https://github.com/halide/Halide
Tip revision: 92aaa6824ad5bffb525a8279564e3f45f620dd36 authored by Steven Johnson on 05 March 2024, 17:58:23 UTC
Merge branch 'arm_sve_redux' into srj/test-arm_sve_redux
Merge branch 'arm_sve_redux' into srj/test-arm_sve_redux
Tip revision: 92aaa68
SpirvIR.h
#ifndef HALIDE_SPIRV_IR_H
#define HALIDE_SPIRV_IR_H
/** \file
* Defines methods for constructing and encoding instructions into the Khronos
* format specification known as the Standard Portable Intermediate Representation
* for Vulkan (SPIR-V). These class interfaces adopt Halide's conventions for its
* own IR, but is implemented as a stand-alone optional component that can be
* enabled as required for certain runtimes (eg Vulkan).
*
* NOTE: This file is only used internally for CodeGen! *DO NOT* add this file
* to the list of exported Halide headers in the src/CMakeFiles.txt or the
* top level Makefile.
*/
#ifdef WITH_SPIRV
#include <map>
#include <set>
#include <stack>
#include <unordered_map>
#include <vector>
#include "IntrusivePtr.h"
#include "Type.h"
#include <spirv/1.6/GLSL.std.450.h> // GLSL extended instructions for common intrinsics
#include <spirv/1.6/spirv.h> // Use v1.6 headers but only use the minimal viable format version (for maximum compatiblity)
namespace Halide {
namespace Internal {
/** Precision requirment for return values */
enum SpvPrecision {
SpvFullPrecision,
SpvRelaxedPrecision,
};
/** Scope qualifiers for Execution & Memory operations */
enum SpvScope {
SpvCrossDeviceScope = 0,
SpvDeviceScope = 1,
SpvWorkgroupScope = 2,
SpvSubgroupScope = 3,
SpvInvocationScope = 4
};
/** Specific types of predefined constants */
enum SpvPredefinedConstant {
SpvNullConstant,
SpvTrueConstant,
SpvFalseConstant,
};
/** Specific types of SPIR-V object ids */
enum SpvKind {
SpvInvalidItem,
SpvTypeId,
SpvVoidTypeId,
SpvBoolTypeId,
SpvIntTypeId,
SpvUIntTypeId,
SpvFloatTypeId,
SpvVectorTypeId,
SpvArrayTypeId,
SpvRuntimeArrayTypeId,
SpvStringTypeId,
SpvPointerTypeId,
SpvStructTypeId,
SpvFunctionTypeId,
SpvAccessChainId,
SpvConstantId,
SpvBoolConstantId,
SpvIntConstantId,
SpvFloatConstantId,
SpvStringConstantId,
SpvCompositeConstantId,
SpvResultId,
SpvVariableId,
SpvInstructionId,
SpvFunctionId,
SpvBlockId,
SpvLabelId,
SpvParameterId,
SpvImportId,
SpvModuleId,
SpvUnknownItem,
};
/** Specific types of SPIR-V operand types */
enum SpvValueType {
SpvInvalidValueType,
SpvOperandId,
SpvBitMaskLiteral,
SpvIntegerLiteral,
SpvIntegerData,
SpvFloatData,
SpvStringData,
SpvUnknownValueType
};
/** SPIR-V requires all IDs to be 32-bit unsigned integers */
using SpvId = uint32_t;
using SpvBinary = std::vector<uint32_t>;
static constexpr SpvStorageClass SpvInvalidStorageClass = SpvStorageClassMax; // sentinel for invalid storage class
static constexpr SpvId SpvInvalidId = SpvId(-1);
static constexpr SpvId SpvNoResult = 0;
static constexpr SpvId SpvNoType = 0;
/** Pre-declarations for SPIR-V IR classes */
class SpvModule;
class SpvFunction;
class SpvBlock;
class SpvInstruction;
class SpvBuilder;
class SpvContext;
struct SpvFactory;
/** Pre-declarations for SPIR-V IR data structures */
struct SpvModuleContents;
struct SpvFunctionContents;
struct SpvBlockContents;
struct SpvInstructionContents;
/** Intrusive pointer types for SPIR-V IR data */
using SpvModuleContentsPtr = IntrusivePtr<SpvModuleContents>;
using SpvFunctionContentsPtr = IntrusivePtr<SpvFunctionContents>;
using SpvBlockContentsPtr = IntrusivePtr<SpvBlockContents>;
using SpvInstructionContentsPtr = IntrusivePtr<SpvInstructionContents>;
/** General interface for representing a SPIR-V Instruction */
class SpvInstruction {
public:
using LiteralValue = std::pair<uint32_t, SpvValueType>;
using Immediates = std::vector<LiteralValue>;
using Operands = std::vector<SpvId>;
using ValueTypes = std::vector<SpvValueType>;
SpvInstruction() = default;
~SpvInstruction();
