clang-r416183b1/include/llvm/ADT/PointerSumType.h - platform/prebuilts/clang/host/windows-x86 - Git at Google

 //===- llvm/ADT/PointerSumType.h --------------------------------*- 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 LLVM_ADT_POINTERSUMTYPE_H
 #define LLVM_ADT_POINTERSUMTYPE_H

 #include "llvm/ADT/bit.h"
 #include "llvm/ADT/DenseMapInfo.h"
 #include "llvm/Support/PointerLikeTypeTraits.h"
 #include <cassert>
 #include <cstdint>
 #include <type_traits>

 namespace llvm {

 /// A compile time pair of an integer tag and the pointer-like type which it
 /// indexes within a sum type. Also allows the user to specify a particular
 /// traits class for pointer types with custom behavior such as over-aligned
 /// allocation.
 template <uintptr_t N, typename PointerArgT,
           typename TraitsArgT = PointerLikeTypeTraits<PointerArgT>>
 struct PointerSumTypeMember {
   enum { Tag = N };
   using PointerT = PointerArgT;
   using TraitsT = TraitsArgT;
 };

 namespace detail {

 template <typename TagT, typename... MemberTs> struct PointerSumTypeHelper;

 } // end namespace detail

 /// A sum type over pointer-like types.
 ///
 /// This is a normal tagged union across pointer-like types that uses the low
 /// bits of the pointers to store the tag.
 ///
 /// Each member of the sum type is specified by passing a \c
 /// PointerSumTypeMember specialization in the variadic member argument list.
 /// This allows the user to control the particular tag value associated with
 /// a particular type, use the same type for multiple different tags, and
 /// customize the pointer-like traits used for a particular member. Note that
 /// these *must* be specializations of \c PointerSumTypeMember, no other type
 /// will suffice, even if it provides a compatible interface.
 ///
 /// This type implements all of the comparison operators and even hash table
 /// support by comparing the underlying storage of the pointer values. It
 /// doesn't support delegating to particular members for comparisons.
 ///
 /// It also default constructs to a zero tag with a null pointer, whatever that
 /// would be. This means that the zero value for the tag type is significant
 /// and may be desirable to set to a state that is particularly desirable to
 /// default construct.
 ///
 /// Having a supported zero-valued tag also enables getting the address of a
 /// pointer stored with that tag provided it is stored in its natural bit
 /// representation. This works because in the case of a zero-valued tag, the
 /// pointer's value is directly stored into this object and we can expose the
 /// address of that internal storage. This is especially useful when building an
 /// `ArrayRef` of a single pointer stored in a sum type.
 ///
 /// There is no support for constructing or accessing with a dynamic tag as
 /// that would fundamentally violate the type safety provided by the sum type.
 template <typename TagT, typename... MemberTs> class PointerSumType {
   using HelperT = detail::PointerSumTypeHelper<TagT, MemberTs...>;

   // We keep both the raw value and the min tag value's pointer in a union. When
   // the minimum tag value is zero, this allows code below to cleanly expose the
   // address of the zero-tag pointer instead of just the zero-tag pointer
   // itself. This is especially useful when building `ArrayRef`s out of a single
   // pointer. However, we have to carefully access the union due to the active
   // member potentially changing. When we *store* a new value, we directly
   // access the union to allow us to store using the obvious types. However,
   // when we *read* a value, we copy the underlying storage out to avoid relying
   // on one member or the other being active.
   union StorageT {
     // Ensure we get a null default constructed value. We don't use a member
     // initializer because some compilers seem to not implement those correctly
     // for a union.
     StorageT() : Value(0) {}

     uintptr_t Value;

     typename HelperT::template Lookup<HelperT::MinTag>::PointerT MinTagPointer;
   };

   StorageT Storage;

 public:
   constexpr PointerSumType() = default;

