mlir/lib/Support/StorageUniquer.cpp - llvm-project - Git at Google

 //===- StorageUniquer.cpp - Common Storage Class Uniquer ------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/Support/StorageUniquer.h"

 #include "mlir/Support/LLVM.h"
 #include "mlir/Support/ThreadLocalCache.h"
 #include "mlir/Support/TypeID.h"
 #include "llvm/Support/RWMutex.h"

 using namespace mlir;
 using namespace mlir::detail;

 namespace {
 /// This class represents a uniquer for storage instances of a specific type
 /// that has parametric storage. It contains all of the necessary data to unique
 /// storage instances in a thread safe way. This allows for the main uniquer to
 /// bucket each of the individual sub-types removing the need to lock the main
 /// uniquer itself.
 class ParametricStorageUniquer {
 public:
   using BaseStorage = StorageUniquer::BaseStorage;
   using StorageAllocator = StorageUniquer::StorageAllocator;

   /// A lookup key for derived instances of storage objects.
   struct LookupKey {
     /// The known hash value of the key.
     unsigned hashValue;

     /// An equality function for comparing with an existing storage instance.
     function_ref<bool(const BaseStorage *)> isEqual;
   };

 private:
   /// A utility wrapper object representing a hashed storage object. This class
   /// contains a storage object and an existing computed hash value.
   struct HashedStorage {
     HashedStorage(unsigned hashValue = 0, BaseStorage *storage = nullptr)
         : hashValue(hashValue), storage(storage) {}
     unsigned hashValue;
     BaseStorage *storage;
   };

   /// Storage info for derived TypeStorage objects.
   struct StorageKeyInfo {
     static inline HashedStorage getEmptyKey() {
       return HashedStorage(0, DenseMapInfo<BaseStorage *>::getEmptyKey());
     }
     static inline HashedStorage getTombstoneKey() {
       return HashedStorage(0, DenseMapInfo<BaseStorage *>::getTombstoneKey());
     }

     static inline unsigned getHashValue(const HashedStorage &key) {
       return key.hashValue;
     }
     static inline unsigned getHashValue(const LookupKey &key) {
       return key.hashValue;
     }

     static inline bool isEqual(const HashedStorage &lhs,
                                const HashedStorage &rhs) {
       return lhs.storage == rhs.storage;
     }
     static inline bool isEqual(const LookupKey &lhs, const HashedStorage &rhs) {
       if (isEqual(rhs, getEmptyKey()) || isEqual(rhs, getTombstoneKey()))
         return false;
       // Invoke the equality function on the lookup key.
       return lhs.isEqual(rhs.storage);
     }
   };
   using StorageTypeSet = DenseSet<HashedStorage, StorageKeyInfo>;

   /// This class represents a single shard of the uniquer. The uniquer uses a
   /// set of shards to allow for multiple threads to create instances with less
   /// lock contention.
   struct Shard {
     /// The set containing the allocated storage instances.
     StorageTypeSet instances;

     /// Allocator to use when constructing derived instances.
     StorageAllocator allocator;

 #if LLVM_ENABLE_THREADS != 0
     /// A mutex to keep uniquing thread-safe.
     llvm::sys::SmartRWMutex<true> mutex;
 #endif
   };

   /// Get or create an instance of a param derived type in an thread-unsafe
   /// fashion.
   BaseStorage *
   getOrCreateUnsafe(Shard &shard, LookupKey &key,
                     function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
     auto existing = shard.instances.insert_as({key.hashValue}, key);
     BaseStorage *&storage = existing.first->storage;
     if (existing.second)
       storage = ctorFn(shard.allocator);
     return storage;
   }

