include/llvm/Analysis/MemoryLocation.h - toolchain/llvm - Git at Google

 //===- MemoryLocation.h - Memory location descriptions ----------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 /// \file
 /// This file provides utility analysis objects describing memory locations.
 /// These are used both by the Alias Analysis infrastructure and more
 /// specialized memory analysis layers.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ANALYSIS_MEMORYLOCATION_H
 #define LLVM_ANALYSIS_MEMORYLOCATION_H

 #include "llvm/ADT/Optional.h"
 #include "llvm/ADT/DenseMapInfo.h"
 #include "llvm/IR/CallSite.h"
 #include "llvm/IR/Metadata.h"

 namespace llvm {

 class LoadInst;
 class StoreInst;
 class MemTransferInst;
 class MemIntrinsic;
 class AtomicMemTransferInst;
 class AtomicMemIntrinsic;
 class AnyMemTransferInst;
 class AnyMemIntrinsic;
 class TargetLibraryInfo;

 // Represents the size of a MemoryLocation. Logically, it's an
 // Optional<uint63_t> that also carries a bit to represent whether the integer
 // it contains, N, is 'precise'. Precise, in this context, means that we know
 // that the area of storage referenced by the given MemoryLocation must be
 // precisely N bytes. An imprecise value is formed as the union of two or more
 // precise values, and can conservatively represent all of the values unioned
 // into it. Importantly, imprecise values are an *upper-bound* on the size of a
 // MemoryLocation.
 //
 // Concretely, a precise MemoryLocation is (%p, 4) in
 // store i32 0, i32* %p
 //
 // Since we know that %p must be at least 4 bytes large at this point.
 // Otherwise, we have UB. An example of an imprecise MemoryLocation is (%p, 4)
 // at the memcpy in
 //
 //   %n = select i1 %foo, i64 1, i64 4
 //   call void @llvm.memcpy.p0i8.p0i8.i64(i8* %p, i8* %baz, i64 %n, i32 1,
 //                                        i1 false)
 //
 // ...Since we'll copy *up to* 4 bytes into %p, but we can't guarantee that
 // we'll ever actually do so.
 //
 // If asked to represent a pathologically large value, this will degrade to
 // None.
 class LocationSize {
   enum : uint64_t {
     Unknown = ~uint64_t(0),
     ImpreciseBit = uint64_t(1) << 63,
     MapEmpty = Unknown - 1,
     MapTombstone = Unknown - 2,

     // The maximum value we can represent without falling back to 'unknown'.
     MaxValue = (MapTombstone - 1) & ~ImpreciseBit,
   };

   uint64_t Value;

   // Hack to support implicit construction. This should disappear when the
   // public LocationSize ctor goes away.
   enum DirectConstruction { Direct };

   constexpr LocationSize(uint64_t Raw, DirectConstruction): Value(Raw) {}

   static_assert(Unknown & ImpreciseBit, "Unknown is imprecise by definition.");
 public:
   // FIXME: Migrate all users to construct via either `precise` or `upperBound`,
   // to make it more obvious at the callsite the kind of size that they're
   // providing.
   //
   // Since the overwhelming majority of users of this provide precise values,
   // this assumes the provided value is precise.
   constexpr LocationSize(uint64_t Raw)
       : Value(Raw > MaxValue ? Unknown : Raw) {}

   static LocationSize precise(uint64_t Value) { return LocationSize(Value); }

   static LocationSize upperBound(uint64_t Value) {
     // You can't go lower than 0, so give a precise result.
     if (LLVM_UNLIKELY(Value == 0))
       return precise(0);
     if (LLVM_UNLIKELY(Value > MaxValue))
       return unknown();
     return LocationSize(Value | ImpreciseBit, Direct);
   }

   constexpr static LocationSize unknown() {
     return LocationSize(Unknown, Direct);
   }

   // Sentinel values, generally used for maps.
   constexpr static LocationSize mapTombstone() {
     return LocationSize(MapTombstone, Direct);
   }
   constexpr static LocationSize mapEmpty() {
     return LocationSize(MapEmpty, Direct);
   }

   // Returns a LocationSize that can correctly represent either `*this` or
   // `Other`.
   LocationSize unionWith(LocationSize Other) const {
     if (Other == *this)
       return *this;

     if (!hasValue() || !Other.hasValue())
       return unknown();

     return upperBound(std::max(getValue(), Other.getValue()));
   }

   bool hasValue() const { return Value != Unknown; }
   uint64_t getValue() const {
     assert(hasValue() && "Getting value from an unknown LocationSize!");
     return Value & ~ImpreciseBit;
   }

