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// Copyright (c) 2019 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 "source/fuzz/fuzzer_util.h"
#include <algorithm>
#include <unordered_set>
#include "source/opt/build_module.h"
namespace spvtools {
namespace fuzz {
namespace fuzzerutil {
namespace {
uint32_t MaybeGetOpConstant(opt::IRContext* ir_context,
const TransformationContext& transformation_context,
const std::vector<uint32_t>& words,
uint32_t type_id, bool is_irrelevant) {
for (const auto& inst : ir_context->types_values()) {
if (inst.opcode() == SpvOpConstant && inst.type_id() == type_id &&
inst.GetInOperand(0).words == words &&
transformation_context.GetFactManager()->IdIsIrrelevant(
inst.result_id()) == is_irrelevant) {
return inst.result_id();
}
}
return 0;
}
} // namespace
const spvtools::MessageConsumer kSilentMessageConsumer =
[](spv_message_level_t, const char*, const spv_position_t&,
const char*) -> void {};
bool IsFreshId(opt::IRContext* context, uint32_t id) {
return !context->get_def_use_mgr()->GetDef(id);
}
void UpdateModuleIdBound(opt::IRContext* context, uint32_t id) {
// TODO(https://github.com/KhronosGroup/SPIRV-Tools/issues/2541) consider the
// case where the maximum id bound is reached.
context->module()->SetIdBound(
std::max(context->module()->id_bound(), id + 1));
}
opt::BasicBlock* MaybeFindBlock(opt::IRContext* context,
uint32_t maybe_block_id) {
auto inst = context->get_def_use_mgr()->GetDef(maybe_block_id);
if (inst == nullptr) {
// No instruction defining this id was found.
return nullptr;
}
if (inst->opcode() != SpvOpLabel) {
// The instruction defining the id is not a label, so it cannot be a block
// id.
return nullptr;
}
return context->cfg()->block(maybe_block_id);
}
bool PhiIdsOkForNewEdge(
opt::IRContext* context, opt::BasicBlock* bb_from, opt::BasicBlock* bb_to,
const google::protobuf::RepeatedField<google::protobuf::uint32>& phi_ids) {
if (bb_from->IsSuccessor(bb_to)) {
// There is already an edge from |from_block| to |to_block|, so there is
// no need to extend OpPhi instructions. Do not allow phi ids to be
// present. This might turn out to be too strict; perhaps it would be OK
// just to ignore the ids in this case.
return phi_ids.empty();
}
// The edge would add a previously non-existent edge from |from_block| to
// |to_block|, so we go through the given phi ids and check that they exactly
// match the OpPhi instructions in |to_block|.
uint32_t phi_index = 0;
// An explicit loop, rather than applying a lambda to each OpPhi in |bb_to|,
// makes sense here because we need to increment |phi_index| for each OpPhi
// instruction.
for (auto& inst : *bb_to) {
if (inst.opcode() != SpvOpPhi) {
// The OpPhi instructions all occur at the start of the block; if we find
// a non-OpPhi then we have seen them all.
break;
}
if (phi_index == static_cast<uint32_t>(phi_ids.size())) {
// Not enough phi ids have been provided to account for the OpPhi
// instructions.
return false;
}
// Look for an instruction defining the next phi id.
opt::Instruction* phi_extension =
context->get_def_use_mgr()->GetDef(phi_ids[phi_index]);
if (!phi_extension) {
// The id given to extend this OpPhi does not exist.
return false;
}
if (phi_extension->type_id() != inst.type_id()) {
// The instruction given to extend this OpPhi either does not have a type
// or its type does not match that of the OpPhi.
return false;
}
if (context->get_instr_block(phi_extension)) {
// The instruction defining the phi id has an associated block (i.e., it
// is not a global value). Check whether its definition dominates the
// exit of |from_block|.
auto dominator_analysis =
context->GetDominatorAnalysis(bb_from->GetParent());
if (!dominator_analysis->Dominates(phi_extension,
bb_from->terminator())) {
// The given id is no good as its definition does not dominate the exit
// of |from_block|
return false;
}
}
phi_index++;
}
// We allow some of the ids provided for extending OpPhi instructions to be
// unused. Their presence does no harm, and requiring a perfect match may
// make transformations less likely to cleanly apply.
return true;
}
void AddUnreachableEdgeAndUpdateOpPhis(
opt::IRContext* context, opt::BasicBlock* bb_from, opt::BasicBlock* bb_to,
uint32_t bool_id,
const google::protobuf::RepeatedField<google::protobuf::uint32>& phi_ids) {
assert(PhiIdsOkForNewEdge(context, bb_from, bb_to, phi_ids) &&
"Precondition on phi_ids is not satisfied");
assert(bb_from->terminator()->opcode() == SpvOpBranch &&
"Precondition on terminator of bb_from is not satisfied");
// Get the id of the boolean constant to be used as the condition.
auto condition_inst = context->get_def_use_mgr()->GetDef(bool_id);
assert(condition_inst &&
(condition_inst->opcode() == SpvOpConstantTrue ||
condition_inst->opcode() == SpvOpConstantFalse) &&
"|bool_id| is invalid");
auto condition_value = condition_inst->opcode() == SpvOpConstantTrue;
const bool from_to_edge_already_exists = bb_from->IsSuccessor(bb_to);
auto successor = bb_from->terminator()->GetSingleWordInOperand(0);
// Add the dead branch, by turning OpBranch into OpBranchConditional, and
// ordering the targets depending on whether the given boolean corresponds to
// true or false.
bb_from->terminator()->SetOpcode(SpvOpBranchConditional);
bb_from->terminator()->SetInOperands(
{{SPV_OPERAND_TYPE_ID, {bool_id}},
{SPV_OPERAND_TYPE_ID, {condition_value ? successor : bb_to->id()}},
{SPV_OPERAND_TYPE_ID, {condition_value ? bb_to->id() : successor}}});
// Update OpPhi instructions in the target block if this branch adds a
// previously non-existent edge from source to target.
if (!from_to_edge_already_exists) {
uint32_t phi_index = 0;
for (auto& inst : *bb_to) {
if (inst.opcode() != SpvOpPhi) {
break;
}
assert(phi_index < static_cast<uint32_t>(phi_ids.size()) &&
"There should be at least one phi id per OpPhi instruction.");
inst.AddOperand({SPV_OPERAND_TYPE_ID, {phi_ids[phi_index]}});
inst.AddOperand({SPV_OPERAND_TYPE_ID, {bb_from->id()}});
phi_index++;
}
}
}
bool BlockIsBackEdge(opt::IRContext* context, uint32_t block_id,
uint32_t loop_header_id) {
auto block = context->cfg()->block(block_id);
auto loop_header = context->cfg()->block(loop_header_id);
// |block| and |loop_header| must be defined, |loop_header| must be in fact
// loop header and |block| must branch to it.
if (!(block && loop_header && loop_header->IsLoopHeader() &&
block->IsSuccessor(loop_header))) {
return false;
}
// |block_id| must be reachable and be dominated by |loop_header|.
opt::DominatorAnalysis* dominator_analysis =
context->GetDominatorAnalysis(loop_header->GetParent());
return dominator_analysis->IsReachable(block_id) &&
dominator_analysis->Dominates(loop_header_id, block_id);
}
bool BlockIsInLoopContinueConstruct(opt::IRContext* context, uint32_t block_id,
uint32_t maybe_loop_header_id) {
// We deem a block to be part of a loop's continue construct if the loop's
// continue target dominates the block.
