// SPDX-FileCopyrightText: Copyright 2021 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#include <algorithm>
#include <functional>
#include <tuple>
#include <type_traits>
#include "common/bit_cast.h"
#include "shader_recompiler/environment.h"
#include "shader_recompiler/exception.h"
#include "shader_recompiler/frontend/ir/ir_emitter.h"
#include "shader_recompiler/frontend/ir/modifiers.h"
#include "shader_recompiler/frontend/ir/value.h"
#include "shader_recompiler/ir_opt/passes.h"
namespace Shader::Optimization {
namespace {
// Metaprogramming stuff to get arguments information out of a lambda
template <typename Func>
struct LambdaTraits : LambdaTraits<decltype(&std::remove_reference_t<Func>::operator())> {};
template <typename ReturnType, typename LambdaType, typename... Args>
struct LambdaTraits<ReturnType (LambdaType::*)(Args...) const> {
template <size_t I>
using ArgType = std::tuple_element_t<I, std::tuple<Args...>>;
static constexpr size_t NUM_ARGS{sizeof...(Args)};
};
template <typename T>
[[nodiscard]] T Arg(const IR::Value& value) {
if constexpr (std::is_same_v<T, bool>) {
return value.U1();
} else if constexpr (std::is_same_v<T, u32>) {
return value.U32();
} else if constexpr (std::is_same_v<T, s32>) {
return static_cast<s32>(value.U32());
} else if constexpr (std::is_same_v<T, f32>) {
return value.F32();
} else if constexpr (std::is_same_v<T, u64>) {
return value.U64();
}
}
template <typename T, typename ImmFn>
bool FoldCommutative(IR::Inst& inst, ImmFn&& imm_fn) {
const IR::Value lhs{inst.Arg(0)};
const IR::Value rhs{inst.Arg(1)};
const bool is_lhs_immediate{lhs.IsImmediate()};
const bool is_rhs_immediate{rhs.IsImmediate()};
if (is_lhs_immediate && is_rhs_immediate) {
const auto result{imm_fn(Arg<T>(lhs), Arg<T>(rhs))};
inst.ReplaceUsesWith(IR::Value{result});
return false;
}
if (is_lhs_immediate && !is_rhs_immediate) {
IR::Inst* const rhs_inst{rhs.InstRecursive()};
if (rhs_inst->GetOpcode() == inst.GetOpcode() && rhs_inst->Arg(1).IsImmediate()) {
const auto combined{imm_fn(Arg<T>(lhs), Arg<T>(rhs_inst->Arg(1)))};
inst.SetArg(0, rhs_inst->Arg(0));
inst.SetArg(1, IR::Value{combined});
} else {
// Normalize
inst.SetArg(0, rhs);
inst.SetArg(1, lhs);
}
}
if (!is_lhs_immediate && is_rhs_immediate) {
const IR::Inst* const lhs_inst{lhs.InstRecursive()};
if (lhs_inst->GetOpcode() == inst.GetOpcode() && lhs_inst->Arg(1).IsImmediate()) {
const auto combined{imm_fn(Arg<T>(rhs), Arg<T>(lhs_inst->Arg(1)))};
inst.SetArg(0, lhs_inst->Arg(0));
inst.SetArg(1, IR::Value{combined});
}
}
return true;
}
template <typename Func>
bool FoldWhenAllImmediates(IR::Inst& inst, Func&& func) {
if (!inst.AreAllArgsImmediates() || inst.HasAssociatedPseudoOperation()) {
return false;
}
using Indices = std::make_index_sequence<LambdaTraits<decltype(func)>::NUM_ARGS>;
inst.ReplaceUsesWith(EvalImmediates(inst, func, Indices{}));
return true;
}
/// Return true when all values in a range are equal
template <typename Range>
bool AreEqual(const Range& range) {
auto resolver{[](const auto& value) { return value.Resolve(); }};
auto equal{[](const IR::Value& lhs, const IR::Value& rhs) {
if (lhs == rhs) {
return true;
}
// Not equal, but try to match if they read the same constant buffer
if (!lhs.IsImmediate() && !rhs.IsImmediate() &&
lhs.Inst()->GetOpcode() == IR::Opcode::GetCbufU32 &&
rhs.Inst()->GetOpcode() == IR::Opcode::GetCbufU32 &&
lhs.Inst()->Arg(0) == rhs.Inst()->Arg(0) && lhs.Inst()->Arg(1) == rhs.Inst()->Arg(1)) {
return true;
}
return false;
}};
return std::ranges::adjacent_find(range, std::not_fn(equal), resolver) == std::end(range);
}
void FoldGetRegister(IR::Inst& inst) {
if (inst.Arg(0).Reg() == IR::Reg::RZ) {
inst.ReplaceUsesWith(IR::Value{u32{0}});
}
}
void FoldGetPred(IR::Inst& inst) {
if (inst.Arg(0).Pred() == IR::Pred::PT) {
inst.ReplaceUsesWith(IR::Value{true});
}
}
/// Replaces the XMAD pattern generated by an integer FMA
bool FoldXmadMultiplyAdd(IR::Block& block, IR::Inst& inst) {
/*
* We are looking for this specific pattern:
* %6 = BitFieldUExtract %op_b, #0, #16
* %7 = BitFieldUExtract %op_a', #16, #16
* %8 = IMul32 %6, %7
* %10 = BitFieldUExtract %op_a', #0, #16
* %11 = BitFieldInsert %8, %10, #16, #16
* %15 = BitFieldUExtract %op_b, #0, #16
* %16 = BitFieldUExtract %op_a, #0, #16
* %17 = IMul32 %15, %16
* %18 = IAdd32 %17, %op_c
* %22 = BitFieldUExtract %op_b, #16, #16
* %23 = BitFieldUExtract %11, #16, #16
* %24 = IMul32 %22, %23
* %25 = ShiftLeftLogical32 %24, #16
* %26 = ShiftLeftLogical32 %11, #16
* %27 = IAdd32 %26, %18
* %result = IAdd32 %25, %27
*
* And replace it with:
* %temp = IMul32 %op_a, %op_b
* %result = IAdd32 %temp, %op_c
*
* This optimization has been proven safe by Nvidia's compiler logic being reversed.
