SPIRV-Tools/source/opt/constants.h
Jaebaek Seo 6a3eb679bd
Preserve debug info in scalar replacement pass (#3461)
1. Set the debug scope and line information for the new replacement
   instructions.
2. Replace DebugDeclare and DebugValue if their OpVariable or value
   operands are replaced by scalars. It uses 'Indexes' operand of
   DebugValue. For example,

   struct S { int a; int b;}
   S foo; // before scalar replacement

   int foo_a; // after scalar replacement
   int foo_b;

   DebugDeclare %dbg_foo %foo %null_expr // before

   DebugValue %dbg_foo %foo_a %Deref_expr 0 // after
   DebugValue %dbg_foo %foo_b %Deref_expr 1 // means Value(foo.members[1]) == Deref(%foo_b)
2020-07-27 13:02:25 -04:00

707 lines
27 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_CONSTANTS_H_
#define SOURCE_OPT_CONSTANTS_H_
#include <cinttypes>
#include <map>
#include <memory>
#include <unordered_map>
#include <unordered_set>
#include <utility>
#include <vector>
#include "source/opt/module.h"
#include "source/opt/type_manager.h"
#include "source/opt/types.h"
#include "source/util/hex_float.h"
#include "source/util/make_unique.h"
namespace spvtools {
namespace opt {
class IRContext;
namespace analysis {
// Class hierarchy to represent the normal constants defined through
// OpConstantTrue, OpConstantFalse, OpConstant, OpConstantNull and
// OpConstantComposite instructions.
// TODO(qining): Add class for constants defined with OpConstantSampler.
class Constant;
class ScalarConstant;
class IntConstant;
class FloatConstant;
class BoolConstant;
class CompositeConstant;
class StructConstant;
class VectorConstant;
class MatrixConstant;
class ArrayConstant;
class NullConstant;
class ConstantManager;
// Abstract class for a SPIR-V constant. It has a bunch of As<subclass> methods,
// which is used as a way to probe the actual <subclass>
class Constant {
public:
Constant() = delete;
virtual ~Constant() {}
// Make a deep copy of this constant.
virtual std::unique_ptr<Constant> Copy() const = 0;
// reflections
virtual ScalarConstant* AsScalarConstant() { return nullptr; }
virtual IntConstant* AsIntConstant() { return nullptr; }
virtual FloatConstant* AsFloatConstant() { return nullptr; }
virtual BoolConstant* AsBoolConstant() { return nullptr; }
virtual CompositeConstant* AsCompositeConstant() { return nullptr; }
virtual StructConstant* AsStructConstant() { return nullptr; }
virtual VectorConstant* AsVectorConstant() { return nullptr; }
virtual MatrixConstant* AsMatrixConstant() { return nullptr; }
virtual ArrayConstant* AsArrayConstant() { return nullptr; }
virtual NullConstant* AsNullConstant() { return nullptr; }
virtual const ScalarConstant* AsScalarConstant() const { return nullptr; }
virtual const IntConstant* AsIntConstant() const { return nullptr; }
virtual const FloatConstant* AsFloatConstant() const { return nullptr; }
virtual const BoolConstant* AsBoolConstant() const { return nullptr; }
virtual const CompositeConstant* AsCompositeConstant() const {
return nullptr;
}
virtual const StructConstant* AsStructConstant() const { return nullptr; }
virtual const VectorConstant* AsVectorConstant() const { return nullptr; }
virtual const MatrixConstant* AsMatrixConstant() const { return nullptr; }
virtual const ArrayConstant* AsArrayConstant() const { return nullptr; }
virtual const NullConstant* AsNullConstant() const { return nullptr; }
// Returns the float representation of the constant. Must be a 32 bit
// Float type.
float GetFloat() const;
// Returns the double representation of the constant. Must be a 64 bit
// Float type.
double GetDouble() const;
// Returns the double representation of the constant. Must be a 32-bit or
// 64-bit Float type.
double GetValueAsDouble() const;
// Returns uint32_t representation of the constant. Must be a 32 bit
// Integer type.
uint32_t GetU32() const;
// Returns uint64_t representation of the constant. Must be a 64 bit
// Integer type.
uint64_t GetU64() const;
// Returns int32_t representation of the constant. Must be a 32 bit
// Integer type.
