mlir/include/mlir/Support/StorageUniquer.h - llvm-project - Git at Google

 //===- StorageUniquer.h - Common Storage Class Uniquer ----------*- C++ -*-===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 #ifndef MLIR_SUPPORT_STORAGEUNIQUER_H
 #define MLIR_SUPPORT_STORAGEUNIQUER_H

 #include "mlir/Support/LLVM.h"
 #include "mlir/Support/LogicalResult.h"
 #include "mlir/Support/TypeID.h"
 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/DenseSet.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/Support/Allocator.h"

 namespace mlir {
 namespace detail {
 struct StorageUniquerImpl;

 /// Trait to check if ImplTy provides a 'getKey' method with types 'Args'.
 template <typename ImplTy, typename... Args>
 using has_impltype_getkey_t = decltype(ImplTy::getKey(std::declval<Args>()...));

 /// Trait to check if ImplTy provides a 'hashKey' method for 'T'.
 template <typename ImplTy, typename T>
 using has_impltype_hash_t = decltype(ImplTy::hashKey(std::declval<T>()));
 } // namespace detail

 /// A utility class to get or create instances of "storage classes". These
 /// storage classes must derive from 'StorageUniquer::BaseStorage'.
 ///
 /// For non-parametric storage classes, i.e. singleton classes, nothing else is
 /// needed. Instances of these classes can be created by calling `get` without
 /// trailing arguments.
 ///
 /// Otherwise, the parametric storage classes may be created with `get`,
 /// and must respect the following:
 ///    - Define a type alias, KeyTy, to a type that uniquely identifies the
 ///      instance of the storage class.
 ///      * The key type must be constructible from the values passed into the
 ///        getComplex call.
 ///      * If the KeyTy does not have an llvm::DenseMapInfo specialization, the
 ///        storage class must define a hashing method:
 ///         'static unsigned hashKey(const KeyTy &)'
 ///
 ///    - Provide a method, 'bool operator==(const KeyTy &) const', to
 ///      compare the storage instance against an instance of the key type.
 ///
 ///    - Provide a static construction method:
 ///        'DerivedStorage *construct(StorageAllocator &, const KeyTy &key)'
 ///      that builds a unique instance of the derived storage. The arguments to
 ///      this function are an allocator to store any uniqued data and the key
 ///      type for this storage.
 ///
 ///    - Provide a cleanup method:
 ///        'void cleanup()'
 ///      that is called when erasing a storage instance. This should cleanup any
 ///      fields of the storage as necessary and not attempt to free the memory
 ///      of the storage itself.
 ///
 /// Storage classes may have an optional mutable component, which must not take
 /// part in the unique immutable key. In this case, storage classes may be
 /// mutated with `mutate` and must additionally respect the following:
 ///    - Provide a mutation method:
 ///        'LogicalResult mutate(StorageAllocator &, <...>)'
 ///      that is called when mutating a storage instance. The first argument is
 ///      an allocator to store any mutable data, and the remaining arguments are
 ///      forwarded from the call site. The storage can be mutated at any time
 ///      after creation. Care must be taken to avoid excessive mutation since
 ///      the allocated storage can keep containing previous states. The return
 ///      value of the function is used to indicate whether the mutation was
 ///      successful, e.g., to limit the number of mutations or enable deferred
 ///      one-time assignment of the mutable component.
 ///
 /// All storage classes must be registered with the uniquer via
 /// `registerStorageType` using an appropriate unique `TypeID` for the storage
 /// class.
 class StorageUniquer {
 public:
   /// This class acts as the base storage that all storage classes must derived
   /// from.
   class alignas(8) BaseStorage {
   protected:
     BaseStorage() = default;
   };

   /// This is a utility allocator used to allocate memory for instances of
   /// derived types.
   class StorageAllocator {
   public:
     /// Copy the specified array of elements into memory managed by our bump
     /// pointer allocator.  This assumes the elements are all PODs.
     template <typename T> ArrayRef<T> copyInto(ArrayRef<T> elements) {
       if (elements.empty())
         return llvm::None;
       auto result = allocator.Allocate<T>(elements.size());
       std::uninitialized_copy(elements.begin(), elements.end(), result);
       return ArrayRef<T>(result, elements.size());
     }