SpvInstruction(const SpvInstruction &) = default;
SpvInstruction &operator=(const SpvInstruction &) = default;
SpvInstruction(SpvInstruction &&) = default;
SpvInstruction &operator=(SpvInstruction &&) = default;
void set_result_id(SpvId id);
void set_type_id(SpvId id);
void set_op_code(SpvOp opcode);
void add_operand(SpvId id);
void add_operands(const Operands &operands);
void add_immediate(SpvId id, SpvValueType type);
void add_immediates(const Immediates &Immediates);
void add_data(uint32_t bytes, const void *data, SpvValueType type);
void add_string(const std::string &str);
template<typename T>
void append(const T &operands_or_immediates_or_strings);
SpvId result_id() const;
SpvId type_id() const;
SpvOp op_code() const;
SpvId operand(uint32_t index) const;
const void *data(uint32_t index = 0) const;
SpvValueType value_type(uint32_t index) const;
const Operands &operands() const;
bool has_type() const;
bool has_result() const;
bool is_defined() const;
bool is_immediate(uint32_t index) const;
uint32_t length() const;
void check_defined() const;
void clear();
void encode(SpvBinary &binary) const;
static SpvInstruction make(SpvOp op_code);
protected:
SpvInstructionContentsPtr contents;
};
/** General interface for representing a SPIR-V Block */
class SpvBlock {
public:
using Instructions = std::vector<SpvInstruction>;
using Variables = std::vector<SpvInstruction>;
using Blocks = std::vector<SpvBlock>;
SpvBlock() = default;
~SpvBlock();
SpvBlock(const SpvBlock &) = default;
SpvBlock &operator=(const SpvBlock &) = default;
SpvBlock(SpvBlock &&) = default;
SpvBlock &operator=(SpvBlock &&) = default;
void add_instruction(SpvInstruction inst);
void add_variable(SpvInstruction var);
const Instructions &instructions() const;
const Variables &variables() const;
bool is_reachable() const;
bool is_terminated() const;
bool is_defined() const;
SpvId id() const;
void check_defined() const;
void clear();
void encode(SpvBinary &binary) const;
static SpvBlock make(SpvId block_id);
protected:
SpvBlockContentsPtr contents;
};
/** General interface for representing a SPIR-V Function */
class SpvFunction {
public:
using Blocks = std::vector<SpvBlock>;
using Parameters = std::vector<SpvInstruction>;
SpvFunction() = default;
~SpvFunction();
SpvFunction(const SpvFunction &) = default;
SpvFunction &operator=(const SpvFunction &) = default;
SpvFunction(SpvFunction &&) = default;
SpvFunction &operator=(SpvFunction &&) = default;
SpvBlock create_block(SpvId block_id);
void add_block(SpvBlock block);
void add_parameter(SpvInstruction param);
void set_return_precision(SpvPrecision precision);
void set_parameter_precision(uint32_t index, SpvPrecision precision);
bool is_defined() const;
void clear();
const Blocks &blocks() const;
SpvBlock entry_block() const;
SpvBlock tail_block() const;
SpvPrecision return_precision() const;
const Parameters ¶meters() const;
SpvPrecision parameter_precision(uint32_t index) const;
uint32_t parameter_count() const;
uint32_t control_mask() const;
SpvInstruction declaration() const;
SpvId return_type_id() const;
SpvId type_id() const;
SpvId id() const;
void check_defined() const;
void encode(SpvBinary &binary) const;
static SpvFunction make(SpvId func_id, SpvId func_type_id, SpvId return_type_id, uint32_t control_mask = SpvFunctionControlMaskNone);
protected:
SpvFunctionContentsPtr contents;
};
/** General interface for representing a SPIR-V code module */
class SpvModule {
public:
using ImportDefinition = std::pair<SpvId, std::string>;
using ImportNames = std::vector<std::string>;
using EntryPointNames = std::vector<std::string>;
using Instructions = std::vector<SpvInstruction>;
using Functions = std::vector<SpvFunction>;
using Capabilities = std::vector<SpvCapability>;
using Extensions = std::vector<std::string>;
using Imports = std::vector<ImportDefinition>;
SpvModule() = default;
~SpvModule();