* (If Nvidia generates this code from 'fma(a, b, c)', we can do the same in the reverse order.)
*/
const IR::Value zero{0u};
const IR::Value sixteen{16u};
IR::Inst* const _25{inst.Arg(0).TryInstRecursive()};
IR::Inst* const _27{inst.Arg(1).TryInstRecursive()};
if (!_25 || !_27) {
return false;
}
if (_27->GetOpcode() != IR::Opcode::IAdd32) {
return false;
}
if (_25->GetOpcode() != IR::Opcode::ShiftLeftLogical32 || _25->Arg(1) != sixteen) {
return false;
}
IR::Inst* const _24{_25->Arg(0).TryInstRecursive()};
if (!_24 || _24->GetOpcode() != IR::Opcode::IMul32) {
return false;
}
IR::Inst* const _22{_24->Arg(0).TryInstRecursive()};
IR::Inst* const _23{_24->Arg(1).TryInstRecursive()};
if (!_22 || !_23) {
return false;
}
if (_22->GetOpcode() != IR::Opcode::BitFieldUExtract) {
return false;
}
if (_23->GetOpcode() != IR::Opcode::BitFieldUExtract) {
return false;
}
if (_22->Arg(1) != sixteen || _22->Arg(2) != sixteen) {
return false;
}
if (_23->Arg(1) != sixteen || _23->Arg(2) != sixteen) {
return false;
}
IR::Inst* const _11{_23->Arg(0).TryInstRecursive()};
if (!_11 || _11->GetOpcode() != IR::Opcode::BitFieldInsert) {
return false;
}
if (_11->Arg(2) != sixteen || _11->Arg(3) != sixteen) {
return false;
}
IR::Inst* const _8{_11->Arg(0).TryInstRecursive()};
IR::Inst* const _10{_11->Arg(1).TryInstRecursive()};
if (!_8 || !_10) {
return false;
}
if (_8->GetOpcode() != IR::Opcode::IMul32) {
return false;
}
if (_10->GetOpcode() != IR::Opcode::BitFieldUExtract) {
return false;
}
IR::Inst* const _6{_8->Arg(0).TryInstRecursive()};
IR::Inst* const _7{_8->Arg(1).TryInstRecursive()};
if (!_6 || !_7) {
return false;
}
if (_6->GetOpcode() != IR::Opcode::BitFieldUExtract) {
return false;
}
if (_7->GetOpcode() != IR::Opcode::BitFieldUExtract) {
return false;
}
if (_6->Arg(1) != zero || _6->Arg(2) != sixteen) {
return false;
}
if (_7->Arg(1) != sixteen || _7->Arg(2) != sixteen) {
return false;
}
IR::Inst* const _26{_27->Arg(0).TryInstRecursive()};
IR::Inst* const _18{_27->Arg(1).TryInstRecursive()};
if (!_26 || !_18) {
return false;
}
if (_26->GetOpcode() != IR::Opcode::ShiftLeftLogical32 || _26->Arg(1) != sixteen) {
return false;
}
if (_26->Arg(0).InstRecursive() != _11) {
return false;
}
if (_18->GetOpcode() != IR::Opcode::IAdd32) {
return false;
}
IR::Inst* const _17{_18->Arg(0).TryInstRecursive()};
if (!_17 || _17->GetOpcode() != IR::Opcode::IMul32) {
return false;
}
IR::Inst* const _15{_17->Arg(0).TryInstRecursive()};
IR::Inst* const _16{_17->Arg(1).TryInstRecursive()};
if (!_15 || !_16) {
return false;
}
if (_15->GetOpcode() != IR::Opcode::BitFieldUExtract) {
return false;
}
if (_16->GetOpcode() != IR::Opcode::BitFieldUExtract) {
return false;
}
if (_15->Arg(1) != zero || _16->Arg(1) != zero || _10->Arg(1) != zero) {
return false;
}
if (_15->Arg(2) != sixteen || _16->Arg(2) != sixteen || _10->Arg(2) != sixteen) {
return false;
}
const std::array<IR::Value, 3> op_as{
_7->Arg(0).Resolve(),
_16->Arg(0).Resolve(),
_10->Arg(0).Resolve(),
};
const std::array<IR::Value, 3> op_bs{
_22->Arg(0).Resolve(),
_6->Arg(0).Resolve(),
_15->Arg(0).Resolve(),
};
const IR::U32 op_c{_18->Arg(1)};
if (!AreEqual(op_as) || !AreEqual(op_bs)) {
return false;
}
IR::IREmitter ir{block, IR::Block::InstructionList::s_iterator_to(inst)};
inst.ReplaceUsesWith(ir.IAdd(ir.IMul(IR::U32{op_as[0]}, IR::U32{op_bs[1]}), op_c));
return true;
}
/// Replaces the pattern generated by two XMAD multiplications
bool FoldXmadMultiply(IR::Block& block, IR::Inst& inst) {
/*
* We are looking for this pattern:
* %rhs_bfe = BitFieldUExtract %factor_a, #0, #16
* %rhs_mul = IMul32 %rhs_bfe, %factor_b
* %lhs_bfe = BitFieldUExtract %factor_a, #16, #16
* %rhs_mul = IMul32 %lhs_bfe, %factor_b
* %lhs_shl = ShiftLeftLogical32 %rhs_mul, #16
* %result = IAdd32 %lhs_shl, %rhs_mul
*
* And replacing it with
* %result = IMul32 %factor_a, %factor_b
*
* This optimization has been proven safe by LLVM and MSVC.
