clang-r437112/include/clang/Analysis/Analyses/ThreadSafetyUtil.h - platform/prebuilts/clang/host/darwin-x86 - Git at Google

 //===- ThreadSafetyUtil.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 some basic utility classes for use by ThreadSafetyTIL.h
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_ANALYSIS_ANALYSES_THREADSAFETYUTIL_H
 #define LLVM_CLANG_ANALYSIS_ANALYSES_THREADSAFETYUTIL_H

 #include "clang/AST/Decl.h"
 #include "clang/Basic/LLVM.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/ADT/iterator_range.h"
 #include "llvm/Support/Allocator.h"
 #include <cassert>
 #include <cstddef>
 #include <cstring>
 #include <iterator>
 #include <ostream>
 #include <string>
 #include <vector>

 namespace clang {

 class Expr;

 namespace threadSafety {
 namespace til {

 // Simple wrapper class to abstract away from the details of memory management.
 // SExprs are allocated in pools, and deallocated all at once.
 class MemRegionRef {
 private:
   union AlignmentType {
     double d;
     void *p;
     long double dd;
     long long ii;
   };

 public:
   MemRegionRef() = default;
   MemRegionRef(llvm::BumpPtrAllocator *A) : Allocator(A) {}

   void *allocate(size_t Sz) {
     return Allocator->Allocate(Sz, alignof(AlignmentType));
   }

   template <typename T> T *allocateT() { return Allocator->Allocate<T>(); }

   template <typename T> T *allocateT(size_t NumElems) {
     return Allocator->Allocate<T>(NumElems);
   }

 private:
   llvm::BumpPtrAllocator *Allocator = nullptr;
 };

 } // namespace til
 } // namespace threadSafety

 } // namespace clang

 inline void *operator new(size_t Sz,
                           clang::threadSafety::til::MemRegionRef &R) {
   return R.allocate(Sz);
 }

 namespace clang {
 namespace threadSafety {

 std::string getSourceLiteralString(const Expr *CE);

 namespace til {

 // A simple fixed size array class that does not manage its own memory,
 // suitable for use with bump pointer allocation.
 template <class T> class SimpleArray {
 public:
   SimpleArray() = default;
   SimpleArray(T *Dat, size_t Cp, size_t Sz = 0)
       : Data(Dat), Size(Sz), Capacity(Cp) {}
   SimpleArray(MemRegionRef A, size_t Cp)
       : Data(Cp == 0 ? nullptr : A.allocateT<T>(Cp)), Capacity(Cp) {}
   SimpleArray(const SimpleArray<T> &A) = delete;

   SimpleArray(SimpleArray<T> &&A)
       : Data(A.Data), Size(A.Size), Capacity(A.Capacity) {
     A.Data = nullptr;
     A.Size = 0;
     A.Capacity = 0;
   }

   SimpleArray &operator=(SimpleArray &&RHS) {
     if (this != &RHS) {
       Data = RHS.Data;
       Size = RHS.Size;
       Capacity = RHS.Capacity;

       RHS.Data = nullptr;
       RHS.Size = RHS.Capacity = 0;
     }
     return *this;
   }

   // Reserve space for at least Ncp items, reallocating if necessary.
   void reserve(size_t Ncp, MemRegionRef A) {
     if (Ncp <= Capacity)
       return;
     T *Odata = Data;
     Data = A.allocateT<T>(Ncp);
     Capacity = Ncp;
     memcpy(Data, Odata, sizeof(T) * Size);
   }

   // Reserve space for at least N more items.
   void reserveCheck(size_t N, MemRegionRef A) {
     if (Capacity == 0)
       reserve(u_max(InitialCapacity, N), A);
     else if (Size + N < Capacity)
       reserve(u_max(Size + N, Capacity * 2), A);
   }

   using iterator = T *;
   using const_iterator = const T *;
   using reverse_iterator = std::reverse_iterator<iterator>;
   using const_reverse_iterator = std::reverse_iterator<const_iterator>;

   size_t size() const { return Size; }
   size_t capacity() const { return Capacity; }