SpvModule(const SpvModule &) = default;
SpvModule &operator=(const SpvModule &) = default;
SpvModule(SpvModule &&) = default;
SpvModule &operator=(SpvModule &&) = default;
void add_debug_string(SpvId result_id, const std::string &string);
void add_debug_symbol(SpvId id, const std::string &symbol);
void add_annotation(SpvInstruction val);
void add_type(SpvInstruction val);
void add_constant(SpvInstruction val);
void add_global(SpvInstruction val);
void add_execution_mode(SpvInstruction val);
void add_function(SpvFunction val);
void add_instruction(SpvInstruction val);
void add_entry_point(const std::string &name, SpvInstruction entry_point);
void import_instruction_set(SpvId id, const std::string &instruction_set);
void require_capability(SpvCapability val);
void require_extension(const std::string &val);
void set_version_format(uint32_t version);
void set_source_language(SpvSourceLanguage val);
void set_addressing_model(SpvAddressingModel val);
void set_memory_model(SpvMemoryModel val);
void set_binding_count(SpvId count);
uint32_t version_format() const;
SpvSourceLanguage source_language() const;
SpvAddressingModel addressing_model() const;
SpvMemoryModel memory_model() const;
SpvInstruction entry_point(const std::string &name) const;
EntryPointNames entry_point_names() const;
ImportNames import_names() const;
SpvId lookup_import(const std::string &Instruction_set) const;
uint32_t entry_point_count() const;
Imports imports() const;
Extensions extensions() const;
Capabilities capabilities() const;
Instructions entry_points() const;
const Instructions &execution_modes() const;
const Instructions &debug_source() const;
const Instructions &debug_symbols() const;
const Instructions &annotations() const;
const Instructions &type_definitions() const;
const Instructions &global_constants() const;
const Instructions &global_variables() const;
const Functions &function_definitions() const;
uint32_t binding_count() const;
SpvModule module() const;
bool is_imported(const std::string &instruction_set) const;
bool is_capability_required(SpvCapability val) const;
bool is_extension_required(const std::string &val) const;
bool is_defined() const;
SpvId id() const;
void check_defined() const;
void clear();
void encode(SpvBinary &binary) const;
static SpvModule make(SpvId module_id,
SpvSourceLanguage source_language = SpvSourceLanguageUnknown,
SpvAddressingModel addressing_model = SpvAddressingModelLogical,
SpvMemoryModel memory_model = SpvMemoryModelSimple);
protected:
SpvModuleContentsPtr contents;
};
/** Builder interface for constructing a SPIR-V code module and
* all associated types, declarations, blocks, functions &
* instructions */
class SpvBuilder {
public:
using ParamTypes = std::vector<SpvId>;
using Components = std::vector<SpvId>;
using StructMemberTypes = std::vector<SpvId>;
using Variables = std::vector<SpvId>;
using Indices = std::vector<uint32_t>;
using Literals = std::vector<uint32_t>;
SpvBuilder();
~SpvBuilder() = default;
SpvBuilder(const SpvBuilder &) = delete;
SpvBuilder &operator=(const SpvBuilder &) = delete;
// Reserve a unique ID to use for identifying a specifc kind of SPIR-V result **/
SpvId reserve_id(SpvKind = SpvResultId);
// Look up the specific kind of SPIR-V item from its unique ID
SpvKind kind_of(SpvId id) const;
// Get a human readable name for a specific kind of SPIR-V item
std::string kind_name(SpvKind kind) const;
// Look up the ID associated with the type for a given variable ID
SpvId type_of(SpvId variable_id) const;
// Top-Level declaration methods ... each of these is a convenvience
// function that checks to see if the requested thing has already been
// declared, in which case it returns its existing id, otherwise it
// adds a new declaration, and returns the new id. This avoids all
// the logic checks in the calling code, and also ensures that
// duplicates aren't created.
