sources/third_party/shaderc/third_party/spirv-tools/source/fuzz/fuzzer_pass.h - toolchain/prebuilts/ndk-darwin/r23 - Git at Google

 // Copyright (c) 2019 Google LLC
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #ifndef SOURCE_FUZZ_FUZZER_PASS_H_
 #define SOURCE_FUZZ_FUZZER_PASS_H_

 #include <functional>
 #include <vector>

 #include "source/fuzz/fuzzer_context.h"
 #include "source/fuzz/protobufs/spirvfuzz_protobufs.h"
 #include "source/fuzz/transformation.h"
 #include "source/fuzz/transformation_context.h"
 #include "source/opt/ir_context.h"

 namespace spvtools {
 namespace fuzz {

 // Interface for applying a pass of transformations to a module.
 class FuzzerPass {
  public:
   FuzzerPass(opt::IRContext* ir_context,
              TransformationContext* transformation_context,
              FuzzerContext* fuzzer_context,
              protobufs::TransformationSequence* transformations);

   virtual ~FuzzerPass();

   // Applies the pass to the module |ir_context_|, assuming and updating
   // information from |transformation_context_|, and using |fuzzer_context_| to
   // guide the process.  Appends to |transformations_| all transformations that
   // were applied during the pass.
   virtual void Apply() = 0;

  protected:
   opt::IRContext* GetIRContext() const { return ir_context_; }

   TransformationContext* GetTransformationContext() const {
     return transformation_context_;
   }

   FuzzerContext* GetFuzzerContext() const { return fuzzer_context_; }

   protobufs::TransformationSequence* GetTransformations() const {
     return transformations_;
   }

   // Returns all instructions that are *available* at |inst_it|, which is
   // required to be inside block |block| of function |function| - that is, all
   // instructions at global scope and all instructions that strictly dominate
   // |inst_it|.
   //
   // Filters said instructions to return only those that satisfy the
   // |instruction_is_relevant| predicate.  This, for instance, could ignore all
   // instructions that have a particular decoration.
   std::vector<opt::Instruction*> FindAvailableInstructions(
       opt::Function* function, opt::BasicBlock* block,
       const opt::BasicBlock::iterator& inst_it,
       std::function<bool(opt::IRContext*, opt::Instruction*)>
           instruction_is_relevant) const;

   // A helper method that iterates through each instruction in each reachable
   // block of |function|, at all times tracking an instruction descriptor that
   // allows the latest instruction to be located even if it has no result id.
   //
   // The code to manipulate the instruction descriptor is a bit fiddly.  The
   // point of this method is to avoiding having to duplicate it in multiple
   // transformation passes.
   //
   // The function |action| is invoked for each instruction |inst_it| in block
   // |block| of function |function| that is encountered.  The
   // |instruction_descriptor| parameter to the function object allows |inst_it|
   // to be identified.
   //
   // In most intended use cases, the job of |action| is to randomly decide
   // whether to try to apply some transformation, and then - if selected - to
   // attempt to apply it.
   void ForEachInstructionWithInstructionDescriptor(
       opt::Function* function,
       std::function<
           void(opt::BasicBlock* block, opt::BasicBlock::iterator inst_it,
                const protobufs::InstructionDescriptor& instruction_descriptor)>
           action);

   // Applies the above overload of ForEachInstructionWithInstructionDescriptor
   // to every function in the module, so that |action| is applied to an
   // |instruction_descriptor| for every instruction, |inst_it|, of every |block|
   // in every |function|.
   void ForEachInstructionWithInstructionDescriptor(
       std::function<
           void(opt::Function* function, opt::BasicBlock* block,
                opt::BasicBlock::iterator inst_it,
                const protobufs::InstructionDescriptor& instruction_descriptor)>
           action);