auto containing_construct_block = context->cfg()->block(maybe_loop_header_id);
if (containing_construct_block->IsLoopHeader()) {
auto continue_target = containing_construct_block->ContinueBlockId();
if (context->GetDominatorAnalysis(containing_construct_block->GetParent())
->Dominates(continue_target, block_id)) {
return true;
}
}
return false;
}
opt::BasicBlock::iterator GetIteratorForInstruction(
opt::BasicBlock* block, const opt::Instruction* inst) {
for (auto inst_it = block->begin(); inst_it != block->end(); ++inst_it) {
if (inst == &*inst_it) {
return inst_it;
}
}
return block->end();
}
bool BlockIsReachableInItsFunction(opt::IRContext* context,
opt::BasicBlock* bb) {
auto enclosing_function = bb->GetParent();
return context->GetDominatorAnalysis(enclosing_function)
->Dominates(enclosing_function->entry().get(), bb);
}
bool CanInsertOpcodeBeforeInstruction(
SpvOp opcode, const opt::BasicBlock::iterator& instruction_in_block) {
if (instruction_in_block->PreviousNode() &&
(instruction_in_block->PreviousNode()->opcode() == SpvOpLoopMerge ||
instruction_in_block->PreviousNode()->opcode() == SpvOpSelectionMerge)) {
// We cannot insert directly after a merge instruction.
return false;
}
if (opcode != SpvOpVariable &&
instruction_in_block->opcode() == SpvOpVariable) {
// We cannot insert a non-OpVariable instruction directly before a
// variable; variables in a function must be contiguous in the entry block.
return false;
}
// We cannot insert a non-OpPhi instruction directly before an OpPhi, because
// OpPhi instructions need to be contiguous at the start of a block.
return opcode == SpvOpPhi || instruction_in_block->opcode() != SpvOpPhi;
}
bool CanMakeSynonymOf(opt::IRContext* ir_context,
const TransformationContext& transformation_context,
opt::Instruction* inst) {
if (inst->opcode() == SpvOpSampledImage) {
// The SPIR-V data rules say that only very specific instructions may
// may consume the result id of an OpSampledImage, and this excludes the
// instructions that are used for making synonyms.
return false;
}
if (!inst->HasResultId()) {
// We can only make a synonym of an instruction that generates an id.
return false;
}
if (transformation_context.GetFactManager()->IdIsIrrelevant(
inst->result_id())) {
// An irrelevant id can't be a synonym of anything.
return false;
}
if (!inst->type_id()) {
// We can only make a synonym of an instruction that has a type.
return false;
}
auto type_inst = ir_context->get_def_use_mgr()->GetDef(inst->type_id());
if (type_inst->opcode() == SpvOpTypeVoid) {
// We only make synonyms of instructions that define objects, and an object
// cannot have void type.
return false;
}
if (type_inst->opcode() == SpvOpTypePointer) {
switch (inst->opcode()) {
case SpvOpConstantNull:
case SpvOpUndef:
// We disallow making synonyms of null or undefined pointers. This is
// to provide the property that if the original shader exhibited no bad
// pointer accesses, the transformed shader will not either.
return false;
default:
break;
}
}
// We do not make synonyms of objects that have decorations: if the synonym is
// not decorated analogously, using the original object vs. its synonymous
// form may not be equivalent.
return ir_context->get_decoration_mgr()
->GetDecorationsFor(inst->result_id(), true)
.empty();
}
bool IsCompositeType(const opt::analysis::Type* type) {
return type && (type->AsArray() || type->AsMatrix() || type->AsStruct() ||
type->AsVector());
}
std::vector<uint32_t> RepeatedFieldToVector(
const google::protobuf::RepeatedField<uint32_t>& repeated_field) {
std::vector<uint32_t> result;
for (auto i : repeated_field) {
result.push_back(i);
}
return result;
}
uint32_t WalkOneCompositeTypeIndex(opt::IRContext* context,
uint32_t base_object_type_id,
uint32_t index) {
auto should_be_composite_type =
context->get_def_use_mgr()->GetDef(base_object_type_id);
assert(should_be_composite_type && "The type should exist.");
switch (should_be_composite_type->opcode()) {
case SpvOpTypeArray: {
auto array_length = GetArraySize(*should_be_composite_type, context);
if (array_length == 0 || index >= array_length) {
return 0;
}
return should_be_composite_type->GetSingleWordInOperand(0);
}
case SpvOpTypeMatrix:
case SpvOpTypeVector: {
auto count = should_be_composite_type->GetSingleWordInOperand(1);
if (index >= count) {
return 0;
}
return should_be_composite_type->GetSingleWordInOperand(0);
}
case SpvOpTypeStruct: {
if (index >= GetNumberOfStructMembers(*should_be_composite_type)) {
return 0;
}
return should_be_composite_type->GetSingleWordInOperand(index);
}
default:
return 0;
}
}
uint32_t WalkCompositeTypeIndices(
opt::IRContext* context, uint32_t base_object_type_id,
const google::protobuf::RepeatedField<google::protobuf::uint32>& indices) {
uint32_t sub_object_type_id = base_object_type_id;
for (auto index : indices) {
sub_object_type_id =
WalkOneCompositeTypeIndex(context, sub_object_type_id, index);
if (!sub_object_type_id) {
return 0;
}
}
return sub_object_type_id;
}
uint32_t GetNumberOfStructMembers(
const opt::Instruction& struct_type_instruction) {
assert(struct_type_instruction.opcode() == SpvOpTypeStruct &&
"An OpTypeStruct instruction is required here.");
return struct_type_instruction.NumInOperands();
}
uint32_t GetArraySize(const opt::Instruction& array_type_instruction,
opt::IRContext* context) {
auto array_length_constant =
context->get_constant_mgr()
->GetConstantFromInst(context->get_def_use_mgr()->GetDef(
array_type_instruction.GetSingleWordInOperand(1)))
->AsIntConstant();
if (array_length_constant->words().size() != 1) {
return 0;
}
return array_length_constant->GetU32();
}
uint32_t GetBoundForCompositeIndex(const opt::Instruction& composite_type_inst,
opt::IRContext* ir_context) {
switch (composite_type_inst.opcode()) {
case SpvOpTypeArray:
return fuzzerutil::GetArraySize(composite_type_inst, ir_context);
case SpvOpTypeMatrix:
case SpvOpTypeVector:
return composite_type_inst.GetSingleWordInOperand(1);
case SpvOpTypeStruct: {
return fuzzerutil::GetNumberOfStructMembers(composite_type_inst);
}
case SpvOpTypeRuntimeArray:
assert(false &&
"GetBoundForCompositeIndex should not be invoked with an "
"OpTypeRuntimeArray, which does not have a static bound.");
return 0;
default:
assert(false && "Unknown composite type.");
return 0;
}
}
bool IsValid(const opt::IRContext* context,
spv_validator_options validator_options,
MessageConsumer consumer) {
std::vector<uint32_t> binary;
context->module()->ToBinary(&binary, false);
SpirvTools tools(context->grammar().target_env());
tools.SetMessageConsumer(consumer);
return tools.Validate(binary.data(), binary.size(), validator_options);
}
bool IsValidAndWellFormed(const opt::IRContext* ir_context,
spv_validator_options validator_options,
MessageConsumer consumer) {
if (!IsValid(ir_context, validator_options, consumer)) {
// Expression to dump |ir_context| to /data/temp/shader.spv:
// DumpShader(ir_context, "/data/temp/shader.spv")
consumer(SPV_MSG_INFO, nullptr, {},
"Module is invalid (set a breakpoint to inspect).");
return false;
}
// Check that all blocks in the module have appropriate parent functions.
for (auto& function : *ir_context->module()) {
for (auto& block : function) {
if (block.GetParent() == nullptr) {
std::stringstream ss;
ss << "Block " << block.id() << " has no parent; its parent should be "
<< function.result_id() << " (set a breakpoint to inspect).";
consumer(SPV_MSG_INFO, nullptr, {}, ss.str().c_str());
return false;
}
if (block.GetParent() != &function) {
std::stringstream ss;
ss << "Block " << block.id() << " should have parent "
<< function.result_id() << " but instead has parent "
<< block.GetParent() << " (set a breakpoint to inspect).";
consumer(SPV_MSG_INFO, nullptr, {}, ss.str().c_str());
return false;
}
}
}
// Check that all instructions have distinct unique ids. We map each unique
// id to the first instruction it is observed to be associated with so that
// if we encounter a duplicate we have access to the previous instruction -
// this is a useful aid to debugging.
