return ctx
->f64_1
;
4049 case nir_op_imin
: return LLVMConstInt(ctx
->i64
, INT64_MAX
, 0);
4050 case nir_op_umin
: return LLVMConstInt(ctx
->i64
, UINT64_MAX
, 0);
4051 case nir_op_fmin
: return LLVMConstReal(ctx
->f64
, INFINITY
);
4052 case nir_op_imax
: return LLVMConstInt(ctx
->i64
, INT64_MIN
, 0);
4053 case nir_op_umax
: return ctx
->i64_0
;
4054 case nir_op_fmax
: return LLVMConstReal(ctx
->f64
, -INFINITY
);
4055 case nir_op_iand
: return LLVMConstInt(ctx
->i64
, -1, 0);
4056 case nir_op_ior
: return ctx
->i64_0
;
4057 case nir_op_ixor
: return ctx
->i64_0
;
4059 unreachable("bad reduction intrinsic");
4065 ac_build_alu_op(struct ac_llvm_context
*ctx
, LLVMValueRef lhs
, LLVMValueRef rhs
, nir_op op
)
4067 bool _64bit
= ac_get_type_size(LLVMTypeOf(lhs
)) == 8;
4068 bool _32bit
= ac_get_type_size(LLVMTypeOf(lhs
)) == 4;
4070 case nir_op_iadd
: return LLVMBuildAdd(ctx
->builder
, lhs
, rhs
, "");
4071 case nir_op_fadd
: return LLVMBuildFAdd(ctx
->builder
, lhs
, rhs
, "");
4072 case nir_op_imul
: return LLVMBuildMul(ctx
->builder
, lhs
, rhs
, "");
4073 case nir_op_fmul
: return LLVMBuildFMul(ctx
->builder
, lhs
, rhs
, "");
4074 case nir_op_imin
: return LLVMBuildSelect(ctx
->builder
,
4075 LLVMBuildICmp(ctx
->builder
, LLVMIntSLT
, lhs
, rhs
, ""),
4077 case nir_op_umin
: return LLVMBuildSelect(ctx
->builder
,
4078 LLVMBuildICmp(ctx
->builder
, LLVMIntULT
, lhs
, rhs
, ""),
4080 case nir_op_fmin
: return ac_build_intrinsic(ctx
,
4081 _64bit
? "llvm.minnum.f64" : _32bit
? "llvm.minnum.f32" : "llvm.minnum.f16",
4082 _64bit
? ctx
->f64
: _32bit
? ctx
->f32
: ctx
->f16
,
4083 (LLVMValueRef
[]){lhs
, rhs
}, 2, AC_FUNC_ATTR_READNONE
);
4084 case nir_op_imax
: return LLVMBuildSelect(ctx
->builder
,
4085 LLVMBuildICmp(ctx
->builder
, LLVMIntSGT
, lhs
, rhs
, ""),
4087 case nir_op_umax
: return LLVMBuildSelect(ctx
->builder
,
4088 LLVMBuildICmp(ctx
->builder
, LLVMIntUGT
, lhs
, rhs
, ""),
4090 case nir_op_fmax
: return ac_build_intrinsic(ctx
,
4091 _64bit
? "llvm.maxnum.f64" : _32bit
? "llvm.maxnum.f32" : "llvm.maxnum.f16",
4092 _64bit
? ctx
->f64
: _32bit
? ctx
->f32
: ctx
->f16
,
4093 (LLVMValueRef
[]){lhs
, rhs
}, 2, AC_FUNC_ATTR_READNONE
);
4094 case nir_op_iand
: return LLVMBuildAnd(ctx
->builder
, lhs
, rhs
, "");
4095 case nir_op_ior
: return LLVMBuildOr(ctx
->builder
, lhs
, rhs
, "");
4096 case nir_op_ixor
: return LLVMBuildXor(ctx
->builder
, lhs
, rhs
, "");
4098 unreachable("bad reduction intrinsic");
4103 * \param src The value to shift.
4104 * \param identity The value to use the first lane.
4105 * \param maxprefix specifies that the result only needs to be correct for a
4106 * prefix of this many threads
4107 * \return src, shifted 1 lane up, and identity shifted into lane 0.
4110 ac_wavefront_shift_right_1(struct ac_llvm_context
*ctx
, LLVMValueRef src
,
4111 LLVMValueRef identity
, unsigned maxprefix
)
4113 if (ctx
->chip_class
>= GFX10
) {
4114 /* wavefront shift_right by 1 on GFX10 (emulate dpp_wf_sr1) */
4115 LLVMValueRef active
, tmp1
, tmp2
;
4116 LLVMValueRef tid
= ac_get_thread_id(ctx
);
4118 tmp1
= ac_build_dpp(ctx
, identity
, src
, dpp_row_sr(1), 0xf, 0xf, false);
4120 tmp2
= ac_build_permlane16(ctx
, src
, (uint64_t)~0, true, false);
4122 if (maxprefix
> 32) {
4123 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
, tid
,
4124 LLVMConstInt(ctx
->i32
, 32, false), "");
4126 tmp2
= LLVMBuildSelect(ctx
->builder
, active
,
4127 ac_build_readlane(ctx
, src
,
4128 LLVMConstInt(ctx
->i32
, 31, false)),
4131 active
= LLVMBuildOr(ctx
->builder
, active
,
4132 LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
,
4133 LLVMBuildAnd(ctx
->builder
, tid
,
4134 LLVMConstInt(ctx
->i32
, 0x1f, false), ""),
4135 LLVMConstInt(ctx
->i32
, 0x10, false), ""), "");
4136 return LLVMBuildSelect(ctx
->builder
, active
, tmp2
, tmp1
, "");
4137 } else if (maxprefix
> 16) {
4138 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
, tid
,
4139 LLVMConstInt(ctx
->i32
, 16, false), "");
4141 return LLVMBuildSelect(ctx
->builder
, active
, tmp2
, tmp1
, "");
4143 } else if (ctx
->chip_class
>= GFX8
) {
4144 return ac_build_dpp(ctx
, identity
, src
, dpp_wf_sr1
, 0xf, 0xf, false);
4147 /* wavefront shift_right by 1 on SI/CI */
4148 LLVMValueRef active
, tmp1
, tmp2
;
4149 LLVMValueRef tid
= ac_get_thread_id(ctx
);
4150 tmp1
= ac_build_ds_swizzle(ctx
, src
, (1 << 15) | dpp_quad_perm(0, 0, 1, 2));
4151 tmp2
= ac_build_ds_swizzle(ctx
, src
, ds_pattern_bitmode(0x18, 0x03, 0x00));
4152 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
,
4153 LLVMBuildAnd(ctx
->builder
, tid
, LLVMConstInt(ctx
->i32
, 0x7, 0), ""),
4154 LLVMConstInt(ctx
->i32
, 0x4, 0), "");
4155 tmp1
= LLVMBuildSelect(ctx
->builder
, active
, tmp2
, tmp1
, "");
4156 tmp2
= ac_build_ds_swizzle(ctx
, src
, ds_pattern_bitmode(0x10, 0x07, 0x00));
4157 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
,
4158 LLVMBuildAnd(ctx
->builder
, tid
, LLVMConstInt(ctx
->i32