   /// A typed setter to a given tagged member of the sum type.
   template <TagT N>
   void set(typename HelperT::template Lookup<N>::PointerT Pointer) {
     void *V = HelperT::template Lookup<N>::TraitsT::getAsVoidPointer(Pointer);
     assert((reinterpret_cast<uintptr_t>(V) & HelperT::TagMask) == 0 &&
            "Pointer is insufficiently aligned to store the discriminant!");
     Storage.Value = reinterpret_cast<uintptr_t>(V) | N;
   }

   /// A typed constructor for a specific tagged member of the sum type.
   template <TagT N>
   static PointerSumType
   create(typename HelperT::template Lookup<N>::PointerT Pointer) {
     PointerSumType Result;
     Result.set<N>(Pointer);
     return Result;
   }

   /// Clear the value to null with the min tag type.
   void clear() { set<HelperT::MinTag>(nullptr); }

   TagT getTag() const {
     return static_cast<TagT>(getOpaqueValue() & HelperT::TagMask);
   }

   template <TagT N> bool is() const { return N == getTag(); }

   template <TagT N> typename HelperT::template Lookup<N>::PointerT get() const {
     void *P = is<N>() ? getVoidPtr() : nullptr;
     return HelperT::template Lookup<N>::TraitsT::getFromVoidPointer(P);
   }

   template <TagT N>
   typename HelperT::template Lookup<N>::PointerT cast() const {
     assert(is<N>() && "This instance has a different active member.");
     return HelperT::template Lookup<N>::TraitsT::getFromVoidPointer(
         getVoidPtr());
   }

   /// If the tag is zero and the pointer's value isn't changed when being
   /// stored, get the address of the stored value type-punned to the zero-tag's
   /// pointer type.
   typename HelperT::template Lookup<HelperT::MinTag>::PointerT const *
   getAddrOfZeroTagPointer() const {
     return const_cast<PointerSumType *>(this)->getAddrOfZeroTagPointer();
   }

   /// If the tag is zero and the pointer's value isn't changed when being
   /// stored, get the address of the stored value type-punned to the zero-tag's
   /// pointer type.
   typename HelperT::template Lookup<HelperT::MinTag>::PointerT *
   getAddrOfZeroTagPointer() {
     static_assert(HelperT::MinTag == 0, "Non-zero minimum tag value!");
     assert(is<HelperT::MinTag>() && "The active tag is not zero!");
     // Store the initial value of the pointer when read out of our storage.
     auto InitialPtr = get<HelperT::MinTag>();
     // Now update the active member of the union to be the actual pointer-typed
     // member so that accessing it indirectly through the returned address is
     // valid.
     Storage.MinTagPointer = InitialPtr;
     // Finally, validate that this was a no-op as expected by reading it back
     // out using the same underlying-storage read as above.
     assert(InitialPtr == get<HelperT::MinTag>() &&
            "Switching to typed storage changed the pointer returned!");
     // Now we can correctly return an address to typed storage.
     return &Storage.MinTagPointer;
   }

   explicit operator bool() const {
     return getOpaqueValue() & HelperT::PointerMask;
   }
   bool operator==(const PointerSumType &R) const {
     return getOpaqueValue() == R.getOpaqueValue();
   }
   bool operator!=(const PointerSumType &R) const {
     return getOpaqueValue() != R.getOpaqueValue();
   }
   bool operator<(const PointerSumType &R) const {
     return getOpaqueValue() < R.getOpaqueValue();
   }
   bool operator>(const PointerSumType &R) const {
     return getOpaqueValue() > R.getOpaqueValue();
   }
   bool operator<=(const PointerSumType &R) const {
     return getOpaqueValue() <= R.getOpaqueValue();
   }
   bool operator>=(const PointerSumType &R) const {
     return getOpaqueValue() >= R.getOpaqueValue();
   }

   uintptr_t getOpaqueValue() const {
     // Read the underlying storage of the union, regardless of the active
     // member.
     return bit_cast<uintptr_t>(Storage);
   }

 protected:
   void *getVoidPtr() const {
     return reinterpret_cast<void *>(getOpaqueValue() & HelperT::PointerMask);
   }
 };

