Upgrade to C++20 and use std::span

This commit is contained in:
ReinUsesLisp 2020-07-29 05:46:50 -03:00
parent eefca56afd
commit c4ea8f4b76
18 changed files with 119 additions and 102 deletions

View file

@ -17,7 +17,7 @@ if (NOT CMAKE_BUILD_TYPE)
endif()
# Set hard requirements for C++
set(CMAKE_CXX_STANDARD 17)
set(CMAKE_CXX_STANDARD 20)
set(CMAKE_CXX_STANDARD_REQUIRED ON)
set(CMAKE_CXX_EXTENSIONS OFF)

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@ -6,13 +6,16 @@
#pragma once
#include <array>
#include <cstdint>
#include <memory>
#include <optional>
#include <span>
#include <string>
#include <unordered_set>
#include <variant>
#include <vector>
#include <spirv/unified1/spirv.hpp11>
namespace Sirit {
@ -50,23 +53,25 @@ public:
/// Adds an entry point.
void AddEntryPoint(spv::ExecutionModel execution_model, Id entry_point, std::string name,
const std::vector<Id>& interfaces = {});
std::span<const Id> interfaces = {});
/// Adds an entry point.
template <typename... Ts>
void AddEntryPoint(spv::ExecutionModel execution_model, Id entry_point, std::string name,
Ts&&... interfaces) {
AddEntryPoint(execution_model, std::move(entry_point), name, {interfaces...});
AddEntryPoint(execution_model, std::move(entry_point), name,
std::span<const Id>{std::array{interfaces...}});
}
/// Declare an execution mode for an entry point.
void AddExecutionMode(Id entry_point, spv::ExecutionMode mode,
const std::vector<Literal>& literals = {});
std::span<const Literal> literals = {});
/// Declare an execution mode for an entry point.
template <typename... Ts>
void AddExecutionMode(Id entry_point, spv::ExecutionMode mode, Ts&&... literals) {
AddExecutionMode(entry_point, mode, {literals...});
const Literal stack_literals[] = {std::forward<Ts>(literals)...};
AddExecutionMode(entry_point, mode, std::span<const Literal>{stack_literals});
}
/**
@ -136,12 +141,12 @@ public:
Id TypeRuntimeArray(Id element_type);
/// Returns type struct.
Id TypeStruct(const std::vector<Id>& members = {});
Id TypeStruct(std::span<const Id> members = {});
/// Returns type struct.
template <typename... Ts>
Id TypeStruct(Ts&&... members) {
return TypeStruct({members...});
return TypeStruct(std::span<const Id>{std::array{members...}});
}
/// Returns type opaque.
@ -151,12 +156,12 @@ public:
Id TypePointer(spv::StorageClass storage_class, Id type);
/// Returns type function.
Id TypeFunction(Id return_type, const std::vector<Id>& arguments = {});
Id TypeFunction(Id return_type, std::span<const Id> arguments = {});
/// Returns type function.
template <typename... Ts>
Id TypeFunction(Id return_type, Ts&&... arguments) {
return OpTypeFunction(return_type, {arguments...});
return TypeFunction(return_type, std::span<const Id>{std::array{arguments...}});
}
/// Returns type event.
@ -186,12 +191,12 @@ public:
Id Constant(Id result_type, const Literal& literal);
/// Returns a numeric scalar constant.
Id ConstantComposite(Id result_type, const std::vector<Id>& constituents);
Id ConstantComposite(Id result_type, std::span<const Id> constituents);
/// Returns a numeric scalar constant.
template <typename... Ts>
Id ConstantComposite(Id result_type, Ts&&... constituents) {
return ConstantComposite(result_type, {constituents...});
return ConstantComposite(result_type, std::span<const Id>{std::array{constituents...}});
}
/// Returns a sampler constant.
@ -210,25 +215,26 @@ public:
Id OpFunctionEnd();
/// Call a function.
Id OpFunctionCall(Id result_type, Id function, const std::vector<Id>& arguments = {});
Id OpFunctionCall(Id result_type, Id function, std::span<const Id> arguments = {});
/// Call a function.
template <typename... Ts>
Id OpFunctionCall(Id result_type, Id function, Ts&&... arguments) {
return OpFunctionCall(result_type, function, {arguments...});
return OpFunctionCall(result_type, function, std::span<const Id>{std::array{arguments...}});
}
// Flow
/// Declare a structured loop.
Id OpLoopMerge(Id merge_block, Id continue_target, spv::LoopControlMask loop_control,
const std::vector<Id>& literals = {});
std::span<const Id> literals = {});
/// Declare a structured loop.
template <typename... Ts>
Id OpLoopMerge(Id merge_block, Id continue_target, spv::LoopControlMask loop_control,
Ts&&... literals) {
return OpLoopMerge(merge_block, continue_target, loop_control, {literals...});
return OpLoopMerge(merge_block, continue_target, loop_control,
std::span<const Id>{std::array{literals...}});
}
/// Declare a structured selection.
@ -251,8 +257,8 @@ public:
std::uint32_t true_weight = 0, std::uint32_t false_weight = 0);
/// Multi-way branch to one of the operand label.
Id OpSwitch(Id selector, Id default_label, const std::vector<Literal>& literals,
const std::vector<Id>& labels);
Id OpSwitch(Id selector, Id default_label, std::span<const Literal> literals,
std::span<const Id> labels);
/// Returns with no value from a function with void return type.
Id OpReturn();
@ -284,7 +290,8 @@ public:
/// Allocate an object in memory, resulting in a copy to it.
Id OpVariable(Id result_type, spv::StorageClass storage_class, Id initializer = nullptr);
/// Form a pointer to a texel of an image. Use of such a pointer is limited to atomic operations.
/// Form a pointer to a texel of an image. Use of such a pointer is limited to atomic
/// operations.
Id OpImageTexelPointer(Id result_type, Id image, Id coordinate, Id sample);
/// Load through a pointer.
@ -294,12 +301,12 @@ public:
Id OpStore(Id pointer, Id object, std::optional<spv::MemoryAccessMask> memory_access = {});
/// Create a pointer into a composite object that can be used with OpLoad and OpStore.
Id OpAccessChain(Id result_type, Id base, const std::vector<Id>& indexes = {});
Id OpAccessChain(Id result_type, Id base, std::span<const Id> indexes = {});
/// Create a pointer into a composite object that can be used with OpLoad and OpStore.
template <typename... Ts>
Id OpAccessChain(Id result_type, Id base, Ts&&... indexes) {
return OpAccessChain(result_type, base, {indexes...});
return OpAccessChain(result_type, base, std::span<const Id>{std::array{indexes...}});
}
