clang-r468909b/include/clang/Analysis/FlowSensitive/MapLattice.h - platform/prebuilts/clang/host/darwin-x86 - Git at Google

 //===------------------------ MapLattice.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
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file defines a parameterized lattice that maps keys to individual
 //  lattice elements (of the parameter lattice type). A typical usage is lifting
 //  a particular lattice to all variables in a lexical scope.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_ANALYSIS_FLOWSENSITIVE__MAPLATTICE_H
 #define LLVM_CLANG_ANALYSIS_FLOWSENSITIVE__MAPLATTICE_H

 #include <ostream>
 #include <string>
 #include <utility>

 #include "DataflowAnalysis.h"
 #include "clang/AST/Decl.h"
 #include "clang/Analysis/FlowSensitive/DataflowLattice.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/StringRef.h"

 namespace clang {
 namespace dataflow {

 /// A lattice that maps keys to individual lattice elements. When instantiated
 /// with an `ElementLattice` that is a bounded semi-lattice, `MapLattice` is
 /// itself a bounded semi-lattice, so long as the user limits themselves to a
 /// finite number of keys. In that case, `top` is (implicitly), the map
 /// containing all valid keys mapped to `top` of `ElementLattice`.
 ///
 /// Requirements on `ElementLattice`:
 /// * Provides standard declarations of a bounded semi-lattice.
 template <typename Key, typename ElementLattice> class MapLattice {
   using Container = llvm::DenseMap<Key, ElementLattice>;
   Container C;

 public:
   using key_type = Key;
   using mapped_type = ElementLattice;
   using value_type = typename Container::value_type;
   using iterator = typename Container::iterator;
   using const_iterator = typename Container::const_iterator;

   MapLattice() = default;

   explicit MapLattice(Container C) { C = std::move(C); }

   // The `bottom` element is the empty map.
   static MapLattice bottom() { return MapLattice(); }

   std::pair<iterator, bool>
   insert(const std::pair<const key_type, mapped_type> &P) {
     return C.insert(P);
   }

   std::pair<iterator, bool> insert(std::pair<const key_type, mapped_type> &&P) {
     return C.insert(std::move(P));
   }

   unsigned size() const { return C.size(); }
   bool empty() const { return C.empty(); }

   iterator begin() { return C.begin(); }
   iterator end() { return C.end(); }
   const_iterator begin() const { return C.begin(); }
   const_iterator end() const { return C.end(); }

   // Equality is direct equality of underlying map entries. One implication of
   // this definition is that a map with (only) keys that map to bottom is not
   // equal to the empty map.
   friend bool operator==(const MapLattice &LHS, const MapLattice &RHS) {
     return LHS.C == RHS.C;
   }

   friend bool operator!=(const MapLattice &LHS, const MapLattice &RHS) {
     return !(LHS == RHS);
   }

   bool contains(const key_type &K) const { return C.find(K) != C.end(); }

   iterator find(const key_type &K) { return C.find(K); }
   const_iterator find(const key_type &K) const { return C.find(K); }

   mapped_type &operator[](const key_type &K) { return C[K]; }

   /// If an entry exists in one map but not the other, the missing entry is
   /// treated as implicitly mapping to `bottom`. So, the joined map contains the
   /// entry as it was in the source map.
   LatticeJoinEffect join(const MapLattice &Other) {
     LatticeJoinEffect Effect = LatticeJoinEffect::Unchanged;
     for (const auto &O : Other.C) {
       auto It = C.find(O.first);
       if (It == C.end()) {
         C.insert(O);
         Effect = LatticeJoinEffect::Changed;
       } else if (It->second.join(O.second) == LatticeJoinEffect::Changed)
         Effect = LatticeJoinEffect::Changed;
     }
     return Effect;
   }
 };

 /// Convenience alias that captures the common use of map lattices to model
 /// in-scope variables.
 template <typename ElementLattice>
 using VarMapLattice = MapLattice<const clang::VarDecl *, ElementLattice>;

 template <typename Key, typename ElementLattice>
 std::ostream &
 operator<<(std::ostream &Os,
            const clang::dataflow::MapLattice<Key, ElementLattice> &M) {
   std::string Separator;
   Os << "{";
   for (const auto &E : M) {
     Os << std::exchange(Separator, ", ") << E.first << " => " << E.second;
   }
   Os << "}";
   return Os;
 }

 template <typename ElementLattice>
 std::ostream &
 operator<<(std::ostream &Os,
            const clang::dataflow::VarMapLattice<ElementLattice> &M) {
   std::string Separator;
   Os << "{";
   for (const auto &E : M) {
     Os << std::exchange(Separator, ", ") << E.first->getName().str() << " => "
        << E.second;
   }
   Os << "}";
   return Os;
 }
 } // namespace dataflow
 } // namespace clang

