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// Copyright 2023 The Dawn & Tint Authors
//
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// modification, are permitted provided that the following conditions are met:
//
// 1. Redistributions of source code must retain the above copyright notice, this
// list of conditions and the following disclaimer.
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// 2. Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
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// 3. Neither the name of the copyright holder nor the names of its
// contributors may be used to endorse or promote products derived from
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#include "src/tint/lang/spirv/reader/parser/parser.h"
#include <algorithm>
#include <memory>
#include <utility>
#include <vector>
TINT_BEGIN_DISABLE_WARNING(NEWLINE_EOF);
TINT_BEGIN_DISABLE_WARNING(OLD_STYLE_CAST);
TINT_BEGIN_DISABLE_WARNING(SIGN_CONVERSION);
TINT_BEGIN_DISABLE_WARNING(WEAK_VTABLES);
#include "source/opt/build_module.h"
TINT_END_DISABLE_WARNING(WEAK_VTABLES);
TINT_END_DISABLE_WARNING(SIGN_CONVERSION);
TINT_END_DISABLE_WARNING(OLD_STYLE_CAST);
TINT_END_DISABLE_WARNING(NEWLINE_EOF);
#include "src/tint/lang/core/ir/builder.h"
#include "src/tint/lang/core/ir/module.h"
#include "src/tint/lang/spirv/validate/validate.h"
using namespace tint::core::fluent_types; // NOLINT
namespace tint::spirv::reader {
namespace {
/// The SPIR-V environment that we validate against.
constexpr auto kTargetEnv = SPV_ENV_VULKAN_1_1;
/// PIMPL class for SPIR-V parser.
/// Validates the SPIR-V module and then parses it to produce a Tint IR module.
class Parser {
public:
/// @param spirv the SPIR-V binary data
/// @returns the generated SPIR-V IR module on success, or failure
Result<core::ir::Module> Run(Slice<const uint32_t> spirv) {
// Validate the incoming SPIR-V binary.
auto result = validate::Validate(spirv, kTargetEnv);
if (result != Success) {
return result.Failure();
}
// Build the SPIR-V tools internal representation of the SPIR-V module.
spvtools::Context context(kTargetEnv);
spirv_context_ =
spvtools::BuildModule(kTargetEnv, context.CContext()->consumer, spirv.data, spirv.len);
if (!spirv_context_) {
return Failure("failed to build the internal representation of the module");
}
// Check for unsupported extensions.
for (const auto& ext : spirv_context_->extensions()) {
auto name = ext.GetOperand(0).AsString();
if (name != "SPV_KHR_storage_buffer_storage_class") {
return Failure("SPIR-V extension '" + name + "' is not supported");
}
}
{
TINT_SCOPED_ASSIGNMENT(current_block_, ir_.root_block);
EmitModuleScopeVariables();
}
EmitFunctions();
EmitEntryPoints();
// TODO(crbug.com/tint/1907): Handle annotation instructions.
// TODO(crbug.com/tint/1907): Handle names.