     /// Copy the provided string into memory managed by our bump pointer
     /// allocator.
     StringRef copyInto(StringRef str) {
       if (str.empty())
         return StringRef();

       char *result = allocator.Allocate<char>(str.size() + 1);
       std::uninitialized_copy(str.begin(), str.end(), result);
       result[str.size()] = 0;
       return StringRef(result, str.size());
     }

     /// Allocate an instance of the provided type.
     template <typename T> T *allocate() { return allocator.Allocate<T>(); }

     /// Allocate 'size' bytes of 'alignment' aligned memory.
     void *allocate(size_t size, size_t alignment) {
       return allocator.Allocate(size, alignment);
     }

     /// Returns true if this allocator allocated the provided object pointer.
     bool allocated(const void *ptr) {
       return allocator.identifyObject(ptr).hasValue();
     }

   private:
     /// The raw allocator for type storage objects.
     llvm::BumpPtrAllocator allocator;
   };

   StorageUniquer();
   ~StorageUniquer();

   /// Set the flag specifying if multi-threading is disabled within the uniquer.
   void disableMultithreading(bool disable = true);

   /// Register a new parametric storage class, this is necessary to create
   /// instances of this class type. `id` is the type identifier that will be
   /// used to identify this type when creating instances of it via 'get'.
   template <typename Storage> void registerParametricStorageType(TypeID id) {
     // If the storage is trivially destructible, we don't need a destructor
     // function.
     if (std::is_trivially_destructible<Storage>::value)
       return registerParametricStorageTypeImpl(id, nullptr);
     registerParametricStorageTypeImpl(id, [](BaseStorage *storage) {
       static_cast<Storage *>(storage)->~Storage();
     });
   }
   /// Utility override when the storage type represents the type id.
   template <typename Storage> void registerParametricStorageType() {
     registerParametricStorageType<Storage>(TypeID::get<Storage>());
   }
   /// Register a new singleton storage class, this is necessary to get the
   /// singletone instance. `id` is the type identifier that will be used to
   /// access the singleton instance via 'get'. An optional initialization
   /// function may also be provided to initialize the newly created storage
   /// instance, and used when the singleton instance is created.
   template <typename Storage>
   void registerSingletonStorageType(TypeID id,
                                     function_ref<void(Storage *)> initFn) {
     auto ctorFn = [&](StorageAllocator &allocator) {
       auto *storage = new (allocator.allocate<Storage>()) Storage();
       if (initFn)
         initFn(storage);
       return storage;
     };
     registerSingletonImpl(id, ctorFn);
   }
   template <typename Storage> void registerSingletonStorageType(TypeID id) {
     registerSingletonStorageType<Storage>(id, llvm::None);
   }
   /// Utility override when the storage type represents the type id.
   template <typename Storage>
   void registerSingletonStorageType(function_ref<void(Storage *)> initFn = {}) {
     registerSingletonStorageType<Storage>(TypeID::get<Storage>(), initFn);
   }

   /// Gets a uniqued instance of 'Storage'. 'id' is the type id used when
   /// registering the storage instance. 'initFn' is an optional parameter that
   /// can be used to initialize a newly inserted storage instance. This function
   /// is used for derived types that have complex storage or uniquing
   /// constraints.
   template <typename Storage, typename... Args>
   Storage *get(function_ref<void(Storage *)> initFn, TypeID id,
                Args &&...args) {
     // Construct a value of the derived key type.
     auto derivedKey = getKey<Storage>(std::forward<Args>(args)...);

     // Create a hash of the derived key.
     unsigned hashValue = getHash<Storage>(derivedKey);

     // Generate an equality function for the derived storage.
     auto isEqual = [&derivedKey](const BaseStorage *existing) {
       return static_cast<const Storage &>(*existing) == derivedKey;
     };

     // Generate a constructor function for the derived storage.
     auto ctorFn = [&](StorageAllocator &allocator) {
       auto *storage = Storage::construct(allocator, derivedKey);
       if (initFn)
         initFn(storage);
       return storage;
     };

     // Get an instance for the derived storage.
     return static_cast<Storage *>(
         getParametricStorageTypeImpl(id, hashValue, isEqual, ctorFn));
   }
   /// Utility override when the storage type represents the type id.
   template <typename Storage, typename... Args>
   Storage *get(function_ref<void(Storage *)> initFn, Args &&...args) {
     return get<Storage>(initFn, TypeID::get<Storage>(),
                         std::forward<Args>(args)...);
   }