   // Returns whether or not this value is precise. Note that if a value is
   // precise, it's guaranteed to not be `unknown()`.
   bool isPrecise() const {
     return (Value & ImpreciseBit) == 0;
   }

   bool operator==(const LocationSize &Other) const {
     return Value == Other.Value;
   }

   bool operator!=(const LocationSize &Other) const {
     return !(*this == Other);
   }

   // Ordering operators are not provided, since it's unclear if there's only one
   // reasonable way to compare:
   // - values that don't exist against values that do, and
   // - precise values to imprecise values

   void print(raw_ostream &OS) const;

   // Returns an opaque value that represents this LocationSize. Cannot be
   // reliably converted back into a LocationSize.
   uint64_t toRaw() const { return Value; }
 };

 inline raw_ostream &operator<<(raw_ostream &OS, LocationSize Size) {
   Size.print(OS);
   return OS;
 }

 /// Representation for a specific memory location.
 ///
 /// This abstraction can be used to represent a specific location in memory.
 /// The goal of the location is to represent enough information to describe
 /// abstract aliasing, modification, and reference behaviors of whatever
 /// value(s) are stored in memory at the particular location.
 ///
 /// The primary user of this interface is LLVM's Alias Analysis, but other
 /// memory analyses such as MemoryDependence can use it as well.
 class MemoryLocation {
 public:
   /// UnknownSize - This is a special value which can be used with the
   /// size arguments in alias queries to indicate that the caller does not
   /// know the sizes of the potential memory references.
   enum : uint64_t { UnknownSize = ~UINT64_C(0) };

   /// The address of the start of the location.
   const Value *Ptr;

   /// The maximum size of the location, in address-units, or
   /// UnknownSize if the size is not known.
   ///
   /// Note that an unknown size does not mean the pointer aliases the entire
   /// virtual address space, because there are restrictions on stepping out of
   /// one object and into another. See
   /// http://llvm.org/docs/LangRef.html#pointeraliasing
   LocationSize Size;

   /// The metadata nodes which describes the aliasing of the location (each
   /// member is null if that kind of information is unavailable).
   AAMDNodes AATags;

   /// Return a location with information about the memory reference by the given
   /// instruction.
   static MemoryLocation get(const LoadInst *LI);
   static MemoryLocation get(const StoreInst *SI);
   static MemoryLocation get(const VAArgInst *VI);
   static MemoryLocation get(const AtomicCmpXchgInst *CXI);
   static MemoryLocation get(const AtomicRMWInst *RMWI);
   static MemoryLocation get(const Instruction *Inst) {
     return *MemoryLocation::getOrNone(Inst);
   }
   static Optional<MemoryLocation> getOrNone(const Instruction *Inst) {
     switch (Inst->getOpcode()) {
     case Instruction::Load:
       return get(cast<LoadInst>(Inst));
     case Instruction::Store:
       return get(cast<StoreInst>(Inst));
     case Instruction::VAArg:
       return get(cast<VAArgInst>(Inst));
     case Instruction::AtomicCmpXchg:
       return get(cast<AtomicCmpXchgInst>(Inst));
     case Instruction::AtomicRMW:
       return get(cast<AtomicRMWInst>(Inst));
     default:
       return None;
     }
   }

   /// Return a location representing the source of a memory transfer.
   static MemoryLocation getForSource(const MemTransferInst *MTI);
   static MemoryLocation getForSource(const AtomicMemTransferInst *MTI);
   static MemoryLocation getForSource(const AnyMemTransferInst *MTI);

   /// Return a location representing the destination of a memory set or
   /// transfer.
   static MemoryLocation getForDest(const MemIntrinsic *MI);
   static MemoryLocation getForDest(const AtomicMemIntrinsic *MI);
   static MemoryLocation getForDest(const AnyMemIntrinsic *MI);

   /// Return a location representing a particular argument of a call.
   static MemoryLocation getForArgument(ImmutableCallSite CS, unsigned ArgIdx,
                                        const TargetLibraryInfo *TLI);
   static MemoryLocation getForArgument(ImmutableCallSite CS, unsigned ArgIdx,
                                        const TargetLibraryInfo &TLI) {
     return getForArgument(CS, ArgIdx, &TLI);
   }

   explicit MemoryLocation(const Value *Ptr = nullptr,
                           LocationSize Size = UnknownSize,
                           const AAMDNodes &AATags = AAMDNodes())
       : Ptr(Ptr), Size(Size), AATags(AATags) {}