/// Extract a single, dynamically selected, component of a vector.
@ -310,50 +317,56 @@ public:
/// Make a copy of a composite object, while modifying one part of it.
Id OpCompositeInsert(Id result_type, Id object, Id composite,
const std::vector<Literal>& indexes = {});
std::span<const Literal> indexes = {});
/// Make a copy of a composite object, while modifying one part of it.
template <typename... Ts>
Id OpCompositeInsert(Id result_type, Id object, Id composite, Ts&&... indexes) {
return OpCompositeInsert(result_type, object, composite, {indexes...});
const Literal stack_indexes[] = {std::forward<Ts>(indexes)...};
return OpCompositeInsert(result_type, object, composite,
std::span<const Literal>{stack_indexes});
}
/// Extract a part of a composite object.
Id OpCompositeExtract(Id result_type, Id composite, const std::vector<Literal>& indexes = {});
Id OpCompositeExtract(Id result_type, Id composite, std::span<const Literal> indexes = {});
/// Extract a part of a composite object.
template <typename... Ts>
Id OpCompositeExtract(Id result_type, Id composite, Ts&&... indexes) {
return OpCompositeExtract(result_type, composite, {indexes...});
const Literal stack_indexes[] = {std::forward<Ts>(indexes)...};
return OpCompositeExtract(result_type, composite, std::span<const Literal>{stack_indexes});
}
/// Construct a new composite object from a set of constituent objects that will fully form it.
Id OpCompositeConstruct(Id result_type, const std::vector<Id>& ids);
Id OpCompositeConstruct(Id result_type, std::span<const Id> ids);
/// Construct a new composite object from a set of constituent objects that will fully form it.
template <typename... Ts>
Id OpCompositeConstruct(Id result_type, Ts&&... ids) {
return OpCompositeConstruct(result_type, {ids...});
return OpCompositeConstruct(result_type, std::span<const Id>{std::array{ids...}});
}
// Annotation
/// Add a decoration to target.
Id Decorate(Id target, spv::Decoration decoration, const std::vector<Literal>& literals = {});
Id Decorate(Id target, spv::Decoration decoration, std::span<const Literal> literals = {});
/// Add a decoration to target.
template <typename... Ts>
Id Decorate(Id target, spv::Decoration decoration, Ts&&... literals) {
return Decorate(target, decoration, {literals...});
const Literal stack_literals[] = {std::forward<Ts>(literals)...};
return Decorate(target, decoration, std::span<const Literal>{stack_literals});
}
Id MemberDecorate(Id structure_type, Literal member, spv::Decoration decoration,
const std::vector<Literal>& literals = {});
std::span<const Literal> literals = {});
template <typename... Ts>
Id MemberDecorate(Id structure_type, Literal member, spv::Decoration decoration,
Ts&&... literals) {
return MemberDecorate(structure_type, member, decoration, {literals...});
const Literal stack_literals[] = {std::forward<Ts>(literals)...};
return MemberDecorate(structure_type, member, decoration,
std::span<const Literal>{stack_literals});
}
// Misc
@ -608,13 +621,13 @@ public:
// Extensions
/// Execute an instruction in an imported set of extended instructions.
Id OpExtInst(Id result_type, Id set, std::uint32_t instruction,
const std::vector<Id>& operands);
Id OpExtInst(Id result_type, Id set, std::uint32_t instruction, std::span<const Id> operands);
/// Execute an instruction in an imported set of extended instructions.
template <typename... Ts>
Id OpExtInst(Id result_type, Id set, std::uint32_t instruction, Ts&&... operands) {
return OpExtInst(result_type, set, instruction, {operands...});
return OpExtInst(result_type, set, instruction,
std::span<const Id>{std::array{operands...}});
}
/// Result is x if x >= 0; otherwise result is -x.
@ -764,86 +777,88 @@ public:
/// Sample an image with an implicit level of detail.
Id OpImageSampleImplicitLod(Id result_type, Id sampled_image, Id coordinate,
std::optional<spv::ImageOperandsMask> image_operands = {},
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Sample an image with an implicit level of detail.
template <typename... Ts>
Id OpImageSampleImplicitLod(Id result_type, Id sampled_image, Id coordinate,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageSampleImplicitLod(result_type, sampled_image, coordinate, image_operands,
{operands...});
std::span<const Id>{std::array{operands...}});
}
/// Sample an image using an explicit level of detail.
Id OpImageSampleExplicitLod(Id result_type, Id sampled_image, Id coordinate,
spv::ImageOperandsMask image_operands,
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Sample an image using an explicit level of detail.
template <typename... Ts>
Id OpImageSampleExplicitLod(Id result_type, Id sampled_image, Id coordinate,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageSampleExplicitLod(result_type, sampled_image, coordinate, image_operands,
{operands...});
std::span<const Id>{std::array{operands...}});
}
/// Sample an image doing depth-comparison with an implicit level of detail.
Id OpImageSampleDrefImplicitLod(Id result_type, Id sampled_image, Id coordinate, Id dref,
std::optional<spv::ImageOperandsMask> image_operands = {},
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Sample an image doing depth-comparison with an implicit level of detail.
template <typename... Ts>
Id OpImageSampleDrefImplicitLod(Id result_type, Id sampled_image, Id coordinate, Id dref,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageSampleDrefImplicitLod(result_type, sampled_image, coordinate, dref,
image_operands, {operands...});
image_operands,
std::span<const Id>{std::array{operands...}});
}
/// Sample an image doing depth-comparison using an explicit level of detail.
Id OpImageSampleDrefExplicitLod(Id result_type, Id sampled_image, Id coordinate, Id dref,
spv::ImageOperandsMask image_operands,
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Sample an image doing depth-comparison using an explicit level of detail.
template <typename... Ts>
Id OpImageSampleDrefExplicitLod(Id result_type, Id sampled_image, Id coordinate, Id dref,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageSampleDrefExplicitLod(result_type, sampled_image, coordinate, dref,