std::unordered_map<uint32_t, opt::Instruction*> unique_ids;
bool found_duplicate = false;
ir_context->module()->ForEachInst([&consumer, &found_duplicate,
&unique_ids](opt::Instruction* inst) {
if (unique_ids.count(inst->unique_id()) != 0) {
consumer(SPV_MSG_INFO, nullptr, {},
"Two instructions have the same unique id (set a breakpoint to "
"inspect).");
found_duplicate = true;
}
unique_ids.insert({inst->unique_id(), inst});
});
return !found_duplicate;
}
std::unique_ptr<opt::IRContext> CloneIRContext(opt::IRContext* context) {
std::vector<uint32_t> binary;
context->module()->ToBinary(&binary, false);
return BuildModule(context->grammar().target_env(), nullptr, binary.data(),
binary.size());
}
bool IsNonFunctionTypeId(opt::IRContext* ir_context, uint32_t id) {
auto type = ir_context->get_type_mgr()->GetType(id);
return type && !type->AsFunction();
}
bool IsMergeOrContinue(opt::IRContext* ir_context, uint32_t block_id) {
bool result = false;
ir_context->get_def_use_mgr()->WhileEachUse(
block_id,
[&result](const opt::Instruction* use_instruction,
uint32_t /*unused*/) -> bool {
switch (use_instruction->opcode()) {
case SpvOpLoopMerge:
case SpvOpSelectionMerge:
result = true;
return false;
default:
return true;
}
});
return result;
}
uint32_t GetLoopFromMergeBlock(opt::IRContext* ir_context,
uint32_t merge_block_id) {
uint32_t result = 0;
ir_context->get_def_use_mgr()->WhileEachUse(
merge_block_id,
[ir_context, &result](opt::Instruction* use_instruction,
uint32_t use_index) -> bool {
switch (use_instruction->opcode()) {
case SpvOpLoopMerge:
// The merge block operand is the first operand in OpLoopMerge.
if (use_index == 0) {
result = ir_context->get_instr_block(use_instruction)->id();
return false;
}
return true;
default:
return true;
}
});
return result;
}
uint32_t FindFunctionType(opt::IRContext* ir_context,
const std::vector<uint32_t>& type_ids) {
// Look through the existing types for a match.
for (auto& type_or_value : ir_context->types_values()) {
if (type_or_value.opcode() != SpvOpTypeFunction) {
// We are only interested in function types.
continue;
}
if (type_or_value.NumInOperands() != type_ids.size()) {
// Not a match: different numbers of arguments.
continue;
}
// Check whether the return type and argument types match.
bool input_operands_match = true;
for (uint32_t i = 0; i < type_or_value.NumInOperands(); i++) {
if (type_ids[i] != type_or_value.GetSingleWordInOperand(i)) {
input_operands_match = false;
break;
}
}
if (input_operands_match) {
// Everything matches.
return type_or_value.result_id();
}
}
// No match was found.
return 0;
}
opt::Instruction* GetFunctionType(opt::IRContext* context,
const opt::Function* function) {
uint32_t type_id = function->DefInst().GetSingleWordInOperand(1);
return context->get_def_use_mgr()->GetDef(type_id);
}
opt::Function* FindFunction(opt::IRContext* ir_context, uint32_t function_id) {
for (auto& function : *ir_context->module()) {
if (function.result_id() == function_id) {
return &function;
}
}
return nullptr;
}
bool FunctionContainsOpKillOrUnreachable(const opt::Function& function) {
for (auto& block : function) {
if (block.terminator()->opcode() == SpvOpKill ||
block.terminator()->opcode() == SpvOpUnreachable) {
return true;
}
}
return false;
}
bool FunctionIsEntryPoint(opt::IRContext* context, uint32_t function_id) {
for (auto& entry_point : context->module()->entry_points()) {
if (entry_point.GetSingleWordInOperand(1) == function_id) {
return true;
}
}
return false;
}
bool IdIsAvailableAtUse(opt::IRContext* context,
opt::Instruction* use_instruction,
uint32_t use_input_operand_index, uint32_t id) {
assert(context->get_instr_block(use_instruction) &&
"|use_instruction| must be in a basic block");
auto defining_instruction = context->get_def_use_mgr()->GetDef(id);
auto enclosing_function =
context->get_instr_block(use_instruction)->GetParent();
// If the id a function parameter, it needs to be associated with the
// function containing the use.
if (defining_instruction->opcode() == SpvOpFunctionParameter) {
return InstructionIsFunctionParameter(defining_instruction,
enclosing_function);
}
if (!context->get_instr_block(id)) {
// The id must be at global scope.
return true;
}
if (defining_instruction == use_instruction) {
// It is not OK for a definition to use itself.
return false;
}
auto dominator_analysis = context->GetDominatorAnalysis(enclosing_function);
if (!dominator_analysis->IsReachable(
context->get_instr_block(use_instruction)) ||
!dominator_analysis->IsReachable(context->get_instr_block(id))) {
// Skip unreachable blocks.
return false;
}
if (use_instruction->opcode() == SpvOpPhi) {
// In the case where the use is an operand to OpPhi, it is actually the
// *parent* block associated with the operand that must be dominated by
// the synonym.
auto parent_block =
use_instruction->GetSingleWordInOperand(use_input_operand_index + 1);
return dominator_analysis->Dominates(
context->get_instr_block(defining_instruction)->id(), parent_block);
}
return dominator_analysis->Dominates(defining_instruction, use_instruction);
}
bool IdIsAvailableBeforeInstruction(opt::IRContext* context,
opt::Instruction* instruction,
uint32_t id) {
assert(context->get_instr_block(instruction) &&
"|instruction| must be in a basic block");
auto id_definition = context->get_def_use_mgr()->GetDef(id);
auto function_enclosing_instruction =
context->get_instr_block(instruction)->GetParent();
// If the id a function parameter, it needs to be associated with the
// function containing the instruction.
if (id_definition->opcode() == SpvOpFunctionParameter) {
return InstructionIsFunctionParameter(id_definition,
function_enclosing_instruction);
}
if (!context->get_instr_block(id)) {
// The id is at global scope.
return true;
}
if (id_definition == instruction) {
// The instruction is not available right before its own definition.
return false;
}
const auto* dominator_analysis =
context->GetDominatorAnalysis(function_enclosing_instruction);
if (dominator_analysis->IsReachable(context->get_instr_block(instruction)) &&
dominator_analysis->IsReachable(context->get_instr_block(id)) &&
dominator_analysis->Dominates(id_definition, instruction)) {
// The id's definition dominates the instruction, and both the definition
// and the instruction are in reachable blocks, thus the id is available at
// the instruction.
return true;
}
if (id_definition->opcode() == SpvOpVariable &&
function_enclosing_instruction ==
context->get_instr_block(id)->GetParent()) {
assert(!dominator_analysis->IsReachable(
context->get_instr_block(instruction)) &&
"If the instruction were in a reachable block we should already "
"have returned true.");
// The id is a variable and it is in the same function as |instruction|.
