2 * Copyright © 2018 Valve Corporation
4 * Permission is hereby granted, free of charge, to any person obtaining a
5 * copy of this software and associated documentation files (the "Software"),
6 * to deal in the Software without restriction, including without limitation
7 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8 * and/or sell copies of the Software, and to permit persons to whom the
9 * Software is furnished to do so, subject to the following conditions:
11 * The above copyright notice and this permission notice (including the next
12 * paragraph) shall be included in all copies or substantial portions of the
15 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
16 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
17 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
18 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
19 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
20 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
24 * Daniel Schürmann (daniel.schuermann@campus.tu-berlin.de)
32 #include "util/half_float.h"
33 #include "util/u_math.h"
38 * The optimizer works in 4 phases:
39 * (1) The first pass collects information for each ssa-def,
40 * propagates reg->reg operands of the same type, inline constants
41 * and neg/abs input modifiers.
42 * (2) The second pass combines instructions like mad, omod, clamp and
43 * propagates sgpr's on VALU instructions.
44 * This pass depends on information collected in the first pass.
45 * (3) The third pass goes backwards, and selects instructions,
46 * i.e. decides if a mad instruction is profitable and eliminates dead code.
47 * (4) The fourth pass cleans up the sequence: literals get applied and dead
48 * instructions are removed from the sequence.
53 aco_ptr
<Instruction
> add_instr
;
58 mad_info(aco_ptr
<Instruction
> instr
, uint32_t id
)
59 : add_instr(std::move(instr
)), mul_temp_id(id
), check_literal(false) {}
64 label_constant
= 1 << 1,
69 label_literal
= 1 << 6,
73 label_omod5
= 1 << 10,
74 label_omod_success
= 1 << 11,
75 label_clamp
= 1 << 12,
76 label_clamp_success
= 1 << 13,
77 label_undefined
= 1 << 14,
80 label_add_sub
= 1 << 17,
81 label_bitwise
= 1 << 18,
82 label_minmax
= 1 << 19,
84 label_uniform_bool
= 1 << 21,
85 label_constant_64bit
= 1 << 22,
86 label_uniform_bitwise
= 1 << 23,
87 label_scc_invert
= 1 << 24,
88 label_vcc_hint
= 1 << 25,
89 label_scc_needed
= 1 << 26,
92 static constexpr uint32_t instr_labels
= label_vec
| label_mul
| label_mad
| label_omod_success
| label_clamp_success
|
93 label_add_sub
| label_bitwise
| label_uniform_bitwise
| label_minmax
| label_fcmp
;
94 static constexpr uint32_t temp_labels
= label_abs
| label_neg
| label_temp
| label_vcc
| label_b2f
| label_uniform_bool
|
95 label_omod2
| label_omod4
| label_omod5
| label_clamp
| label_scc_invert
;
96 static constexpr uint32_t val_labels
= label_constant
| label_constant_64bit
| label_literal
| label_mad
;
106 ssa_info() : label(0) {}
108 void add_label(Label new_label
)
110 /* Since all labels which use "instr" use it for the same thing
111 * (indicating the defining instruction), there is no need to clear
112 * any other instr labels. */
113 if (new_label
& instr_labels
)
114 label
&= ~temp_labels
; /* instr and temp alias */
116 if (new_label
& temp_labels
) {
117 label
&= ~temp_labels
;
118 label
&= ~instr_labels
; /* instr and temp alias */
121 if (new_label
& val_labels
)
122 label
&= ~val_labels
;
127 void set_vec(Instruction
* vec
)
129 add_label(label_vec
);
135 return label
& label_vec
;
138 void set_constant(uint32_t constant
)
140 add_label(label_constant
);
146 return label
& label_constant
;
149 void set_constant_64bit(uint32_t constant
)
151 add_label(label_constant_64bit
);
155 bool is_constant_64bit()
157 return label
& label_constant_64bit
;
160 void set_abs(Temp abs_temp
)
162 add_label(label_abs
);
168 return label
& label_abs
;
171 void set_neg(Temp neg_temp
)
173 add_label(label_neg
);
179 return label
& label_neg
;
182 void set_neg_abs(Temp neg_abs_temp
)
184 add_label((Label
)((uint32_t)label_abs
| (uint32_t)label_neg
));
188 void set_mul(Instruction
* mul
)
190 add_label(label_mul
);
196 return label
& label_mul
;
199 void set_temp(Temp tmp
)
201 add_label(label_temp
);
207 return label
& label_temp
;
210 void set_literal(uint32_t lit
)
212 add_label(label_literal
);
218 return label
& label_literal
;
221 void set_mad(Instruction
* mad
, uint32_t mad_info_idx
)
223 add_label(label_mad
);
230 return label
& label_mad
;
233 void set_omod2(Temp def
)
235 add_label(label_omod2
);
241 return label
& label_omod2
;
244 void set_omod4(Temp def
)
246 add_label(label_omod4
);
252 return label
& label_omod4
;
255 void set_omod5(Temp def
)
257 add_label(label_omod5
);
263 return label
& label_omod5
;
266 void set_omod_success(Instruction
* omod_instr
)
268 add_label(label_omod_success
);
272 bool is_omod_success()
274 return label
& label_omod_success
;
277 void set_clamp(Temp def
)
279 add_label(label_clamp
);
285 return label
& label_clamp
;
288 void set_clamp_success(Instruction
* clamp_instr
)
290 add_label(label_clamp_success
);
294 bool is_clamp_success()
296 return label
& label_clamp_success
;
301 add_label(label_undefined
);
306 return label
& label_undefined
;
309 void set_vcc(Temp vcc
)
311 add_label(label_vcc
);
317 return label
& label_vcc
;
320 bool is_constant_or_literal()
322 return is_constant() || is_literal();
325 void set_b2f(Temp val
)
327 add_label(label_b2f
);
333 return label
& label_b2f
;
336 void set_add_sub(Instruction
*add_sub_instr
)
338 add_label(label_add_sub
);
339 instr
= add_sub_instr
;
344 return label
& label_add_sub
;
347 void set_bitwise(Instruction
*bitwise_instr
)
349 add_label(label_bitwise
);
350 instr
= bitwise_instr
;
355 return label
& label_bitwise
;
358 void set_uniform_bitwise()
360 add_label(label_uniform_bitwise
);
363 bool is_uniform_bitwise()
365 return label
& label_uniform_bitwise
;
368 void set_minmax(Instruction
*minmax_instr
)
370 add_label(label_minmax
);
371 instr
= minmax_instr
;
376 return label
& label_minmax
;
379 void set_fcmp(Instruction
*fcmp_instr
)
381 add_label(label_fcmp
);
387 return label
& label_fcmp
;
390 void set_scc_needed()
392 add_label(label_scc_needed
);
397 return label
& label_scc_needed
;
400 void set_scc_invert(Temp scc_inv
)
402 add_label(label_scc_invert
);
408 return label
& label_scc_invert
;
411 void set_uniform_bool(Temp uniform_bool
)
413 add_label(label_uniform_bool
);
417 bool is_uniform_bool()
419 return label
& label_uniform_bool
;
424 add_label(label_vcc_hint
);
429 return label
& label_vcc_hint
;
435 std::vector
<aco_ptr
<Instruction
>> instructions
;
437 std::pair
<uint32_t,Temp
> last_literal
;
438 std::vector
<mad_info
> mad_infos
;
439 std::vector
<uint16_t> uses
;
442 bool can_swap_operands(aco_ptr
<Instruction
>& instr
)
444 if (instr
->operands
[0].isConstant() ||
445 (instr
->operands
[0].isTemp() && instr
->operands
[0].getTemp().type() == RegType::sgpr
))
448 switch (instr
->opcode
) {
449 case aco_opcode::v_add_f32
:
450 case aco_opcode::v_mul_f32
:
451 case aco_opcode::v_or_b32
:
452 case aco_opcode::v_and_b32
:
453 case aco_opcode::v_xor_b32
:
454 case aco_opcode::v_max_f32
:
455 case aco_opcode::v_min_f32
:
456 case aco_opcode::v_max_i32
:
457 case aco_opcode::v_min_i32
:
458 case aco_opcode::v_max_u32
:
459 case aco_opcode::v_min_u32
:
460 case aco_opcode::v_cmp_eq_f32
:
461 case aco_opcode::v_cmp_lg_f32
:
463 case aco_opcode::v_sub_f32
:
464 instr
->opcode
= aco_opcode::v_subrev_f32
;
466 case aco_opcode::v_cmp_lt_f32
:
467 instr
->opcode
= aco_opcode::v_cmp_gt_f32
;
469 case aco_opcode::v_cmp_ge_f32
:
470 instr
->opcode
= aco_opcode::v_cmp_le_f32
;
472 case aco_opcode::v_cmp_lt_i32
:
473 instr
->opcode
= aco_opcode::v_cmp_gt_i32
;
480 bool can_use_VOP3(opt_ctx
& ctx
, aco_ptr
<Instruction
>& instr
)
485 if (instr
->operands
.size() && instr
->operands
[0].isLiteral() && ctx
.program
->chip_class
< GFX10
)
488 if (instr
->isDPP() || instr
->isSDWA())
491 return instr
->opcode
!= aco_opcode::v_madmk_f32
&&
492 instr
->opcode
!= aco_opcode::v_madak_f32
&&
493 instr
->opcode
!= aco_opcode::v_madmk_f16
&&
494 instr
->opcode
!= aco_opcode::v_madak_f16
&&
495 instr
->opcode
!= aco_opcode::v_fmamk_f32
&&
496 instr
->opcode
!= aco_opcode::v_fmaak_f32
&&
497 instr
->opcode
!= aco_opcode::v_fmamk_f16
&&
498 instr
->opcode
!= aco_opcode::v_fmaak_f16
&&
499 instr
->opcode
!= aco_opcode::v_readlane_b32
&&
500 instr
->opcode
!= aco_opcode::v_writelane_b32
&&
501 instr
->opcode
!= aco_opcode::v_readfirstlane_b32
;
504 bool can_apply_sgprs(aco_ptr
<Instruction
>& instr
)
506 return instr
->opcode
!= aco_opcode::v_readfirstlane_b32
&&
507 instr
->opcode
!= aco_opcode::v_readlane_b32
&&
508 instr
->opcode
!= aco_opcode::v_readlane_b32_e64
&&
509 instr
->opcode
!= aco_opcode::v_writelane_b32
&&
510 instr
->opcode
!= aco_opcode::v_writelane_b32_e64
;
513 void to_VOP3(opt_ctx
& ctx
, aco_ptr
<Instruction
>& instr
)
518 aco_ptr
<Instruction
> tmp
= std::move(instr
);
519 Format format
= asVOP3(tmp
->format
);
520 instr
.reset(create_instruction
<VOP3A_instruction
>(tmp
->opcode
, format
, tmp
->operands
.size(), tmp
->definitions
.size()));
521 std::copy(tmp
->operands
.cbegin(), tmp
->operands
.cend(), instr
->operands
.begin());
522 for (unsigned i
= 0; i
< instr
->definitions
.size(); i
++) {
523 instr
->definitions
[i
] = tmp
->definitions
[i
];
524 if (instr
->definitions
[i
].isTemp()) {
525 ssa_info
& info
= ctx
.info
[instr
->definitions
[i
].tempId()];
526 if (info
.label
& instr_labels
&& info
.instr
== tmp
.get())
527 info
.instr
= instr
.get();
532 /* only covers special cases */
533 bool alu_can_accept_constant(aco_opcode opcode
, unsigned operand
)
536 case aco_opcode::v_interp_p2_f32
:
537 case aco_opcode::v_mac_f32
:
538 case aco_opcode::v_writelane_b32
:
539 case aco_opcode::v_writelane_b32_e64
:
540 case aco_opcode::v_cndmask_b32
:
542 case aco_opcode::s_addk_i32
:
543 case aco_opcode::s_mulk_i32
:
544 case aco_opcode::p_wqm
:
545 case aco_opcode::p_extract_vector
:
546 case aco_opcode::p_split_vector
:
547 case aco_opcode::v_readlane_b32
:
548 case aco_opcode::v_readlane_b32_e64
:
549 case aco_opcode::v_readfirstlane_b32
:
556 bool valu_can_accept_vgpr(aco_ptr
<Instruction
>& instr
, unsigned operand
)
558 if (instr
->opcode
== aco_opcode::v_readlane_b32
|| instr
->opcode
== aco_opcode::v_readlane_b32_e64
||
559 instr
->opcode
== aco_opcode::v_writelane_b32
|| instr
->opcode
== aco_opcode::v_writelane_b32_e64
)
564 /* check constant bus and literal limitations */
565 bool check_vop3_operands(opt_ctx
& ctx
, unsigned num_operands
, Operand
*operands
)
567 int limit
= ctx
.program
->chip_class
>= GFX10
? 2 : 1;
568 Operand
literal32(s1
);
569 Operand
literal64(s2
);
570 unsigned num_sgprs
= 0;
571 unsigned sgpr
[] = {0, 0};
573 for (unsigned i
= 0; i
< num_operands
; i
++) {
574 Operand op
= operands
[i
];
576 if (op
.hasRegClass() && op
.regClass().type() == RegType::sgpr
) {
577 /* two reads of the same SGPR count as 1 to the limit */
578 if (op
.tempId() != sgpr
[0] && op
.tempId() != sgpr
[1]) {
580 sgpr
[num_sgprs
++] = op
.tempId();
585 } else if (op
.isLiteral()) {
586 if (ctx
.program
->chip_class
< GFX10
)
589 if (!literal32
.isUndefined() && literal32
.constantValue() != op
.constantValue())
591 if (!literal64
.isUndefined() && literal64
.constantValue() != op
.constantValue())
594 /* Any number of 32-bit literals counts as only 1 to the limit. Same
595 * (but separately) for 64-bit literals. */
596 if (op
.size() == 1 && literal32
.isUndefined()) {
599 } else if (op
.size() == 2 && literal64
.isUndefined()) {
612 bool parse_base_offset(opt_ctx
&ctx
, Instruction
* instr
, unsigned op_index
, Temp
*base
, uint32_t *offset
)
614 Operand op
= instr
->operands
[op_index
];
618 Temp tmp
= op
.getTemp();
619 if (!ctx
.info
[tmp
.id()].is_add_sub())
622 Instruction
*add_instr
= ctx
.info
[tmp
.id()].instr
;
624 switch (add_instr
->opcode
) {
625 case aco_opcode::v_add_u32
:
626 case aco_opcode::v_add_co_u32
:
627 case aco_opcode::v_add_co_u32_e64
:
628 case aco_opcode::s_add_i32
:
629 case aco_opcode::s_add_u32
:
635 if (add_instr
->usesModifiers())
638 for (unsigned i
= 0; i
< 2; i
++) {
639 if (add_instr
->operands
[i
].isConstant()) {
640 *offset
= add_instr
->operands
[i
].constantValue();
641 } else if (add_instr
->operands
[i
].isTemp() &&
642 ctx
.info
[add_instr
->operands
[i
].tempId()].is_constant_or_literal()) {
643 *offset
= ctx
.info
[add_instr
->operands
[i
].tempId()].val
;
647 if (!add_instr
->operands
[!i
].isTemp())
650 uint32_t offset2
= 0;
651 if (parse_base_offset(ctx
, add_instr
, !i
, base
, &offset2
)) {
654 *base
= add_instr
->operands
[!i
].getTemp();
662 Operand
get_constant_op(opt_ctx
&ctx
, uint32_t val
, bool is64bit
= false)
664 // TODO: this functions shouldn't be needed if we store Operand instead of value.