   MemoryLocation getWithNewPtr(const Value *NewPtr) const {
     MemoryLocation Copy(*this);
     Copy.Ptr = NewPtr;
     return Copy;
   }

   MemoryLocation getWithNewSize(LocationSize NewSize) const {
     MemoryLocation Copy(*this);
     Copy.Size = NewSize;
     return Copy;
   }

   MemoryLocation getWithoutAATags() const {
     MemoryLocation Copy(*this);
     Copy.AATags = AAMDNodes();
     return Copy;
   }

   bool operator==(const MemoryLocation &Other) const {
     return Ptr == Other.Ptr && Size == Other.Size && AATags == Other.AATags;
   }
 };

 // Specialize DenseMapInfo.
 template <> struct DenseMapInfo<LocationSize> {
   static inline LocationSize getEmptyKey() {
     return LocationSize::mapEmpty();
   }
   static inline LocationSize getTombstoneKey() {
     return LocationSize::mapTombstone();
   }
   static unsigned getHashValue(const LocationSize &Val) {
     return DenseMapInfo<uint64_t>::getHashValue(Val.toRaw());
   }
   static bool isEqual(const LocationSize &LHS, const LocationSize &RHS) {
     return LHS == RHS;
   }
 };

 template <> struct DenseMapInfo<MemoryLocation> {
   static inline MemoryLocation getEmptyKey() {
     return MemoryLocation(DenseMapInfo<const Value *>::getEmptyKey(),
                           DenseMapInfo<LocationSize>::getEmptyKey());
   }
   static inline MemoryLocation getTombstoneKey() {
     return MemoryLocation(DenseMapInfo<const Value *>::getTombstoneKey(),
                           DenseMapInfo<LocationSize>::getTombstoneKey());
   }
   static unsigned getHashValue(const MemoryLocation &Val) {
     return DenseMapInfo<const Value *>::getHashValue(Val.Ptr) ^
            DenseMapInfo<LocationSize>::getHashValue(Val.Size) ^
            DenseMapInfo<AAMDNodes>::getHashValue(Val.AATags);
   }
   static bool isEqual(const MemoryLocation &LHS, const MemoryLocation &RHS) {
     return LHS == RHS;
   }
 };
 }

 #endif
	//===- MemoryLocation.h - Memory location descriptions ----------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	/// \file
	/// This file provides utility analysis objects describing memory locations.
	/// These are used both by the Alias Analysis infrastructure and more
	/// specialized memory analysis layers.
	///
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ANALYSIS_MEMORYLOCATION_H
	#define LLVM_ANALYSIS_MEMORYLOCATION_H

	#include "llvm/ADT/Optional.h"
	#include "llvm/ADT/DenseMapInfo.h"
	#include "llvm/IR/CallSite.h"
	#include "llvm/IR/Metadata.h"

	namespace llvm {

	class LoadInst;
	class StoreInst;
	class MemTransferInst;
	class MemIntrinsic;
	class AtomicMemTransferInst;
	class AtomicMemIntrinsic;
	class AnyMemTransferInst;
	class AnyMemIntrinsic;
	class TargetLibraryInfo;

	// Represents the size of a MemoryLocation. Logically, it's an
	// Optional<uint63_t> that also carries a bit to represent whether the integer
	// it contains, N, is 'precise'. Precise, in this context, means that we know
	// that the area of storage referenced by the given MemoryLocation must be
	// precisely N bytes. An imprecise value is formed as the union of two or more
	// precise values, and can conservatively represent all of the values unioned
	// into it. Importantly, imprecise values are an upper-bound on the size of a
	// MemoryLocation.
	//
	// Concretely, a precise MemoryLocation is (%p, 4) in
	// store i32 0, i32* %p
	//
	// Since we know that %p must be at least 4 bytes large at this point.
	// Otherwise, we have UB. An example of an imprecise MemoryLocation is (%p, 4)
	// at the memcpy in
	//
	// %n = select i1 %foo, i64 1, i64 4
	// call void @llvm.memcpy.p0i8.p0i8.i64(i8* %p, i8* %baz, i64 %n, i32 1,
	// i1 false)
	//
	// ...Since we'll copy up to 4 bytes into %p, but we can't guarantee that
	// we'll ever actually do so.
	//
	// If asked to represent a pathologically large value, this will degrade to
	// None.
	class LocationSize {
	enum : uint64_t {
	Unknown = ~uint64_t(0),
	ImpreciseBit = uint64_t(1) << 63,
	MapEmpty = Unknown - 1,
	MapTombstone = Unknown - 2,