 #endif // LLVM_CLANG_ANALYSIS_FLOWSENSITIVE__MAPLATTICE_H
	//===------------------------ MapLattice.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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines a parameterized lattice that maps keys to individual
	// lattice elements (of the parameter lattice type). A typical usage is lifting
	// a particular lattice to all variables in a lexical scope.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_ANALYSIS_FLOWSENSITIVE__MAPLATTICE_H
	#define LLVM_CLANG_ANALYSIS_FLOWSENSITIVE__MAPLATTICE_H

	#include <ostream>
	#include <string>
	#include <utility>

	#include "DataflowAnalysis.h"
	#include "clang/AST/Decl.h"
	#include "clang/Analysis/FlowSensitive/DataflowLattice.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/StringRef.h"

	namespace clang {
	namespace dataflow {

	/// A lattice that maps keys to individual lattice elements. When instantiated
	/// with an `ElementLattice` that is a bounded semi-lattice, `MapLattice` is
	/// itself a bounded semi-lattice, so long as the user limits themselves to a
	/// finite number of keys. In that case, `top` is (implicitly), the map
	/// containing all valid keys mapped to `top` of `ElementLattice`.
	///
	/// Requirements on `ElementLattice`:
	/// * Provides standard declarations of a bounded semi-lattice.
	template <typename Key, typename ElementLattice> class MapLattice {
	using Container = llvm::DenseMap<Key, ElementLattice>;
	Container C;

	public:
	using key_type = Key;
	using mapped_type = ElementLattice;
	using value_type = typename Container::value_type;
	using iterator = typename Container::iterator;
	using const_iterator = typename Container::const_iterator;

	MapLattice() = default;

	explicit MapLattice(Container C) { C = std::move(C); }

	// The `bottom` element is the empty map.
	static MapLattice bottom() { return MapLattice(); }

	std::pair<iterator, bool>
	insert(const std::pair<const key_type, mapped_type> &P) {
	return C.insert(P);
	}

	std::pair<iterator, bool> insert(std::pair<const key_type, mapped_type> &&P) {
	return C.insert(std::move(P));
	}

	unsigned size() const { return C.size(); }
	bool empty() const { return C.empty(); }

	iterator begin() { return C.begin(); }
	iterator end() { return C.end(); }
	const_iterator begin() const { return C.begin(); }
	const_iterator end() const { return C.end(); }

	// Equality is direct equality of underlying map entries. One implication of
	// this definition is that a map with (only) keys that map to bottom is not
	// equal to the empty map.
	friend bool operator==(const MapLattice &LHS, const MapLattice &RHS) {
	return LHS.C == RHS.C;
	}

	friend bool operator!=(const MapLattice &LHS, const MapLattice &RHS) {
	return !(LHS == RHS);
	}

	bool contains(const key_type &K) const { return C.find(K) != C.end(); }

	iterator find(const key_type &K) { return C.find(K); }
	const_iterator find(const key_type &K) const { return C.find(K); }

	mapped_type &operator[](const key_type &K) { return C[K]; }

	/// If an entry exists in one map but not the other, the missing entry is
	/// treated as implicitly mapping to `bottom`. So, the joined map contains the
	/// entry as it was in the source map.
	LatticeJoinEffect join(const MapLattice &Other) {
	LatticeJoinEffect Effect = LatticeJoinEffect::Unchanged;
	for (const auto &O : Other.C) {
	auto It = C.find(O.first);
	if (It == C.end()) {
	C.insert(O);
	Effect = LatticeJoinEffect::Changed;
	} else if (It->second.join(O.second) == LatticeJoinEffect::Changed)
	Effect = LatticeJoinEffect::Changed;
	}
	return Effect;
	}
	};

	/// Convenience alias that captures the common use of map lattices to model
	/// in-scope variables.
	template <typename ElementLattice>
	using VarMapLattice = MapLattice<const clang::VarDecl *, ElementLattice>;

	template <typename Key, typename ElementLattice>
	std::ostream &
	operator<<(std::ostream &Os,
	const clang::dataflow::MapLattice<Key, ElementLattice> &M) {
	std::string Separator;
	Os << "{";
	for (const auto &E : M) {
	Os << std::exchange(Separator, ", ") << E.first << " => " << E.second;
	}
	Os << "}";
	return Os;
	}

	template <typename ElementLattice>
	std::ostream &
	operator<<(std::ostream &Os,
	const clang::dataflow::VarMapLattice<ElementLattice> &M) {
	std::string Separator;
	Os << "{";
	for (const auto &E : M) {
	Os << std::exchange(Separator, ", ") << E.first->getName().str() << " => "
	<< E.second;
	}
	Os << "}";
	return Os;
	}
	} // namespace dataflow
	} // namespace clang

	#endif // LLVM_CLANG_ANALYSIS_FLOWSENSITIVE__MAPLATTICE_H