SPIRV-Tools/source/opt/upgrade_memory_model.cpp

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// Copyright (c) 2018 Google LLC
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "upgrade_memory_model.h"
#include <utility>
#include "source/opt/ir_builder.h"
#include "source/opt/ir_context.h"
#include "source/spirv_constant.h"
#include "source/util/make_unique.h"
#include "source/util/string_utils.h"
namespace spvtools {
namespace opt {
Pass::Status UpgradeMemoryModel::Process() {
// TODO: This pass needs changes to support cooperative matrices.
if (context()->get_feature_mgr()->HasCapability(
spv::Capability::CooperativeMatrixNV)) {
return Pass::Status::SuccessWithoutChange;
}
// Only update Logical GLSL450 to Logical VulkanKHR.
Instruction* memory_model = get_module()->GetMemoryModel();
if (memory_model->GetSingleWordInOperand(0u) !=
uint32_t(spv::AddressingModel::Logical) ||
memory_model->GetSingleWordInOperand(1u) !=
uint32_t(spv::MemoryModel::GLSL450)) {
return Pass::Status::SuccessWithoutChange;
}
UpgradeMemoryModelInstruction();
UpgradeInstructions();
CleanupDecorations();
UpgradeBarriers();
UpgradeMemoryScope();
return Pass::Status::SuccessWithChange;
}
void UpgradeMemoryModel::UpgradeMemoryModelInstruction() {
// Overall changes necessary:
// 1. Add the OpExtension.
// 2. Add the OpCapability.
// 3. Modify the memory model.
Instruction* memory_model = get_module()->GetMemoryModel();
context()->AddCapability(MakeUnique<Instruction>(
context(), spv::Op::OpCapability, 0, 0,
std::initializer_list<Operand>{
{SPV_OPERAND_TYPE_CAPABILITY,
{uint32_t(spv::Capability::VulkanMemoryModelKHR)}}}));
const std::string extension = "SPV_KHR_vulkan_memory_model";
std::vector<uint32_t> words = spvtools::utils::MakeVector(extension);
context()->AddExtension(
MakeUnique<Instruction>(context(), spv::Op::OpExtension, 0, 0,
std::initializer_list<Operand>{
{SPV_OPERAND_TYPE_LITERAL_STRING, words}}));
memory_model->SetInOperand(1u, {uint32_t(spv::MemoryModel::VulkanKHR)});
}
void UpgradeMemoryModel::UpgradeInstructions() {
// Coherent and Volatile decorations are deprecated. Remove them and replace
// with flags on the memory/image operations. The decorations can occur on
// OpVariable, OpFunctionParameter (of pointer type) and OpStructType (member
// decoration). Trace from the decoration target(s) to the final memory/image
// instructions. Additionally, Workgroup storage class variables and function
// parameters are implicitly coherent in GLSL450.
// Upgrade modf and frexp first since they generate new stores.
// In SPIR-V 1.4 or later, normalize OpCopyMemory* access operands.
for (auto& func : *get_module()) {
func.ForEachInst([this](Instruction* inst) {
if (inst->opcode() == spv::Op::OpExtInst) {
auto ext_inst = inst->GetSingleWordInOperand(1u);
if (ext_inst == GLSLstd450Modf || ext_inst == GLSLstd450Frexp) {
auto import =
get_def_use_mgr()->GetDef(inst->GetSingleWordInOperand(0u));
if (import->GetInOperand(0u).AsString() == "GLSL.std.450") {
UpgradeExtInst(inst);
}
}
} else if (get_module()->version() >= SPV_SPIRV_VERSION_WORD(1, 4)) {
if (inst->opcode() == spv::Op::OpCopyMemory ||
inst->opcode() == spv::Op::OpCopyMemorySized) {
uint32_t start_operand =
inst->opcode() == spv::Op::OpCopyMemory ? 2u : 3u;
if (inst->NumInOperands() > start_operand) {
auto num_access_words = MemoryAccessNumWords(
inst->GetSingleWordInOperand(start_operand));
if ((num_access_words + start_operand) == inst->NumInOperands()) {
// There is a single memory access operand. Duplicate it to have a
// separate operand for both source and target.