*/
IR::Inst* const lhs_shl{inst.Arg(0).TryInstRecursive()};
IR::Inst* const rhs_mul{inst.Arg(1).TryInstRecursive()};
if (!lhs_shl || !rhs_mul) {
return false;
}
if (lhs_shl->GetOpcode() != IR::Opcode::ShiftLeftLogical32 ||
lhs_shl->Arg(1) != IR::Value{16U}) {
return false;
}
IR::Inst* const lhs_mul{lhs_shl->Arg(0).TryInstRecursive()};
if (!lhs_mul) {
return false;
}
if (lhs_mul->GetOpcode() != IR::Opcode::IMul32 || rhs_mul->GetOpcode() != IR::Opcode::IMul32) {
return false;
}
const IR::U32 factor_b{lhs_mul->Arg(1)};
if (factor_b.Resolve() != rhs_mul->Arg(1).Resolve()) {
return false;
}
IR::Inst* const lhs_bfe{lhs_mul->Arg(0).TryInstRecursive()};
IR::Inst* const rhs_bfe{rhs_mul->Arg(0).TryInstRecursive()};
if (!lhs_bfe || !rhs_bfe) {
return false;
}
if (lhs_bfe->GetOpcode() != IR::Opcode::BitFieldUExtract) {
return false;
}
if (rhs_bfe->GetOpcode() != IR::Opcode::BitFieldUExtract) {
return false;
}
if (lhs_bfe->Arg(1) != IR::Value{16U} || lhs_bfe->Arg(2) != IR::Value{16U}) {
return false;
}
if (rhs_bfe->Arg(1) != IR::Value{0U} || rhs_bfe->Arg(2) != IR::Value{16U}) {
return false;
}
const IR::U32 factor_a{lhs_bfe->Arg(0)};
if (factor_a.Resolve() != rhs_bfe->Arg(0).Resolve()) {
return false;
}
IR::IREmitter ir{block, IR::Block::InstructionList::s_iterator_to(inst)};
inst.ReplaceUsesWith(ir.IMul(factor_a, factor_b));
return true;
}
template <typename T>
void FoldAdd(IR::Block& block, IR::Inst& inst) {
if (inst.HasAssociatedPseudoOperation()) {
return;
}
if (!FoldCommutative<T>(inst, [](T a, T b) { return a + b; })) {
return;
}
const IR::Value rhs{inst.Arg(1)};
if (rhs.IsImmediate() && Arg<T>(rhs) == 0) {
inst.ReplaceUsesWith(inst.Arg(0));
return;
}
if constexpr (std::is_same_v<T, u32>) {
if (FoldXmadMultiply(block, inst)) {
return;
}
if (FoldXmadMultiplyAdd(block, inst)) {
return;
}
}
}
void FoldISub32(IR::Inst& inst) {
if (FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a - b; })) {
return;
}
if (inst.Arg(0).IsImmediate() || inst.Arg(1).IsImmediate()) {
return;
}
// ISub32 is generally used to subtract two constant buffers, compare and replace this with
// zero if they equal.
const auto equal_cbuf{[](IR::Inst* a, IR::Inst* b) {
return a->GetOpcode() == IR::Opcode::GetCbufU32 &&
b->GetOpcode() == IR::Opcode::GetCbufU32 && a->Arg(0) == b->Arg(0) &&
a->Arg(1) == b->Arg(1);
}};
IR::Inst* op_a{inst.Arg(0).InstRecursive()};
IR::Inst* op_b{inst.Arg(1).InstRecursive()};
if (equal_cbuf(op_a, op_b)) {
inst.ReplaceUsesWith(IR::Value{u32{0}});
return;
}
// It's also possible a value is being added to a cbuf and then subtracted
if (op_b->GetOpcode() == IR::Opcode::IAdd32) {
// Canonicalize local variables to simplify the following logic
std::swap(op_a, op_b);
}
if (op_b->GetOpcode() != IR::Opcode::GetCbufU32) {
return;
}
IR::Inst* const inst_cbuf{op_b};
if (op_a->GetOpcode() != IR::Opcode::IAdd32) {
return;
}
IR::Value add_op_a{op_a->Arg(0)};
IR::Value add_op_b{op_a->Arg(1)};
if (add_op_b.IsImmediate()) {
// Canonicalize
std::swap(add_op_a, add_op_b);
}
if (add_op_b.IsImmediate()) {
return;
}
IR::Inst* const add_cbuf{add_op_b.InstRecursive()};
if (equal_cbuf(add_cbuf, inst_cbuf)) {
inst.ReplaceUsesWith(add_op_a);
}
}
void FoldSelect(IR::Inst& inst) {
const IR::Value cond{inst.Arg(0)};
if (cond.IsImmediate()) {
inst.ReplaceUsesWith(cond.U1() ? inst.Arg(1) : inst.Arg(2));
}
}
void FoldFPAdd32(IR::Inst& inst) {
if (FoldWhenAllImmediates(inst, [](f32 a, f32 b) { return a + b; })) {
return;
}
const IR::Value lhs_value{inst.Arg(0)};
const IR::Value rhs_value{inst.Arg(1)};
const auto check_neutral = [](const IR::Value& one_operand) {
return one_operand.IsImmediate() && std::abs(one_operand.F32()) == 0.0f;