665 Operand
op(val
, is64bit
);
666 if (val
== 0x3e22f983 && ctx
.program
->chip_class
>= GFX8
)
667 op
.setFixed(PhysReg
{248}); /* 1/2 PI can be an inline constant on GFX8+ */
671 bool fixed_to_exec(Operand op
)
673 return op
.isFixed() && op
.physReg() == exec
;
676 void label_instruction(opt_ctx
&ctx
, Block
& block
, aco_ptr
<Instruction
>& instr
)
678 if (instr
->isSALU() || instr
->isVALU() || instr
->format
== Format::PSEUDO
) {
679 ASSERTED
bool all_const
= false;
680 for (Operand
& op
: instr
->operands
)
681 all_const
= all_const
&& (!op
.isTemp() || ctx
.info
[op
.tempId()].is_constant_or_literal());
682 perfwarn(all_const
, "All instruction operands are constant", instr
.get());
685 for (unsigned i
= 0; i
< instr
->operands
.size(); i
++)
687 if (!instr
->operands
[i
].isTemp())
690 ssa_info info
= ctx
.info
[instr
->operands
[i
].tempId()];
691 /* propagate undef */
692 if (info
.is_undefined() && is_phi(instr
))
693 instr
->operands
[i
] = Operand(instr
->operands
[i
].regClass());
694 /* propagate reg->reg of same type */
695 if (info
.is_temp() && info
.temp
.regClass() == instr
->operands
[i
].getTemp().regClass()) {
696 instr
->operands
[i
].setTemp(ctx
.info
[instr
->operands
[i
].tempId()].temp
);
697 info
= ctx
.info
[info
.temp
.id()];
700 /* SALU / PSEUDO: propagate inline constants */
701 if (instr
->isSALU() || instr
->format
== Format::PSEUDO
) {
702 const bool is_subdword
= std::any_of(instr
->definitions
.begin(), instr
->definitions
.end(),
703 [] (const Definition
& def
) { return def
.regClass().is_subdword();});
704 // TODO: optimize SGPR and constant propagation for subdword pseudo instructions on gfx9+
708 if (info
.is_temp() && info
.temp
.type() == RegType::sgpr
) {
709 instr
->operands
[i
].setTemp(info
.temp
);
710 info
= ctx
.info
[info
.temp
.id()];
711 } else if (info
.is_temp() && info
.temp
.type() == RegType::vgpr
) {
712 /* propagate vgpr if it can take it */
713 switch (instr
->opcode
) {
714 case aco_opcode::p_create_vector
:
715 case aco_opcode::p_split_vector
:
716 case aco_opcode::p_extract_vector
:
717 case aco_opcode::p_phi
: {
718 const bool all_vgpr
= std::none_of(instr
->definitions
.begin(), instr
->definitions
.end(),
719 [] (const Definition
& def
) { return def
.getTemp().type() != RegType::vgpr
;});
721 instr
->operands
[i
] = Operand(info
.temp
);
722 info
= ctx
.info
[info
.temp
.id()];
730 if ((info
.is_constant() || info
.is_constant_64bit() || (info
.is_literal() && instr
->format
== Format::PSEUDO
)) &&
731 !instr
->operands
[i
].isFixed() && alu_can_accept_constant(instr
->opcode
, i
)) {
732 instr
->operands
[i
] = get_constant_op(ctx
, info
.val
, info
.is_constant_64bit());
737 /* VALU: propagate neg, abs & inline constants */
738 else if (instr
->isVALU()) {
739 if (info
.is_temp() && info
.temp
.type() == RegType::vgpr
&& valu_can_accept_vgpr(instr
, i
)) {
740 instr
->operands
[i
].setTemp(info
.temp
);
741 info
= ctx
.info
[info
.temp
.id()];
743 if (info
.is_abs() && (can_use_VOP3(ctx
, instr
) || instr
->isDPP()) && instr_info
.can_use_input_modifiers
[(int)instr
->opcode
]) {
746 instr
->operands
[i
] = Operand(info
.temp
);
748 static_cast<DPP_instruction
*>(instr
.get())->abs
[i
] = true;
750 static_cast<VOP3A_instruction
*>(instr
.get())->abs
[i
] = true;
752 if (info
.is_neg() && instr
->opcode
== aco_opcode::v_add_f32
) {
753 instr
->opcode
= i
? aco_opcode::v_sub_f32
: aco_opcode::v_subrev_f32
;
754 instr
->operands
[i
].setTemp(info
.temp
);
756 } else if (info
.is_neg() && (can_use_VOP3(ctx
, instr
) || instr
->isDPP()) && instr_info
.can_use_input_modifiers
[(int)instr
->opcode
]) {
759 instr
->operands
[i
].setTemp(info
.temp
);
761 static_cast<DPP_instruction
*>(instr
.get())->neg
[i
] = true;
763 static_cast<VOP3A_instruction
*>(instr
.get())->neg
[i
] = true;
766 if ((info
.is_constant() || info
.is_constant_64bit()) && alu_can_accept_constant(instr
->opcode
, i
)) {
767 Operand op
= get_constant_op(ctx
, info
.val
, info
.is_constant_64bit());
768 perfwarn(instr
->opcode
== aco_opcode::v_cndmask_b32
&& i
== 2, "v_cndmask_b32 with a constant selector", instr
.get());
769 if (i
== 0 || instr
->opcode
== aco_opcode::v_readlane_b32
|| instr
->opcode
== aco_opcode::v_writelane_b32
) {
770 instr
->operands
[i
] = op
;
772 } else if (!instr
->isVOP3() && can_swap_operands(instr
)) {
773 instr
->operands
[i
] = instr
->operands
[0];
774 instr
->operands
[0] = op
;
776 } else if (can_use_VOP3(ctx
, instr
)) {
778 instr
->operands
[i
] = op
;
784 /* MUBUF: propagate constants and combine additions */
785 else if (instr
->format
== Format::MUBUF
) {
786 MUBUF_instruction
*mubuf
= static_cast<MUBUF_instruction
*>(instr
.get());
789 while (info
.is_temp())
790 info
= ctx
.info
[info
.temp
.id()];
792 if (mubuf
->offen
&& i
== 1 && info
.is_constant_or_literal() && mubuf
->offset
+ info
.val
< 4096) {
793 assert(!mubuf
->idxen
);
794 instr
->operands
[1] = Operand(v1
);
795 mubuf
->offset
+= info
.val
;
796 mubuf
->offen
= false;
798 } else if (i
== 2 && info
.is_constant_or_literal() && mubuf
->offset
+ info
.val
< 4096) {
799 instr
->operands
[2] = Operand((uint32_t) 0);
800 mubuf
->offset
+= info
.val
;
802 } else if (mubuf
->offen
&& i
== 1 && parse_base_offset(ctx
, instr
.get(), i
, &base
, &offset
) && base
.regClass() == v1
&& mubuf
->offset
+ offset
< 4096) {
803 assert(!mubuf
->idxen
);
804 instr
->operands
[1].setTemp(base
);
805 mubuf
->offset
+= offset
;
807 } else if (i
== 2 && parse_base_offset(ctx
, instr
.get(), i
, &base
, &offset
) && base
.regClass() == s1
&& mubuf
->offset
+ offset
< 4096) {
808 instr
->operands
[i
].setTemp(base
);
809 mubuf
->offset
+= offset
;
814 /* DS: combine additions */
815 else if (instr
->format
== Format::DS
) {
817 DS_instruction
*ds
= static_cast<DS_instruction
*>(instr
.get());
820 bool has_usable_ds_offset
= ctx
.program
->chip_class
>= GFX7
;
821 if (has_usable_ds_offset
&&
822 i
== 0 && parse_base_offset(ctx
, instr
.get(), i
, &base
, &offset
) &&
823 base
.regClass() == instr
->operands
[i
].regClass() &&
824 instr
->opcode
!= aco_opcode::ds_swizzle_b32
) {
825 if (instr
->opcode
== aco_opcode::ds_write2_b32
|| instr
->opcode
== aco_opcode::ds_read2_b32
||
826 instr
->opcode
== aco_opcode::ds_write2_b64
|| instr
->opcode
== aco_opcode::ds_read2_b64
) {
827 unsigned mask
= (instr
->opcode
== aco_opcode::ds_write2_b64
|| instr
->opcode
== aco_opcode::ds_read2_b64
) ? 0x7 : 0x3;
828 unsigned shifts
= (instr
->opcode
== aco_opcode::ds_write2_b64
|| instr
->opcode
== aco_opcode::ds_read2_b64
) ? 3 : 2;
830 if ((offset
& mask
) == 0 &&
831 ds
->offset0
+ (offset
>> shifts
) <= 255 &&
832 ds
->offset1
+ (offset
>> shifts
) <= 255) {
833 instr
->operands
[i
].setTemp(base
);
834 ds
->offset0
+= offset
>> shifts
;
835 ds
->offset1
+= offset
>> shifts
;
838 if (ds
->offset0
+ offset
<= 65535) {
839 instr
->operands
[i
].setTemp(base
);
840 ds
->offset0
+= offset
;
846 /* SMEM: propagate constants and combine additions */
847 else if (instr
->format
== Format::SMEM
) {
849 SMEM_instruction
*smem
= static_cast<SMEM_instruction
*>(instr
.get());
852 if (i
== 1 && info
.is_constant_or_literal() &&
853 ((ctx
.program
->chip_class
== GFX6
&& info
.val
<= 0x3FF) ||
854 (ctx
.program
->chip_class
== GFX7
&& info
.val
<= 0xFFFFFFFF) ||
855 (ctx
.program
->chip_class
>= GFX8
&& info
.val
<= 0xFFFFF))) {
856 instr
->operands
[i
] = Operand(info
.val
);
858 } else if (i
== 1 && parse_base_offset(ctx
, instr
.get(), i
, &base
, &offset
) && base
.regClass() == s1
&& offset
<= 0xFFFFF && ctx
.program
->chip_class
>= GFX9
) {
859 bool soe
= smem
->operands
.size() >= (!smem
->definitions
.empty() ? 3 : 4);
861 (!ctx
.info
[smem
->operands
.back().tempId()].is_constant_or_literal() ||
862 ctx
.info
[smem
->operands
.back().tempId()].val
!= 0)) {
866 smem
->operands
[1] = Operand(offset
);
867 smem
->operands
.back() = Operand(base
);
869 SMEM_instruction
*new_instr
= create_instruction
<SMEM_instruction
>(smem
->opcode
, Format::SMEM
, smem
->operands
.size() + 1, smem
->definitions
.size());
870 new_instr
->operands
[0] = smem
->operands
[0];
871 new_instr
->operands
[1] = Operand(offset
);
872 if (smem
->definitions
.empty())
873 new_instr
->operands
[2] = smem
->operands
[2];
874 new_instr
->operands
.back() = Operand(base
);
875 if (!smem
->definitions
.empty())
876 new_instr
->definitions
[0] = smem
->definitions
[0];
877 new_instr
->can_reorder
= smem
->can_reorder
;
878 new_instr
->barrier
= smem
->barrier
;
879 instr
.reset(new_instr
);
880 smem
= static_cast<SMEM_instruction
*>(instr
.get());
886 else if (instr
->format
== Format::PSEUDO_BRANCH
) {
887 if (ctx
.info
[instr
->operands
[0].tempId()].is_scc_invert()) {
888 /* Flip the branch instruction to get rid of the scc_invert instruction */
889 instr
->opcode
= instr
->opcode
== aco_opcode::p_cbranch_z
? aco_opcode::p_cbranch_nz
: aco_opcode::p_cbranch_z
;
890 instr
->operands
[0].setTemp(ctx
.info
[instr
->operands
[0].tempId()].temp
);
895 /* if this instruction doesn't define anything, return */
896 if (instr
->definitions
.empty())
899 switch (instr
->opcode
) {
900 case aco_opcode::p_create_vector
: {
901 unsigned num_ops
= instr
->operands
.size();
902 for (const Operand
& op
: instr
->operands
) {
903 if (op
.isTemp() && ctx
.info
[op
.tempId()].is_vec())
904 num_ops
+= ctx
.info
[op
.tempId()].instr
->operands
.size() - 1;
906 if (num_ops
!= instr
->operands
.size()) {
907 aco_ptr
<Instruction
> old_vec
= std::move(instr
);
908 instr
.reset(create_instruction
<Pseudo_instruction
>(aco_opcode::p_create_vector
, Format::PSEUDO
, num_ops
, 1));
909 instr
->definitions
[0] = old_vec
->definitions
[0];
911 for (Operand
& old_op
: old_vec
->operands
) {
912 if (old_op
.isTemp() && ctx
.info
[old_op
.tempId()].is_vec()) {
913 for (unsigned j
= 0; j
< ctx
.info
[old_op
.tempId()].instr
->operands
.size(); j
++) {
914 Operand op
= ctx
.info
[old_op
.tempId()].instr
->operands
[j
];
915 if (op
.isTemp() && ctx
.info
[op
.tempId()].is_temp() &&
916 ctx
.info
[op
.tempId()].temp
.type() == instr
->definitions
[0].regClass().type())
917 op
.setTemp(ctx
.info
[op
.tempId()].temp
);
918 instr
->operands
[k
++] = op
;
921 instr
->operands
[k
++] = old_op
;
924 assert(k
== num_ops
);
926 if (instr
->operands
.size() == 1 && instr
->operands
[0].isTemp())
927 ctx
.info
[instr
->definitions
[0].tempId()].set_temp(instr
->operands
[0].getTemp());
929 ctx
.info
[instr
->definitions
[0].tempId()].set_vec(instr
.get());
932 case aco_opcode::p_split_vector
: {
933 if (!ctx
.info
[instr
->operands
[0].tempId()].is_vec())
935 Instruction
* vec
= ctx
.info
[instr
->operands
[0].tempId()].instr
;
936 unsigned split_offset
= 0;
937 unsigned vec_offset
= 0;
938 unsigned vec_index
= 0;
939 for (unsigned i
= 0; i
< instr
->definitions
.size(); split_offset
+= instr
->definitions
[i
++].bytes()) {
940 while (vec_offset
< split_offset
&& vec_index
< vec
->operands
.size())
941 vec_offset
+= vec
->operands
[vec_index
++].bytes();
943 if (vec_offset
!= split_offset
|| vec
->operands
[vec_index
].bytes() != instr
->definitions
[i
].bytes())
946 Operand vec_op
= vec
->operands
[vec_index
];
947 if (vec_op
.isConstant()) {
948 if (vec_op
.isLiteral())
949 ctx
.info
[instr
->definitions
[i
].tempId()].set_literal(vec_op
.constantValue());
950 else if (vec_op
.size() == 1)
951 ctx
.info
[instr
->definitions
[i
].tempId()].set_constant(vec_op
.constantValue());
952 else if (vec_op
.size() == 2)
953 ctx
.info
[instr
->definitions
[i
].tempId()].set_constant_64bit(vec_op
.constantValue());
955 assert(vec_op
.isTemp());
956 ctx
.info
[instr
->definitions
[i
].tempId()].set_temp(vec_op
.getTemp());
961 case aco_opcode::p_extract_vector
: { /* mov */
962 if (!ctx
.info
[instr
->operands
[0].tempId()].is_vec())
965 /* check if we index directly into a vector element */
966 Instruction
* vec
= ctx
.info
[instr
->operands
[0].tempId()].instr
;
967 const unsigned index
= instr
