include/llvm/Support/Alignment.h - llvm-project/llvm - Git at Google

 //===-- llvm/Support/Alignment.h - Useful alignment functions ---*- 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file contains types to represent alignments.
 // They are instrumented to guarantee some invariants are preserved and prevent
 // invalid manipulations.
 //
 // - Align represents an alignment in bytes, it is always set and always a valid
 // power of two, its minimum value is 1 which means no alignment requirements.
 //
 // - MaybeAlign is an optional type, it may be undefined or set. When it's set
 // you can get the underlying Align type by using the getValue() method.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_SUPPORT_ALIGNMENT_H_
 #define LLVM_SUPPORT_ALIGNMENT_H_

 #include "llvm/ADT/Optional.h"
 #include "llvm/Support/MathExtras.h"
 #include <cassert>
 #ifndef NDEBUG
 #include <string>
 #endif // NDEBUG

 namespace llvm {

 #define ALIGN_CHECK_ISPOSITIVE(decl)                                           \
   assert(decl > 0 && (#decl " should be defined"))

 /// This struct is a compact representation of a valid (non-zero power of two)
 /// alignment.
 /// It is suitable for use as static global constants.
 struct Align {
 private:
   uint8_t ShiftValue = 0; /// The log2 of the required alignment.
                           /// ShiftValue is less than 64 by construction.

   friend struct MaybeAlign;
   friend unsigned Log2(Align);
   friend bool operator==(Align Lhs, Align Rhs);
   friend bool operator!=(Align Lhs, Align Rhs);
   friend bool operator<=(Align Lhs, Align Rhs);
   friend bool operator>=(Align Lhs, Align Rhs);
   friend bool operator<(Align Lhs, Align Rhs);
   friend bool operator>(Align Lhs, Align Rhs);
   friend unsigned encode(struct MaybeAlign A);
   friend struct MaybeAlign decodeMaybeAlign(unsigned Value);

   /// A trivial type to allow construction of constexpr Align.
   /// This is currently needed to workaround a bug in GCC 5.3 which prevents
   /// definition of constexpr assign operators.
   /// https://stackoverflow.com/questions/46756288/explicitly-defaulted-function-cannot-be-declared-as-constexpr-because-the-implic
   /// FIXME: Remove this, make all assign operators constexpr and introduce user
   /// defined literals when we don't have to support GCC 5.3 anymore.
   /// https://llvm.org/docs/GettingStarted.html#getting-a-modern-host-c-toolchain
   struct LogValue {
     uint8_t Log;
   };

 public:
   /// Default is byte-aligned.
   constexpr Align() = default;
   /// Do not perform checks in case of copy/move construct/assign, because the
   /// checks have been performed when building `Other`.
   constexpr Align(const Align &Other) = default;
   constexpr Align(Align &&Other) = default;
   Align &operator=(const Align &Other) = default;
   Align &operator=(Align &&Other) = default;

   explicit Align(uint64_t Value) {
     assert(Value > 0 && "Value must not be 0");
     assert(llvm::isPowerOf2_64(Value) && "Alignment is not a power of 2");
     ShiftValue = Log2_64(Value);
     assert(ShiftValue < 64 && "Broken invariant");
   }

   /// This is a hole in the type system and should not be abused.
   /// Needed to interact with C for instance.
   uint64_t value() const { return uint64_t(1) << ShiftValue; }

   /// Returns a default constructed Align which corresponds to no alignment.
   /// It was decided to deprecate Align::None because it's too close to
   /// llvm::None which can be used to initialize `MaybeAlign`.
   /// MaybeAlign = llvm::None means unspecified alignment,
   /// Align = Align::None() means alignment of one byte.
   LLVM_ATTRIBUTE_DEPRECATED(constexpr static const Align None(),
                             "Use Align() or Align(1) instead") {
     return Align();
   }

   /// Allow constructions of constexpr Align.
   template <size_t kValue> constexpr static LogValue Constant() {
     return LogValue{static_cast<uint8_t>(CTLog2<kValue>())};
   }

