third_party/SPIRV-Tools/source/fuzz/fuzzer_pass_construct_composites.cpp - SwiftShader - 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.

 #include "source/fuzz/fuzzer_pass_construct_composites.h"

 #include <memory>

 #include "source/fuzz/available_instructions.h"
 #include "source/fuzz/fuzzer_util.h"
 #include "source/fuzz/transformation_composite_construct.h"

 namespace spvtools {
 namespace fuzz {

 FuzzerPassConstructComposites::FuzzerPassConstructComposites(
     opt::IRContext* ir_context, TransformationContext* transformation_context,
     FuzzerContext* fuzzer_context,
     protobufs::TransformationSequence* transformations,
     bool ignore_inapplicable_transformations)
     : FuzzerPass(ir_context, transformation_context, fuzzer_context,
                  transformations, ignore_inapplicable_transformations) {}

 void FuzzerPassConstructComposites::Apply() {
   // Gather up the ids of all composite types, but skip block-/buffer
   // block-decorated struct types.
   std::vector<uint32_t> composite_type_ids;
   for (auto& inst : GetIRContext()->types_values()) {
     if (fuzzerutil::IsCompositeType(
             GetIRContext()->get_type_mgr()->GetType(inst.result_id())) &&
         !fuzzerutil::HasBlockOrBufferBlockDecoration(GetIRContext(),
                                                      inst.result_id())) {
       composite_type_ids.push_back(inst.result_id());
     }
   }

   if (composite_type_ids.empty()) {
     // There are no composite types, so this fuzzer pass cannot do anything.
     return;
   }

   AvailableInstructions available_composite_constituents(
       GetIRContext(),
       [this](opt::IRContext* ir_context, opt::Instruction* inst) -> bool {
         if (!inst->result_id() || !inst->type_id()) {
           return false;
         }

         // If the id is irrelevant, we can use it since it will not
         // participate in DataSynonym fact. Otherwise, we should be able
         // to produce a synonym out of the id.
         return GetTransformationContext()->GetFactManager()->IdIsIrrelevant(
                    inst->result_id()) ||
                fuzzerutil::CanMakeSynonymOf(ir_context,
                                             *GetTransformationContext(), *inst);
       });

   ForEachInstructionWithInstructionDescriptor(
       [this, &available_composite_constituents, &composite_type_ids](
           opt::Function* /*unused*/, opt::BasicBlock* /*unused*/,
           opt::BasicBlock::iterator inst_it,
           const protobufs::InstructionDescriptor& instruction_descriptor)
           -> void {
         // Randomly decide whether to try inserting a composite construction
         // here.
         if (!GetFuzzerContext()->ChoosePercentage(
                 GetFuzzerContext()->GetChanceOfConstructingComposite())) {
           return;
         }

         // Check whether it is legitimate to insert a composite construction
         // before the instruction.
         if (!fuzzerutil::CanInsertOpcodeBeforeInstruction(
                 spv::Op::OpCompositeConstruct, inst_it)) {
           return;
         }

         // For each instruction that is available at this program point (i.e. an
         // instruction that is global or whose definition strictly dominates the
         // program point) and suitable for making a synonym of, associate it
         // with the id of its result type.
         TypeIdToInstructions type_id_to_available_instructions;
         auto available_instructions =
             available_composite_constituents.GetAvailableBeforeInstruction(
                 &*inst_it);
         for (uint32_t available_instruction_index = 0;
              available_instruction_index < available_instructions.size();
              available_instruction_index++) {
           opt::Instruction* inst =
               available_instructions[available_instruction_index];
           type_id_to_available_instructions[inst->type_id()].push_back(
               inst->result_id());
         }

         // At this point, |composite_type_ids| captures all the composite types
         // we could try to create, while |type_id_to_available_instructions|
         // captures all the available result ids we might use, organized by
         // type.