for (uint32_t i = 0; i < num_access_words; ++i) {
auto operand = inst->GetInOperand(start_operand + i);
inst->AddOperand(std::move(operand));
}
}
} else {
// Add two memory access operands.
inst->AddOperand({SPV_OPERAND_TYPE_MEMORY_ACCESS,
{uint32_t(spv::MemoryAccessMask::MaskNone)}});
inst->AddOperand({SPV_OPERAND_TYPE_MEMORY_ACCESS,
{uint32_t(spv::MemoryAccessMask::MaskNone)}});
}
}
}
});
}
UpgradeMemoryAndImages();
UpgradeAtomics();
}
void UpgradeMemoryModel::UpgradeMemoryAndImages() {
for (auto& func : *get_module()) {
func.ForEachInst([this](Instruction* inst) {
bool is_coherent = false;
bool is_volatile = false;
bool src_coherent = false;
bool src_volatile = false;
bool dst_coherent = false;
bool dst_volatile = false;
uint32_t start_operand = 0u;
spv::Scope scope = spv::Scope::QueueFamilyKHR;
spv::Scope src_scope = spv::Scope::QueueFamilyKHR;
spv::Scope dst_scope = spv::Scope::QueueFamilyKHR;
switch (inst->opcode()) {
case spv::Op::OpLoad:
case spv::Op::OpStore:
std::tie(is_coherent, is_volatile, scope) =
GetInstructionAttributes(inst->GetSingleWordInOperand(0u));
break;
case spv::Op::OpImageRead:
case spv::Op::OpImageSparseRead:
case spv::Op::OpImageWrite:
std::tie(is_coherent, is_volatile, scope) =
GetInstructionAttributes(inst->GetSingleWordInOperand(0u));
break;
case spv::Op::OpCopyMemory:
case spv::Op::OpCopyMemorySized:
std::tie(dst_coherent, dst_volatile, dst_scope) =
GetInstructionAttributes(inst->GetSingleWordInOperand(0u));
std::tie(src_coherent, src_volatile, src_scope) =
GetInstructionAttributes(inst->GetSingleWordInOperand(1u));
break;
default:
break;
}
switch (inst->opcode()) {
case spv::Op::OpLoad:
UpgradeFlags(inst, 1u, is_coherent, is_volatile, kVisibility,
kMemory);
break;
case spv::Op::OpStore:
UpgradeFlags(inst, 2u, is_coherent, is_volatile, kAvailability,
kMemory);
break;
case spv::Op::OpCopyMemory:
case spv::Op::OpCopyMemorySized:
start_operand = inst->opcode() == spv::Op::OpCopyMemory ? 2u : 3u;
if (get_module()->version() >= SPV_SPIRV_VERSION_WORD(1, 4)) {
// There are guaranteed to be two memory access operands at this
// point so treat source and target separately.
uint32_t num_access_words = MemoryAccessNumWords(
inst->GetSingleWordInOperand(start_operand));
UpgradeFlags(inst, start_operand, dst_coherent, dst_volatile,
kAvailability, kMemory);
UpgradeFlags(inst, start_operand + num_access_words, src_coherent,
src_volatile, kVisibility, kMemory);
} else {
UpgradeFlags(inst, start_operand, dst_coherent, dst_volatile,
kAvailability, kMemory);
UpgradeFlags(inst, start_operand, src_coherent, src_volatile,
kVisibility, kMemory);
}
break;
case spv::Op::OpImageRead:
case spv::Op::OpImageSparseRead:
UpgradeFlags(inst, 2u, is_coherent, is_volatile, kVisibility, kImage);
break;
case spv::Op::OpImageWrite:
UpgradeFlags(inst, 3u, is_coherent, is_volatile, kAvailability,
kImage);
break;
default:
break;
}
// |is_coherent| is never used for the same instructions as
// |src_coherent| and |dst_coherent|.