	// The maximum value we can represent without falling back to 'unknown'.
	MaxValue = (MapTombstone - 1) & ~ImpreciseBit,
	};

	uint64_t Value;

	// Hack to support implicit construction. This should disappear when the
	// public LocationSize ctor goes away.
	enum DirectConstruction { Direct };

	constexpr LocationSize(uint64_t Raw, DirectConstruction): Value(Raw) {}

	static_assert(Unknown & ImpreciseBit, "Unknown is imprecise by definition.");
	public:
	// FIXME: Migrate all users to construct via either `precise` or `upperBound`,
	// to make it more obvious at the callsite the kind of size that they're
	// providing.
	//
	// Since the overwhelming majority of users of this provide precise values,
	// this assumes the provided value is precise.
	constexpr LocationSize(uint64_t Raw)
	: Value(Raw > MaxValue ? Unknown : Raw) {}

	static LocationSize precise(uint64_t Value) { return LocationSize(Value); }

	static LocationSize upperBound(uint64_t Value) {
	// You can't go lower than 0, so give a precise result.
	if (LLVM_UNLIKELY(Value == 0))
	return precise(0);
	if (LLVM_UNLIKELY(Value > MaxValue))
	return unknown();
	return LocationSize(Value \| ImpreciseBit, Direct);
	}

	constexpr static LocationSize unknown() {
	return LocationSize(Unknown, Direct);
	}

	// Sentinel values, generally used for maps.
	constexpr static LocationSize mapTombstone() {
	return LocationSize(MapTombstone, Direct);
	}
	constexpr static LocationSize mapEmpty() {
	return LocationSize(MapEmpty, Direct);
	}

	// Returns a LocationSize that can correctly represent either `*this` or
	// `Other`.
	LocationSize unionWith(LocationSize Other) const {
	if (Other == *this)
	return *this;

	if (!hasValue() \|\| !Other.hasValue())
	return unknown();

	return upperBound(std::max(getValue(), Other.getValue()));
	}

	bool hasValue() const { return Value != Unknown; }
	uint64_t getValue() const {
	assert(hasValue() && "Getting value from an unknown LocationSize!");
	return Value & ~ImpreciseBit;
	}

	// Returns whether or not this value is precise. Note that if a value is
	// precise, it's guaranteed to not be `unknown()`.
	bool isPrecise() const {
	return (Value & ImpreciseBit) == 0;
	}

	bool operator==(const LocationSize &Other) const {
	return Value == Other.Value;
	}

	bool operator!=(const LocationSize &Other) const {
	return !(*this == Other);
	}

	// Ordering operators are not provided, since it's unclear if there's only one
	// reasonable way to compare:
	// - values that don't exist against values that do, and
	// - precise values to imprecise values

	void print(raw_ostream &OS) const;

	// Returns an opaque value that represents this LocationSize. Cannot be
	// reliably converted back into a LocationSize.
	uint64_t toRaw() const { return Value; }
	};

	inline raw_ostream &operator<<(raw_ostream &OS, LocationSize Size) {
	Size.print(OS);
	return OS;
	}

	/// Representation for a specific memory location.
	///
	/// This abstraction can be used to represent a specific location in memory.
	/// The goal of the location is to represent enough information to describe
	/// abstract aliasing, modification, and reference behaviors of whatever
	/// value(s) are stored in memory at the particular location.
	///
	/// The primary user of this interface is LLVM's Alias Analysis, but other
	/// memory analyses such as MemoryDependence can use it as well.
	class MemoryLocation {
	public:
	/// UnknownSize - This is a special value which can be used with the
	/// size arguments in alias queries to indicate that the caller does not
	/// know the sizes of the potential memory references.
	enum : uint64_t { UnknownSize = ~UINT64_C(0) };

	/// The address of the start of the location.
	const Value *Ptr;

	/// The maximum size of the location, in address-units, or
	/// UnknownSize if the size is not known.
	///
	/// Note that an unknown size does not mean the pointer aliases the entire
	/// virtual address space, because there are restrictions on stepping out of
	/// one object and into another. See
	/// http://llvm.org/docs/LangRef.html#pointeraliasing
	LocationSize Size;

	/// The metadata nodes which describes the aliasing of the location (each
	/// member is null if that kind of information is unavailable).
	AAMDNodes AATags;