->operands
[1].constantValue();
968 const unsigned dst_offset
= index
* instr
->definitions
[0].bytes();
971 for (const Operand
& op
: vec
->operands
) {
972 if (offset
< dst_offset
) {
973 offset
+= op
.bytes();
975 } else if (offset
!= dst_offset
|| op
.bytes() != instr
->definitions
[0].bytes()) {
979 /* convert this extract into a copy instruction */
980 instr
->opcode
= aco_opcode::p_parallelcopy
;
981 instr
->operands
.pop_back();
982 instr
->operands
[0] = op
;
984 if (op
.isConstant()) {
986 ctx
.info
[instr
->definitions
[0].tempId()].set_literal(op
.constantValue());
987 else if (op
.size() == 1)
988 ctx
.info
[instr
->definitions
[0].tempId()].set_constant(op
.constantValue());
989 else if (op
.size() == 2)
990 ctx
.info
[instr
->definitions
[0].tempId()].set_constant_64bit(op
.constantValue());
993 ctx
.info
[instr
->definitions
[0].tempId()].set_temp(op
.getTemp());
999 case aco_opcode::s_mov_b32
: /* propagate */
1000 case aco_opcode::s_mov_b64
:
1001 case aco_opcode::v_mov_b32
:
1002 case aco_opcode::p_as_uniform
:
1003 if (instr
->definitions
[0].isFixed()) {
1004 /* don't copy-propagate copies into fixed registers */
1005 } else if (instr
->usesModifiers()) {
1007 } else if (instr
->operands
[0].isConstant()) {
1008 if (instr
->operands
[0].isLiteral())
1009 ctx
.info
[instr
->definitions
[0].tempId()].set_literal(instr
->operands
[0].constantValue());
1010 else if (instr
->operands
[0].size() == 1)
1011 ctx
.info
[instr
->definitions
[0].tempId()].set_constant(instr
->operands
[0].constantValue());
1012 else if (instr
->operands
[0].size() == 2)
1013 ctx
.info
[instr
->definitions
[0].tempId()].set_constant_64bit(instr
->operands
[0].constantValue());
1014 } else if (instr
->operands
[0].isTemp()) {
1015 ctx
.info
[instr
->definitions
[0].tempId()].set_temp(instr
->operands
[0].getTemp());
1017 assert(instr
->operands
[0].isFixed());
1020 case aco_opcode::p_is_helper
:
1021 if (!ctx
.program
->needs_wqm
)
1022 ctx
.info
[instr
->definitions
[0].tempId()].set_constant(0u);
1024 case aco_opcode::s_movk_i32
: {
1025 uint32_t v
= static_cast<SOPK_instruction
*>(instr
.get())->imm
;
1026 v
= v
& 0x8000 ? (v
| 0xffff0000) : v
;
1027 if (v
<= 64 || v
>= 0xfffffff0)
1028 ctx
.info
[instr
->definitions
[0].tempId()].set_constant(v
);
1030 ctx
.info
[instr
->definitions
[0].tempId()].set_literal(v
);
1033 case aco_opcode::v_bfrev_b32
:
1034 case aco_opcode::s_brev_b32
: {
1035 if (instr
->operands
[0].isConstant()) {
1036 uint32_t v
= util_bitreverse(instr
->operands
[0].constantValue());
1037 if (v
<= 64 || v
>= 0xfffffff0)
1038 ctx
.info
[instr
->definitions
[0].tempId()].set_constant(v
);
1040 ctx
.info
[instr
->definitions
[0].tempId()].set_literal(v
);
1044 case aco_opcode::s_bfm_b32
: {
1045 if (instr
->operands
[0].isConstant() && instr
->operands
[1].isConstant()) {
1046 unsigned size
= instr
->operands
[0].constantValue() & 0x1f;
1047 unsigned start
= instr
->operands
[1].constantValue() & 0x1f;
1048 uint32_t v
= ((1u << size
) - 1u) << start
;
1049 if (v
<= 64 || v
>= 0xfffffff0)
1050 ctx
.info
[instr
->definitions
[0].tempId()].set_constant(v
);
1052 ctx
.info
[instr
->definitions
[0].tempId()].set_literal(v
);
1055 case aco_opcode::v_mul_f32
: { /* omod */
1056 /* TODO: try to move the negate/abs modifier to the consumer instead */
1057 if (instr
->usesModifiers())
1060 for (unsigned i
= 0; i
< 2; i
++) {
1061 if (instr
->operands
[!i
].isConstant() && instr
->operands
[i
].isTemp()) {
1062 if (instr
->operands
[!i
].constantValue() == 0x40000000) { /* 2.0 */
1063 ctx
.info
[instr
->operands
[i
].tempId()].set_omod2(instr
->definitions
[0].getTemp());
1064 } else if (instr
->operands
[!i
].constantValue() == 0x40800000) { /* 4.0 */
1065 ctx
.info
[instr
->operands
[i
].tempId()].set_omod4(instr
->definitions
[0].getTemp());
1066 } else if (instr
->operands
[!i
].constantValue() == 0x3f000000) { /* 0.5 */
1067 ctx
.info
[instr
->operands
[i
].tempId()].set_omod5(instr
->definitions
[0].getTemp());
1068 } else if (instr
->operands
[!i
].constantValue() == 0x3f800000 &&
1069 !block
.fp_mode
.must_flush_denorms32
) { /* 1.0 */
1070 ctx
.info
[instr
->definitions
[0].tempId()].set_temp(instr
->operands
[i
].getTemp());
1079 case aco_opcode::v_and_b32
: /* abs */
1080 if (!instr
->usesModifiers() && instr
->operands
[0].constantEquals(0x7FFFFFFF) &&
1081 instr
->operands
[1].isTemp() && instr
->operands
[1].getTemp().type() == RegType::vgpr
)
1082 ctx
.info
[instr
->definitions
[0].tempId()].set_abs(instr
->operands
[1].getTemp());
1084 ctx
.info
[instr
->definitions
[0].tempId()].set_bitwise(instr
.get());
1086 case aco_opcode::v_xor_b32
: { /* neg */
1087 if (!instr
->usesModifiers() && instr
->operands
[0].constantEquals(0x80000000u
) && instr
->operands
[1].isTemp()) {
1088 if (ctx
.info
[instr
->operands
[1].tempId()].is_neg()) {
1089 ctx
.info
[instr
->definitions
[0].tempId()].set_temp(ctx
.info
[instr
->operands
[1].tempId()].temp
);
1090 } else if (instr
->operands
[1].getTemp().type() == RegType::vgpr
) {
1091 if (ctx
.info
[instr
->operands
[1].tempId()].is_abs()) { /* neg(abs(x)) */
1092 instr
->operands
[1].setTemp(ctx
.info
[instr
->operands
[1].tempId()].temp
);
1093 instr
->opcode
= aco_opcode::v_or_b32
;
1094 ctx
.info
[instr
->definitions
[0].tempId()].set_neg_abs(instr
->operands
[1].getTemp());
1096 ctx
.info
[instr
->definitions
[0].tempId()].set_neg(instr
->operands
[1].getTemp());
1100 ctx
.info
[instr
->definitions
[0].tempId()].set_bitwise(instr
.get());
1104 case aco_opcode::v_med3_f32
: { /* clamp */
1105 VOP3A_instruction
* vop3
= static_cast<VOP3A_instruction
*>(instr
.get());
1106 if (vop3
->abs
[0] || vop3
->abs
[1] || vop3
->abs
[2] ||
1107 vop3
->neg
[0] || vop3
->neg
[1] || vop3
->neg
[2] ||
1108 vop3
->omod
!= 0 || vop3
->opsel
!= 0)
1112 bool found_zero
= false, found_one
= false;
1113 for (unsigned i
= 0; i
< 3; i
++)
1115 if (instr
->operands
[i
].constantEquals(0))
1117 else if (instr
->operands
[i
].constantEquals(0x3f800000)) /* 1.0 */
1122 if (found_zero
&& found_one
&& instr
->operands
[idx
].isTemp()) {
1123 ctx
.info
[instr
->operands
[idx
].tempId()].set_clamp(instr
->definitions
[0].getTemp());
1127 case aco_opcode::v_cndmask_b32
:
1128 if (instr
->operands
[0].constantEquals(0) &&
1129 instr
->operands
[1].constantEquals(0xFFFFFFFF) &&
1130 instr
->operands
[2].isTemp())
1131 ctx
.info
[instr
->definitions
[0].tempId()].set_vcc(instr
->operands
[2].getTemp());
1132 else if (instr
->operands
[0].constantEquals(0) &&
1133 instr
->operands
[1].constantEquals(0x3f800000u
) &&
1134 instr
->operands
[2].isTemp())
1135 ctx
.info
[instr
->definitions
[0].tempId()].set_b2f(instr
->operands
[2].getTemp());
1137 ctx
.info
[instr
->operands
[2].tempId()].set_vcc_hint();
1139 case aco_opcode::v_cmp_lg_u32
:
1140 if (instr
->format
== Format::VOPC
&& /* don't optimize VOP3 / SDWA / DPP */
1141 instr
->operands
[0].constantEquals(0) &&
1142 instr
->operands
[1].isTemp() && ctx
.info
[instr
->operands
[1].tempId()].is_vcc())
1143 ctx
.info
[instr
->definitions
[0].tempId()].set_temp(ctx
.info
[instr
->operands
[1].tempId()].temp
);
1145 case aco_opcode::p_phi
:
1146 case aco_opcode::p_linear_phi
: {
1147 /* lower_bool_phis() can create phis like this */
1148 bool all_same_temp
= instr
->operands
[0].isTemp();
1149 /* this check is needed when moving uniform loop counters out of a divergent loop */
1151 all_same_temp
= instr
->definitions
[0].regClass() == instr
->operands
[0].regClass();
1152 for (unsigned i
= 1; all_same_temp
&& (i
< instr
->operands
.size()); i
++) {
1153 if (!instr
->operands
[i
].isTemp() || instr
->operands
[i
].tempId() != instr
->operands
[0].tempId())
1154 all_same_temp
= false;
1156 if (all_same_temp
) {
1157 ctx
.info
[instr
->definitions
[0].tempId()].set_temp(instr
->operands
[0].getTemp());
1159 bool all_undef
= instr
->operands
[0].isUndefined();
1160 for (unsigned i
= 1; all_undef
&& (i
< instr
->operands
.size()); i
++) {
1161 if (!instr
->operands
[i
].isUndefined())
1165 ctx
.info
[instr
->definitions
[0].tempId()].set_undefined();
1169 case aco_opcode::v_add_u32
:
1170 case aco_opcode::v_add_co_u32
:
1171 case aco_opcode::v_add_co_u32_e64
:
1172 case aco_opcode::s_add_i32
:
1173 case aco_opcode::s_add_u32
:
1174 ctx
.info
[instr
->definitions
[0].tempId()].set_add_sub(instr
.get());
1176 case aco_opcode::s_not_b32
:
1177 case aco_opcode::s_not_b64
:
1178 if (ctx
.info
[instr
->operands
[0].tempId()].is_uniform_bool()) {
1179 ctx
.info
[instr
->definitions
[0].tempId()].set_uniform_bitwise();
1180 ctx
.info
[instr
->definitions
[1].tempId()].set_scc_invert(ctx
.info
[instr
->operands
[0].tempId()].temp
);
1181 } else if (ctx
.info
[instr
->operands
[0].tempId()].is_uniform_bitwise()) {
1182 ctx
.info
[instr
->definitions
[0].tempId()].set_uniform_bitwise();
1183 ctx
.info
[instr
->definitions
[1].tempId()].set_scc_invert(ctx
.info
[instr
->operands
[0].tempId()].instr
->definitions
[1].getTemp());
1185 ctx
.info
[instr
->definitions
[0].tempId()].set_bitwise(instr
.get());
1187 case aco_opcode::s_and_b32
:
1188 case aco_opcode::s_and_b64
:
1189 if (fixed_to_exec(instr
->operands
[1]) && instr
->operands
[0].isTemp()) {
1190 if (ctx
.info
[instr
->operands
[0].tempId()].is_uniform_bool()) {
1191 /* Try to get rid of the superfluous s_cselect + s_and_b64 that comes from turning a uniform bool into divergent */
1192 ctx
.info
[instr
->definitions
[1].tempId()].set_temp(ctx
.info
[instr
->operands
[0].tempId()].temp
);
1193 ctx
.info
[instr
->definitions
[0].tempId()].set_uniform_bool(ctx
.info
[instr
->operands
[0].tempId()].temp
);
1195 } else if (ctx
.info
[instr
->operands
[0].tempId()].is_uniform_bitwise()) {
1196 /* Try to get rid of the superfluous s_and_b64, since the uniform bitwise instruction already produces the same SCC */
1197 ctx
.info
[instr
->definitions
[1].tempId()].set_temp(ctx
.info
[instr
->operands
[0].tempId()].instr
->definitions
[1].getTemp());
1198 ctx
.info
[instr
->definitions
[0].tempId()].set_uniform_bool(ctx
.info
[instr
->operands
[0].tempId()].instr
->definitions
[1].getTemp());
1203 case aco_opcode::s_or_b32
:
1204 case aco_opcode::s_or_b64
:
1205 case aco_opcode::s_xor_b32
:
1206 case aco_opcode::s_xor_b64
:
1207 if (std::all_of(instr
->operands
.begin(), instr
->operands
.end(), [&ctx
](const Operand
& op
) {
1208 return op
.isTemp() && (ctx
.info
[op
.tempId()].is_uniform_bool() || ctx
.info
[op
.tempId()].is_uniform_bitwise());
1210 ctx
.info
[instr
->definitions
[0].tempId()].set_uniform_bitwise();
1213 case aco_opcode::s_lshl_b32
:
1214 case aco_opcode::v_or_b32
:
1215 case aco_opcode::v_lshlrev_b32
:
1216 ctx
.info
[instr
->definitions
[0].tempId()].set_bitwise(instr
.get());
1218 case aco_opcode::v_min_f32
:
1219 case aco_opcode::v_min_f16
:
1220 case aco_opcode::v_min_u32
:
1221 case aco_opcode::v_min_i32
:
1222 case aco_opcode::v_min_u16
:
1223 case aco_opcode::v_min_i16
:
1224 case aco_opcode::v_max_f32
:
1225 case aco_opcode::v_max_f16
:
1226 case aco_opcode::v_max_u32
:
1227 case aco_opcode::v_max_i32
:
1228 case aco_opcode::v_max_u16
:
1229 case aco_opcode::v_max_i16
:
1230 ctx
.info
[instr
->definitions
[0].tempId()].set_minmax(instr
.get());
1232 case aco_opcode::v_cmp_lt_f32
:
1233 case aco_opcode::v_cmp_eq_f32
:
1234 case aco_opcode::v_cmp_le_f32
:
1235 case aco_opcode::v_cmp_gt_f32
:
1236 case aco_opcode::v_cmp_lg_f32
:
1237 case aco_opcode::v_cmp_ge_f32
:
1238 case aco_opcode::v_cmp_o_f32
:
1239 case aco_opcode::v_cmp_u_f32
:
1240 case aco_opcode::v_cmp_nge_f32
:
1241 case aco_opcode::v_cmp_nlg_f32
:
1242 case aco_opcode::v_cmp_ngt_f32
:
1243 case aco_opcode::v_cmp_nle_f32
:
1244 case aco_opcode::v_cmp_neq_f32
:
1245 case aco_opcode::v_cmp_nlt_f32
:
1246 ctx
.info
[instr
->definitions
[0].tempId()].set_fcmp(instr
.get());
1248 case aco_opcode::s_cselect_b64
:
1249 case aco_opcode::s_cselect_b32
:
1250 if (instr
->operands
[0].constantEquals((unsigned) -1) &&
1251 instr
->operands