   /// Destroy all of the storage instances within the given shard.
   void destroyShardInstances(Shard &shard) {
     if (!destructorFn)
       return;
     for (HashedStorage &instance : shard.instances)
       destructorFn(instance.storage);
   }

 public:
 #if LLVM_ENABLE_THREADS != 0
   /// Initialize the storage uniquer with a given number of storage shards to
   /// use. The provided shard number is required to be a valid power of 2. The
   /// destructor function is used to destroy any allocated storage instances.
   ParametricStorageUniquer(function_ref<void(BaseStorage *)> destructorFn,
                            size_t numShards = 8)
       : shards(new std::atomic<Shard *>[numShards]), numShards(numShards),
         destructorFn(destructorFn) {
     assert(llvm::isPowerOf2_64(numShards) &&
            "the number of shards is required to be a power of 2");
     for (size_t i = 0; i < numShards; i++)
       shards[i].store(nullptr, std::memory_order_relaxed);
   }
   ~ParametricStorageUniquer() {
     // Free all of the allocated shards.
     for (size_t i = 0; i != numShards; ++i) {
       if (Shard *shard = shards[i].load()) {
         destroyShardInstances(*shard);
         delete shard;
       }
     }
   }
   /// Get or create an instance of a parametric type.
   BaseStorage *
   getOrCreate(bool threadingIsEnabled, unsigned hashValue,
               function_ref<bool(const BaseStorage *)> isEqual,
               function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
     Shard &shard = getShard(hashValue);
     ParametricStorageUniquer::LookupKey lookupKey{hashValue, isEqual};
     if (!threadingIsEnabled)
       return getOrCreateUnsafe(shard, lookupKey, ctorFn);

     // Check for a instance of this object in the local cache.
     auto localIt = localCache->insert_as({hashValue}, lookupKey);
     BaseStorage *&localInst = localIt.first->storage;
     if (localInst)
       return localInst;

     // Check for an existing instance in read-only mode.
     {
       llvm::sys::SmartScopedReader<true> typeLock(shard.mutex);
       auto it = shard.instances.find_as(lookupKey);
       if (it != shard.instances.end())
         return localInst = it->storage;
     }

     // Acquire a writer-lock so that we can safely create the new storage
     // instance.
     llvm::sys::SmartScopedWriter<true> typeLock(shard.mutex);
     return localInst = getOrCreateUnsafe(shard, lookupKey, ctorFn);
   }
   /// Run a mutation function on the provided storage object in a thread-safe
   /// way.
   LogicalResult
   mutate(bool threadingIsEnabled, BaseStorage *storage,
          function_ref<LogicalResult(StorageAllocator &)> mutationFn) {
     Shard &shard = getShardFor(storage);
     if (!threadingIsEnabled)
       return mutationFn(shard.allocator);

     llvm::sys::SmartScopedWriter<true> lock(shard.mutex);
     return mutationFn(shard.allocator);
   }

 private:
   /// Return the shard used for the given hash value.
   Shard &getShard(unsigned hashValue) {
     // Get a shard number from the provided hashvalue.
     unsigned shardNum = hashValue & (numShards - 1);

     // Try to acquire an already initialized shard.
     Shard *shard = shards[shardNum].load(std::memory_order_acquire);
     if (shard)
       return *shard;

     // Otherwise, try to allocate a new shard.
     Shard *newShard = new Shard();
     if (shards[shardNum].compare_exchange_strong(shard, newShard))
       return *newShard;

     // If one was allocated before we can initialize ours, delete ours.
     delete newShard;
     return *shard;
   }

   /// Return the shard that allocated the provided storage object.
   Shard &getShardFor(BaseStorage *storage) {
     for (size_t i = 0; i != numShards; ++i) {
       if (Shard *shard = shards[i].load(std::memory_order_acquire)) {
         llvm::sys::SmartScopedReader<true> lock(shard->mutex);
         if (shard->allocator.allocated(storage))
           return *shard;
       }
     }
     llvm_unreachable("expected storage object to have a valid shard");
   }

   /// A thread local cache for storage objects. This helps to reduce the lock
   /// contention when an object already existing in the cache.
   ThreadLocalCache<StorageTypeSet> localCache;

   /// A set of uniquer shards to allow for further bucketing accesses for
   /// instances of this storage type. Each shard is lazily initialized to reduce
   /// the overhead when only a small amount of shards are in use.
   std::unique_ptr<std::atomic<Shard *>[]> shards;

   /// The number of available shards.
   size_t numShards;

   /// Function to used to destruct any allocated storage instances.
   function_ref<void(BaseStorage *)> destructorFn;

