SPIRV-Tools/source/opt/module.h
Nathan Gauër 85a4482131
NFC: makes the FeatureManager immutable for users (#5329)
* NFC: makes the FeatureManager immutable for users

The FeatureManager contains some internal state, like
a set of capabilities and extensions. Those are derived
from the module.

Before this commit, the FeatureManager exposed Remove* functions
which could unsync the reported extensions/capabilities from
the truth: the module.

The only valid usecase to remove items directly from the FeatureManager
is by the context itself, when an instruction is killed:
instead of running the whole an analysis, we remove the single outdated
item.

The was 2 users who mutated its state:
 - one to invalidate the manager. Moved to call a reset function.
 - one who removed an extension from the feature manager after removing
   it from the module. This logic has been moved to the context, who
   now handles the extension removal itself.

Signed-off-by: Nathan Gauër <brioche@google.com>

* clang-format

* add RemoveCapability since the fuzztests are using it

* add tests

---------

Signed-off-by: Nathan Gauër <brioche@google.com>
2023-07-17 11:15:08 -04:00

551 lines
20 KiB
C++

// Copyright (c) 2016 Google Inc.
//
// 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.
#ifndef SOURCE_OPT_MODULE_H_
#define SOURCE_OPT_MODULE_H_
#include <functional>
#include <memory>
#include <string_view>
#include <unordered_map>
#include <utility>
#include <vector>
#include "source/opt/function.h"
#include "source/opt/instruction.h"
#include "source/opt/iterator.h"
namespace spvtools {
namespace opt {
class IRContext;
// A struct for containing the module header information.
struct ModuleHeader {
uint32_t magic_number;
uint32_t version;
uint32_t generator;
uint32_t bound;
uint32_t schema;
};
// A SPIR-V module. It contains all the information for a SPIR-V module and
// serves as the backbone of optimization transformations.
class Module {
public:
using iterator = UptrVectorIterator<Function>;
using const_iterator = UptrVectorIterator<Function, true>;
using inst_iterator = InstructionList::iterator;
using const_inst_iterator = InstructionList::const_iterator;
// Creates an empty module with zero'd header.
Module() : header_({}), contains_debug_info_(false) {}
// Sets the header to the given |header|.
void SetHeader(const ModuleHeader& header) { header_ = header; }
// Sets the Id bound. The Id bound cannot be set to 0.
void SetIdBound(uint32_t bound) {
assert(bound != 0);
header_.bound = bound;
}
// Returns the Id bound.
uint32_t IdBound() const { return header_.bound; }
// Returns the current Id bound and increases it to the next available value.
// If the id bound has already reached its maximum value, then 0 is returned.
// The maximum value for the id bound is obtained from the context. If there
// is none, then the minimum that limit can be according to the spir-v
// specification.
// TODO(1841): Update the uses to check for a 0 return value.
uint32_t TakeNextIdBound();
// Appends a capability instruction to this module.
inline void AddCapability(std::unique_ptr<Instruction> c);
// Appends an extension instruction to this module.
inline void AddExtension(std::unique_ptr<Instruction> e);
// Appends an extended instruction set instruction to this module.
inline void AddExtInstImport(std::unique_ptr<Instruction> e);
// Set the memory model for this module.
inline void SetMemoryModel(std::unique_ptr<Instruction> m);
// Set the sampled image addressing mode for this module.
inline void SetSampledImageAddressMode(std::unique_ptr<Instruction> m);
// Appends an entry point instruction to this module.
inline void AddEntryPoint(std::unique_ptr<Instruction> e);
// Appends an execution mode instruction to this module.
inline void AddExecutionMode(std::unique_ptr<Instruction> e);
// Appends a debug 1 instruction (excluding OpLine & OpNoLine) to this module.
// "debug 1" instructions are the ones in layout section 7.a), see section