[1].constantEquals(0)) {
1252 /* Found a cselect that operates on a uniform bool that comes from eg. s_cmp */
1253 ctx
.info
[instr
->definitions
[0].tempId()].set_uniform_bool(instr
->operands
[2].getTemp());
1255 if (instr
->operands
[2].isTemp() && ctx
.info
[instr
->operands
[2].tempId()].is_scc_invert()) {
1256 /* Flip the operands to get rid of the scc_invert instruction */
1257 std::swap(instr
->operands
[0], instr
->operands
[1]);
1258 instr
->operands
[2].setTemp(ctx
.info
[instr
->operands
[2].tempId()].temp
);
1261 case aco_opcode::p_wqm
:
1262 if (instr
->operands
[0].isTemp() &&
1263 ctx
.info
[instr
->operands
[0].tempId()].is_scc_invert()) {
1264 ctx
.info
[instr
->definitions
[0].tempId()].set_temp(instr
->operands
[0].getTemp());
1272 ALWAYS_INLINE
bool get_cmp_info(aco_opcode op
, aco_opcode
*ordered
, aco_opcode
*unordered
, aco_opcode
*inverse
)
1274 *ordered
= *unordered
= op
;
1276 #define CMP(ord, unord) \
1277 case aco_opcode::v_cmp_##ord##_f32:\
1278 case aco_opcode::v_cmp_n##unord##_f32:\
1279 *ordered = aco_opcode::v_cmp_##ord##_f32;\
1280 *unordered = aco_opcode::v_cmp_n##unord##_f32;\
1281 *inverse = op == aco_opcode::v_cmp_n##unord##_f32 ? aco_opcode::v_cmp_##unord##_f32 : aco_opcode::v_cmp_n##ord##_f32;\
1295 aco_opcode
get_ordered(aco_opcode op
)
1297 aco_opcode ordered
, unordered
, inverse
;
1298 return get_cmp_info(op
, &ordered
, &unordered
, &inverse
) ? ordered
: aco_opcode::last_opcode
;
1301 aco_opcode
get_unordered(aco_opcode op
)
1303 aco_opcode ordered
, unordered
, inverse
;
1304 return get_cmp_info(op
, &ordered
, &unordered
, &inverse
) ? unordered
: aco_opcode::last_opcode
;
1307 aco_opcode
get_inverse(aco_opcode op
)
1309 aco_opcode ordered
, unordered
, inverse
;
1310 return get_cmp_info(op
, &ordered
, &unordered
, &inverse
) ? inverse
: aco_opcode::last_opcode
;
1313 bool is_cmp(aco_opcode op
)
1315 aco_opcode ordered
, unordered
, inverse
;
1316 return get_cmp_info(op
, &ordered
, &unordered
, &inverse
);
1319 unsigned original_temp_id(opt_ctx
&ctx
, Temp tmp
)
1321 if (ctx
.info
[tmp
.id()].is_temp())
1322 return ctx
.info
[tmp
.id()].temp
.id();
1327 void decrease_uses(opt_ctx
&ctx
, Instruction
* instr
)
1329 if (!--ctx
.uses
[instr
->definitions
[0].tempId()]) {
1330 for (const Operand
& op
: instr
->operands
) {
1332 ctx
.uses
[op
.tempId()]--;
1337 Instruction
*follow_operand(opt_ctx
&ctx
, Operand op
, bool ignore_uses
=false)
1339 if (!op
.isTemp() || !(ctx
.info
[op
.tempId()].label
& instr_labels
))
1341 if (!ignore_uses
&& ctx
.uses
[op
.tempId()] > 1)
1344 Instruction
*instr
= ctx
.info
[op
.tempId()].instr
;
1346 if (instr
->definitions
.size() == 2) {
1347 assert(instr
->definitions
[0].isTemp() && instr
->definitions
[0].tempId() == op
.tempId());
1348 if (instr
->definitions
[1].isTemp() && ctx
.uses
[instr
->definitions
[1].tempId()])
1355 /* s_or_b64(neq(a, a), neq(b, b)) -> v_cmp_u_f32(a, b)
1356 * s_and_b64(eq(a, a), eq(b, b)) -> v_cmp_o_f32(a, b) */
1357 bool combine_ordering_test(opt_ctx
&ctx
, aco_ptr
<Instruction
>& instr
)
1359 if (instr
->definitions
[0].regClass() != ctx
.program
->lane_mask
)
1361 if (instr
->definitions
[1].isTemp() && ctx
.uses
[instr
->definitions
[1].tempId()])
1364 bool is_or
= instr
->opcode
== aco_opcode::s_or_b64
|| instr
->opcode
== aco_opcode::s_or_b32
;
1366 bool neg
[2] = {false, false};
1367 bool abs
[2] = {false, false};
1369 Instruction
*op_instr
[2];
1372 for (unsigned i
= 0; i
< 2; i
++) {
1373 op_instr
[i
] = follow_operand(ctx
, instr
->operands
[i
], true);
1377 aco_opcode expected_cmp
= is_or
? aco_opcode::v_cmp_neq_f32
: aco_opcode::v_cmp_eq_f32
;
1379 if (op_instr
[i
]->opcode
!= expected_cmp
)
1381 if (!op_instr
[i
]->operands
[0].isTemp() || !op_instr
[i
]->operands
[1].isTemp())
1384 if (op_instr
[i
]->isVOP3()) {
1385 VOP3A_instruction
*vop3
= static_cast<VOP3A_instruction
*>(op_instr
[i
]);
1386 if (vop3
->neg
[0] != vop3
->neg
[1] || vop3
->abs
[0] != vop3
->abs
[1] || vop3
->opsel
== 1 || vop3
->opsel
== 2)
1388 neg
[i
] = vop3
->neg
[0];
1389 abs
[i
] = vop3
->abs
[0];
1390 opsel
|= (vop3
->opsel
& 1) << i
;
1393 Temp op0
= op_instr
[i
]->operands
[0].getTemp();
1394 Temp op1
= op_instr
[i
]->operands
[1].getTemp();
1395 if (original_temp_id(ctx
, op0
) != original_temp_id(ctx
, op1
))
1401 if (op
[1].type() == RegType::sgpr
)
1402 std::swap(op
[0], op
[1]);
1403 unsigned num_sgprs
= (op
[0].type() == RegType::sgpr
) + (op
[1].type() == RegType::sgpr
);
1404 if (num_sgprs
> (ctx
.program
->chip_class
>= GFX10
? 2 : 1))
1407 ctx
.uses
[op
[0].id()]++;
1408 ctx
.uses
[op
[1].id()]++;
1409 decrease_uses(ctx
, op_instr
[0]);
1410 decrease_uses(ctx
, op_instr
[1]);
1412 aco_opcode new_op
= is_or
? aco_opcode::v_cmp_u_f32
: aco_opcode::v_cmp_o_f32
;
1413 Instruction
*new_instr
;
1414 if (neg
[0] || neg
[1] || abs
[0] || abs
[1] || opsel
|| num_sgprs
> 1) {
1415 VOP3A_instruction
*vop3
= create_instruction
<VOP3A_instruction
>(new_op
, asVOP3(Format::VOPC
), 2, 1);
1416 for (unsigned i
= 0; i
< 2; i
++) {
1417 vop3
->neg
[i
] = neg
[i
];
1418 vop3
->abs
[i
] = abs
[i
];
1420 vop3
->opsel
= opsel
;
1421 new_instr
= static_cast<Instruction
*>(vop3
);
1423 new_instr
= create_instruction
<VOPC_instruction
>(new_op
, Format::VOPC
, 2, 1);
1425 new_instr
->operands
[0] = Operand(op
[0]);
1426 new_instr
->operands
[1] = Operand(op
[1]);
1427 new_instr
->definitions
[0] = instr
->definitions
[0];
1429 ctx
.info
[instr
->definitions
[0].tempId()].label
= 0;
1430 ctx
.info
[instr
->definitions
[0].tempId()].set_fcmp(new_instr
);
1432 instr
.reset(new_instr
);
1437 /* s_or_b64(v_cmp_u_f32(a, b), cmp(a, b)) -> get_unordered(cmp)(a, b)
1438 * s_and_b64(v_cmp_o_f32(a, b), cmp(a, b)) -> get_ordered(cmp)(a, b) */
1439 bool combine_comparison_ordering(opt_ctx
&ctx
, aco_ptr
<Instruction
>& instr
)
1441 if (instr
->definitions
[0].regClass() != ctx
.program
->lane_mask
)
1443 if (instr
->definitions
[1].isTemp() && ctx
.uses
[instr
->definitions
[1].tempId()])
1446 bool is_or
= instr
->opcode
== aco_opcode::s_or_b64
|| instr
->opcode
== aco_opcode::s_or_b32
;
1447 aco_opcode expected_nan_test
= is_or
? aco_opcode::v_cmp_u_f32
: aco_opcode::v_cmp_o_f32
;
1449 Instruction
*nan_test
= follow_operand(ctx
, instr
->operands
[0], true);
1450 Instruction
*cmp
= follow_operand(ctx
, instr
->operands
[1], true);
1451 if (!nan_test
|| !cmp
)
1454 if (cmp
->opcode
== expected_nan_test
)
1455 std::swap(nan_test
, cmp
);
1456 else if (nan_test
->opcode
!= expected_nan_test
)
1459 if (!is_cmp(cmp
->opcode
))
1462 if (!nan_test
->operands
[0].isTemp() || !nan_test
->operands
[1].isTemp())
1464 if (!cmp
->operands
[0].isTemp() || !cmp
->operands
[1].isTemp())
1467 unsigned prop_cmp0
= original_temp_id(ctx
, cmp
->operands
[0].getTemp());
1468 unsigned prop_cmp1
= original_temp_id(ctx
, cmp
->operands
[1].getTemp());
1469 unsigned prop_nan0
= original_temp_id(ctx
, nan_test
->operands
[0].getTemp());
1470 unsigned prop_nan1
= original_temp_id(ctx
, nan_test
->operands
[1].getTemp());
1471 if (prop_cmp0
!= prop_nan0
&& prop_cmp0
!= prop_nan1
)
1473 if (prop_cmp1
!= prop_nan0
&& prop_cmp1
!= prop_nan1
)
1476 ctx
.uses
[cmp
->operands
[0].tempId()]++;
1477 ctx
.uses
[cmp
->operands
[1].tempId()]++;
1478 decrease_uses(ctx
, nan_test
);
1479 decrease_uses(ctx
, cmp
);
1481 aco_opcode new_op
= is_or
? get_unordered(cmp
->opcode
) : get_ordered(cmp
->opcode
);
1482 Instruction
*new_instr
;
1483 if (cmp
->isVOP3()) {
1484 VOP3A_instruction
*new_vop3
= create_instruction
<VOP3A_instruction
>(new_op
, asVOP3(Format::VOPC
), 2, 1);
1485 VOP3A_instruction
*cmp_vop3
= static_cast<VOP3A_instruction
*>(cmp
);
1486 memcpy(new_vop3
->abs
, cmp_vop3
->abs
, sizeof(new_vop3
->abs
));
1487 memcpy(new_vop3
->neg
, cmp_vop3
->neg
, sizeof(new_vop3
->neg
));
1488 new_vop3
->clamp
= cmp_vop3
->clamp
;
1489 new_vop3
->omod
= cmp_vop3
->omod
;
1490 new_vop3
->opsel
= cmp_vop3
->opsel
;
1491 new_instr
= new_vop3
;
1493 new_instr
= create_instruction
<VOPC_instruction
>(new_op
, Format::VOPC
, 2, 1);
1495 new_instr
->operands
[0] = cmp
->operands
[0];
1496 new_instr
->operands
[1] = cmp
->operands
[1];
1497 new_instr
->definitions
[0] = instr
->definitions
[0];
1499 ctx
.info
[instr
->definitions
[0].tempId()].label
= 0;
1500 ctx
.info
[instr
->definitions
[0].tempId()].set_fcmp(new_instr
);
1502 instr
.reset(new_instr
);
1507 /* s_or_b64(v_cmp_neq_f32(a, a), cmp(a, #b)) and b is not NaN -> get_unordered(cmp)(a, b)
1508 * s_and_b64(v_cmp_eq_f32(a, a), cmp(a, #b)) and b is not NaN -> get_ordered(cmp)(a, b) */
1509 bool combine_constant_comparison_ordering(opt_ctx
&ctx
, aco_ptr
<Instruction
>& instr
)
1511 if (instr
->definitions
[0].regClass() != ctx
.program
->lane_mask
)
1513 if (instr
->definitions
[1].isTemp() && ctx
.uses
[instr
->definitions
[1].tempId()])
1516 bool is_or
= instr
->opcode
== aco_opcode::s_or_b64
|| instr
->opcode
== aco_opcode::s_or_b32
;
1518 Instruction
*nan_test
= follow_operand(ctx
, instr
->operands
[0], true);
1519 Instruction
*cmp
= follow_operand(ctx
, instr
->operands
[1], true);
1521 if (!nan_test
|| !cmp
)
1524 aco_opcode expected_nan_test
= is_or
? aco_opcode::v_cmp_neq_f32
: aco_opcode::v_cmp_eq_f32
;
1525 if (cmp
->opcode
== expected_nan_test
)
1526 std::swap(nan_test
, cmp
);
1527 else if (nan_test
->opcode
!= expected_nan_test
)
1530 if (!is_cmp(cmp
->opcode
))
1533 if (!nan_test
->operands
[0].isTemp() || !nan_test
->operands
[1].isTemp())
1535 if (!cmp
->operands
[0].isTemp() && !cmp
->operands
[1].isTemp())
1538 unsigned prop_nan0
= original_temp_id(ctx
, nan_test
->operands
[0].getTemp());
1539 unsigned prop_nan1
= original_temp_id(ctx
, nan_test
->operands
[1].getTemp());
1540 if (prop_nan0
!= prop_nan1
)
1543 if (nan_test
->isVOP3()) {
1544 VOP3A_instruction
*vop3
= static_cast<VOP3A_instruction
*>(nan_test
);
1545 if (vop3
->neg
[0] != vop3
->neg
[1] || vop3
->abs
[0] != vop3
->abs
[1] || vop3
->opsel
== 1 || vop3
->opsel
== 2)
1549 int constant_operand
= -1;
1550 for (unsigned i
= 0; i
< 2; i
++) {
1551 if (cmp
->operands
[i
].isTemp() && original_temp_id(ctx
, cmp
->operands
[i
].getTemp()) == prop_nan0
) {
1552 constant_operand
= !i
;
1556 if (constant_operand
== -1)
1560 if (cmp
->operands
[constant_operand
].isConstant()) {
1561 constant
= cmp
->operands
[constant_operand
].constantValue();
1562 } else if (cmp
->operands
[constant_operand
].isTemp()) {
1563 Temp tmp
= cmp
->operands
[constant_operand
].getTemp();
1564 unsigned id
= original_temp_id(ctx
, tmp
);
1565 if (!ctx
.info
[id
].is_constant() && !ctx
.info
[id
].is_literal())
1567 constant
= ctx
.info
[id
].val
;
1573 memcpy(&constantf
, &constant
, 4);
1574 if (isnan(constantf
))
1577 if (cmp
->operands
[0].isTemp())
1578 ctx
.uses
[cmp
->operands
[0].tempId()]++;
1579 if (cmp
->operands
[1].isTemp())
1580 ctx
.uses
[cmp
->operands
[1].tempId()]++;
1581 decrease_uses(ctx
, nan_test
);
1582 decrease_uses(ctx
, cmp
);
1584 aco_opcode new_op
= is_or
? get_unordered(cmp
->opcode
) : get_ordered(cmp
->opcode
);
1585 Instruction
*new_instr
;
1586 if (cmp
->isVOP3()) {
1587 VOP3A_instruction
*new_vop3
= create_instruction
<VOP3A_instruction
>(new_op
, asVOP3(Format::VOPC
), 2, 1);
1588 VOP3A_instruction
*cmp_vop3
= static_cast<VOP3A_instruction
*>(cmp
);
1589 memcpy(new_vop3
->abs
, cmp_vop3
->abs
, sizeof(new_vop3
->abs
));
1590 memcpy(new_vop3
->neg
, cmp_vop3
->neg
, sizeof(new_vop3
->neg
));
1591 new_vop3
->clamp
= cmp_vop3
->clamp
;
1592 new_vop3
->omod
= cmp_vop3
->omod
;
1593 new_vop3
->opsel
= cmp_vop3
->opsel
;
1594 new_instr
= new_vop3
;
1596 new_instr
= create_instruction
<VOPC_instruction
>(new_op
, Format::VOPC
, 2, 1);
1598 new_instr
->operands
[0] = cmp
->operands
[0];
1599 new_instr
->operands
[1] = cmp
->operands
[1];
1600 new_instr
->definitions
[0] = instr
->definitions
[0];
1602 ctx
.info
[instr
->definitions
[0].tempId()].label
= 0;
1603 ctx
.info
[instr
->definitions
[0].tempId()].set_fcmp(new_instr
);
1605 instr
.reset(new_instr