   /// Gets a uniqued instance of 'Storage' which is a singleton storage type.
   /// 'id' is the type id used when registering the storage instance.
   template <typename Storage> Storage *get(TypeID id) {
     return static_cast<Storage *>(getSingletonImpl(id));
   }
   /// Utility override when the storage type represents the type id.
   template <typename Storage> Storage *get() {
     return get<Storage>(TypeID::get<Storage>());
   }

   /// Test if there is a singleton storage uniquer initialized for the provided
   /// TypeID. This is only useful for debugging/diagnostic purpose: the uniquer
   /// is initialized when a dialect is loaded.
   bool isSingletonStorageInitialized(TypeID id);

   /// Test if there is a parametric storage uniquer initialized for the provided
   /// TypeID. This is only useful for debugging/diagnostic purpose: the uniquer
   /// is initialized when a dialect is loaded.
   bool isParametricStorageInitialized(TypeID id);

   /// Changes the mutable component of 'storage' by forwarding the trailing
   /// arguments to the 'mutate' function of the derived class.
   template <typename Storage, typename... Args>
   LogicalResult mutate(TypeID id, Storage *storage, Args &&...args) {
     auto mutationFn = [&](StorageAllocator &allocator) -> LogicalResult {
       return static_cast<Storage &>(*storage).mutate(
           allocator, std::forward<Args>(args)...);
     };
     return mutateImpl(id, storage, mutationFn);
   }

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

   /// Implementation for registering an instance of a derived type with
   /// parametric storage. This method takes an optional destructor function that
   /// destructs storage instances when necessary.
   void registerParametricStorageTypeImpl(
       TypeID id, function_ref<void(BaseStorage *)> destructorFn);

   /// Implementation for getting an instance of a derived type with default
   /// storage.
   BaseStorage *getSingletonImpl(TypeID id);

   /// Implementation for registering an instance of a derived type with default
   /// storage.
   void
   registerSingletonImpl(TypeID id,
                         function_ref<BaseStorage *(StorageAllocator &)> ctorFn);

   /// Implementation for mutating an instance of a derived storage.
   LogicalResult
   mutateImpl(TypeID id, BaseStorage *storage,
              function_ref<LogicalResult(StorageAllocator &)> mutationFn);

   /// The internal implementation class.
   std::unique_ptr<detail::StorageUniquerImpl> impl;

   //===--------------------------------------------------------------------===//
   // Key Construction
   //===--------------------------------------------------------------------===//

   /// Used to construct an instance of 'ImplTy::KeyTy' if there is an
   /// 'ImplTy::getKey' function for the provided arguments.
   template <typename ImplTy, typename... Args>
   static typename std::enable_if<
       llvm::is_detected<detail::has_impltype_getkey_t, ImplTy, Args...>::value,
       typename ImplTy::KeyTy>::type
   getKey(Args &&...args) {
     return ImplTy::getKey(args...);
   }
   /// If there is no 'ImplTy::getKey' method, then we try to directly construct
   /// the 'ImplTy::KeyTy' with the provided arguments.
   template <typename ImplTy, typename... Args>
   static typename std::enable_if<
       !llvm::is_detected<detail::has_impltype_getkey_t, ImplTy, Args...>::value,
       typename ImplTy::KeyTy>::type
   getKey(Args &&...args) {
     return typename ImplTy::KeyTy(args...);
   }

   //===--------------------------------------------------------------------===//
   // Key Hashing
   //===--------------------------------------------------------------------===//

   /// Used to generate a hash for the 'ImplTy::KeyTy' of a storage instance if
   /// there is an 'ImplTy::hashKey' overload for 'DerivedKey'.
   template <typename ImplTy, typename DerivedKey>
   static typename std::enable_if<
       llvm::is_detected<detail::has_impltype_hash_t, ImplTy, DerivedKey>::value,
       ::llvm::hash_code>::type
   getHash(const DerivedKey &derivedKey) {
     return ImplTy::hashKey(derivedKey);
   }
   /// If there is no 'ImplTy::hashKey' default to using the 'llvm::DenseMapInfo'
   /// definition for 'DerivedKey' for generating a hash.
   template <typename ImplTy, typename DerivedKey>
   static typename std::enable_if<!llvm::is_detected<detail::has_impltype_hash_t,
                                                     ImplTy, DerivedKey>::value,
                                  ::llvm::hash_code>::type
   getHash(const DerivedKey &derivedKey) {
     return DenseMapInfo<DerivedKey>::getHashValue(derivedKey);
   }
 };
 } // end namespace mlir