return std::move(ir_);
}
/// @param sc a SPIR-V storage class
/// @returns the Tint address space for a SPIR-V storage class
core::AddressSpace AddressSpace(spv::StorageClass sc) {
switch (sc) {
case spv::StorageClass::Input:
return core::AddressSpace::kIn;
case spv::StorageClass::Output:
return core::AddressSpace::kOut;
case spv::StorageClass::Function:
return core::AddressSpace::kFunction;
case spv::StorageClass::Private:
return core::AddressSpace::kPrivate;
case spv::StorageClass::StorageBuffer:
return core::AddressSpace::kStorage;
case spv::StorageClass::Uniform:
return core::AddressSpace::kUniform;
default:
TINT_UNIMPLEMENTED()
<< "unhandled SPIR-V storage class: " << static_cast<uint32_t>(sc);
return core::AddressSpace::kUndefined;
}
}
/// @param b a SPIR-V BuiltIn
/// @returns the Tint builtin value for a SPIR-V BuiltIn decoration
core::BuiltinValue Builtin(spv::BuiltIn b) {
switch (b) {
case spv::BuiltIn::FragCoord:
return core::BuiltinValue::kPosition;
case spv::BuiltIn::FragDepth:
return core::BuiltinValue::kFragDepth;
case spv::BuiltIn::FrontFacing:
return core::BuiltinValue::kFrontFacing;
case spv::BuiltIn::GlobalInvocationId:
return core::BuiltinValue::kGlobalInvocationId;
case spv::BuiltIn::InstanceIndex:
return core::BuiltinValue::kInstanceIndex;
case spv::BuiltIn::LocalInvocationId:
return core::BuiltinValue::kLocalInvocationId;
case spv::BuiltIn::LocalInvocationIndex:
return core::BuiltinValue::kLocalInvocationIndex;
case spv::BuiltIn::NumWorkgroups:
return core::BuiltinValue::kNumWorkgroups;
case spv::BuiltIn::PointSize:
return core::BuiltinValue::kPointSize;
case spv::BuiltIn::Position:
return core::BuiltinValue::kPosition;
case spv::BuiltIn::SampleId:
return core::BuiltinValue::kSampleIndex;
case spv::BuiltIn::SampleMask:
return core::BuiltinValue::kSampleMask;
case spv::BuiltIn::VertexIndex:
return core::BuiltinValue::kVertexIndex;
case spv::BuiltIn::WorkgroupId:
return core::BuiltinValue::kWorkgroupId;
default:
TINT_UNIMPLEMENTED() << "unhandled SPIR-V BuiltIn: " << static_cast<uint32_t>(b);
return core::BuiltinValue::kUndefined;
}
}
/// @param type a SPIR-V type object
/// @param access_mode an optional access mode (for pointers)
/// @returns a Tint type object
const core::type::Type* Type(const spvtools::opt::analysis::Type* type,
core::Access access_mode = core::Access::kUndefined) {
return types_.GetOrAdd(TypeKey{type, access_mode}, [&]() -> const core::type::Type* {
switch (type->kind()) {
case spvtools::opt::analysis::Type::kVoid:
return ty_.void_();
case spvtools::opt::analysis::Type::kBool:
return ty_.bool_();
case spvtools::opt::analysis::Type::kInteger: {
auto* int_ty = type->AsInteger();
TINT_ASSERT_OR_RETURN_VALUE(int_ty->width() == 32, ty_.void_());
if (int_ty->IsSigned()) {
return ty_.i32();
} else {
return ty_.u32();
}
}
case spvtools::opt::analysis::Type::kFloat: {
auto* float_ty = type->AsFloat();
if (float_ty->width() == 16) {
return ty_.f16();
} else if (float_ty->width() == 32) {
return ty_.f32();
} else {
TINT_UNREACHABLE()
<< "unsupported floating point type width: " << float_ty->width();
return ty_.void_();
}
}
case spvtools::opt::analysis::Type::kVector: {
auto* vec_ty = type->AsVector();
TINT_ASSERT_OR_RETURN_VALUE(vec_ty->element_count() <= 4, ty_.void_());
return ty_.vec(Type(vec_ty->element_type()), vec_ty->element_count());
}
case spvtools::opt::analysis::Type::kMatrix: {
auto* mat_ty = type->AsMatrix();
TINT_ASSERT_OR_RETURN_VALUE(mat_ty->element_count() <= 4, ty_.void_());
return ty_.mat(As<core::type::Vector>(Type(mat_ty->element_type())),
mat_ty->element_count());
}
case spvtools::opt::analysis::Type::kArray:
return EmitArray(type->AsArray());
case spvtools::opt::analysis::Type::kStruct:
return EmitStruct(type->AsStruct());
case spvtools::opt::analysis::Type::kPointer: {
auto* ptr_ty = type->AsPointer();
return ty_.ptr(AddressSpace(ptr_ty->storage_class()),
Type(ptr_ty->pointee_type()), access_mode);
}
default:
TINT_UNIMPLEMENTED() << "unhandled SPIR-V type: " << type->str();
return ty_.void_();
}
});
}
/// @param id a SPIR-V result ID for a type declaration instruction
/// @param access_mode an optional access mode (for pointers)
/// @returns a Tint type object
const core::type::Type* Type(uint32_t id, core::Access access_mode = core::Access::kUndefined) {
return Type(spirv_context_->get_type_mgr()->GetType(id), access_mode);
}
/// @param arr_ty a SPIR-V array object
/// @returns a Tint array object
const core::type::Type* EmitArray(const spvtools::opt::analysis::Array* arr_ty) {
const auto& length = arr_ty->length_info();
TINT_ASSERT_OR_RETURN_VALUE(!length.words.empty(), ty_.void_());
if (length.words[0] != spvtools::opt::analysis::Array::LengthInfo::kConstant) {
TINT_UNIMPLEMENTED() << "specialized array lengths";
return ty_.void_();
}
// Get the value from the constant used for the element count.