   // A generic helper for applying a transformation that should be applicable
   // by construction, and adding it to the sequence of applied transformations.
   void ApplyTransformation(const Transformation& transformation) {
     assert(transformation.IsApplicable(GetIRContext(),
                                        *GetTransformationContext()) &&
            "Transformation should be applicable by construction.");
     transformation.Apply(GetIRContext(), GetTransformationContext());
     protobufs::Transformation transformation_message =
         transformation.ToMessage();
     assert(transformation_message.transformation_case() !=
                protobufs::Transformation::TRANSFORMATION_NOT_SET &&
            "Bad transformation.");
     *GetTransformations()->add_transformation() = transformation_message;
   }

   // A generic helper for applying a transformation only if it is applicable.
   // If it is applicable, the transformation is applied and then added to the
   // sequence of applied transformations and the function returns true.
   // Otherwise, the function returns false.
   bool MaybeApplyTransformation(const Transformation& transformation) {
     if (transformation.IsApplicable(GetIRContext(),
                                     *GetTransformationContext())) {
       transformation.Apply(GetIRContext(), GetTransformationContext());
       protobufs::Transformation transformation_message =
           transformation.ToMessage();
       assert(transformation_message.transformation_case() !=
                  protobufs::Transformation::TRANSFORMATION_NOT_SET &&
              "Bad transformation.");
       *GetTransformations()->add_transformation() = transformation_message;
       return true;
     }
     return false;
   }

   // Returns the id of an OpTypeBool instruction.  If such an instruction does
   // not exist, a transformation is applied to add it.
   uint32_t FindOrCreateBoolType();

   // Returns the id of an OpTypeInt instruction, with width and signedness
   // specified by |width| and |is_signed|, respectively.  If such an instruction
   // does not exist, a transformation is applied to add it.
   uint32_t FindOrCreateIntegerType(uint32_t width, bool is_signed);

   // Returns the id of an OpTypeFloat instruction, with width specified by
   // |width|.  If such an instruction does not exist, a transformation is
   // applied to add it.
   uint32_t FindOrCreateFloatType(uint32_t width);

   // Returns the id of an OpTypeFunction %<return_type_id> %<...argument_id>
   // instruction. If such an instruction doesn't exist, a transformation
   // is applied to create a new one.
   uint32_t FindOrCreateFunctionType(uint32_t return_type_id,
                                     const std::vector<uint32_t>& argument_id);

   // Returns the id of an OpTypeVector instruction, with |component_type_id|
   // (which must already exist) as its base type, and |component_count|
   // elements (which must be in the range [2, 4]).  If such an instruction does
   // not exist, a transformation is applied to add it.
   uint32_t FindOrCreateVectorType(uint32_t component_type_id,
                                   uint32_t component_count);

   // Returns the id of an OpTypeMatrix instruction, with |column_count| columns
   // and |row_count| rows (each of which must be in the range [2, 4]).  If the
   // float and vector types required to build this matrix type or the matrix
   // type itself do not exist, transformations are applied to add them.
   uint32_t FindOrCreateMatrixType(uint32_t column_count, uint32_t row_count);

   // Returns the id of an OpTypeStruct instruction with |component_type_ids| as
   // type ids for struct's components. If no such a struct type exists,
   // transformations are applied to add it. |component_type_ids| may not contain
   // a result id of an OpTypeFunction.
   uint32_t FindOrCreateStructType(
       const std::vector<uint32_t>& component_type_ids);

   // Returns the id of a pointer type with base type |base_type_id| (which must
   // already exist) and storage class |storage_class|.  A transformation is
   // applied to add the pointer if it does not already exist.
   uint32_t FindOrCreatePointerType(uint32_t base_type_id,
                                    SpvStorageClass storage_class);

   // Returns the id of an OpTypePointer instruction, with a integer base
   // type of width and signedness specified by |width| and |is_signed|,
   // respectively.  If the pointer type or required integer base type do not
   // exist, transformations are applied to add them.
   uint32_t FindOrCreatePointerToIntegerType(uint32_t width, bool is_signed,
                                             SpvStorageClass storage_class);