 namespace detail {

 /// A helper template for implementing \c PointerSumType. It provides fast
 /// compile-time lookup of the member from a particular tag value, along with
 /// useful constants and compile time checking infrastructure..
 template <typename TagT, typename... MemberTs>
 struct PointerSumTypeHelper : MemberTs... {
   // First we use a trick to allow quickly looking up information about
   // a particular member of the sum type. This works because we arranged to
   // have this type derive from all of the member type templates. We can select
   // the matching member for a tag using type deduction during overload
   // resolution.
   template <TagT N, typename PointerT, typename TraitsT>
   static PointerSumTypeMember<N, PointerT, TraitsT>
   LookupOverload(PointerSumTypeMember<N, PointerT, TraitsT> *);
   template <TagT N> static void LookupOverload(...);
   template <TagT N> struct Lookup {
     // Compute a particular member type by resolving the lookup helper overload.
     using MemberT = decltype(
         LookupOverload<N>(static_cast<PointerSumTypeHelper *>(nullptr)));

     /// The Nth member's pointer type.
     using PointerT = typename MemberT::PointerT;

     /// The Nth member's traits type.
     using TraitsT = typename MemberT::TraitsT;
   };

   // Next we need to compute the number of bits available for the discriminant
   // by taking the min of the bits available for each member. Much of this
   // would be amazingly easier with good constexpr support.
   template <uintptr_t V, uintptr_t... Vs>
   struct Min : std::integral_constant<
                    uintptr_t, (V < Min<Vs...>::value ? V : Min<Vs...>::value)> {
   };
   template <uintptr_t V>
   struct Min<V> : std::integral_constant<uintptr_t, V> {};
   enum { NumTagBits = Min<MemberTs::TraitsT::NumLowBitsAvailable...>::value };

   // Also compute the smallest discriminant and various masks for convenience.
   constexpr static TagT MinTag =
       static_cast<TagT>(Min<MemberTs::Tag...>::value);
   enum : uint64_t {
     PointerMask = static_cast<uint64_t>(-1) << NumTagBits,
     TagMask = ~PointerMask
   };

   // Finally we need a recursive template to do static checks of each
   // member.
   template <typename MemberT, typename... InnerMemberTs>
   struct Checker : Checker<InnerMemberTs...> {
     static_assert(MemberT::Tag < (1 << NumTagBits),
                   "This discriminant value requires too many bits!");
   };
   template <typename MemberT> struct Checker<MemberT> : std::true_type {
     static_assert(MemberT::Tag < (1 << NumTagBits),
                   "This discriminant value requires too many bits!");
   };
   static_assert(Checker<MemberTs...>::value,
                 "Each member must pass the checker.");
 };

 } // end namespace detail

 // Teach DenseMap how to use PointerSumTypes as keys.
 template <typename TagT, typename... MemberTs>
 struct DenseMapInfo<PointerSumType<TagT, MemberTs...>> {
   using SumType = PointerSumType<TagT, MemberTs...>;
   using HelperT = detail::PointerSumTypeHelper<TagT, MemberTs...>;
   enum { SomeTag = HelperT::MinTag };
   using SomePointerT =
       typename HelperT::template Lookup<HelperT::MinTag>::PointerT;
   using SomePointerInfo = DenseMapInfo<SomePointerT>;

   static inline SumType getEmptyKey() {
     return SumType::create<SomeTag>(SomePointerInfo::getEmptyKey());
   }

   static inline SumType getTombstoneKey() {
     return SumType::create<SomeTag>(SomePointerInfo::getTombstoneKey());
   }

   static unsigned getHashValue(const SumType &Arg) {
     uintptr_t OpaqueValue = Arg.getOpaqueValue();
     return DenseMapInfo<uintptr_t>::getHashValue(OpaqueValue);
   }

   static bool isEqual(const SumType &LHS, const SumType &RHS) {
     return LHS == RHS;
   }
 };