const auto* count_const =
spirv_context_->get_constant_mgr()->FindDeclaredConstant(length.id);
TINT_ASSERT_OR_RETURN_VALUE(count_const, ty_.void_());
const uint64_t count_val = count_const->GetZeroExtendedValue();
TINT_ASSERT_OR_RETURN_VALUE(count_val <= UINT32_MAX, ty_.void_());
// TODO(crbug.com/1907): Handle decorations that affect the array layout.
return ty_.array(Type(arr_ty->element_type()), static_cast<uint32_t>(count_val));
}
/// @param struct_ty a SPIR-V struct object
/// @returns a Tint struct object
const core::type::Type* EmitStruct(const spvtools::opt::analysis::Struct* struct_ty) {
if (struct_ty->NumberOfComponents() == 0) {
TINT_ICE() << "empty structures are not supported";
return ty_.void_();
}
// Build a list of struct members.
uint32_t current_size = 0u;
Vector<core::type::StructMember*, 4> members;
for (uint32_t i = 0; i < struct_ty->NumberOfComponents(); i++) {
auto* member_ty = Type(struct_ty->element_types()[i]);
uint32_t align = std::max<uint32_t>(member_ty->Align(), 1u);
uint32_t offset = tint::RoundUp(align, current_size);
core::type::StructMemberAttributes attributes;
auto interpolation = [&]() -> core::Interpolation& {
// Create the interpolation field with the default values on first call.
if (!attributes.interpolation.has_value()) {
attributes.interpolation =
core::Interpolation{core::InterpolationType::kPerspective,
core::InterpolationSampling::kCenter};
}
return attributes.interpolation.value();
};
// Handle member decorations that affect layout or attributes.
if (struct_ty->element_decorations().count(i)) {
for (auto& deco : struct_ty->element_decorations().at(i)) {
switch (spv::Decoration(deco[0])) {
case spv::Decoration::Offset:
offset = deco[1];
break;
case spv::Decoration::BuiltIn:
attributes.builtin = Builtin(spv::BuiltIn(deco[1]));
break;
case spv::Decoration::Invariant:
attributes.invariant = true;
break;
case spv::Decoration::Location:
attributes.location = deco[1];
break;
case spv::Decoration::NoPerspective:
interpolation().type = core::InterpolationType::kLinear;
break;
case spv::Decoration::Flat:
interpolation().type = core::InterpolationType::kFlat;
break;
case spv::Decoration::Centroid:
interpolation().sampling = core::InterpolationSampling::kCentroid;
break;
case spv::Decoration::Sample:
interpolation().sampling = core::InterpolationSampling::kSample;
break;
default:
TINT_UNIMPLEMENTED() << "unhandled member decoration: " << deco[0];
break;
}
}
}
// TODO(crbug.com/tint/1907): Use OpMemberName to name it.