if (is_coherent) {
inst->AddOperand(
{SPV_OPERAND_TYPE_SCOPE_ID, {GetScopeConstant(scope)}});
}
if (get_module()->version() >= SPV_SPIRV_VERSION_WORD(1, 4)) {
// There are two memory access operands. The first is for the target and
// the second is for the source.
if (dst_coherent || src_coherent) {
start_operand = inst->opcode() == spv::Op::OpCopyMemory ? 2u : 3u;
std::vector<Operand> new_operands;
uint32_t num_access_words =
MemoryAccessNumWords(inst->GetSingleWordInOperand(start_operand));
// The flags were already updated so subtract if we're adding a
// scope.
if (dst_coherent) --num_access_words;
for (uint32_t i = 0; i < start_operand + num_access_words; ++i) {
new_operands.push_back(inst->GetInOperand(i));
}
// Add the target scope if necessary.
if (dst_coherent) {
new_operands.push_back(
{SPV_OPERAND_TYPE_SCOPE_ID, {GetScopeConstant(dst_scope)}});
}
// Copy the remaining current operands.
for (uint32_t i = start_operand + num_access_words;
i < inst->NumInOperands(); ++i) {
new_operands.push_back(inst->GetInOperand(i));
}
// Add the source scope if necessary.
if (src_coherent) {
new_operands.push_back(
{SPV_OPERAND_TYPE_SCOPE_ID, {GetScopeConstant(src_scope)}});
}
inst->SetInOperands(std::move(new_operands));
}
} else {
// According to SPV_KHR_vulkan_memory_model, if both available and
// visible flags are used the first scope operand is for availability
// (writes) and the second is for visibility (reads).
if (dst_coherent) {
inst->AddOperand(
{SPV_OPERAND_TYPE_SCOPE_ID, {GetScopeConstant(dst_scope)}});
}
if (src_coherent) {
inst->AddOperand(
{SPV_OPERAND_TYPE_SCOPE_ID, {GetScopeConstant(src_scope)}});
}
}
});
}
}
void UpgradeMemoryModel::UpgradeAtomics() {
for (auto& func : *get_module()) {
func.ForEachInst([this](Instruction* inst) {
if (spvOpcodeIsAtomicOp(inst->opcode())) {
bool unused_coherent = false;
bool is_volatile = false;
spv::Scope unused_scope = spv::Scope::QueueFamilyKHR;
std::tie(unused_coherent, is_volatile, unused_scope) =
GetInstructionAttributes(inst->GetSingleWordInOperand(0));
UpgradeSemantics(inst, 2u, is_volatile);
if (inst->opcode() == spv::Op::OpAtomicCompareExchange ||
inst->opcode() == spv::Op::OpAtomicCompareExchangeWeak) {
UpgradeSemantics(inst, 3u, is_volatile);
}
}
});
}
}
void UpgradeMemoryModel::UpgradeSemantics(Instruction* inst,
uint32_t in_operand,
bool is_volatile) {
if (!is_volatile) return;
uint32_t semantics_id = inst->GetSingleWordInOperand(in_operand);
const analysis::Constant* constant =
context()->get_constant_mgr()->FindDeclaredConstant(semantics_id);
const analysis::Integer* type = constant->type()->AsInteger();
assert(type && type->width() == 32);
uint32_t value = 0;
if (type->IsSigned()) {
value = static_cast<uint32_t>(constant->GetS32());
} else {
value = constant->GetU32();
}
value |= uint32_t(spv::MemorySemanticsMask::Volatile);
auto new_constant = context()->get_constant_mgr()->GetConstant(type, {value});
auto new_semantics =
context()->get_constant_mgr()->GetDefiningInstruction(new_constant);
inst->SetInOperand(in_operand, {new_semantics->result_id()});
}
std::tuple<bool, bool, spv::Scope> UpgradeMemoryModel::GetInstructionAttributes(
uint32_t id) {
// |id| is a pointer used in a memory/image instruction. Need to determine if
// that pointer points to volatile or coherent memory. Workgroup storage
// class is implicitly coherent and cannot be decorated with volatile, so
// short circuit that case.
