cc/base/contiguous_container.h - chromium/src - Git at Google

 // Copyright 2015 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef CC_BASE_CONTIGUOUS_CONTAINER_H_
 #define CC_BASE_CONTIGUOUS_CONTAINER_H_

 #include <stddef.h>
 #include <utility>

 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/memory/scoped_ptr.h"
 #include "base/stl_util.h"
 #include "cc/base/cc_export.h"

 namespace cc {

 // ContiguousContainer is a container which stores a list of heterogeneous
 // objects (in particular, of varying sizes), packed next to one another in
 // memory. Objects are never relocated, so it is safe to store pointers to them
 // for the lifetime of the container (unless the object is removed).
 //
 // Memory is allocated in a series of buffers (with exponential growth). When an
 // object is allocated, it is given only the space it requires (possibly with
 // enough padding to preserve alignment), rather than the maximum possible size.
 // This allows small and large objects to coexist without wasting much space.
 //
 // Since it stores pointers to all of the objects it allocates in a vector, it
 // supports efficient iteration and indexing. However, for mutation the
 // supported operations are limited to appending to, and removing from, the end
 // of the list.
 //
 // Clients should instantiate ContiguousContainer; ContiguousContainerBase is an
 // artifact of the implementation.

 class CC_EXPORT ContiguousContainerBase {
  protected:
   explicit ContiguousContainerBase(size_t max_object_size);
   ContiguousContainerBase(size_t max_object_size, size_t initial_size_bytes);
   ~ContiguousContainerBase();

   size_t size() const { return elements_.size(); }
   bool empty() const { return !size(); }
   size_t GetCapacityInBytes() const;
   size_t UsedCapacityInBytes() const;
   size_t MemoryUsageInBytes() const;

   // These do not invoke constructors or destructors.
   void* Allocate(size_t object_size);
   void Clear();
   void RemoveLast();
   void Swap(ContiguousContainerBase& other);

   std::vector<void*> elements_;

  private:
   class Buffer;

   Buffer* AllocateNewBufferForNextAllocation(size_t buffer_size);

   std::vector<scoped_ptr<Buffer>> buffers_;
   size_t end_index_;
   size_t max_object_size_;

   DISALLOW_COPY_AND_ASSIGN(ContiguousContainerBase);
 };

 // For most cases, no alignment stricter than pointer alignment is required. If
 // one of the derived classes has stronger alignment requirements (and the
 // static_assert fires), set alignment to the least common multiple of the
 // derived class alignments. For small structs without pointers, it may be
 // possible to reduce alignment for tighter packing.

 template <class BaseElementType, unsigned alignment = sizeof(void*)>
 class ContiguousContainer : public ContiguousContainerBase {
  private:
   // Declares itself as a forward iterator, but also supports a few more
   // things. The whole random access iterator interface is a bit much.
   template <typename BaseIterator, typename ValueType>
   class IteratorWrapper
       : public std::iterator<std::forward_iterator_tag, ValueType> {
    public:
     IteratorWrapper() {}
     bool operator==(const IteratorWrapper& other) const {
       return it_ == other.it_;
     }
     bool operator!=(const IteratorWrapper& other) const {
       return it_ != other.it_;
     }
     ValueType& operator*() const { return *static_cast<ValueType*>(*it_); }
     ValueType* operator->() const { return &operator*(); }
     IteratorWrapper operator+(std::ptrdiff_t n) const {
       return IteratorWrapper(it_ + n);
     }
     IteratorWrapper operator++(int) {
       IteratorWrapper tmp = *this;
       ++it_;
       return tmp;
     }
     std::ptrdiff_t operator-(const IteratorWrapper& other) const {
       return it_ - other.it_;
     }
     IteratorWrapper& operator++() {
       ++it_;
       return *this;
     }

    private:
     explicit IteratorWrapper(const BaseIterator& it) : it_(it) {}
     BaseIterator it_;
     friend class ContiguousContainer;
   };