         // Now we choose a composite type to construct, building it from
         // available constituent components and using zero constants if suitable
         // components are not available.

         std::vector<uint32_t> constructor_arguments;
         uint32_t chosen_composite_type =
             composite_type_ids[GetFuzzerContext()->RandomIndex(
                 composite_type_ids)];

         // Construct a composite of this type, using an appropriate helper
         // method depending on the kind of composite type.
         auto composite_type_inst =
             GetIRContext()->get_def_use_mgr()->GetDef(chosen_composite_type);
         switch (composite_type_inst->opcode()) {
           case spv::Op::OpTypeArray:
             constructor_arguments = FindComponentsToConstructArray(
                 *composite_type_inst, type_id_to_available_instructions);
             break;
           case spv::Op::OpTypeMatrix:
             constructor_arguments = FindComponentsToConstructMatrix(
                 *composite_type_inst, type_id_to_available_instructions);
             break;
           case spv::Op::OpTypeStruct:
             constructor_arguments = FindComponentsToConstructStruct(
                 *composite_type_inst, type_id_to_available_instructions);
             break;
           case spv::Op::OpTypeVector:
             constructor_arguments = FindComponentsToConstructVector(
                 *composite_type_inst, type_id_to_available_instructions);
             break;
           default:
             assert(false &&
                    "The space of possible composite types should be covered "
                    "by the above cases.");
             break;
         }
         assert(!constructor_arguments.empty());

         // Make and apply a transformation.
         ApplyTransformation(TransformationCompositeConstruct(
             chosen_composite_type, constructor_arguments,
             instruction_descriptor, GetFuzzerContext()->GetFreshId()));
       });
 }

 std::vector<uint32_t>
 FuzzerPassConstructComposites::FindComponentsToConstructArray(
     const opt::Instruction& array_type_instruction,
     const TypeIdToInstructions& type_id_to_available_instructions) {
   assert(array_type_instruction.opcode() == spv::Op::OpTypeArray &&
          "Precondition: instruction must be an array type.");

   // Get the element type for the array.
   auto element_type_id = array_type_instruction.GetSingleWordInOperand(0);

   // Get all instructions at our disposal that compute something of this element
   // type.
   auto available_instructions =
       type_id_to_available_instructions.find(element_type_id);

   uint32_t array_length =
       GetIRContext()
           ->get_def_use_mgr()
           ->GetDef(array_type_instruction.GetSingleWordInOperand(1))
           ->GetSingleWordInOperand(0);

   std::vector<uint32_t> result;
   for (uint32_t index = 0; index < array_length; index++) {
     if (available_instructions == type_id_to_available_instructions.cend()) {
       // No suitable instructions are available, so use a zero constant
       result.push_back(FindOrCreateZeroConstant(element_type_id, true));
     } else {
       result.push_back(
           available_instructions->second[GetFuzzerContext()->RandomIndex(
               available_instructions->second)]);
     }
   }
   return result;
 }

 std::vector<uint32_t>
 FuzzerPassConstructComposites::FindComponentsToConstructMatrix(
     const opt::Instruction& matrix_type_instruction,
     const TypeIdToInstructions& type_id_to_available_instructions) {
   assert(matrix_type_instruction.opcode() == spv::Op::OpTypeMatrix &&
          "Precondition: instruction must be a matrix type.");

   // Get the element type for the matrix.
   auto element_type_id = matrix_type_instruction.GetSingleWordInOperand(0);