// This is OK despite |instruction| being unreachable.
return true;
}
return false;
}
bool InstructionIsFunctionParameter(opt::Instruction* instruction,
opt::Function* function) {
if (instruction->opcode() != SpvOpFunctionParameter) {
return false;
}
bool found_parameter = false;
function->ForEachParam(
[instruction, &found_parameter](opt::Instruction* param) {
if (param == instruction) {
found_parameter = true;
}
});
return found_parameter;
}
uint32_t GetTypeId(opt::IRContext* context, uint32_t result_id) {
const auto* inst = context->get_def_use_mgr()->GetDef(result_id);
assert(inst && "|result_id| is invalid");
return inst->type_id();
}
uint32_t GetPointeeTypeIdFromPointerType(opt::Instruction* pointer_type_inst) {
assert(pointer_type_inst && pointer_type_inst->opcode() == SpvOpTypePointer &&
"Precondition: |pointer_type_inst| must be OpTypePointer.");
return pointer_type_inst->GetSingleWordInOperand(1);
}
uint32_t GetPointeeTypeIdFromPointerType(opt::IRContext* context,
uint32_t pointer_type_id) {
return GetPointeeTypeIdFromPointerType(
context->get_def_use_mgr()->GetDef(pointer_type_id));
}
SpvStorageClass GetStorageClassFromPointerType(
opt::Instruction* pointer_type_inst) {
assert(pointer_type_inst && pointer_type_inst->opcode() == SpvOpTypePointer &&
"Precondition: |pointer_type_inst| must be OpTypePointer.");
return static_cast<SpvStorageClass>(
pointer_type_inst->GetSingleWordInOperand(0));
}
SpvStorageClass GetStorageClassFromPointerType(opt::IRContext* context,
uint32_t pointer_type_id) {
return GetStorageClassFromPointerType(
context->get_def_use_mgr()->GetDef(pointer_type_id));
}
uint32_t MaybeGetPointerType(opt::IRContext* context, uint32_t pointee_type_id,
SpvStorageClass storage_class) {
for (auto& inst : context->types_values()) {
switch (inst.opcode()) {
case SpvOpTypePointer:
if (inst.GetSingleWordInOperand(0) == storage_class &&
inst.GetSingleWordInOperand(1) == pointee_type_id) {
return inst.result_id();
}
break;
default:
break;
}
}
return 0;
}
uint32_t InOperandIndexFromOperandIndex(const opt::Instruction& inst,
uint32_t absolute_index) {
// Subtract the number of non-input operands from the index
return absolute_index - inst.NumOperands() + inst.NumInOperands();
}
bool IsNullConstantSupported(const opt::analysis::Type& type) {
return type.AsBool() || type.AsInteger() || type.AsFloat() ||
type.AsMatrix() || type.AsVector() || type.AsArray() ||
type.AsStruct() || type.AsPointer() || type.AsEvent() ||
type.AsDeviceEvent() || type.AsReserveId() || type.AsQueue();
}
bool GlobalVariablesMustBeDeclaredInEntryPointInterfaces(
const opt::IRContext* ir_context) {
// TODO(afd): We capture the universal environments for which this requirement
// holds. The check should be refined on demand for other target
// environments.
switch (ir_context->grammar().target_env()) {
case SPV_ENV_UNIVERSAL_1_0:
case SPV_ENV_UNIVERSAL_1_1:
case SPV_ENV_UNIVERSAL_1_2:
case SPV_ENV_UNIVERSAL_1_3:
return false;
default:
return true;
}
}
void AddVariableIdToEntryPointInterfaces(opt::IRContext* context, uint32_t id) {
if (GlobalVariablesMustBeDeclaredInEntryPointInterfaces(context)) {
// Conservatively add this global to the interface of every entry point in
// the module. This means that the global is available for other
// transformations to use.
//
// A downside of this is that the global will be in the interface even if it
// ends up never being used.
//
// TODO(https://github.com/KhronosGroup/SPIRV-Tools/issues/3111) revisit
// this if a more thorough approach to entry point interfaces is taken.
for (auto& entry_point : context->module()->entry_points()) {
entry_point.AddOperand({SPV_OPERAND_TYPE_ID, {id}});
}
}
}
void AddGlobalVariable(opt::IRContext* context, uint32_t result_id,
uint32_t type_id, SpvStorageClass storage_class,
uint32_t initializer_id) {
// Check various preconditions.
assert(result_id != 0 && "Result id can't be 0");
assert((storage_class == SpvStorageClassPrivate ||
storage_class == SpvStorageClassWorkgroup) &&
"Variable's storage class must be either Private or Workgroup");
auto* type_inst = context->get_def_use_mgr()->GetDef(type_id);
(void)type_inst; // Variable becomes unused in release mode.
assert(type_inst && type_inst->opcode() == SpvOpTypePointer &&
GetStorageClassFromPointerType(type_inst) == storage_class &&
"Variable's type is invalid");
if (storage_class == SpvStorageClassWorkgroup) {
assert(initializer_id == 0);
}
if (initializer_id != 0) {
const auto* constant_inst =
context->get_def_use_mgr()->GetDef(initializer_id);
(void)constant_inst; // Variable becomes unused in release mode.
assert(constant_inst && spvOpcodeIsConstant(constant_inst->opcode()) &&
GetPointeeTypeIdFromPointerType(type_inst) ==
constant_inst->type_id() &&
"Initializer is invalid");
}
opt::Instruction::OperandList operands = {
{SPV_OPERAND_TYPE_STORAGE_CLASS, {static_cast<uint32_t>(storage_class)}}};
if (initializer_id) {
operands.push_back({SPV_OPERAND_TYPE_ID, {initializer_id}});
}
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context, SpvOpVariable, type_id, result_id, std::move(operands)));
AddVariableIdToEntryPointInterfaces(context, result_id);
UpdateModuleIdBound(context, result_id);
}
void AddLocalVariable(opt::IRContext* context, uint32_t result_id,
uint32_t type_id, uint32_t function_id,
uint32_t initializer_id) {
// Check various preconditions.
assert(result_id != 0 && "Result id can't be 0");
auto* type_inst = context->get_def_use_mgr()->GetDef(type_id);
(void)type_inst; // Variable becomes unused in release mode.
assert(type_inst && type_inst->opcode() == SpvOpTypePointer &&
GetStorageClassFromPointerType(type_inst) == SpvStorageClassFunction &&
"Variable's type is invalid");
const auto* constant_inst =
context->get_def_use_mgr()->GetDef(initializer_id);
(void)constant_inst; // Variable becomes unused in release mode.
assert(constant_inst && spvOpcodeIsConstant(constant_inst->opcode()) &&
GetPointeeTypeIdFromPointerType(type_inst) ==
constant_inst->type_id() &&
"Initializer is invalid");
auto* function = FindFunction(context, function_id);
assert(function && "Function id is invalid");
function->begin()->begin()->InsertBefore(MakeUnique<opt::Instruction>(
context, SpvOpVariable, type_id, result_id,
opt::Instruction::OperandList{
{SPV_OPERAND_TYPE_STORAGE_CLASS, {SpvStorageClassFunction}},
{SPV_OPERAND_TYPE_ID, {initializer_id}}}));
UpdateModuleIdBound(context, result_id);
}
bool HasDuplicates(const std::vector<uint32_t>& arr) {
return std::unordered_set<uint32_t>(arr.begin(), arr.end()).size() !=
arr.size();
}
bool IsPermutationOfRange(const std::vector<uint32_t>& arr, uint32_t lo,
uint32_t hi) {
if (arr.empty()) {
return lo > hi;
}
if (HasDuplicates(arr)) {
return false;
}
auto min_max = std::minmax_element(arr.begin(), arr.end());
return arr.size() == hi - lo + 1 && *min_max.first == lo &&
*min_max.second == hi;
}
std::vector<opt::Instruction*> GetParameters(opt::IRContext* ir_context,
uint32_t function_id) {
auto* function = FindFunction(ir_context, function_id);
assert(function && "|function_id| is invalid");
std::vector<opt::Instruction*> result;
function->ForEachParam(
[&result](opt::Instruction* inst) { result.push_back(inst); });
return result;
}
void RemoveParameter(opt::IRContext* ir_context, uint32_t parameter_id) {
auto* function = GetFunctionFromParameterId(ir_context, parameter_id);
assert(function && "|parameter_id| is invalid");
assert(!FunctionIsEntryPoint(ir_context, function->result_id()) &&
"Can't remove parameter from an entry point function");
function->RemoveParameter(parameter_id);
// We've just removed parameters from the function and cleared their memory.
