// Copyright 2014 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_LIST_CONTAINER_H_ #define CC_BASE_LIST_CONTAINER_H_ #include #include "base/logging.h" #include "base/macros.h" #include "base/memory/scoped_ptr.h" #include "cc/base/cc_export.h" #include "cc/base/list_container_helper.h" namespace cc { // ListContainer is a container type that handles allocating contiguous memory // for new elements and traversing through elements with either iterator or // reverse iterator. Since this container hands out raw pointers of its // elements, it is very important that this container never reallocate its // memory so those raw pointer will continue to be valid. This class is used to // contain SharedQuadState or DrawQuad. Since the size of each DrawQuad varies, // to hold DrawQuads, the allocations size of each element in this class is // LargestDrawQuadSize while BaseElementType is DrawQuad. template class ListContainer { public: // BaseElementType is the type of raw pointers this class hands out; however, // its derived classes might require different memory sizes. // max_size_for_derived_class the largest memory size required for all the // derived classes to use for allocation. explicit ListContainer(size_t max_size_for_derived_class) : helper_(max_size_for_derived_class) {} // This constructor omits input variable for max_size_for_derived_class. This // is used when there is no derived classes from BaseElementType we need to // worry about, and allocation size is just sizeof(BaseElementType). ListContainer() : helper_(sizeof(BaseElementType)) {} // This constructor reserves the requested memory up front so only single // allocation is needed. When num_of_elements_to_reserve_for is zero, use the // default size. ListContainer(size_t max_size_for_derived_class, size_t num_of_elements_to_reserve_for) : helper_(max_size_for_derived_class, num_of_elements_to_reserve_for) {} ~ListContainer() { for (Iterator i = begin(); i != end(); ++i) { i->~BaseElementType(); } } class Iterator; class ConstIterator; class ReverseIterator; class ConstReverseIterator; // Removes the last element of the list and makes its space available for // allocation. void RemoveLast() { DCHECK(!empty()); back()->~BaseElementType(); helper_.RemoveLast(); } // When called, all raw pointers that have been handed out are no longer // valid. Use with caution. // Returns a valid Iterator pointing to the element after the erased element. // This function does not deallocate memory. Iterator EraseAndInvalidateAllPointers(Iterator position) { BaseElementType* item = *position; item->~BaseElementType(); helper_.EraseAndInvalidateAllPointers(&position); return empty() ? end() : position; } ConstReverseIterator crbegin() const { return ConstReverseIterator(helper_.crbegin()); } ConstReverseIterator crend() const { return ConstReverseIterator(helper_.crend()); } ConstReverseIterator rbegin() const { return crbegin(); } ConstReverseIterator rend() const { return crend(); } ReverseIterator rbegin() { return ReverseIterator(helper_.rbegin()); } ReverseIterator rend() { return ReverseIterator(helper_.rend()); } ConstIterator cbegin() const { return ConstIterator(helper_.cbegin()); } ConstIterator cend() const { return ConstIterator(helper_.cend()); } ConstIterator begin() const { return cbegin(); } ConstIterator end() const { return cend(); } Iterator begin() { return Iterator(helper_.begin()); } Iterator end() { return Iterator(helper_.end()); } // TODO(weiliangc): front(), back() and ElementAt() function should return // reference, consistent with container-of-object. BaseElementType* front() { return *begin(); } BaseElementType* back() { return *rbegin(); } const BaseElementType* front() const { return *begin(); } const BaseElementType* back() const { return *rbegin(); } BaseElementType* ElementAt(size_t index) { return *Iterator(helper_.IteratorAt(index)); } const BaseElementType* ElementAt(size_t index) const { return *ConstIterator(helper_.IteratorAt(index)); } // Take in derived element type and construct it at location generated by // Allocate(). template DerivedElementType* AllocateAndConstruct() { return new (helper_.Allocate(sizeof(DerivedElementType))) DerivedElementType; } // Take in derived element type and copy construct it at location generated by // Allocate(). template DerivedElementType* AllocateAndCopyFrom(const DerivedElementType* source) { return new (helper_.Allocate(sizeof(DerivedElementType))) DerivedElementType(*source); } // Construct a new element on top of an existing one. template DerivedElementType* ReplaceExistingElement(Iterator at) { at->~BaseElementType(); return new (at.item_iterator) DerivedElementType(); } // Insert |count| new elements of |DerivedElementType| before |at|. This will // invalidate all outstanding pointers and iterators. Return a valid iterator // for the beginning of the newly inserted segment. template Iterator InsertBeforeAndInvalidateAllPointers(Iterator at, size_t count) { helper_.InsertBeforeAndInvalidateAllPointers(&at, count); Iterator result = at; for (size_t i = 0; i < count; ++i) { new (at.item_iterator) DerivedElementType(); ++at; } return result; } template void swap(ListContainer& other) { helper_.data_.swap(other.helper_.data_); } // Appends a new item without copying. The original item will not be // destructed and will be replaced with a new