, 0xf, 0), ""),
4159 LLVMConstInt(ctx
->i32
, 0x8, 0), "");
4160 tmp1
= LLVMBuildSelect(ctx
->builder
, active
, tmp2
, tmp1
, "");
4161 tmp2
= ac_build_ds_swizzle(ctx
, src
, ds_pattern_bitmode(0x00, 0x0f, 0x00));
4162 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
,
4163 LLVMBuildAnd(ctx
->builder
, tid
, LLVMConstInt(ctx
->i32
, 0x1f, 0), ""),
4164 LLVMConstInt(ctx
->i32
, 0x10, 0), "");
4165 tmp1
= LLVMBuildSelect(ctx
->builder
, active
, tmp2
, tmp1
, "");
4166 tmp2
= ac_build_readlane(ctx
, src
, LLVMConstInt(ctx
->i32
, 31, 0));
4167 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
, tid
, LLVMConstInt(ctx
->i32
, 32, 0), "");
4168 tmp1
= LLVMBuildSelect(ctx
->builder
, active
, tmp2
, tmp1
, "");
4169 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntEQ
, tid
, LLVMConstInt(ctx
->i32
, 0, 0), "");
4170 return LLVMBuildSelect(ctx
->builder
, active
, identity
, tmp1
, "");
4174 * \param maxprefix specifies that the result only needs to be correct for a
4175 * prefix of this many threads
4178 ac_build_scan(struct ac_llvm_context
*ctx
, nir_op op
, LLVMValueRef src
, LLVMValueRef identity
,
4179 unsigned maxprefix
, bool inclusive
)
4181 LLVMValueRef result
, tmp
;
4184 src
= ac_wavefront_shift_right_1(ctx
, src
, identity
, maxprefix
);
4188 if (ctx
->chip_class
<= GFX7
) {
4189 assert(maxprefix
== 64);
4190 LLVMValueRef tid
= ac_get_thread_id(ctx
);
4191 LLVMValueRef active
;
4192 tmp
= ac_build_ds_swizzle(ctx
, src
, ds_pattern_bitmode(0x1e, 0x00, 0x00));
4193 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntNE
,
4194 LLVMBuildAnd(ctx
->builder
, tid
, ctx
->i32_1
, ""),
4196 tmp
= LLVMBuildSelect(ctx
->builder
, active
, tmp
, identity
, "");
4197 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4198 tmp
= ac_build_ds_swizzle(ctx
, result
, ds_pattern_bitmode(0x1c, 0x01, 0x00));
4199 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntNE
,
4200 LLVMBuildAnd(ctx
->builder
, tid
, LLVMConstInt(ctx
->i32
, 2, 0), ""),
4202 tmp
= LLVMBuildSelect(ctx
->builder
, active
, tmp
, identity
, "");
4203 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4204 tmp
= ac_build_ds_swizzle(ctx
, result
, ds_pattern_bitmode(0x18, 0x03, 0x00));
4205 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntNE
,
4206 LLVMBuildAnd(ctx
->builder
, tid
, LLVMConstInt(ctx
->i32
, 4, 0), ""),
4208 tmp
= LLVMBuildSelect(ctx
->builder
, active
, tmp
, identity
, "");
4209 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4210 tmp
= ac_build_ds_swizzle(ctx
, result
, ds_pattern_bitmode(0x10, 0x07, 0x00));
4211 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntNE
,
4212 LLVMBuildAnd(ctx
->builder
, tid
, LLVMConstInt(ctx
->i32
, 8, 0), ""),
4214 tmp
= LLVMBuildSelect(ctx
->builder
, active
, tmp
, identity
, "");
4215 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4216 tmp
= ac_build_ds_swizzle(ctx
, result
, ds_pattern_bitmode(0x00, 0x0f, 0x00));
4217 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntNE
,
4218 LLVMBuildAnd(ctx
->builder
, tid
, LLVMConstInt(ctx
->i32
, 16, 0), ""),
4220 tmp
= LLVMBuildSelect(ctx
->builder
, active
, tmp
, identity
, "");
4221 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4222 tmp
= ac_build_readlane(ctx
, result
, LLVMConstInt(ctx
->i32
, 31, 0));
4223 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntNE
,
4224 LLVMBuildAnd(ctx
->builder
, tid
, LLVMConstInt(ctx
->i32
, 32, 0), ""),
4226 tmp
= LLVMBuildSelect(ctx
->builder
, active
, tmp
, identity
, "");
4227 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4233 tmp
= ac_build_dpp(ctx
, identity
, src
, dpp_row_sr(1), 0xf, 0xf, false);
4234 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4237 tmp
= ac_build_dpp(ctx
, identity
, src
, dpp_row_sr(2), 0xf, 0xf, false);
4238 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4241 tmp
= ac_build_dpp(ctx
, identity
, src
, dpp_row_sr(3), 0xf, 0xf, false);
4242 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4245 tmp
= ac_build_dpp(ctx
, identity
, result
, dpp_row_sr(4), 0xf, 0xe, false);
4246 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4249 tmp
= ac_build_dpp(ctx
, identity
, result
, dpp_row_sr(8), 0xf, 0xc, false);
4250 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4251 if (maxprefix
<= 16)
4254 if (ctx
->chip_class
>= GFX10
) {
4255 LLVMValueRef tid
= ac_get_thread_id(ctx
);
4256 LLVMValueRef active
;
4258 tmp
= ac_build_permlane16(ctx
, result
, ~(uint64_t)0, true, false);
4260 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntNE
,
4261 LLVMBuildAnd(ctx
->builder
, tid
,
4262 LLVMConstInt(ctx
->i32
, 16, false), ""),
4265 tmp
= LLVMBuildSelect(ctx
->builder
, active
, tmp
, identity
, "");
4267 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4269 if (maxprefix
<= 32)
4272 tmp
= ac_build_readlane(ctx
, result
, LLVMConstInt(ctx
->i32
, 31, false));
4274 active
= LLVMBuildICmp(ctx
->builder
, LLVMIntUGE
, tid
,
4275 LLVMConstInt(ctx
