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https://github.com/wolfpld/tracy.git
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241 lines
8.9 KiB
C
241 lines
8.9 KiB
C
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// Copyright (c) 2013 Doug Binks
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//
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// This software is provided 'as-is', without any express or implied
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// warranty. In no event will the authors be held liable for any damages
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// arising from the use of this software.
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//
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// Permission is granted to anyone to use this software for any purpose,
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// including commercial applications, and to alter it and redistribute it
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// freely, subject to the following restrictions:
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//
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// 1. The origin of this software must not be misrepresented; you must not
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// claim that you wrote the original software. If you use this software
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// in a product, an acknowledgement in the product documentation would be
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// appreciated but is not required.
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// 2. Altered source versions must be plainly marked as such, and must not be
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// misrepresented as being the original software.
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// 3. This notice may not be removed or altered from any source distribution.
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#pragma once
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#include <stdint.h>
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#include <assert.h>
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#include "Atomics.h"
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#include <string.h>
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namespace enki
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{
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// LockLessMultiReadPipe - Single writer, multiple reader thread safe pipe using (semi) lockless programming
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// Readers can only read from the back of the pipe
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// The single writer can write to the front of the pipe, and read from both ends (a writer can be a reader)
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// for many of the principles used here, see http://msdn.microsoft.com/en-us/library/windows/desktop/ee418650(v=vs.85).aspx
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// Note: using log2 sizes so we do not need to clamp (multi-operation)
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// T is the contained type
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// Note this is not true lockless as the use of flags as a form of lock state.
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template<uint8_t cSizeLog2, typename T> class LockLessMultiReadPipe
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{
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public:
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LockLessMultiReadPipe();
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~LockLessMultiReadPipe() {}
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// ReaderTryReadBack returns false if we were unable to read
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// This is thread safe for both multiple readers and the writer
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bool ReaderTryReadBack( T* pOut );
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// WriterTryReadFront returns false if we were unable to read
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// This is thread safe for the single writer, but should not be called by readers
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bool WriterTryReadFront( T* pOut );
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// WriterTryWriteFront returns false if we were unable to write
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// This is thread safe for the single writer, but should not be called by readers
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bool WriterTryWriteFront( const T& in );
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// IsPipeEmpty() is a utility function, not intended for general use
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// Should only be used very prudently.
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bool IsPipeEmpty() const
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{
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return 0 == m_WriteIndex - m_ReadCount;
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}
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void Clear()
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{
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m_WriteIndex = 0;
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m_ReadIndex = 0;
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m_ReadCount = 0;
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memset( (void*)m_Flags, 0, sizeof( m_Flags ) );
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}
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private:
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const static uint32_t ms_cSize = ( 1 << cSizeLog2 );
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const static uint32_t ms_cIndexMask = ms_cSize - 1;
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const static uint32_t FLAG_INVALID = 0xFFFFFFFF; // 32bit for CAS
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const static uint32_t FLAG_CAN_WRITE = 0x00000000; // 32bit for CAS
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const static uint32_t FLAG_CAN_READ = 0x11111111; // 32bit for CAS
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T m_Buffer[ ms_cSize ];
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// read and write indexes allow fast access to the pipe, but actual access
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// controlled by the access flags.
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volatile uint32_t BASE_ALIGN(4) m_WriteIndex;
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volatile uint32_t BASE_ALIGN(4) m_ReadCount;
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volatile uint32_t m_Flags[ ms_cSize ];
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volatile uint32_t BASE_ALIGN(4) m_ReadIndex;
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};
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template<uint8_t cSizeLog2, typename T> inline
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LockLessMultiReadPipe<cSizeLog2,T>::LockLessMultiReadPipe()
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: m_WriteIndex(0)
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, m_ReadIndex(0)
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, m_ReadCount(0)
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{
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assert( cSizeLog2 < 32 );
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memset( (void*)m_Flags, 0, sizeof( m_Flags ) );
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}
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template<uint8_t cSizeLog2, typename T> inline
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bool LockLessMultiReadPipe<cSizeLog2,T>::ReaderTryReadBack( T* pOut )
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{
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uint32_t actualReadIndex;
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uint32_t readCount = m_ReadCount;
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// We get hold of read index for consistency,
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// and do first pass starting at read count
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uint32_t readIndexToUse = readCount;
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while(true)
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{
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uint32_t writeIndex = m_WriteIndex;
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// power of two sizes ensures we can use a simple calc without modulus
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uint32_t numInPipe = writeIndex - readCount;
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if( 0 == numInPipe )
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{
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return false;
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}
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if( readIndexToUse >= writeIndex )
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{
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// move back to start
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readIndexToUse = m_ReadIndex;
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}
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// power of two sizes ensures we can perform AND for a modulus
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actualReadIndex = readIndexToUse & ms_cIndexMask;
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// Multiple potential readers mean we should check if the data is valid,
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// using an atomic compare exchange
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uint32_t previous = AtomicCompareAndSwap( &m_Flags[ actualReadIndex ], FLAG_INVALID, FLAG_CAN_READ );
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if( FLAG_CAN_READ == previous )
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{
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break;
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}
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++readIndexToUse;
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//update known readcount
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readCount = m_ReadCount;
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}
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// we update the read index using an atomic add, as we've only read one piece of data.