	/// Return a location with information about the memory reference by the given
	/// instruction.
	static MemoryLocation get(const LoadInst *LI);
	static MemoryLocation get(const StoreInst *SI);
	static MemoryLocation get(const VAArgInst *VI);
	static MemoryLocation get(const AtomicCmpXchgInst *CXI);
	static MemoryLocation get(const AtomicRMWInst *RMWI);
	static MemoryLocation get(const Instruction *Inst) {
	return *MemoryLocation::getOrNone(Inst);
	}
	static Optional<MemoryLocation> getOrNone(const Instruction *Inst) {
	switch (Inst->getOpcode()) {
	case Instruction::Load:
	return get(cast<LoadInst>(Inst));
	case Instruction::Store:
	return get(cast<StoreInst>(Inst));
	case Instruction::VAArg:
	return get(cast<VAArgInst>(Inst));
	case Instruction::AtomicCmpXchg:
	return get(cast<AtomicCmpXchgInst>(Inst));
	case Instruction::AtomicRMW:
	return get(cast<AtomicRMWInst>(Inst));
	default:
	return None;
	}
	}

	/// Return a location representing the source of a memory transfer.
	static MemoryLocation getForSource(const MemTransferInst *MTI);
	static MemoryLocation getForSource(const AtomicMemTransferInst *MTI);
	static MemoryLocation getForSource(const AnyMemTransferInst *MTI);

	/// Return a location representing the destination of a memory set or
	/// transfer.
	static MemoryLocation getForDest(const MemIntrinsic *MI);
	static MemoryLocation getForDest(const AtomicMemIntrinsic *MI);
	static MemoryLocation getForDest(const AnyMemIntrinsic *MI);

	/// Return a location representing a particular argument of a call.
	static MemoryLocation getForArgument(ImmutableCallSite CS, unsigned ArgIdx,
	const TargetLibraryInfo *TLI);
	static MemoryLocation getForArgument(ImmutableCallSite CS, unsigned ArgIdx,
	const TargetLibraryInfo &TLI) {
	return getForArgument(CS, ArgIdx, &TLI);
	}

	explicit MemoryLocation(const Value *Ptr = nullptr,
	LocationSize Size = UnknownSize,
	const AAMDNodes &AATags = AAMDNodes())
	: Ptr(Ptr), Size(Size), AATags(AATags) {}

	MemoryLocation getWithNewPtr(const Value *NewPtr) const {
	MemoryLocation Copy(*this);
	Copy.Ptr = NewPtr;
	return Copy;
	}

	MemoryLocation getWithNewSize(LocationSize NewSize) const {
	MemoryLocation Copy(*this);
	Copy.Size = NewSize;
	return Copy;
	}

	MemoryLocation getWithoutAATags() const {
	MemoryLocation Copy(*this);
	Copy.AATags = AAMDNodes();
	return Copy;
	}

	bool operator==(const MemoryLocation &Other) const {
	return Ptr == Other.Ptr && Size == Other.Size && AATags == Other.AATags;
	}
	};

	// Specialize DenseMapInfo.
	template <> struct DenseMapInfo<LocationSize> {
	static inline LocationSize getEmptyKey() {
	return LocationSize::mapEmpty();
	}
	static inline LocationSize getTombstoneKey() {
	return LocationSize::mapTombstone();
	}
	static unsigned getHashValue(const LocationSize &Val) {
	return DenseMapInfo<uint64_t>::getHashValue(Val.toRaw());
	}
	static bool isEqual(const LocationSize &LHS, const LocationSize &RHS) {
	return LHS == RHS;
	}
	};

	template <> struct DenseMapInfo<MemoryLocation> {
	static inline MemoryLocation getEmptyKey() {
	return MemoryLocation(DenseMapInfo<const Value *>::getEmptyKey(),
	DenseMapInfo<LocationSize>::getEmptyKey());
	}
	static inline MemoryLocation getTombstoneKey() {
	return MemoryLocation(DenseMapInfo<const Value *>::getTombstoneKey(),
	DenseMapInfo<LocationSize>::getTombstoneKey());
	}
	static unsigned getHashValue(const MemoryLocation &Val) {
	return DenseMapInfo<const Value *>::getHashValue(Val.Ptr) ^
	DenseMapInfo<LocationSize>::getHashValue(Val.Size) ^
	DenseMapInfo<AAMDNodes>::getHashValue(Val.AATags);
	}
	static bool isEqual(const MemoryLocation &LHS, const MemoryLocation &RHS) {
	return LHS == RHS;
	}
	};
	}

	#endif