image_operands, {operands...});
image_operands,
std::span<const Id>{std::array{operands...}});
}
/// Sample an image with with a project coordinate and an implicit level of detail.
Id OpImageSampleProjImplicitLod(Id result_type, Id sampled_image, Id coordinate,
std::optional<spv::ImageOperandsMask> image_operands = {},
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Sample an image with with a project coordinate and an implicit level of detail.
template <typename... Ts>
Id OpImageSampleProjImplicitLod(Id result_type, Id sampled_image, Id coordinate,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageSampleProjImplicitLod(result_type, sampled_image, coordinate, image_operands,
{operands...});
std::span<const Id>{std::array{operands...}});
}
/// Sample an image with a project coordinate using an explicit level of detail.
Id OpImageSampleProjExplicitLod(Id result_type, Id sampled_image, Id coordinate,
spv::ImageOperandsMask image_operands,
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Sample an image with a project coordinate using an explicit level of detail.
template <typename... Ts>
Id OpImageSampleProjExplicitLod(Id result_type, Id sampled_image, Id coordinate,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageSampleProjExplicitLod(result_type, sampled_image, coordinate, image_operands,
{operands...});
std::span<const Id>{std::array{operands...}});
}
/// Sample an image with a project coordinate, doing depth-comparison, with an implicit level of
/// detail.
Id OpImageSampleProjDrefImplicitLod(Id result_type, Id sampled_image, Id coordinate, Id dref,
std::optional<spv::ImageOperandsMask> image_operands = {},
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Sample an image with a project coordinate, doing depth-comparison, with an implicit level of
/// detail.
@ -851,14 +866,15 @@ public:
Id OpImageSampleProjDrefImplicitLod(Id result_type, Id sampled_image, Id coordinate, Id dref,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageSampleProjDrefImplicitLod(result_type, sampled_image, coordinate, dref,
image_operands, {operands...});
image_operands,
std::span<const Id>{std::array{operands...}});
}
/// Sample an image with a project coordinate, doing depth-comparison, using an explicit level
/// of detail.
Id OpImageSampleProjDrefExplicitLod(Id result_type, Id sampled_image, Id coordinate, Id dref,
spv::ImageOperandsMask image_operands,
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Sample an image with a project coordinate, doing depth-comparison, using an explicit level
/// of detail.
@ -866,69 +882,73 @@ public:
Id OpImageSampleProjDrefExplicitLod(Id result_type, Id sampled_image, Id coordinate, Id dref,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageSampleProjDrefExplicitLod(result_type, sampled_image, coordinate, dref,
image_operands, {operands...});
image_operands,
std::span<const Id>{std::array{operands...}});
}
/// Fetch a single texel from an image whose Sampled operand is 1.
Id OpImageFetch(Id result_type, Id sampled_image, Id coordinate,
std::optional<spv::ImageOperandsMask> image_operands = {},
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Fetch a single texel from an image whose Sampled operand is 1.
template <typename... Ts>
Id OpImageFetch(Id result_type, Id sampled_image, Id coordinate,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageFetch(result_type, sampled_image, coordinate, image_operands, {operands...});
return OpImageFetch(result_type, sampled_image, coordinate, image_operands,
std::span<const Id>{std::array{operands...}});
}
/// Gathers the requested component from four texels.
Id OpImageGather(Id result_type, Id sampled_image, Id coordinate, Id component,
std::optional<spv::ImageOperandsMask> image_operands = {},
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Gathers the requested component from four texels.
template <typename... Ts>
Id OpImageGather(Id result_type, Id sampled_image, Id coordinate, Id component,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageGather(result_type, sampled_image, coordinate, component, image_operands,
{operands...});
std::span<const Id>{std::array{operands...}});
}
/// Gathers the requested depth-comparison from four texels.
Id OpImageDrefGather(Id result_type, Id sampled_image, Id coordinate, Id dref,
std::optional<spv::ImageOperandsMask> image_operands = {},
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Gathers the requested depth-comparison from four texels.
template <typename... Ts>
Id OpImageDrefGather(Id result_type, Id sampled_image, Id coordinate, Id dref,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageDrefGather(result_type, sampled_image, coordinate, dref, image_operands,
{operands...});
std::span<const Id>{std::array{operands...}});
}
/// Read a texel from an image without a sampler.
Id OpImageRead(Id result_type, Id sampled_image, Id coordinate,
std::optional<spv::ImageOperandsMask> image_operands = {},
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Read a texel from an image without a sampler.
template <typename... Ts>
Id OpImageRead(Id result_type, Id sampled_image, Id coordinate,
spv::ImageOperandsMask image_operands, Ts&&... operands) {
return OpImageRead(result_type, sampled_image, coordinate, image_operands, {operands...});
return OpImageRead(result_type, sampled_image, coordinate, image_operands,
std::span<const Id>{std::array{operands...}});
}
/// Write a texel to an image without a sampler.
Id OpImageWrite(Id image, Id coordinate, Id texel,
std::optional<spv::ImageOperandsMask> image_operands = {},
const std::vector<Id>& operands = {});
std::span<const Id> operands = {});
/// Write a texel to an image without a sampler.
template <typename... Ts>
Id OpImageWrite(Id image, Id coordinate, Id texel, spv::ImageOperandsMask image_operands,
Ts&&... operands) {
return OpImageWrite(image, coordinate, texel, image_operands, {operands...});
return OpImageWrite(image, coordinate, texel, image_operands,
std::span<const Id>{std::array{operands...}});
}
/// Extract the image from a sampled image.