 } // end namespace llvm

 #endif // LLVM_ADT_POINTERSUMTYPE_H
	//===- llvm/ADT/PointerSumType.h --------------------------------- 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 LLVM_ADT_POINTERSUMTYPE_H
	#define LLVM_ADT_POINTERSUMTYPE_H

	#include "llvm/ADT/bit.h"
	#include "llvm/ADT/DenseMapInfo.h"
	#include "llvm/Support/PointerLikeTypeTraits.h"
	#include <cassert>
	#include <cstdint>
	#include <type_traits>

	namespace llvm {

	/// A compile time pair of an integer tag and the pointer-like type which it
	/// indexes within a sum type. Also allows the user to specify a particular
	/// traits class for pointer types with custom behavior such as over-aligned
	/// allocation.
	template <uintptr_t N, typename PointerArgT,
	typename TraitsArgT = PointerLikeTypeTraits<PointerArgT>>
	struct PointerSumTypeMember {
	enum { Tag = N };
	using PointerT = PointerArgT;
	using TraitsT = TraitsArgT;
	};

	namespace detail {

	template <typename TagT, typename... MemberTs> struct PointerSumTypeHelper;

	} // end namespace detail

	/// A sum type over pointer-like types.
	///
	/// This is a normal tagged union across pointer-like types that uses the low
	/// bits of the pointers to store the tag.
	///
	/// Each member of the sum type is specified by passing a \c
	/// PointerSumTypeMember specialization in the variadic member argument list.
	/// This allows the user to control the particular tag value associated with
	/// a particular type, use the same type for multiple different tags, and
	/// customize the pointer-like traits used for a particular member. Note that
	/// these must be specializations of \c PointerSumTypeMember, no other type
	/// will suffice, even if it provides a compatible interface.
	///
	/// This type implements all of the comparison operators and even hash table
	/// support by comparing the underlying storage of the pointer values. It
	/// doesn't support delegating to particular members for comparisons.
	///
	/// It also default constructs to a zero tag with a null pointer, whatever that
	/// would be. This means that the zero value for the tag type is significant
	/// and may be desirable to set to a state that is particularly desirable to
	/// default construct.
	///
	/// Having a supported zero-valued tag also enables getting the address of a
	/// pointer stored with that tag provided it is stored in its natural bit
	/// representation. This works because in the case of a zero-valued tag, the
	/// pointer's value is directly stored into this object and we can expose the
	/// address of that internal storage. This is especially useful when building an
	/// `ArrayRef` of a single pointer stored in a sum type.
	///
	/// There is no support for constructing or accessing with a dynamic tag as
	/// that would fundamentally violate the type safety provided by the sum type.
	template <typename TagT, typename... MemberTs> class PointerSumType {
	using HelperT = detail::PointerSumTypeHelper<TagT, MemberTs...>;

	// We keep both the raw value and the min tag value's pointer in a union. When
	// the minimum tag value is zero, this allows code below to cleanly expose the
	// address of the zero-tag pointer instead of just the zero-tag pointer
	// itself. This is especially useful when building `ArrayRef`s out of a single
	// pointer. However, we have to carefully access the union due to the active
	// member potentially changing. When we store a new value, we directly
	// access the union to allow us to store using the obvious types. However,
	// when we read a value, we copy the underlying storage out to avoid relying
	// on one member or the other being active.
	union StorageT {
	// Ensure we get a null default constructed value. We don't use a member
	// initializer because some compilers seem to not implement those correctly
	// for a union.
	StorageT() : Value(0) {}

	uintptr_t Value;

	typename HelperT::template Lookup<HelperT::MinTag>::PointerT MinTagPointer;
	};

	StorageT Storage;

	public:
	constexpr PointerSumType() = default;