Instruction* inst = context()->get_def_use_mgr()->GetDef(id);
analysis::Type* type = context()->get_type_mgr()->GetType(inst->type_id());
if (type->AsPointer() &&
type->AsPointer()->storage_class() == spv::StorageClass::Workgroup) {
return std::make_tuple(true, false, spv::Scope::Workgroup);
}
bool is_coherent = false;
bool is_volatile = false;
std::unordered_set<uint32_t> visited;
std::tie(is_coherent, is_volatile) =
TraceInstruction(context()->get_def_use_mgr()->GetDef(id),
std::vector<uint32_t>(), &visited);
return std::make_tuple(is_coherent, is_volatile, spv::Scope::QueueFamilyKHR);
}
std::pair<bool, bool> UpgradeMemoryModel::TraceInstruction(
Instruction* inst, std::vector<uint32_t> indices,
std::unordered_set<uint32_t>* visited) {
auto iter = cache_.find(std::make_pair(inst->result_id(), indices));
if (iter != cache_.end()) {
return iter->second;
}
if (!visited->insert(inst->result_id()).second) {
return std::make_pair(false, false);
}
// Initialize the cache before |indices| is (potentially) modified.
auto& cached_result = cache_[std::make_pair(inst->result_id(), indices)];
cached_result.first = false;
cached_result.second = false;
bool is_coherent = false;
bool is_volatile = false;
switch (inst->opcode()) {
case spv::Op::OpVariable:
case spv::Op::OpFunctionParameter:
is_coherent |= HasDecoration(inst, 0, spv::Decoration::Coherent);
is_volatile |= HasDecoration(inst, 0, spv::Decoration::Volatile);
if (!is_coherent || !is_volatile) {
bool type_coherent = false;
bool type_volatile = false;
std::tie(type_coherent, type_volatile) =
CheckType(inst->type_id(), indices);
is_coherent |= type_coherent;
is_volatile |= type_volatile;
}
break;
case spv::Op::OpAccessChain:
case spv::Op::OpInBoundsAccessChain:
// Store indices in reverse order.
for (uint32_t i = inst->NumInOperands() - 1; i > 0; --i) {
indices.push_back(inst->GetSingleWordInOperand(i));
}
break;
case spv::Op::OpPtrAccessChain:
// Store indices in reverse order. Skip the |Element| operand.
for (uint32_t i = inst->NumInOperands() - 1; i > 1; --i) {
indices.push_back(inst->GetSingleWordInOperand(i));
}
break;
default:
break;
}
// No point searching further.
if (is_coherent && is_volatile) {
cached_result.first = true;
cached_result.second = true;
return std::make_pair(true, true);
}
// Variables and function parameters are sources. Continue searching until we
// reach them.