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@ -12,7 +12,7 @@
namespace Sirit {
Id Module::Decorate(Id target, spv::Decoration decoration, const std::vector<Literal>& literals) {
Id Module::Decorate(Id target, spv::Decoration decoration, std::span<const Literal> literals) {
auto op{std::make_unique<Op>(spv::Op::OpDecorate)};
op->Add(target);
op->Add(static_cast<u32>(decoration));
@ -22,7 +22,7 @@ Id Module::Decorate(Id target, spv::Decoration decoration, const std::vector<Lit
}
Id Module::MemberDecorate(Id structure_type, Literal member, spv::Decoration decoration,
const std::vector<Literal>& literals) {
std::span<const Literal> literals) {
auto op{std::make_unique<Op>(spv::Op::OpMemberDecorate)};
op->Add(structure_type);
op->Add(member);

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@ -24,7 +24,7 @@ Id Module::Constant(Id result_type, const Literal& literal) {
return AddDeclaration(std::move(op));
}
Id Module::ConstantComposite(Id result_type, const std::vector<Id>& constituents) {
Id Module::ConstantComposite(Id result_type, std::span<const Id> constituents) {
auto op{std::make_unique<Op>(spv::Op::OpConstantComposite, bound, result_type)};
op->Add(constituents);
return AddDeclaration(std::move(op));