);
1610 /* s_not_b64(cmp(a, b) -> get_inverse(cmp)(a, b) */
1611 bool combine_inverse_comparison(opt_ctx
&ctx
, aco_ptr
<Instruction
>& instr
)
1613 if (instr
->opcode
!= aco_opcode::s_not_b64
)
1615 if (instr
->definitions
[1].isTemp() && ctx
.uses
[instr
->definitions
[1].tempId()])
1617 if (!instr
->operands
[0].isTemp())
1620 Instruction
*cmp
= follow_operand(ctx
, instr
->operands
[0]);
1624 aco_opcode new_opcode
= get_inverse(cmp
->opcode
);
1625 if (new_opcode
== aco_opcode::last_opcode
)
1628 if (cmp
->operands
[0].isTemp())
1629 ctx
.uses
[cmp
->operands
[0].tempId()]++;
1630 if (cmp
->operands
[1].isTemp())
1631 ctx
.uses
[cmp
->operands
[1].tempId()]++;
1632 decrease_uses(ctx
, cmp
);
1634 Instruction
*new_instr
;
1635 if (cmp
->isVOP3()) {
1636 VOP3A_instruction
*new_vop3
= create_instruction
<VOP3A_instruction
>(new_opcode
, asVOP3(Format::VOPC
), 2, 1);
1637 VOP3A_instruction
*cmp_vop3
= static_cast<VOP3A_instruction
*>(cmp
);
1638 memcpy(new_vop3
->abs
, cmp_vop3
->abs
, sizeof(new_vop3
->abs
));
1639 memcpy(new_vop3
->neg
, cmp_vop3
->neg
, sizeof(new_vop3
->neg
));
1640 new_vop3
->clamp
= cmp_vop3
->clamp
;
1641 new_vop3
->omod
= cmp_vop3
->omod
;
1642 new_vop3
->opsel
= cmp_vop3
->opsel
;
1643 new_instr
= new_vop3
;
1645 new_instr
= create_instruction
<VOPC_instruction
>(new_opcode
, Format::VOPC
, 2, 1);
1647 new_instr
->operands
[0] = cmp
->operands
[0];
1648 new_instr
->operands
[1] = cmp
->operands
[1];
1649 new_instr
->definitions
[0] = instr
->definitions
[0];
1651 ctx
.info
[instr
->definitions
[0].tempId()].label
= 0;
1652 ctx
.info
[instr
->definitions
[0].tempId()].set_fcmp(new_instr
);
1654 instr
.reset(new_instr
);
1659 /* op1(op2(1, 2), 0) if swap = false
1660 * op1(0, op2(1, 2)) if swap = true */
1661 bool match_op3_for_vop3(opt_ctx
&ctx
, aco_opcode op1
, aco_opcode op2
,
1662 Instruction
* op1_instr
, bool swap
, const char *shuffle_str
,
1663 Operand operands
[3], bool neg
[3], bool abs
[3], uint8_t *opsel
,
1664 bool *op1_clamp
, uint8_t *op1_omod
,
1665 bool *inbetween_neg
, bool *inbetween_abs
, bool *inbetween_opsel
)
1668 if (op1_instr
->opcode
!= op1
)
1671 Instruction
*op2_instr
= follow_operand(ctx
, op1_instr
->operands
[swap
]);
1672 if (!op2_instr
|| op2_instr
->opcode
!= op2
)
1674 if (fixed_to_exec(op2_instr
->operands
[0]) || fixed_to_exec(op2_instr
->operands
[1]))
1677 VOP3A_instruction
*op1_vop3
= op1_instr
->isVOP3() ? static_cast<VOP3A_instruction
*>(op1_instr
) : NULL
;
1678 VOP3A_instruction
*op2_vop3
= op2_instr
->isVOP3() ? static_cast<VOP3A_instruction
*>(op2_instr
) : NULL
;
1680 /* don't support inbetween clamp/omod */
1681 if (op2_vop3
&& (op2_vop3
->clamp
|| op2_vop3
->omod
))
1684 /* get operands and modifiers and check inbetween modifiers */
1685 *op1_clamp
= op1_vop3
? op1_vop3
->clamp
: false;
1686 *op1_omod
= op1_vop3
? op1_vop3
->omod
: 0u;
1689 *inbetween_neg
= op1_vop3
? op1_vop3
->neg
[swap
] : false;
1690 else if (op1_vop3
&& op1_vop3
->neg
[swap
])
1694 *inbetween_abs
= op1_vop3
? op1_vop3
->abs
[swap
] : false;
1695 else if (op1_vop3
&& op1_vop3
->abs
[swap
])
1698 if (inbetween_opsel
)
1699 *inbetween_opsel
= op1_vop3
? op1_vop3
->opsel
& (1 << swap
) : false;
1700 else if (op1_vop3
&& op1_vop3
->opsel
& (1 << swap
))
1704 shuffle
[shuffle_str
[0] - '0'] = 0;
1705 shuffle
[shuffle_str
[1] - '0'] = 1;
1706 shuffle
[shuffle_str
[2] - '0'] = 2;
1708 operands
[shuffle
[0]] = op1_instr
->operands
[!swap
];
1709 neg
[shuffle
[0]] = op1_vop3
? op1_vop3
->neg
[!swap
] : false;
1710 abs
[shuffle
[0]] = op1_vop3
? op1_vop3
->abs
[!swap
] : false;
1711 if (op1_vop3
&& op1_vop3
->opsel
& (1 << !swap
))
1712 *opsel
|= 1 << shuffle
[0];
1714 for (unsigned i
= 0; i
< 2; i
++) {
1715 operands
[shuffle
[i
+ 1]] = op2_instr
->operands
[i
];
1716 neg
[shuffle
[i
+ 1]] = op2_vop3
? op2_vop3
->neg
[i
] : false;
1717 abs
[shuffle
[i
+ 1]] = op2_vop3
? op2_vop3
->abs
[i
] : false;
1718 if (op2_vop3
&& op2_vop3
->opsel
& (1 << i
))
1719 *opsel
|= 1 << shuffle
[i
+ 1];
1722 /* check operands */
1723 if (!check_vop3_operands(ctx
, 3, operands
))
1729 void create_vop3_for_op3(opt_ctx
& ctx
, aco_opcode opcode
, aco_ptr
<Instruction
>& instr
,
1730 Operand operands
[3], bool neg
[3], bool abs
[3], uint8_t opsel
,
1731 bool clamp
, unsigned omod
)
1733 VOP3A_instruction
*new_instr
= create_instruction
<VOP3A_instruction
>(opcode
, Format::VOP3A
, 3, 1);
1734 memcpy(new_instr
->abs
, abs
, sizeof(bool[3]));
1735 memcpy(new_instr
->neg
, neg
, sizeof(bool[3]));
1736 new_instr
->clamp
= clamp
;
1737 new_instr
->omod
= omod
;
1738 new_instr
->opsel
= opsel
;
1739 new_instr
->operands
[0] = operands
[0];
1740 new_instr
->operands
[1] = operands
[1];
1741 new_instr
->operands
[2] = operands
[2];
1742 new_instr
->definitions
[0] = instr
->definitions
[0];
1743 ctx
.info
[instr
->definitions
[0].tempId()].label
= 0;
1745 instr
.reset(new_instr
);
1748 bool combine_three_valu_op(opt_ctx
& ctx
, aco_ptr
<Instruction
>& instr
, aco_opcode op2
, aco_opcode new_op
, const char *shuffle
, uint8_t ops
)
1750 uint32_t omod_clamp
= ctx
.info
[instr
->definitions
[0].tempId()].label
&
1751 (label_omod_success
| label_clamp_success
);
1753 for (unsigned swap
= 0; swap
< 2; swap
++) {
1754 if (!((1 << swap
) & ops
))
1757 Operand operands
[3];
1758 bool neg
[3], abs
[3], clamp
;
1759 uint8_t opsel
= 0, omod
= 0;
1760 if (match_op3_for_vop3(ctx
, instr
->opcode
, op2
,
1761 instr
.get(), swap
, shuffle
,
1762 operands
, neg
, abs
, &opsel
,
1763 &clamp
, &omod
, NULL
, NULL
, NULL
)) {
1764 ctx
.uses
[instr
->operands
[swap
].tempId()]--;
1765 create_vop3_for_op3(ctx
, new_op
, instr
, operands
, neg
, abs
, opsel
, clamp
, omod
);
1766 if (omod_clamp
& label_omod_success
)
1767 ctx
.info
[instr
->definitions
[0].tempId()].set_omod_success(instr
.get());
1768 if (omod_clamp
& label_clamp_success
)
1769 ctx
.info
[instr
->definitions
[0].tempId()].set_clamp_success(instr
.get());
1776 bool combine_minmax(opt_ctx
& ctx
, aco_ptr
<Instruction
>& instr
, aco_opcode opposite
, aco_opcode minmax3
)
1778 if (combine_three_valu_op(ctx
, instr
, instr
->opcode
, minmax3
, "012", 1 | 2))
1781 uint32_t omod_clamp
= ctx
.info
[instr
->definitions
[0].tempId()].label
&
1782 (label_omod_success
| label_clamp_success
);
1784 /* min(-max(a, b), c) -> min3(-a, -b, c) *
1785 * max(-min(a, b), c) -> max3(-a, -b, c) */
1786 for (unsigned swap
= 0; swap
< 2; swap
++) {
1787 Operand operands
[3];
1788 bool neg
[3], abs
[3], clamp
;
1789 uint8_t opsel
= 0, omod
= 0;
1791 if (match_op3_for_vop3(ctx
, instr
->opcode
, opposite
,
1792 instr
.get(), swap
, "012",
1793 operands
, neg
, abs
, &opsel
,
1794 &clamp
, &omod
, &inbetween_neg
, NULL
, NULL
) &&
1796 ctx
.uses
[instr
->operands
[swap
].tempId()]--;
1799 create_vop3_for_op3(ctx
, minmax3
, instr
, operands
, neg
, abs
, opsel
, clamp
, omod
);
1800 if (omod_clamp
& label_omod_success
)
1801 ctx
.info
[instr
->definitions
[0].tempId()].set_omod_success(instr
.get());
1802 if (omod_clamp
& label_clamp_success
)
1803 ctx
.info
[instr
->definitions
[0].tempId()].set_clamp_success(instr
.get());
1810 /* s_not_b32(s_and_b32(a, b)) -> s_nand_b32(a, b)
1811 * s_not_b32(s_or_b32(a, b)) -> s_nor_b32(a, b)
1812 * s_not_b32(s_xor_b32(a, b)) -> s_xnor_b32(a, b)
1813 * s_not_b64(s_and_b64(a, b)) -> s_nand_b64(a, b)
1814 * s_not_b64(s_or_b64(a, b)) -> s_nor_b64(a, b)
1815 * s_not_b64(s_xor_b64(a, b)) -> s_xnor_b64(a, b) */
1816 bool combine_salu_not_bitwise(opt_ctx
& ctx
, aco_ptr
<Instruction
>& instr
)
1819 if (!instr
->operands
[0].isTemp())
1821 if (instr
->definitions
[1].isTemp() && ctx
.uses
[instr
->definitions
[1].tempId()])
1824 Instruction
*op2_instr
= follow_operand(ctx
, instr
->operands
[0]);
1827 switch (op2_instr
->opcode
) {
1828 case aco_opcode::s_and_b32
:
1829 case aco_opcode::s_or_b32
:
1830 case aco_opcode::s_xor_b32
:
1831 case aco_opcode::s_and_b64
:
1832 case aco_opcode::s_or_b64
:
1833 case aco_opcode::s_xor_b64
:
1839 /* create instruction */
1840 std::swap(instr
->definitions
[0], op2_instr
->definitions
[0]);
1841 std::swap(instr
->definitions
[1], op2_instr
->definitions
[1]);
1842 ctx
.uses
[instr
->operands
[0].tempId()]--;
1843 ctx
.info
[op2_instr
->definitions
[0].tempId()].label
= 0;
1845 switch (op2_instr
->opcode
) {
1846 case aco_opcode::s_and_b32
:
1847 op2_instr
->opcode
= aco_opcode::s_nand_b32
;
1849 case aco_opcode::s_or_b32
:
1850 op2_instr
->opcode
= aco_opcode::s_nor_b32
;
1852 case aco_opcode::s_xor_b32
:
1853 op2_instr
->opcode
= aco_opcode::s_xnor_b32
;
1855 case aco_opcode::s_and_b64
:
1856 op2_instr
->opcode
= aco_opcode::s_nand_b64
;
1858 case aco_opcode::s_or_b64
:
1859 op2_instr
->opcode
= aco_opcode::s_nor_b64
;
1861 case aco_opcode::s_xor_b64
:
1862 op2_instr
->opcode
= aco_opcode::s_xnor_b64
;
1871 /* s_and_b32(a, s_not_b32(b)) -> s_andn2_b32(a, b)
1872 * s_or_b32(a, s_not_b32(b)) -> s_orn2_b32(a, b)
1873 * s_and_b64(a, s_not_b64(b)) -> s_andn2_b64(a, b)
1874 * s_or_b64(a, s_not_b64(b)) -> s_orn2_b64(a, b) */
1875 bool combine_salu_n2(opt_ctx
& ctx
, aco_ptr
<Instruction
>& instr
)
1877 if (instr
->definitions
[0].isTemp() && ctx
.info
[instr
->definitions
[0].tempId()].is_uniform_bool())
1880 for (unsigned i
= 0; i
< 2; i
++) {
1881 Instruction
*op2_instr
= follow_operand(ctx
, instr
->operands
[i
]);
1882 if (!op2_instr
|| (op2_instr
->opcode
!= aco_opcode::s_not_b32
&& op2_instr
->opcode
!= aco_opcode::s_not_b64
))
1884 if (ctx
.uses
[op2_instr
->definitions
[1].tempId()] || fixed_to_exec(op2_instr
->operands
[0]))
1887 if (instr
->operands
[!i
].isLiteral() && op2_instr
->operands
[0].isLiteral() &&
1888 instr
->operands
[!i
].constantValue() != op2_instr
->operands
[0].constantValue())
1891 ctx
.uses
[instr
->operands
[i
].tempId()]--;
1892 instr
->operands
[0] = instr
->operands
[!i
];
1893 instr
->operands
[1] = op2_instr
->operands
[0];
1894 ctx
.info
[instr
->definitions
[0].tempId()].label
= 0;
1896 switch (instr
->opcode
) {
1897 case aco_opcode::s_and_b32
:
1898 instr
->opcode
= aco_opcode::s_andn2_b32
;
1900 case aco_opcode::s_or_b32
:
1901 instr
->opcode
= aco_opcode::s_orn2_b32
;
1903 case aco_opcode::s_and_b64
:
1904 instr
->opcode
= aco_opcode::s_andn2_b64
;
1906 case aco_opcode::s_or_b64
:
1907 instr
->opcode
= aco_opcode::s_orn2_b64
;
1918 /* s_add_{i32,u32}(a, s_lshl_b32(b, <n>)) -> s_lshl<n>_add_u32(a, b) */
1919 bool combine_salu_lshl_add(opt_ctx
& ctx
, aco_ptr
<Instruction
>& instr
)
1921 if (instr
->opcode
== aco_opcode::s_add_i32
&& ctx
.uses
[instr
->definitions
[1].tempId()])
1924 for (unsigned i
= 0; i
< 2; i
++) {
1925 Instruction
*op2_instr
= follow_operand(ctx
, instr
->operands
[i
]);
1926 if (!op2_instr
|| op2_instr
->opcode
!= aco_opcode::s_lshl_b32
||
1927 ctx
.uses
[op2_instr
->definitions
[1].tempId()])
1929 if (!op2_instr
->operands
[1].isConstant() || fixed_to_exec(op2_instr
->operands
[0]))
1932 uint32_t shift
= op2_instr
->operands
[1].constantValue();
1933 if (shift
< 1 || shift
> 4)
1936 if (instr
->operands
[!i
].isLiteral() && op2_instr
->operands
[0].isLiteral() &&
1937 instr
->operands
[!i
].constantValue() != op2_instr
->operands
[0].constantValue())
1940 ctx
.uses
[instr
->operands
[i
].tempId()]--;
1941 instr
->operands
[1] = instr
->operands
[!i
];
1942 instr
->operands
[0] = op2_instr
->operands
[0];
1943 ctx
.info
[instr
->definitions
[0].tempId()].label
= 0;
1945 instr
->opcode
= ((aco_opcode
[]){aco_opcode::s_lshl1_add_u32
,
1946 aco_opcode::s_lshl2_add_u32
,
1947 aco_opcode::s_lshl3_add_u32
,
1948 aco_opcode::s_lshl4_add_u32
})[shift
- 1];
1955 bool get_minmax_info(aco_opcode op
, aco_opcode
*min
, aco_opcode
*max
, aco_opcode
*min3
, aco_opcode
*max3
, aco_opcode
*med3
, bool *some_gfx9_only
)
1958 #define MINMAX(type, gfx9) \
1959 case aco_opcode::v_min_##type:\
1960 case aco_opcode::v_max_##type:\
1961 case aco_opcode::v_med3_##type:\
1962 *min = aco_opcode::v_min_##type;\
1963 *max = aco_opcode::v_max_##type;\
1964 *med3 = aco_opcode::v_med3_##type;\