 #endif
	//===- StorageUniquer.h - Common Storage Class Uniquer ----------- C++ --===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	#ifndef MLIR_SUPPORT_STORAGEUNIQUER_H
	#define MLIR_SUPPORT_STORAGEUNIQUER_H

	#include "mlir/Support/LLVM.h"
	#include "mlir/Support/LogicalResult.h"
	#include "mlir/Support/TypeID.h"
	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/DenseSet.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/Support/Allocator.h"

	namespace mlir {
	namespace detail {
	struct StorageUniquerImpl;

	/// Trait to check if ImplTy provides a 'getKey' method with types 'Args'.
	template <typename ImplTy, typename... Args>
	using has_impltype_getkey_t = decltype(ImplTy::getKey(std::declval<Args>()...));

	/// Trait to check if ImplTy provides a 'hashKey' method for 'T'.
	template <typename ImplTy, typename T>
	using has_impltype_hash_t = decltype(ImplTy::hashKey(std::declval<T>()));
	} // namespace detail

	/// A utility class to get or create instances of "storage classes". These
	/// storage classes must derive from 'StorageUniquer::BaseStorage'.
	///
	/// For non-parametric storage classes, i.e. singleton classes, nothing else is
	/// needed. Instances of these classes can be created by calling `get` without
	/// trailing arguments.
	///
	/// Otherwise, the parametric storage classes may be created with `get`,
	/// and must respect the following:
	/// - Define a type alias, KeyTy, to a type that uniquely identifies the
	/// instance of the storage class.
	/// * The key type must be constructible from the values passed into the
	/// getComplex call.
	/// * If the KeyTy does not have an llvm::DenseMapInfo specialization, the
	/// storage class must define a hashing method:
	/// 'static unsigned hashKey(const KeyTy &)'
	///
	/// - Provide a method, 'bool operator==(const KeyTy &) const', to
	/// compare the storage instance against an instance of the key type.
	///
	/// - Provide a static construction method:
	/// 'DerivedStorage *construct(StorageAllocator &, const KeyTy &key)'
	/// that builds a unique instance of the derived storage. The arguments to
	/// this function are an allocator to store any uniqued data and the key
	/// type for this storage.
	///
	/// - Provide a cleanup method:
	/// 'void cleanup()'
	/// that is called when erasing a storage instance. This should cleanup any
	/// fields of the storage as necessary and not attempt to free the memory
	/// of the storage itself.
	///
	/// Storage classes may have an optional mutable component, which must not take
	/// part in the unique immutable key. In this case, storage classes may be
	/// mutated with `mutate` and must additionally respect the following:
	/// - Provide a mutation method:
	/// 'LogicalResult mutate(StorageAllocator &, <...>)'
	/// that is called when mutating a storage instance. The first argument is
	/// an allocator to store any mutable data, and the remaining arguments are
	/// forwarded from the call site. The storage can be mutated at any time
	/// after creation. Care must be taken to avoid excessive mutation since
	/// the allocated storage can keep containing previous states. The return
	/// value of the function is used to indicate whether the mutation was
	/// successful, e.g., to limit the number of mutations or enable deferred
	/// one-time assignment of the mutable component.
	///
	/// All storage classes must be registered with the uniquer via
	/// `registerStorageType` using an appropriate unique `TypeID` for the storage
	/// class.
	class StorageUniquer {
	public:
	/// This class acts as the base storage that all storage classes must derived
	/// from.
	class alignas(8) BaseStorage {
	protected:
	BaseStorage() = default;
	};

	/// This is a utility allocator used to allocate memory for instances of
	/// derived types.
	class StorageAllocator {
	public:
	/// Copy the specified array of elements into memory managed by our bump
	/// pointer allocator. This assumes the elements are all PODs.
	template <typename T> ArrayRef<T> copyInto(ArrayRef<T> elements) {
	if (elements.empty())
	return llvm::None;
	auto result = allocator.Allocate<T>(elements.size());
	std::uninitialized_copy(elements.begin(), elements.end(), result);
	return ArrayRef<T>(result, elements.size());
	}

	/// Copy the provided string into memory managed by our bump pointer
	/// allocator.
	StringRef copyInto(StringRef str) {
	if (str.empty())
	return StringRef();

	char *result = allocator.Allocate<char>(str.size() + 1);
	std::uninitialized_copy(str.begin(), str.end(), result);
	result[str.size()] = 0;
	return StringRef(result, str.size());
	}