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@ -12,7 +12,7 @@
namespace Sirit {
Id Module::OpExtInst(Id result_type, Id set, u32 instruction, const std::vector<Id>& operands) {
Id Module::OpExtInst(Id result_type, Id set, u32 instruction, std::span<const Id> operands) {
auto op{std::make_unique<Op>(spv::Op::OpExtInst, bound++, result_type)};
op->Add(set);
op->Add(instruction);

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@ -13,7 +13,7 @@
namespace Sirit {
Id Module::OpLoopMerge(Id merge_block, Id continue_target, spv::LoopControlMask loop_control,
const std::vector<Id>& literals) {
std::span<const Id> literals) {
auto op{std::make_unique<Op>(spv::Op::OpLoopMerge)};
op->Add(merge_block);
op->Add(continue_target);
@ -52,8 +52,8 @@ Id Module::OpBranchConditional(Id condition, Id true_label, Id false_label, u32
return AddCode(std::move(op));
}
Id Module::OpSwitch(Id selector, Id default_label, const std::vector<Literal>& literals,
const std::vector<Id>& labels) {
Id Module::OpSwitch(Id selector, Id default_label, std::span<const Literal> literals,
std::span<const Id> labels) {
const std::size_t size = literals.size();
assert(literals.size() == labels.size());
auto op{std::make_unique<Op>(spv::Op::OpSwitch)};