int32_t GetS32() const;
// Returns int64_t representation of the constant. Must be a 64 bit
// Integer type.
int64_t GetS64() const;
// Returns the zero-extended representation of an integer constant. Must
// be an integral constant of at most 64 bits.
uint64_t GetZeroExtendedValue() const;
// Returns the sign-extended representation of an integer constant. Must
// be an integral constant of at most 64 bits.
int64_t GetSignExtendedValue() const;
// Returns true if the constant is a zero or a composite containing 0s.
virtual bool IsZero() const { return false; }
const Type* type() const { return type_; }
// Returns an std::vector containing the elements of |constant|. The type of
// |constant| must be |Vector|.
std::vector<const Constant*> GetVectorComponents(
ConstantManager* const_mgr) const;
protected:
Constant(const Type* ty) : type_(ty) {}
// The type of this constant.
const Type* type_;
};
// Abstract class for scalar type constants.
class ScalarConstant : public Constant {
public:
ScalarConstant() = delete;
ScalarConstant* AsScalarConstant() override { return this; }
const ScalarConstant* AsScalarConstant() const override { return this; }
// Returns a const reference of the value of this constant in 32-bit words.
virtual const std::vector<uint32_t>& words() const { return words_; }
// Returns true if the value is zero.
bool IsZero() const override {
bool is_zero = true;
for (uint32_t v : words()) {
if (v != 0) {
is_zero = false;
break;
}
}
return is_zero;
}
protected:
ScalarConstant(const Type* ty, const std::vector<uint32_t>& w)
: Constant(ty), words_(w) {}
ScalarConstant(const Type* ty, std::vector<uint32_t>&& w)
: Constant(ty), words_(std::move(w)) {}
std::vector<uint32_t> words_;
};
// Integer type constant.
class IntConstant : public ScalarConstant {
public:
IntConstant(const Integer* ty, const std::vector<uint32_t>& w)
: ScalarConstant(ty, w) {}
IntConstant(const Integer* ty, std::vector<uint32_t>&& w)
: ScalarConstant(ty, std::move(w)) {}
IntConstant* AsIntConstant() override { return this; }
const IntConstant* AsIntConstant() const override { return this; }
int32_t GetS32BitValue() const {
// Relies on signed values smaller than 32-bit being sign extended. See
// section 2.2.1 of the SPIR-V spec.
assert(words().size() == 1);
return words()[0];
}
uint32_t GetU32BitValue() const {
// Relies on unsigned values smaller than 32-bit being zero extended. See
// section 2.2.1 of the SPIR-V spec.
assert(words().size() == 1);
return words()[0];
}
int64_t GetS64BitValue() const {
// Relies on unsigned values smaller than 64-bit being sign extended. See
// section 2.2.1 of the SPIR-V spec.
assert(words().size() == 2);
return static_cast<uint64_t>(words()[1]) << 32 |
static_cast<uint64_t>(words()[0]);
}
uint64_t GetU64BitValue() const {
// Relies on unsigned values smaller than 64-bit being zero extended. See
// section 2.2.1 of the SPIR-V spec.
assert(words().size() == 2);
return static_cast<uint64_t>(words()[1]) << 32 |
static_cast<uint64_t>(words()[0]);
}
// Make a copy of this IntConstant instance.
std::unique_ptr<IntConstant> CopyIntConstant() const {
return MakeUnique<IntConstant>(type_->AsInteger(), words_);
}
std::unique_ptr<Constant> Copy() const override {
return std::unique_ptr<Constant>(CopyIntConstant().release());
}
};
// Float type constant.
class FloatConstant : public ScalarConstant {
public:
FloatConstant(const Float* ty, const std::vector<uint32_t>& w)
: ScalarConstant(ty, w) {}
FloatConstant(const Float* ty, std::vector<uint32_t>&& w)
: ScalarConstant(ty, std::move(w)) {}
FloatConstant* AsFloatConstant() override { return this; }
const FloatConstant* AsFloatConstant() const override { return this; }
// Make a copy of this FloatConstant instance.
std::unique_ptr<FloatConstant> CopyFloatConstant() const {
return MakeUnique<FloatConstant>(type_->AsFloat(), words_);
}
std::unique_ptr<Constant> Copy() const override {
return std::unique_ptr<Constant>(CopyFloatConstant().release());
}
// Returns the float value of |this|. The type of |this| must be |Float| with
// width of 32.