   // Returns the id of an OpConstant instruction, with a integer type of
   // width and signedness specified by |width| and |is_signed|, respectively,
   // with |words| as its value.  If either the required integer type or the
   // constant do not exist, transformations are applied to add them.
   // The returned id either participates in IdIsIrrelevant fact or not,
   // depending on the |is_irrelevant| parameter.
   uint32_t FindOrCreateIntegerConstant(const std::vector<uint32_t>& words,
                                        uint32_t width, bool is_signed,
                                        bool is_irrelevant);

   // Returns the id of an OpConstant instruction, with a floating-point
   // type of width specified by |width|, with |words| as its value.  If either
   // the required floating-point type or the constant do not exist,
   // transformations are applied to add them. The returned id either
   // participates in IdIsIrrelevant fact or not, depending on the
   // |is_irrelevant| parameter.
   uint32_t FindOrCreateFloatConstant(const std::vector<uint32_t>& words,
                                      uint32_t width, bool is_irrelevant);

   // Returns the id of an OpConstantTrue or OpConstantFalse instruction,
   // according to |value|.  If either the required instruction or the bool
   // type do not exist, transformations are applied to add them.
   // The returned id either participates in IdIsIrrelevant fact or not,
   // depending on the |is_irrelevant| parameter.
   uint32_t FindOrCreateBoolConstant(bool value, bool is_irrelevant);

   // Returns the id of an OpConstant instruction of type with |type_id|
   // that consists of |words|. If that instruction doesn't exist,
   // transformations are applied to add it. |type_id| must be a valid
   // result id of either scalar or boolean OpType* instruction that exists
   // in the module. The returned id either participates in IdIsIrrelevant fact
   // or not, depending on the |is_irrelevant| parameter.
   uint32_t FindOrCreateConstant(const std::vector<uint32_t>& words,
                                 uint32_t type_id, bool is_irrelevant);

   // Returns the id of an OpConstantComposite instruction of type with |type_id|
   // that consists of |component_ids|. If that instruction doesn't exist,
   // transformations are applied to add it. |type_id| must be a valid
   // result id of an OpType* instruction that represents a composite type
   // (i.e. a vector, matrix, struct or array).
   // The returned id either participates in IdIsIrrelevant fact or not,
   // depending on the |is_irrelevant| parameter.
   uint32_t FindOrCreateCompositeConstant(
       const std::vector<uint32_t>& component_ids, uint32_t type_id,
       bool is_irrelevant);

   // Returns the result id of an instruction of the form:
   //   %id = OpUndef %|type_id|
   // If no such instruction exists, a transformation is applied to add it.
   uint32_t FindOrCreateGlobalUndef(uint32_t type_id);

   // Returns the id of an OpNullConstant instruction of type |type_id|. If
   // that instruction doesn't exist, it is added through a transformation.
   // |type_id| must be a valid result id of an OpType* instruction that exists
   // in the module.
   uint32_t FindOrCreateNullConstant(uint32_t type_id);

   // Define a *basic type* to be an integer, boolean or floating-point type,
   // or a matrix, vector, struct or fixed-size array built from basic types.  In
   // particular, a basic type cannot contain an opaque type (such as an image),
   // or a runtime-sized array.
   //
   // Yields a pair, (basic_type_ids, basic_type_ids_to_pointers), such that:
   // - basic_type_ids captures every basic type declared in the module.
   // - basic_type_ids_to_pointers maps every such basic type to the sequence
   //   of all pointer types that have storage class |storage_class| and the
   //   given basic type as their pointee type.  The sequence may be empty for
   //   some basic types if no pointers to those types are defined for the given
   //   storage class, and the sequence will have multiple elements if there are
   //   repeated pointer declarations for the same basic type and storage class.
   std::pair<std::vector<uint32_t>, std::map<uint32_t, std::vector<uint32_t>>>
   GetAvailableBasicTypesAndPointers(SpvStorageClass storage_class) const;