   T &operator[](unsigned i) {
     assert(i < Size && "Array index out of bounds.");
     return Data[i];
   }

   const T &operator[](unsigned i) const {
     assert(i < Size && "Array index out of bounds.");
     return Data[i];
   }

   T &back() {
     assert(Size && "No elements in the array.");
     return Data[Size - 1];
   }

   const T &back() const {
     assert(Size && "No elements in the array.");
     return Data[Size - 1];
   }

   iterator begin() { return Data; }
   iterator end() { return Data + Size; }

   const_iterator begin() const { return Data; }
   const_iterator end() const { return Data + Size; }

   const_iterator cbegin() const { return Data; }
   const_iterator cend() const { return Data + Size; }

   reverse_iterator rbegin() { return reverse_iterator(end()); }
   reverse_iterator rend() { return reverse_iterator(begin()); }

   const_reverse_iterator rbegin() const {
     return const_reverse_iterator(end());
   }

   const_reverse_iterator rend() const {
     return const_reverse_iterator(begin());
   }

   void push_back(const T &Elem) {
     assert(Size < Capacity);
     Data[Size++] = Elem;
   }

   // drop last n elements from array
   void drop(unsigned n = 0) {
     assert(Size > n);
     Size -= n;
   }

   void setValues(unsigned Sz, const T& C) {
     assert(Sz <= Capacity);
     Size = Sz;
     for (unsigned i = 0; i < Sz; ++i) {
       Data[i] = C;
     }
   }

   template <class Iter> unsigned append(Iter I, Iter E) {
     size_t Osz = Size;
     size_t J = Osz;
     for (; J < Capacity && I != E; ++J, ++I)
       Data[J] = *I;
     Size = J;
     return J - Osz;
   }

   llvm::iterator_range<reverse_iterator> reverse() {
     return llvm::make_range(rbegin(), rend());
   }

   llvm::iterator_range<const_reverse_iterator> reverse() const {
     return llvm::make_range(rbegin(), rend());
   }

 private:
   // std::max is annoying here, because it requires a reference,
   // thus forcing InitialCapacity to be initialized outside the .h file.
   size_t u_max(size_t i, size_t j) { return (i < j) ? j : i; }

   static const size_t InitialCapacity = 4;

   T *Data = nullptr;
   size_t Size = 0;
   size_t Capacity = 0;
 };

 }  // namespace til

 // A copy on write vector.
 // The vector can be in one of three states:
 // * invalid -- no operations are permitted.
 // * read-only -- read operations are permitted.
 // * writable -- read and write operations are permitted.
 // The init(), destroy(), and makeWritable() methods will change state.
 template<typename T>
 class CopyOnWriteVector {
   class VectorData {
   public:
     unsigned NumRefs = 1;
     std::vector<T> Vect;

     VectorData() = default;
     VectorData(const VectorData &VD) : Vect(VD.Vect) {}
   };

 public:
   CopyOnWriteVector() = default;
   CopyOnWriteVector(CopyOnWriteVector &&V) : Data(V.Data) { V.Data = nullptr; }

   CopyOnWriteVector &operator=(CopyOnWriteVector &&V) {
     destroy();
     Data = V.Data;
     V.Data = nullptr;
     return *this;
   }

   // No copy constructor or copy assignment.  Use clone() with move assignment.
   CopyOnWriteVector(const CopyOnWriteVector &) = delete;
   CopyOnWriteVector &operator=(const CopyOnWriteVector &) = delete;

   ~CopyOnWriteVector() { destroy(); }

   // Returns true if this holds a valid vector.
   bool valid() const  { return Data; }

   // Returns true if this vector is writable.
   bool writable() const { return Data && Data->NumRefs == 1; }

   // If this vector is not valid, initialize it to a valid vector.
   void init() {
     if (!Data) {
       Data = new VectorData();
     }
   }

   // Destroy this vector; thus making it invalid.
   void destroy() {
     if (!Data)
       return;
     if (Data->NumRefs <= 1)
       delete Data;
     else
       --Data->NumRefs;
     Data = nullptr;
   }