if (inst->opcode() != spv::Op::OpVariable &&
inst->opcode() != spv::Op::OpFunctionParameter) {
inst->ForEachInId([this, &is_coherent, &is_volatile, &indices,
&visited](const uint32_t* id_ptr) {
Instruction* op_inst = context()->get_def_use_mgr()->GetDef(*id_ptr);
const analysis::Type* type =
context()->get_type_mgr()->GetType(op_inst->type_id());
if (type &&
(type->AsPointer() || type->AsImage() || type->AsSampledImage())) {
bool operand_coherent = false;
bool operand_volatile = false;
std::tie(operand_coherent, operand_volatile) =
TraceInstruction(op_inst, indices, visited);
is_coherent |= operand_coherent;
is_volatile |= operand_volatile;
}
});
}
cached_result.first = is_coherent;
cached_result.second = is_volatile;
return std::make_pair(is_coherent, is_volatile);
}
std::pair<bool, bool> UpgradeMemoryModel::CheckType(
uint32_t type_id, const std::vector<uint32_t>& indices) {
bool is_coherent = false;
bool is_volatile = false;
Instruction* type_inst = context()->get_def_use_mgr()->GetDef(type_id);
assert(type_inst->opcode() == spv::Op::OpTypePointer);
Instruction* element_inst = context()->get_def_use_mgr()->GetDef(
type_inst->GetSingleWordInOperand(1u));
for (int i = (int)indices.size() - 1; i >= 0; --i) {
if (is_coherent && is_volatile) break;
if (element_inst->opcode() == spv::Op::OpTypePointer) {
element_inst = context()->get_def_use_mgr()->GetDef(
element_inst->GetSingleWordInOperand(1u));
} else if (element_inst->opcode() == spv::Op::OpTypeStruct) {
uint32_t index = indices.at(i);
Instruction* index_inst = context()->get_def_use_mgr()->GetDef(index);
assert(index_inst->opcode() == spv::Op::OpConstant);
uint64_t value = GetIndexValue(index_inst);
is_coherent |= HasDecoration(element_inst, static_cast<uint32_t>(value),
spv::Decoration::Coherent);
is_volatile |= HasDecoration(element_inst, static_cast<uint32_t>(value),
spv::Decoration::Volatile);
element_inst = context()->get_def_use_mgr()->GetDef(
element_inst->GetSingleWordInOperand(static_cast<uint32_t>(value)));
} else {
assert(spvOpcodeIsComposite(element_inst->opcode()));
element_inst = context()->get_def_use_mgr()->GetDef(
element_inst->GetSingleWordInOperand(0u));
}
}
if (!is_coherent || !is_volatile) {
bool remaining_coherent = false;
bool remaining_volatile = false;
std::tie(remaining_coherent, remaining_volatile) =
CheckAllTypes(element_inst);
is_coherent |= remaining_coherent;
is_volatile |= remaining_volatile;
}
return std::make_pair(is_coherent, is_volatile);
}
std::pair<bool, bool> UpgradeMemoryModel::CheckAllTypes(
const Instruction* inst) {
std::unordered_set<const Instruction*> visited;
std::vector<const Instruction*> stack;
stack.push_back(inst);
bool is_coherent = false;
bool is_volatile = false;
while (!stack.empty()) {
const Instruction* def = stack.back();
stack.pop_back();
if (!visited.insert(def).second) continue;
if (def->opcode() == spv::Op::OpTypeStruct) {
// Any member decorated with coherent and/or volatile is enough to have
// the related operation be flagged as coherent and/or volatile.
is_coherent |= HasDecoration(def, std::numeric_limits<uint32_t>::max(),
spv::Decoration::Coherent);
is_volatile |= HasDecoration(def, std::numeric_limits<uint32_t>::max(),
spv::Decoration::Volatile);
if (is_coherent && is_volatile)
return std::make_pair(is_coherent, is_volatile);
// Check the subtypes.
for (uint32_t i = 0; i < def->NumInOperands(); ++i) {
stack.push_back(context()->get_def_use_mgr()->GetDef(
def->GetSingleWordInOperand(i)));
}
} else if (spvOpcodeIsComposite(def->opcode())) {
stack.push_back(context()->get_def_use_mgr()->GetDef(
def->GetSingleWordInOperand(0u)));
} else if (def->opcode() == spv::Op::OpTypePointer) {
stack.push_back(context()->get_def_use_mgr()->GetDef(
def->GetSingleWordInOperand(1u)));
}
}
return std::make_pair(is_coherent, is_volatile);
}
uint64_t UpgradeMemoryModel::GetIndexValue(Instruction* index_inst) {
const analysis::Constant* index_constant =
context()->get_constant_mgr()->GetConstantFromInst(index_inst);
assert(index_constant->AsIntConstant());
if (index_constant->type()->AsInteger()->IsSigned()) {
if (index_constant->type()->AsInteger()->width() == 32) {
return index_constant->GetS32();
} else {
return index_constant->GetS64();
}
} else {
if (index_constant->type()->AsInteger()->width() == 32) {
return index_constant->GetU32();
} else {
return index_constant->GetU64();
}
}
}
bool UpgradeMemoryModel::HasDecoration(const Instruction* inst, uint32_t value,
spv::Decoration decoration) {
// If the iteration was terminated early then an appropriate decoration was
// found.