// 2.4 Logical Layout of a Module from the SPIR-V specification.
inline void AddDebug1Inst(std::unique_ptr<Instruction> d);
// Appends a debug 2 instruction (excluding OpLine & OpNoLine) to this module.
// "debug 2" instructions are the ones in layout section 7.b), see section
// 2.4 Logical Layout of a Module from the SPIR-V specification.
inline void AddDebug2Inst(std::unique_ptr<Instruction> d);
// Appends a debug 3 instruction (OpModuleProcessed) to this module.
// This is due to decision by the SPIR Working Group, pending publication.
inline void AddDebug3Inst(std::unique_ptr<Instruction> d);
// Appends a debug info extension (OpenCL.DebugInfo.100,
// NonSemantic.Shader.DebugInfo.100, or DebugInfo) instruction to this module.
inline void AddExtInstDebugInfo(std::unique_ptr<Instruction> d);
// Appends an annotation instruction to this module.
inline void AddAnnotationInst(std::unique_ptr<Instruction> a);
// Appends a type-declaration instruction to this module.
inline void AddType(std::unique_ptr<Instruction> t);
// Appends a constant, global variable, or OpUndef instruction to this module.
inline void AddGlobalValue(std::unique_ptr<Instruction> v);
// Appends a function to this module.
inline void AddFunction(std::unique_ptr<Function> f);
// Sets |contains_debug_info_| as true.
inline void SetContainsDebugInfo();
inline bool ContainsDebugInfo() { return contains_debug_info_; }
// Returns a vector of pointers to type-declaration instructions in this
// module.
std::vector<Instruction*> GetTypes();
std::vector<const Instruction*> GetTypes() const;
// Returns a vector of pointers to constant-creation instructions in this
// module.
std::vector<Instruction*> GetConstants();
std::vector<const Instruction*> GetConstants() const;
// Return result id of global value with |opcode|, 0 if not present.
uint32_t GetGlobalValue(spv::Op opcode) const;
// Add global value with |opcode|, |result_id| and |type_id|
void AddGlobalValue(spv::Op opcode, uint32_t result_id, uint32_t type_id);
inline uint32_t id_bound() const { return header_.bound; }
inline uint32_t version() const { return header_.version; }
inline uint32_t generator() const { return header_.generator; }
inline uint32_t schema() const { return header_.schema; }
inline void set_version(uint32_t v) { header_.version = v; }
// Iterators for capabilities instructions contained in this module.
inline inst_iterator capability_begin();
inline inst_iterator capability_end();
inline IteratorRange<inst_iterator> capabilities();
inline IteratorRange<const_inst_iterator> capabilities() const;
// Iterators for ext_inst_imports instructions contained in this module.
inline inst_iterator ext_inst_import_begin();
inline inst_iterator ext_inst_import_end();
inline IteratorRange<inst_iterator> ext_inst_imports();
inline IteratorRange<const_inst_iterator> ext_inst_imports() const;
// Return the memory model instruction contained in this module.
inline Instruction* GetMemoryModel() { return memory_model_.get(); }
inline const Instruction* GetMemoryModel() const {
return memory_model_.get();
}
// Return the sampled image address mode instruction contained in this module.
inline Instruction* GetSampledImageAddressMode() {
return sampled_image_address_mode_.get();
}
inline const Instruction* GetSampledImageAddressMode() const {
return sampled_image_address_mode_.get();
}
// There are several kinds of debug instructions, according to where they can
// appear in the logical layout of a module:
// - Section 7a: OpString, OpSourceExtension, OpSource, OpSourceContinued
// - Section 7b: OpName, OpMemberName
// - Section 7c: OpModuleProcessed
// - Mostly anywhere: OpLine and OpNoLine
//
// Iterators for debug 1 instructions (excluding OpLine & OpNoLine) contained
// in this module. These are for layout section 7a.
inline inst_iterator debug1_begin();
inline inst_iterator debug1_end();
inline IteratorRange<inst_iterator> debugs1();
inline IteratorRange<const_inst_iterator> debugs1() const;