   // Make this vector writable, creating a copy if needed.
   void makeWritable() {
     if (!Data) {
       Data = new VectorData();
       return;
     }
     if (Data->NumRefs == 1)
       return;   // already writeable.
     --Data->NumRefs;
     Data = new VectorData(*Data);
   }

   // Create a lazy copy of this vector.
   CopyOnWriteVector clone() { return CopyOnWriteVector(Data); }

   using const_iterator = typename std::vector<T>::const_iterator;

   const std::vector<T> &elements() const { return Data->Vect; }

   const_iterator begin() const { return elements().cbegin(); }
   const_iterator end() const { return elements().cend(); }

   const T& operator[](unsigned i) const { return elements()[i]; }

   unsigned size() const { return Data ? elements().size() : 0; }

   // Return true if V and this vector refer to the same data.
   bool sameAs(const CopyOnWriteVector &V) const { return Data == V.Data; }

   // Clear vector.  The vector must be writable.
   void clear() {
     assert(writable() && "Vector is not writable!");
     Data->Vect.clear();
   }

   // Push a new element onto the end.  The vector must be writable.
   void push_back(const T &Elem) {
     assert(writable() && "Vector is not writable!");
     Data->Vect.push_back(Elem);
   }

   // Gets a mutable reference to the element at index(i).
   // The vector must be writable.
   T& elem(unsigned i) {
     assert(writable() && "Vector is not writable!");
     return Data->Vect[i];
   }

   // Drops elements from the back until the vector has size i.
   void downsize(unsigned i) {
     assert(writable() && "Vector is not writable!");
     Data->Vect.erase(Data->Vect.begin() + i, Data->Vect.end());
   }

 private:
   CopyOnWriteVector(VectorData *D) : Data(D) {
     if (!Data)
       return;
     ++Data->NumRefs;
   }

   VectorData *Data = nullptr;
 };

 inline std::ostream& operator<<(std::ostream& ss, const StringRef str) {
   return ss.write(str.data(), str.size());
 }

 } // namespace threadSafety
 } // namespace clang

 #endif // LLVM_CLANG_THREAD_SAFETY_UTIL_H
	//===- ThreadSafetyUtil.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 some basic utility classes for use by ThreadSafetyTIL.h
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_ANALYSIS_ANALYSES_THREADSAFETYUTIL_H
	#define LLVM_CLANG_ANALYSIS_ANALYSES_THREADSAFETYUTIL_H

	#include "clang/AST/Decl.h"
	#include "clang/Basic/LLVM.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/ADT/iterator_range.h"
	#include "llvm/Support/Allocator.h"
	#include <cassert>
	#include <cstddef>
	#include <cstring>
	#include <iterator>
	#include <ostream>
	#include <string>
	#include <vector>

	namespace clang {

	class Expr;

	namespace threadSafety {
	namespace til {

	// Simple wrapper class to abstract away from the details of memory management.
	// SExprs are allocated in pools, and deallocated all at once.
	class MemRegionRef {
	private:
	union AlignmentType {
	double d;
	void *p;
	long double dd;
	long long ii;
	};

	public:
	MemRegionRef() = default;
	MemRegionRef(llvm::BumpPtrAllocator *A) : Allocator(A) {}

	void *allocate(size_t Sz) {
	return Allocator->Allocate(Sz, alignof(AlignmentType));
	}

	template <typename T> T *allocateT() { return Allocator->Allocate<T>(); }

	template <typename T> T *allocateT(size_t NumElems) {
	return Allocator->Allocate<T>(NumElems);
	}

	private:
	llvm::BumpPtrAllocator *Allocator = nullptr;
	};