return !context()->get_decoration_mgr()->WhileEachDecoration(
inst->result_id(), (uint32_t)decoration, [value](const Instruction& i) {
if (i.opcode() == spv::Op::OpDecorate ||
i.opcode() == spv::Op::OpDecorateId) {
return false;
} else if (i.opcode() == spv::Op::OpMemberDecorate) {
if (value == i.GetSingleWordInOperand(1u) ||
value == std::numeric_limits<uint32_t>::max())
return false;
}
return true;
});
}
void UpgradeMemoryModel::UpgradeFlags(Instruction* inst, uint32_t in_operand,
bool is_coherent, bool is_volatile,
OperationType operation_type,
InstructionType inst_type) {
if (!is_coherent && !is_volatile) return;
uint32_t flags = 0;
if (inst->NumInOperands() > in_operand) {
flags |= inst->GetSingleWordInOperand(in_operand);
}
if (is_coherent) {
if (inst_type == kMemory) {
flags |= uint32_t(spv::MemoryAccessMask::NonPrivatePointerKHR);
if (operation_type == kVisibility) {
flags |= uint32_t(spv::MemoryAccessMask::MakePointerVisibleKHR);
} else {
flags |= uint32_t(spv::MemoryAccessMask::MakePointerAvailableKHR);
}
} else {
flags |= uint32_t(spv::ImageOperandsMask::NonPrivateTexelKHR);
if (operation_type == kVisibility) {
flags |= uint32_t(spv::ImageOperandsMask::MakeTexelVisibleKHR);
} else {
flags |= uint32_t(spv::ImageOperandsMask::MakeTexelAvailableKHR);
}
}
}
if (is_volatile) {
if (inst_type == kMemory) {
flags |= uint32_t(spv::MemoryAccessMask::Volatile);
} else {
flags |= uint32_t(spv::ImageOperandsMask::VolatileTexelKHR);
}
}
if (inst->NumInOperands() > in_operand) {
inst->SetInOperand(in_operand, {flags});
} else if (inst_type == kMemory) {
inst->AddOperand({SPV_OPERAND_TYPE_OPTIONAL_MEMORY_ACCESS, {flags}});
} else {
inst->AddOperand({SPV_OPERAND_TYPE_OPTIONAL_IMAGE, {flags}});
}
}
uint32_t UpgradeMemoryModel::GetScopeConstant(spv::Scope scope) {
analysis::Integer int_ty(32, false);
uint32_t int_id = context()->get_type_mgr()->GetTypeInstruction(&int_ty);
const analysis::Constant* constant =
context()->get_constant_mgr()->GetConstant(
context()->get_type_mgr()->GetType(int_id),
{static_cast<uint32_t>(scope)});
return context()
->get_constant_mgr()
->GetDefiningInstruction(constant)
->result_id();
}
void UpgradeMemoryModel::CleanupDecorations() {
// All of the volatile and coherent decorations have been dealt with, so now
// we can just remove them.