// Iterators for debug 2 instructions (excluding OpLine & OpNoLine) contained
// in this module. These are for layout section 7b.
inline inst_iterator debug2_begin();
inline inst_iterator debug2_end();
inline IteratorRange<inst_iterator> debugs2();
inline IteratorRange<const_inst_iterator> debugs2() const;
// Iterators for debug 3 instructions (excluding OpLine & OpNoLine) contained
// in this module. These are for layout section 7c.
inline inst_iterator debug3_begin();
inline inst_iterator debug3_end();
inline IteratorRange<inst_iterator> debugs3();
inline IteratorRange<const_inst_iterator> debugs3() const;
// Iterators for debug info instructions (excluding OpLine & OpNoLine)
// contained in this module. These are OpExtInst for DebugInfo extension
// placed between section 9 and 10.
inline inst_iterator ext_inst_debuginfo_begin();
inline inst_iterator ext_inst_debuginfo_end();
inline IteratorRange<inst_iterator> ext_inst_debuginfo();
inline IteratorRange<const_inst_iterator> ext_inst_debuginfo() const;
// Iterators for entry point instructions contained in this module
inline IteratorRange<inst_iterator> entry_points();
inline IteratorRange<const_inst_iterator> entry_points() const;
// Iterators for execution_modes instructions contained in this module.
inline inst_iterator execution_mode_begin();
inline inst_iterator execution_mode_end();
inline IteratorRange<inst_iterator> execution_modes();
inline IteratorRange<const_inst_iterator> execution_modes() const;
// Iterators for annotation instructions contained in this module.
inline inst_iterator annotation_begin();
inline inst_iterator annotation_end();
IteratorRange<inst_iterator> annotations();
IteratorRange<const_inst_iterator> annotations() const;
// Iterators for extension instructions contained in this module.
inline inst_iterator extension_begin();
inline inst_iterator extension_end();
IteratorRange<inst_iterator> extensions();
IteratorRange<const_inst_iterator> extensions() const;
// Iterators for types, constants and global variables instructions.
inline inst_iterator types_values_begin();
inline inst_iterator types_values_end();
inline IteratorRange<inst_iterator> types_values();
inline IteratorRange<const_inst_iterator> types_values() const;
// Iterators for functions contained in this module.
iterator begin() { return iterator(&functions_, functions_.begin()); }
iterator end() { return iterator(&functions_, functions_.end()); }
const_iterator begin() const { return cbegin(); }
const_iterator end() const { return cend(); }
inline const_iterator cbegin() const;
inline const_iterator cend() const;
// Invokes function |f| on all instructions in this module, and optionally on
// the debug line instructions that precede them.
void ForEachInst(const std::function<void(Instruction*)>& f,
bool run_on_debug_line_insts = false);
void ForEachInst(const std::function<void(const Instruction*)>& f,
bool run_on_debug_line_insts = false) const;
// Pushes the binary segments for this instruction into the back of *|binary|.
// If |skip_nop| is true and this is a OpNop, do nothing.
void ToBinary(std::vector<uint32_t>* binary, bool skip_nop) const;
// Returns 1 more than the maximum Id value mentioned in the module.
uint32_t ComputeIdBound() const;
// Returns true if module has capability |cap|
bool HasExplicitCapability(uint32_t cap);
// Returns id for OpExtInst instruction for extension |extstr|.
// Returns 0 if not found.
uint32_t GetExtInstImportId(const char* extstr);
// Sets the associated context for this module
void SetContext(IRContext* c) { context_ = c; }
// Gets the associated context for this module
IRContext* context() const { return context_; }
// Sets the trailing debug line info to |dbg_line_info|.
void SetTrailingDbgLineInfo(std::vector<Instruction>&& dbg_line_info) {
trailing_dbg_line_info_ = std::move(dbg_line_info);
}
std::vector<Instruction>& trailing_dbg_line_info() {
return trailing_dbg_line_info_;
}
const std::vector<Instruction>& trailing_dbg_line_info() const {