1965 *min3 = aco_opcode::v_min3_##type;\
1966 *max3 = aco_opcode::v_max3_##type;\
1967 *some_gfx9_only = gfx9;\
1981 /* v_min_{f,u,i}{16,32}(v_max_{f,u,i}{16,32}(a, lb), ub) -> v_med3_{f,u,i}{16,32}(a, lb, ub) when ub > lb
1982 * v_max_{f,u,i}{16,32}(v_min_{f,u,i}{16,32}(a, ub), lb) -> v_med3_{f,u,i}{16,32}(a, lb, ub) when ub > lb */
1983 bool combine_clamp(opt_ctx
& ctx
, aco_ptr
<Instruction
>& instr
,
1984 aco_opcode min
, aco_opcode max
, aco_opcode med
)
1986 /* TODO: GLSL's clamp(x, minVal, maxVal) and SPIR-V's
1987 * FClamp(x, minVal, maxVal)/NClamp(x, minVal, maxVal) are undefined if
1988 * minVal > maxVal, which means we can always select it to a v_med3_f32 */
1989 aco_opcode other_op
;
1990 if (instr
->opcode
== min
)
1992 else if (instr
->opcode
== max
)
1997 uint32_t omod_clamp
= ctx
.info
[instr
->definitions
[0].tempId()].label
&
1998 (label_omod_success
| label_clamp_success
);
2000 for (unsigned swap
= 0; swap
< 2; swap
++) {
2001 Operand operands
[3];
2002 bool neg
[3], abs
[3], clamp
;
2003 uint8_t opsel
= 0, omod
= 0;
2004 if (match_op3_for_vop3(ctx
, instr
->opcode
, other_op
, instr
.get(), swap
,
2005 "012", operands
, neg
, abs
, &opsel
,
2006 &clamp
, &omod
, NULL
, NULL
, NULL
)) {
2007 int const0_idx
= -1, const1_idx
= -1;
2008 uint32_t const0
= 0, const1
= 0;
2009 for (int i
= 0; i
< 3; i
++) {
2011 if (operands
[i
].isConstant()) {
2012 val
= operands
[i
].constantValue();
2013 } else if (operands
[i
].isTemp() && ctx
.info
[operands
[i
].tempId()].is_constant_or_literal()) {
2014 val
= ctx
.info
[operands
[i
].tempId()].val
;
2018 if (const0_idx
>= 0) {
2026 if (const0_idx
< 0 || const1_idx
< 0)
2029 if (opsel
& (1 << const0_idx
))
2031 if (opsel
& (1 << const1_idx
))
2034 int lower_idx
= const0_idx
;
2036 case aco_opcode::v_min_f32
:
2037 case aco_opcode::v_min_f16
: {
2038 float const0_f
, const1_f
;
2039 if (min
== aco_opcode::v_min_f32
) {
2040 memcpy(&const0_f
, &const0
, 4);
2041 memcpy(&const1_f
, &const1
, 4);
2043 const0_f
= _mesa_half_to_float(const0
);
2044 const1_f
= _mesa_half_to_float(const1
);
2046 if (abs
[const0_idx
]) const0_f
= fabsf(const0_f
);
2047 if (abs
[const1_idx
]) const1_f
= fabsf(const1_f
);
2048 if (neg
[const0_idx
]) const0_f
= -const0_f
;
2049 if (neg
[const1_idx
]) const1_f
= -const1_f
;
2050 lower_idx
= const0_f
< const1_f
? const0_idx
: const1_idx
;
2053 case aco_opcode::v_min_u32
: {
2054 lower_idx
= const0
< const1
? const0_idx
: const1_idx
;
2057 case aco_opcode::v_min_u16
: {
2058 lower_idx
= (uint16_t)const0
< (uint16_t)const1
? const0_idx
: const1_idx
;
2061 case aco_opcode::v_min_i32
: {
2062 int32_t const0_i
= const0
& 0x80000000u
? -2147483648 + (int32_t)(const0
& 0x7fffffffu
) : const0
;
2063 int32_t const1_i
= const1
& 0x80000000u
? -2147483648 + (int32_t)(const1
& 0x7fffffffu
) : const1
;
2064 lower_idx
= const0_i
< const1_i
? const0_idx
: const1_idx
;
2067 case aco_opcode::v_min_i16
: {
2068 int16_t const0_i
= const0
& 0x8000u
? -32768 + (int16_t)(const0
& 0x7fffu
) : const0
;
2069 int16_t const1_i
= const1
& 0x8000u
? -32768 + (int16_t)(const1
& 0x7fffu
) : const1
;
2070 lower_idx
= const0_i
< const1_i
? const0_idx
: const1_idx
;
2076 int upper_idx
= lower_idx
== const0_idx
? const1_idx
: const0_idx
;
2078 if (instr
->opcode
== min
) {
2079 if (upper_idx
!= 0 || lower_idx
== 0)
2082 if (upper_idx
== 0 || lower_idx
!= 0)
2086 ctx
.uses
[instr
->operands
[swap
].tempId()]--;
2087 create_vop3_for_op3(ctx
, med
, instr
, operands
, neg
, abs
, opsel
, clamp
, omod
);
2088 if (omod_clamp
& label_omod_success
)
2089 ctx
.info
[instr
->definitions
[0].tempId()].set_omod_success(instr
.get());
2090 if (omod_clamp
& label_clamp_success
)
2091 ctx
.info
[instr
->definitions
[0].tempId()].set_clamp_success(instr
.get());
2101 void apply_sgprs(opt_ctx
&ctx
, aco_ptr
<Instruction
>& instr
)
2103 bool is_shift64
= instr
->opcode
== aco_opcode::v_lshlrev_b64
||
2104 instr
->opcode
== aco_opcode::v_lshrrev_b64
||
2105 instr
->opcode
== aco_opcode::v_ashrrev_i64
;
2107 /* find candidates and create the set of sgprs already read */
2108 unsigned sgpr_ids
[2] = {0, 0};
2109 uint32_t operand_mask
= 0;
2110 bool has_literal
= false;
2111 for (unsigned i
= 0; i
< instr
->operands
.size(); i
++) {
2112 if (instr
->operands
[i
].isLiteral())
2114 if (!instr
->operands
[i
].isTemp())
2116 if (instr
->operands
[i
].getTemp().type() == RegType::sgpr
) {
2117 if (instr
->operands
[i
].tempId() != sgpr_ids
[0])
2118 sgpr_ids
[!!sgpr_ids
[0]] = instr
->operands
[i
].tempId();
2120 ssa_info
& info
= ctx
.info
[instr
->operands
[i
].tempId()];
2121 if (info
.is_temp() && info
.temp
.type() == RegType::sgpr
)
2122 operand_mask
|= 1u << i
;
2124 unsigned max_sgprs
= 1;
2125 if (ctx
.program
->chip_class
>= GFX10
&& !is_shift64
)
2130 unsigned num_sgprs
= !!sgpr_ids
[0] + !!sgpr_ids
[1];
2132 /* keep on applying sgprs until there is nothing left to be done */
2133 while (operand_mask
) {
2134 uint32_t sgpr_idx
= 0;
2135 uint32_t sgpr_info_id
= 0;
2136 uint32_t mask
= operand_mask
;
2139 unsigned i
= u_bit_scan(&mask
);
2140 uint16_t uses
= ctx
.uses
[instr
->operands
[i
].tempId()];
2141 if (sgpr_info_id
== 0 || uses
< ctx
.uses
[sgpr_info_id
]) {
2143 sgpr_info_id
= instr
->operands
[i
].tempId();
2146 operand_mask
&= ~(1u << sgpr_idx
);
2148 /* Applying two sgprs require making it VOP3, so don't do it unless it's
2149 * definitively beneficial.
2150 * TODO: this is too conservative because later the use count could be reduced to 1 */
2151 if (num_sgprs
&& ctx
.uses
[sgpr_info_id
] > 1 && !instr
->isVOP3())
2154 Temp sgpr
= ctx
.info
[sgpr_info_id
].temp
;
2155 bool new_sgpr
= sgpr
.id() != sgpr_ids
[0] && sgpr
.id() != sgpr_ids
[1];
2156 if (new_sgpr
&& num_sgprs
>= max_sgprs
)
2159 if (sgpr_idx
== 0 || instr
->isVOP3()) {
2160 instr
->operands
[sgpr_idx
] = Operand(sgpr
);
2161 } else if (can_swap_operands(instr
)) {
2162 instr
->operands
[sgpr_idx
] = instr
->operands
[0];
2163 instr
->operands
[0] = Operand(sgpr
);
2164 /* swap bits using a 4-entry LUT */
2165 uint32_t swapped
= (0x3120 >> (operand_mask
& 0x3)) & 0xf;
2166 operand_mask
= (operand_mask
& ~0x3) | swapped
;
2167 } else if (can_use_VOP3(ctx
, instr
)) {
2168 to_VOP3(ctx
, instr
);
2169 instr
->operands
[sgpr_idx
] = Operand(sgpr
);
2175 sgpr_ids
[num_sgprs
++] = sgpr
.id();
2176 ctx
.uses
[sgpr_info_id
]--;
2177 ctx
.uses
[sgpr
.id()]++;
2181 bool apply_omod_clamp(opt_ctx
&ctx
, Block
& block
, aco_ptr
<Instruction
>& instr
)
2183 /* check if we could apply omod on predecessor */
2184 if (instr
->opcode
== aco_opcode::v_mul_f32
) {
2185 bool op0
= instr
->operands
[0].isTemp() && ctx
.info
[instr
->operands
[0].tempId()].is_omod_success();
2186 bool op1
= instr
->operands
[1].isTemp() && ctx
.info
[instr
->operands
[1].tempId()].is_omod_success();
2188 unsigned idx
= op0
? 0 : 1;
2189 /* omod was successfully applied */
2190 /* if the omod instruction is v_mad, we also have to change the original add */
2191 if (ctx
.info
[instr
->operands
[idx
].tempId()].is_mad()) {
2192 Instruction
* add_instr
= ctx
.mad_infos
[ctx
.info
[instr
->operands
[idx
].tempId()].val
].add_instr
.get();
2193 if (ctx
.info
[instr
->definitions
[0].tempId()].is_clamp())
2194 static_cast<VOP3A_instruction
*>(add_instr
)->clamp
= true;
2195 add_instr
->definitions
[0] = instr
->definitions
[0];
2198 Instruction
* omod_instr
= ctx
.info
[instr
->operands
[idx
].tempId()].instr
;
2199 /* check if we have an additional clamp modifier */
2200 if (ctx
.info
[instr
->definitions
[0].tempId()].is_clamp() && ctx
.uses
[instr
->definitions
[0].tempId()] == 1 &&
2201 ctx
.uses
[ctx
.info
[instr
->definitions
[0].tempId()].temp
.id()]) {
2202 static_cast<VOP3A_instruction
*>(omod_instr
)->clamp
= true;
2203 ctx
.info
[instr
->definitions
[0].tempId()].set_clamp_success(omod_instr
);
2205 /* change definition ssa-id of modified instruction */
2206 omod_instr
->definitions
[0] = instr
->definitions
[0];
2208 /* change the definition of instr to something unused, e.g. the original omod def */
2209 instr
->definitions
[0] = Definition(instr
->operands
[idx
].getTemp());
2210 ctx
.uses
[instr
->definitions
[0].tempId()] = 0;
2213 if (!ctx
.info
[instr
->definitions
[0].tempId()].label
) {
2214 /* in all other cases, label this instruction as option for multiply-add */
2215 ctx
.info
[instr
->definitions
[0].tempId()].set_mul(instr
.get());
2219 /* check if we could apply clamp on predecessor */
2220 if (instr
->opcode
== aco_opcode::v_med3_f32
) {
2222 bool found_zero
= false, found_one
= false;
2223 for (unsigned i
= 0; i
< 3; i
++)
2225 if (instr
->operands
[i
].constantEquals(0))
2227 else if (instr
->operands
[i
].constantEquals(0x3f800000)) /* 1.0 */
2232 if (found_zero
&& found_one
&& instr
->operands
[idx
].isTemp() &&
2233 ctx
.info
[instr
->operands
[idx
].tempId()].is_clamp_success()) {
2234 /* clamp was successfully applied */
2235 /* if the clamp instruction is v_mad, we also have to change the original add */
2236 if (ctx
.info
[instr
->operands
[idx
].tempId()].is_mad()) {
2237 Instruction
* add_instr
= ctx
.mad_infos
[ctx
.info
[instr
->operands
[idx
].tempId()].val
].add_instr
.get();
2238 add_instr
->definitions
[0] = instr
->definitions
[0];
2240 Instruction
* clamp_instr
= ctx
.info
[instr
->operands
[idx
].tempId()].instr
;
2241 /* change definition ssa-id of modified instruction */
2242 clamp_instr
->definitions
[0] = instr
->definitions
[0];
2244 /* change the definition of instr to something unused, e.g. the original omod def */
2245 instr
->definitions
[0] = Definition(instr
->operands
[idx
].getTemp());
2246 ctx
.uses
[instr
->definitions
[0].tempId()] = 0;
2251 /* omod has no effect if denormals are enabled */
2252 bool can_use_omod
= block
.fp_mode
.denorm32
== 0;
2254 /* apply omod / clamp modifiers if the def is used only once and the instruction can have modifiers */
2255 if (!instr
->definitions
.empty() && ctx
.uses
[instr
->definitions
[0].tempId()] == 1 &&
2256 can_use_VOP3(ctx
, instr
) && instr_info
.can_use_output_modifiers
[(int)instr
->opcode
]) {
2257 ssa_info
& def_info
= ctx
.info
[instr
->definitions
[0].tempId()];
2258 if (can_use_omod
&& def_info
.is_omod2() && ctx
.uses
[def_info
.temp
.id()]) {
2259 to_VOP3(ctx
, instr
);
2260 static_cast<VOP3A_instruction
*>(instr
.get())->omod
= 1;
2261 def_info
.set_omod_success(instr
.get());
2262 } else if (can_use_omod
&& def_info
.is_omod4() && ctx
.uses
[def_info
.temp
.id()]) {
2263 to_VOP3(ctx
, instr
);
2264 static_cast<VOP3A_instruction
*>(instr
.get())->omod
= 2;
2265 def_info
.set_omod_success(instr
.get());
2266 } else if (can_use_omod
&& def_info
.is_omod5() && ctx
.uses
[def_info
.temp
.id()]) {
2267 to_VOP3(ctx
, instr
);
2268 static_cast<VOP3A_instruction
*>(instr
.get())->omod
= 3;
2269 def_info
.set_omod_success(instr
.get());
2270 } else if (def_info
.is_clamp() && ctx
.uses
[def_info
.temp
.id()]) {
2271 to_VOP3(ctx
, instr
);
2272 static_cast<VOP3A_instruction
*>(instr
.get())->clamp
= true;
2273 def_info
.set_clamp_success(instr
.get());
2280 // TODO: we could possibly move the whole label_instruction pass to combine_instruction:
2281 // this would mean that we'd have to fix the instruction uses while value propagation
2283 void combine_instruction(opt_ctx
&ctx
, Block
& block
, aco_ptr
<Instruction
>& instr
)
2285 if (instr
->definitions
.empty() || is_dead(ctx
.uses
, instr
.get()))
2288 if (instr
->isVALU()) {
2289 if (can_apply_sgprs(instr
))
2290 apply_sgprs(ctx
, instr
);
2291 if (apply_omod_clamp(ctx
, block
, instr
))
2295 if (ctx
.info
[instr
->definitions
[0].tempId()].is_vcc_hint()) {
2296 instr
->definitions
[0].setHint(vcc
);
2299 /* TODO: There are still some peephole optimizations that could be done:
2300 * - abs(a - b) -> s_absdiff_i32
2301 * - various patterns for s_bitcmp{0,1}_b32 and s_bitset{0,1}_b32
2302 * - patterns for v_alignbit_b32 and v_alignbyte_b32
2303 * These aren't probably too interesting though.