 #else
   /// If multi-threading is disabled, ignore the shard parameter as we will
   /// always use one shard. The destructor function is used to destroy any
   /// allocated storage instances.
   ParametricStorageUniquer(function_ref<void(BaseStorage *)> destructorFn,
                            size_t numShards = 0)
       : destructorFn(destructorFn) {}
   ~ParametricStorageUniquer() { destroyShardInstances(shard); }

   /// Get or create an instance of a parametric type.
   BaseStorage *
   getOrCreate(bool threadingIsEnabled, unsigned hashValue,
               function_ref<bool(const BaseStorage *)> isEqual,
               function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
     ParametricStorageUniquer::LookupKey lookupKey{hashValue, isEqual};
     return getOrCreateUnsafe(shard, lookupKey, ctorFn);
   }
   /// Run a mutation function on the provided storage object in a thread-safe
   /// way.
   LogicalResult
   mutate(bool threadingIsEnabled, BaseStorage *storage,
          function_ref<LogicalResult(StorageAllocator &)> mutationFn) {
     return mutationFn(shard.allocator);
   }

 private:
   /// The main uniquer shard that is used for allocating storage instances.
   Shard shard;

   /// Function to used to destruct any allocated storage instances.
   function_ref<void(BaseStorage *)> destructorFn;
 #endif
 };
 } // end anonymous namespace

 namespace mlir {
 namespace detail {
 /// This is the implementation of the StorageUniquer class.
 struct StorageUniquerImpl {
   using BaseStorage = StorageUniquer::BaseStorage;
   using StorageAllocator = StorageUniquer::StorageAllocator;

   //===--------------------------------------------------------------------===//
   // Parametric Storage
   //===--------------------------------------------------------------------===//

   /// Check if an instance of a parametric storage class exists.
   bool hasParametricStorage(TypeID id) { return parametricUniquers.count(id); }

   /// Get or create an instance of a parametric type.
   BaseStorage *
   getOrCreate(TypeID id, unsigned hashValue,
               function_ref<bool(const BaseStorage *)> isEqual,
               function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
     assert(parametricUniquers.count(id) &&
            "creating unregistered storage instance");
     ParametricStorageUniquer &storageUniquer = *parametricUniquers[id];
     return storageUniquer.getOrCreate(threadingIsEnabled, hashValue, isEqual,
                                       ctorFn);
   }

   /// Run a mutation function on the provided storage object in a thread-safe
   /// way.
   LogicalResult
   mutate(TypeID id, BaseStorage *storage,
          function_ref<LogicalResult(StorageAllocator &)> mutationFn) {
     assert(parametricUniquers.count(id) &&
            "mutating unregistered storage instance");
     ParametricStorageUniquer &storageUniquer = *parametricUniquers[id];
     return storageUniquer.mutate(threadingIsEnabled, storage, mutationFn);
   }

   //===--------------------------------------------------------------------===//
   // Singleton Storage
   //===--------------------------------------------------------------------===//

   /// Get or create an instance of a singleton storage class.
   BaseStorage *getSingleton(TypeID id) {
     BaseStorage *singletonInstance = singletonInstances[id];
     assert(singletonInstance && "expected singleton instance to exist");
     return singletonInstance;
   }

   /// Check if an instance of a singleton storage class exists.
   bool hasSingleton(TypeID id) const { return singletonInstances.count(id); }

   //===--------------------------------------------------------------------===//
   // Instance Storage
   //===--------------------------------------------------------------------===//

   /// Map of type ids to the storage uniquer to use for registered objects.
   DenseMap<TypeID, std::unique_ptr<ParametricStorageUniquer>>
       parametricUniquers;

   /// Map of type ids to a singleton instance when the storage class is a
   /// singleton.
   DenseMap<TypeID, BaseStorage *> singletonInstances;

   /// Allocator used for uniquing singleton instances.
   StorageAllocator singletonAllocator;

   /// Flag specifying if multi-threading is enabled within the uniquer.
   bool threadingIsEnabled = true;
 };
 } // end namespace detail
 } // namespace mlir

 StorageUniquer::StorageUniquer() : impl(new StorageUniquerImpl()) {}
 StorageUniquer::~StorageUniquer() {}