// Make sure analyses have no dangling pointers.
ir_context->InvalidateAnalysesExceptFor(
opt::IRContext::Analysis::kAnalysisNone);
}
std::vector<opt::Instruction*> GetCallers(opt::IRContext* ir_context,
uint32_t function_id) {
assert(FindFunction(ir_context, function_id) &&
"|function_id| is not a result id of a function");
std::vector<opt::Instruction*> result;
ir_context->get_def_use_mgr()->ForEachUser(
function_id, [&result, function_id](opt::Instruction* inst) {
if (inst->opcode() == SpvOpFunctionCall &&
inst->GetSingleWordInOperand(0) == function_id) {
result.push_back(inst);
}
});
return result;
}
opt::Function* GetFunctionFromParameterId(opt::IRContext* ir_context,
uint32_t param_id) {
auto* param_inst = ir_context->get_def_use_mgr()->GetDef(param_id);
assert(param_inst && "Parameter id is invalid");
for (auto& function : *ir_context->module()) {
if (InstructionIsFunctionParameter(param_inst, &function)) {
return &function;
}
}
return nullptr;
}
uint32_t UpdateFunctionType(opt::IRContext* ir_context, uint32_t function_id,
uint32_t new_function_type_result_id,
uint32_t return_type_id,
const std::vector<uint32_t>& parameter_type_ids) {
// Check some initial constraints.
assert(ir_context->get_type_mgr()->GetType(return_type_id) &&
"Return type is invalid");
for (auto id : parameter_type_ids) {
const auto* type = ir_context->get_type_mgr()->GetType(id);
(void)type; // Make compilers happy in release mode.
// Parameters can't be OpTypeVoid.
assert(type && !type->AsVoid() && "Parameter has invalid type");
}
auto* function = FindFunction(ir_context, function_id);
assert(function && "|function_id| is invalid");
auto* old_function_type = GetFunctionType(ir_context, function);
assert(old_function_type && "Function has invalid type");
std::vector<uint32_t> operand_ids = {return_type_id};
operand_ids.insert(operand_ids.end(), parameter_type_ids.begin(),
parameter_type_ids.end());
// A trivial case - we change nothing.
if (FindFunctionType(ir_context, operand_ids) ==
old_function_type->result_id()) {
return old_function_type->result_id();
}
if (ir_context->get_def_use_mgr()->NumUsers(old_function_type) == 1 &&
FindFunctionType(ir_context, operand_ids) == 0) {
// We can change |old_function_type| only if it's used once in the module
// and we are certain we won't create a duplicate as a result of the change.
// Update |old_function_type| in-place.
opt::Instruction::OperandList operands;
for (auto id : operand_ids) {
operands.push_back({SPV_OPERAND_TYPE_ID, {id}});
}
old_function_type->SetInOperands(std::move(operands));
// |operands| may depend on result ids defined below the |old_function_type|
// in the module.
old_function_type->RemoveFromList();
ir_context->AddType(std::unique_ptr<opt::Instruction>(old_function_type));
return old_function_type->result_id();
} else {
// We can't modify the |old_function_type| so we have to either use an
// existing one or create a new one.
auto type_id = FindOrCreateFunctionType(
ir_context, new_function_type_result_id, operand_ids);
assert(type_id != old_function_type->result_id() &&
"We should've handled this case above");
function->DefInst().SetInOperand(1, {type_id});
// DefUseManager hasn't been updated yet, so if the following condition is
// true, then |old_function_type| will have no users when this function
// returns. We might as well remove it.
if (ir_context->get_def_use_mgr()->NumUsers(old_function_type) == 1) {
ir_context->KillInst(old_function_type);
}
return type_id;
}
}
void AddFunctionType(opt::IRContext* ir_context, uint32_t result_id,
const std::vector<uint32_t>& type_ids) {
assert(result_id != 0 && "Result id can't be 0");
assert(!type_ids.empty() &&
"OpTypeFunction always has at least one operand - function's return "
"type");
assert(IsNonFunctionTypeId(ir_context, type_ids[0]) &&
"Return type must not be a function");
for (size_t i = 1; i < type_ids.size(); ++i) {
const auto* param_type = ir_context->get_type_mgr()->GetType(type_ids[i]);
(void)param_type; // Make compiler happy in release mode.
assert(param_type && !param_type->AsVoid() && !param_type->AsFunction() &&
"Function parameter can't have a function or void type");
}
opt::Instruction::OperandList operands;
operands.reserve(type_ids.size());
for (auto id : type_ids) {
operands.push_back({SPV_OPERAND_TYPE_ID, {id}});
}
ir_context->AddType(MakeUnique<opt::Instruction>(
ir_context, SpvOpTypeFunction, 0, result_id, std::move(operands)));
UpdateModuleIdBound(ir_context, result_id);
}
uint32_t FindOrCreateFunctionType(opt::IRContext* ir_context,
uint32_t result_id,
const std::vector<uint32_t>& type_ids) {
if (auto existing_id = FindFunctionType(ir_context, type_ids)) {
return existing_id;
}
AddFunctionType(ir_context, result_id, type_ids);
return result_id;
}
uint32_t MaybeGetIntegerType(opt::IRContext* ir_context, uint32_t width,
bool is_signed) {
opt::analysis::Integer type(width, is_signed);
return ir_context->get_type_mgr()->GetId(&type);
}
uint32_t MaybeGetFloatType(opt::IRContext* ir_context, uint32_t width) {
opt::analysis::Float type(width);
return ir_context->get_type_mgr()->GetId(&type);
}
uint32_t MaybeGetBoolType(opt::IRContext* ir_context) {
opt::analysis::Bool type;
return ir_context->get_type_mgr()->GetId(&type);
}
uint32_t MaybeGetVectorType(opt::IRContext* ir_context,
uint32_t component_type_id,
uint32_t element_count) {
const auto* component_type =
ir_context->get_type_mgr()->GetType(component_type_id);
assert(component_type &&
(component_type->AsInteger() || component_type->AsFloat() ||
component_type->AsBool()) &&
"|component_type_id| is invalid");
assert(element_count >= 2 && element_count <= 4 &&
"Precondition: component count must be in range [2, 4].");
opt::analysis::Vector type(component_type, element_count);
return ir_context->get_type_mgr()->GetId(&type);
}
uint32_t MaybeGetStructType(opt::IRContext* ir_context,
const std::vector<uint32_t>& component_type_ids) {
for (auto& type_or_value : ir_context->types_values()) {
if (type_or_value.opcode() != SpvOpTypeStruct ||
type_or_value.NumInOperands() !=
static_cast<uint32_t>(component_type_ids.size())) {
continue;
}
bool all_components_match = true;
for (uint32_t i = 0; i < component_type_ids.size(); i++) {
if (type_or_value.GetSingleWordInOperand(i) != component_type_ids[i]) {
all_components_match = false;
break;
}
}
if (all_components_match) {
return type_or_value.result_id();
}
}
return 0;
}
uint32_t MaybeGetVoidType(opt::IRContext* ir_context) {
opt::analysis::Void type;
return ir_context->get_type_mgr()->GetId(&type);
}
uint32_t MaybeGetZeroConstant(
opt::IRContext* ir_context,
const TransformationContext& transformation_context,
uint32_t scalar_or_composite_type_id, bool is_irrelevant) {
const auto* type_inst =
ir_context->get_def_use_mgr()->GetDef(scalar_or_composite_type_id);
assert(type_inst && "|scalar_or_composite_type_id| is invalid");
switch (type_inst->opcode()) {
case SpvOpTypeBool:
return MaybeGetBoolConstant(ir_context, transformation_context, false,
is_irrelevant);
case SpvOpTypeFloat:
case SpvOpTypeInt: {
const auto width = type_inst->GetSingleWordInOperand(0);
std::vector<uint32_t> words = {0};
if (width > 32) {
words.push_back(0);
}
return MaybeGetScalarConstant(ir_context, transformation_context, words,
scalar_or_composite_type_id, is_irrelevant);
}
case SpvOpTypeStruct: {
std::vector<uint32_t> component_ids;
for (uint32_t i = 0; i < type_inst->NumInOperands(); ++i) {
const auto component_type_id = type_inst->GetSingleWordInOperand(i);
auto component_id =
MaybeGetZeroConstant(ir_context, transformation_context,
component_type_id, is_irrelevant);
if (component_id == 0 && is_irrelevant) {
// Irrelevant constants can use either relevant or irrelevant
// constituents.