SpvId declare_void_type();
SpvId declare_type(const Type &type, uint32_t array_size = 1);
SpvId declare_pointer_type(const Type &type, SpvStorageClass storage_class);
SpvId declare_pointer_type(SpvId type_id, SpvStorageClass storage_class);
SpvId declare_constant(const Type &type, const void *data, bool is_specialization = false);
SpvId declare_null_constant(const Type &type);
SpvId declare_bool_constant(bool value);
SpvId declare_string_constant(const std::string &str);
SpvId declare_integer_constant(const Type &type, int64_t value);
SpvId declare_float_constant(const Type &type, double value);
SpvId declare_scalar_constant(const Type &type, const void *data);
SpvId declare_vector_constant(const Type &type, const void *data);
SpvId declare_specialization_constant(const Type &type, const void *data);
SpvId declare_access_chain(SpvId ptr_type_id, SpvId base_id, const Indices &indices);
SpvId declare_pointer_access_chain(SpvId ptr_type_id, SpvId base_id, SpvId element_id, const Indices &indices);
SpvId declare_function_type(SpvId return_type, const ParamTypes ¶m_types = {});
SpvId declare_function(const std::string &name, SpvId function_type);
SpvId declare_struct(const std::string &name, const StructMemberTypes &member_types);
SpvId declare_variable(const std::string &name, SpvId type_id, SpvStorageClass storage_class, SpvId initializer_id = SpvInvalidId);
SpvId declare_global_variable(const std::string &name, SpvId type_id, SpvStorageClass storage_class, SpvId initializer_id = SpvInvalidId);
SpvId declare_symbol(const std::string &symbol, SpvId id, SpvId scope_id);
// Top level creation methods for adding new items ... these have a limited
// number of checks and the caller must ensure that duplicates aren't created
SpvId add_type(const Type &type, uint32_t array_size = 1);
SpvId add_struct(const std::string &name, const StructMemberTypes &member_types);
SpvId add_array_with_default_size(SpvId base_type_id, SpvId array_size_id);
SpvId add_runtime_array(SpvId base_type_id);
SpvId add_pointer_type(const Type &type, SpvStorageClass storage_class);
SpvId add_pointer_type(SpvId base_type_id, SpvStorageClass storage_class);
SpvId add_constant(const Type &type, const void *data, bool is_specialization = false);
SpvId add_function_type(SpvId return_type_id, const ParamTypes ¶m_type_ids);
SpvId add_function(const std::string &name, SpvId return_type, const ParamTypes ¶m_types = {});
SpvId add_instruction(SpvInstruction val);
void add_annotation(SpvId target_id, SpvDecoration decoration_type, const Literals &literals = {});
void add_struct_annotation(SpvId struct_type_id, uint32_t member_index, SpvDecoration decoration_type, const Literals &literals = {});
void add_symbol(const std::string &symbol, SpvId id, SpvId scope_id);
void add_entry_point(SpvId func_id, SpvExecutionModel exec_model,
const Variables &variables = {});
// Define the execution mode with a fixed local size for the workgroup (using literal values)
void add_execution_mode_local_size(SpvId entry_point_id, uint32_t local_size_x, uint32_t local_size_y, uint32_t local_size_z);
// Same as above but uses id's for the local size (to allow specialization constants to be used)
void add_execution_mode_local_size_id(SpvId entry_point_id, SpvId local_size_x, SpvId local_size_y, SpvId local_size_z);
// Assigns a specific SPIR-V version format for output (needed for compatibility)
void set_version_format(uint32_t version);
// Assigns a specific source language hint to the module
void set_source_language(SpvSourceLanguage val);
// Sets the addressing model to use for the module
void set_addressing_model(SpvAddressingModel val);
// Sets the memory model to use for the module
void set_memory_model(SpvMemoryModel val);
// Returns the source language hint for the module
SpvSourceLanguage source_language() const;
// Returns the addressing model used for the module
SpvAddressingModel addressing_model() const;
// Returns the memory model used for the module
SpvMemoryModel memory_model() const;
// Import the GLSL.std.450 external instruction set. Returns its corresponding ID.
SpvId import_glsl_intrinsics();
// Import an external instruction set bby name. Returns its corresponding ID.