};
if (check_neutral(lhs_value)) {
inst.ReplaceUsesWith(rhs_value);
}
if (check_neutral(rhs_value)) {
inst.ReplaceUsesWith(lhs_value);
}
}
bool FoldDerivativeYFromCorrection(IR::Inst& inst) {
const IR::Value lhs_value{inst.Arg(0)};
const IR::Value rhs_value{inst.Arg(1)};
IR::Inst* const lhs_op{lhs_value.InstRecursive()};
IR::Inst* const rhs_op{rhs_value.InstRecursive()};
if (lhs_op->GetOpcode() == IR::Opcode::YDirection) {
if (rhs_op->GetOpcode() != IR::Opcode::DPdyFine) {
return false;
}
inst.ReplaceUsesWith(rhs_value);
return true;
}
if (rhs_op->GetOpcode() != IR::Opcode::YDirection) {
return false;
}
if (lhs_op->GetOpcode() != IR::Opcode::DPdyFine) {
return false;
}
inst.ReplaceUsesWith(lhs_value);
return true;
}
void FoldFPMul32(IR::Inst& inst) {
if (FoldWhenAllImmediates(inst, [](f32 a, f32 b) { return a * b; })) {
return;
}
const auto control{inst.Flags<IR::FpControl>()};
if (control.no_contraction) {
return;
}
// Fold interpolation operations
const IR::Value lhs_value{inst.Arg(0)};
const IR::Value rhs_value{inst.Arg(1)};
if (lhs_value.IsImmediate() || rhs_value.IsImmediate()) {
return;
}
if (FoldDerivativeYFromCorrection(inst)) {
return;
}
IR::Inst* const lhs_op{lhs_value.InstRecursive()};
IR::Inst* const rhs_op{rhs_value.InstRecursive()};
if (lhs_op->GetOpcode() != IR::Opcode::FPMul32 ||
rhs_op->GetOpcode() != IR::Opcode::FPRecip32) {
return;
}
const IR::Value recip_source{rhs_op->Arg(0)};
const IR::Value lhs_mul_source{lhs_op->Arg(1).Resolve()};
if (recip_source.IsImmediate() || lhs_mul_source.IsImmediate()) {
return;
}
IR::Inst* const attr_a{recip_source.InstRecursive()};
IR::Inst* const attr_b{lhs_mul_source.InstRecursive()};
if (attr_a->GetOpcode() != IR::Opcode::GetAttribute ||
attr_b->GetOpcode() != IR::Opcode::GetAttribute) {
return;
}
if (attr_a->Arg(0).Attribute() == attr_b->Arg(0).Attribute()) {
inst.ReplaceUsesWith(lhs_op->Arg(0));
}
}
void FoldLogicalAnd(IR::Inst& inst) {
if (!FoldCommutative<bool>(inst, [](bool a, bool b) { return a && b; })) {
return;
}
const IR::Value rhs{inst.Arg(1)};
if (rhs.IsImmediate()) {
if (rhs.U1()) {
inst.ReplaceUsesWith(inst.Arg(0));
} else {
inst.ReplaceUsesWith(IR::Value{false});
}
}
}
void FoldLogicalOr(IR::Inst& inst) {
if (!FoldCommutative<bool>(inst, [](bool a, bool b) { return a || b; })) {
return;
}
const IR::Value rhs{inst.Arg(1)};
if (rhs.IsImmediate()) {
if (rhs.U1()) {
inst.ReplaceUsesWith(IR::Value{true});
} else {
inst.ReplaceUsesWith(inst.Arg(0));
}
}
}
void FoldLogicalNot(IR::Inst& inst) {
const IR::U1 value{inst.Arg(0)};
if (value.IsImmediate()) {
inst.ReplaceUsesWith(IR::Value{!value.U1()});
return;
}
IR::Inst* const arg{value.InstRecursive()};
if (arg->GetOpcode() == IR::Opcode::LogicalNot) {
inst.ReplaceUsesWith(arg->Arg(0));
}
}
template <IR::Opcode op, typename Dest, typename Source>
void FoldBitCast(IR::Inst& inst, IR::Opcode reverse) {
const IR::Value value{inst.Arg(0)};
if (value.IsImmediate()) {
inst.ReplaceUsesWith(IR::Value{Common::BitCast<Dest>(Arg<Source>(value))});
return;
}
IR::Inst* const arg_inst{value.InstRecursive()};
if (arg_inst->GetOpcode() == reverse) {
inst.ReplaceUsesWith(arg_inst->Arg(0));
return;
}
if constexpr (op == IR::Opcode::BitCastF32U32) {
if (arg_inst->GetOpcode() == IR::Opcode::GetCbufU32) {
// Replace the bitcast with a typed constant buffer read
inst.ReplaceOpcode(IR::Opcode::GetCbufF32);
inst.SetArg(0, arg_inst->Arg(0));
inst.SetArg(1, arg_inst->Arg(1));
return;
}
}
if constexpr (op == IR::Opcode::BitCastU32F32) {
// Workaround for new NVIDIA driver bug, where:
// uint attr = ftou(itof(gl_InstanceID));
// always returned 0.