	/// A typed setter to a given tagged member of the sum type.
	template <TagT N>
	void set(typename HelperT::template Lookup<N>::PointerT Pointer) {
	void *V = HelperT::template Lookup<N>::TraitsT::getAsVoidPointer(Pointer);
	assert((reinterpret_cast<uintptr_t>(V) & HelperT::TagMask) == 0 &&
	"Pointer is insufficiently aligned to store the discriminant!");
	Storage.Value = reinterpret_cast<uintptr_t>(V) \| N;
	}

	/// A typed constructor for a specific tagged member of the sum type.
	template <TagT N>
	static PointerSumType
	create(typename HelperT::template Lookup<N>::PointerT Pointer) {
	PointerSumType Result;
	Result.set<N>(Pointer);
	return Result;
	}

	/// Clear the value to null with the min tag type.
	void clear() { set<HelperT::MinTag>(nullptr); }

	TagT getTag() const {
	return static_cast<TagT>(getOpaqueValue() & HelperT::TagMask);
	}

	template <TagT N> bool is() const { return N == getTag(); }

	template <TagT N> typename HelperT::template Lookup<N>::PointerT get() const {
	void *P = is<N>() ? getVoidPtr() : nullptr;
	return HelperT::template Lookup<N>::TraitsT::getFromVoidPointer(P);
	}

	template <TagT N>
	typename HelperT::template Lookup<N>::PointerT cast() const {
	assert(is<N>() && "This instance has a different active member.");
	return HelperT::template Lookup<N>::TraitsT::getFromVoidPointer(
	getVoidPtr());
	}

	/// If the tag is zero and the pointer's value isn't changed when being
	/// stored, get the address of the stored value type-punned to the zero-tag's
	/// pointer type.
	typename HelperT::template Lookup<HelperT::MinTag>::PointerT const *
	getAddrOfZeroTagPointer() const {
	return const_cast<PointerSumType *>(this)->getAddrOfZeroTagPointer();
	}

	/// If the tag is zero and the pointer's value isn't changed when being
	/// stored, get the address of the stored value type-punned to the zero-tag's
	/// pointer type.
	typename HelperT::template Lookup<HelperT::MinTag>::PointerT *
	getAddrOfZeroTagPointer() {
	static_assert(HelperT::MinTag == 0, "Non-zero minimum tag value!");
	assert(is<HelperT::MinTag>() && "The active tag is not zero!");
	// Store the initial value of the pointer when read out of our storage.
	auto InitialPtr = get<HelperT::MinTag>();
	// Now update the active member of the union to be the actual pointer-typed
	// member so that accessing it indirectly through the returned address is
	// valid.
	Storage.MinTagPointer = InitialPtr;
	// Finally, validate that this was a no-op as expected by reading it back
	// out using the same underlying-storage read as above.
	assert(InitialPtr == get<HelperT::MinTag>() &&
	"Switching to typed storage changed the pointer returned!");
	// Now we can correctly return an address to typed storage.
	return &Storage.MinTagPointer;
	}

	explicit operator bool() const {
	return getOpaqueValue() & HelperT::PointerMask;
	}
	bool operator==(const PointerSumType &R) const {
	return getOpaqueValue() == R.getOpaqueValue();
	}
	bool operator!=(const PointerSumType &R) const {
	return getOpaqueValue() != R.getOpaqueValue();
	}
	bool operator<(const PointerSumType &R) const {
	return getOpaqueValue() < R.getOpaqueValue();
	}
	bool operator>(const PointerSumType &R) const {
	return getOpaqueValue() > R.getOpaqueValue();
	}
	bool operator<=(const PointerSumType &R) const {
	return getOpaqueValue() <= R.getOpaqueValue();
	}
	bool operator>=(const PointerSumType &R) const {
	return getOpaqueValue() >= R.getOpaqueValue();
	}

	uintptr_t getOpaqueValue() const {
	// Read the underlying storage of the union, regardless of the active
	// member.
	return bit_cast<uintptr_t>(Storage);
	}

	protected:
	void *getVoidPtr() const {
	return reinterpret_cast<void *>(getOpaqueValue() & HelperT::PointerMask);
	}
	};