->i32
, 32, false), "");
4277 tmp
= LLVMBuildSelect(ctx
->builder
, active
, tmp
, identity
, "");
4279 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4283 tmp
= ac_build_dpp(ctx
, identity
, result
, dpp_row_bcast15
, 0xa, 0xf, false);
4284 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4285 if (maxprefix
<= 32)
4287 tmp
= ac_build_dpp(ctx
, identity
, result
, dpp_row_bcast31
, 0xc, 0xf, false);
4288 result
= ac_build_alu_op(ctx
, result
, tmp
, op
);
4293 ac_build_inclusive_scan(struct ac_llvm_context
*ctx
, LLVMValueRef src
, nir_op op
)
4295 LLVMValueRef result
;
4297 if (LLVMTypeOf(src
) == ctx
->i1
&& op
== nir_op_iadd
) {
4298 LLVMBuilderRef builder
= ctx
->builder
;
4299 src
= LLVMBuildZExt(builder
, src
, ctx
->i32
, "");
4300 result
= ac_build_ballot(ctx
, src
);
4301 result
= ac_build_mbcnt(ctx
, result
);
4302 result
= LLVMBuildAdd(builder
, result
, src
, "");
4306 ac_build_optimization_barrier(ctx
, &src
);
4308 LLVMValueRef identity
=
4309 get_reduction_identity(ctx
, op
, ac_get_type_size(LLVMTypeOf(src
)));
4310 result
= LLVMBuildBitCast(ctx
->builder
, ac_build_set_inactive(ctx
, src
, identity
),
4311 LLVMTypeOf(identity
), "");
4312 result
= ac_build_scan(ctx
, op
, result
, identity
, ctx
->wave_size
, true);
4314 return ac_build_wwm(ctx
, result
);
4318 ac_build_exclusive_scan(struct ac_llvm_context
*ctx
, LLVMValueRef src
, nir_op op
)
4320 LLVMValueRef result
;
4322 if (LLVMTypeOf(src
) == ctx
->i1
&& op
== nir_op_iadd
) {
4323 LLVMBuilderRef builder
= ctx
->builder
;
4324 src
= LLVMBuildZExt(builder
, src
, ctx
->i32
, "");
4325 result
= ac_build_ballot(ctx
, src
);
4326 result
= ac_build_mbcnt(ctx
, result
);
4330 ac_build_optimization_barrier(ctx
, &src
);
4332 LLVMValueRef identity
=
4333 get_reduction_identity(ctx
, op
, ac_get_type_size(LLVMTypeOf(src
)));
4334 result
= LLVMBuildBitCast(ctx
->builder
, ac_build_set_inactive(ctx
, src
, identity
),
4335 LLVMTypeOf(identity
), "");
4336 result
= ac_build_scan(ctx
, op
, result
, identity
, ctx
->wave_size
, false);
4338 return ac_build_wwm(ctx
, result
);
4342 ac_build_reduce(struct ac_llvm_context
*ctx
, LLVMValueRef src
, nir_op op
, unsigned cluster_size
)
4344 if (cluster_size
== 1) return src
;
4345 ac_build_optimization_barrier(ctx
, &src
);
4346 LLVMValueRef result
, swap
;
4347 LLVMValueRef identity
= get_reduction_identity(ctx
, op
,
4348 ac_get_type_size(LLVMTypeOf(src
)));
4349 result
= LLVMBuildBitCast(ctx
->builder
,
4350 ac_build_set_inactive(ctx
, src
, identity
),
4351 LLVMTypeOf(identity
), "");
4352 swap
= ac_build_quad_swizzle(ctx
, result
, 1, 0, 3, 2);
4353 result
= ac_build_alu_op(ctx
, result
, swap
, op
);
4354 if (cluster_size
== 2) return ac_build_wwm(ctx
, result
);
4356 swap
= ac_build_quad_swizzle(ctx
, result
, 2, 3, 0, 1);
4357 result
= ac_build_alu_op(ctx
, result
, swap
, op
);
4358 if (cluster_size
== 4) return ac_build_wwm(ctx
, result
);
4360 if (ctx
->chip_class
>= GFX8
)
4361 swap
= ac_build_dpp(ctx
, identity
, result
, dpp_row_half_mirror
, 0xf, 0xf, false);
4363 swap
= ac_build_ds_swizzle(ctx
, result
, ds_pattern_bitmode(0x1f, 0, 0x04));
4364 result
= ac_build_alu_op(ctx
, result
, swap
, op
);
4365 if (cluster_size
== 8) return ac_build_wwm(ctx
, result
);
4367 if (ctx
->chip_class
>= GFX8
)
4368 swap
= ac_build_dpp(ctx
, identity
, result
, dpp_row_mirror
, 0xf, 0xf, false);
4370 swap
= ac_build_ds_swizzle(ctx
, result
, ds_pattern_bitmode(0x1f, 0, 0x08));
4371 result
= ac_build_alu_op(ctx
, result
, swap
, op
);
4372 if (cluster_size
== 16) return ac_build_wwm(ctx
, result
);
4374 if (ctx
->chip_class
>= GFX10
)
4375 swap
= ac_build_permlane16(ctx
, result
, 0, true, false);
4376 else if (ctx
->chip_class
>= GFX8
&& cluster_size
!= 32)
4377 swap
= ac_build_dpp(ctx
, identity
, result
, dpp_row_bcast15
, 0xa, 0xf, false);
4379 swap
= ac_build_ds_swizzle(ctx
, result
, ds_pattern_bitmode(0x1f, 0, 0x10));
4380 result
= ac_build_alu_op(ctx
, result
, swap
, op
);
4381 if (cluster_size
== 32) return ac_build_wwm(ctx
, result
);
4383 if (ctx
->chip_class
>= GFX8
) {
4384 if (ctx
->wave_size
== 64) {
4385 if (ctx
->chip_class
>= GFX10
)
4386 swap
= ac_build_readlane(ctx
, result
, LLVMConstInt(ctx
->i32
, 31, false));
4388 swap
= ac_build_dpp(ctx
, identity
, result
, dpp_row_bcast31
, 0xc, 0xf, false);
4389 result
= ac_build_alu_op(ctx
, result
, swap
, op
);
4390 result
= ac_build_readlane(ctx
, result
, LLVMConstInt(ctx
->i32
, 63, 0));
4393 return ac_build_wwm(ctx
, result
);
4395 swap
= ac_build_readlane(ctx
, result
, ctx
->i32_0
);
4396 result
= ac_build_readlane(ctx
, result
, LLVMConstInt(ctx
->i32
, 32, 0));
4397 result
= ac_build_alu_op(ctx
, result
, swap
, op
);
4398 return ac_build_wwm(ctx
, result
);
4403 * "Top half" of a scan that reduces per-wave values across an entire
4406 * The source value must be present in the highest lane of the wave, and the
4407 * highest lane must be live.