float GetFloatValue() const {
assert(type()->AsFloat()->width() == 32 &&
"Not a 32-bit floating point value.");
utils::FloatProxy<float> a(words()[0]);
return a.getAsFloat();
}
// Returns the double value of |this|. The type of |this| must be |Float|
// with width of 64.
double GetDoubleValue() const {
assert(type()->AsFloat()->width() == 64 &&
"Not a 32-bit floating point value.");
uint64_t combined_words = words()[1];
combined_words = combined_words << 32;
combined_words |= words()[0];
utils::FloatProxy<double> a(combined_words);
return a.getAsFloat();
}
};
// Bool type constant.
class BoolConstant : public ScalarConstant {
public:
BoolConstant(const Bool* ty, bool v)
: ScalarConstant(ty, {static_cast<uint32_t>(v)}), value_(v) {}
BoolConstant* AsBoolConstant() override { return this; }
const BoolConstant* AsBoolConstant() const override { return this; }
// Make a copy of this BoolConstant instance.
std::unique_ptr<BoolConstant> CopyBoolConstant() const {
return MakeUnique<BoolConstant>(type_->AsBool(), value_);
}
std::unique_ptr<Constant> Copy() const override {
return std::unique_ptr<Constant>(CopyBoolConstant().release());
}
bool value() const { return value_; }
private:
bool value_;
};
// Abstract class for composite constants.
class CompositeConstant : public Constant {
public:
CompositeConstant() = delete;
CompositeConstant* AsCompositeConstant() override { return this; }
const CompositeConstant* AsCompositeConstant() const override { return this; }
// Returns a const reference of the components held in this composite
// constant.
virtual const std::vector<const Constant*>& GetComponents() const {
return components_;
}
bool IsZero() const override {
for (const Constant* c : GetComponents()) {
if (!c->IsZero()) {
return false;
}
}
return true;
}
protected:
CompositeConstant(const Type* ty) : Constant(ty), components_() {}
CompositeConstant(const Type* ty,
const std::vector<const Constant*>& components)
: Constant(ty), components_(components) {}
CompositeConstant(const Type* ty, std::vector<const Constant*>&& components)
: Constant(ty), components_(std::move(components)) {}
std::vector<const Constant*> components_;
};
// Struct type constant.
class StructConstant : public CompositeConstant {
public:
StructConstant(const Struct* ty) : CompositeConstant(ty) {}
StructConstant(const Struct* ty,
const std::vector<const Constant*>& components)
: CompositeConstant(ty, components) {}
StructConstant(const Struct* ty, std::vector<const Constant*>&& components)
: CompositeConstant(ty, std::move(components)) {}
StructConstant* AsStructConstant() override { return this; }
const StructConstant* AsStructConstant() const override { return this; }
// Make a copy of this StructConstant instance.
std::unique_ptr<StructConstant> CopyStructConstant() const {
return MakeUnique<StructConstant>(type_->AsStruct(), components_);
}
std::unique_ptr<Constant> Copy() const override {
return std::unique_ptr<Constant>(CopyStructConstant().release());
}
};
// Vector type constant.
class VectorConstant : public CompositeConstant {
public:
VectorConstant(const Vector* ty)
: CompositeConstant(ty), component_type_(ty->element_type()) {}
VectorConstant(const Vector* ty,
const std::vector<const Constant*>& components)
: CompositeConstant(ty, components),
component_type_(ty->element_type()) {}
VectorConstant(const Vector* ty, std::vector<const Constant*>&& components)
: CompositeConstant(ty, std::move(components)),
component_type_(ty->element_type()) {}
VectorConstant* AsVectorConstant() override { return this; }
const VectorConstant* AsVectorConstant() const override { return this; }
// Make a copy of this VectorConstant instance.
std::unique_ptr<VectorConstant> CopyVectorConstant() const {
auto another = MakeUnique<VectorConstant>(type_->AsVector());
another->components_.insert(another->components_.end(), components_.begin(),
components_.end());
return another;
}
std::unique_ptr<Constant> Copy() const override {
return std::unique_ptr<Constant>(CopyVectorConstant().release());
}
const Type* component_type() const { return component_type_; }
private:
const Type* component_type_;
};
// Matrix type constant.