  public:
   using iterator =
       IteratorWrapper<std::vector<void*>::iterator, BaseElementType>;
   using const_iterator = IteratorWrapper<std::vector<void*>::const_iterator,
                                          const BaseElementType>;
   using reverse_iterator =
       IteratorWrapper<std::vector<void*>::reverse_iterator, BaseElementType>;
   using const_reverse_iterator =
       IteratorWrapper<std::vector<void*>::const_reverse_iterator,
                       const BaseElementType>;

   explicit ContiguousContainer(size_t max_object_size)
       : ContiguousContainerBase(Align(max_object_size)) {}
   ContiguousContainer(size_t max_object_size, size_t initial_size_bytes)
       : ContiguousContainerBase(Align(max_object_size), initial_size_bytes) {}

   ~ContiguousContainer() {
     for (auto& element : *this) {
       // MSVC incorrectly reports this variable as unused.
       (void)element;
       element.~BaseElementType();
     }
   }

   using ContiguousContainerBase::size;
   using ContiguousContainerBase::empty;
   using ContiguousContainerBase::GetCapacityInBytes;
   using ContiguousContainerBase::UsedCapacityInBytes;
   using ContiguousContainerBase::MemoryUsageInBytes;

   iterator begin() { return iterator(elements_.begin()); }
   iterator end() { return iterator(elements_.end()); }
   const_iterator begin() const { return const_iterator(elements_.begin()); }
   const_iterator end() const { return const_iterator(elements_.end()); }
   reverse_iterator rbegin() { return reverse_iterator(elements_.rbegin()); }
   reverse_iterator rend() { return reverse_iterator(elements_.rend()); }
   const_reverse_iterator rbegin() const {
     return const_reverse_iterator(elements_.rbegin());
   }
   const_reverse_iterator rend() const {
     return const_reverse_iterator(elements_.rend());
   }

   BaseElementType& first() { return *begin(); }
   const BaseElementType& first() const { return *begin(); }
   BaseElementType& last() { return *rbegin(); }
   const BaseElementType& last() const { return *rbegin(); }
   BaseElementType& operator[](size_t index) { return *(begin() + index); }
   const BaseElementType& operator[](size_t index) const {
     return *(begin() + index);
   }

   template <class DerivedElementType, typename... Args>
   DerivedElementType& AllocateAndConstruct(Args&&... args) {
     static_assert(alignment % ALIGNOF(DerivedElementType) == 0,
                   "Derived type requires stronger alignment.");
     size_t alloc_size = Align(sizeof(DerivedElementType));
     return *new (Allocate(alloc_size))
         DerivedElementType(std::forward<Args>(args)...);
   }

   void RemoveLast() {
     DCHECK(!empty());
     last().~BaseElementType();
     ContiguousContainerBase::RemoveLast();
   }

   void Clear() {
     for (auto& element : *this) {
       // MSVC incorrectly reports this variable as unused.
       (void)element;
       element.~BaseElementType();
     }
     ContiguousContainerBase::Clear();
   }

   void Swap(ContiguousContainer& other) {
     ContiguousContainerBase::Swap(other);
   }

   // Appends a new element using memcpy, then default-constructs a base
   // element in its place. Use with care.
   BaseElementType& AppendByMoving(BaseElementType* item, size_t size) {
     DCHECK_GE(size, sizeof(BaseElementType));
     void* new_item = Allocate(size);
     memcpy(new_item, static_cast<void*>(item), size);
     new (item) BaseElementType;
     return *static_cast<BaseElementType*>(new_item);
   }

  private:
   static size_t Align(size_t size) {
     size_t aligned_size = alignment * ((size + alignment - 1) / alignment);
     DCHECK_EQ(aligned_size % alignment, 0u);
     DCHECK_GE(aligned_size, size);
     DCHECK_LT(aligned_size, size + alignment);
     return aligned_size;
   }
 };

