/* * Copyright (C) 2015 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef ANDROID_SENSOR_SERVICE_UTIL_RING_BUFFER_H #define ANDROID_SENSOR_SERVICE_UTIL_RING_BUFFER_H #include #include #include #include #include namespace android { namespace SensorServiceUtil { /** * A RingBuffer class that maintains an array of objects that can grow up to a certain size. * Elements added to the RingBuffer are inserted in the logical front of the buffer, and * invalidate all current iterators for that RingBuffer object. */ template class RingBuffer final { public: /** * Construct a RingBuffer that can grow up to the given length. */ explicit RingBuffer(size_t length); /** * Forward iterator to this class. Implements an std:forward_iterator. */ class iterator : public std::iterator { public: iterator(T* ptr, size_t size, size_t pos, size_t ctr); iterator& operator++(); iterator operator++(int); bool operator==(const iterator& rhs); bool operator!=(const iterator& rhs); T& operator*(); T* operator->(); private: T* mPtr; size_t mSize; size_t mPos; size_t mCtr; }; /** * Constant forward iterator to this class. Implements an std:forward_iterator. */ class const_iterator : public std::iterator { public: const_iterator(const T* ptr, size_t size, size_t pos, size_t ctr); const_iterator& operator++(); const_iterator operator++(int); bool operator==(const const_iterator& rhs); bool operator!=(const const_iterator& rhs); const T& operator*(); const T* operator->(); private: const T* mPtr; size_t mSize; size_t mPos; size_t mCtr; }; /** * Adds item to the front of this RingBuffer. If the RingBuffer is at its maximum length, * this will result in the last element being replaced (this is done using the element's * assignment operator). * * All current iterators are invalidated. */ void add(const T& item); /** * Moves item to the front of this RingBuffer. Following a call to this, item should no * longer be used. If the RingBuffer is at its maximum length, this will result in the * last element being replaced (this is done using the element's assignment operator). * * All current iterators are invalidated. */ void add(T&& item); /** * Construct item in-place in the front of this RingBuffer using the given arguments. If * the RingBuffer is at its maximum length, this will result in the last element being * replaced (this is done using the element's assignment operator). * * All current iterators are invalidated. */ template void emplace(Args&&... args); /** * Get an iterator to the front of this RingBuffer. */ iterator begin(); /** * Get an iterator to the end of this RingBuffer. */ iterator end(); /** * Get a const_iterator to the front of this RingBuffer. */ const_iterator begin() const; /** * Get a const_iterator to the end of this RingBuffer. */ const_iterator end() const; /** * Return a reference to the element at a given index. If the index is out of range for * this ringbuffer, [0, size), the behavior for this is undefined. */ T& operator[](size_t index); /** * Return a const reference to the element at a given index. If the index is out of range * for this ringbuffer, [0, size), the behavior for this is undefined. */ const T& operator[](size_t index) const; /** * Return the current size of this RingBuffer. */ size_t size() const; /** * Remove all elements from this RingBuffer and set the size to 0. */ void clear(); private: size_t mFrontIdx; size_t mMaxBufferSize; std::vector mBuffer; }; // class RingBuffer template RingBuffer::RingBuffer(size_t length) : mFrontIdx{0}, mMaxBufferSize{length} {} template RingBuffer::iterator::iterator(T* ptr, size_t size, size_t pos, size_t ctr) : mPtr{ptr}, mSize{size}, mPos{pos}, mCtr{ctr} {} template typename RingBuffer::iterator& RingBuffer::iterator::operator++() { ++mCtr; if (CC_UNLIKELY(mCtr == mSize)) { mPos = mSize; return *this; } mPos = ((CC_UNLIKELY(mPos == 0)) ? mSize - 1 : mPos - 1); return *this; } template typename RingBuffer::iterator RingBuffer::iterator::operator++(int) { iterator tmp{mPtr, mSize, mPos, mCtr}; ++(*this); return tmp; } template bool RingBuffer::iterator::operator==(const iterator& rhs) { return (mPtr + mPos) == (rhs.mPtr + rhs.mPos); } template bool RingBuffer::iterator::operator!