   // Get all instructions at our disposal that compute something of this element
   // type.
   auto available_instructions =
       type_id_to_available_instructions.find(element_type_id);

   std::vector<uint32_t> result;
   for (uint32_t index = 0;
        index < matrix_type_instruction.GetSingleWordInOperand(1); index++) {
     if (available_instructions == type_id_to_available_instructions.cend()) {
       // No suitable components are available, so use a zero constant.
       result.push_back(FindOrCreateZeroConstant(element_type_id, true));
     } else {
       result.push_back(
           available_instructions->second[GetFuzzerContext()->RandomIndex(
               available_instructions->second)]);
     }
   }
   return result;
 }

 std::vector<uint32_t>
 FuzzerPassConstructComposites::FindComponentsToConstructStruct(
     const opt::Instruction& struct_type_instruction,
     const TypeIdToInstructions& type_id_to_available_instructions) {
   assert(struct_type_instruction.opcode() == spv::Op::OpTypeStruct &&
          "Precondition: instruction must be a struct type.");
   std::vector<uint32_t> result;
   // Consider the type of each field of the struct.
   for (uint32_t in_operand_index = 0;
        in_operand_index < struct_type_instruction.NumInOperands();
        in_operand_index++) {
     auto element_type_id =
         struct_type_instruction.GetSingleWordInOperand(in_operand_index);
     // Find the instructions at our disposal that compute something of the field
     // type.
     auto available_instructions =
         type_id_to_available_instructions.find(element_type_id);
     if (available_instructions == type_id_to_available_instructions.cend()) {
       // No suitable component is available for this element type, so use a zero
       // constant.
       result.push_back(FindOrCreateZeroConstant(element_type_id, true));
     } else {
       result.push_back(
           available_instructions->second[GetFuzzerContext()->RandomIndex(
               available_instructions->second)]);
     }
   }
   return result;
 }

 std::vector<uint32_t>
 FuzzerPassConstructComposites::FindComponentsToConstructVector(
     const opt::Instruction& vector_type_instruction,
     const TypeIdToInstructions& type_id_to_available_instructions) {
   assert(vector_type_instruction.opcode() == spv::Op::OpTypeVector &&
          "Precondition: instruction must be a vector type.");

   // Get details of the type underlying the vector, and the width of the vector,
   // for convenience.
   auto element_type_id = vector_type_instruction.GetSingleWordInOperand(0);
   auto element_type = GetIRContext()->get_type_mgr()->GetType(element_type_id);
   auto element_count = vector_type_instruction.GetSingleWordInOperand(1);

   // Collect a mapping, from type id to width, for scalar/vector types that are
   // smaller in width than |vector_type|, but that have the same underlying
   // type.  For example, if |vector_type| is vec4, the mapping will be:
   //   { float -> 1, vec2 -> 2, vec3 -> 3 }
   // The mapping will have missing entries if some of these types do not exist.

   std::map<uint32_t, uint32_t> smaller_vector_type_id_to_width;
   // Add the underlying type.  This id must exist, in order for |vector_type| to
   // exist.
   smaller_vector_type_id_to_width[element_type_id] = 1;

   // Now add every vector type with width at least 2, and less than the width of
   // |vector_type|.
   for (uint32_t width = 2; width < element_count; width++) {
     opt::analysis::Vector smaller_vector_type(element_type, width);
     auto smaller_vector_type_id =
         GetIRContext()->get_type_mgr()->GetId(&smaller_vector_type);
     // We might find that there is no declared type of this smaller width.
     // For example, a module can declare vec4 without having declared vec2 or
     // vec3.
     if (smaller_vector_type_id) {
       smaller_vector_type_id_to_width[smaller_vector_type_id] = width;
     }
   }

   // Now we know the types that are available to us, we set about populating a
   // vector of the right length.  We do this by deciding, with no order in mind,
   // which instructions we will use to populate the vector, and subsequently
   // randomly choosing an order.  This is to avoid biasing construction of
   // vectors with smaller vectors to the left and scalars to the right.  That is
   // a concern because, e.g. in the case of populating a vec4, if we populate
   // the constructor instructions left-to-right, we can always choose a vec3 to
   // construct the first three elements, but can only choose a vec3 to construct
   // the last three elements if we chose a float to construct the first element
   // (otherwise there will not be space left for a vec3).

   uint32_t vector_slots_used = 0;