members.Push(ty_.Get<core::type::StructMember>(ir_.symbols.New(), member_ty, i, offset,
align, member_ty->Size(),
std::move(attributes)));
current_size = offset + member_ty->Size();
}
// TODO(crbug.com/tint/1907): Use OpName to name it.
return ty_.Struct(ir_.symbols.New(), std::move(members));
}
/// @param id a SPIR-V result ID for a function declaration instruction
/// @returns a Tint function object
core::ir::Function* Function(uint32_t id) {
return functions_.GetOrAdd(id, [&] {
return b_.Function(ty_.void_(), core::ir::Function::PipelineStage::kUndefined,
std::nullopt);
});
}
/// @param id a SPIR-V result ID
/// @returns a Tint value object
core::ir::Value* Value(uint32_t id) {
return values_.GetOrAdd(id, [&]() -> core::ir::Value* {
if (auto* c = spirv_context_->get_constant_mgr()->FindDeclaredConstant(id)) {
return b_.Constant(Constant(c));
}
TINT_UNREACHABLE() << "missing value for result ID " << id;
return nullptr;
});
}
/// @param constant a SPIR-V constant object
/// @returns a Tint constant value
const core::constant::Value* Constant(const spvtools::opt::analysis::Constant* constant) {
// Handle OpConstantNull for all types.
if (constant->AsNullConstant()) {
return ir_.constant_values.Zero(Type(constant->type()));
}
if (auto* bool_ = constant->AsBoolConstant()) {
return b_.ConstantValue(bool_->value());
}
if (auto* i = constant->AsIntConstant()) {
auto* int_ty = i->type()->AsInteger();
TINT_ASSERT_OR_RETURN_VALUE(int_ty->width() == 32, nullptr);
if (int_ty->IsSigned()) {
return b_.ConstantValue(i32(i->GetS32BitValue()));
} else {
return b_.ConstantValue(u32(i->GetU32BitValue()));
}
}
if (auto* f = constant->AsFloatConstant()) {
auto* float_ty = f->type()->AsFloat();
if (float_ty->width() == 16) {
return b_.ConstantValue(f16::FromBits(static_cast<uint16_t>(f->words()[0])));
} else if (float_ty->width() == 32) {
return b_.ConstantValue(f32(f->GetFloat()));
} else {
TINT_UNREACHABLE() << "unsupported floating point type width";
return nullptr;
}
}
if (auto* v = constant->AsVectorConstant()) {
Vector<const core::constant::Value*, 4> elements;
for (auto& el : v->GetComponents()) {
elements.Push(Constant(el));
}
return ir_.constant_values.Composite(Type(v->type()), std::move(elements));
}
if (auto* m = constant->AsMatrixConstant()) {
Vector<const core::constant::Value*, 4> columns;
for (auto& el : m->GetComponents()) {
columns.Push(Constant(el));
}
return ir_.constant_values.Composite(Type(m->type()), std::move(columns));
}
if (auto* a = constant->AsArrayConstant()) {
Vector<const core::constant::Value*, 16> elements;
for (auto& el : a->GetComponents()) {
elements.Push(Constant(el));
}
return ir_.constant_values.Composite(Type(a->type()), std::move(elements));
}
if (auto* s = constant->AsStructConstant()) {
Vector<const core::constant::Value*, 16> elements;
for (auto& el : s->GetComponents()) {
elements.Push(Constant(el));
}
return ir_.constant_values.Composite(Type(s->type()), std::move(elements));
}
TINT_UNIMPLEMENTED() << "unhandled constant type";
return nullptr;
}
/// Register an IR value for a SPIR-V result ID.
/// @param result_id the SPIR-V result ID
/// @param value the IR value
void AddValue(uint32_t result_id, core::ir::Value* value) { values_.Add(result_id, value); }
/// Emit an instruction to the current block.