4410 ac_build_wg_wavescan_top(struct ac_llvm_context
*ctx
, struct ac_wg_scan
*ws
)
4412 if (ws
->maxwaves
<= 1)
4415 const LLVMValueRef last_lane
= LLVMConstInt(ctx
->i32
, ctx
->wave_size
- 1, false);
4416 LLVMBuilderRef builder
= ctx
->builder
;
4417 LLVMValueRef tid
= ac_get_thread_id(ctx
);
4420 tmp
= LLVMBuildICmp(builder
, LLVMIntEQ
, tid
, last_lane
, "");
4421 ac_build_ifcc(ctx
, tmp
, 1000);
4422 LLVMBuildStore(builder
, ws
->src
, LLVMBuildGEP(builder
, ws
->scratch
, &ws
->waveidx
, 1, ""));
4423 ac_build_endif(ctx
, 1000);
4427 * "Bottom half" of a scan that reduces per-wave values across an entire
4430 * The caller must place a barrier between the top and bottom halves.
4433 ac_build_wg_wavescan_bottom(struct ac_llvm_context
*ctx
, struct ac_wg_scan
*ws
)
4435 const LLVMTypeRef type
= LLVMTypeOf(ws
->src
);
4436 const LLVMValueRef identity
=
4437 get_reduction_identity(ctx
, ws
->op
, ac_get_type_size(type
));
4439 if (ws
->maxwaves
<= 1) {
4440 ws
->result_reduce
= ws
->src
;
4441 ws
->result_inclusive
= ws
->src
;
4442 ws
->result_exclusive
= identity
;
4445 assert(ws
->maxwaves
<= 32);
4447 LLVMBuilderRef builder
= ctx
->builder
;
4448 LLVMValueRef tid
= ac_get_thread_id(ctx
);
4449 LLVMBasicBlockRef bbs
[2];
4450 LLVMValueRef phivalues_scan
[2];
4451 LLVMValueRef tmp
, tmp2
;
4453 bbs
[0] = LLVMGetInsertBlock(builder
);
4454 phivalues_scan
[0] = LLVMGetUndef(type
);
4456 if (ws
->enable_reduce
)
4457 tmp
= LLVMBuildICmp(builder
, LLVMIntULT
, tid
, ws
->numwaves
, "");
4458 else if (ws
->enable_inclusive
)
4459 tmp
= LLVMBuildICmp(builder
, LLVMIntULE
, tid
, ws
->waveidx
, "");
4461 tmp
= LLVMBuildICmp(builder
, LLVMIntULT
, tid
, ws
->waveidx
, "");
4462 ac_build_ifcc(ctx
, tmp
, 1001);
4464 tmp
= LLVMBuildLoad(builder
, LLVMBuildGEP(builder
, ws
->scratch
, &tid
, 1, ""), "");
4466 ac_build_optimization_barrier(ctx
, &tmp
);
4468 bbs
[1] = LLVMGetInsertBlock(builder
);
4469 phivalues_scan
[1] = ac_build_scan(ctx
, ws
->op
, tmp
, identity
, ws
->maxwaves
, true);
4471 ac_build_endif(ctx
, 1001);
4473 const LLVMValueRef scan
= ac_build_phi(ctx
, type
, 2, phivalues_scan
, bbs
);
4475 if (ws
->enable_reduce
) {
4476 tmp
= LLVMBuildSub(builder
, ws
->numwaves
, ctx
->i32_1
, "");
4477 ws
->result_reduce
= ac_build_readlane(ctx
, scan
, tmp
);
4479 if (ws
->enable_inclusive
)
4480 ws
->result_inclusive
= ac_build_readlane(ctx
, scan
, ws
->waveidx
);
4481 if (ws
->enable_exclusive
) {
4482 tmp
= LLVMBuildSub(builder
, ws
->waveidx
, ctx
->i32_1
, "");
4483 tmp
= ac_build_readlane(ctx
, scan
, tmp
);
4484 tmp2
= LLVMBuildICmp(builder
, LLVMIntEQ
, ws
->waveidx
, ctx
->i32_0
, "");
4485 ws
->result_exclusive
= LLVMBuildSelect(builder
, tmp2
, identity
, tmp
, "");
4490 * Inclusive scan of a per-wave value across an entire workgroup.
4492 * This implies an s_barrier instruction.
4494 * Unlike ac_build_inclusive_scan, the caller \em must ensure that all threads
4495 * of the workgroup are live. (This requirement cannot easily be relaxed in a
4496 * useful manner because of the barrier in the algorithm.)
4499 ac_build_wg_wavescan(struct ac_llvm_context
*ctx
, struct ac_wg_scan
*ws
)
4501 ac_build_wg_wavescan_top(ctx
, ws
);
4502 ac_build_s_barrier(ctx
);
4503 ac_build_wg_wavescan_bottom(ctx
, ws
);
4507 * "Top half" of a scan that reduces per-thread values across an entire
4510 * All lanes must be active when this code runs.