   /// Allow constructions of constexpr Align from types.
   /// Compile time equivalent to Align(alignof(T)).
   template <typename T> constexpr static LogValue Of() {
     return Constant<std::alignment_of<T>::value>();
   }

   /// Constexpr constructor from LogValue type.
   constexpr Align(LogValue CA) : ShiftValue(CA.Log) {}
 };

 /// Treats the value 0 as a 1, so Align is always at least 1.
 inline Align assumeAligned(uint64_t Value) {
   return Value ? Align(Value) : Align();
 }

 /// This struct is a compact representation of a valid (power of two) or
 /// undefined (0) alignment.
 struct MaybeAlign : public llvm::Optional<Align> {
 private:
   using UP = llvm::Optional<Align>;

 public:
   /// Default is undefined.
   MaybeAlign() = default;
   /// Do not perform checks in case of copy/move construct/assign, because the
   /// checks have been performed when building `Other`.
   MaybeAlign(const MaybeAlign &Other) = default;
   MaybeAlign &operator=(const MaybeAlign &Other) = default;
   MaybeAlign(MaybeAlign &&Other) = default;
   MaybeAlign &operator=(MaybeAlign &&Other) = default;

   /// Use llvm::Optional<Align> constructor.
   using UP::UP;

   explicit MaybeAlign(uint64_t Value) {
     assert((Value == 0 || llvm::isPowerOf2_64(Value)) &&
            "Alignment is neither 0 nor a power of 2");
     if (Value)
       emplace(Value);
   }

   /// For convenience, returns a valid alignment or 1 if undefined.
   Align valueOrOne() const { return hasValue() ? getValue() : Align(); }
 };

 /// Checks that SizeInBytes is a multiple of the alignment.
 inline bool isAligned(Align Lhs, uint64_t SizeInBytes) {
   return SizeInBytes % Lhs.value() == 0;
 }

 /// Checks that Addr is a multiple of the alignment.
 inline bool isAddrAligned(Align Lhs, const void *Addr) {
   return isAligned(Lhs, reinterpret_cast<uintptr_t>(Addr));
 }

 /// Returns a multiple of A needed to store `Size` bytes.
 inline uint64_t alignTo(uint64_t Size, Align A) {
   const uint64_t Value = A.value();
   // The following line is equivalent to `(Size + Value - 1) / Value * Value`.

   // The division followed by a multiplication can be thought of as a right
   // shift followed by a left shift which zeros out the extra bits produced in
   // the bump; `~(Value - 1)` is a mask where all those bits being zeroed out
   // are just zero.

   // Most compilers can generate this code but the pattern may be missed when
   // multiple functions gets inlined.
   return (Size + Value - 1) & ~(Value - 1U);
 }

 /// If non-zero \p Skew is specified, the return value will be a minimal integer
 /// that is greater than or equal to \p Size and equal to \p A * N + \p Skew for
 /// some integer N. If \p Skew is larger than \p A, its value is adjusted to '\p
 /// Skew mod \p A'.
 ///
 /// Examples:
 /// \code
 ///   alignTo(5, Align(8), 7) = 7
 ///   alignTo(17, Align(8), 1) = 17
 ///   alignTo(~0LL, Align(8), 3) = 3
 /// \endcode
 inline uint64_t alignTo(uint64_t Size, Align A, uint64_t Skew) {
   const uint64_t Value = A.value();
   Skew %= Value;
   return ((Size + Value - 1 - Skew) & ~(Value - 1U)) + Skew;
 }

 /// Returns a multiple of A needed to store `Size` bytes.
 /// Returns `Size` if current alignment is undefined.
 inline uint64_t alignTo(uint64_t Size, MaybeAlign A) {
   return A ? alignTo(Size, A.getValue()) : Size;
 }