class MatrixConstant : public CompositeConstant {
public:
MatrixConstant(const Matrix* ty)
: CompositeConstant(ty), component_type_(ty->element_type()) {}
MatrixConstant(const Matrix* ty,
const std::vector<const Constant*>& components)
: CompositeConstant(ty, components),
component_type_(ty->element_type()) {}
MatrixConstant(const Vector* ty, std::vector<const Constant*>&& components)
: CompositeConstant(ty, std::move(components)),
component_type_(ty->element_type()) {}
MatrixConstant* AsMatrixConstant() override { return this; }
const MatrixConstant* AsMatrixConstant() const override { return this; }
// Make a copy of this MatrixConstant instance.
std::unique_ptr<MatrixConstant> CopyMatrixConstant() const {
auto another = MakeUnique<MatrixConstant>(type_->AsMatrix());
another->components_.insert(another->components_.end(), components_.begin(),
components_.end());
return another;
}
std::unique_ptr<Constant> Copy() const override {
return std::unique_ptr<Constant>(CopyMatrixConstant().release());
}
const Type* component_type() { return component_type_; }
private:
const Type* component_type_;
};
// Array type constant.
class ArrayConstant : public CompositeConstant {
public:
ArrayConstant(const Array* ty) : CompositeConstant(ty) {}
ArrayConstant(const Array* ty, const std::vector<const Constant*>& components)
: CompositeConstant(ty, components) {}
ArrayConstant(const Array* ty, std::vector<const Constant*>&& components)
: CompositeConstant(ty, std::move(components)) {}
ArrayConstant* AsArrayConstant() override { return this; }
const ArrayConstant* AsArrayConstant() const override { return this; }
// Make a copy of this ArrayConstant instance.
std::unique_ptr<ArrayConstant> CopyArrayConstant() const {
return MakeUnique<ArrayConstant>(type_->AsArray(), components_);
}
std::unique_ptr<Constant> Copy() const override {
return std::unique_ptr<Constant>(CopyArrayConstant().release());
}
};
// Null type constant.
class NullConstant : public Constant {
public:
NullConstant(const Type* ty) : Constant(ty) {}
NullConstant* AsNullConstant() override { return this; }
const NullConstant* AsNullConstant() const override { return this; }
// Make a copy of this NullConstant instance.
std::unique_ptr<NullConstant> CopyNullConstant() const {
return MakeUnique<NullConstant>(type_);
}
std::unique_ptr<Constant> Copy() const override {
return std::unique_ptr<Constant>(CopyNullConstant().release());
}
bool IsZero() const override { return true; }
};
// Hash function for Constant instances. Use the structure of the constant as
// the key.
struct ConstantHash {
void add_pointer(std::u32string* h, const void* p) const {
uint64_t ptr_val = reinterpret_cast<uint64_t>(p);
h->push_back(static_cast<uint32_t>(ptr_val >> 32));
h->push_back(static_cast<uint32_t>(ptr_val));
}
size_t operator()(const Constant* const_val) const {
std::u32string h;
add_pointer(&h, const_val->type());
if (const auto scalar = const_val->AsScalarConstant()) {
for (const auto& w : scalar->words()) {
h.push_back(w);
}
} else if (const auto composite = const_val->AsCompositeConstant()) {
for (const auto& c : composite->GetComponents()) {
add_pointer(&h, c);
}
} else if (const_val->AsNullConstant()) {
h.push_back(0);
} else {
assert(
false &&
"Tried to compute the hash value of an invalid Constant instance.");
}
return std::hash<std::u32string>()(h);
}
};
// Equality comparison structure for two constants.
struct ConstantEqual {
bool operator()(const Constant* c1, const Constant* c2) const {
if (c1->type() != c2->type()) {
return false;
}
if (const auto& s1 = c1->AsScalarConstant()) {
const auto& s2 = c2->AsScalarConstant();
return s2 && s1->words() == s2->words();
} else if (const auto& composite1 = c1->AsCompositeConstant()) {
const auto& composite2 = c2->AsCompositeConstant();
return composite2 &&
composite1->GetComponents() == composite2->GetComponents();
} else if (c1->AsNullConstant()) {
return c2->AsNullConstant() != nullptr;
} else {
assert(false && "Tried to compare two invalid Constant instances.");
}
return false;
}
};
// This class represents a pool of constants.