component_id = MaybeGetZeroConstant(
ir_context, transformation_context, component_type_id, false);
}
if (component_id == 0) {
return 0;
}
component_ids.push_back(component_id);
}
return MaybeGetCompositeConstant(
ir_context, transformation_context, component_ids,
scalar_or_composite_type_id, is_irrelevant);
}
case SpvOpTypeMatrix:
case SpvOpTypeVector: {
const auto component_type_id = type_inst->GetSingleWordInOperand(0);
auto component_id = MaybeGetZeroConstant(
ir_context, transformation_context, component_type_id, is_irrelevant);
if (component_id == 0 && is_irrelevant) {
// Irrelevant constants can use either relevant or irrelevant
// constituents.
component_id = MaybeGetZeroConstant(ir_context, transformation_context,
component_type_id, false);
}
if (component_id == 0) {
return 0;
}
const auto component_count = type_inst->GetSingleWordInOperand(1);
return MaybeGetCompositeConstant(
ir_context, transformation_context,
std::vector<uint32_t>(component_count, component_id),
scalar_or_composite_type_id, is_irrelevant);
}
case SpvOpTypeArray: {
const auto component_type_id = type_inst->GetSingleWordInOperand(0);
auto component_id = MaybeGetZeroConstant(
ir_context, transformation_context, component_type_id, is_irrelevant);
if (component_id == 0 && is_irrelevant) {
// Irrelevant constants can use either relevant or irrelevant
// constituents.
component_id = MaybeGetZeroConstant(ir_context, transformation_context,
component_type_id, false);
}
if (component_id == 0) {
return 0;
}
return MaybeGetCompositeConstant(
ir_context, transformation_context,
std::vector<uint32_t>(GetArraySize(*type_inst, ir_context),
component_id),
scalar_or_composite_type_id, is_irrelevant);
}
default:
assert(false && "Type is not supported");
return 0;
}
}
bool CanCreateConstant(opt::IRContext* ir_context, uint32_t type_id) {
opt::Instruction* type_instr = ir_context->get_def_use_mgr()->GetDef(type_id);
assert(type_instr != nullptr && "The type must exist.");
assert(spvOpcodeGeneratesType(type_instr->opcode()) &&
"A type-generating opcode was expected.");
switch (type_instr->opcode()) {
case SpvOpTypeBool:
case SpvOpTypeInt:
case SpvOpTypeFloat:
case SpvOpTypeMatrix:
case SpvOpTypeVector:
return true;
case SpvOpTypeArray:
return CanCreateConstant(ir_context,
type_instr->GetSingleWordInOperand(0));
case SpvOpTypeStruct:
if (HasBlockOrBufferBlockDecoration(ir_context, type_id)) {
return false;
}
for (uint32_t index = 0; index < type_instr->NumInOperands(); index++) {
if (!CanCreateConstant(ir_context,
type_instr->GetSingleWordInOperand(index))) {
return false;
}
}
return true;
default:
return false;
}
}
uint32_t MaybeGetScalarConstant(
opt::IRContext* ir_context,
const TransformationContext& transformation_context,
const std::vector<uint32_t>& words, uint32_t scalar_type_id,
bool is_irrelevant) {
const auto* type = ir_context->get_type_mgr()->GetType(scalar_type_id);
assert(type && "|scalar_type_id| is invalid");
if (const auto* int_type = type->AsInteger()) {
return MaybeGetIntegerConstant(ir_context, transformation_context, words,
int_type->width(), int_type->IsSigned(),
is_irrelevant);
} else if (const auto* float_type = type->AsFloat()) {
return MaybeGetFloatConstant(ir_context, transformation_context, words,
float_type->width(), is_irrelevant);
} else {
assert(type->AsBool() && words.size() == 1 &&
"|scalar_type_id| doesn't represent a scalar type");
return MaybeGetBoolConstant(ir_context, transformation_context, words[0],
is_irrelevant);
}
}
uint32_t MaybeGetCompositeConstant(
opt::IRContext* ir_context,
const TransformationContext& transformation_context,
const std::vector<uint32_t>& component_ids, uint32_t composite_type_id,
bool is_irrelevant) {
const auto* type = ir_context->get_type_mgr()->GetType(composite_type_id);
(void)type; // Make compilers happy in release mode.
assert(IsCompositeType(type) && "|composite_type_id| is invalid");
for (const auto& inst : ir_context->types_values()) {
if (inst.opcode() == SpvOpConstantComposite &&
inst.type_id() == composite_type_id &&
transformation_context.GetFactManager()->IdIsIrrelevant(
inst.result_id()) == is_irrelevant &&
inst.NumInOperands() == component_ids.size()) {
bool is_match = true;
for (uint32_t i = 0; i < inst.NumInOperands(); ++i) {
if (inst.GetSingleWordInOperand(i) != component_ids[i]) {
is_match = false;
break;
}
}
if (is_match) {
return inst.result_id();
}
}
}
return 0;
}
uint32_t MaybeGetIntegerConstant(
opt::IRContext* ir_context,
const TransformationContext& transformation_context,
const std::vector<uint32_t>& words, uint32_t width, bool is_signed,
bool is_irrelevant) {
if (auto type_id = MaybeGetIntegerType(ir_context, width, is_signed)) {
return MaybeGetOpConstant(ir_context, transformation_context, words,
type_id, is_irrelevant);
}
return 0;
}
uint32_t MaybeGetIntegerConstantFromValueAndType(opt::IRContext* ir_context,
uint32_t value,
uint32_t int_type_id) {
auto int_type_inst = ir_context->get_def_use_mgr()->GetDef(int_type_id);
assert(int_type_inst && "The given type id must exist.");
auto int_type = ir_context->get_type_mgr()
->GetType(int_type_inst->result_id())
->AsInteger();
assert(int_type && int_type->width() == 32 &&
"The given type id must correspond to an 32-bit integer type.");
opt::analysis::IntConstant constant(int_type, {value});
// Check that the constant exists in the module.
if (!ir_context->get_constant_mgr()->FindConstant(&constant)) {
return 0;
}
return ir_context->get_constant_mgr()
->GetDefiningInstruction(&constant)
->result_id();
}
uint32_t MaybeGetFloatConstant(
opt::IRContext* ir_context,
const TransformationContext& transformation_context,
const std::vector<uint32_t>& words, uint32_t width, bool is_irrelevant) {
if (auto type_id = MaybeGetFloatType(ir_context, width)) {
return MaybeGetOpConstant(ir_context, transformation_context, words,
type_id, is_irrelevant);
}
return 0;
}
uint32_t MaybeGetBoolConstant(
opt::IRContext* ir_context,
const TransformationContext& transformation_context, bool value,
bool is_irrelevant) {
if (auto type_id = MaybeGetBoolType(ir_context)) {
for (const auto& inst : ir_context->types_values()) {
if (inst.opcode() == (value ? SpvOpConstantTrue : SpvOpConstantFalse) &&
inst.type_id() == type_id &&
transformation_context.GetFactManager()->IdIsIrrelevant(
inst.result_id()) == is_irrelevant) {
return inst.result_id();
}
}
}
return 0;
}
void AddIntegerType(opt::IRContext* ir_context, uint32_t result_id,
uint32_t width, bool is_signed) {
ir_context->module()->AddType(MakeUnique<opt::Instruction>(
ir_context, SpvOpTypeInt, 0, result_id,
opt::Instruction::OperandList{
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {width}},
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {is_signed ? 1u : 0u}}}));
UpdateModuleIdBound(ir_context, result_id);
}
void AddFloatType(opt::IRContext* ir_context, uint32_t result_id,
uint32_t width) {
ir_context->module()->AddType(MakeUnique<opt::Instruction>(
ir_context, SpvOpTypeFloat, 0, result_id,
opt::Instruction::OperandList{
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {width}}}));
UpdateModuleIdBound(ir_context, result_id);
}
void AddVectorType(opt::IRContext* ir_context, uint32_t result_id,
uint32_t component_type_id, uint32_t element_count) {
const auto* component_type =
ir_context->get_type_mgr()->GetType(component_type_id);
(void)component_type; // Make compiler happy in release mode.