 /// Aligns `Addr` to `Alignment` bytes, rounding up.
 inline uintptr_t alignAddr(const void *Addr, Align Alignment) {
   uintptr_t ArithAddr = reinterpret_cast<uintptr_t>(Addr);
   assert(static_cast<uintptr_t>(ArithAddr + Alignment.value() - 1) >=
              ArithAddr &&
          "Overflow");
   return alignTo(ArithAddr, Alignment);
 }

 /// Returns the offset to the next integer (mod 2**64) that is greater than
 /// or equal to \p Value and is a multiple of \p Align.
 inline uint64_t offsetToAlignment(uint64_t Value, Align Alignment) {
   return alignTo(Value, Alignment) - Value;
 }

 /// Returns the necessary adjustment for aligning `Addr` to `Alignment`
 /// bytes, rounding up.
 inline uint64_t offsetToAlignedAddr(const void *Addr, Align Alignment) {
   return offsetToAlignment(reinterpret_cast<uintptr_t>(Addr), Alignment);
 }

 /// Returns the log2 of the alignment.
 inline unsigned Log2(Align A) { return A.ShiftValue; }

 /// Returns the alignment that satisfies both alignments.
 /// Same semantic as MinAlign.
 inline Align commonAlignment(Align A, Align B) { return std::min(A, B); }

 /// Returns the alignment that satisfies both alignments.
 /// Same semantic as MinAlign.
 inline Align commonAlignment(Align A, uint64_t Offset) {
   return Align(MinAlign(A.value(), Offset));
 }

 /// Returns the alignment that satisfies both alignments.
 /// Same semantic as MinAlign.
 inline MaybeAlign commonAlignment(MaybeAlign A, MaybeAlign B) {
   return A && B ? commonAlignment(*A, *B) : A ? A : B;
 }

 /// Returns the alignment that satisfies both alignments.
 /// Same semantic as MinAlign.
 inline MaybeAlign commonAlignment(MaybeAlign A, uint64_t Offset) {
   return MaybeAlign(MinAlign((*A).value(), Offset));
 }

 /// Returns a representation of the alignment that encodes undefined as 0.
 inline unsigned encode(MaybeAlign A) { return A ? A->ShiftValue + 1 : 0; }

 /// Dual operation of the encode function above.
 inline MaybeAlign decodeMaybeAlign(unsigned Value) {
   if (Value == 0)
     return MaybeAlign();
   Align Out;
   Out.ShiftValue = Value - 1;
   return Out;
 }

 /// Returns a representation of the alignment, the encoded value is positive by
 /// definition.
 inline unsigned encode(Align A) { return encode(MaybeAlign(A)); }

 /// Comparisons between Align and scalars. Rhs must be positive.
 inline bool operator==(Align Lhs, uint64_t Rhs) {
   ALIGN_CHECK_ISPOSITIVE(Rhs);
   return Lhs.value() == Rhs;
 }
 inline bool operator!=(Align Lhs, uint64_t Rhs) {
   ALIGN_CHECK_ISPOSITIVE(Rhs);
   return Lhs.value() != Rhs;
 }
 inline bool operator<=(Align Lhs, uint64_t Rhs) {
   ALIGN_CHECK_ISPOSITIVE(Rhs);
   return Lhs.value() <= Rhs;
 }
 inline bool operator>=(Align Lhs, uint64_t Rhs) {
   ALIGN_CHECK_ISPOSITIVE(Rhs);
   return Lhs.value() >= Rhs;
 }
 inline bool operator<(Align Lhs, uint64_t Rhs) {
   ALIGN_CHECK_ISPOSITIVE(Rhs);
   return Lhs.value() < Rhs;
 }
 inline bool operator>(Align Lhs, uint64_t Rhs) {
   ALIGN_CHECK_ISPOSITIVE(Rhs);
   return Lhs.value() > Rhs;
 }

 /// Comparisons between MaybeAlign and scalars.
 inline bool operator==(MaybeAlign Lhs, uint64_t Rhs) {
   return Lhs ? (*Lhs).value() == Rhs : Rhs == 0;
 }
 inline bool operator!=(MaybeAlign Lhs, uint64_t Rhs) {
   return Lhs ? (*Lhs).value() != Rhs : Rhs != 0;
 }