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// this ensure consistency of the read index, and the above loop ensures readers
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// only read from unread data
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AtomicAdd( (volatile int32_t*)&m_ReadCount, 1 );
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BASE_MEMORYBARRIER_ACQUIRE();
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// now read data, ensuring we do so after above reads & CAS
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*pOut = m_Buffer[ actualReadIndex ];
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m_Flags[ actualReadIndex ] = FLAG_CAN_WRITE;
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return true;
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}
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template<uint8_t cSizeLog2, typename T> inline
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bool LockLessMultiReadPipe<cSizeLog2,T>::WriterTryReadFront( T* pOut )
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{
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uint32_t writeIndex = m_WriteIndex;
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uint32_t frontReadIndex = writeIndex;
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// Multiple potential readers mean we should check if the data is valid,
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// using an atomic compare exchange - which acts as a form of lock (so not quite lockless really).
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uint32_t previous = FLAG_INVALID;
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uint32_t actualReadIndex = 0;
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while( true )
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{
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// power of two sizes ensures we can use a simple calc without modulus
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uint32_t readCount = m_ReadCount;
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uint32_t numInPipe = writeIndex - readCount;
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if( 0 == numInPipe || 0 == frontReadIndex )
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{
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// frontReadIndex can get to 0 here if that item was just being read by another thread.
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m_ReadIndex = readCount;
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return false;
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}
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--frontReadIndex;
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actualReadIndex = frontReadIndex & ms_cIndexMask;
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previous = AtomicCompareAndSwap( &m_Flags[ actualReadIndex ], FLAG_INVALID, FLAG_CAN_READ );
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if( FLAG_CAN_READ == previous )
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{
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break;
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}
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else if( m_ReadIndex >= frontReadIndex )
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{
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return false;
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}
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}
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// now read data, ensuring we do so after above reads & CAS
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*pOut = m_Buffer[ actualReadIndex ];
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m_Flags[ actualReadIndex ] = FLAG_CAN_WRITE;
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BASE_MEMORYBARRIER_RELEASE();
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// 32-bit aligned stores are atomic, and writer owns the write index
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// we only move one back as this is as many as we have read, not where we have read from.
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--m_WriteIndex;
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return true;
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}
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template<uint8_t cSizeLog2, typename T> inline
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bool LockLessMultiReadPipe<cSizeLog2,T>::WriterTryWriteFront( const T& in )
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{
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// The writer 'owns' the write index, and readers can only reduce
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// the amount of data in the pipe.
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// We get hold of both values for consistency and to reduce false sharing
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// impacting more than one access
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uint32_t writeIndex = m_WriteIndex;
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// power of two sizes ensures we can perform AND for a modulus
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uint32_t actualWriteIndex = writeIndex & ms_cIndexMask;
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// a reader may still be reading this item, as there are multiple readers
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if( m_Flags[ actualWriteIndex ] != FLAG_CAN_WRITE )
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{
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return false; // still being read, so have caught up with tail.
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}
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// as we are the only writer we can update the data without atomics
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// whilst the write index has not been updated
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m_Buffer[ actualWriteIndex ] = in;
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m_Flags[ actualWriteIndex ] = FLAG_CAN_READ;
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// We need to ensure the above writes occur prior to updating the write index,
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// otherwise another thread might read before it's finished
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BASE_MEMORYBARRIER_RELEASE();
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// 32-bit aligned stores are atomic, and the writer controls the write index
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++writeIndex;
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m_WriteIndex = writeIndex;
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return true;
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}
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}
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