/// @param inst the instruction to emit
/// @param result_id an optional SPIR-V result ID to register the instruction result for
void Emit(core::ir::Instruction* inst, uint32_t result_id = 0) {
current_block_->Append(inst);
if (result_id != 0) {
TINT_ASSERT_OR_RETURN(inst->Results().Length() == 1u);
AddValue(result_id, inst->Result(0));
}
}
/// Emit the module-scope variables.
void EmitModuleScopeVariables() {
for (auto& inst : spirv_context_->module()->types_values()) {
if (inst.opcode() == spv::Op::OpVariable) {
EmitVar(inst);
}
}
}
/// Emit the functions.
void EmitFunctions() {
for (auto& func : *spirv_context_->module()) {
Vector<core::ir::FunctionParam*, 4> params;
func.ForEachParam([&](spvtools::opt::Instruction* spirv_param) {
auto* param = b_.FunctionParam(Type(spirv_param->type_id()));
values_.Add(spirv_param->result_id(), param);
params.Push(param);
});
current_function_ = Function(func.result_id());
current_function_->SetParams(std::move(params));
current_function_->SetReturnType(Type(func.type_id()));
functions_.Add(func.result_id(), current_function_);
EmitBlock(current_function_->Block(), *func.entry());
}
}
/// Emit entry point attributes.
void EmitEntryPoints() {
// Handle OpEntryPoint declarations.
for (auto& entry_point : spirv_context_->module()->entry_points()) {
auto model = entry_point.GetSingleWordInOperand(0);
auto* func = Function(entry_point.GetSingleWordInOperand(1));
// Set the pipeline stage.
switch (spv::ExecutionModel(model)) {
case spv::ExecutionModel::GLCompute:
func->SetStage(core::ir::Function::PipelineStage::kCompute);
break;
case spv::ExecutionModel::Fragment:
func->SetStage(core::ir::Function::PipelineStage::kFragment);
break;
case spv::ExecutionModel::Vertex:
func->SetStage(core::ir::Function::PipelineStage::kVertex);
break;
default:
TINT_UNIMPLEMENTED() << "unhandled execution model: " << model;
}
// Set the entry point name.
ir_.SetName(func, entry_point.GetOperand(2).AsString());
}
// Handle OpExecutionMode declarations.
for (auto& execution_mode : spirv_context_->module()->execution_modes()) {
auto* func = functions_.GetOr(execution_mode.GetSingleWordInOperand(0), nullptr);
auto mode = execution_mode.GetSingleWordInOperand(1);
TINT_ASSERT_OR_RETURN(func);
switch (spv::ExecutionMode(mode)) {
case spv::ExecutionMode::LocalSize:
func->SetWorkgroupSize(execution_mode.GetSingleWordInOperand(2),
execution_mode.GetSingleWordInOperand(3),
execution_mode.GetSingleWordInOperand(4));
break;
case spv::ExecutionMode::DepthReplacing:
case spv::ExecutionMode::OriginUpperLeft:
// These are ignored as they are implicitly supported by Tint IR.
break;
default:
TINT_UNIMPLEMENTED() << "unhandled execution mode: " << mode;
}
}
}
/// Emit the contents of SPIR-V block @p src into Tint IR block @p dst.