 /// Set the flag specifying if multi-threading is disabled within the uniquer.
 void StorageUniquer::disableMultithreading(bool disable) {
   impl->threadingIsEnabled = !disable;
 }

 /// Implementation for getting/creating an instance of a derived type with
 /// parametric storage.
 auto StorageUniquer::getParametricStorageTypeImpl(
     TypeID id, unsigned hashValue,
     function_ref<bool(const BaseStorage *)> isEqual,
     function_ref<BaseStorage *(StorageAllocator &)> ctorFn) -> BaseStorage * {
   return impl->getOrCreate(id, hashValue, isEqual, ctorFn);
 }

 /// Implementation for registering an instance of a derived type with
 /// parametric storage.
 void StorageUniquer::registerParametricStorageTypeImpl(
     TypeID id, function_ref<void(BaseStorage *)> destructorFn) {
   impl->parametricUniquers.try_emplace(
       id, std::make_unique<ParametricStorageUniquer>(destructorFn));
 }

 /// Implementation for getting an instance of a derived type with default
 /// storage.
 auto StorageUniquer::getSingletonImpl(TypeID id) -> BaseStorage * {
   return impl->getSingleton(id);
 }

 /// Test is the storage singleton is initialized.
 bool StorageUniquer::isSingletonStorageInitialized(TypeID id) {
   return impl->hasSingleton(id);
 }

 /// Test is the parametric storage is initialized.
 bool StorageUniquer::isParametricStorageInitialized(TypeID id) {
   return impl->hasParametricStorage(id);
 }

 /// Implementation for registering an instance of a derived type with default
 /// storage.
 void StorageUniquer::registerSingletonImpl(
     TypeID id, function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
   assert(!impl->singletonInstances.count(id) &&
          "storage class already registered");
   impl->singletonInstances.try_emplace(id, ctorFn(impl->singletonAllocator));
 }

 /// Implementation for mutating an instance of a derived storage.
 LogicalResult StorageUniquer::mutateImpl(
     TypeID id, BaseStorage *storage,
     function_ref<LogicalResult(StorageAllocator &)> mutationFn) {
   return impl->mutate(id, storage, mutationFn);
 }
	//===- StorageUniquer.cpp - Common Storage Class Uniquer ------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/Support/StorageUniquer.h"

	#include "mlir/Support/LLVM.h"
	#include "mlir/Support/ThreadLocalCache.h"
	#include "mlir/Support/TypeID.h"
	#include "llvm/Support/RWMutex.h"

	using namespace mlir;
	using namespace mlir::detail;

	namespace {
	/// This class represents a uniquer for storage instances of a specific type
	/// that has parametric storage. It contains all of the necessary data to unique
	/// storage instances in a thread safe way. This allows for the main uniquer to
	/// bucket each of the individual sub-types removing the need to lock the main
	/// uniquer itself.
	class ParametricStorageUniquer {
	public:
	using BaseStorage = StorageUniquer::BaseStorage;
	using StorageAllocator = StorageUniquer::StorageAllocator;

	/// A lookup key for derived instances of storage objects.
	struct LookupKey {
	/// The known hash value of the key.
	unsigned hashValue;

	/// An equality function for comparing with an existing storage instance.
	function_ref<bool(const BaseStorage *)> isEqual;
	};

	private:
	/// A utility wrapper object representing a hashed storage object. This class
	/// contains a storage object and an existing computed hash value.
	struct HashedStorage {
	HashedStorage(unsigned hashValue = 0, BaseStorage *storage = nullptr)
	: hashValue(hashValue), storage(storage) {}
	unsigned hashValue;
	BaseStorage *storage;
	};

	/// Storage info for derived TypeStorage objects.
	struct StorageKeyInfo {
	static inline HashedStorage getEmptyKey() {
	return HashedStorage(0, DenseMapInfo<BaseStorage *>::getEmptyKey());
	}
	static inline HashedStorage getTombstoneKey() {
	return HashedStorage(0, DenseMapInfo<BaseStorage *>::getTombstoneKey());
	}

	static inline unsigned getHashValue(const HashedStorage &key) {
	return key.hashValue;
	}
	static inline unsigned getHashValue(const LookupKey &key) {
	return key.hashValue;
	}

	static inline bool isEqual(const HashedStorage &lhs,
	const HashedStorage &rhs) {
	return lhs.storage == rhs.storage;
	}
	static inline bool isEqual(const LookupKey &lhs, const HashedStorage &rhs) {
	if (isEqual(rhs, getEmptyKey()) \|\| isEqual(rhs, getTombstoneKey()))
	return false;
	// Invoke the equality function on the lookup key.
	return lhs.isEqual(rhs.storage);
	}
	};
	using StorageTypeSet = DenseSet<HashedStorage, StorageKeyInfo>;