   // The instructions result ids we will use to construct the vector, in no
   // particular order at this stage.
   std::vector<uint32_t> result;

   while (vector_slots_used < element_count) {
     std::vector<uint32_t> instructions_to_choose_from;
     for (auto& entry : smaller_vector_type_id_to_width) {
       if (entry.second >
           std::min(element_count - 1, element_count - vector_slots_used)) {
         continue;
       }
       auto available_instructions =
           type_id_to_available_instructions.find(entry.first);
       if (available_instructions == type_id_to_available_instructions.cend()) {
         continue;
       }
       instructions_to_choose_from.insert(instructions_to_choose_from.end(),
                                          available_instructions->second.begin(),
                                          available_instructions->second.end());
     }
     // If there are no instructions to choose from then use a zero constant,
     // otherwise select one of the instructions at random.
     uint32_t id_of_instruction_to_use =
         instructions_to_choose_from.empty()
             ? FindOrCreateZeroConstant(element_type_id, true)
             : instructions_to_choose_from[GetFuzzerContext()->RandomIndex(
                   instructions_to_choose_from)];
     opt::Instruction* instruction_to_use =
         GetIRContext()->get_def_use_mgr()->GetDef(id_of_instruction_to_use);
     result.push_back(instruction_to_use->result_id());
     auto chosen_type =
         GetIRContext()->get_type_mgr()->GetType(instruction_to_use->type_id());
     if (chosen_type->AsVector()) {
       assert(chosen_type->AsVector()->element_type() == element_type);
       assert(chosen_type->AsVector()->element_count() < element_count);
       assert(chosen_type->AsVector()->element_count() <=
              element_count - vector_slots_used);
       vector_slots_used += chosen_type->AsVector()->element_count();
     } else {
       assert(chosen_type == element_type);
       vector_slots_used += 1;
     }
   }
   assert(vector_slots_used == element_count);

   GetFuzzerContext()->Shuffle(&result);
   return result;
 }

 }  // namespace fuzz
 }  // namespace spvtools
	// 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.

	#include "source/fuzz/fuzzer_pass_construct_composites.h"

	#include <memory>

	#include "source/fuzz/available_instructions.h"
	#include "source/fuzz/fuzzer_util.h"
	#include "source/fuzz/transformation_composite_construct.h"

	namespace spvtools {
	namespace fuzz {

	FuzzerPassConstructComposites::FuzzerPassConstructComposites(
	opt::IRContext* ir_context, TransformationContext* transformation_context,
	FuzzerContext* fuzzer_context,
	protobufs::TransformationSequence* transformations,
	bool ignore_inapplicable_transformations)
	: FuzzerPass(ir_context, transformation_context, fuzzer_context,
	transformations, ignore_inapplicable_transformations) {}

	void FuzzerPassConstructComposites::Apply() {
	// Gather up the ids of all composite types, but skip block-/buffer
	// block-decorated struct types.
	std::vector<uint32_t> composite_type_ids;
	for (auto& inst : GetIRContext()->types_values()) {
	if (fuzzerutil::IsCompositeType(
	GetIRContext()->get_type_mgr()->GetType(inst.result_id())) &&
	!fuzzerutil::HasBlockOrBufferBlockDecoration(GetIRContext(),
	inst.result_id())) {
	composite_type_ids.push_back(inst.result_id());
	}
	}

	if (composite_type_ids.empty()) {
	// There are no composite types, so this fuzzer pass cannot do anything.
	return;
	}

	AvailableInstructions available_composite_constituents(
	GetIRContext(),
	[this](opt::IRContext* ir_context, opt::Instruction* inst) -> bool {
	if (!inst->result_id() \|\| !inst->type_id()) {
	return false;
	}