   // Given a type id, |scalar_or_composite_type_id|, which must correspond to
   // some scalar or composite type, returns the result id of an instruction
   // defining a constant of the given type that is zero or false at everywhere.
   // If such an instruction does not yet exist, transformations are applied to
   // add it. The returned id either participates in IdIsIrrelevant fact or not,
   // depending on the |is_irrelevant| parameter.
   //
   // Examples:
   // --------------+-------------------------------
   //   TYPE        | RESULT is id corresponding to
   // --------------+-------------------------------
   //   bool        | false
   // --------------+-------------------------------
   //   bvec4       | (false, false, false, false)
   // --------------+-------------------------------
   //   float       | 0.0
   // --------------+-------------------------------
   //   vec2        | (0.0, 0.0)
   // --------------+-------------------------------
   //   int[3]      | [0, 0, 0]
   // --------------+-------------------------------
   //   struct S {  |
   //     int i;    | S(0, false, (0u, 0u))
   //     bool b;   |
   //     uint2 u;  |
   //   }           |
   // --------------+-------------------------------
   uint32_t FindOrCreateZeroConstant(uint32_t scalar_or_composite_type_id,
                                     bool is_irrelevant);

   // Adds a pair (id_use_descriptor, |replacement_id|) to the vector
   // |uses_to_replace|, where id_use_descriptor is the id use descriptor
   // representing the usage of an id in the |use_inst| instruction, at operand
   // index |use_index|, only if the instruction is in a basic block.
   // If the instruction is not in a basic block, it does nothing.
   void MaybeAddUseToReplace(
       opt::Instruction* use_inst, uint32_t use_index, uint32_t replacement_id,
       std::vector<std::pair<protobufs::IdUseDescriptor, uint32_t>>*
           uses_to_replace);

   // Returns the preheader of the loop with header |header_id|, which satisfies
   // all of the following conditions:
   // - It is the only out-of-loop predecessor of the header
   // - It unconditionally branches to the header
   // - It is not a loop header itself
   // If such preheader does not exist, a new one is added and returned.
   // Requires |header_id| to be the label id of a loop header block that is
   // reachable in the CFG (and thus has at least 2 predecessors).
   opt::BasicBlock* GetOrCreateSimpleLoopPreheader(uint32_t header_id);

   // Returns the second block in the pair obtained by splitting |block_id| just
   // after the last OpPhi or OpVariable instruction in it. Assumes that the
   // block is not a loop header.
   opt::BasicBlock* SplitBlockAfterOpPhiOrOpVariable(uint32_t block_id);

   // Returns the id of an available local variable (storage class Function) with
   // the fact PointeeValueIsIrrelevant set according to
   // |pointee_value_is_irrelevant|. If there is no such variable, it creates one
   // in the |function| adding a zero initializer constant that is irrelevant.
   // The new variable has the fact PointeeValueIsIrrelevant set according to
   // |pointee_value_is_irrelevant|. The function returns the id of the created
   // variable.
   uint32_t FindOrCreateLocalVariable(uint32_t pointer_type_id,
                                      uint32_t function_id,
                                      bool pointee_value_is_irrelevant);

   // Returns the id of an available global variable (storage class Private or
   // Workgroup) with the fact PointeeValueIsIrrelevant set according to
   // |pointee_value_is_irrelevant|. If there is no such variable, it creates
   // one, adding a zero initializer constant that is irrelevant. The new
   // variable has the fact PointeeValueIsIrrelevant set according to
   // |pointee_value_is_irrelevant|. The function returns the id of the created
   // variable.
   uint32_t FindOrCreateGlobalVariable(uint32_t pointer_type_id,
                                       bool pointee_value_is_irrelevant);

  private:
   opt::IRContext* ir_context_;
   TransformationContext* transformation_context_;
   FuzzerContext* fuzzer_context_;
   protobufs::TransformationSequence* transformations_;
 };