 /// Comparisons operators between Align.
 inline bool operator==(Align Lhs, Align Rhs) {
   return Lhs.ShiftValue == Rhs.ShiftValue;
 }
 inline bool operator!=(Align Lhs, Align Rhs) {
   return Lhs.ShiftValue != Rhs.ShiftValue;
 }
 inline bool operator<=(Align Lhs, Align Rhs) {
   return Lhs.ShiftValue <= Rhs.ShiftValue;
 }
 inline bool operator>=(Align Lhs, Align Rhs) {
   return Lhs.ShiftValue >= Rhs.ShiftValue;
 }
 inline bool operator<(Align Lhs, Align Rhs) {
   return Lhs.ShiftValue < Rhs.ShiftValue;
 }
 inline bool operator>(Align Lhs, Align Rhs) {
   return Lhs.ShiftValue > Rhs.ShiftValue;
 }

 // Don't allow relational comparisons with MaybeAlign.
 bool operator<=(Align Lhs, MaybeAlign Rhs) = delete;
 bool operator>=(Align Lhs, MaybeAlign Rhs) = delete;
 bool operator<(Align Lhs, MaybeAlign Rhs) = delete;
 bool operator>(Align Lhs, MaybeAlign Rhs) = delete;

 bool operator<=(MaybeAlign Lhs, Align Rhs) = delete;
 bool operator>=(MaybeAlign Lhs, Align Rhs) = delete;
 bool operator<(MaybeAlign Lhs, Align Rhs) = delete;
 bool operator>(MaybeAlign Lhs, Align Rhs) = delete;

 bool operator<=(MaybeAlign Lhs, MaybeAlign Rhs) = delete;
 bool operator>=(MaybeAlign Lhs, MaybeAlign Rhs) = delete;
 bool operator<(MaybeAlign Lhs, MaybeAlign Rhs) = delete;
 bool operator>(MaybeAlign Lhs, MaybeAlign Rhs) = delete;

 inline Align operator*(Align Lhs, uint64_t Rhs) {
   assert(Rhs > 0 && "Rhs must be positive");
   return Align(Lhs.value() * Rhs);
 }

 inline MaybeAlign operator*(MaybeAlign Lhs, uint64_t Rhs) {
   assert(Rhs > 0 && "Rhs must be positive");
   return Lhs ? Lhs.getValue() * Rhs : MaybeAlign();
 }

 inline Align operator/(Align Lhs, uint64_t Divisor) {
   assert(llvm::isPowerOf2_64(Divisor) &&
          "Divisor must be positive and a power of 2");
   assert(Lhs != 1 && "Can't halve byte alignment");
   return Align(Lhs.value() / Divisor);
 }

 inline MaybeAlign operator/(MaybeAlign Lhs, uint64_t Divisor) {
   assert(llvm::isPowerOf2_64(Divisor) &&
          "Divisor must be positive and a power of 2");
   return Lhs ? Lhs.getValue() / Divisor : MaybeAlign();
 }

 inline Align max(MaybeAlign Lhs, Align Rhs) {
   return Lhs && *Lhs > Rhs ? *Lhs : Rhs;
 }

 inline Align max(Align Lhs, MaybeAlign Rhs) {
   return Rhs && *Rhs > Lhs ? *Rhs : Lhs;
 }

 #ifndef NDEBUG
 // For usage in LLVM_DEBUG macros.
 inline std::string DebugStr(const Align &A) {
   return std::to_string(A.value());
 }
 // For usage in LLVM_DEBUG macros.
 inline std::string DebugStr(const MaybeAlign &MA) {
   if (MA)
     return std::to_string(MA->value());
   return "None";
 }
 #endif // NDEBUG