	// If the id is irrelevant, we can use it since it will not
	// participate in DataSynonym fact. Otherwise, we should be able
	// to produce a synonym out of the id.
	return GetTransformationContext()->GetFactManager()->IdIsIrrelevant(
	inst->result_id()) \|\|
	fuzzerutil::CanMakeSynonymOf(ir_context,
	GetTransformationContext(), inst);
	});

	ForEachInstructionWithInstructionDescriptor(
	[this, &available_composite_constituents, &composite_type_ids](
	opt::Function* /unused/, opt::BasicBlock* /unused/,
	opt::BasicBlock::iterator inst_it,
	const protobufs::InstructionDescriptor& instruction_descriptor)
	-> void {
	// Randomly decide whether to try inserting a composite construction
	// here.
	if (!GetFuzzerContext()->ChoosePercentage(
	GetFuzzerContext()->GetChanceOfConstructingComposite())) {
	return;
	}

	// Check whether it is legitimate to insert a composite construction
	// before the instruction.
	if (!fuzzerutil::CanInsertOpcodeBeforeInstruction(
	spv::Op::OpCompositeConstruct, inst_it)) {
	return;
	}

	// For each instruction that is available at this program point (i.e. an
	// instruction that is global or whose definition strictly dominates the
	// program point) and suitable for making a synonym of, associate it
	// with the id of its result type.
	TypeIdToInstructions type_id_to_available_instructions;
	auto available_instructions =
	available_composite_constituents.GetAvailableBeforeInstruction(
	&*inst_it);
	for (uint32_t available_instruction_index = 0;
	available_instruction_index < available_instructions.size();
	available_instruction_index++) {
	opt::Instruction* inst =
	available_instructions[available_instruction_index];
	type_id_to_available_instructions[inst->type_id()].push_back(
	inst->result_id());
	}

	// At this point, \|composite_type_ids\| captures all the composite types
	// we could try to create, while \|type_id_to_available_instructions\|
	// captures all the available result ids we might use, organized by
	// type.

	// Now we choose a composite type to construct, building it from
	// available constituent components and using zero constants if suitable
	// components are not available.

	std::vector<uint32_t> constructor_arguments;
	uint32_t chosen_composite_type =
	composite_type_ids[GetFuzzerContext()->RandomIndex(
	composite_type_ids)];

	// Construct a composite of this type, using an appropriate helper
	// method depending on the kind of composite type.
	auto composite_type_inst =
	GetIRContext()->get_def_use_mgr()->GetDef(chosen_composite_type);
	switch (composite_type_inst->opcode()) {
	case spv::Op::OpTypeArray:
	constructor_arguments = FindComponentsToConstructArray(
	*composite_type_inst, type_id_to_available_instructions);
	break;
	case spv::Op::OpTypeMatrix:
	constructor_arguments = FindComponentsToConstructMatrix(
	*composite_type_inst, type_id_to_available_instructions);
	break;
	case spv::Op::OpTypeStruct:
	constructor_arguments = FindComponentsToConstructStruct(
	*composite_type_inst, type_id_to_available_instructions);
	break;
	case spv::Op::OpTypeVector:
	constructor_arguments = FindComponentsToConstructVector(
	*composite_type_inst, type_id_to_available_instructions);
	break;
	default:
	assert(false &&
	"The space of possible composite types should be covered "
	"by the above cases.");
	break;
	}
	assert(!constructor_arguments.empty());

	// Make and apply a transformation.
	ApplyTransformation(TransformationCompositeConstruct(
	chosen_composite_type, constructor_arguments,
	instruction_descriptor, GetFuzzerContext()->GetFreshId()));
	});
	}

	std::vector<uint32_t>
	FuzzerPassConstructComposites::FindComponentsToConstructArray(
	const opt::Instruction& array_type_instruction,
	const TypeIdToInstructions& type_id_to_available_instructions) {
	assert(array_type_instruction.opcode() == spv::Op::OpTypeArray &&
	"Precondition: instruction must be an array type.");