get_module()->ForEachInst([this](Instruction* inst) {
if (inst->result_id() != 0) {
context()->get_decoration_mgr()->RemoveDecorationsFrom(
inst->result_id(), [](const Instruction& dec) {
switch (dec.opcode()) {
case spv::Op::OpDecorate:
case spv::Op::OpDecorateId:
if (spv::Decoration(dec.GetSingleWordInOperand(1u)) ==
spv::Decoration::Coherent ||
spv::Decoration(dec.GetSingleWordInOperand(1u)) ==
spv::Decoration::Volatile)
return true;
break;
case spv::Op::OpMemberDecorate:
if (spv::Decoration(dec.GetSingleWordInOperand(2u)) ==
spv::Decoration::Coherent ||
spv::Decoration(dec.GetSingleWordInOperand(2u)) ==
spv::Decoration::Volatile)
return true;
break;
default:
break;
}
return false;
});
}
});
}
void UpgradeMemoryModel::UpgradeBarriers() {
std::vector<Instruction*> barriers;
// Collects all the control barriers in |function|. Returns true if the
// function operates on the Output storage class.
ProcessFunction CollectBarriers = [this, &barriers](Function* function) {
bool operates_on_output = false;
for (auto& block : *function) {
block.ForEachInst([this, &barriers,
&operates_on_output](Instruction* inst) {
if (inst->opcode() == spv::Op::OpControlBarrier) {
barriers.push_back(inst);
} else if (!operates_on_output) {
// This instruction operates on output storage class if it is a
// pointer to output type or any input operand is a pointer to output
// type.
analysis::Type* type =
context()->get_type_mgr()->GetType(inst->type_id());
if (type && type->AsPointer() &&
type->AsPointer()->storage_class() == spv::StorageClass::Output) {
operates_on_output = true;
return;
}
inst->ForEachInId([this, &operates_on_output](uint32_t* id_ptr) {
Instruction* op_inst =
context()->get_def_use_mgr()->GetDef(*id_ptr);
analysis::Type* op_type =
context()->get_type_mgr()->GetType(op_inst->type_id());
if (op_type && op_type->AsPointer() &&
op_type->AsPointer()->storage_class() ==
spv::StorageClass::Output)
operates_on_output = true;
});
}
});
}
return operates_on_output;
};
std::queue<uint32_t> roots;
for (auto& e : get_module()->entry_points())
if (spv::ExecutionModel(e.GetSingleWordInOperand(0u)) ==
spv::ExecutionModel::TessellationControl) {
roots.push(e.GetSingleWordInOperand(1u));
if (context()->ProcessCallTreeFromRoots(CollectBarriers, &roots)) {
for (auto barrier : barriers) {
// Add OutputMemoryKHR to the semantics of the barriers.
uint32_t semantics_id = barrier->GetSingleWordInOperand(2u);
Instruction* semantics_inst =
context()->get_def_use_mgr()->GetDef(semantics_id);
analysis::Type* semantics_type =
context()->get_type_mgr()->GetType(semantics_inst->type_id());
uint64_t semantics_value = GetIndexValue(semantics_inst);
const analysis::Constant* constant =
context()->get_constant_mgr()->GetConstant(
semantics_type,
{static_cast<uint32_t>(semantics_value) |
uint32_t(spv::MemorySemanticsMask::OutputMemoryKHR)});
barrier->SetInOperand(2u, {context()
->get_constant_mgr()
->GetDefiningInstruction(constant)
->result_id()});
}
}
barriers.clear();
}
}
void UpgradeMemoryModel::UpgradeMemoryScope() {
get_module()->ForEachInst([this](Instruction* inst) {
// Don't need to handle all the operations that take a scope.