4513 ac_build_wg_scan_top(struct ac_llvm_context
*ctx
, struct ac_wg_scan
*ws
)
4515 if (ws
->enable_exclusive
) {
4516 ws
->extra
= ac_build_exclusive_scan(ctx
, ws
->src
, ws
->op
);
4517 if (LLVMTypeOf(ws
->src
) == ctx
->i1
&& ws
->op
== nir_op_iadd
)
4518 ws
->src
= LLVMBuildZExt(ctx
->builder
, ws
->src
, ctx
->i32
, "");
4519 ws
->src
= ac_build_alu_op(ctx
, ws
->extra
, ws
->src
, ws
->op
);
4521 ws
->src
= ac_build_inclusive_scan(ctx
, ws
->src
, ws
->op
);
4524 bool enable_inclusive
= ws
->enable_inclusive
;
4525 bool enable_exclusive
= ws
->enable_exclusive
;
4526 ws
->enable_inclusive
= false;
4527 ws
->enable_exclusive
= ws
->enable_exclusive
|| enable_inclusive
;
4528 ac_build_wg_wavescan_top(ctx
, ws
);
4529 ws
->enable_inclusive
= enable_inclusive
;
4530 ws
->enable_exclusive
= enable_exclusive
;
4534 * "Bottom half" of a scan that reduces per-thread values across an entire
4537 * The caller must place a barrier between the top and bottom halves.
4540 ac_build_wg_scan_bottom(struct ac_llvm_context
*ctx
, struct ac_wg_scan
*ws
)
4542 bool enable_inclusive
= ws
->enable_inclusive
;
4543 bool enable_exclusive
= ws
->enable_exclusive
;
4544 ws
->enable_inclusive
= false;
4545 ws
->enable_exclusive
= ws
->enable_exclusive
|| enable_inclusive
;
4546 ac_build_wg_wavescan_bottom(ctx
, ws
);
4547 ws
->enable_inclusive
= enable_inclusive
;
4548 ws
->enable_exclusive
= enable_exclusive
;
4550 /* ws->result_reduce is already the correct value */
4551 if (ws
->enable_inclusive
)
4552 ws
->result_inclusive
= ac_build_alu_op(ctx
, ws
->result_inclusive
, ws
->src
, ws
->op
);
4553 if (ws
->enable_exclusive
)
4554 ws
->result_exclusive
= ac_build_alu_op(ctx
, ws
->result_exclusive
, ws
->extra
, ws
->op
);
4558 * A scan that reduces per-thread values across an entire workgroup.
4560 * The caller must ensure that all lanes are active when this code runs
4561 * (WWM is insufficient!), because there is an implied barrier.
4564 ac_build_wg_scan(struct ac_llvm_context
*ctx
, struct ac_wg_scan
*ws
)
4566 ac_build_wg_scan_top(ctx
, ws
);
4567 ac_build_s_barrier(ctx
);
4568 ac_build_wg_scan_bottom(ctx
, ws
);
4572 ac_build_quad_swizzle(struct ac_llvm_context
*ctx
, LLVMValueRef src
,
4573 unsigned lane0
, unsigned lane1
, unsigned lane2
, unsigned lane3
)
4575 unsigned mask
= dpp_quad_perm(lane0
, lane1
, lane2
, lane3
);
4576 if (ctx
->chip_class
>= GFX8
) {
4577 return ac_build_dpp(ctx
, src
, src
, mask
, 0xf, 0xf, false);
4579 return ac_build_ds_swizzle(ctx
, src
, (1 << 15) | mask
);
4584 ac_build_shuffle(struct ac_llvm_context
*ctx
, LLVMValueRef src
, LLVMValueRef index
)
4586 LLVMTypeRef type
= LLVMTypeOf(src
);
4587 LLVMValueRef result
;
4589 index
= LLVMBuildMul(ctx
->builder
, index
, LLVMConstInt(ctx
->i32
, 4, 0), "");
4590 src
= LLVMBuildZExt(ctx
->builder
, src
, ctx
->i32
, "");
4592 result
= ac_build_intrinsic(ctx
, "llvm.amdgcn.ds.bpermute", ctx
->i32
,
4593 (LLVMValueRef
[]) {index
, src
}, 2,
4594 AC_FUNC_ATTR_READNONE
|
4595 AC_FUNC_ATTR_CONVERGENT
);
4596 return LLVMBuildTrunc(ctx
->builder
, result
, type
, "");
4600 ac_build_frexp_exp(struct ac_llvm_context
*ctx
, LLVMValueRef src0
,
4606 if (bitsize
== 16) {
4607 intr
= "llvm.amdgcn.frexp.exp.i16.f16";
4609 } else if (bitsize
== 32) {
4610 intr
= "llvm.amdgcn.frexp.exp.i32.f32";
4613 intr
= "llvm.amdgcn.frexp.exp.i32.f64";
4617 LLVMValueRef params
[] = {
4620 return ac_build_intrinsic(ctx
, intr
, type
, params
, 1,
4621 AC_FUNC_ATTR_READNONE
);
4624 ac_build_frexp_mant(struct ac_llvm_context
*ctx
, LLVMValueRef src0
,
4630 if (bitsize
== 16) {
4631 intr
= "llvm.amdgcn.frexp.mant.f16";
4633 } else if (bitsize
== 32) {
4634 intr
= "llvm.amdgcn.frexp.mant.f32";
4637 intr
= "llvm.amdgcn.frexp.mant.f64";
4641 LLVMValueRef params
[] = {
4644 return ac_build_intrinsic(ctx
, intr
, type
, params
, 1,
4645 AC_FUNC_ATTR_READNONE
);
4649 ac_build_canonicalize(struct ac_llvm_context
*ctx
, LLVMValueRef src0
,
4655 if (bitsize
== 16) {
4656 intr
= "llvm.canonicalize.f16";
4658 } else if (bitsize
== 32) {
4659 intr
= "llvm.canonicalize.f32";
4662 intr
= "llvm.canonicalize.f64";
4666 LLVMValueRef params
[] = {
4669 return ac_build_intrinsic(ctx
, intr
, type
, params
, 1,
4670 AC_FUNC_ATTR_READNONE
);
4674 * this takes an I,J coordinate pair,
4675 * and works out the X and Y derivatives.
4676 * it returns DDX(I), DDX(J), DDY(I), DDY(J).