assert(component_type &&
(component_type->AsInteger() || component_type->AsFloat() ||
component_type->AsBool()) &&
"|component_type_id| is invalid");
assert(element_count >= 2 && element_count <= 4 &&
"Precondition: component count must be in range [2, 4].");
ir_context->module()->AddType(MakeUnique<opt::Instruction>(
ir_context, SpvOpTypeVector, 0, result_id,
opt::Instruction::OperandList{
{SPV_OPERAND_TYPE_ID, {component_type_id}},
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {element_count}}}));
UpdateModuleIdBound(ir_context, result_id);
}
void AddStructType(opt::IRContext* ir_context, uint32_t result_id,
const std::vector<uint32_t>& component_type_ids) {
opt::Instruction::OperandList operands;
operands.reserve(component_type_ids.size());
for (auto type_id : component_type_ids) {
const auto* type = ir_context->get_type_mgr()->GetType(type_id);
(void)type; // Make compiler happy in release mode.
assert(type && !type->AsFunction() && "Component's type id is invalid");
if (type->AsStruct()) {
// From the spec for the BuiltIn decoration:
// - When applied to a structure-type member, that structure type cannot
// be contained as a member of another structure type.
assert(!MembersHaveBuiltInDecoration(ir_context, type_id) &&
"A member struct has BuiltIn members");
}
operands.push_back({SPV_OPERAND_TYPE_ID, {type_id}});
}
ir_context->AddType(MakeUnique<opt::Instruction>(
ir_context, SpvOpTypeStruct, 0, result_id, std::move(operands)));
UpdateModuleIdBound(ir_context, result_id);
}
std::vector<uint32_t> IntToWords(uint64_t value, uint32_t width,
bool is_signed) {
assert(width <= 64 && "The bit width should not be more than 64 bits");
// Sign-extend or zero-extend the last |width| bits of |value|, depending on
// |is_signed|.
if (is_signed) {
// Sign-extend by shifting left and then shifting right, interpreting the
// integer as signed.
value = static_cast<int64_t>(value << (64 - width)) >> (64 - width);
} else {
// Zero-extend by shifting left and then shifting right, interpreting the
// integer as unsigned.
value = (value << (64 - width)) >> (64 - width);
}
std::vector<uint32_t> result;
result.push_back(static_cast<uint32_t>(value));
if (width > 32) {
result.push_back(static_cast<uint32_t>(value >> 32));
}
return result;
}
bool TypesAreEqualUpToSign(opt::IRContext* ir_context, uint32_t type1_id,
uint32_t type2_id) {
if (type1_id == type2_id) {
return true;
}
auto type1 = ir_context->get_type_mgr()->GetType(type1_id);
auto type2 = ir_context->get_type_mgr()->GetType(type2_id);
// Integer scalar types must have the same width
if (type1->AsInteger() && type2->AsInteger()) {
return type1->AsInteger()->width() == type2->AsInteger()->width();
}
// Integer vector types must have the same number of components and their
// component types must be integers with the same width.
if (type1->AsVector() && type2->AsVector()) {
auto component_type1 = type1->AsVector()->element_type()->AsInteger();
auto component_type2 = type2->AsVector()->element_type()->AsInteger();
// Only check the component count and width if they are integer.
if (component_type1 && component_type2) {
return type1->AsVector()->element_count() ==
type2->AsVector()->element_count() &&
component_type1->width() == component_type2->width();
}
}
// In all other cases, the types cannot be considered equal.
return false;
}
std::map<uint32_t, uint32_t> RepeatedUInt32PairToMap(
const google::protobuf::RepeatedPtrField<protobufs::UInt32Pair>& data) {
std::map<uint32_t, uint32_t> result;
for (const auto& entry : data) {
result[entry.first()] = entry.second();
}
return result;
}
google::protobuf::RepeatedPtrField<protobufs::UInt32Pair>
MapToRepeatedUInt32Pair(const std::map<uint32_t, uint32_t>& data) {
google::protobuf::RepeatedPtrField<protobufs::UInt32Pair> result;
for (const auto& entry : data) {
protobufs::UInt32Pair pair;
pair.set_first(entry.first);
pair.set_second(entry.second);
*result.Add() = std::move(pair);
}
return result;
}
opt::Instruction* GetLastInsertBeforeInstruction(opt::IRContext* ir_context,
uint32_t block_id,
SpvOp opcode) {
// CFG::block uses std::map::at which throws an exception when |block_id| is
// invalid. The error message is unhelpful, though. Thus, we test that
// |block_id| is valid here.
const auto* label_inst = ir_context->get_def_use_mgr()->GetDef(block_id);
(void)label_inst; // Make compilers happy in release mode.
assert(label_inst && label_inst->opcode() == SpvOpLabel &&
"|block_id| is invalid");
auto* block = ir_context->cfg()->block(block_id);
auto it = block->rbegin();
assert(it != block->rend() && "Basic block can't be empty");
if (block->GetMergeInst()) {
++it;
assert(it != block->rend() &&
"|block| must have at least two instructions:"
"terminator and a merge instruction");
}
return CanInsertOpcodeBeforeInstruction(opcode, &*it) ? &*it : nullptr;
}
bool IdUseCanBeReplaced(opt::IRContext* ir_context,
const TransformationContext& transformation_context,
opt::Instruction* use_instruction,
uint32_t use_in_operand_index) {
if (spvOpcodeIsAccessChain(use_instruction->opcode()) &&
use_in_operand_index > 0) {
// A replacement for an irrelevant index in OpAccessChain must be clamped
// first.
if (transformation_context.GetFactManager()->IdIsIrrelevant(
use_instruction->GetSingleWordInOperand(use_in_operand_index))) {
return false;
}
// This is an access chain index. If the (sub-)object being accessed by the
// given index has struct type then we cannot replace the use, as it needs
// to be an OpConstant.
// Get the top-level composite type that is being accessed.
auto object_being_accessed = ir_context->get_def_use_mgr()->GetDef(
use_instruction->GetSingleWordInOperand(0));
auto pointer_type =
ir_context->get_type_mgr()->GetType(object_being_accessed->type_id());
assert(pointer_type->AsPointer());
auto composite_type_being_accessed =
pointer_type->AsPointer()->pointee_type();
// Now walk the access chain, tracking the type of each sub-object of the
// composite that is traversed, until the index of interest is reached.
for (uint32_t index_in_operand = 1; index_in_operand < use_in_operand_index;
index_in_operand++) {
// For vectors, matrices and arrays, getting the type of the sub-object is
// trivial. For the struct case, the sub-object type is field-sensitive,
// and depends on the constant index that is used.
if (composite_type_being_accessed->AsVector()) {
composite_type_being_accessed =
composite_type_being_accessed->AsVector()->element_type();
} else if (composite_type_being_accessed->AsMatrix()) {
composite_type_being_accessed =
composite_type_being_accessed->AsMatrix()->element_type();
} else if (composite_type_being_accessed->AsArray()) {
composite_type_being_accessed =
composite_type_being_accessed->AsArray()->element_type();
} else if (composite_type_being_accessed->AsRuntimeArray()) {
composite_type_being_accessed =
composite_type_being_accessed->AsRuntimeArray()->element_type();
} else {
assert(composite_type_being_accessed->AsStruct());
auto constant_index_instruction = ir_context->get_def_use_mgr()->GetDef(
use_instruction->GetSingleWordInOperand(index_in_operand));
assert(constant_index_instruction->opcode() == SpvOpConstant);
uint32_t member_index =
constant_index_instruction->GetSingleWordInOperand(0);
composite_type_being_accessed =
composite_type_being_accessed->AsStruct()
->element_types()[member_index];
}
}
// We have found the composite type being accessed by the index we are
// considering replacing. If it is a struct, then we cannot do the
// replacement as struct indices must be constants.
if (composite_type_being_accessed->AsStruct()) {
return false;
}
}
if (use_instruction->opcode() == SpvOpFunctionCall &&
use_in_operand_index > 0) {
// This is a function call argument. It is not allowed to have pointer
// type.