return trailing_dbg_line_info_;
}
private:
ModuleHeader header_; // Module header
// The following fields respect the "Logical Layout of a Module" in
// Section 2.4 of the SPIR-V specification.
IRContext* context_;
InstructionList capabilities_;
InstructionList extensions_;
InstructionList ext_inst_imports_;
// A module only has one memory model instruction.
std::unique_ptr<Instruction> memory_model_;
// A module can only have one optional sampled image addressing mode
std::unique_ptr<Instruction> sampled_image_address_mode_;
InstructionList entry_points_;
InstructionList execution_modes_;
InstructionList debugs1_;
InstructionList debugs2_;
InstructionList debugs3_;
InstructionList ext_inst_debuginfo_;
InstructionList annotations_;
// Type declarations, constants, and global variable declarations.
InstructionList types_values_;
std::vector<std::unique_ptr<Function>> functions_;
// If the module ends with Op*Line instruction, they will not be attached to
// any instruction. We record them here, so they will not be lost.
std::vector<Instruction> trailing_dbg_line_info_;
// This module contains DebugScope/DebugNoScope or OpLine/OpNoLine.
bool contains_debug_info_;
};
// Pretty-prints |module| to |str|. Returns |str|.
std::ostream& operator<<(std::ostream& str, const Module& module);
inline void Module::AddCapability(std::unique_ptr<Instruction> c) {
capabilities_.push_back(std::move(c));
}
inline void Module::AddExtension(std::unique_ptr<Instruction> e) {
extensions_.push_back(std::move(e));
}
inline void Module::AddExtInstImport(std::unique_ptr<Instruction> e) {
ext_inst_imports_.push_back(std::move(e));
}
inline void Module::SetMemoryModel(std::unique_ptr<Instruction> m) {
memory_model_ = std::move(m);
}
inline void Module::SetSampledImageAddressMode(std::unique_ptr<Instruction> m) {
sampled_image_address_mode_ = std::move(m);
}
inline void Module::AddEntryPoint(std::unique_ptr<Instruction> e) {
entry_points_.push_back(std::move(e));
}
inline void Module::AddExecutionMode(std::unique_ptr<Instruction> e) {
execution_modes_.push_back(std::move(e));
}
inline void Module::AddDebug1Inst(std::unique_ptr<Instruction> d) {
debugs1_.push_back(std::move(d));
}
inline void Module::AddDebug2Inst(std::unique_ptr<Instruction> d) {
debugs2_.push_back(std::move(d));
}
inline void Module::AddDebug3Inst(std::unique_ptr<Instruction> d) {
debugs3_.push_back(std::move(d));
}
inline void Module::AddExtInstDebugInfo(std::unique_ptr<Instruction> d) {
ext_inst_debuginfo_.push_back(std::move(d));
}
inline void Module::AddAnnotationInst(std::unique_ptr<Instruction> a) {
annotations_.push_back(std::move(a));
}
inline void Module::AddType(std::unique_ptr<Instruction> t) {
types_values_.push_back(std::move(t));
}
inline void Module::AddGlobalValue(std::unique_ptr<Instruction> v) {
types_values_.push_back(std::move(v));
}
inline void Module::AddFunction(std::unique_ptr<Function> f) {
functions_.emplace_back(std::move(f));
}
inline void Module::SetContainsDebugInfo() { contains_debug_info_ = true; }
inline Module::inst_iterator Module::capability_begin() {
return capabilities_.begin();
}
inline Module::inst_iterator Module::capability_end() {
return capabilities_.end();
}
inline IteratorRange<Module::inst_iterator> Module::capabilities() {
return make_range(capabilities_.begin(), capabilities_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::capabilities() const {
return make_range(capabilities_.begin(), capabilities_.end());
}
inline Module::inst_iterator Module::ext_inst_import_begin() {
return ext_inst_imports_.begin();
}
inline Module::inst_iterator Module::ext_inst_import_end() {
return ext_inst_imports_.end();
}
inline IteratorRange<Module::inst_iterator> Module::ext_inst_imports() {
return make_range(ext_inst_imports_.begin(), ext_inst_imports_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::ext_inst_imports()
const {
return make_range(ext_inst_imports_.begin(), ext_inst_imports_.end());
}
inline Module::inst_iterator Module::debug1_begin() { return debugs1_.begin(); }