 #undef ALIGN_CHECK_ISPOSITIVE

 } // namespace llvm

 #endif // LLVM_SUPPORT_ALIGNMENT_H_
	//===-- llvm/Support/Alignment.h - Useful alignment functions ---- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains types to represent alignments.
	// They are instrumented to guarantee some invariants are preserved and prevent
	// invalid manipulations.
	//
	// - Align represents an alignment in bytes, it is always set and always a valid
	// power of two, its minimum value is 1 which means no alignment requirements.
	//
	// - MaybeAlign is an optional type, it may be undefined or set. When it's set
	// you can get the underlying Align type by using the getValue() method.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_SUPPORT_ALIGNMENT_H_
	#define LLVM_SUPPORT_ALIGNMENT_H_

	#include "llvm/ADT/Optional.h"
	#include "llvm/Support/MathExtras.h"
	#include <cassert>
	#ifndef NDEBUG
	#include <string>
	#endif // NDEBUG

	namespace llvm {

	#define ALIGN_CHECK_ISPOSITIVE(decl) \
	assert(decl > 0 && (#decl " should be defined"))

	/// This struct is a compact representation of a valid (non-zero power of two)
	/// alignment.
	/// It is suitable for use as static global constants.
	struct Align {
	private:
	uint8_t ShiftValue = 0; /// The log2 of the required alignment.
	/// ShiftValue is less than 64 by construction.

	friend struct MaybeAlign;
	friend unsigned Log2(Align);
	friend bool operator==(Align Lhs, Align Rhs);
	friend bool operator!=(Align Lhs, Align Rhs);
	friend bool operator<=(Align Lhs, Align Rhs);
	friend bool operator>=(Align Lhs, Align Rhs);
	friend bool operator<(Align Lhs, Align Rhs);
	friend bool operator>(Align Lhs, Align Rhs);
	friend unsigned encode(struct MaybeAlign A);
	friend struct MaybeAlign decodeMaybeAlign(unsigned Value);

	/// A trivial type to allow construction of constexpr Align.
	/// This is currently needed to workaround a bug in GCC 5.3 which prevents
	/// definition of constexpr assign operators.
	/// https://stackoverflow.com/questions/46756288/explicitly-defaulted-function-cannot-be-declared-as-constexpr-because-the-implic
	/// FIXME: Remove this, make all assign operators constexpr and introduce user
	/// defined literals when we don't have to support GCC 5.3 anymore.
	/// https://llvm.org/docs/GettingStarted.html#getting-a-modern-host-c-toolchain
	struct LogValue {
	uint8_t Log;
	};

	public:
	/// Default is byte-aligned.
	constexpr Align() = default;
	/// Do not perform checks in case of copy/move construct/assign, because the
	/// checks have been performed when building `Other`.
	constexpr Align(const Align &Other) = default;
	constexpr Align(Align &&Other) = default;
	Align &operator=(const Align &Other) = default;
	Align &operator=(Align &&Other) = default;

	explicit Align(uint64_t Value) {
	assert(Value > 0 && "Value must not be 0");
	assert(llvm::isPowerOf2_64(Value) && "Alignment is not a power of 2");
	ShiftValue = Log2_64(Value);
	assert(ShiftValue < 64 && "Broken invariant");
	}

	/// This is a hole in the type system and should not be abused.
	/// Needed to interact with C for instance.
	uint64_t value() const { return uint64_t(1) << ShiftValue; }

	/// Returns a default constructed Align which corresponds to no alignment.
	/// It was decided to deprecate Align::None because it's too close to
	/// llvm::None which can be used to initialize `MaybeAlign`.
	/// MaybeAlign = llvm::None means unspecified alignment,
	/// Align = Align::None() means alignment of one byte.
	LLVM_ATTRIBUTE_DEPRECATED(constexpr static const Align None(),
	"Use Align() or Align(1) instead") {
	return Align();
	}

	/// Allow constructions of constexpr Align.
	template <size_t kValue> constexpr static LogValue Constant() {
	return LogValue{static_cast<uint8_t>(CTLog2<kValue>())};
	}