	/// This class represents a single shard of the uniquer. The uniquer uses a
	/// set of shards to allow for multiple threads to create instances with less
	/// lock contention.
	struct Shard {
	/// The set containing the allocated storage instances.
	StorageTypeSet instances;

	/// Allocator to use when constructing derived instances.
	StorageAllocator allocator;

	#if LLVM_ENABLE_THREADS != 0
	/// A mutex to keep uniquing thread-safe.
	llvm::sys::SmartRWMutex<true> mutex;
	#endif
	};

	/// Get or create an instance of a param derived type in an thread-unsafe
	/// fashion.
	BaseStorage *
	getOrCreateUnsafe(Shard &shard, LookupKey &key,
	function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
	auto existing = shard.instances.insert_as({key.hashValue}, key);
	BaseStorage *&storage = existing.first->storage;
	if (existing.second)
	storage = ctorFn(shard.allocator);
	return storage;
	}

	/// Destroy all of the storage instances within the given shard.
	void destroyShardInstances(Shard &shard) {
	if (!destructorFn)
	return;
	for (HashedStorage &instance : shard.instances)
	destructorFn(instance.storage);
	}

	public:
	#if LLVM_ENABLE_THREADS != 0
	/// Initialize the storage uniquer with a given number of storage shards to
	/// use. The provided shard number is required to be a valid power of 2. The
	/// destructor function is used to destroy any allocated storage instances.
	ParametricStorageUniquer(function_ref<void(BaseStorage *)> destructorFn,
	size_t numShards = 8)
	: shards(new std::atomic<Shard *>[numShards]), numShards(numShards),
	destructorFn(destructorFn) {
	assert(llvm::isPowerOf2_64(numShards) &&
	"the number of shards is required to be a power of 2");
	for (size_t i = 0; i < numShards; i++)
	shards[i].store(nullptr, std::memory_order_relaxed);
	}
	~ParametricStorageUniquer() {
	// Free all of the allocated shards.
	for (size_t i = 0; i != numShards; ++i) {
	if (Shard *shard = shards[i].load()) {
	destroyShardInstances(*shard);
	delete shard;
	}
	}
	}
	/// Get or create an instance of a parametric type.
	BaseStorage *
	getOrCreate(bool threadingIsEnabled, unsigned hashValue,
	function_ref<bool(const BaseStorage *)> isEqual,
	function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
	Shard &shard = getShard(hashValue);
	ParametricStorageUniquer::LookupKey lookupKey{hashValue, isEqual};
	if (!threadingIsEnabled)
	return getOrCreateUnsafe(shard, lookupKey, ctorFn);

	// Check for a instance of this object in the local cache.
	auto localIt = localCache->insert_as({hashValue}, lookupKey);
	BaseStorage *&localInst = localIt.first->storage;
	if (localInst)
	return localInst;

	// Check for an existing instance in read-only mode.
	{
	llvm::sys::SmartScopedReader<true> typeLock(shard.mutex);
	auto it = shard.instances.find_as(lookupKey);
	if (it != shard.instances.end())
	return localInst = it->storage;
	}

	// Acquire a writer-lock so that we can safely create the new storage
	// instance.
	llvm::sys::SmartScopedWriter<true> typeLock(shard.mutex);
	return localInst = getOrCreateUnsafe(shard, lookupKey, ctorFn);
	}
	/// Run a mutation function on the provided storage object in a thread-safe
	/// way.
	LogicalResult
	mutate(bool threadingIsEnabled, BaseStorage *storage,
	function_ref<LogicalResult(StorageAllocator &)> mutationFn) {
	Shard &shard = getShardFor(storage);
	if (!threadingIsEnabled)
	return mutationFn(shard.allocator);

	llvm::sys::SmartScopedWriter<true> lock(shard.mutex);
	return mutationFn(shard.allocator);
	}

	private:
	/// Return the shard used for the given hash value.
	Shard &getShard(unsigned hashValue) {
	// Get a shard number from the provided hashvalue.
	unsigned shardNum = hashValue & (numShards - 1);