// We can instead manually optimize this and work around the driver bug:
// uint attr = uint(gl_InstanceID);
if (arg_inst->GetOpcode() == IR::Opcode::GetAttribute) {
const IR::Attribute attr{arg_inst->Arg(0).Attribute()};
switch (attr) {
case IR::Attribute::PrimitiveId:
case IR::Attribute::InstanceId:
case IR::Attribute::VertexId:
case IR::Attribute::BaseVertex:
case IR::Attribute::BaseInstance:
case IR::Attribute::DrawID:
break;
default:
return;
}
// Replace the bitcasts with an integer attribute get
inst.ReplaceOpcode(IR::Opcode::GetAttributeU32);
inst.SetArg(0, arg_inst->Arg(0));
inst.SetArg(1, arg_inst->Arg(1));
return;
}
}
}
void FoldInverseFunc(IR::Inst& inst, IR::Opcode reverse) {
const IR::Value value{inst.Arg(0)};
if (value.IsImmediate()) {
return;
}
IR::Inst* const arg_inst{value.InstRecursive()};
if (arg_inst->GetOpcode() == reverse) {
inst.ReplaceUsesWith(arg_inst->Arg(0));
return;
}
}
template <typename Func, size_t... I>
IR::Value EvalImmediates(const IR::Inst& inst, Func&& func, std::index_sequence<I...>) {
using Traits = LambdaTraits<decltype(func)>;
return IR::Value{func(Arg<typename Traits::template ArgType<I>>(inst.Arg(I))...)};
}
std::optional<IR::Value> FoldCompositeExtractImpl(IR::Value inst_value, IR::Opcode insert,
IR::Opcode construct, u32 first_index) {
IR::Inst* const inst{inst_value.InstRecursive()};
if (inst->GetOpcode() == construct) {
return inst->Arg(first_index);
}
if (inst->GetOpcode() != insert) {
return std::nullopt;
}
IR::Value value_index{inst->Arg(2)};
if (!value_index.IsImmediate()) {
return std::nullopt;
}
const u32 second_index{value_index.U32()};
if (first_index != second_index) {
IR::Value value_composite{inst->Arg(0)};
if (value_composite.IsImmediate()) {
return std::nullopt;
}
return FoldCompositeExtractImpl(value_composite, insert, construct, first_index);
}
return inst->Arg(1);
}
void FoldCompositeExtract(IR::Inst& inst, IR::Opcode construct, IR::Opcode insert) {
const IR::Value value_1{inst.Arg(0)};
const IR::Value value_2{inst.Arg(1)};
if (value_1.IsImmediate()) {
return;
}
if (!value_2.IsImmediate()) {
return;
}
const u32 first_index{value_2.U32()};
const std::optional result{FoldCompositeExtractImpl(value_1, insert, construct, first_index)};
if (!result) {
return;
}
inst.ReplaceUsesWith(*result);
}
IR::Value GetThroughCast(IR::Value value, IR::Opcode expected_cast) {
if (value.IsImmediate()) {
return value;
}
IR::Inst* const inst{value.InstRecursive()};
if (inst->GetOpcode() == expected_cast) {
return inst->Arg(0).Resolve();
}
return value;
}
void FoldFSwizzleAdd(IR::Block& block, IR::Inst& inst) {
const IR::Value swizzle{inst.Arg(2)};
if (!swizzle.IsImmediate()) {
return;
}
const IR::Value value_1{GetThroughCast(inst.Arg(0).Resolve(), IR::Opcode::BitCastF32U32)};
const IR::Value value_2{GetThroughCast(inst.Arg(1).Resolve(), IR::Opcode::BitCastF32U32)};
if (value_1.IsImmediate()) {
return;
}
const u32 swizzle_value{swizzle.U32()};
if (swizzle_value != 0x99 && swizzle_value != 0xA5) {
return;
}
IR::Inst* const inst2{value_1.InstRecursive()};
if (inst2->GetOpcode() != IR::Opcode::ShuffleButterfly) {
return;
}
const IR::Value value_3{GetThroughCast(inst2->Arg(0).Resolve(), IR::Opcode::BitCastU32F32)};
if (value_2 != value_3) {
if (!value_2.IsImmediate() || !value_3.IsImmediate()) {
return;
}
if (Common::BitCast<u32>(value_2.F32()) != value_3.U32()) {
return;
}
}
const IR::Value index{inst2->Arg(1)};
const IR::Value clamp{inst2->Arg(2)};
const IR::Value segmentation_mask{inst2->Arg(3)};
if (!index.IsImmediate() || !clamp.IsImmediate() || !segmentation_mask.IsImmediate()) {
return;
}
if (clamp.U32() != 3 || segmentation_mask.U32() != 28) {
return;
}
if (swizzle_value == 0x99) {
// DPdxFine
if (index.U32() == 1) {
IR::IREmitter ir{block, IR::Block::InstructionList::s_iterator_to(inst)};
inst.ReplaceUsesWith(ir.DPdxFine(IR::F32{inst.Arg(1)}));
}
} else if (swizzle_value == 0xA5) {
// DPdyFine
if (index.U32() == 2) {
IR::IREmitter ir{block, IR::Block::InstructionList::s_iterator_to(inst)};
inst.ReplaceUsesWith(ir.DPdyFine(IR::F32{inst.Arg(1)}));
}
}
}
bool FindGradient3DDerivatives(std::array<IR::Value, 3>& results, IR::Value coord) {
if (coord.IsImmediate()) {
return false;
}
const auto check_through_shuffle = [](IR::Value input, IR::Value& result) {
const IR::Value value_1{GetThroughCast(input.Resolve(), IR::Opcode::BitCastF32U32)};
IR::Inst* const inst2{value_1.InstRecursive()};
if (inst2->GetOpcode() != IR::Opcode::ShuffleIndex) {
return false;
}