	/// Allow constructions of constexpr Align from types.
	/// Compile time equivalent to Align(alignof(T)).
	template <typename T> constexpr static LogValue Of() {
	return Constant<std::alignment_of<T>::value>();
	}

	/// Constexpr constructor from LogValue type.
	constexpr Align(LogValue CA) : ShiftValue(CA.Log) {}
	};

	/// Treats the value 0 as a 1, so Align is always at least 1.
	inline Align assumeAligned(uint64_t Value) {
	return Value ? Align(Value) : Align();
	}

	/// This struct is a compact representation of a valid (power of two) or
	/// undefined (0) alignment.
	struct MaybeAlign : public llvm::Optional<Align> {
	private:
	using UP = llvm::Optional<Align>;

	public:
	/// Default is undefined.
	MaybeAlign() = default;
	/// Do not perform checks in case of copy/move construct/assign, because the
	/// checks have been performed when building `Other`.
	MaybeAlign(const MaybeAlign &Other) = default;
	MaybeAlign &operator=(const MaybeAlign &Other) = default;
	MaybeAlign(MaybeAlign &&Other) = default;
	MaybeAlign &operator=(MaybeAlign &&Other) = default;

	/// Use llvm::Optional<Align> constructor.
	using UP::UP;

	explicit MaybeAlign(uint64_t Value) {
	assert((Value == 0 \|\| llvm::isPowerOf2_64(Value)) &&
	"Alignment is neither 0 nor a power of 2");
	if (Value)
	emplace(Value);
	}

	/// For convenience, returns a valid alignment or 1 if undefined.
	Align valueOrOne() const { return hasValue() ? getValue() : Align(); }
	};

	/// Checks that SizeInBytes is a multiple of the alignment.
	inline bool isAligned(Align Lhs, uint64_t SizeInBytes) {
	return SizeInBytes % Lhs.value() == 0;
	}

	/// Checks that Addr is a multiple of the alignment.
	inline bool isAddrAligned(Align Lhs, const void *Addr) {
	return isAligned(Lhs, reinterpret_cast<uintptr_t>(Addr));
	}

	/// Returns a multiple of A needed to store `Size` bytes.
	inline uint64_t alignTo(uint64_t Size, Align A) {
	const uint64_t Value = A.value();
	// The following line is equivalent to `(Size + Value - 1) / Value * Value`.

	// The division followed by a multiplication can be thought of as a right
	// shift followed by a left shift which zeros out the extra bits produced in
	// the bump; `~(Value - 1)` is a mask where all those bits being zeroed out
	// are just zero.

	// Most compilers can generate this code but the pattern may be missed when
	// multiple functions gets inlined.
	return (Size + Value - 1) & ~(Value - 1U);
	}

	/// If non-zero \p Skew is specified, the return value will be a minimal integer
	/// that is greater than or equal to \p Size and equal to \p A * N + \p Skew for
	/// some integer N. If \p Skew is larger than \p A, its value is adjusted to '\p
	/// Skew mod \p A'.
	///
	/// Examples:
	/// \code
	/// alignTo(5, Align(8), 7) = 7
	/// alignTo(17, Align(8), 1) = 17
	/// alignTo(~0LL, Align(8), 3) = 3
	/// \endcode
	inline uint64_t alignTo(uint64_t Size, Align A, uint64_t Skew) {
	const uint64_t Value = A.value();
	Skew %= Value;
	return ((Size + Value - 1 - Skew) & ~(Value - 1U)) + Skew;
	}

	/// Returns a multiple of A needed to store `Size` bytes.
	/// Returns `Size` if current alignment is undefined.
	inline uint64_t alignTo(uint64_t Size, MaybeAlign A) {
	return A ? alignTo(Size, A.getValue()) : Size;
	}