4679 ac_build_ddxy_interp(struct ac_llvm_context
*ctx
, LLVMValueRef interp_ij
)
4681 LLVMValueRef result
[4], a
;
4684 for (i
= 0; i
< 2; i
++) {
4685 a
= LLVMBuildExtractElement(ctx
->builder
, interp_ij
,
4686 LLVMConstInt(ctx
->i32
, i
, false), "");
4687 result
[i
] = ac_build_ddxy(ctx
, AC_TID_MASK_TOP_LEFT
, 1, a
);
4688 result
[2+i
] = ac_build_ddxy(ctx
, AC_TID_MASK_TOP_LEFT
, 2, a
);
4690 return ac_build_gather_values(ctx
, result
, 4);
4694 ac_build_load_helper_invocation(struct ac_llvm_context
*ctx
)
4696 LLVMValueRef result
= ac_build_intrinsic(ctx
, "llvm.amdgcn.ps.live",
4698 AC_FUNC_ATTR_READNONE
);
4699 result
= LLVMBuildNot(ctx
->builder
, result
, "");
4700 return LLVMBuildSExt(ctx
->builder
, result
, ctx
->i32
, "");
4704 ac_build_is_helper_invocation(struct ac_llvm_context
*ctx
)
4706 if (!ctx
->postponed_kill
)
4707 return ac_build_load_helper_invocation(ctx
);
4709 /* !(exact && postponed) */
4710 LLVMValueRef exact
= ac_build_intrinsic(ctx
, "llvm.amdgcn.ps.live",
4712 AC_FUNC_ATTR_READNONE
);
4714 LLVMValueRef postponed
= LLVMBuildLoad(ctx
->builder
, ctx
->postponed_kill
, "");
4715 LLVMValueRef result
= LLVMBuildAnd(ctx
->builder
, exact
, postponed
, "");
4717 return LLVMBuildSelect(ctx
->builder
, result
, ctx
->i32_0
,
4718 LLVMConstInt(ctx
->i32
, 0xFFFFFFFF, false), "");
4721 LLVMValueRef
ac_build_call(struct ac_llvm_context
*ctx
, LLVMValueRef func
,
4722 LLVMValueRef
*args
, unsigned num_args
)
4724 LLVMValueRef ret
= LLVMBuildCall(ctx
->builder
, func
, args
, num_args
, "");
4725 LLVMSetInstructionCallConv(ret
, LLVMGetFunctionCallConv(func
));
4730 ac_export_mrt_z(struct ac_llvm_context
*ctx
, LLVMValueRef depth
,
4731 LLVMValueRef stencil
, LLVMValueRef samplemask
,
4732 struct ac_export_args
*args
)
4735 unsigned format
= ac_get_spi_shader_z_format(depth
!= NULL
,
4737 samplemask
!= NULL
);
4739 assert(depth
|| stencil
|| samplemask
);
4741 memset(args
, 0, sizeof(*args
));
4743 args
->valid_mask
= 1; /* whether the EXEC mask is valid */
4744 args
->done
= 1; /* DONE bit */
4746 /* Specify the target we are exporting */
4747 args
->target
= V_008DFC_SQ_EXP_MRTZ
;
4749 args
->compr
= 0; /* COMP flag */
4750 args
->out
[0] = LLVMGetUndef(ctx
->f32
); /* R, depth */
4751 args
->out
[1] = LLVMGetUndef(ctx
->f32
); /* G, stencil test val[0:7], stencil op val[8:15] */
4752 args
->out
[2] = LLVMGetUndef(ctx
->f32
); /* B, sample mask */
4753 args
->out
[3] = LLVMGetUndef(ctx
->f32
); /* A, alpha to mask */
4755 if (format
== V_028710_SPI_SHADER_UINT16_ABGR
) {
4757 args
->compr
= 1; /* COMPR flag */
4760 /* Stencil should be in X[23:16]. */
4761 stencil
= ac_to_integer(ctx
, stencil
);
4762 stencil
= LLVMBuildShl(ctx
->builder
, stencil
,
4763 LLVMConstInt(ctx
->i32
, 16, 0), "");
4764 args
->out
[0] = ac_to_float(ctx
, stencil
);
4768 /* SampleMask should be in Y[15:0]. */
4769 args
->out
[1] = samplemask
;
4774 args
->out
[0] = depth
;
4778 args
->out
[1] = stencil
;
4782 args
->out
[2] = samplemask
;
4787 /* GFX6 (except OLAND and HAINAN) has a bug that it only looks
4788 * at the X writemask component. */
4789 if (ctx
->chip_class
== GFX6
&&
4790 ctx
->family
!= CHIP_OLAND
&&
4791 ctx
->family
!= CHIP_HAINAN
)
4794 /* Specify which components to enable */
4795 args
->enabled_channels
= mask
;
4798 /* Send GS Alloc Req message from the first wave of the group to SPI.
4799 * Message payload is:
4800 * - bits 0..10: vertices in group
4801 * - bits 12..22: primitives in group
4803 void ac_build_sendmsg_gs_alloc_req(struct ac_llvm_context
*ctx
, LLVMValueRef wave_id
,
4804 LLVMValueRef vtx_cnt
, LLVMValueRef prim_cnt
)
4806 LLVMBuilderRef builder
= ctx
->builder
;
4808 bool export_dummy_prim
= false;
4810 /* HW workaround for a GPU hang with 100% culling.
4811 * We always have to export at least 1 primitive.
4812 * Export a degenerate triangle using vertex 0 for all 3 vertices.