 }  // namespace fuzz
 }  // namespace spvtools

 #endif  // SOURCE_FUZZ_FUZZER_PASS_H_
	// Copyright (c) 2019 Google LLC
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#ifndef SOURCE_FUZZ_FUZZER_PASS_H_
	#define SOURCE_FUZZ_FUZZER_PASS_H_

	#include <functional>
	#include <vector>

	#include "source/fuzz/fuzzer_context.h"
	#include "source/fuzz/protobufs/spirvfuzz_protobufs.h"
	#include "source/fuzz/transformation.h"
	#include "source/fuzz/transformation_context.h"
	#include "source/opt/ir_context.h"

	namespace spvtools {
	namespace fuzz {

	// Interface for applying a pass of transformations to a module.
	class FuzzerPass {
	public:
	FuzzerPass(opt::IRContext* ir_context,
	TransformationContext* transformation_context,
	FuzzerContext* fuzzer_context,
	protobufs::TransformationSequence* transformations);

	virtual ~FuzzerPass();

	// Applies the pass to the module \|ir_context_\|, assuming and updating
	// information from \|transformation_context_\|, and using \|fuzzer_context_\| to
	// guide the process. Appends to \|transformations_\| all transformations that
	// were applied during the pass.
	virtual void Apply() = 0;

	protected:
	opt::IRContext* GetIRContext() const { return ir_context_; }

	TransformationContext* GetTransformationContext() const {
	return transformation_context_;
	}

	FuzzerContext* GetFuzzerContext() const { return fuzzer_context_; }

	protobufs::TransformationSequence* GetTransformations() const {
	return transformations_;
	}

	// Returns all instructions that are available at \|inst_it\|, which is
	// required to be inside block \|block\| of function \|function\| - that is, all
	// instructions at global scope and all instructions that strictly dominate
	// \|inst_it\|.
	//
	// Filters said instructions to return only those that satisfy the
	// \|instruction_is_relevant\| predicate. This, for instance, could ignore all
	// instructions that have a particular decoration.
	std::vector<opt::Instruction*> FindAvailableInstructions(
	opt::Function* function, opt::BasicBlock* block,
	const opt::BasicBlock::iterator& inst_it,
	std::function<bool(opt::IRContext, opt::Instruction)>
	instruction_is_relevant) const;

	// A helper method that iterates through each instruction in each reachable
	// block of \|function\|, at all times tracking an instruction descriptor that
	// allows the latest instruction to be located even if it has no result id.
	//
	// The code to manipulate the instruction descriptor is a bit fiddly. The
	// point of this method is to avoiding having to duplicate it in multiple
	// transformation passes.
	//
	// The function \|action\| is invoked for each instruction \|inst_it\| in block
	// \|block\| of function \|function\| that is encountered. The
	// \|instruction_descriptor\| parameter to the function object allows \|inst_it\|
	// to be identified.
	//
	// In most intended use cases, the job of \|action\| is to randomly decide
	// whether to try to apply some transformation, and then - if selected - to
	// attempt to apply it.
	void ForEachInstructionWithInstructionDescriptor(
	opt::Function* function,
	std::function<
	void(opt::BasicBlock* block, opt::BasicBlock::iterator inst_it,
	const protobufs::InstructionDescriptor& instruction_descriptor)>
	action);

	// Applies the above overload of ForEachInstructionWithInstructionDescriptor
	// to every function in the module, so that \|action\| is applied to an
	// \|instruction_descriptor\| for every instruction, \|inst_it\|, of every \|block\|
	// in every \|function\|.
	void ForEachInstructionWithInstructionDescriptor(
	std::function<
	void(opt::Function* function, opt::BasicBlock* block,
	opt::BasicBlock::iterator inst_it,
	const protobufs::InstructionDescriptor& instruction_descriptor)>
	action);