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@ -21,7 +21,7 @@ Id Module::OpFunctionEnd() {
return AddCode(spv::Op::OpFunctionEnd);
}
Id Module::OpFunctionCall(Id result_type, Id function, const std::vector<Id>& arguments) {
Id Module::OpFunctionCall(Id result_type, Id function, std::span<const Id> arguments) {
auto op{std::make_unique<Op>(spv::Op::OpFunctionCall, bound++, result_type)};
op->Add(function);
op->Add(arguments);

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@ -11,7 +11,7 @@
namespace Sirit {
static void AddImageOperands(Op* op, std::optional<spv::ImageOperandsMask> image_operands,
const std::vector<Id>& operands) {
std::span<const Id> operands) {
if (!image_operands)
return;
op->Add(static_cast<u32>(*image_operands));
@ -21,7 +21,7 @@ static void AddImageOperands(Op* op, std::optional<spv::ImageOperandsMask> image
#define DEFINE_IMAGE_OP(opcode) \
Id Module::opcode(Id result_type, Id sampled_image, Id coordinate, \
std::optional<spv::ImageOperandsMask> image_operands, \
const std::vector<Id>& operands) { \
std::span<const Id> operands) { \
auto op{std::make_unique<Op>(spv::Op::opcode, bound++, result_type)}; \
op->Add(sampled_image); \
op->Add(coordinate); \
@ -31,7 +31,7 @@ static void AddImageOperands(Op* op, std::optional<spv::ImageOperandsMask> image
#define DEFINE_IMAGE_EXP_OP(opcode) \
Id Module::opcode(Id result_type, Id sampled_image, Id coordinate, \
spv::ImageOperandsMask image_operands, const std::vector<Id>& operands) { \
spv::ImageOperandsMask image_operands, std::span<const Id> operands) { \
auto op{std::make_unique<Op>(spv::Op::opcode, bound++, result_type)}; \
op->Add(sampled_image); \
op->Add(coordinate); \
@ -43,7 +43,7 @@ static void AddImageOperands(Op* op, std::optional<spv::ImageOperandsMask> image
#define DEFINE_IMAGE_EXTRA_OP(opcode) \
Id Module::opcode(Id result_type, Id sampled_image, Id coordinate, Id extra, \
std::optional<spv::ImageOperandsMask> image_operands, \
const std::vector<Id>& operands) { \
std::span<const Id> operands) { \
auto op{std::make_unique<Op>(spv::Op::opcode, bound++, result_type)}; \
op->Add(sampled_image); \
op->Add(coordinate); \
@ -54,7 +54,7 @@ static void AddImageOperands(Op* op, std::optional<spv::ImageOperandsMask> image
#define DEFINE_IMAGE_EXTRA_EXP_OP(opcode) \
Id Module::opcode(Id result_type, Id sampled_image, Id coordinate, Id extra, \
spv::ImageOperandsMask image_operands, const std::vector<Id>& operands) { \
spv::ImageOperandsMask image_operands, std::span<const Id> operands) { \
auto op{std::make_unique<Op>(spv::Op::opcode, bound++, result_type)}; \
op->Add(sampled_image); \
op->Add(coordinate); \
@ -106,7 +106,7 @@ Id Module::OpSampledImage(Id result_type, Id image, Id sampler) {
Id Module::OpImageWrite(Id image, Id coordinate, Id texel,
std::optional<spv::ImageOperandsMask> image_operands,
const std::vector<Id>& operands) {
std::span<const Id> operands) {
auto op{std::make_unique<Op>(spv::Op::OpImageWrite)};
op->Add(image);
op->Add(coordinate);