class ConstantManager {
public:
ConstantManager(IRContext* ctx);
IRContext* context() const { return ctx_; }
// Gets or creates a unique Constant instance of type |type| and a vector of
// constant defining words |words|. If a Constant instance existed already in
// the constant pool, it returns a pointer to it. Otherwise, it creates one
// using CreateConstant. If a new Constant instance cannot be created, it
// returns nullptr.
const Constant* GetConstant(
const Type* type, const std::vector<uint32_t>& literal_words_or_ids);
template <class C>
const Constant* GetConstant(const Type* type, const C& literal_words_or_ids) {
return GetConstant(type, std::vector<uint32_t>(literal_words_or_ids.begin(),
literal_words_or_ids.end()));
}
// Gets or creates a Constant instance to hold the constant value of the given
// instruction. It returns a pointer to a Constant instance or nullptr if it
// could not create the constant.
const Constant* GetConstantFromInst(const Instruction* inst);
// Gets or creates a constant defining instruction for the given Constant |c|.
// If |c| had already been defined, it returns a pointer to the existing
// declaration. Otherwise, it calls BuildInstructionAndAddToModule. If the
// optional |pos| is given, it will insert any newly created instructions at
// the given instruction iterator position. Otherwise, it inserts the new
// instruction at the end of the current module's types section.
//
// |type_id| is an optional argument for disambiguating equivalent types. If
// |type_id| is specified, the contant returned will have that type id.
Instruction* GetDefiningInstruction(const Constant* c, uint32_t type_id = 0,
Module::inst_iterator* pos = nullptr);
// Creates a constant defining instruction for the given Constant instance
// and inserts the instruction at the position specified by the given
// instruction iterator. Returns a pointer to the created instruction if
// succeeded, otherwise returns a null pointer. The instruction iterator
// points to the same instruction before and after the insertion. This is the
// only method that actually manages id creation/assignment and instruction
// creation/insertion for a new Constant instance.
//
// |type_id| is an optional argument for disambiguating equivalent types. If
// |type_id| is specified, it is used as the type of the constant. Otherwise
// the type of the constant is derived by getting an id from the type manager
// for |c|.
Instruction* BuildInstructionAndAddToModule(const Constant* c,
Module::inst_iterator* pos,
uint32_t type_id = 0);
// A helper function to get the result type of the given instruction. Returns
// nullptr if the instruction does not have a type id (type id is 0).
Type* GetType(const Instruction* inst) const;
// A helper function to get the collected normal constant with the given id.
// Returns the pointer to the Constant instance in case it is found.
// Otherwise, it returns a null pointer.
const Constant* FindDeclaredConstant(uint32_t id) const {
auto iter = id_to_const_val_.find(id);
return (iter != id_to_const_val_.end()) ? iter->second : nullptr;
}
// A helper function to get the id of a collected constant with the pointer
// to the Constant instance. Returns 0 in case the constant is not found.
uint32_t FindDeclaredConstant(const Constant* c, uint32_t type_id) const;
// Returns the canonical constant that has the same structure and value as the
// given Constant |cst|. If none is found, it returns nullptr.
//
// TODO: Should be able to give a type id to disambiguate types with the same
// structure.
const Constant* FindConstant(const Constant* c) const {
auto it = const_pool_.find(c);
return (it != const_pool_.end()) ? *it : nullptr;
}
// Registers a new constant |cst| in the constant pool. If the constant
// existed already, it returns a pointer to the previously existing Constant
// in the pool. Otherwise, it returns |cst|.
const Constant* RegisterConstant(std::unique_ptr<Constant> cst) {
auto ret = const_pool_.insert(cst.get());
if (ret.second) {
owned_constants_.emplace_back(std::move(cst));
}
return *ret.first;
}
// A helper function to get a vector of Constant instances with the specified
// ids. If it can not find the Constant instance for any one of the ids,
// it returns an empty vector.
std::vector<const Constant*> GetConstantsFromIds(
const std::vector<uint32_t>& ids) const;
// Returns a vector of constants representing each in operand. If an operand
// is not constant its entry is nullptr.
std::vector<const Constant*> GetOperandConstants(
const Instruction* inst) const;
// Records a mapping between |inst| and the constant value generated by it.