	// A generic helper for applying a transformation that should be applicable
	// by construction, and adding it to the sequence of applied transformations.
	void ApplyTransformation(const Transformation& transformation) {
	assert(transformation.IsApplicable(GetIRContext(),
	*GetTransformationContext()) &&
	"Transformation should be applicable by construction.");
	transformation.Apply(GetIRContext(), GetTransformationContext());
	protobufs::Transformation transformation_message =
	transformation.ToMessage();
	assert(transformation_message.transformation_case() !=
	protobufs::Transformation::TRANSFORMATION_NOT_SET &&
	"Bad transformation.");
	*GetTransformations()->add_transformation() = transformation_message;
	}

	// A generic helper for applying a transformation only if it is applicable.
	// If it is applicable, the transformation is applied and then added to the
	// sequence of applied transformations and the function returns true.
	// Otherwise, the function returns false.
	bool MaybeApplyTransformation(const Transformation& transformation) {
	if (transformation.IsApplicable(GetIRContext(),
	*GetTransformationContext())) {
	transformation.Apply(GetIRContext(), GetTransformationContext());
	protobufs::Transformation transformation_message =
	transformation.ToMessage();
	assert(transformation_message.transformation_case() !=
	protobufs::Transformation::TRANSFORMATION_NOT_SET &&
	"Bad transformation.");
	*GetTransformations()->add_transformation() = transformation_message;
	return true;
	}
	return false;
	}

	// Returns the id of an OpTypeBool instruction. If such an instruction does
	// not exist, a transformation is applied to add it.
	uint32_t FindOrCreateBoolType();

	// Returns the id of an OpTypeInt instruction, with width and signedness
	// specified by \|width\| and \|is_signed\|, respectively. If such an instruction
	// does not exist, a transformation is applied to add it.
	uint32_t FindOrCreateIntegerType(uint32_t width, bool is_signed);

	// Returns the id of an OpTypeFloat instruction, with width specified by
	// \|width\|. If such an instruction does not exist, a transformation is
	// applied to add it.
	uint32_t FindOrCreateFloatType(uint32_t width);

	// Returns the id of an OpTypeFunction %<return_type_id> %<...argument_id>
	// instruction. If such an instruction doesn't exist, a transformation
	// is applied to create a new one.
	uint32_t FindOrCreateFunctionType(uint32_t return_type_id,
	const std::vector<uint32_t>& argument_id);

	// Returns the id of an OpTypeVector instruction, with \|component_type_id\|
	// (which must already exist) as its base type, and \|component_count\|
	// elements (which must be in the range [2, 4]). If such an instruction does
	// not exist, a transformation is applied to add it.
	uint32_t FindOrCreateVectorType(uint32_t component_type_id,
	uint32_t component_count);

	// Returns the id of an OpTypeMatrix instruction, with \|column_count\| columns
	// and \|row_count\| rows (each of which must be in the range [2, 4]). If the
	// float and vector types required to build this matrix type or the matrix
	// type itself do not exist, transformations are applied to add them.
	uint32_t FindOrCreateMatrixType(uint32_t column_count, uint32_t row_count);

	// Returns the id of an OpTypeStruct instruction with \|component_type_ids\| as
	// type ids for struct's components. If no such a struct type exists,
	// transformations are applied to add it. \|component_type_ids\| may not contain
	// a result id of an OpTypeFunction.
	uint32_t FindOrCreateStructType(
	const std::vector<uint32_t>& component_type_ids);

	// Returns the id of a pointer type with base type \|base_type_id\| (which must
	// already exist) and storage class \|storage_class\|. A transformation is
	// applied to add the pointer if it does not already exist.
	uint32_t FindOrCreatePointerType(uint32_t base_type_id,
	SpvStorageClass storage_class);

	// Returns the id of an OpTypePointer instruction, with a integer base
	// type of width and signedness specified by \|width\| and \|is_signed\|,
	// respectively. If the pointer type or required integer base type do not
	// exist, transformations are applied to add them.
	uint32_t FindOrCreatePointerToIntegerType(uint32_t width, bool is_signed,
	SpvStorageClass storage_class);