2304 * There are also patterns for v_cmp_class_f{16,32,64}. This is difficult but
2305 * probably more useful than the previously mentioned optimizations.
2306 * The various comparison optimizations also currently only work with 32-bit
2309 /* neg(mul(a, b)) -> mul(neg(a), b) */
2310 if (ctx
.info
[instr
->definitions
[0].tempId()].is_neg() && ctx
.uses
[instr
->operands
[1].tempId()] == 1) {
2311 Temp val
= ctx
.info
[instr
->definitions
[0].tempId()].temp
;
2313 if (!ctx
.info
[val
.id()].is_mul())
2316 Instruction
* mul_instr
= ctx
.info
[val
.id()].instr
;
2318 if (mul_instr
->operands
[0].isLiteral())
2320 if (mul_instr
->isVOP3() && static_cast<VOP3A_instruction
*>(mul_instr
)->clamp
)
2323 /* convert to mul(neg(a), b) */
2324 ctx
.uses
[mul_instr
->definitions
[0].tempId()]--;
2325 Definition def
= instr
->definitions
[0];
2326 /* neg(abs(mul(a, b))) -> mul(neg(abs(a)), abs(b)) */
2327 bool is_abs
= ctx
.info
[instr
->definitions
[0].tempId()].is_abs();
2328 instr
.reset(create_instruction
<VOP3A_instruction
>(aco_opcode::v_mul_f32
, asVOP3(Format::VOP2
), 2, 1));
2329 instr
->operands
[0] = mul_instr
->operands
[0];
2330 instr
->operands
[1] = mul_instr
->operands
[1];
2331 instr
->definitions
[0] = def
;
2332 VOP3A_instruction
* new_mul
= static_cast<VOP3A_instruction
*>(instr
.get());
2333 if (mul_instr
->isVOP3()) {
2334 VOP3A_instruction
* mul
= static_cast<VOP3A_instruction
*>(mul_instr
);
2335 new_mul
->neg
[0] = mul
->neg
[0] && !is_abs
;
2336 new_mul
->neg
[1] = mul
->neg
[1] && !is_abs
;
2337 new_mul
->abs
[0] = mul
->abs
[0] || is_abs
;
2338 new_mul
->abs
[1] = mul
->abs
[1] || is_abs
;
2339 new_mul
->omod
= mul
->omod
;
2341 new_mul
->neg
[0] ^= true;
2342 new_mul
->clamp
= false;
2344 ctx
.info
[instr
->definitions
[0].tempId()].set_mul(instr
.get());
2347 /* combine mul+add -> mad */
2348 else if ((instr
->opcode
== aco_opcode::v_add_f32
||
2349 instr
->opcode
== aco_opcode::v_sub_f32
||
2350 instr
->opcode
== aco_opcode::v_subrev_f32
) &&
2351 block
.fp_mode
.denorm32
== 0 && !block
.fp_mode
.preserve_signed_zero_inf_nan32
) {
2352 //TODO: we could use fma instead when denormals are enabled if the NIR isn't marked as precise
2354 uint32_t uses_src0
= UINT32_MAX
;
2355 uint32_t uses_src1
= UINT32_MAX
;
2356 Instruction
* mul_instr
= nullptr;
2357 unsigned add_op_idx
;
2358 /* check if any of the operands is a multiplication */
2359 if (instr
->operands
[0].isTemp() && ctx
.info
[instr
->operands
[0].tempId()].is_mul())
2360 uses_src0
= ctx
.uses
[instr
->operands
[0].tempId()];
2361 if (instr
->operands
[1].isTemp() && ctx
.info
[instr
->operands
[1].tempId()].is_mul())
2362 uses_src1
= ctx
.uses
[instr
->operands
[1].tempId()];
2364 /* find the 'best' mul instruction to combine with the add */
2365 if (uses_src0
< uses_src1
) {
2366 mul_instr
= ctx
.info
[instr
->operands
[0].tempId()].instr
;
2368 } else if (uses_src1
< uses_src0
) {
2369 mul_instr
= ctx
.info
[instr
->operands
[1].tempId()].instr
;
2371 } else if (uses_src0
!= UINT32_MAX
) {
2372 /* tiebreaker: quite random what to pick */
2373 if (ctx
.info
[instr
->operands
[0].tempId()].instr
->operands
[0].isLiteral()) {
2374 mul_instr
= ctx
.info
[instr
->operands
[1].tempId()].instr
;
2377 mul_instr
= ctx
.info
[instr
->operands
[0].tempId()].instr
;
2382 Operand op
[3] = {Operand(v1
), Operand(v1
), Operand(v1
)};
2383 bool neg
[3] = {false, false, false};
2384 bool abs
[3] = {false, false, false};
2387 op
[0] = mul_instr
->operands
[0];
2388 op
[1] = mul_instr
->operands
[1];
2389 op
[2] = instr
->operands
[add_op_idx
];
2390 // TODO: would be better to check this before selecting a mul instr?
2391 if (!check_vop3_operands(ctx
, 3, op
))
2394 if (mul_instr
->isVOP3()) {
2395 VOP3A_instruction
* vop3
= static_cast<VOP3A_instruction
*> (mul_instr
);
2396 neg
[0] = vop3
->neg
[0];
2397 neg
[1] = vop3
->neg
[1];
2398 abs
[0] = vop3
->abs
[0];
2399 abs
[1] = vop3
->abs
[1];
2400 /* we cannot use these modifiers between mul and add */
2401 if (vop3
->clamp
|| vop3
->omod
)
2405 /* convert to mad */
2406 ctx
.uses
[mul_instr
->definitions
[0].tempId()]--;
2407 if (ctx
.uses
[mul_instr
->definitions
[0].tempId()]) {
2409 ctx
.uses
[op
[0].tempId()]++;
2411 ctx
.uses
[op
[1].tempId()]++;
2414 if (instr
->isVOP3()) {
2415 VOP3A_instruction
* vop3
= static_cast<VOP3A_instruction
*> (instr
.get());
2416 neg
[2] = vop3
->neg
[add_op_idx
];
2417 abs
[2] = vop3
->abs
[add_op_idx
];
2419 clamp
= vop3
->clamp
;
2420 /* abs of the multiplication result */
2421 if (vop3
->abs
[1 - add_op_idx
]) {
2427 /* neg of the multiplication result */
2428 neg
[1] = neg
[1] ^ vop3
->neg
[1 - add_op_idx
];
2430 if (instr
->opcode
== aco_opcode::v_sub_f32
)
2431 neg
[1 + add_op_idx
] = neg
[1 + add_op_idx
] ^ true;
2432 else if (instr
->opcode
== aco_opcode::v_subrev_f32
)
2433 neg
[2 - add_op_idx
] = neg
[2 - add_op_idx
] ^ true;
2435 aco_ptr
<VOP3A_instruction
> mad
{create_instruction
<VOP3A_instruction
>(aco_opcode::v_mad_f32
, Format::VOP3A
, 3, 1)};
2436 for (unsigned i
= 0; i
< 3; i
++)
2438 mad
->operands
[i
] = op
[i
];
2439 mad
->neg
[i
] = neg
[i
];
2440 mad
->abs
[i
] = abs
[i
];
2444 mad
->definitions
[0] = instr
->definitions
[0];
2446 /* mark this ssa_def to be re-checked for profitability and literals */
2447 ctx
.mad_infos
.emplace_back(std::move(instr
), mul_instr
->definitions
[0].tempId());
2448 ctx
.info
[mad
->definitions
[0].tempId()].set_mad(mad
.get(), ctx
.mad_infos
.size() - 1);
2449 instr
.reset(mad
.release());
2453 /* v_mul_f32(v_cndmask_b32(0, 1.0, cond), a) -> v_cndmask_b32(0, a, cond) */
2454 else if (instr
->opcode
== aco_opcode::v_mul_f32
&& !instr
->isVOP3()) {
2455 for (unsigned i
= 0; i
< 2; i
++) {
2456 if (instr
->operands
[i
].isTemp() && ctx
.info
[instr
->operands
[i
].tempId()].is_b2f() &&
2457 ctx
.uses
[instr
->operands
[i
].tempId()] == 1 &&
2458 instr
->operands
[!i
].isTemp() && instr
->operands
[!i
].getTemp().type() == RegType::vgpr
) {
2459 ctx
.uses
[instr
->operands
[i
].tempId()]--;
2460 ctx
.uses
[ctx
.info
[instr
->operands
[i
].tempId()].temp
.id()]++;
2462 aco_ptr
<VOP2_instruction
> new_instr
{create_instruction
<VOP2_instruction
>(aco_opcode::v_cndmask_b32
, Format::VOP2
, 3, 1)};
2463 new_instr
->operands
[0] = Operand(0u);
2464 new_instr
->operands
[1] = instr
->operands
[!i
];
2465 new_instr
->operands
[2] = Operand(ctx
.info
[instr
->operands
[i
].tempId()].temp
);
2466 new_instr
->definitions
[0] = instr
->definitions
[0];
2467 instr
.reset(new_instr
.release());
2468 ctx
.info
[instr
->definitions
[0].tempId()].label
= 0;
2472 } else if (instr
->opcode
== aco_opcode::v_or_b32
&& ctx
.program
->chip_class
>= GFX9
) {
2473 if (combine_three_valu_op(ctx
, instr
, aco_opcode::v_or_b32
, aco_opcode::v_or3_b32
, "012", 1 | 2)) ;
2474 else if (combine_three_valu_op(ctx
, instr
, aco_opcode::v_and_b32
, aco_opcode::v_and_or_b32
, "120", 1 | 2)) ;
2475 else combine_three_valu_op(ctx
, instr
, aco_opcode::v_lshlrev_b32
, aco_opcode::v_lshl_or_b32
, "210", 1 | 2);
2476 } else if (instr
->opcode
== aco_opcode::v_add_u32
&& ctx
.program
->chip_class
>= GFX9
) {
2477 if (combine_three_valu_op(ctx
, instr
, aco_opcode::v_xor_b32
, aco_opcode::v_xad_u32
, "120", 1 | 2)) ;
2478 else if (combine_three_valu_op(ctx
, instr
, aco_opcode::v_add_u32
, aco_opcode::v_add3_u32
, "012", 1 | 2)) ;
2479 else combine_three_valu_op(ctx
, instr
, aco_opcode::v_lshlrev_b32
, aco_opcode::v_lshl_add_u32
, "210", 1 | 2);
2480 } else if (instr
->opcode
== aco_opcode::v_lshlrev_b32
&& ctx
.program
->chip_class
>= GFX9
) {
2481 combine_three_valu_op(ctx
, instr
, aco_opcode::v_add_u32
, aco_opcode::v_add_lshl_u32
, "120", 2);
2482 } else if ((instr
->opcode
== aco_opcode::s_add_u32
|| instr
->opcode
== aco_opcode::s_add_i32
) && ctx
.program
->chip_class
>= GFX9
) {
2483 combine_salu_lshl_add(ctx
, instr
);
2484 } else if (instr
->opcode
== aco_opcode::s_not_b32
) {
2485 combine_salu_not_bitwise(ctx
, instr
);
2486 } else if (instr
->opcode
== aco_opcode::s_not_b64
) {
2487 if (combine_inverse_comparison(ctx
, instr
)) ;
2488 else combine_salu_not_bitwise(ctx
, instr
);
2489 } else if (instr
->opcode
== aco_opcode::s_and_b32
|| instr
->opcode
== aco_opcode::s_or_b32
||
2490 instr
->opcode
== aco_opcode::s_and_b64
|| instr
->opcode
== aco_opcode::s_or_b64
) {
2491 if (combine_ordering_test(ctx
, instr
)) ;
2492 else if (combine_comparison_ordering(ctx
, instr
)) ;
2493 else if (combine_constant_comparison_ordering(ctx
, instr
)) ;
2494 else combine_salu_n2(ctx
, instr
);
2496 aco_opcode min
, max
, min3
, max3
, med3
;
2497 bool some_gfx9_only
;
2498 if (get_minmax_info(instr
->opcode
, &min
, &max
, &min3
, &max3
, &med3
, &some_gfx9_only
) &&
2499 (!some_gfx9_only
|| ctx
.program
->chip_class
>= GFX9
)) {
2500 if (combine_minmax(ctx
, instr
, instr
->opcode
== min
? max
: min
, instr
->opcode
== min
? min3
: max3
)) ;
2501 else combine_clamp(ctx
, instr
, min
, max
, med3
);
2506 bool to_uniform_bool_instr(opt_ctx
&ctx
, aco_ptr
<Instruction
> &instr
)
2508 switch (instr
->opcode
) {
2509 case aco_opcode::s_and_b32
:
2510 case aco_opcode::s_and_b64
:
2511 instr
->opcode
= aco_opcode::s_and_b32
;
2513 case aco_opcode::s_or_b32
:
2514 case aco_opcode::s_or_b64
:
2515 instr
->opcode
= aco_opcode::s_or_b32
;
2517 case aco_opcode::s_xor_b32
:
2518 case aco_opcode::s_xor_b64
:
2519 instr
->opcode
= aco_opcode::s_absdiff_i32
;
2522 /* Don't transform other instructions. They are very unlikely to appear here. */
2526 for (Operand
&op
: instr
->operands
) {
2527 ctx
.uses
[op
.tempId()]--;
2529 if (ctx
.info
[op
.tempId()].is_uniform_bool()) {
2530 /* Just use the uniform boolean temp. */
2531 op
.setTemp(ctx
.info
[op
.tempId()].temp
);
2532 } else if (ctx
.info
[op
.tempId()].is_uniform_bitwise()) {
2533 /* Use the SCC definition of the predecessor instruction.