=(const iterator& rhs) { return (mPtr + mPos) != (rhs.mPtr + rhs.mPos); } template T& RingBuffer::iterator::operator*() { return *(mPtr + mPos); } template T* RingBuffer::iterator::operator->() { return mPtr + mPos; } template RingBuffer::const_iterator::const_iterator(const T* ptr, size_t size, size_t pos, size_t ctr) : mPtr{ptr}, mSize{size}, mPos{pos}, mCtr{ctr} {} template typename RingBuffer::const_iterator& RingBuffer::const_iterator::operator++() { ++mCtr; if (CC_UNLIKELY(mCtr == mSize)) { mPos = mSize; return *this; } mPos = ((CC_UNLIKELY(mPos == 0)) ? mSize - 1 : mPos - 1); return *this; } template typename RingBuffer::const_iterator RingBuffer::const_iterator::operator++(int) { const_iterator tmp{mPtr, mSize, mPos, mCtr}; ++(*this); return tmp; } template bool RingBuffer::const_iterator::operator==(const const_iterator& rhs) { return (mPtr + mPos) == (rhs.mPtr + rhs.mPos); } template bool RingBuffer::const_iterator::operator!=(const const_iterator& rhs) { return (mPtr + mPos) != (rhs.mPtr + rhs.mPos); } template const T& RingBuffer::const_iterator::operator*() { return *(mPtr + mPos); } template const T* RingBuffer::const_iterator::operator->() { return mPtr + mPos; } template void RingBuffer::add(const T& item) { if (mBuffer.size() < mMaxBufferSize) { mBuffer.push_back(item); mFrontIdx = ((mFrontIdx + 1) % mMaxBufferSize); return; } mBuffer[mFrontIdx] = item; mFrontIdx = ((mFrontIdx + 1) % mMaxBufferSize); } template void RingBuffer::add(T&& item) { if (mBuffer.size() != mMaxBufferSize) { mBuffer.push_back(std::forward(item)); mFrontIdx = ((mFrontIdx + 1) % mMaxBufferSize); return; } // Only works for types with move assignment operator mBuffer[mFrontIdx] = std::forward(item); mFrontIdx = ((mFrontIdx + 1) % mMaxBufferSize); } template template void RingBuffer::emplace(Args&&... args) { if (mBuffer.size() != mMaxBufferSize) { mBuffer.emplace_back(std::forward(args)...); mFrontIdx = ((mFrontIdx + 1) % mMaxBufferSize); return; } // Only works for types with move assignment operator mBuffer[mFrontIdx] = T(std::forward(args)...); mFrontIdx = ((mFrontIdx + 1) % mMaxBufferSize); } template typename RingBuffer::iterator RingBuffer::begin() { size_t tmp = (mBuffer.size() == 0) ? 0 : mBuffer.size() - 1; return iterator(mBuffer.data(), mBuffer.size(), (mFrontIdx == 0) ? tmp : mFrontIdx - 1, 0); } template typename RingBuffer::iterator RingBuffer::end() { size_t s = mBuffer.size(); return iterator(mBuffer.data(), s, s, s); } template typename RingBuffer::const_iterator RingBuffer::begin() const { size_t tmp = (mBuffer.size() == 0) ? 0 : mBuffer.size() - 1; return const_iterator(mBuffer.data(), mBuffer.size(), (mFrontIdx == 0) ? tmp : mFrontIdx - 1, 0); } template typename RingBuffer::const_iterator RingBuffer::end() const { size_t s = mBuffer.size(); return const_iterator(mBuffer.data(), s, s, s); } template T& RingBuffer::operator[](size_t index) { LOG_ALWAYS_FATAL_IF(index >= mBuffer.size(), "Index %zu out of bounds, size is %zu.", index, mBuffer.size()); size_t pos = (index >= mFrontIdx) ? mBuffer.size() - 1 - (index - mFrontIdx) : mFrontIdx - 1 - index; return mBuffer[pos]; } template const T& RingBuffer::operator[](size_t index) const { LOG_ALWAYS_FATAL_IF(index >= mBuffer.size(), "Index %zu out of bounds, size is %zu.", index, mBuffer.size()); size_t pos = (index >= mFrontIdx) ? mBuffer.size() - 1 - (index - mFrontIdx) : mFrontIdx - 1 - index; return mBuffer[pos]; } template size_t RingBuffer::size() const { return mBuffer.size(); } template void RingBuffer::clear() { mBuffer.clear(); mFrontIdx = 0; } } // namespace SensorServiceUtil }; // namespace android #endif // ANDROID_SENSOR_SERVICE_UTIL_RING_BUFFER_H