	// Returns the id of an OpConstant instruction, with a integer type of
	// width and signedness specified by \|width\| and \|is_signed\|, respectively,
	// with \|words\| as its value. If either the required integer type or the
	// constant do not exist, transformations are applied to add them.
	// The returned id either participates in IdIsIrrelevant fact or not,
	// depending on the \|is_irrelevant\| parameter.
	uint32_t FindOrCreateIntegerConstant(const std::vector<uint32_t>& words,
	uint32_t width, bool is_signed,
	bool is_irrelevant);

	// Returns the id of an OpConstant instruction, with a floating-point
	// type of width specified by \|width\|, with \|words\| as its value. If either
	// the required floating-point type or the constant do not exist,
	// transformations are applied to add them. The returned id either
	// participates in IdIsIrrelevant fact or not, depending on the
	// \|is_irrelevant\| parameter.
	uint32_t FindOrCreateFloatConstant(const std::vector<uint32_t>& words,
	uint32_t width, bool is_irrelevant);

	// Returns the id of an OpConstantTrue or OpConstantFalse instruction,
	// according to \|value\|. If either the required instruction or the bool
	// type do not exist, transformations are applied to add them.
	// The returned id either participates in IdIsIrrelevant fact or not,
	// depending on the \|is_irrelevant\| parameter.
	uint32_t FindOrCreateBoolConstant(bool value, bool is_irrelevant);

	// Returns the id of an OpConstant instruction of type with \|type_id\|
	// that consists of \|words\|. If that instruction doesn't exist,
	// transformations are applied to add it. \|type_id\| must be a valid
	// result id of either scalar or boolean OpType* instruction that exists
	// in the module. The returned id either participates in IdIsIrrelevant fact
	// or not, depending on the \|is_irrelevant\| parameter.
	uint32_t FindOrCreateConstant(const std::vector<uint32_t>& words,
	uint32_t type_id, bool is_irrelevant);

	// Returns the id of an OpConstantComposite instruction of type with \|type_id\|
	// that consists of \|component_ids\|. If that instruction doesn't exist,
	// transformations are applied to add it. \|type_id\| must be a valid
	// result id of an OpType* instruction that represents a composite type
	// (i.e. a vector, matrix, struct or array).
	// The returned id either participates in IdIsIrrelevant fact or not,
	// depending on the \|is_irrelevant\| parameter.
	uint32_t FindOrCreateCompositeConstant(
	const std::vector<uint32_t>& component_ids, uint32_t type_id,
	bool is_irrelevant);

	// Returns the result id of an instruction of the form:
	// %id = OpUndef %\|type_id\|
	// If no such instruction exists, a transformation is applied to add it.
	uint32_t FindOrCreateGlobalUndef(uint32_t type_id);

	// Returns the id of an OpNullConstant instruction of type \|type_id\|. If
	// that instruction doesn't exist, it is added through a transformation.
	// \|type_id\| must be a valid result id of an OpType* instruction that exists
	// in the module.
	uint32_t FindOrCreateNullConstant(uint32_t type_id);

	// Define a basic type to be an integer, boolean or floating-point type,
	// or a matrix, vector, struct or fixed-size array built from basic types. In
	// particular, a basic type cannot contain an opaque type (such as an image),
	// or a runtime-sized array.
	//
	// Yields a pair, (basic_type_ids, basic_type_ids_to_pointers), such that:
	// - basic_type_ids captures every basic type declared in the module.
	// - basic_type_ids_to_pointers maps every such basic type to the sequence
	// of all pointer types that have storage class \|storage_class\| and the
	// given basic type as their pointee type. The sequence may be empty for
	// some basic types if no pointers to those types are defined for the given
	// storage class, and the sequence will have multiple elements if there are
	// repeated pointer declarations for the same basic type and storage class.
	std::pair<std::vector<uint32_t>, std::map<uint32_t, std::vector<uint32_t>>>
	GetAvailableBasicTypesAndPointers(SpvStorageClass storage_class) const;