	namespace detail {

	/// A helper template for implementing \c PointerSumType. It provides fast
	/// compile-time lookup of the member from a particular tag value, along with
	/// useful constants and compile time checking infrastructure..
	template <typename TagT, typename... MemberTs>
	struct PointerSumTypeHelper : MemberTs... {
	// First we use a trick to allow quickly looking up information about
	// a particular member of the sum type. This works because we arranged to
	// have this type derive from all of the member type templates. We can select
	// the matching member for a tag using type deduction during overload
	// resolution.
	template <TagT N, typename PointerT, typename TraitsT>
	static PointerSumTypeMember<N, PointerT, TraitsT>
	LookupOverload(PointerSumTypeMember<N, PointerT, TraitsT> *);
	template <TagT N> static void LookupOverload(...);
	template <TagT N> struct Lookup {
	// Compute a particular member type by resolving the lookup helper overload.
	using MemberT = decltype(
	LookupOverload<N>(static_cast<PointerSumTypeHelper *>(nullptr)));

	/// The Nth member's pointer type.
	using PointerT = typename MemberT::PointerT;

	/// The Nth member's traits type.
	using TraitsT = typename MemberT::TraitsT;
	};

	// Next we need to compute the number of bits available for the discriminant
	// by taking the min of the bits available for each member. Much of this
	// would be amazingly easier with good constexpr support.
	template <uintptr_t V, uintptr_t... Vs>
	struct Min : std::integral_constant<
	uintptr_t, (V < Min<Vs...>::value ? V : Min<Vs...>::value)> {
	};
	template <uintptr_t V>
	struct Min<V> : std::integral_constant<uintptr_t, V> {};
	enum { NumTagBits = Min<MemberTs::TraitsT::NumLowBitsAvailable...>::value };

	// Also compute the smallest discriminant and various masks for convenience.
	constexpr static TagT MinTag =
	static_cast<TagT>(Min<MemberTs::Tag...>::value);
	enum : uint64_t {
	PointerMask = static_cast<uint64_t>(-1) << NumTagBits,
	TagMask = ~PointerMask
	};

	// Finally we need a recursive template to do static checks of each
	// member.
	template <typename MemberT, typename... InnerMemberTs>
	struct Checker : Checker<InnerMemberTs...> {
	static_assert(MemberT::Tag < (1 << NumTagBits),
	"This discriminant value requires too many bits!");
	};
	template <typename MemberT> struct Checker<MemberT> : std::true_type {
	static_assert(MemberT::Tag < (1 << NumTagBits),
	"This discriminant value requires too many bits!");
	};
	static_assert(Checker<MemberTs...>::value,
	"Each member must pass the checker.");
	};

	} // end namespace detail

	// Teach DenseMap how to use PointerSumTypes as keys.
	template <typename TagT, typename... MemberTs>
	struct DenseMapInfo<PointerSumType<TagT, MemberTs...>> {
	using SumType = PointerSumType<TagT, MemberTs...>;
	using HelperT = detail::PointerSumTypeHelper<TagT, MemberTs...>;
	enum { SomeTag = HelperT::MinTag };
	using SomePointerT =
	typename HelperT::template Lookup<HelperT::MinTag>::PointerT;
	using SomePointerInfo = DenseMapInfo<SomePointerT>;

	static inline SumType getEmptyKey() {
	return SumType::create<SomeTag>(SomePointerInfo::getEmptyKey());
	}

	static inline SumType getTombstoneKey() {
	return SumType::create<SomeTag>(SomePointerInfo::getTombstoneKey());
	}

	static unsigned getHashValue(const SumType &Arg) {
	uintptr_t OpaqueValue = Arg.getOpaqueValue();
	return DenseMapInfo<uintptr_t>::getHashValue(OpaqueValue);
	}

	static bool isEqual(const SumType &LHS, const SumType &RHS) {
	return LHS == RHS;
	}
	};

	} // end namespace llvm

	#endif // LLVM_ADT_POINTERSUMTYPE_H