	/// Aligns `Addr` to `Alignment` bytes, rounding up.
	inline uintptr_t alignAddr(const void *Addr, Align Alignment) {
	uintptr_t ArithAddr = reinterpret_cast<uintptr_t>(Addr);
	assert(static_cast<uintptr_t>(ArithAddr + Alignment.value() - 1) >=
	ArithAddr &&
	"Overflow");
	return alignTo(ArithAddr, Alignment);
	}

	/// Returns the offset to the next integer (mod 2**64) that is greater than
	/// or equal to \p Value and is a multiple of \p Align.
	inline uint64_t offsetToAlignment(uint64_t Value, Align Alignment) {
	return alignTo(Value, Alignment) - Value;
	}

	/// Returns the necessary adjustment for aligning `Addr` to `Alignment`
	/// bytes, rounding up.
	inline uint64_t offsetToAlignedAddr(const void *Addr, Align Alignment) {
	return offsetToAlignment(reinterpret_cast<uintptr_t>(Addr), Alignment);
	}

	/// Returns the log2 of the alignment.
	inline unsigned Log2(Align A) { return A.ShiftValue; }

	/// Returns the alignment that satisfies both alignments.
	/// Same semantic as MinAlign.
	inline Align commonAlignment(Align A, Align B) { return std::min(A, B); }

	/// Returns the alignment that satisfies both alignments.
	/// Same semantic as MinAlign.
	inline Align commonAlignment(Align A, uint64_t Offset) {
	return Align(MinAlign(A.value(), Offset));
	}

	/// Returns the alignment that satisfies both alignments.
	/// Same semantic as MinAlign.
	inline MaybeAlign commonAlignment(MaybeAlign A, MaybeAlign B) {
	return A && B ? commonAlignment(A, B) : A ? A : B;
	}

	/// Returns the alignment that satisfies both alignments.
	/// Same semantic as MinAlign.
	inline MaybeAlign commonAlignment(MaybeAlign A, uint64_t Offset) {
	return MaybeAlign(MinAlign((*A).value(), Offset));
	}

	/// Returns a representation of the alignment that encodes undefined as 0.
	inline unsigned encode(MaybeAlign A) { return A ? A->ShiftValue + 1 : 0; }

	/// Dual operation of the encode function above.
	inline MaybeAlign decodeMaybeAlign(unsigned Value) {
	if (Value == 0)
	return MaybeAlign();
	Align Out;
	Out.ShiftValue = Value - 1;
	return Out;
	}

	/// Returns a representation of the alignment, the encoded value is positive by
	/// definition.
	inline unsigned encode(Align A) { return encode(MaybeAlign(A)); }

	/// Comparisons between Align and scalars. Rhs must be positive.
	inline bool operator==(Align Lhs, uint64_t Rhs) {
	ALIGN_CHECK_ISPOSITIVE(Rhs);
	return Lhs.value() == Rhs;
	}
	inline bool operator!=(Align Lhs, uint64_t Rhs) {
	ALIGN_CHECK_ISPOSITIVE(Rhs);
	return Lhs.value() != Rhs;
	}
	inline bool operator<=(Align Lhs, uint64_t Rhs) {
	ALIGN_CHECK_ISPOSITIVE(Rhs);
	return Lhs.value() <= Rhs;
	}
	inline bool operator>=(Align Lhs, uint64_t Rhs) {
	ALIGN_CHECK_ISPOSITIVE(Rhs);
	return Lhs.value() >= Rhs;
	}
	inline bool operator<(Align Lhs, uint64_t Rhs) {
	ALIGN_CHECK_ISPOSITIVE(Rhs);
	return Lhs.value() < Rhs;
	}
	inline bool operator>(Align Lhs, uint64_t Rhs) {
	ALIGN_CHECK_ISPOSITIVE(Rhs);
	return Lhs.value() > Rhs;
	}

	/// Comparisons between MaybeAlign and scalars.
	inline bool operator==(MaybeAlign Lhs, uint64_t Rhs) {
	return Lhs ? (*Lhs).value() == Rhs : Rhs == 0;
	}
	inline bool operator!=(MaybeAlign Lhs, uint64_t Rhs) {
	return Lhs ? (*Lhs).value() != Rhs : Rhs != 0;
	}