	/// Allocate an instance of the provided type.
	template <typename T> T *allocate() { return allocator.Allocate<T>(); }

	/// Allocate 'size' bytes of 'alignment' aligned memory.
	void *allocate(size_t size, size_t alignment) {
	return allocator.Allocate(size, alignment);
	}

	/// Returns true if this allocator allocated the provided object pointer.
	bool allocated(const void *ptr) {
	return allocator.identifyObject(ptr).hasValue();
	}

	private:
	/// The raw allocator for type storage objects.
	llvm::BumpPtrAllocator allocator;
	};

	StorageUniquer();
	~StorageUniquer();

	/// Set the flag specifying if multi-threading is disabled within the uniquer.
	void disableMultithreading(bool disable = true);

	/// Register a new parametric storage class, this is necessary to create
	/// instances of this class type. `id` is the type identifier that will be
	/// used to identify this type when creating instances of it via 'get'.
	template <typename Storage> void registerParametricStorageType(TypeID id) {
	// If the storage is trivially destructible, we don't need a destructor
	// function.
	if (std::is_trivially_destructible<Storage>::value)
	return registerParametricStorageTypeImpl(id, nullptr);
	registerParametricStorageTypeImpl(id, [](BaseStorage *storage) {
	static_cast<Storage *>(storage)->~Storage();
	});
	}
	/// Utility override when the storage type represents the type id.
	template <typename Storage> void registerParametricStorageType() {
	registerParametricStorageType<Storage>(TypeID::get<Storage>());
	}
	/// Register a new singleton storage class, this is necessary to get the
	/// singletone instance. `id` is the type identifier that will be used to
	/// access the singleton instance via 'get'. An optional initialization
	/// function may also be provided to initialize the newly created storage
	/// instance, and used when the singleton instance is created.
	template <typename Storage>
	void registerSingletonStorageType(TypeID id,
	function_ref<void(Storage *)> initFn) {
	auto ctorFn = [&](StorageAllocator &allocator) {
	auto *storage = new (allocator.allocate<Storage>()) Storage();
	if (initFn)
	initFn(storage);
	return storage;
	};
	registerSingletonImpl(id, ctorFn);
	}
	template <typename Storage> void registerSingletonStorageType(TypeID id) {
	registerSingletonStorageType<Storage>(id, llvm::None);
	}
	/// Utility override when the storage type represents the type id.
	template <typename Storage>
	void registerSingletonStorageType(function_ref<void(Storage *)> initFn = {}) {
	registerSingletonStorageType<Storage>(TypeID::get<Storage>(), initFn);
	}

	/// Gets a uniqued instance of 'Storage'. 'id' is the type id used when
	/// registering the storage instance. 'initFn' is an optional parameter that
	/// can be used to initialize a newly inserted storage instance. This function
	/// is used for derived types that have complex storage or uniquing
	/// constraints.
	template <typename Storage, typename... Args>
	Storage get(function_ref<void(Storage )> initFn, TypeID id,
	Args &&...args) {
	// Construct a value of the derived key type.
	auto derivedKey = getKey<Storage>(std::forward<Args>(args)...);

	// Create a hash of the derived key.
	unsigned hashValue = getHash<Storage>(derivedKey);

	// Generate an equality function for the derived storage.
	auto isEqual = [&derivedKey](const BaseStorage *existing) {
	return static_cast<const Storage &>(*existing) == derivedKey;
	};

	// Generate a constructor function for the derived storage.
	auto ctorFn = [&](StorageAllocator &allocator) {
	auto *storage = Storage::construct(allocator, derivedKey);
	if (initFn)
	initFn(storage);
	return storage;
	};

	// Get an instance for the derived storage.
	return static_cast<Storage *>(
	getParametricStorageTypeImpl(id, hashValue, isEqual, ctorFn));
	}
	/// Utility override when the storage type represents the type id.
	template <typename Storage, typename... Args>
	Storage get(function_ref<void(Storage )> initFn, Args &&...args) {
	return get<Storage>(initFn, TypeID::get<Storage>(),
	std::forward<Args>(args)...);
	}