SpvId import_instruction_set(const std::string &instruction_set);
// Add an extension string to the list of required extensions for the module
void require_extension(const std::string &extension);
// Add a specific capability to the list of requirements for the module
void require_capability(SpvCapability);
// Returns true if the given instruction set has been imported
bool is_imported(const std::string &instruction_set) const;
// Returns true if the given extension string is required by the module
bool is_extension_required(const std::string &extension) const;
// Returns true if the given capability is required by the module
bool is_capability_required(SpvCapability) const;
// Change the current build location to the given block. All local
// declarations and instructions will be added here.
void enter_block(const SpvBlock &block);
// Create a new block with the given ID
SpvBlock create_block(SpvId block_id);
// Returns the current block (the active scope for building)
SpvBlock current_block() const;
// Resets the block build scope, and unassigns the current block
SpvBlock leave_block();
// Change the current build scope to be within the given function
void enter_function(const SpvFunction &func);
// Returns the function object for the given ID (or an invalid function if none is found)
SpvFunction lookup_function(SpvId func_id) const;
// Returns the current function being used as the active build scope
SpvFunction current_function() const;
// Resets the function build scope, and unassigns the current function
SpvFunction leave_function();
// Returns the current id being used for building (ie the last item created)
SpvId current_id() const;
// Updates the current id being used for building
void update_id(SpvId id);
// Returns true if the given id is of the corresponding type
bool is_pointer_type(SpvId id) const;
bool is_struct_type(SpvId id) const;
bool is_vector_type(SpvId id) const;
bool is_scalar_type(SpvId id) const;
bool is_array_type(SpvId id) const;
bool is_constant(SpvId id) const;
// Looks up the given pointer type id and returns a corresponding base type id (or an invalid id if none is found)
SpvId lookup_base_type(SpvId pointer_type) const;
// Returns the storage class for the given variable id (or invalid if none is found)
SpvStorageClass lookup_storage_class(SpvId id) const;
// Returns the item id for the given symbol name (or an invalid id if none is found)
SpvId lookup_id(const std::string &symbol) const;
// Returns the build scope id for the item id (or an invalid id if none is found)
SpvId lookup_scope(SpvId id) const;
// Returns the id for the imported instruction set (or an invalid id if none is found)
SpvId lookup_import(const std::string &instruction_set) const;
// Returns the symbol string for the given id (or an empty string if none is found)
std::string lookup_symbol(SpvId id) const;
// Returns the current module being used for building
SpvModule current_module() const;
// Appends the given instruction to the current build location
void append(SpvInstruction inst);
// Finalizes the module and prepares it for encoding (must be called before module can be used)
void finalize();
// Encodes the current module to the given binary
void encode(SpvBinary &binary) const;
// Resets the builder and all internal state
void reset();
protected:
using TypeKey = uint64_t;
using TypeMap = std::unordered_map<TypeKey, SpvId>;
using KindMap = std::unordered_map<SpvId, SpvKind>;
using PointerTypeKey = std::pair<SpvId, SpvStorageClass>;
using PointerTypeMap = std::map<PointerTypeKey, SpvId>;
using BaseTypeMap = std::unordered_map<SpvId, SpvId>;
using VariableTypeMap = std::unordered_map<SpvId, SpvId>;
using StorageClassMap = std::unordered_map<SpvId, SpvStorageClass>;
using ConstantKey = uint64_t;
using ConstantMap = std::unordered_map<ConstantKey, SpvId>;
using StringMap = std::unordered_map<ConstantKey, SpvId>;
using ScopeMap = std::unordered_map<SpvId, SpvId>;
using IdSymbolMap = std::unordered_map<SpvId, std::string>;
using SymbolIdMap = std::unordered_map<std::string, SpvId>;
using FunctionTypeKey = uint64_t;
using FunctionTypeMap = std::unordered_map<FunctionTypeKey, SpvId>;
using FunctionMap = std::unordered_map<SpvId, SpvFunction>;
// Internal methods for creating ids, keys, and look ups
SpvId make_id(SpvKind kind);
TypeKey make_type_key(const Type &type, uint32_t array_size = 1) const;
SpvId lookup_type(const Type &type, uint32_t array_size = 1) const;