	// Try to acquire an already initialized shard.
	Shard *shard = shards[shardNum].load(std::memory_order_acquire);
	if (shard)
	return *shard;

	// Otherwise, try to allocate a new shard.
	Shard *newShard = new Shard();
	if (shards[shardNum].compare_exchange_strong(shard, newShard))
	return *newShard;

	// If one was allocated before we can initialize ours, delete ours.
	delete newShard;
	return *shard;
	}

	/// Return the shard that allocated the provided storage object.
	Shard &getShardFor(BaseStorage *storage) {
	for (size_t i = 0; i != numShards; ++i) {
	if (Shard *shard = shards[i].load(std::memory_order_acquire)) {
	llvm::sys::SmartScopedReader<true> lock(shard->mutex);
	if (shard->allocator.allocated(storage))
	return *shard;
	}
	}
	llvm_unreachable("expected storage object to have a valid shard");
	}

	/// A thread local cache for storage objects. This helps to reduce the lock
	/// contention when an object already existing in the cache.
	ThreadLocalCache<StorageTypeSet> localCache;

	/// A set of uniquer shards to allow for further bucketing accesses for
	/// instances of this storage type. Each shard is lazily initialized to reduce
	/// the overhead when only a small amount of shards are in use.
	std::unique_ptr<std::atomic<Shard *>[]> shards;

	/// The number of available shards.
	size_t numShards;

	/// Function to used to destruct any allocated storage instances.
	function_ref<void(BaseStorage *)> destructorFn;

	#else
	/// If multi-threading is disabled, ignore the shard parameter as we will
	/// always use one shard. The destructor function is used to destroy any
	/// allocated storage instances.
	ParametricStorageUniquer(function_ref<void(BaseStorage *)> destructorFn,
	size_t numShards = 0)
	: destructorFn(destructorFn) {}
	~ParametricStorageUniquer() { destroyShardInstances(shard); }

	/// Get or create an instance of a parametric type.
	BaseStorage *
	getOrCreate(bool threadingIsEnabled, unsigned hashValue,
	function_ref<bool(const BaseStorage *)> isEqual,
	function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
	ParametricStorageUniquer::LookupKey lookupKey{hashValue, isEqual};
	return getOrCreateUnsafe(shard, lookupKey, ctorFn);
	}
	/// Run a mutation function on the provided storage object in a thread-safe
	/// way.
	LogicalResult
	mutate(bool threadingIsEnabled, BaseStorage *storage,
	function_ref<LogicalResult(StorageAllocator &)> mutationFn) {
	return mutationFn(shard.allocator);
	}

	private:
	/// The main uniquer shard that is used for allocating storage instances.
	Shard shard;

	/// Function to used to destruct any allocated storage instances.
	function_ref<void(BaseStorage *)> destructorFn;
	#endif
	};
	} // end anonymous namespace

	namespace mlir {
	namespace detail {
	/// This is the implementation of the StorageUniquer class.
	struct StorageUniquerImpl {
	using BaseStorage = StorageUniquer::BaseStorage;
	using StorageAllocator = StorageUniquer::StorageAllocator;

	//===--------------------------------------------------------------------===//
	// Parametric Storage
	//===--------------------------------------------------------------------===//

	/// Check if an instance of a parametric storage class exists.
	bool hasParametricStorage(TypeID id) { return parametricUniquers.count(id); }

	/// Get or create an instance of a parametric type.
	BaseStorage *
	getOrCreate(TypeID id, unsigned hashValue,
	function_ref<bool(const BaseStorage *)> isEqual,
	function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
	assert(parametricUniquers.count(id) &&
	"creating unregistered storage instance");
	ParametricStorageUniquer &storageUniquer = *parametricUniquers[id];
	return storageUniquer.getOrCreate(threadingIsEnabled, hashValue, isEqual,
	ctorFn);
	}