2534 * This allows the predecessor to get picked up by the same optimization (if it has no divergent users),
2535 * and it also makes sure that the current instruction will keep working even if the predecessor won't be transformed.
2537 Instruction
*pred_instr
= ctx
.info
[op
.tempId()].instr
;
2538 assert(pred_instr
->definitions
.size() >= 2);
2539 assert(pred_instr
->definitions
[1].isFixed() && pred_instr
->definitions
[1].physReg() == scc
);
2540 op
.setTemp(pred_instr
->definitions
[1].getTemp());
2542 unreachable("Invalid operand on uniform bitwise instruction.");
2545 ctx
.uses
[op
.tempId()]++;
2548 instr
->definitions
[0].setTemp(Temp(instr
->definitions
[0].tempId(), s1
));
2549 assert(instr
->operands
[0].regClass() == s1
);
2550 assert(instr
->operands
[1].regClass() == s1
);
2554 void select_instruction(opt_ctx
&ctx
, aco_ptr
<Instruction
>& instr
)
2556 const uint32_t threshold
= 4;
2558 if (is_dead(ctx
.uses
, instr
.get())) {
2563 /* convert split_vector into a copy or extract_vector if only one definition is ever used */
2564 if (instr
->opcode
== aco_opcode::p_split_vector
) {
2565 unsigned num_used
= 0;
2567 unsigned split_offset
= 0;
2568 for (unsigned i
= 0, offset
= 0; i
< instr
->definitions
.size(); offset
+= instr
->definitions
[i
++].bytes()) {
2569 if (ctx
.uses
[instr
->definitions
[i
].tempId()]) {
2572 split_offset
= offset
;
2576 if (num_used
== 1 && ctx
.info
[instr
->operands
[0].tempId()].is_vec() &&
2577 ctx
.uses
[instr
->operands
[0].tempId()] == 1) {
2578 Instruction
*vec
= ctx
.info
[instr
->operands
[0].tempId()].instr
;
2582 for (Operand
& vec_op
: vec
->operands
) {
2583 if (off
== split_offset
) {
2587 off
+= vec_op
.bytes();
2589 if (off
!= instr
->operands
[0].bytes() && op
.bytes() == instr
->definitions
[idx
].bytes()) {
2590 ctx
.uses
[instr
->operands
[0].tempId()]--;
2591 for (Operand
& vec_op
: vec
->operands
) {
2592 if (vec_op
.isTemp())
2593 ctx
.uses
[vec_op
.tempId()]--;
2596 ctx
.uses
[op
.tempId()]++;
2598 aco_ptr
<Pseudo_instruction
> extract
{create_instruction
<Pseudo_instruction
>(aco_opcode::p_create_vector
, Format::PSEUDO
, 1, 1)};
2599 extract
->operands
[0] = op
;
2600 extract
->definitions
[0] = instr
->definitions
[idx
];
2601 instr
.reset(extract
.release());
2607 if (!done
&& num_used
== 1 &&
2608 instr
->operands
[0].bytes() % instr
->definitions
[idx
].bytes() == 0 &&
2609 split_offset
% instr
->definitions
[idx
].bytes() == 0) {
2610 aco_ptr
<Pseudo_instruction
> extract
{create_instruction
<Pseudo_instruction
>(aco_opcode::p_extract_vector
, Format::PSEUDO
, 2, 1)};
2611 extract
->operands
[0] = instr
->operands
[0];
2612 extract
->operands
[1] = Operand((uint32_t) split_offset
/ instr
->definitions
[idx
].bytes());
2613 extract
->definitions
[0] = instr
->definitions
[idx
];
2614 instr
.reset(extract
.release());
2618 mad_info
* mad_info
= NULL
;
2619 if (instr
->opcode
== aco_opcode::v_mad_f32
&& ctx
.info
[instr
->definitions
[0].tempId()].is_mad()) {
2620 mad_info
= &ctx
.mad_infos
[ctx
.info
[instr
->definitions
[0].tempId()].val
];
2621 /* re-check mad instructions */
2622 if (ctx
.uses
[mad_info
->mul_temp_id
]) {
2623 ctx
.uses
[mad_info
->mul_temp_id
]++;
2624 if (instr
->operands
[0].isTemp())
2625 ctx
.uses
[instr
->operands
[0].tempId()]--;
2626 if (instr
->operands
[1].isTemp())
2627 ctx
.uses
[instr
->operands
[1].tempId()]--;
2628 instr
.swap(mad_info
->add_instr
);
2631 /* check literals */
2632 else if (!instr
->usesModifiers()) {
2633 bool sgpr_used
= false;
2634 uint32_t literal_idx
= 0;
2635 uint32_t literal_uses
= UINT32_MAX
;
2636 for (unsigned i
= 0; i
< instr
->operands
.size(); i
++)
2638 if (instr
->operands
[i
].isConstant() && i
> 0) {
2639 literal_uses
= UINT32_MAX
;
2642 if (!instr
->operands
[i
].isTemp())
2644 /* if one of the operands is sgpr, we cannot add a literal somewhere else on pre-GFX10 or operands other than the 1st */
2645 if (instr
->operands
[i
].getTemp().type() == RegType::sgpr
&& (i
> 0 || ctx
.program
->chip_class
< GFX10
)) {
2646 if (!sgpr_used
&& ctx
.info
[instr
->operands
[i
].tempId()].is_literal()) {
2647 literal_uses
= ctx
.uses
[instr
->operands
[i
].tempId()];
2650 literal_uses
= UINT32_MAX
;
2653 /* don't break because we still need to check constants */
2654 } else if (!sgpr_used
&&
2655 ctx
.info
[instr
->operands
[i
].tempId()].is_literal() &&
2656 ctx
.uses
[instr
->operands
[i
].tempId()] < literal_uses
) {
2657 literal_uses
= ctx
.uses
[instr
->operands
[i
].tempId()];
2662 /* Limit the number of literals to apply to not increase the code
2663 * size too much, but always apply literals for v_mad->v_madak
2664 * because both instructions are 64-bit and this doesn't increase
2666 * TODO: try to apply the literals earlier to lower the number of
2667 * uses below threshold
2669 if (literal_uses
< threshold
|| literal_idx
== 2) {
2670 ctx
.uses
[instr
->operands
[literal_idx
].tempId()]--;
2671 mad_info
->check_literal
= true;
2672 mad_info
->literal_idx
= literal_idx
;
2678 /* Mark SCC needed, so the uniform boolean transformation won't swap the definitions when it isn't beneficial */
2679 if (instr
->format
== Format::PSEUDO_BRANCH
&&
2680 instr
->operands
.size() &&
2681 instr
->operands
[0].isTemp()) {
2682 ctx
.info
[instr
->operands
[0].tempId()].set_scc_needed();
2684 } else if ((instr
->opcode
== aco_opcode::s_cselect_b64
||
2685 instr
->opcode
== aco_opcode::s_cselect_b32
) &&
2686 instr
->operands
[2].isTemp()) {
2687 ctx
.info
[instr
->operands
[2].tempId()].set_scc_needed();
2690 /* check for literals */
2691 if (!instr
->isSALU() && !instr
->isVALU())
2694 /* Transform uniform bitwise boolean operations to 32-bit when there are no divergent uses. */
2695 if (instr
->definitions
.size() &&
2696 ctx
.uses
[instr
->definitions
[0].tempId()] == 0 &&
2697 ctx
.info
[instr
->definitions
[0].tempId()].is_uniform_bitwise()) {
2698 bool transform_done
= to_uniform_bool_instr(ctx
, instr
);
2700 if (transform_done
&& !ctx
.info
[instr
->definitions
[1].tempId()].is_scc_needed()) {
2701 /* Swap the two definition IDs in order to avoid overusing the SCC. This reduces extra moves generated by RA. */
2702 uint32_t def0_id
= instr
->definitions
[0].getTemp().id();
2703 uint32_t def1_id
= instr
->definitions
[1].getTemp().id();
2704 instr
->definitions
[0].setTemp(Temp(def1_id
, s1
));
2705 instr
->definitions
[1].setTemp(Temp(def0_id
, s1
));
2711 if (instr
->isSDWA() || instr
->isDPP() || (instr
->isVOP3() && ctx
.program
->chip_class
< GFX10
))
2712 return; /* some encodings can't ever take literals */
2714 /* we do not apply the literals yet as we don't know if it is profitable */
2715 Operand
current_literal(s1
);
2717 unsigned literal_id
= 0;
2718 unsigned literal_uses
= UINT32_MAX
;
2719 Operand
literal(s1
);
2720 unsigned num_operands
= 1;
2721 if (instr
->isSALU() || (ctx
.program
->chip_class
>= GFX10
&& can_use_VOP3(ctx
, instr
)))
2722 num_operands
= instr
->operands
.size();
2723 /* catch VOP2 with a 3rd SGPR operand (e.g. v_cndmask_b32, v_addc_co_u32) */
2724 else if (instr
->isVALU() && instr
->operands
.size() >= 3)
2727 unsigned sgpr_ids
[2] = {0, 0};
2728 bool is_literal_sgpr
= false;
2731 /* choose a literal to apply */
2732 for (unsigned i
= 0; i
< num_operands
; i
++) {
2733 Operand op
= instr
->operands
[i
];
2735 if (instr
->isVALU() && op
.isTemp() && op
.getTemp().type() == RegType::sgpr
&&
2736 op
.tempId() != sgpr_ids
[0])
2737 sgpr_ids
[!!sgpr_ids
[0]] = op
.tempId();
2739 if (op
.isLiteral()) {
2740 current_literal
= op
;
2742 } else if (!op
.isTemp() || !ctx
.info
[op
.tempId()].is_literal()) {
2746 if (!alu_can_accept_constant(instr
->opcode
, i
))
2749 if (ctx
.uses
[op
.tempId()] < literal_uses
) {
2750 is_literal_sgpr
= op
.getTemp().type() == RegType::sgpr
;
2752 literal
= Operand(ctx
.info
[op
.tempId()].val
);
2753 literal_uses
= ctx
.uses
[op
.tempId()];
2754 literal_id
= op
.tempId();
2757 mask
|= (op
.tempId() == literal_id
) << i
;
2761 /* don't go over the constant bus limit */
2762 bool is_shift64
= instr
->opcode
== aco_opcode::v_lshlrev_b64
||
2763 instr
->opcode
== aco_opcode::v_lshrrev_b64
||
2764 instr
->opcode
== aco_opcode::v_ashrrev_i64
;
2765 unsigned const_bus_limit
= instr
->isVALU() ? 1 : UINT32_MAX
;
2766 if (ctx
.program
->chip_class
>= GFX10
&& !is_shift64
)
2767 const_bus_limit
= 2;
2769 unsigned num_sgprs
= !!sgpr_ids
[0] + !!sgpr_ids
[1];
2770 if (num_sgprs
== const_bus_limit
&& !is_literal_sgpr
)
2773 if (literal_id
&& literal_uses
< threshold
&&
2774 (current_literal
.isUndefined() ||
2775 (current_literal
.size() == literal
.size() &&
2776 current_literal
.constantValue() == literal
.constantValue()))) {
2777 /* mark the literal to be applied */
2779 unsigned i
= u_bit_scan(&mask
);
2780 if (instr
->operands
[i
].isTemp() && instr
->operands
[i
].tempId() == literal_id
)
2781 ctx
.uses
[instr
->operands
[i
].tempId()]--;
2787 void apply_literals(opt_ctx
&ctx
, aco_ptr
<Instruction
>& instr
)
2789 /* Cleanup Dead Instructions */
2793 /* apply literals on MAD */
2794 if (instr
->opcode
== aco_opcode::v_mad_f32
&& ctx
.info
[instr
->definitions
[0].tempId()].is_mad()) {
2795 mad_info
* info
= &ctx
.mad_infos
[ctx
.info
[instr
->definitions
[0].tempId()].val
];
2796 if (info
->check_literal
&&
2797 (ctx
.uses
[instr
->operands
[info
->literal_idx
].tempId()] == 0 || info
->literal_idx
== 2)) {
2798 aco_ptr
<Instruction
> new_mad
;
2799 if (info
->literal_idx
== 2) { /* add literal -> madak */
2800 new_mad
.reset(create_instruction
<VOP2_instruction
>(aco_opcode::v_madak_f32
, Format::VOP2
, 3, 1));
2801 new_mad
->operands
[0] = instr
->operands
[0];
2802 new_mad
->operands
[1] = instr
->operands
[1];
2803 } else { /* mul literal -> madmk */
2804 new_mad
.reset(create_instruction
<VOP2_instruction
>(aco_opcode::v_madmk_f32
, Format::VOP2
, 3, 1));
2805 new_mad
->operands
[0] = instr
->operands
[1 - info
->literal_idx
];
2806 new_mad
->operands
[1] = instr
->operands
[2];
2808 new_mad
->operands
[2] = Operand(ctx
.info
[instr
->operands
[info
->literal_idx
].tempId()].val
);
2809 new_mad
->definitions
[0] = instr
->definitions
[0];
2810 ctx
.instructions
.emplace_back(std::move(new_mad
));
2815 /* apply literals on other SALU/VALU */
2816 if (instr
->isSALU() || instr
->isVALU()) {
2817 for (unsigned i
= 0; i
< instr
->operands
.size(); i
++) {
2818 Operand op
= instr
->operands
[i
];
2819 if (op
.isTemp() && ctx
.info
[op
.tempId()].is_literal() && ctx
.uses
[op
.tempId()] == 0) {
2820 Operand
literal(ctx
.info
[op
.tempId()].val
);
2821 if (instr
->isVALU() && i
> 0)
2822 to_VOP3(ctx
, instr
);
2823 instr
->operands
[i
] = literal
;
2828 ctx
.instructions
.emplace_back(std::move(instr
));
2832 void optimize(Program
* program
)
2835 ctx
.program
= program
;
2836 std::vector
<ssa_info
> info(program
->peekAllocationId());
2837 ctx
.info
= info
.data();
2839 /* 1. Bottom-Up DAG pass (forward) to label all ssa-defs */
2840 for (Block
& block
: program
->blocks
) {
2841 for (aco_ptr
<Instruction
>& instr
: block
.instructions
)
2842 label_instruction(ctx
, block
, instr
);
2845 ctx
.uses
= std::move(dead_code_analysis(program
));
2847 /* 2. Combine v_mad, omod, clamp and propagate sgpr on VALU instructions */
2848 for (Block
& block
: program
->blocks
) {
2849 for (aco_ptr
<Instruction
>& instr
: block
.instructions
)
2850 combine_instruction(ctx
, block
, instr
);
2853 /* 3. Top-Down DAG pass (backward) to select instructions (includes DCE) */
2854 for (std::vector
<Block
>::reverse_iterator it
= program
->blocks
.rbegin(); it
!= program
->blocks
.rend(); ++it
) {
2855 Block
* block
= &(*it
);
2856 for (std::vector
<aco_ptr
<Instruction
>>::reverse_iterator it
= block
->instructions
.rbegin(); it
!= block
->instructions
.rend(); ++it
)
2857 select_instruction(ctx
, *it
);
2860 /* 4. Add literals to instructions */
2861 for (Block
& block
: program
->blocks
) {
2862 ctx
.instructions
.clear();
2863 for (aco_ptr
<Instruction
>& instr
: block
.instructions
)
2864 apply_literals(ctx
, instr
);
2865 block
.instructions
.swap(ctx
.instructions
);