const IR::Value index{inst2->Arg(1).Resolve()};
const IR::Value clamp{inst2->Arg(2).Resolve()};
const IR::Value segmentation_mask{inst2->Arg(3).Resolve()};
if (!index.IsImmediate() || !clamp.IsImmediate() || !segmentation_mask.IsImmediate()) {
return false;
}
if (index.U32() != 3 && clamp.U32() != 3) {
return false;
}
result = GetThroughCast(inst2->Arg(0).Resolve(), IR::Opcode::BitCastU32F32);
return true;
};
IR::Inst* const inst = coord.InstRecursive();
if (inst->GetOpcode() != IR::Opcode::FSwizzleAdd) {
return false;
}
std::array<IR::Value, 3> temporary_values;
IR::Value value_1 = inst->Arg(0).Resolve();
IR::Value value_2 = inst->Arg(1).Resolve();
IR::Value value_3 = inst->Arg(2).Resolve();
std::array<u32, 4> swizzles_mask_a{};
std::array<u32, 4> swizzles_mask_b{};
const auto resolve_mask = [](std::array<u32, 4>& mask_results, IR::Value mask) {
u32 value = mask.U32();
for (size_t i = 0; i < 4; i++) {
mask_results[i] = (value >> (i * 2)) & 0x3;
}
};
resolve_mask(swizzles_mask_a, value_3);
size_t coordinate_index = 0;
const auto resolve_pending = [&](IR::Value resolve_v) {
IR::Inst* const inst_r = resolve_v.InstRecursive();
if (inst_r->GetOpcode() != IR::Opcode::FSwizzleAdd) {
return false;
}
if (!check_through_shuffle(inst_r->Arg(0).Resolve(), temporary_values[1])) {
return false;
}
if (!check_through_shuffle(inst_r->Arg(1).Resolve(), temporary_values[2])) {
return false;
}
resolve_mask(swizzles_mask_b, inst_r->Arg(2).Resolve());
return true;
};
if (value_1.IsImmediate() || value_2.IsImmediate()) {
return false;
}
bool should_continue = false;
if (resolve_pending(value_1)) {
should_continue = check_through_shuffle(value_2, temporary_values[0]);
coordinate_index = 0;
}
if (resolve_pending(value_2)) {
should_continue = check_through_shuffle(value_1, temporary_values[0]);
coordinate_index = 2;
}
if (!should_continue) {
return false;
}
// figure which is which
size_t zero_mask_a = 0;
size_t zero_mask_b = 0;
for (size_t i = 0; i < 4; i++) {
if (swizzles_mask_a[i] == 2 || swizzles_mask_b[i] == 2) {
// last operand can be inversed, we cannot determine a result.
return false;
}
zero_mask_a |= static_cast<size_t>(swizzles_mask_a[i] == 3 ? 1 : 0) << i;
zero_mask_b |= static_cast<size_t>(swizzles_mask_b[i] == 3 ? 1 : 0) << i;
}
static constexpr size_t ddx_pattern = 0b1010;
static constexpr size_t ddx_pattern_inv = ~ddx_pattern & 0b00001111;
if (std::popcount(zero_mask_a) != 2) {
return false;
}
if (std::popcount(zero_mask_b) != 2) {
return false;
}
if (zero_mask_a == zero_mask_b) {
return false;
}
results[0] = temporary_values[coordinate_index];
if (coordinate_index == 0) {
if (zero_mask_b == ddx_pattern || zero_mask_b == ddx_pattern_inv) {
results[1] = temporary_values[1];
results[2] = temporary_values[2];
return true;
}
results[2] = temporary_values[1];
results[1] = temporary_values[2];
} else {
const auto assign_result = [&results](IR::Value temporary_value, size_t mask) {
if (mask == ddx_pattern || mask == ddx_pattern_inv) {
results[1] = temporary_value;
return;
}
results[2] = temporary_value;
};
assign_result(temporary_values[1], zero_mask_b);
assign_result(temporary_values[0], zero_mask_a);
}
return true;
}
void ConvertDerivatives(std::array<IR::Value, 3>& results, IR::IREmitter& ir) {
for (size_t i = 0; i < 3; i++) {
if (results[i].Type() == IR::Type::U32) {
results[i] = results[i].IsImmediate() ? ir.Imm32(Common::BitCast<f32>(results[i].U32()))
: ir.BitCast<IR::F32>(IR::U32(results[i]));
}
}
}
void FoldImageSampleImplicitLod(IR::Block& block, IR::Inst& inst) {
IR::TextureInstInfo info = inst.Flags<IR::TextureInstInfo>();
auto orig_opcode = inst.GetOpcode();
if (info.ndv_is_active == 0) {
return;
}
if (info.type != TextureType::Color3D) {
return;
}
const IR::Value handle{inst.Arg(0)};
const IR::Value coords{inst.Arg(1)};
const IR::Value bias_lc{inst.Arg(2)};
const IR::Value offset{inst.Arg(3)};
if (!offset.IsImmediate()) {
return;
}
IR::IREmitter ir{block, IR::Block::InstructionList::s_iterator_to(inst)};
IR::Inst* const inst2 = coords.InstRecursive();
std::array<std::array<IR::Value, 3>, 3> results_matrix;
for (size_t i = 0; i < 3; i++) {
if (!FindGradient3DDerivatives(results_matrix[i], inst2->Arg(i).Resolve())) {
return;
}
ConvertDerivatives(results_matrix[i], ir);
}
IR::F32 lod_clamp{};
if (info.has_lod_clamp != 0) {
if (!bias_lc.IsImmediate()) {
lod_clamp = IR::F32{bias_lc.InstRecursive()->Arg(1).Resolve()};
} else {
lod_clamp = IR::F32{bias_lc};
}
}
IR::Value new_coords =
ir.CompositeConstruct(results_matrix[0][0], results_matrix[1][0], results_matrix[2][0]);