// It returns true if a new Constant was successfully mapped, false if |inst|
// generates no constant values.
bool MapInst(Instruction* inst) {
if (auto cst = GetConstantFromInst(inst)) {
MapConstantToInst(cst, inst);
return true;
}
return false;
}
void RemoveId(uint32_t id) {
auto it = id_to_const_val_.find(id);
if (it != id_to_const_val_.end()) {
const_val_to_id_.erase(it->second);
id_to_const_val_.erase(it);
}
}
// Records a new mapping between |inst| and |const_value|. This updates the
// two mappings |id_to_const_val_| and |const_val_to_id_|.
void MapConstantToInst(const Constant* const_value, Instruction* inst) {
if (id_to_const_val_.insert({inst->result_id(), const_value}).second) {
const_val_to_id_.insert({const_value, inst->result_id()});
}
}
// Returns the id of a 32-bit floating point constant with value |val|.
uint32_t GetFloatConst(float val);
// Returns the id of a 32-bit signed integer constant with value |val|.
uint32_t GetSIntConst(int32_t val);
private:
// Creates a Constant instance with the given type and a vector of constant
// defining words. Returns a unique pointer to the created Constant instance
// if the Constant instance can be created successfully. To create scalar
// type constants, the vector should contain the constant value in 32 bit
// words and the given type must be of type Bool, Integer or Float. To create
// composite type constants, the vector should contain the component ids, and
// those component ids should have been recorded before as Normal Constants.
// And the given type must be of type Struct, Vector or Array. When creating
// VectorType Constant instance, the components must be scalars of the same
// type, either Bool, Integer or Float. If any of the rules above failed, the
// creation will fail and nullptr will be returned. If the vector is empty,
// a NullConstant instance will be created with the given type.
std::unique_ptr<Constant> CreateConstant(
const Type* type,
const std::vector<uint32_t>& literal_words_or_ids) const;
// Creates an instruction with the given result id to declare a constant
// represented by the given Constant instance. Returns an unique pointer to
// the created instruction if the instruction can be created successfully.
// Otherwise, returns a null pointer.
//
// |type_id| is an optional argument for disambiguating equivalent types. If
// |type_id| is specified, it is used as the type of the constant. Otherwise
// the type of the constant is derived by getting an id from the type manager
// for |c|.
std::unique_ptr<Instruction> CreateInstruction(uint32_t result_id,
const Constant* c,
uint32_t type_id = 0) const;
// Creates an OpConstantComposite instruction with the given result id and
// the CompositeConst instance which represents a composite constant. Returns
// an unique pointer to the created instruction if succeeded. Otherwise
// returns a null pointer.
//
// |type_id| is an optional argument for disambiguating equivalent types. If
// |type_id| is specified, it is used as the type of the constant. Otherwise
// the type of the constant is derived by getting an id from the type manager
// for |c|.
std::unique_ptr<Instruction> CreateCompositeInstruction(
uint32_t result_id, const CompositeConstant* cc,
uint32_t type_id = 0) const;
// IR context that owns this constant manager.
IRContext* ctx_;
// A mapping from the result ids of Normal Constants to their
// Constant instances. All Normal Constants in the module, either
// existing ones before optimization or the newly generated ones, should have
// their Constant instance stored and their result id registered in this map.
std::unordered_map<uint32_t, const Constant*> id_to_const_val_;
// A mapping from the Constant instance of Normal Constants to their
// result id in the module. This is a mirror map of |id_to_const_val_|. All
// Normal Constants that defining instructions in the module should have
// their Constant and their result id registered here.
std::multimap<const Constant*, uint32_t> const_val_to_id_;
// The constant pool. All created constants are registered here.
std::unordered_set<const Constant*, ConstantHash, ConstantEqual> const_pool_;
// The constant that are owned by the constant manager. Every constant in
// |const_pool_| should be in |owned_constants_| as well.
std::vector<std::unique_ptr<Constant>> owned_constants_;
};
} // namespace analysis
} // namespace opt
} // namespace spvtools
#endif // SOURCE_OPT_CONSTANTS_H_