	/// Run a mutation function on the provided storage object in a thread-safe
	/// way.
	LogicalResult
	mutate(TypeID id, BaseStorage *storage,
	function_ref<LogicalResult(StorageAllocator &)> mutationFn) {
	assert(parametricUniquers.count(id) &&
	"mutating unregistered storage instance");
	ParametricStorageUniquer &storageUniquer = *parametricUniquers[id];
	return storageUniquer.mutate(threadingIsEnabled, storage, mutationFn);
	}

	//===--------------------------------------------------------------------===//
	// Singleton Storage
	//===--------------------------------------------------------------------===//

	/// Get or create an instance of a singleton storage class.
	BaseStorage *getSingleton(TypeID id) {
	BaseStorage *singletonInstance = singletonInstances[id];
	assert(singletonInstance && "expected singleton instance to exist");
	return singletonInstance;
	}

	/// Check if an instance of a singleton storage class exists.
	bool hasSingleton(TypeID id) const { return singletonInstances.count(id); }

	//===--------------------------------------------------------------------===//
	// Instance Storage
	//===--------------------------------------------------------------------===//

	/// Map of type ids to the storage uniquer to use for registered objects.
	DenseMap<TypeID, std::unique_ptr<ParametricStorageUniquer>>
	parametricUniquers;

	/// Map of type ids to a singleton instance when the storage class is a
	/// singleton.
	DenseMap<TypeID, BaseStorage *> singletonInstances;

	/// Allocator used for uniquing singleton instances.
	StorageAllocator singletonAllocator;

	/// Flag specifying if multi-threading is enabled within the uniquer.
	bool threadingIsEnabled = true;
	};
	} // end namespace detail
	} // namespace mlir

	StorageUniquer::StorageUniquer() : impl(new StorageUniquerImpl()) {}
	StorageUniquer::~StorageUniquer() {}

	/// Set the flag specifying if multi-threading is disabled within the uniquer.
	void StorageUniquer::disableMultithreading(bool disable) {
	impl->threadingIsEnabled = !disable;
	}

	/// Implementation for getting/creating an instance of a derived type with
	/// parametric storage.
	auto StorageUniquer::getParametricStorageTypeImpl(
	TypeID id, unsigned hashValue,
	function_ref<bool(const BaseStorage *)> isEqual,
	function_ref<BaseStorage (StorageAllocator &)> ctorFn) -> BaseStorage {
	return impl->getOrCreate(id, hashValue, isEqual, ctorFn);
	}

	/// Implementation for registering an instance of a derived type with
	/// parametric storage.
	void StorageUniquer::registerParametricStorageTypeImpl(
	TypeID id, function_ref<void(BaseStorage *)> destructorFn) {
	impl->parametricUniquers.try_emplace(
	id, std::make_unique<ParametricStorageUniquer>(destructorFn));
	}

	/// Implementation for getting an instance of a derived type with default
	/// storage.
	auto StorageUniquer::getSingletonImpl(TypeID id) -> BaseStorage * {
	return impl->getSingleton(id);
	}

	/// Test is the storage singleton is initialized.
	bool StorageUniquer::isSingletonStorageInitialized(TypeID id) {
	return impl->hasSingleton(id);
	}

	/// Test is the parametric storage is initialized.
	bool StorageUniquer::isParametricStorageInitialized(TypeID id) {
	return impl->hasParametricStorage(id);
	}

	/// Implementation for registering an instance of a derived type with default
	/// storage.
	void StorageUniquer::registerSingletonImpl(
	TypeID id, function_ref<BaseStorage *(StorageAllocator &)> ctorFn) {
	assert(!impl->singletonInstances.count(id) &&
	"storage class already registered");
	impl->singletonInstances.try_emplace(id, ctorFn(impl->singletonAllocator));
	}

	/// Implementation for mutating an instance of a derived storage.
	LogicalResult StorageUniquer::mutateImpl(
	TypeID id, BaseStorage *storage,
	function_ref<LogicalResult(StorageAllocator &)> mutationFn) {
	return impl->mutate(id, storage, mutationFn);
	}