TypeKey make_struct_type_key(const StructMemberTypes &member_types) const;
SpvId lookup_struct(const std::string &name, const StructMemberTypes &member_types) const;
PointerTypeKey make_pointer_type_key(const Type &type, SpvStorageClass storage_class) const;
SpvId lookup_pointer_type(const Type &type, SpvStorageClass storage_class) const;
PointerTypeKey make_pointer_type_key(SpvId base_type_id, SpvStorageClass storage_class) const;
SpvId lookup_pointer_type(SpvId base_type_id, SpvStorageClass storage_class) const;
template<typename T>
SpvId declare_scalar_constant_of_type(const Type &scalar_type, const T *data);
template<typename T>
SpvId declare_specialization_constant_of_type(const Type &scalar_type, const T *data);
template<typename T>
SpvBuilder::Components declare_constants_for_each_lane(Type type, const void *data);
ConstantKey make_bool_constant_key(bool value) const;
ConstantKey make_string_constant_key(const std::string &value) const;
ConstantKey make_constant_key(uint8_t code, uint8_t bits, int lanes, size_t bytes, const void *data, bool is_specialization = false) const;
ConstantKey make_constant_key(const Type &type, const void *data, bool is_specialization = false) const;
SpvId lookup_constant(const Type &type, const void *data, bool is_specialization = false) const;
ConstantKey make_null_constant_key(const Type &type) const;
SpvId lookup_null_constant(const Type &type) const;
SpvId lookup_variable(const std::string &name, SpvId type_id, SpvStorageClass storage_class, SpvId scope_id) const;
bool has_variable(const std::string &name, SpvId type_id, SpvStorageClass storage_class, SpvId scope_id) const;
FunctionTypeKey make_function_type_key(SpvId return_type_id, const ParamTypes ¶m_type_ids) const;
SpvId lookup_function_type(SpvId return_type_id, const ParamTypes ¶m_type_ids) const;
SpvId active_id = SpvInvalidId;
SpvFunction active_function;
SpvBlock active_block;
SpvModule module;
KindMap kind_map;
TypeMap type_map;
TypeMap struct_map;
ScopeMap scope_map;
StringMap string_map;
ConstantMap constant_map;
FunctionMap function_map;
IdSymbolMap id_symbol_map;
SymbolIdMap symbol_id_map;
BaseTypeMap base_type_map;
StorageClassMap storage_class_map;
PointerTypeMap pointer_type_map;
VariableTypeMap variable_type_map;
FunctionTypeMap function_type_map;
};
/** Factory interface for constructing specific SPIR-V instructions */
struct SpvFactory {
using Indices = std::vector<uint32_t>;
using Literals = std::vector<uint32_t>;
using BranchWeights = std::vector<uint32_t>;
using Components = std::vector<SpvId>;
using ParamTypes = std::vector<SpvId>;
using MemberTypeIds = std::vector<SpvId>;
using Operands = std::vector<SpvId>;
using Variables = std::vector<SpvId>;
using VariableBlockIdPair = std::pair<SpvId, SpvId>; // (Variable Id, Block Id)
using BlockVariables = std::vector<VariableBlockIdPair>;
static SpvInstruction no_op(SpvId result_id);
static SpvInstruction capability(const SpvCapability &capability);
static SpvInstruction extension(const std::string &extension);
static SpvInstruction import(SpvId instruction_set_id, const std::string &instruction_set_name);
static SpvInstruction label(SpvId result_id);
static SpvInstruction debug_line(SpvId string_id, uint32_t line, uint32_t column);
static SpvInstruction debug_string(SpvId result_id, const std::string &string);
static SpvInstruction debug_symbol(SpvId target_id, const std::string &symbol);
static SpvInstruction decorate(SpvId target_id, SpvDecoration decoration_type, const Literals &literals = {});
static SpvInstruction decorate_member(SpvId struct_type_id, uint32_t member_index, SpvDecoration decoration_type, const Literals &literals = {});
static SpvInstruction void_type(SpvId void_type_id);
static SpvInstruction bool_type(SpvId bool_type_id);
static SpvInstruction integer_type(SpvId int_type_id, uint32_t bits, uint32_t signedness);
static SpvInstruction float_type(SpvId float_type_id, uint32_t bits);
static SpvInstruction vector_type(SpvId vector_type_id, SpvId element_type_id, uint32_t vector_size);
static SpvInstruction array_type(SpvId array_type_id, SpvId element_type_id, SpvId array_size_id);
static SpvInstruction struct_type(SpvId result_id, const MemberTypeIds &member_type_ids);
static SpvInstruction runtime_array_type(SpvId result_type_id, SpvId base_type_id);
static SpvInstruction pointer_type(SpvId pointer_type_id, SpvStorageClass storage_class, SpvId base_type_id);
static SpvInstruction function_type(SpvId function_type_id, SpvId return_type_id, const ParamTypes ¶m_type_ids);