IR::Value derivatives_1 = ir.CompositeConstruct(results_matrix[0][1], results_matrix[0][2],
results_matrix[1][1], results_matrix[1][2]);
IR::Value derivatives_2 = ir.CompositeConstruct(results_matrix[2][1], results_matrix[2][2]);
info.num_derivatives.Assign(3);
IR::Value new_gradient_instruction =
ir.ImageGradient(handle, new_coords, derivatives_1, derivatives_2, lod_clamp, info);
IR::Inst* const new_inst = new_gradient_instruction.InstRecursive();
if (orig_opcode == IR::Opcode::ImageSampleImplicitLod) {
new_inst->ReplaceOpcode(IR::Opcode::ImageGradient);
}
inst.ReplaceUsesWith(new_gradient_instruction);
}
void FoldConstBuffer(Environment& env, IR::Block& block, IR::Inst& inst) {
const IR::Value bank{inst.Arg(0)};
const IR::Value offset{inst.Arg(1)};
if (!bank.IsImmediate() || !offset.IsImmediate()) {
return;
}
const auto bank_value = bank.U32();
const auto offset_value = offset.U32();
auto replacement = env.GetReplaceConstBuffer(bank_value, offset_value);
if (!replacement) {
return;
}
const auto new_attribute = [replacement]() {
switch (*replacement) {
case ReplaceConstant::BaseInstance:
return IR::Attribute::BaseInstance;
case ReplaceConstant::BaseVertex:
return IR::Attribute::BaseVertex;
case ReplaceConstant::DrawID:
return IR::Attribute::DrawID;
default:
throw NotImplementedException("Not implemented replacement variable {}", *replacement);
}
}();
IR::IREmitter ir{block, IR::Block::InstructionList::s_iterator_to(inst)};
if (inst.GetOpcode() == IR::Opcode::GetCbufU32) {
inst.ReplaceUsesWith(ir.GetAttributeU32(new_attribute));
} else {
inst.ReplaceUsesWith(ir.GetAttribute(new_attribute));
}
}
void FoldDriverConstBuffer(Environment& env, IR::Block& block, IR::Inst& inst, u32 which_bank,
u32 offset_start = 0, u32 offset_end = std::numeric_limits<u16>::max()) {
const IR::Value bank{inst.Arg(0)};
const IR::Value offset{inst.Arg(1)};
if (!bank.IsImmediate() || !offset.IsImmediate()) {
return;
}
const auto bank_value = bank.U32();
if (bank_value != which_bank) {
return;
}
const auto offset_value = offset.U32();
if (offset_value < offset_start || offset_value >= offset_end) {
return;
}
IR::IREmitter ir{block, IR::Block::InstructionList::s_iterator_to(inst)};
if (inst.GetOpcode() == IR::Opcode::GetCbufU32) {
inst.ReplaceUsesWith(IR::Value{env.ReadCbufValue(bank_value, offset_value)});
} else {
inst.ReplaceUsesWith(
IR::Value{Common::BitCast<f32>(env.ReadCbufValue(bank_value, offset_value))});
}
}
void ConstantPropagation(Environment& env, IR::Block& block, IR::Inst& inst) {
switch (inst.GetOpcode()) {
case IR::Opcode::GetRegister:
return FoldGetRegister(inst);
case IR::Opcode::GetPred:
return FoldGetPred(inst);
case IR::Opcode::IAdd32:
return FoldAdd<u32>(block, inst);
case IR::Opcode::ISub32:
return FoldISub32(inst);
case IR::Opcode::IMul32:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a * b; });
return;
case IR::Opcode::ShiftRightArithmetic32:
FoldWhenAllImmediates(inst, [](s32 a, s32 b) { return static_cast<u32>(a >> b); });
return;
case IR::Opcode::BitCastF32U32:
return FoldBitCast<IR::Opcode::BitCastF32U32, f32, u32>(inst, IR::Opcode::BitCastU32F32);
case IR::Opcode::BitCastU32F32:
return FoldBitCast<IR::Opcode::BitCastU32F32, u32, f32>(inst, IR::Opcode::BitCastF32U32);
case IR::Opcode::IAdd64:
return FoldAdd<u64>(block, inst);
case IR::Opcode::PackHalf2x16:
return FoldInverseFunc(inst, IR::Opcode::UnpackHalf2x16);
case IR::Opcode::UnpackHalf2x16:
return FoldInverseFunc(inst, IR::Opcode::PackHalf2x16);
case IR::Opcode::PackFloat2x16:
return FoldInverseFunc(inst, IR::Opcode::UnpackFloat2x16);
case IR::Opcode::UnpackFloat2x16:
return FoldInverseFunc(inst, IR::Opcode::PackFloat2x16);
case IR::Opcode::SelectU1:
case IR::Opcode::SelectU8:
case IR::Opcode::SelectU16:
case IR::Opcode::SelectU32:
case IR::Opcode::SelectU64:
case IR::Opcode::SelectF16:
case IR::Opcode::SelectF32:
case IR::Opcode::SelectF64:
return FoldSelect(inst);
case IR::Opcode::FPNeg32:
FoldWhenAllImmediates(inst, [](f32 a) { return -a; });
return;
case IR::Opcode::FPAdd32:
FoldFPAdd32(inst);
return;
case IR::Opcode::FPMul32:
return FoldFPMul32(inst);
case IR::Opcode::LogicalAnd:
return FoldLogicalAnd(inst);
case IR::Opcode::LogicalOr:
return FoldLogicalOr(inst);
case IR::Opcode::LogicalNot:
return FoldLogicalNot(inst);
case IR::Opcode::SLessThan:
FoldWhenAllImmediates(inst, [](s32 a, s32 b) { return a < b; });
return;
case IR::Opcode::ULessThan:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a < b; });
return;