inline Module::inst_iterator Module::debug1_end() { return debugs1_.end(); }
inline IteratorRange<Module::inst_iterator> Module::debugs1() {
return make_range(debugs1_.begin(), debugs1_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::debugs1() const {
return make_range(debugs1_.begin(), debugs1_.end());
}
inline Module::inst_iterator Module::debug2_begin() { return debugs2_.begin(); }
inline Module::inst_iterator Module::debug2_end() { return debugs2_.end(); }
inline IteratorRange<Module::inst_iterator> Module::debugs2() {
return make_range(debugs2_.begin(), debugs2_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::debugs2() const {
return make_range(debugs2_.begin(), debugs2_.end());
}
inline Module::inst_iterator Module::debug3_begin() { return debugs3_.begin(); }
inline Module::inst_iterator Module::debug3_end() { return debugs3_.end(); }
inline IteratorRange<Module::inst_iterator> Module::debugs3() {
return make_range(debugs3_.begin(), debugs3_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::debugs3() const {
return make_range(debugs3_.begin(), debugs3_.end());
}
inline Module::inst_iterator Module::ext_inst_debuginfo_begin() {
return ext_inst_debuginfo_.begin();
}
inline Module::inst_iterator Module::ext_inst_debuginfo_end() {
return ext_inst_debuginfo_.end();
}
inline IteratorRange<Module::inst_iterator> Module::ext_inst_debuginfo() {
return make_range(ext_inst_debuginfo_.begin(), ext_inst_debuginfo_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::ext_inst_debuginfo()
const {
return make_range(ext_inst_debuginfo_.begin(), ext_inst_debuginfo_.end());
}
inline IteratorRange<Module::inst_iterator> Module::entry_points() {
return make_range(entry_points_.begin(), entry_points_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::entry_points() const {
return make_range(entry_points_.begin(), entry_points_.end());
}
inline Module::inst_iterator Module::execution_mode_begin() {
return execution_modes_.begin();
}
inline Module::inst_iterator Module::execution_mode_end() {
return execution_modes_.end();
}
inline IteratorRange<Module::inst_iterator> Module::execution_modes() {
return make_range(execution_modes_.begin(), execution_modes_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::execution_modes()
const {
return make_range(execution_modes_.begin(), execution_modes_.end());
}
inline Module::inst_iterator Module::annotation_begin() {
return annotations_.begin();
}
inline Module::inst_iterator Module::annotation_end() {
return annotations_.end();
}
inline IteratorRange<Module::inst_iterator> Module::annotations() {
return make_range(annotations_.begin(), annotations_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::annotations() const {
return make_range(annotations_.begin(), annotations_.end());
}
inline Module::inst_iterator Module::extension_begin() {
return extensions_.begin();
}
inline Module::inst_iterator Module::extension_end() {
return extensions_.end();
}
inline IteratorRange<Module::inst_iterator> Module::extensions() {
return make_range(extensions_.begin(), extensions_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::extensions() const {
return make_range(extensions_.begin(), extensions_.end());
}
inline Module::inst_iterator Module::types_values_begin() {
return types_values_.begin();
}
inline Module::inst_iterator Module::types_values_end() {
return types_values_.end();
}
inline IteratorRange<Module::inst_iterator> Module::types_values() {
return make_range(types_values_.begin(), types_values_.end());
}
inline IteratorRange<Module::const_inst_iterator> Module::types_values() const {
return make_range(types_values_.begin(), types_values_.end());
}
inline Module::const_iterator Module::cbegin() const {
return const_iterator(&functions_, functions_.cbegin());
}
inline Module::const_iterator Module::cend() const {
return const_iterator(&functions_, functions_.cend());
}
} // namespace opt
} // namespace spvtools
#endif // SOURCE_OPT_MODULE_H_