linux-x64/clang/include/llvm/Support/ArrayRecycler.h - hafnium/prebuilts - Git at Google

 //==- llvm/Support/ArrayRecycler.h - Recycling of Arrays ---------*- C++ -*-==//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the ArrayRecycler class template which can recycle small
 // arrays allocated from one of the allocators in Allocator.h
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_SUPPORT_ARRAYRECYCLER_H
 #define LLVM_SUPPORT_ARRAYRECYCLER_H

 #include "llvm/ADT/SmallVector.h"
 #include "llvm/Support/Allocator.h"
 #include "llvm/Support/MathExtras.h"

 namespace llvm {

 /// Recycle small arrays allocated from a BumpPtrAllocator.
 ///
 /// Arrays are allocated in a small number of fixed sizes. For each supported
 /// array size, the ArrayRecycler keeps a free list of available arrays.
 ///
 template <class T, size_t Align = alignof(T)> class ArrayRecycler {
   // The free list for a given array size is a simple singly linked list.
   // We can't use iplist or Recycler here since those classes can't be copied.
   struct FreeList {
     FreeList *Next;
   };

   static_assert(Align >= alignof(FreeList), "Object underaligned");
   static_assert(sizeof(T) >= sizeof(FreeList), "Objects are too small");

   // Keep a free list for each array size.
   SmallVector<FreeList*, 8> Bucket;

   // Remove an entry from the free list in Bucket[Idx] and return it.
   // Return NULL if no entries are available.
   T *pop(unsigned Idx) {
     if (Idx >= Bucket.size())
       return nullptr;
     FreeList *Entry = Bucket[Idx];
     if (!Entry)
       return nullptr;
     __asan_unpoison_memory_region(Entry, Capacity::get(Idx).getSize());
     Bucket[Idx] = Entry->Next;
     __msan_allocated_memory(Entry, Capacity::get(Idx).getSize());
     return reinterpret_cast<T*>(Entry);
   }

   // Add an entry to the free list at Bucket[Idx].
   void push(unsigned Idx, T *Ptr) {
     assert(Ptr && "Cannot recycle NULL pointer");
     FreeList *Entry = reinterpret_cast<FreeList*>(Ptr);
     if (Idx >= Bucket.size())
       Bucket.resize(size_t(Idx) + 1);
     Entry->Next = Bucket[Idx];
     Bucket[Idx] = Entry;
     __asan_poison_memory_region(Ptr, Capacity::get(Idx).getSize());
   }

 public:
   /// The size of an allocated array is represented by a Capacity instance.
   ///
   /// This class is much smaller than a size_t, and it provides methods to work
   /// with the set of legal array capacities.
   class Capacity {
     uint8_t Index;
     explicit Capacity(uint8_t idx) : Index(idx) {}

   public:
     Capacity() : Index(0) {}

     /// Get the capacity of an array that can hold at least N elements.
     static Capacity get(size_t N) {
       return Capacity(N ? Log2_64_Ceil(N) : 0);
     }

     /// Get the number of elements in an array with this capacity.
     size_t getSize() const { return size_t(1u) << Index; }

     /// Get the bucket number for this capacity.
     unsigned getBucket() const { return Index; }

     /// Get the next larger capacity. Large capacities grow exponentially, so
     /// this function can be used to reallocate incrementally growing vectors
     /// in amortized linear time.
     Capacity getNext() const { return Capacity(Index + 1); }
   };

   ~ArrayRecycler() {
     // The client should always call clear() so recycled arrays can be returned
     // to the allocator.
     assert(Bucket.empty() && "Non-empty ArrayRecycler deleted!");
   }

   /// Release all the tracked allocations to the allocator. The recycler must
   /// be free of any tracked allocations before being deleted.
   template<class AllocatorType>
   void clear(AllocatorType &Allocator) {
     for (; !Bucket.empty(); Bucket.pop_back())
       while (T *Ptr = pop(Bucket.size() - 1))
         Allocator.Deallocate(Ptr);
   }

   /// Special case for BumpPtrAllocator which has an empty Deallocate()
   /// function.
   ///
   /// There is no need to traverse the free lists, pulling all the objects into
   /// cache.
   void clear(BumpPtrAllocator&) {
     Bucket.clear();
   }

   /// Allocate an array of at least the requested capacity.
   ///
   /// Return an existing recycled array, or allocate one from Allocator if
   /// none are available for recycling.
   ///
   template<class AllocatorType>
   T *allocate(Capacity Cap, AllocatorType &Allocator) {
     // Try to recycle an existing array.
     if (T *Ptr = pop(Cap.getBucket()))
       return Ptr;
     // Nope, get more memory.
     return static_cast<T*>(Allocator.Allocate(sizeof(T)*Cap.getSize(), Align));
   }

   /// Deallocate an array with the specified Capacity.
   ///
   /// Cap must be the same capacity that was given to allocate().
   ///
   void deallocate(Capacity Cap, T *Ptr) {
     push(Cap.getBucket(), Ptr);
   }
 };