	// Get the element type for the array.
	auto element_type_id = array_type_instruction.GetSingleWordInOperand(0);

	// Get all instructions at our disposal that compute something of this element
	// type.
	auto available_instructions =
	type_id_to_available_instructions.find(element_type_id);

	uint32_t array_length =
	GetIRContext()
	->get_def_use_mgr()
	->GetDef(array_type_instruction.GetSingleWordInOperand(1))
	->GetSingleWordInOperand(0);

	std::vector<uint32_t> result;
	for (uint32_t index = 0; index < array_length; index++) {
	if (available_instructions == type_id_to_available_instructions.cend()) {
	// No suitable instructions are available, so use a zero constant
	result.push_back(FindOrCreateZeroConstant(element_type_id, true));
	} else {
	result.push_back(
	available_instructions->second[GetFuzzerContext()->RandomIndex(
	available_instructions->second)]);
	}
	}
	return result;
	}

	std::vector<uint32_t>
	FuzzerPassConstructComposites::FindComponentsToConstructMatrix(
	const opt::Instruction& matrix_type_instruction,
	const TypeIdToInstructions& type_id_to_available_instructions) {
	assert(matrix_type_instruction.opcode() == spv::Op::OpTypeMatrix &&
	"Precondition: instruction must be a matrix type.");

	// Get the element type for the matrix.
	auto element_type_id = matrix_type_instruction.GetSingleWordInOperand(0);

	// Get all instructions at our disposal that compute something of this element
	// type.
	auto available_instructions =
	type_id_to_available_instructions.find(element_type_id);

	std::vector<uint32_t> result;
	for (uint32_t index = 0;
	index < matrix_type_instruction.GetSingleWordInOperand(1); index++) {
	if (available_instructions == type_id_to_available_instructions.cend()) {
	// No suitable components are available, so use a zero constant.
	result.push_back(FindOrCreateZeroConstant(element_type_id, true));
	} else {
	result.push_back(
	available_instructions->second[GetFuzzerContext()->RandomIndex(
	available_instructions->second)]);
	}
	}
	return result;
	}

	std::vector<uint32_t>
	FuzzerPassConstructComposites::FindComponentsToConstructStruct(
	const opt::Instruction& struct_type_instruction,
	const TypeIdToInstructions& type_id_to_available_instructions) {
	assert(struct_type_instruction.opcode() == spv::Op::OpTypeStruct &&
	"Precondition: instruction must be a struct type.");
	std::vector<uint32_t> result;
	// Consider the type of each field of the struct.
	for (uint32_t in_operand_index = 0;
	in_operand_index < struct_type_instruction.NumInOperands();
	in_operand_index++) {
	auto element_type_id =
	struct_type_instruction.GetSingleWordInOperand(in_operand_index);
	// Find the instructions at our disposal that compute something of the field
	// type.
	auto available_instructions =
	type_id_to_available_instructions.find(element_type_id);
	if (available_instructions == type_id_to_available_instructions.cend()) {
	// No suitable component is available for this element type, so use a zero
	// constant.
	result.push_back(FindOrCreateZeroConstant(element_type_id, true));
	} else {
	result.push_back(
	available_instructions->second[GetFuzzerContext()->RandomIndex(
	available_instructions->second)]);
	}
	}
	return result;
	}

	std::vector<uint32_t>
	FuzzerPassConstructComposites::FindComponentsToConstructVector(
	const opt::Instruction& vector_type_instruction,
	const TypeIdToInstructions& type_id_to_available_instructions) {
	assert(vector_type_instruction.opcode() == spv::Op::OpTypeVector &&
	"Precondition: instruction must be a vector type.");

	// Get details of the type underlying the vector, and the width of the vector,
	// for convenience.
	auto element_type_id = vector_type_instruction.GetSingleWordInOperand(0);
	auto element_type = GetIRContext()->get_type_mgr()->GetType(element_type_id);
	auto element_count = vector_type_instruction.GetSingleWordInOperand(1);