	} // namespace til
	} // namespace threadSafety

	} // namespace clang

	inline void *operator new(size_t Sz,
	clang::threadSafety::til::MemRegionRef &R) {
	return R.allocate(Sz);
	}

	namespace clang {
	namespace threadSafety {

	std::string getSourceLiteralString(const Expr *CE);

	namespace til {

	// A simple fixed size array class that does not manage its own memory,
	// suitable for use with bump pointer allocation.
	template <class T> class SimpleArray {
	public:
	SimpleArray() = default;
	SimpleArray(T *Dat, size_t Cp, size_t Sz = 0)
	: Data(Dat), Size(Sz), Capacity(Cp) {}
	SimpleArray(MemRegionRef A, size_t Cp)
	: Data(Cp == 0 ? nullptr : A.allocateT<T>(Cp)), Capacity(Cp) {}
	SimpleArray(const SimpleArray<T> &A) = delete;

	SimpleArray(SimpleArray<T> &&A)
	: Data(A.Data), Size(A.Size), Capacity(A.Capacity) {
	A.Data = nullptr;
	A.Size = 0;
	A.Capacity = 0;
	}

	SimpleArray &operator=(SimpleArray &&RHS) {
	if (this != &RHS) {
	Data = RHS.Data;
	Size = RHS.Size;
	Capacity = RHS.Capacity;

	RHS.Data = nullptr;
	RHS.Size = RHS.Capacity = 0;
	}
	return *this;
	}

	// Reserve space for at least Ncp items, reallocating if necessary.
	void reserve(size_t Ncp, MemRegionRef A) {
	if (Ncp <= Capacity)
	return;
	T *Odata = Data;
	Data = A.allocateT<T>(Ncp);
	Capacity = Ncp;
	memcpy(Data, Odata, sizeof(T) * Size);
	}

	// Reserve space for at least N more items.
	void reserveCheck(size_t N, MemRegionRef A) {
	if (Capacity == 0)
	reserve(u_max(InitialCapacity, N), A);
	else if (Size + N < Capacity)
	reserve(u_max(Size + N, Capacity * 2), A);
	}

	using iterator = T *;
	using const_iterator = const T *;
	using reverse_iterator = std::reverse_iterator<iterator>;
	using const_reverse_iterator = std::reverse_iterator<const_iterator>;

	size_t size() const { return Size; }
	size_t capacity() const { return Capacity; }

	T &operator[](unsigned i) {
	assert(i < Size && "Array index out of bounds.");
	return Data[i];
	}

	const T &operator[](unsigned i) const {
	assert(i < Size && "Array index out of bounds.");
	return Data[i];
	}

	T &back() {
	assert(Size && "No elements in the array.");
	return Data[Size - 1];
	}

	const T &back() const {
	assert(Size && "No elements in the array.");
	return Data[Size - 1];
	}

	iterator begin() { return Data; }
	iterator end() { return Data + Size; }

	const_iterator begin() const { return Data; }
	const_iterator end() const { return Data + Size; }

	const_iterator cbegin() const { return Data; }
	const_iterator cend() const { return Data + Size; }

	reverse_iterator rbegin() { return reverse_iterator(end()); }
	reverse_iterator rend() { return reverse_iterator(begin()); }

	const_reverse_iterator rbegin() const {
	return const_reverse_iterator(end());
	}

	const_reverse_iterator rend() const {
	return const_reverse_iterator(begin());
	}

	void push_back(const T &Elem) {
	assert(Size < Capacity);
	Data[Size++] = Elem;
	}

	// drop last n elements from array
	void drop(unsigned n = 0) {
	assert(Size > n);
	Size -= n;
	}

	void setValues(unsigned Sz, const T& C) {
	assert(Sz <= Capacity);
	Size = Sz;
	for (unsigned i = 0; i < Sz; ++i) {
	Data[i] = C;
	}
	}

	template <class Iter> unsigned append(Iter I, Iter E) {
	size_t Osz = Size;
	size_t J = Osz;
	for (; J < Capacity && I != E; ++J, ++I)
	Data[J] = *I;
	Size = J;
	return J - Osz;
	}

	llvm::iterator_range<reverse_iterator> reverse() {
	return llvm::make_range(rbegin(), rend());
	}

	llvm::iterator_range<const_reverse_iterator> reverse() const {
	return llvm::make_range(rbegin(), rend());
	}

	private:
	// std::max is annoying here, because it requires a reference,
	// thus forcing InitialCapacity to be initialized outside the .h file.
	size_t u_max(size_t i, size_t j) { return (i < j) ? j : i; }

	static const size_t InitialCapacity = 4;