 }  // namespace cc

 #endif  // CC_BASE_CONTIGUOUS_CONTAINER_H_
	// Copyright 2015 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef CC_BASE_CONTIGUOUS_CONTAINER_H_
	#define CC_BASE_CONTIGUOUS_CONTAINER_H_

	#include <stddef.h>
	#include <utility>

	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/memory/scoped_ptr.h"
	#include "base/stl_util.h"
	#include "cc/base/cc_export.h"

	namespace cc {

	// ContiguousContainer is a container which stores a list of heterogeneous
	// objects (in particular, of varying sizes), packed next to one another in
	// memory. Objects are never relocated, so it is safe to store pointers to them
	// for the lifetime of the container (unless the object is removed).
	//
	// Memory is allocated in a series of buffers (with exponential growth). When an
	// object is allocated, it is given only the space it requires (possibly with
	// enough padding to preserve alignment), rather than the maximum possible size.
	// This allows small and large objects to coexist without wasting much space.
	//
	// Since it stores pointers to all of the objects it allocates in a vector, it
	// supports efficient iteration and indexing. However, for mutation the
	// supported operations are limited to appending to, and removing from, the end
	// of the list.
	//
	// Clients should instantiate ContiguousContainer; ContiguousContainerBase is an
	// artifact of the implementation.

	class CC_EXPORT ContiguousContainerBase {
	protected:
	explicit ContiguousContainerBase(size_t max_object_size);
	ContiguousContainerBase(size_t max_object_size, size_t initial_size_bytes);
	~ContiguousContainerBase();

	size_t size() const { return elements_.size(); }
	bool empty() const { return !size(); }
	size_t GetCapacityInBytes() const;
	size_t UsedCapacityInBytes() const;
	size_t MemoryUsageInBytes() const;

	// These do not invoke constructors or destructors.
	void* Allocate(size_t object_size);
	void Clear();
	void RemoveLast();
	void Swap(ContiguousContainerBase& other);

	std::vector<void*> elements_;

	private:
	class Buffer;

	Buffer* AllocateNewBufferForNextAllocation(size_t buffer_size);

	std::vector<scoped_ptr<Buffer>> buffers_;
	size_t end_index_;
	size_t max_object_size_;

	DISALLOW_COPY_AND_ASSIGN(ContiguousContainerBase);
	};

	// For most cases, no alignment stricter than pointer alignment is required. If
	// one of the derived classes has stronger alignment requirements (and the
	// static_assert fires), set alignment to the least common multiple of the
	// derived class alignments. For small structs without pointers, it may be
	// possible to reduce alignment for tighter packing.

	template <class BaseElementType, unsigned alignment = sizeof(void*)>
	class ContiguousContainer : public ContiguousContainerBase {
	private:
	// Declares itself as a forward iterator, but also supports a few more
	// things. The whole random access iterator interface is a bit much.
	template <typename BaseIterator, typename ValueType>
	class IteratorWrapper
	: public std::iterator<std::forward_iterator_tag, ValueType> {
	public:
	IteratorWrapper() {}
	bool operator==(const IteratorWrapper& other) const {
	return it_ == other.it_;
	}
	bool operator!=(const IteratorWrapper& other) const {
	return it_ != other.it_;
	}
	ValueType& operator() const { return static_cast<ValueType>(it_); }
	ValueType* operator->() const { return &operator*(); }
	IteratorWrapper operator+(std::ptrdiff_t n) const {
	return IteratorWrapper(it_ + n);
	}
	IteratorWrapper operator++(int) {
	IteratorWrapper tmp = *this;
	++it_;
	return tmp;
	}
	std::ptrdiff_t operator-(const IteratorWrapper& other) const {
	return it_ - other.it_;
	}
	IteratorWrapper& operator++() {
	++it_;
	return *this;
	}

	private:
	explicit IteratorWrapper(const BaseIterator& it) : it_(it) {}
	BaseIterator it_;
	friend class ContiguousContainer;
	};