4814 if (prim_cnt
== ctx
->i32_0
&& ctx
->chip_class
== GFX10
) {
4815 assert(vtx_cnt
== ctx
->i32_0
);
4816 prim_cnt
= ctx
->i32_1
;
4817 vtx_cnt
= ctx
->i32_1
;
4818 export_dummy_prim
= true;
4821 ac_build_ifcc(ctx
, LLVMBuildICmp(builder
, LLVMIntEQ
, wave_id
, ctx
->i32_0
, ""), 5020);
4823 tmp
= LLVMBuildShl(builder
, prim_cnt
, LLVMConstInt(ctx
->i32
, 12, false),"");
4824 tmp
= LLVMBuildOr(builder
, tmp
, vtx_cnt
, "");
4825 ac_build_sendmsg(ctx
, AC_SENDMSG_GS_ALLOC_REQ
, tmp
);
4827 if (export_dummy_prim
) {
4828 struct ac_ngg_prim prim
= {};
4829 /* The vertex indices are 0,0,0. */
4830 prim
.passthrough
= ctx
->i32_0
;
4832 struct ac_export_args pos
= {};
4833 pos
.out
[0] = pos
.out
[1] = pos
.out
[2] = pos
.out
[3] = ctx
->f32_0
;
4834 pos
.target
= V_008DFC_SQ_EXP_POS
;
4835 pos
.enabled_channels
= 0xf;
4838 ac_build_ifcc(ctx
, LLVMBuildICmp(builder
, LLVMIntEQ
, ac_get_thread_id(ctx
),
4839 ctx
->i32_0
, ""), 5021);
4840 ac_build_export_prim(ctx
, &prim
);
4841 ac_build_export(ctx
, &pos
);
4842 ac_build_endif(ctx
, 5021);
4845 ac_build_endif(ctx
, 5020);
4848 LLVMValueRef
ac_pack_prim_export(struct ac_llvm_context
*ctx
,
4849 const struct ac_ngg_prim
*prim
)
4851 /* The prim export format is:
4852 * - bits 0..8: index 0
4853 * - bit 9: edge flag 0
4854 * - bits 10..18: index 1
4855 * - bit 19: edge flag 1
4856 * - bits 20..28: index 2
4857 * - bit 29: edge flag 2
4858 * - bit 31: null primitive (skip)
4860 LLVMBuilderRef builder
= ctx
->builder
;
4861 LLVMValueRef tmp
= LLVMBuildZExt(builder
, prim
->isnull
, ctx
->i32
, "");
4862 LLVMValueRef result
= LLVMBuildShl(builder
, tmp
, LLVMConstInt(ctx
->i32
, 31, false), "");
4864 for (unsigned i
= 0; i
< prim
->num_vertices
; ++i
) {
4865 tmp
= LLVMBuildShl(builder
, prim
->index
[i
],
4866 LLVMConstInt(ctx
->i32
, 10 * i
, false), "");
4867 result
= LLVMBuildOr(builder
, result
, tmp
, "");
4868 tmp
= LLVMBuildZExt(builder
, prim
->edgeflag
[i
], ctx
->i32
, "");
4869 tmp
= LLVMBuildShl(builder
, tmp
,
4870 LLVMConstInt(ctx
->i32
, 10 * i
+ 9, false), "");
4871 result
= LLVMBuildOr(builder
, result
, tmp
, "");
4876 void ac_build_export_prim(struct ac_llvm_context
*ctx
,
4877 const struct ac_ngg_prim
*prim
)
4879 struct ac_export_args args
;
4881 if (prim
->passthrough
) {
4882 args
.out
[0] = prim
->passthrough
;
4884 args
.out
[0] = ac_pack_prim_export(ctx
, prim
);
4887 args
.out
[0] = LLVMBuildBitCast(ctx
->builder
, args
.out
[0], ctx
->f32
, "");
4888 args
.out
[1] = LLVMGetUndef(ctx
->f32
);
4889 args
.out
[2] = LLVMGetUndef(ctx
->f32
);
4890 args
.out
[3] = LLVMGetUndef(ctx
->f32
);
4892 args
.target
= V_008DFC_SQ_EXP_PRIM
;
4893 args
.enabled_channels
= 1;
4895 args
.valid_mask
= false;
4898 ac_build_export(ctx
, &args
);
4902 arg_llvm_type(enum ac_arg_type type
, unsigned size
, struct ac_llvm_context
*ctx
)
4904 if (type
== AC_ARG_FLOAT
) {
4905 return size
== 1 ? ctx
->f32
: LLVMVectorType(ctx
->f32
, size
);
4906 } else if (type
== AC_ARG_INT
) {
4907 return size
== 1 ? ctx
->i32
: LLVMVectorType(ctx
->i32
, size
);
4909 LLVMTypeRef ptr_type
;
4911 case AC_ARG_CONST_PTR
:
4914 case AC_ARG_CONST_FLOAT_PTR
:
4915 ptr_type
= ctx
->f32
;
4917 case AC_ARG_CONST_PTR_PTR
:
4918 ptr_type
= ac_array_in_const32_addr_space(ctx
->i8
);
4920 case AC_ARG_CONST_DESC_PTR
:
4921 ptr_type
= ctx
->v4i32
;
4923 case AC_ARG_CONST_IMAGE_PTR
:
4924 ptr_type
= ctx
->v8i32
;
4927 unreachable("unknown arg type");
4930 return ac_array_in_const32_addr_space(ptr_type
);
4933 return ac_array_in_const_addr_space(ptr_type
);
4939 ac_build_main(const struct ac_shader_args
*args
,
4940 struct ac_llvm_context
*ctx
,
4941 enum ac_llvm_calling_convention convention
,
4942 const char *name
, LLVMTypeRef ret_type
,
4943 LLVMModuleRef module
)
4945 LLVMTypeRef arg_types
[AC_MAX_ARGS
];
4947 for (unsigned i
= 0; i
< args
->arg_count
; i
++) {
4948 arg_types
[i
] = arg_llvm_type(args
->args
[i
].type
,
4949 args
->args
[i
].size
, ctx
);
4952 LLVMTypeRef main_function_type
=
4953 LLVMFunctionType(ret_type
, arg_types
, args
->arg_count
, 0);
4955 LLVMValueRef main_function
=
4956 LLVMAddFunction(module
, name
, main_function_type
);
4957 LLVMBasicBlockRef main_function_body
=
4958 LLVMAppendBasicBlockInContext(ctx
->context
, main_function
, "main_body");
4959 LLVMPositionBuilderAtEnd(ctx
->builder
, main_function_body
);
4961 LLVMSetFunctionCallConv(main_function
, convention
);
4962 for (unsigned i
= 0; i
< args
->arg_count
; ++i
) {
4963 LLVMValueRef P
= LLVMGetParam(main_function
, i
);
4965 if (args
->args
[i
].file
!= AC_ARG_SGPR
)
4968 ac_add_function_attr(ctx
->context
, main_function
, i
+ 1, AC_FUNC_ATTR_INREG
);
4970 if (LLVMGetTypeKind(LLVMTypeOf(P
)) == LLVMPointerTypeKind
) {