// Get the definition of the function being called.
auto function = ir_context->get_def_use_mgr()->GetDef(
use_instruction->GetSingleWordInOperand(0));
// From the function definition, get the function type.
auto function_type = ir_context->get_def_use_mgr()->GetDef(
function->GetSingleWordInOperand(1));
// OpTypeFunction's 0-th input operand is the function return type, and the
// function argument types follow. Because the arguments to OpFunctionCall
// start from input operand 1, we can use |use_in_operand_index| to get the
// type associated with this function argument.
auto parameter_type = ir_context->get_type_mgr()->GetType(
function_type->GetSingleWordInOperand(use_in_operand_index));
if (parameter_type->AsPointer()) {
return false;
}
}
if (use_instruction->opcode() == SpvOpImageTexelPointer &&
use_in_operand_index == 2) {
// The OpImageTexelPointer instruction has a Sample parameter that in some
// situations must be an id for the value 0. To guard against disrupting
// that requirement, we do not replace this argument to that instruction.
return false;
}
return true;
}
bool MembersHaveBuiltInDecoration(opt::IRContext* ir_context,
uint32_t struct_type_id) {
const auto* type_inst = ir_context->get_def_use_mgr()->GetDef(struct_type_id);
assert(type_inst && type_inst->opcode() == SpvOpTypeStruct &&
"|struct_type_id| is not a result id of an OpTypeStruct");
uint32_t builtin_count = 0;
ir_context->get_def_use_mgr()->ForEachUser(
type_inst,
[struct_type_id, &builtin_count](const opt::Instruction* user) {
if (user->opcode() == SpvOpMemberDecorate &&
user->GetSingleWordInOperand(0) == struct_type_id &&
static_cast<SpvDecoration>(user->GetSingleWordInOperand(2)) ==
SpvDecorationBuiltIn) {
++builtin_count;
}
});
assert((builtin_count == 0 || builtin_count == type_inst->NumInOperands()) &&
"The module is invalid: either none or all of the members of "
"|struct_type_id| may be builtin");
return builtin_count != 0;
}
bool HasBlockOrBufferBlockDecoration(opt::IRContext* ir_context, uint32_t id) {
for (auto decoration : {SpvDecorationBlock, SpvDecorationBufferBlock}) {
if (!ir_context->get_decoration_mgr()->WhileEachDecoration(
id, decoration, [](const opt::Instruction & /*unused*/) -> bool {
return false;
})) {
return true;
}
}
return false;
}
bool SplittingBeforeInstructionSeparatesOpSampledImageDefinitionFromUse(
opt::BasicBlock* block_to_split, opt::Instruction* split_before) {
std::set<uint32_t> sampled_image_result_ids;
bool before_split = true;
// Check all the instructions in the block to split.
for (auto& instruction : *block_to_split) {
if (&instruction == &*split_before) {
before_split = false;
}
if (before_split) {
// If the instruction comes before the split and its opcode is
// OpSampledImage, record its result id.
if (instruction.opcode() == SpvOpSampledImage) {
sampled_image_result_ids.insert(instruction.result_id());
}
} else {
// If the instruction comes after the split, check if ids
// corresponding to OpSampledImage instructions defined before the split
// are used, and return true if they are.
if (!instruction.WhileEachInId(
[&sampled_image_result_ids](uint32_t* id) -> bool {
return !sampled_image_result_ids.count(*id);
})) {
return true;
}
}
}
// No usage that would be separated from the definition has been found.
return false;
}
bool InstructionHasNoSideEffects(const opt::Instruction& instruction) {
switch (instruction.opcode()) {
case SpvOpUndef:
case SpvOpAccessChain:
case SpvOpInBoundsAccessChain:
case SpvOpArrayLength:
case SpvOpVectorExtractDynamic:
case SpvOpVectorInsertDynamic:
case SpvOpVectorShuffle:
case SpvOpCompositeConstruct:
case SpvOpCompositeExtract:
case SpvOpCompositeInsert:
case SpvOpCopyObject:
case SpvOpTranspose:
case SpvOpConvertFToU:
case SpvOpConvertFToS:
case SpvOpConvertSToF:
case SpvOpConvertUToF:
case SpvOpUConvert:
case SpvOpSConvert:
case SpvOpFConvert:
case SpvOpQuantizeToF16:
case SpvOpSatConvertSToU:
case SpvOpSatConvertUToS:
case SpvOpBitcast:
case SpvOpSNegate:
case SpvOpFNegate:
case SpvOpIAdd:
case SpvOpFAdd:
case SpvOpISub:
case SpvOpFSub:
case SpvOpIMul:
case SpvOpFMul:
case SpvOpUDiv:
case SpvOpSDiv:
case SpvOpFDiv:
case SpvOpUMod:
case SpvOpSRem:
case SpvOpSMod:
case SpvOpFRem:
case SpvOpFMod:
case SpvOpVectorTimesScalar:
case SpvOpMatrixTimesScalar:
case SpvOpVectorTimesMatrix:
case SpvOpMatrixTimesVector:
case SpvOpMatrixTimesMatrix:
case SpvOpOuterProduct:
case SpvOpDot:
case SpvOpIAddCarry:
case SpvOpISubBorrow:
case SpvOpUMulExtended:
case SpvOpSMulExtended:
case SpvOpAny:
case SpvOpAll:
case SpvOpIsNan:
case SpvOpIsInf:
case SpvOpIsFinite:
case SpvOpIsNormal:
case SpvOpSignBitSet:
case SpvOpLessOrGreater:
case SpvOpOrdered:
case SpvOpUnordered:
case SpvOpLogicalEqual:
case SpvOpLogicalNotEqual:
case SpvOpLogicalOr:
case SpvOpLogicalAnd:
case SpvOpLogicalNot:
case SpvOpSelect:
case SpvOpIEqual:
case SpvOpINotEqual:
case SpvOpUGreaterThan:
case SpvOpSGreaterThan:
case SpvOpUGreaterThanEqual:
case SpvOpSGreaterThanEqual:
case SpvOpULessThan:
case SpvOpSLessThan:
case SpvOpULessThanEqual:
case SpvOpSLessThanEqual:
case SpvOpFOrdEqual:
case SpvOpFUnordEqual:
case SpvOpFOrdNotEqual:
case SpvOpFUnordNotEqual:
case SpvOpFOrdLessThan:
case SpvOpFUnordLessThan:
case SpvOpFOrdGreaterThan:
case SpvOpFUnordGreaterThan:
case SpvOpFOrdLessThanEqual:
case SpvOpFUnordLessThanEqual:
case SpvOpFOrdGreaterThanEqual:
case SpvOpFUnordGreaterThanEqual:
case SpvOpShiftRightLogical:
case SpvOpShiftRightArithmetic:
case SpvOpShiftLeftLogical:
case SpvOpBitwiseOr:
case SpvOpBitwiseXor:
case SpvOpBitwiseAnd:
case SpvOpNot:
case SpvOpBitFieldInsert:
case SpvOpBitFieldSExtract:
case SpvOpBitFieldUExtract:
case SpvOpBitReverse:
case SpvOpBitCount:
case SpvOpCopyLogical:
case SpvOpPhi:
case SpvOpPtrEqual:
case SpvOpPtrNotEqual:
return true;
default:
return false;
}
}
std::set<uint32_t> GetReachableReturnBlocks(opt::IRContext* ir_context,
uint32_t function_id) {
auto function = ir_context->GetFunction(function_id);
assert(function && "The function |function_id| must exist.");
std::set<uint32_t> result;
ir_context->cfg()->ForEachBlockInPostOrder(function->entry().get(),
[&result](opt::BasicBlock* block) {
if (block->IsReturn()) {
result.emplace(block->id());
}
});
return result;
}
} // namespace fuzzerutil
} // namespace fuzz
} // namespace spvtools