/// @param dst the Tint IR block to append to
/// @param src the SPIR-V block to emit
void EmitBlock(core::ir::Block* dst, const spvtools::opt::BasicBlock& src) {
TINT_SCOPED_ASSIGNMENT(current_block_, dst);
for (auto& inst : src) {
switch (inst.opcode()) {
case spv::Op::OpAccessChain:
case spv::Op::OpInBoundsAccessChain:
EmitAccess(inst);
break;
case spv::Op::OpCompositeConstruct:
EmitConstruct(inst);
break;
case spv::Op::OpCompositeExtract:
EmitCompositeExtract(inst);
break;
case spv::Op::OpFAdd:
EmitBinary(inst, core::BinaryOp::kAdd);
break;
case spv::Op::OpFMul:
EmitBinary(inst, core::BinaryOp::kMultiply);
break;
case spv::Op::OpFunctionCall:
EmitFunctionCall(inst);
break;
case spv::Op::OpLoad:
Emit(b_.Load(Value(inst.GetSingleWordOperand(2))), inst.result_id());
break;
case spv::Op::OpReturn:
Emit(b_.Return(current_function_));
break;
case spv::Op::OpReturnValue:
Emit(b_.Return(current_function_, Value(inst.GetSingleWordOperand(0))));
break;
case spv::Op::OpStore:
Emit(b_.Store(Value(inst.GetSingleWordOperand(0)),
Value(inst.GetSingleWordOperand(1))));
break;
case spv::Op::OpVariable:
EmitVar(inst);
break;
default:
TINT_UNIMPLEMENTED()
<< "unhandled SPIR-V instruction: " << static_cast<uint32_t>(inst.opcode());
}
}
}
/// @param inst the SPIR-V instruction for OpAccessChain
void EmitAccess(const spvtools::opt::Instruction& inst) {
Vector<core::ir::Value*, 4> indices;
for (uint32_t i = 3; i < inst.NumOperandWords(); i++) {
indices.Push(Value(inst.GetSingleWordOperand(i)));
}
auto* base = Value(inst.GetSingleWordOperand(2));
// Propagate the access mode of the base object.
auto access_mode = core::Access::kUndefined;
if (auto* ptr = base->Type()->As<core::type::Pointer>()) {
access_mode = ptr->Access();
}
auto* access = b_.Access(Type(inst.type_id(), access_mode), base, std::move(indices));
Emit(access, inst.result_id());
}
/// @param inst the SPIR-V instruction
/// @param op the binary operator to use
void EmitBinary(const spvtools::opt::Instruction& inst, core::BinaryOp op) {
auto* lhs = Value(inst.GetSingleWordOperand(2));
auto* rhs = Value(inst.GetSingleWordOperand(3));
auto* binary = b_.Binary(op, Type(inst.type_id()), lhs, rhs);
Emit(binary, inst.result_id());
}
/// @param inst the SPIR-V instruction for OpCompositeExtract
void EmitCompositeExtract(const spvtools::opt::Instruction& inst) {
Vector<core::ir::Value*, 4> indices;
for (uint32_t i = 3; i < inst.NumOperandWords(); i++) {
indices.Push(b_.Constant(u32(inst.GetSingleWordOperand(i))));
}
auto* object = Value(inst.GetSingleWordOperand(2));
auto* access = b_.Access(Type(inst.type_id()), object, std::move(indices));
Emit(access, inst.result_id());
}
/// @param inst the SPIR-V instruction for OpCompositeConstruct
void EmitConstruct(const spvtools::opt::Instruction& inst) {
Vector<core::ir::Value*, 4> values;
for (uint32_t i = 2; i < inst.NumOperandWords(); i++) {
values.Push(Value(inst.GetSingleWordOperand(i)));
}
auto* construct = b_.Construct(Type(inst.type_id()), std::move(values));
Emit(construct, inst.result_id());
}
/// @param inst the SPIR-V instruction for OpFunctionCall
void EmitFunctionCall(const spvtools::opt::Instruction& inst) {
// TODO(crbug.com/tint/1907): Capture result.