	/// Comparisons operators between Align.
	inline bool operator==(Align Lhs, Align Rhs) {
	return Lhs.ShiftValue == Rhs.ShiftValue;
	}
	inline bool operator!=(Align Lhs, Align Rhs) {
	return Lhs.ShiftValue != Rhs.ShiftValue;
	}
	inline bool operator<=(Align Lhs, Align Rhs) {
	return Lhs.ShiftValue <= Rhs.ShiftValue;
	}
	inline bool operator>=(Align Lhs, Align Rhs) {
	return Lhs.ShiftValue >= Rhs.ShiftValue;
	}
	inline bool operator<(Align Lhs, Align Rhs) {
	return Lhs.ShiftValue < Rhs.ShiftValue;
	}
	inline bool operator>(Align Lhs, Align Rhs) {
	return Lhs.ShiftValue > Rhs.ShiftValue;
	}

	// Don't allow relational comparisons with MaybeAlign.
	bool operator<=(Align Lhs, MaybeAlign Rhs) = delete;
	bool operator>=(Align Lhs, MaybeAlign Rhs) = delete;
	bool operator<(Align Lhs, MaybeAlign Rhs) = delete;
	bool operator>(Align Lhs, MaybeAlign Rhs) = delete;

	bool operator<=(MaybeAlign Lhs, Align Rhs) = delete;
	bool operator>=(MaybeAlign Lhs, Align Rhs) = delete;
	bool operator<(MaybeAlign Lhs, Align Rhs) = delete;
	bool operator>(MaybeAlign Lhs, Align Rhs) = delete;

	bool operator<=(MaybeAlign Lhs, MaybeAlign Rhs) = delete;
	bool operator>=(MaybeAlign Lhs, MaybeAlign Rhs) = delete;
	bool operator<(MaybeAlign Lhs, MaybeAlign Rhs) = delete;
	bool operator>(MaybeAlign Lhs, MaybeAlign Rhs) = delete;

	inline Align operator*(Align Lhs, uint64_t Rhs) {
	assert(Rhs > 0 && "Rhs must be positive");
	return Align(Lhs.value() * Rhs);
	}

	inline MaybeAlign operator*(MaybeAlign Lhs, uint64_t Rhs) {
	assert(Rhs > 0 && "Rhs must be positive");
	return Lhs ? Lhs.getValue() * Rhs : MaybeAlign();
	}

	inline Align operator/(Align Lhs, uint64_t Divisor) {
	assert(llvm::isPowerOf2_64(Divisor) &&
	"Divisor must be positive and a power of 2");
	assert(Lhs != 1 && "Can't halve byte alignment");
	return Align(Lhs.value() / Divisor);
	}

	inline MaybeAlign operator/(MaybeAlign Lhs, uint64_t Divisor) {
	assert(llvm::isPowerOf2_64(Divisor) &&
	"Divisor must be positive and a power of 2");
	return Lhs ? Lhs.getValue() / Divisor : MaybeAlign();
	}

	inline Align max(MaybeAlign Lhs, Align Rhs) {
	return Lhs && Lhs > Rhs ? Lhs : Rhs;
	}

	inline Align max(Align Lhs, MaybeAlign Rhs) {
	return Rhs && Rhs > Lhs ? Rhs : Lhs;
	}

	#ifndef NDEBUG
	// For usage in LLVM_DEBUG macros.
	inline std::string DebugStr(const Align &A) {
	return std::to_string(A.value());
	}
	// For usage in LLVM_DEBUG macros.
	inline std::string DebugStr(const MaybeAlign &MA) {
	if (MA)
	return std::to_string(MA->value());
	return "None";
	}
	#endif // NDEBUG

	#undef ALIGN_CHECK_ISPOSITIVE

	} // namespace llvm

	#endif // LLVM_SUPPORT_ALIGNMENT_H_