	/// Gets a uniqued instance of 'Storage' which is a singleton storage type.
	/// 'id' is the type id used when registering the storage instance.
	template <typename Storage> Storage *get(TypeID id) {
	return static_cast<Storage *>(getSingletonImpl(id));
	}
	/// Utility override when the storage type represents the type id.
	template <typename Storage> Storage *get() {
	return get<Storage>(TypeID::get<Storage>());
	}

	/// Test if there is a singleton storage uniquer initialized for the provided
	/// TypeID. This is only useful for debugging/diagnostic purpose: the uniquer
	/// is initialized when a dialect is loaded.
	bool isSingletonStorageInitialized(TypeID id);

	/// Test if there is a parametric storage uniquer initialized for the provided
	/// TypeID. This is only useful for debugging/diagnostic purpose: the uniquer
	/// is initialized when a dialect is loaded.
	bool isParametricStorageInitialized(TypeID id);

	/// Changes the mutable component of 'storage' by forwarding the trailing
	/// arguments to the 'mutate' function of the derived class.
	template <typename Storage, typename... Args>
	LogicalResult mutate(TypeID id, Storage *storage, Args &&...args) {
	auto mutationFn = [&](StorageAllocator &allocator) -> LogicalResult {
	return static_cast<Storage &>(*storage).mutate(
	allocator, std::forward<Args>(args)...);
	};
	return mutateImpl(id, storage, mutationFn);
	}

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

	/// Implementation for registering an instance of a derived type with
	/// parametric storage. This method takes an optional destructor function that
	/// destructs storage instances when necessary.
	void registerParametricStorageTypeImpl(
	TypeID id, function_ref<void(BaseStorage *)> destructorFn);

	/// Implementation for getting an instance of a derived type with default
	/// storage.
	BaseStorage *getSingletonImpl(TypeID id);

	/// Implementation for registering an instance of a derived type with default
	/// storage.
	void
	registerSingletonImpl(TypeID id,
	function_ref<BaseStorage *(StorageAllocator &)> ctorFn);

	/// Implementation for mutating an instance of a derived storage.
	LogicalResult
	mutateImpl(TypeID id, BaseStorage *storage,
	function_ref<LogicalResult(StorageAllocator &)> mutationFn);

	/// The internal implementation class.
	std::unique_ptr<detail::StorageUniquerImpl> impl;

	//===--------------------------------------------------------------------===//
	// Key Construction
	//===--------------------------------------------------------------------===//

	/// Used to construct an instance of 'ImplTy::KeyTy' if there is an
	/// 'ImplTy::getKey' function for the provided arguments.
	template <typename ImplTy, typename... Args>
	static typename std::enable_if<
	llvm::is_detected<detail::has_impltype_getkey_t, ImplTy, Args...>::value,
	typename ImplTy::KeyTy>::type
	getKey(Args &&...args) {
	return ImplTy::getKey(args...);
	}
	/// If there is no 'ImplTy::getKey' method, then we try to directly construct
	/// the 'ImplTy::KeyTy' with the provided arguments.
	template <typename ImplTy, typename... Args>
	static typename std::enable_if<
	!llvm::is_detected<detail::has_impltype_getkey_t, ImplTy, Args...>::value,
	typename ImplTy::KeyTy>::type
	getKey(Args &&...args) {
	return typename ImplTy::KeyTy(args...);
	}

	//===--------------------------------------------------------------------===//
	// Key Hashing
	//===--------------------------------------------------------------------===//

	/// Used to generate a hash for the 'ImplTy::KeyTy' of a storage instance if
	/// there is an 'ImplTy::hashKey' overload for 'DerivedKey'.
	template <typename ImplTy, typename DerivedKey>
	static typename std::enable_if<
	llvm::is_detected<detail::has_impltype_hash_t, ImplTy, DerivedKey>::value,
	::llvm::hash_code>::type
	getHash(const DerivedKey &derivedKey) {
	return ImplTy::hashKey(derivedKey);
	}
	/// If there is no 'ImplTy::hashKey' default to using the 'llvm::DenseMapInfo'
	/// definition for 'DerivedKey' for generating a hash.
	template <typename ImplTy, typename DerivedKey>
	static typename std::enable_if<!llvm::is_detected<detail::has_impltype_hash_t,
	ImplTy, DerivedKey>::value,
	::llvm::hash_code>::type
	getHash(const DerivedKey &derivedKey) {
	return DenseMapInfo<DerivedKey>::getHashValue(derivedKey);
	}
	};
	} // end namespace mlir

	#endif