static SpvInstruction constant(SpvId result_id, SpvId type_id, size_t bytes, const void *data, SpvValueType value_type);
static SpvInstruction null_constant(SpvId result_id, SpvId type_id);
static SpvInstruction bool_constant(SpvId result_id, SpvId type_id, bool value);
static SpvInstruction string_constant(SpvId result_id, const std::string &value);
static SpvInstruction composite_constant(SpvId result_id, SpvId type_id, const Components &components);
static SpvInstruction specialization_constant(SpvId result_id, SpvId type_id, size_t bytes, const void *data, SpvValueType value_type);
static SpvInstruction variable(SpvId result_id, SpvId result_type_id, uint32_t storage_class, SpvId initializer_id = SpvInvalidId);
static SpvInstruction function(SpvId return_type_id, SpvId func_id, uint32_t control_mask, SpvId func_type_id);
static SpvInstruction function_parameter(SpvId param_type_id, SpvId param_id);
static SpvInstruction function_end();
static SpvInstruction return_stmt(SpvId return_value_id = SpvInvalidId);
static SpvInstruction entry_point(SpvId exec_model, SpvId func_id, const std::string &name, const Variables &variables);
static SpvInstruction memory_model(SpvAddressingModel addressing_model, SpvMemoryModel memory_model);
static SpvInstruction exec_mode_local_size(SpvId function_id, uint32_t local_size_size_x, uint32_t local_size_size_y, uint32_t local_size_size_z);
static SpvInstruction exec_mode_local_size_id(SpvId function_id, SpvId local_size_x_id, SpvId local_size_y_id, SpvId local_size_z_id); // only avail in 1.2
static SpvInstruction memory_barrier(SpvId memory_scope_id, SpvId semantics_mask_id);
static SpvInstruction control_barrier(SpvId execution_scope_id, SpvId memory_scope_id, SpvId semantics_mask_id);
static SpvInstruction bitwise_not(SpvId type_id, SpvId result_id, SpvId src_id);
static SpvInstruction bitwise_and(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id);
static SpvInstruction logical_not(SpvId type_id, SpvId result_id, SpvId src_id);
static SpvInstruction logical_and(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id);
static SpvInstruction shift_right_logical(SpvId type_id, SpvId result_id, SpvId src_id, SpvId shift_id);
static SpvInstruction shift_right_arithmetic(SpvId type_id, SpvId result_id, SpvId src_id, SpvId shift_id);
static SpvInstruction multiply_extended(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id, bool is_signed);
static SpvInstruction select(SpvId type_id, SpvId result_id, SpvId condition_id, SpvId true_id, SpvId false_id);
static SpvInstruction in_bounds_access_chain(SpvId type_id, SpvId result_id, SpvId base_id, const Indices &indices);
static SpvInstruction pointer_access_chain(SpvId type_id, SpvId result_id, SpvId base_id, SpvId element_id, const Indices &indices);
static SpvInstruction load(SpvId type_id, SpvId result_id, SpvId ptr_id, uint32_t access_mask = 0x0);
static SpvInstruction store(SpvId ptr_id, SpvId obj_id, uint32_t access_mask = 0x0);
static SpvInstruction vector_insert_dynamic(SpvId type_id, SpvId result_id, SpvId vector_id, SpvId value_id, SpvId index_id);
static SpvInstruction vector_extract_dynamic(SpvId type_id, SpvId result_id, SpvId vector_id, SpvId value_id, SpvId index_id);
static SpvInstruction vector_shuffle(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id, const Indices &indices);
static SpvInstruction composite_insert(SpvId type_id, SpvId result_id, SpvId object_id, SpvId composite_id, const SpvFactory::Indices &indices);
static SpvInstruction composite_extract(SpvId type_id, SpvId result_id, SpvId composite_id, const Indices &indices);
static SpvInstruction composite_construct(SpvId type_id, SpvId result_id, const Components &constituents);
static SpvInstruction is_inf(SpvId type_id, SpvId result_id, SpvId src_id);
static SpvInstruction is_nan(SpvId type_id, SpvId result_id, SpvId src_id);
static SpvInstruction bitcast(SpvId type_id, SpvId result_id, SpvId src_id);
static SpvInstruction float_add(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id);
static SpvInstruction integer_add(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id);
static SpvInstruction integer_equal(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id);
static SpvInstruction integer_not_equal(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id);
static SpvInstruction integer_less_than(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id, bool is_signed);