case IR::Opcode::SLessThanEqual:
FoldWhenAllImmediates(inst, [](s32 a, s32 b) { return a <= b; });
return;
case IR::Opcode::ULessThanEqual:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a <= b; });
return;
case IR::Opcode::SGreaterThan:
FoldWhenAllImmediates(inst, [](s32 a, s32 b) { return a > b; });
return;
case IR::Opcode::UGreaterThan:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a > b; });
return;
case IR::Opcode::SGreaterThanEqual:
FoldWhenAllImmediates(inst, [](s32 a, s32 b) { return a >= b; });
return;
case IR::Opcode::UGreaterThanEqual:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a >= b; });
return;
case IR::Opcode::IEqual:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a == b; });
return;
case IR::Opcode::INotEqual:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a != b; });
return;
case IR::Opcode::BitwiseAnd32:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a & b; });
return;
case IR::Opcode::BitwiseOr32:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a | b; });
return;
case IR::Opcode::BitwiseXor32:
FoldWhenAllImmediates(inst, [](u32 a, u32 b) { return a ^ b; });
return;
case IR::Opcode::BitFieldUExtract:
FoldWhenAllImmediates(inst, [](u32 base, u32 shift, u32 count) {
if (static_cast<size_t>(shift) + static_cast<size_t>(count) > 32) {
throw LogicError("Undefined result in {}({}, {}, {})", IR::Opcode::BitFieldUExtract,
base, shift, count);
}
return (base >> shift) & ((1U << count) - 1);
});
return;
case IR::Opcode::BitFieldSExtract:
FoldWhenAllImmediates(inst, [](s32 base, u32 shift, u32 count) {
const size_t back_shift{static_cast<size_t>(shift) + static_cast<size_t>(count)};
const size_t left_shift{32 - back_shift};
const size_t right_shift{static_cast<size_t>(32 - count)};
if (back_shift > 32 || left_shift >= 32 || right_shift >= 32) {
throw LogicError("Undefined result in {}({}, {}, {})", IR::Opcode::BitFieldSExtract,
base, shift, count);
}
return static_cast<u32>((base << left_shift) >> right_shift);
});
return;
case IR::Opcode::BitFieldInsert:
FoldWhenAllImmediates(inst, [](u32 base, u32 insert, u32 offset, u32 bits) {
if (bits >= 32 || offset >= 32) {
throw LogicError("Undefined result in {}({}, {}, {}, {})",
IR::Opcode::BitFieldInsert, base, insert, offset, bits);
}
return (base & ~(~(~0u << bits) << offset)) | (insert << offset);
});
return;
case IR::Opcode::CompositeExtractU32x2:
return FoldCompositeExtract(inst, IR::Opcode::CompositeConstructU32x2,
IR::Opcode::CompositeInsertU32x2);
case IR::Opcode::CompositeExtractU32x3:
return FoldCompositeExtract(inst, IR::Opcode::CompositeConstructU32x3,
IR::Opcode::CompositeInsertU32x3);
case IR::Opcode::CompositeExtractU32x4:
return FoldCompositeExtract(inst, IR::Opcode::CompositeConstructU32x4,
IR::Opcode::CompositeInsertU32x4);
case IR::Opcode::CompositeExtractF32x2:
return FoldCompositeExtract(inst, IR::Opcode::CompositeConstructF32x2,
IR::Opcode::CompositeInsertF32x2);
case IR::Opcode::CompositeExtractF32x3:
return FoldCompositeExtract(inst, IR::Opcode::CompositeConstructF32x3,
IR::Opcode::CompositeInsertF32x3);
case IR::Opcode::CompositeExtractF32x4:
return FoldCompositeExtract(inst, IR::Opcode::CompositeConstructF32x4,
IR::Opcode::CompositeInsertF32x4);
case IR::Opcode::CompositeExtractF16x2:
return FoldCompositeExtract(inst, IR::Opcode::CompositeConstructF16x2,
IR::Opcode::CompositeInsertF16x2);
case IR::Opcode::CompositeExtractF16x3:
return FoldCompositeExtract(inst, IR::Opcode::CompositeConstructF16x3,
IR::Opcode::CompositeInsertF16x3);
case IR::Opcode::CompositeExtractF16x4:
return FoldCompositeExtract(inst, IR::Opcode::CompositeConstructF16x4,
IR::Opcode::CompositeInsertF16x4);
case IR::Opcode::FSwizzleAdd:
return FoldFSwizzleAdd(block, inst);
case IR::Opcode::GetCbufF32:
case IR::Opcode::GetCbufU32:
if (env.HasHLEMacroState()) {
FoldConstBuffer(env, block, inst);
}
if (env.IsPropietaryDriver()) {
FoldDriverConstBuffer(env, block, inst, 1);
}
break;
case IR::Opcode::BindlessImageSampleImplicitLod:
case IR::Opcode::BoundImageSampleImplicitLod:
case IR::Opcode::ImageSampleImplicitLod:
FoldImageSampleImplicitLod(block, inst);
break;
default:
break;
}
}
} // Anonymous namespace
void ConstantPropagationPass(Environment& env, IR::Program& program) {
const auto end{program.post_order_blocks.rend()};
for (auto it = program.post_order_blocks.rbegin(); it != end; ++it) {
IR::Block* const block{*it};
for (IR::Inst& inst : block->Instructions()) {
ConstantPropagation(env, *block, inst);
}
}
}
} // namespace Shader::Optimization