 } // end llvm namespace

 #endif
	//==- llvm/Support/ArrayRecycler.h - Recycling of Arrays ---------- C++ --==//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the ArrayRecycler class template which can recycle small
	// arrays allocated from one of the allocators in Allocator.h
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_SUPPORT_ARRAYRECYCLER_H
	#define LLVM_SUPPORT_ARRAYRECYCLER_H

	#include "llvm/ADT/SmallVector.h"
	#include "llvm/Support/Allocator.h"
	#include "llvm/Support/MathExtras.h"

	namespace llvm {

	/// Recycle small arrays allocated from a BumpPtrAllocator.
	///
	/// Arrays are allocated in a small number of fixed sizes. For each supported
	/// array size, the ArrayRecycler keeps a free list of available arrays.
	///
	template <class T, size_t Align = alignof(T)> class ArrayRecycler {
	// The free list for a given array size is a simple singly linked list.
	// We can't use iplist or Recycler here since those classes can't be copied.
	struct FreeList {
	FreeList *Next;
	};

	static_assert(Align >= alignof(FreeList), "Object underaligned");
	static_assert(sizeof(T) >= sizeof(FreeList), "Objects are too small");

	// Keep a free list for each array size.
	SmallVector<FreeList*, 8> Bucket;

	// Remove an entry from the free list in Bucket[Idx] and return it.
	// Return NULL if no entries are available.
	T *pop(unsigned Idx) {
	if (Idx >= Bucket.size())
	return nullptr;
	FreeList *Entry = Bucket[Idx];
	if (!Entry)
	return nullptr;
	__asan_unpoison_memory_region(Entry, Capacity::get(Idx).getSize());
	Bucket[Idx] = Entry->Next;
	__msan_allocated_memory(Entry, Capacity::get(Idx).getSize());
	return reinterpret_cast<T*>(Entry);
	}

	// Add an entry to the free list at Bucket[Idx].
	void push(unsigned Idx, T *Ptr) {
	assert(Ptr && "Cannot recycle NULL pointer");
	FreeList Entry = reinterpret_cast<FreeList>(Ptr);
	if (Idx >= Bucket.size())
	Bucket.resize(size_t(Idx) + 1);
	Entry->Next = Bucket[Idx];
	Bucket[Idx] = Entry;
	__asan_poison_memory_region(Ptr, Capacity::get(Idx).getSize());
	}

	public:
	/// The size of an allocated array is represented by a Capacity instance.
	///
	/// This class is much smaller than a size_t, and it provides methods to work
	/// with the set of legal array capacities.
	class Capacity {
	uint8_t Index;
	explicit Capacity(uint8_t idx) : Index(idx) {}

	public:
	Capacity() : Index(0) {}

	/// Get the capacity of an array that can hold at least N elements.
	static Capacity get(size_t N) {
	return Capacity(N ? Log2_64_Ceil(N) : 0);
	}

	/// Get the number of elements in an array with this capacity.
	size_t getSize() const { return size_t(1u) << Index; }

	/// Get the bucket number for this capacity.
	unsigned getBucket() const { return Index; }

	/// Get the next larger capacity. Large capacities grow exponentially, so
	/// this function can be used to reallocate incrementally growing vectors
	/// in amortized linear time.
	Capacity getNext() const { return Capacity(Index + 1); }
	};

	~ArrayRecycler() {
	// The client should always call clear() so recycled arrays can be returned
	// to the allocator.
	assert(Bucket.empty() && "Non-empty ArrayRecycler deleted!");
	}

	/// Release all the tracked allocations to the allocator. The recycler must
	/// be free of any tracked allocations before being deleted.
	template<class AllocatorType>
	void clear(AllocatorType &Allocator) {
	for (; !Bucket.empty(); Bucket.pop_back())
	while (T *Ptr = pop(Bucket.size() - 1))
	Allocator.Deallocate(Ptr);
	}

	/// Special case for BumpPtrAllocator which has an empty Deallocate()
	/// function.
	///
	/// There is no need to traverse the free lists, pulling all the objects into
	/// cache.
	void clear(BumpPtrAllocator&) {
	Bucket.clear();
	}

	/// Allocate an array of at least the requested capacity.
	///
	/// Return an existing recycled array, or allocate one from Allocator if
	/// none are available for recycling.
	///
	template<class AllocatorType>
	T *allocate(Capacity Cap, AllocatorType &Allocator) {
	// Try to recycle an existing array.
	if (T *Ptr = pop(Cap.getBucket()))
	return Ptr;
	// Nope, get more memory.
	return static_cast<T>(Allocator.Allocate(sizeof(T)Cap.getSize(), Align));
	}

	/// Deallocate an array with the specified Capacity.
	///
	/// Cap must be the same capacity that was given to allocate().
	///
	void deallocate(Capacity Cap, T *Ptr) {
	push(Cap.getBucket(), Ptr);
	}
	};

	} // end llvm namespace

	#endif