// * Group operations can only be subgroup
// * Non-uniform can only be workgroup or subgroup
// * Named barriers are not supported by Vulkan
// * Workgroup ops (e.g. async_copy) have at most workgroup scope.
if (spvOpcodeIsAtomicOp(inst->opcode())) {
if (IsDeviceScope(inst->GetSingleWordInOperand(1))) {
inst->SetInOperand(1, {GetScopeConstant(spv::Scope::QueueFamilyKHR)});
}
} else if (inst->opcode() == spv::Op::OpControlBarrier) {
if (IsDeviceScope(inst->GetSingleWordInOperand(1))) {
inst->SetInOperand(1, {GetScopeConstant(spv::Scope::QueueFamilyKHR)});
}
} else if (inst->opcode() == spv::Op::OpMemoryBarrier) {
if (IsDeviceScope(inst->GetSingleWordInOperand(0))) {
inst->SetInOperand(0, {GetScopeConstant(spv::Scope::QueueFamilyKHR)});
}
}
});
}
bool UpgradeMemoryModel::IsDeviceScope(uint32_t scope_id) {
const analysis::Constant* constant =
context()->get_constant_mgr()->FindDeclaredConstant(scope_id);
assert(constant && "Memory scope must be a constant");
const analysis::Integer* type = constant->type()->AsInteger();
assert(type);
assert(type->width() == 32 || type->width() == 64);
if (type->width() == 32) {
if (type->IsSigned())
return static_cast<spv::Scope>(constant->GetS32()) == spv::Scope::Device;
else
return static_cast<spv::Scope>(constant->GetU32()) == spv::Scope::Device;
} else {
if (type->IsSigned())
return static_cast<spv::Scope>(constant->GetS64()) == spv::Scope::Device;
else
return static_cast<spv::Scope>(constant->GetU64()) == spv::Scope::Device;
}
assert(false);
return false;
}
void UpgradeMemoryModel::UpgradeExtInst(Instruction* ext_inst) {
const bool is_modf = ext_inst->GetSingleWordInOperand(1u) == GLSLstd450Modf;
auto ptr_id = ext_inst->GetSingleWordInOperand(3u);
auto ptr_type_id = get_def_use_mgr()->GetDef(ptr_id)->type_id();
auto pointee_type_id =
get_def_use_mgr()->GetDef(ptr_type_id)->GetSingleWordInOperand(1u);
auto element_type_id = ext_inst->type_id();
std::vector<const analysis::Type*> element_types(2);
element_types[0] = context()->get_type_mgr()->GetType(element_type_id);
element_types[1] = context()->get_type_mgr()->GetType(pointee_type_id);
analysis::Struct struct_type(element_types);
uint32_t struct_id =
context()->get_type_mgr()->GetTypeInstruction(&struct_type);
// Change the operation
GLSLstd450 new_op = is_modf ? GLSLstd450ModfStruct : GLSLstd450FrexpStruct;
ext_inst->SetOperand(3u, {static_cast<uint32_t>(new_op)});
// Remove the pointer argument
ext_inst->RemoveOperand(5u);
// Set the type id to the new struct.
ext_inst->SetResultType(struct_id);
// The result is now a struct of the original result. The zero'th element is
// old result and should replace the old result. The one'th element needs to
// be stored via a new instruction.
auto where = ext_inst->NextNode();
InstructionBuilder builder(
context(), where,
IRContext::kAnalysisDefUse | IRContext::kAnalysisInstrToBlockMapping);
auto extract_0 =
builder.AddCompositeExtract(element_type_id, ext_inst->result_id(), {0});
context()->ReplaceAllUsesWith(ext_inst->result_id(), extract_0->result_id());
// The extract's input was just changed to itself, so fix that.
extract_0->SetInOperand(0u, {ext_inst->result_id()});
auto extract_1 =
builder.AddCompositeExtract(pointee_type_id, ext_inst->result_id(), {1});
builder.AddStore(ptr_id, extract_1->result_id());
}
uint32_t UpgradeMemoryModel::MemoryAccessNumWords(uint32_t mask) {
uint32_t result = 1;
if (mask & uint32_t(spv::MemoryAccessMask::Aligned)) ++result;
if (mask & uint32_t(spv::MemoryAccessMask::MakePointerAvailableKHR)) ++result;
if (mask & uint32_t(spv::MemoryAccessMask::MakePointerVisibleKHR)) ++result;
return result;
}
} // namespace opt
} // namespace spvtools