static SpvInstruction integer_less_than_equal(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id, bool is_signed);
static SpvInstruction integer_greater_than(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id, bool is_signed);
static SpvInstruction integer_greater_than_equal(SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id, bool is_signed);
static SpvInstruction branch(SpvId target_label_id);
static SpvInstruction conditional_branch(SpvId condition_label_id, SpvId true_label_id, SpvId false_label_id, const BranchWeights &weights = {});
static SpvInstruction loop_merge(SpvId merge_label_id, SpvId continue_label_id, uint32_t loop_control_mask = SpvLoopControlMaskNone);
static SpvInstruction selection_merge(SpvId merge_label_id, uint32_t selection_control_mask = SpvSelectionControlMaskNone);
static SpvInstruction phi(SpvId type_id, SpvId result_id, const BlockVariables &block_vars);
static SpvInstruction unary_op(SpvOp op_code, SpvId type_id, SpvId result_id, SpvId src_id);
static SpvInstruction binary_op(SpvOp op_code, SpvId type_id, SpvId result_id, SpvId src_a_id, SpvId src_b_id);
static SpvInstruction convert(SpvOp op_code, SpvId type_id, SpvId result_id, SpvId src_id);
static SpvInstruction extended(SpvId instruction_set_id, SpvId instruction_number, SpvId type_id, SpvId result_id, const SpvFactory::Operands &operands);
};
/** Contents of a SPIR-V Instruction */
struct SpvInstructionContents {
using Operands = std::vector<SpvId>;
using ValueTypes = std::vector<SpvValueType>;
mutable RefCount ref_count;
SpvOp op_code = SpvOpNop;
SpvId result_id = SpvNoResult;
SpvId type_id = SpvNoType;
Operands operands;
ValueTypes value_types;
};
/** Contents of a SPIR-V code block */
struct SpvBlockContents {
using Instructions = std::vector<SpvInstruction>;
using Variables = std::vector<SpvInstruction>;
using Blocks = std::vector<SpvBlock>;
mutable RefCount ref_count;
SpvId block_id = SpvInvalidId;
Instructions instructions;
Variables variables;
Blocks before;
Blocks after;
bool reachable = true;
};
/** Contents of a SPIR-V function */
struct SpvFunctionContents {
using PrecisionMap = std::unordered_map<SpvId, SpvPrecision>;
using Parameters = std::vector<SpvInstruction>;
using Blocks = std::vector<SpvBlock>;
mutable RefCount ref_count;
SpvId function_id;
SpvId function_type_id;
SpvId return_type_id;
uint32_t control_mask;
SpvInstruction declaration;
Parameters parameters;
PrecisionMap precision;
Blocks blocks;
};
/** Contents of a SPIR-V code module */
struct SpvModuleContents {
using Capabilities = std::set<SpvCapability>;
using Extensions = std::set<std::string>;
using Imports = std::unordered_map<std::string, SpvId>;
using Functions = std::vector<SpvFunction>;
using Instructions = std::vector<SpvInstruction>;
using EntryPoints = std::unordered_map<std::string, SpvInstruction>;
mutable RefCount ref_count;
SpvId module_id = SpvInvalidId;
SpvId version_format = SpvVersion;
SpvId binding_count = 0;
SpvSourceLanguage source_language = SpvSourceLanguageUnknown;
SpvAddressingModel addressing_model = SpvAddressingModelLogical;
SpvMemoryModel memory_model = SpvMemoryModelSimple;
Capabilities capabilities;
Extensions extensions;
Imports imports;
EntryPoints entry_points;
Instructions execution_modes;
Instructions debug_source;
Instructions debug_symbols;
Instructions annotations;
Instructions types;
Instructions constants;
Instructions globals;
Functions functions;
Instructions instructions;
};
/** Helper functions for determining calling convention of GLSL builtins **/
bool is_glsl_unary_op(SpvId glsl_op_code);
bool is_glsl_binary_op(SpvId glsl_op_code);
uint32_t glsl_operand_count(SpvId glsl_op_code);
/** Output the contents of a SPIR-V module in human-readable form **/
std::ostream &operator<<(std::ostream &stream, const SpvModule &);
/** Output the definition of a SPIR-V function in human-readable form **/
std::ostream &operator<<(std::ostream &stream, const SpvFunction &);
/** Output the contents of a SPIR-V block in human-readable form **/
std::ostream &operator<<(std::ostream &stream, const SpvBlock &);
/** Output a SPIR-V instruction in human-readable form **/
std::ostream &operator<<(std::ostream &stream, const SpvInstruction &);
} // namespace Internal
} // namespace Halide
#endif // WITH_SPIRV
namespace Halide {
namespace Internal {
/** Internal test for SPIR-V IR **/
void spirv_ir_test();
} // namespace Internal
} // namespace Halide
#endif // HALIDE_SPIRV_IR_H