	T *Data = nullptr;
	size_t Size = 0;
	size_t Capacity = 0;
	};

	} // namespace til

	// A copy on write vector.
	// The vector can be in one of three states:
	// * invalid -- no operations are permitted.
	// * read-only -- read operations are permitted.
	// * writable -- read and write operations are permitted.
	// The init(), destroy(), and makeWritable() methods will change state.
	template<typename T>
	class CopyOnWriteVector {
	class VectorData {
	public:
	unsigned NumRefs = 1;
	std::vector<T> Vect;

	VectorData() = default;
	VectorData(const VectorData &VD) : Vect(VD.Vect) {}
	};

	public:
	CopyOnWriteVector() = default;
	CopyOnWriteVector(CopyOnWriteVector &&V) : Data(V.Data) { V.Data = nullptr; }

	CopyOnWriteVector &operator=(CopyOnWriteVector &&V) {
	destroy();
	Data = V.Data;
	V.Data = nullptr;
	return *this;
	}

	// No copy constructor or copy assignment. Use clone() with move assignment.
	CopyOnWriteVector(const CopyOnWriteVector &) = delete;
	CopyOnWriteVector &operator=(const CopyOnWriteVector &) = delete;

	~CopyOnWriteVector() { destroy(); }

	// Returns true if this holds a valid vector.
	bool valid() const { return Data; }

	// Returns true if this vector is writable.
	bool writable() const { return Data && Data->NumRefs == 1; }

	// If this vector is not valid, initialize it to a valid vector.
	void init() {
	if (!Data) {
	Data = new VectorData();
	}
	}

	// Destroy this vector; thus making it invalid.
	void destroy() {
	if (!Data)
	return;
	if (Data->NumRefs <= 1)
	delete Data;
	else
	--Data->NumRefs;
	Data = nullptr;
	}

	// Make this vector writable, creating a copy if needed.
	void makeWritable() {
	if (!Data) {
	Data = new VectorData();
	return;
	}
	if (Data->NumRefs == 1)
	return; // already writeable.
	--Data->NumRefs;
	Data = new VectorData(*Data);
	}

	// Create a lazy copy of this vector.
	CopyOnWriteVector clone() { return CopyOnWriteVector(Data); }

	using const_iterator = typename std::vector<T>::const_iterator;

	const std::vector<T> &elements() const { return Data->Vect; }

	const_iterator begin() const { return elements().cbegin(); }
	const_iterator end() const { return elements().cend(); }

	const T& operator[](unsigned i) const { return elements()[i]; }

	unsigned size() const { return Data ? elements().size() : 0; }

	// Return true if V and this vector refer to the same data.
	bool sameAs(const CopyOnWriteVector &V) const { return Data == V.Data; }

	// Clear vector. The vector must be writable.
	void clear() {
	assert(writable() && "Vector is not writable!");
	Data->Vect.clear();
	}

	// Push a new element onto the end. The vector must be writable.
	void push_back(const T &Elem) {
	assert(writable() && "Vector is not writable!");
	Data->Vect.push_back(Elem);
	}

	// Gets a mutable reference to the element at index(i).
	// The vector must be writable.
	T& elem(unsigned i) {
	assert(writable() && "Vector is not writable!");
	return Data->Vect[i];
	}

	// Drops elements from the back until the vector has size i.
	void downsize(unsigned i) {
	assert(writable() && "Vector is not writable!");
	Data->Vect.erase(Data->Vect.begin() + i, Data->Vect.end());
	}

	private:
	CopyOnWriteVector(VectorData *D) : Data(D) {
	if (!Data)
	return;
	++Data->NumRefs;
	}

	VectorData *Data = nullptr;
	};

	inline std::ostream& operator<<(std::ostream& ss, const StringRef str) {
	return ss.write(str.data(), str.size());
	}

	} // namespace threadSafety
	} // namespace clang

	#endif // LLVM_CLANG_THREAD_SAFETY_UTIL_H