	// Given a type id, \|scalar_or_composite_type_id\|, which must correspond to
	// some scalar or composite type, returns the result id of an instruction
	// defining a constant of the given type that is zero or false at everywhere.
	// If such an instruction does not yet exist, transformations are applied to
	// add it. The returned id either participates in IdIsIrrelevant fact or not,
	// depending on the \|is_irrelevant\| parameter.
	//
	// Examples:
	// --------------+-------------------------------
	// TYPE \| RESULT is id corresponding to
	// --------------+-------------------------------
	// bool \| false
	// --------------+-------------------------------
	// bvec4 \| (false, false, false, false)
	// --------------+-------------------------------
	// float \| 0.0
	// --------------+-------------------------------
	// vec2 \| (0.0, 0.0)
	// --------------+-------------------------------
	// int[3] \| [0, 0, 0]
	// --------------+-------------------------------
	// struct S { \|
	// int i; \| S(0, false, (0u, 0u))
	// bool b; \|
	// uint2 u; \|
	// } \|
	// --------------+-------------------------------
	uint32_t FindOrCreateZeroConstant(uint32_t scalar_or_composite_type_id,
	bool is_irrelevant);

	// Adds a pair (id_use_descriptor, \|replacement_id\|) to the vector
	// \|uses_to_replace\|, where id_use_descriptor is the id use descriptor
	// representing the usage of an id in the \|use_inst\| instruction, at operand
	// index \|use_index\|, only if the instruction is in a basic block.
	// If the instruction is not in a basic block, it does nothing.
	void MaybeAddUseToReplace(
	opt::Instruction* use_inst, uint32_t use_index, uint32_t replacement_id,
	std::vector<std::pair<protobufs::IdUseDescriptor, uint32_t>>*
	uses_to_replace);

	// Returns the preheader of the loop with header \|header_id\|, which satisfies
	// all of the following conditions:
	// - It is the only out-of-loop predecessor of the header
	// - It unconditionally branches to the header
	// - It is not a loop header itself
	// If such preheader does not exist, a new one is added and returned.
	// Requires \|header_id\| to be the label id of a loop header block that is
	// reachable in the CFG (and thus has at least 2 predecessors).
	opt::BasicBlock* GetOrCreateSimpleLoopPreheader(uint32_t header_id);

	// Returns the second block in the pair obtained by splitting \|block_id\| just
	// after the last OpPhi or OpVariable instruction in it. Assumes that the
	// block is not a loop header.
	opt::BasicBlock* SplitBlockAfterOpPhiOrOpVariable(uint32_t block_id);

	// Returns the id of an available local variable (storage class Function) with
	// the fact PointeeValueIsIrrelevant set according to
	// \|pointee_value_is_irrelevant\|. If there is no such variable, it creates one
	// in the \|function\| adding a zero initializer constant that is irrelevant.
	// The new variable has the fact PointeeValueIsIrrelevant set according to
	// \|pointee_value_is_irrelevant\|. The function returns the id of the created
	// variable.
	uint32_t FindOrCreateLocalVariable(uint32_t pointer_type_id,
	uint32_t function_id,
	bool pointee_value_is_irrelevant);

	// Returns the id of an available global variable (storage class Private or
	// Workgroup) with the fact PointeeValueIsIrrelevant set according to
	// \|pointee_value_is_irrelevant\|. If there is no such variable, it creates
	// one, adding a zero initializer constant that is irrelevant. The new
	// variable has the fact PointeeValueIsIrrelevant set according to
	// \|pointee_value_is_irrelevant\|. The function returns the id of the created
	// variable.
	uint32_t FindOrCreateGlobalVariable(uint32_t pointer_type_id,
	bool pointee_value_is_irrelevant);

	private:
	opt::IRContext* ir_context_;
	TransformationContext* transformation_context_;
	FuzzerContext* fuzzer_context_;
	protobufs::TransformationSequence* transformations_;
	};

	} // namespace fuzz
	} // namespace spvtools

	#endif // SOURCE_FUZZ_FUZZER_PASS_H_