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@ -46,7 +46,7 @@ Id Module::OpStore(Id pointer, Id object, std::optional<spv::MemoryAccessMask> m
return AddCode(std::move(op));
}
Id Module::OpAccessChain(Id result_type, Id base, const std::vector<Id>& indexes) {
Id Module::OpAccessChain(Id result_type, Id base, std::span<const Id> indexes) {
assert(indexes.size() > 0);
auto op{std::make_unique<Op>(spv::Op::OpAccessChain, bound++, result_type)};
op->Add(base);
@ -70,7 +70,7 @@ Id Module::OpVectorInsertDynamic(Id result_type, Id vector, Id component, Id ind
}
Id Module::OpCompositeInsert(Id result_type, Id object, Id composite,
const std::vector<Literal>& indexes) {
std::span<const Literal> indexes) {
auto op{std::make_unique<Op>(spv::Op::OpCompositeInsert, bound++, result_type)};
op->Add(object);
op->Add(composite);
@ -78,14 +78,14 @@ Id Module::OpCompositeInsert(Id result_type, Id object, Id composite,
return AddCode(std::move(op));
}
Id Module::OpCompositeExtract(Id result_type, Id composite, const std::vector<Literal>& indexes) {
Id Module::OpCompositeExtract(Id result_type, Id composite, std::span<const Literal> indexes) {
auto op{std::make_unique<Op>(spv::Op::OpCompositeExtract, bound++, result_type)};
op->Add(composite);
op->Add(indexes);
return AddCode(std::move(op));
}
Id Module::OpCompositeConstruct(Id result_type, const std::vector<Id>& ids) {
Id Module::OpCompositeConstruct(Id result_type, std::span<const Id> ids) {
assert(ids.size() >= 1);
auto op{std::make_unique<Op>(spv::Op::OpCompositeConstruct, bound++, result_type)};
op->Add(ids);

View file

@ -90,7 +90,7 @@ Id Module::TypeRuntimeArray(Id element_type) {
return AddDeclaration(std::move(op));
}
Id Module::TypeStruct(const std::vector<Id>& members) {
Id Module::TypeStruct(std::span<const Id> members) {
auto op{std::make_unique<Op>(spv::Op::OpTypeStruct, bound)};
op->Add(members);
return AddDeclaration(std::move(op));
@ -109,7 +109,7 @@ Id Module::TypePointer(spv::StorageClass storage_class, Id type) {
return AddDeclaration(std::move(op));
}
Id Module::TypeFunction(Id return_type, const std::vector<Id>& arguments) {
Id Module::TypeFunction(Id return_type, std::span<const Id> arguments) {
auto op{std::make_unique<Op>(spv::Op::OpTypeFunction, bound)};
op->Add(return_type);
op->Add(arguments);

View file

@ -26,7 +26,7 @@ std::size_t LiteralNumber::GetWordCount() const noexcept {
return is_32 ? 1 : 2;
}
bool LiteralNumber::operator==(const Operand& other) const noexcept {
bool LiteralNumber::Equal(const Operand& other) const noexcept {
if (!EqualType(other)) {
return false;
}

View file

@ -24,7 +24,7 @@ public:
std::size_t GetWordCount() const noexcept override;
bool operator==(const Operand& other) const noexcept override;
bool Equal(const Operand& other) const noexcept override;
template <typename T>
static std::unique_ptr<LiteralNumber> Create(T value) {

View file

@ -23,7 +23,7 @@ std::size_t LiteralString::GetWordCount() const noexcept {
return string.size() / 4 + 1;
}
bool LiteralString::operator==(const Operand& other) const noexcept {
bool LiteralString::Equal(const Operand& other) const noexcept {
if (!EqualType(other)) {
return false;
}

View file

@ -21,7 +21,7 @@ public:
std::size_t GetWordCount() const noexcept override;
bool operator==(const Operand& other) const noexcept override;
bool Equal(const Operand& other) const noexcept override;
private:
std::string string;