DerivedElementType. The // DerivedElementType does not have to match the moved type as a full block // of memory will be moved (up to MaxSizeForDerivedClass()). A pointer to // the moved element is returned. template DerivedElementType* AppendByMoving(DerivedElementType* item) { size_t max_size_for_derived_class = helper_.MaxSizeForDerivedClass(); void* new_item = helper_.Allocate(max_size_for_derived_class); memcpy(new_item, static_cast(item), max_size_for_derived_class); // Construct a new element in-place so it can be destructed safely. new (item) DerivedElementType; return static_cast(new_item); } size_t size() const { return helper_.size(); } bool empty() const { return helper_.empty(); } size_t GetCapacityInBytes() const { return helper_.GetCapacityInBytes(); } void clear() { for (Iterator i = begin(); i != end(); ++i) { i->~BaseElementType(); } helper_.clear(); } size_t AvailableSizeWithoutAnotherAllocationForTesting() const { return helper_.AvailableSizeWithoutAnotherAllocationForTesting(); } // Iterator classes that can be used to access data. ///////////////////////////////////////////////////////////////// class Iterator : public ListContainerHelper::Iterator { // This class is only defined to forward iterate through // CharAllocator. public: Iterator(ListContainerHelper::CharAllocator* container, size_t vector_ind, char* item_iter, size_t index) : ListContainerHelper::Iterator(container, vector_ind, item_iter, index) {} BaseElementType* operator->() const { return reinterpret_cast(item_iterator); } BaseElementType* operator*() const { return reinterpret_cast(item_iterator); } Iterator operator++(int unused_post_increment) { Iterator tmp = *this; operator++(); return tmp; } Iterator& operator++() { Increment(); ++index_; return *this; } private: explicit Iterator(const ListContainerHelper::Iterator& base_iterator) : ListContainerHelper::Iterator(base_iterator) {} friend Iterator ListContainer::begin(); friend Iterator ListContainer::end(); friend BaseElementType* ListContainer::ElementAt( size_t index); }; class ConstIterator : public ListContainerHelper::ConstIterator { // This class is only defined to forward iterate through // CharAllocator. public: ConstIterator(ListContainerHelper::CharAllocator* container, size_t vector_ind, char* item_iter, size_t index) : ListContainerHelper::ConstIterator(container, vector_ind, item_iter, index) {} ConstIterator(const Iterator& other) // NOLINT : ListContainerHelper::ConstIterator(other) {} const BaseElementType* operator->() const { return reinterpret_cast(item_iterator); } const BaseElementType* operator*() const { return reinterpret_cast(item_iterator); } ConstIterator operator++(int unused_post_increment) { ConstIterator tmp = *this; operator++(); return tmp; } ConstIterator& operator++() { Increment(); ++index_; return *this; } private: explicit ConstIterator( const ListContainerHelper::ConstIterator& base_iterator) : ListContainerHelper::ConstIterator(base_iterator) {} friend ConstIterator ListContainer::cbegin() const; friend ConstIterator ListContainer::cend() const; friend const BaseElementType* ListContainer::ElementAt( size_t index) const; }; class ReverseIterator : public ListContainerHelper::ReverseIterator { // This class is only defined to reverse iterate through // CharAllocator. public: ReverseIterator(ListContainerHelper::CharAllocator* container, size_t vector_ind, char* item_iter, size_t index) : ListContainerHelper::ReverseIterator(container, vector_ind, item_iter, index) {} BaseElementType* operator->() const { return reinterpret_cast(item_iterator); } BaseElementType* operator*() const { return reinterpret_cast(item_iterator); } ReverseIterator operator++(int unused_post_increment) { ReverseIterator tmp = *this; operator++(); return tmp; } ReverseIterator& operator++() { ReverseIncrement(); ++index_; return *this; } private: explicit ReverseIterator(ListContainerHelper::ReverseIterator base_iterator) : ListContainerHelper::ReverseIterator(base_iterator) {} friend ReverseIterator ListContainer::rbegin(); friend ReverseIterator ListContainer::rend(); }; class ConstReverseIterator : public ListContainerHelper::ConstReverseIterator { // This class is only defined to reverse iterate through // CharAllocator. public: ConstReverseIterator(ListContainerHelper::CharAllocator* container, size_t vector_ind, char* item_iter, size_t index) : ListContainerHelper::ConstReverseIterator(container, vector_ind, item_iter, index) {} ConstReverseIterator(const ReverseIterator& other) // NOLINT : ListContainerHelper::ConstReverseIterator(other) {} const BaseElementType* operator->() const { return reinterpret_cast(item_iterator); } const BaseElementType* operator*() const { return reinterpret_cast(item_iterator); } ConstReverseIterator operator++(int unused_post_increment) { ConstReverseIterator tmp = *this; operator++(); return tmp; } ConstReverseIterator& operator++() { ReverseIncrement(); ++index_; return *this; } private: explicit ConstReverseIterator( ListContainerHelper::ConstReverseIterator base_iterator) : ListContainerHelper::ConstReverseIterator(base_iterator) {} friend ConstReverseIterator ListContainer::crbegin() const; friend ConstReverseIterator ListContainer::crend() const; }; private: ListContainerHelper helper_; DISALLOW_COPY_AND_ASSIGN(ListContainer); }; } // namespace cc #endif // CC_BASE_LIST_CONTAINER_H_