4971 ac_add_function_attr(ctx
->context
, main_function
, i
+ 1, AC_FUNC_ATTR_NOALIAS
);
4972 ac_add_attr_dereferenceable(P
, UINT64_MAX
);
4976 ctx
->main_function
= main_function
;
4978 if (LLVM_VERSION_MAJOR
>= 11) {
4979 /* Enable denormals for FP16 and FP64: */
4980 LLVMAddTargetDependentFunctionAttr(main_function
, "denormal-fp-math",
4982 /* Disable denormals for FP32: */
4983 LLVMAddTargetDependentFunctionAttr(main_function
, "denormal-fp-math-f32",
4984 "preserve-sign,preserve-sign");
4986 return main_function
;
4989 void ac_build_s_endpgm(struct ac_llvm_context
*ctx
)
4991 LLVMTypeRef calltype
= LLVMFunctionType(ctx
->voidt
, NULL
, 0, false);
4992 LLVMValueRef code
= LLVMConstInlineAsm(calltype
, "s_endpgm", "", true, false);
4993 LLVMBuildCall(ctx
->builder
, code
, NULL
, 0, "");
4996 LLVMValueRef
ac_prefix_bitcount(struct ac_llvm_context
*ctx
,
4997 LLVMValueRef mask
, LLVMValueRef index
)
4999 LLVMBuilderRef builder
= ctx
->builder
;
5000 LLVMTypeRef type
= LLVMTypeOf(mask
);
5002 LLVMValueRef bit
= LLVMBuildShl(builder
, LLVMConstInt(type
, 1, 0),
5003 LLVMBuildZExt(builder
, index
, type
, ""), "");
5004 LLVMValueRef prefix_bits
= LLVMBuildSub(builder
, bit
, LLVMConstInt(type
, 1, 0), "");
5005 LLVMValueRef prefix_mask
= LLVMBuildAnd(builder
, mask
, prefix_bits
, "");
5006 return ac_build_bit_count(ctx
, prefix_mask
);
5009 /* Compute the prefix sum of the "mask" bit array with 128 elements (bits). */
5010 LLVMValueRef
ac_prefix_bitcount_2x64(struct ac_llvm_context
*ctx
,
5011 LLVMValueRef mask
[2], LLVMValueRef index
)
5013 LLVMBuilderRef builder
= ctx
->builder
;
5015 /* Reference version using i128. */
5016 LLVMValueRef input_mask
=
5017 LLVMBuildBitCast(builder
, ac_build_gather_values(ctx
, mask
, 2), ctx
->i128
, "");
5019 return ac_prefix_bitcount(ctx
, input_mask
, index
);
5021 /* Optimized version using 2 64-bit masks. */
5022 LLVMValueRef is_hi
, is_0
, c64
, c128
, all_bits
;
5023 LLVMValueRef prefix_mask
[2], shift
[2], mask_bcnt0
, prefix_bcnt
[2];
5025 /* Compute the 128-bit prefix mask. */
5026 c64
= LLVMConstInt(ctx
->i32
, 64, 0);
5027 c128
= LLVMConstInt(ctx
->i32
, 128, 0);
5028 all_bits
= LLVMConstInt(ctx
->i64
, UINT64_MAX
, 0);
5029 /* The first index that can have non-zero high bits in the prefix mask is 65. */
5030 is_hi
= LLVMBuildICmp(builder
, LLVMIntUGT
, index
, c64
, "");
5031 is_0
= LLVMBuildICmp(builder
, LLVMIntEQ
, index
, ctx
->i32_0
, "");
5032 mask_bcnt0
= ac_build_bit_count(ctx
, mask
[0]);
5034 for (unsigned i
= 0; i
< 2; i
++) {
5035 shift
[i
] = LLVMBuildSub(builder
, i
? c128
: c64
, index
, "");
5036 /* For i==0, index==0, the right shift by 64 doesn't give the desired result,
5037 * so we handle it by the is_0 select.
5038 * For i==1, index==64, same story, so we handle it by the last is_hi select.
5039 * For i==0, index==64, we shift by 0, which is what we want.
5041 prefix_mask
[i
] = LLVMBuildLShr(builder
, all_bits
,
5042 LLVMBuildZExt(builder
, shift
[i
], ctx
->i64
, ""), "");
5043 prefix_mask
[i
] = LLVMBuildAnd(builder
, mask
[i
], prefix_mask
[i
], "");
5044 prefix_bcnt
[i
] = ac_build_bit_count(ctx
, prefix_mask
[i
]);
5047 prefix_bcnt
[0] = LLVMBuildSelect(builder
, is_0
, ctx
->i32_0
, prefix_bcnt
[0], "");
5048 prefix_bcnt
[0] = LLVMBuildSelect(builder
, is_hi
, mask_bcnt0
, prefix_bcnt
[0], "");
5049 prefix_bcnt
[1] = LLVMBuildSelect(builder
, is_hi
, prefix_bcnt
[1], ctx
->i32_0
, "");
5051 return LLVMBuildAdd(builder
, prefix_bcnt
[0], prefix_bcnt
[1], "");
5056 * Convert triangle strip indices to triangle indices. This is used to decompose
5057 * triangle strips into triangles.
5059 void ac_build_triangle_strip_indices_to_triangle(struct ac_llvm_context
*ctx
,
5060 LLVMValueRef is_odd
,
5061 LLVMValueRef flatshade_first
,
5062 LLVMValueRef index
[3])
5064 LLVMBuilderRef builder
= ctx
->builder
;
5065 LLVMValueRef out
[3];
5067 /* We need to change the vertex order for odd triangles to get correct
5068 * front/back facing by swapping 2 vertex indices, but we also have to
5069 * keep the provoking vertex in the same place.
5071 * If the first vertex is provoking, swap index 1 and 2.
5072 * If the last vertex is provoking, swap index 0 and 1.
5074 out
[0] = LLVMBuildSelect(builder
, flatshade_first
,
5076 LLVMBuildSelect(builder
, is_odd
,
5077 index
[1], index
[0], ""), "");
5078 out
[1] = LLVMBuildSelect(builder
, flatshade_first
,
5079 LLVMBuildSelect(builder
, is_odd
,
5080 index
[2], index
[1], ""),
5081 LLVMBuildSelect(builder
, is_odd
,
5082 index
[0], index
[1], ""), "");
5083 out
[2] = LLVMBuildSelect(builder
, flatshade_first
,
5084 LLVMBuildSelect(builder
, is_odd
,
5085 index
[1], index
[2], ""),
5087 memcpy(index
, out
, sizeof(out
));