View file

@ -30,7 +30,7 @@ std::size_t Op::GetWordCount() const noexcept {
return 1;
}
bool Op::operator==(const Operand& other) const noexcept {
bool Op::Equal(const Operand& other) const noexcept {
if (!EqualType(other)) {
return false;
}
@ -38,7 +38,7 @@ bool Op::operator==(const Operand& other) const noexcept {
if (op.opcode == opcode && result_type == op.result_type &&
operands.size() == op.operands.size()) {
for (std::size_t i = 0; i < operands.size(); i++) {
if (*operands[i] != *op.operands[i]) {
if (!operands[i]->Equal(*op.operands[i])) {
return false;
}
}
@ -89,7 +89,7 @@ void Op::Add(const Literal& literal) {
}());
}
void Op::Add(const std::vector<Literal>& literals) {
void Op::Add(std::span<const Literal> literals) {
for (const auto& literal : literals) {
Add(literal);
}
@ -112,7 +112,7 @@ void Op::Add(std::string string) {
Sink(std::make_unique<LiteralString>(std::move(string)));
}
void Op::Add(const std::vector<Id>& ids) {
void Op::Add(std::span<const Id> ids) {
assert(std::all_of(ids.begin(), ids.end(), [](auto id_) { return id_; }));
operands.insert(operands.end(), ids.begin(), ids.end());
}

View file

@ -26,7 +26,7 @@ public:
std::size_t GetWordCount() const noexcept override;
bool operator==(const Operand& other) const noexcept override;
bool Equal(const Operand& other) const noexcept override;
void Write(Stream& stream) const;
@ -34,7 +34,7 @@ public:
void Add(const Literal& literal);
void Add(const std::vector<Literal>& literals);
void Add(std::span<const Literal> literals);
void Add(const Operand* operand);
@ -44,7 +44,7 @@ public:
void Add(std::string string);
void Add(const std::vector<Id>& ids);
void Add(std::span<const Id> ids);
private:
u16 CalculateTotalWords() const noexcept;

View file

@ -23,11 +23,7 @@ public:
virtual std::size_t GetWordCount() const noexcept = 0;
virtual bool operator==(const Operand& other) const noexcept = 0;
bool operator!=(const Operand& other) const noexcept {
return !operator==(other);
}
virtual bool Equal(const Operand& other) const noexcept = 0;
bool EqualType(const Operand& other) const noexcept {
return operand_type == other.operand_type;

View file

@ -74,13 +74,14 @@ void Module::AddCapability(spv::Capability capability) {
capabilities.insert(capability);
}
void Module::SetMemoryModel(spv::AddressingModel addressing_model_, spv::MemoryModel memory_model_) {
void Module::SetMemoryModel(spv::AddressingModel addressing_model_,
spv::MemoryModel memory_model_) {
this->addressing_model = addressing_model_;
this->memory_model = memory_model_;
}
void Module::AddEntryPoint(spv::ExecutionModel execution_model, Id entry_point,
std::string name, const std::vector<Id>& interfaces) {
void Module::AddEntryPoint(spv::ExecutionModel execution_model, Id entry_point, std::string name,
std::span<const Id> interfaces) {
auto op{std::make_unique<Op>(spv::Op::OpEntryPoint)};
op->Add(static_cast<u32>(execution_model));
op->Add(entry_point);
@ -90,7 +91,7 @@ void Module::AddEntryPoint(spv::ExecutionModel execution_model, Id entry_point,
}
void Module::AddExecutionMode(Id entry_point, spv::ExecutionMode mode,
const std::vector<Literal>& literals) {
std::span<const Literal> literals) {
auto op{std::make_unique<Op>(spv::Op::OpExecutionMode)};
op->Add(entry_point);
op->Add(static_cast<u32>(mode));
@ -123,14 +124,14 @@ Id Module::AddCode(spv::Op opcode, std::optional<u32> id) {
}
Id Module::AddDeclaration(std::unique_ptr<Op> op) {
const auto& found{std::find_if(declarations.begin(), declarations.end(),
[&op](const auto& other) { return *other == *op; })};
const auto found = std::find_if(declarations.begin(), declarations.end(),
[&op](const auto& other) { return op->Equal(*other); });
if (found != declarations.end()) {
return found->get();
}
const auto id = op.get();
declarations.push_back(std::move(op));
bound++;
++bound;
return id;
}