	// Collect a mapping, from type id to width, for scalar/vector types that are
	// smaller in width than \|vector_type\|, but that have the same underlying
	// type. For example, if \|vector_type\| is vec4, the mapping will be:
	// { float -> 1, vec2 -> 2, vec3 -> 3 }
	// The mapping will have missing entries if some of these types do not exist.

	std::map<uint32_t, uint32_t> smaller_vector_type_id_to_width;
	// Add the underlying type. This id must exist, in order for \|vector_type\| to
	// exist.
	smaller_vector_type_id_to_width[element_type_id] = 1;

	// Now add every vector type with width at least 2, and less than the width of
	// \|vector_type\|.
	for (uint32_t width = 2; width < element_count; width++) {
	opt::analysis::Vector smaller_vector_type(element_type, width);
	auto smaller_vector_type_id =
	GetIRContext()->get_type_mgr()->GetId(&smaller_vector_type);
	// We might find that there is no declared type of this smaller width.
	// For example, a module can declare vec4 without having declared vec2 or
	// vec3.
	if (smaller_vector_type_id) {
	smaller_vector_type_id_to_width[smaller_vector_type_id] = width;
	}
	}

	// Now we know the types that are available to us, we set about populating a
	// vector of the right length. We do this by deciding, with no order in mind,
	// which instructions we will use to populate the vector, and subsequently
	// randomly choosing an order. This is to avoid biasing construction of
	// vectors with smaller vectors to the left and scalars to the right. That is
	// a concern because, e.g. in the case of populating a vec4, if we populate
	// the constructor instructions left-to-right, we can always choose a vec3 to
	// construct the first three elements, but can only choose a vec3 to construct
	// the last three elements if we chose a float to construct the first element
	// (otherwise there will not be space left for a vec3).

	uint32_t vector_slots_used = 0;

	// The instructions result ids we will use to construct the vector, in no
	// particular order at this stage.
	std::vector<uint32_t> result;

	while (vector_slots_used < element_count) {
	std::vector<uint32_t> instructions_to_choose_from;
	for (auto& entry : smaller_vector_type_id_to_width) {
	if (entry.second >
	std::min(element_count - 1, element_count - vector_slots_used)) {
	continue;
	}
	auto available_instructions =
	type_id_to_available_instructions.find(entry.first);
	if (available_instructions == type_id_to_available_instructions.cend()) {
	continue;
	}
	instructions_to_choose_from.insert(instructions_to_choose_from.end(),
	available_instructions->second.begin(),
	available_instructions->second.end());
	}
	// If there are no instructions to choose from then use a zero constant,
	// otherwise select one of the instructions at random.
	uint32_t id_of_instruction_to_use =
	instructions_to_choose_from.empty()
	? FindOrCreateZeroConstant(element_type_id, true)
	: instructions_to_choose_from[GetFuzzerContext()->RandomIndex(
	instructions_to_choose_from)];
	opt::Instruction* instruction_to_use =
	GetIRContext()->get_def_use_mgr()->GetDef(id_of_instruction_to_use);
	result.push_back(instruction_to_use->result_id());
	auto chosen_type =
	GetIRContext()->get_type_mgr()->GetType(instruction_to_use->type_id());
	if (chosen_type->AsVector()) {
	assert(chosen_type->AsVector()->element_type() == element_type);
	assert(chosen_type->AsVector()->element_count() < element_count);
	assert(chosen_type->AsVector()->element_count() <=
	element_count - vector_slots_used);
	vector_slots_used += chosen_type->AsVector()->element_count();
	} else {
	assert(chosen_type == element_type);
	vector_slots_used += 1;
	}
	}
	assert(vector_slots_used == element_count);

	GetFuzzerContext()->Shuffle(&result);
	return result;
	}

	} // namespace fuzz
	} // namespace spvtools