Vector<core::ir::Value*, 4> args;
for (uint32_t i = 3; i < inst.NumOperandWords(); i++) {
args.Push(Value(inst.GetSingleWordOperand(i)));
}
Emit(b_.Call(Function(inst.GetSingleWordInOperand(0)), std::move(args)), inst.result_id());
}
/// @param inst the SPIR-V instruction for OpVariable
void EmitVar(const spvtools::opt::Instruction& inst) {
// Handle decorations.
std::optional<uint32_t> group;
std::optional<uint32_t> binding;
core::Access access_mode = core::Access::kUndefined;
core::ir::IOAttributes io_attributes;
auto interpolation = [&]() -> core::Interpolation& {
// Create the interpolation field with the default values on first call.
if (!io_attributes.interpolation.has_value()) {
io_attributes.interpolation = core::Interpolation{
core::InterpolationType::kPerspective, core::InterpolationSampling::kCenter};
}
return io_attributes.interpolation.value();
};
for (auto* deco :
spirv_context_->get_decoration_mgr()->GetDecorationsFor(inst.result_id(), false)) {
auto d = deco->GetSingleWordOperand(1);
switch (spv::Decoration(d)) {
case spv::Decoration::NonWritable:
access_mode = core::Access::kRead;
break;
case spv::Decoration::DescriptorSet:
group = deco->GetSingleWordOperand(2);
break;
case spv::Decoration::Binding:
binding = deco->GetSingleWordOperand(2);
break;
case spv::Decoration::BuiltIn:
io_attributes.builtin = Builtin(spv::BuiltIn(deco->GetSingleWordOperand(2)));
break;
case spv::Decoration::Invariant:
io_attributes.invariant = true;
break;
case spv::Decoration::Location:
io_attributes.location = deco->GetSingleWordOperand(2);
break;
case spv::Decoration::NoPerspective:
interpolation().type = core::InterpolationType::kLinear;
break;
case spv::Decoration::Flat:
interpolation().type = core::InterpolationType::kFlat;
break;
case spv::Decoration::Centroid:
interpolation().sampling = core::InterpolationSampling::kCentroid;
break;
case spv::Decoration::Sample:
interpolation().sampling = core::InterpolationSampling::kSample;
break;
default:
TINT_UNIMPLEMENTED() << "unhandled decoration " << d;
break;
}
}
auto* var = b_.Var(Type(inst.type_id(), access_mode)->As<core::type::Pointer>());
if (inst.NumOperands() > 3) {
var->SetInitializer(Value(inst.GetSingleWordOperand(3)));
}
if (group || binding) {
TINT_ASSERT(group && binding);
var->SetBindingPoint(group.value(), binding.value());
}
var->SetAttributes(std::move(io_attributes));
Emit(var, inst.result_id());
}
private:
/// TypeKey describes a SPIR-V type with an access mode.
struct TypeKey {
/// The SPIR-V type object.
const spvtools::opt::analysis::Type* type;
/// The access mode.
core::Access access_mode;
// Equality operator for TypeKey.
bool operator==(const TypeKey& other) const {
return type == other.type && access_mode == other.access_mode;
}
/// @returns the hash code of the TypeKey
tint::HashCode HashCode() const { return Hash(type, access_mode); }
};
/// The generated IR module.
core::ir::Module ir_;
/// The Tint IR builder.
core::ir::Builder b_{ir_};
/// The Tint type manager.
core::type::Manager& ty_{ir_.Types()};
/// The Tint IR function that is currently being emitted.
core::ir::Function* current_function_ = nullptr;
/// The Tint IR block that is currently being emitted.
core::ir::Block* current_block_ = nullptr;
/// A map from a SPIR-V type declaration to the corresponding Tint type object.
Hashmap<TypeKey, const core::type::Type*, 16> types_;
/// A map from a SPIR-V function definition result ID to the corresponding Tint function object.
Hashmap<uint32_t, core::ir::Function*, 8> functions_;
/// A map from a SPIR-V result ID to the corresponding Tint value object.
Hashmap<uint32_t, core::ir::Value*, 8> values_;
/// The SPIR-V context containing the SPIR-V tools intermediate representation.
std::unique_ptr<spvtools::opt::IRContext> spirv_context_;
};
} // namespace
Result<core::ir::Module> Parse(Slice<const uint32_t> spirv) {
return Parser{}.Run(spirv);
}
} // namespace tint::spirv::reader