	public:
	using iterator =
	IteratorWrapper<std::vector<void*>::iterator, BaseElementType>;
	using const_iterator = IteratorWrapper<std::vector<void*>::const_iterator,
	const BaseElementType>;
	using reverse_iterator =
	IteratorWrapper<std::vector<void*>::reverse_iterator, BaseElementType>;
	using const_reverse_iterator =
	IteratorWrapper<std::vector<void*>::const_reverse_iterator,
	const BaseElementType>;

	explicit ContiguousContainer(size_t max_object_size)
	: ContiguousContainerBase(Align(max_object_size)) {}
	ContiguousContainer(size_t max_object_size, size_t initial_size_bytes)
	: ContiguousContainerBase(Align(max_object_size), initial_size_bytes) {}

	~ContiguousContainer() {
	for (auto& element : *this) {
	// MSVC incorrectly reports this variable as unused.
	(void)element;
	element.~BaseElementType();
	}
	}

	using ContiguousContainerBase::size;
	using ContiguousContainerBase::empty;
	using ContiguousContainerBase::GetCapacityInBytes;
	using ContiguousContainerBase::UsedCapacityInBytes;
	using ContiguousContainerBase::MemoryUsageInBytes;

	iterator begin() { return iterator(elements_.begin()); }
	iterator end() { return iterator(elements_.end()); }
	const_iterator begin() const { return const_iterator(elements_.begin()); }
	const_iterator end() const { return const_iterator(elements_.end()); }
	reverse_iterator rbegin() { return reverse_iterator(elements_.rbegin()); }
	reverse_iterator rend() { return reverse_iterator(elements_.rend()); }
	const_reverse_iterator rbegin() const {
	return const_reverse_iterator(elements_.rbegin());
	}
	const_reverse_iterator rend() const {
	return const_reverse_iterator(elements_.rend());
	}

	BaseElementType& first() { return *begin(); }
	const BaseElementType& first() const { return *begin(); }
	BaseElementType& last() { return *rbegin(); }
	const BaseElementType& last() const { return *rbegin(); }
	BaseElementType& operator[](size_t index) { return *(begin() + index); }
	const BaseElementType& operator[](size_t index) const {
	return *(begin() + index);
	}

	template <class DerivedElementType, typename... Args>
	DerivedElementType& AllocateAndConstruct(Args&&... args) {
	static_assert(alignment % ALIGNOF(DerivedElementType) == 0,
	"Derived type requires stronger alignment.");
	size_t alloc_size = Align(sizeof(DerivedElementType));
	return *new (Allocate(alloc_size))
	DerivedElementType(std::forward<Args>(args)...);
	}

	void RemoveLast() {
	DCHECK(!empty());
	last().~BaseElementType();
	ContiguousContainerBase::RemoveLast();
	}

	void Clear() {
	for (auto& element : *this) {
	// MSVC incorrectly reports this variable as unused.
	(void)element;
	element.~BaseElementType();
	}
	ContiguousContainerBase::Clear();
	}

	void Swap(ContiguousContainer& other) {
	ContiguousContainerBase::Swap(other);
	}

	// Appends a new element using memcpy, then default-constructs a base
	// element in its place. Use with care.
	BaseElementType& AppendByMoving(BaseElementType* item, size_t size) {
	DCHECK_GE(size, sizeof(BaseElementType));
	void* new_item = Allocate(size);
	memcpy(new_item, static_cast<void*>(item), size);
	new (item) BaseElementType;
	return static_cast<BaseElementType>(new_item);
	}

	private:
	static size_t Align(size_t size) {
	size_t aligned_size = alignment * ((size + alignment - 1) / alignment);
	DCHECK_EQ(aligned_size % alignment, 0u);
	DCHECK_GE(aligned_size, size);
	DCHECK_LT(aligned_size, size + alignment);
	return aligned_size;
	}
	};

	} // namespace cc

	#endif // CC_BASE_CONTIGUOUS_CONTAINER_H_