/* * SRT - Secure, Reliable, Transport * Copyright (c) 2018 Haivision Systems Inc. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * */ /***************************************************************************** Copyright (c) 2001 - 2011, The Board of Trustees of the University of Illinois. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the University of Illinois nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. *****************************************************************************/ /***************************************************************************** written by Yunhong Gu, last updated 01/12/2011 modified by Haivision Systems Inc. *****************************************************************************/ #ifndef INC_SRT_QUEUE_H #define INC_SRT_QUEUE_H #include "channel.h" #include "common.h" #include "packet.h" #include "netinet_any.h" #include "utilities.h" #include #include #include #include class CUDT; struct CUnit { CPacket m_Packet; // packet enum Flag { FREE = 0, GOOD = 1, PASSACK = 2, DROPPED = 3 }; Flag m_iFlag; // 0: free, 1: occupied, 2: msg read but not freed (out-of-order), 3: msg dropped }; class CUnitQueue { public: CUnitQueue(); ~CUnitQueue(); public: // Storage size operations /// Initialize the unit queue. /// @param [in] size queue size /// @param [in] mss maximum segment size /// @param [in] version IP version /// @return 0: success, -1: failure. int init(int size, int mss, int version); /// Increase (double) the unit queue size. /// @return 0: success, -1: failure. int increase(); /// Decrease (halve) the unit queue size. /// @return 0: success, -1: failure. int shrink(); public: int size() const { return m_iSize - m_iCount; } int capacity() const { return m_iSize; } public: // Operations on units /// find an available unit for incoming packet. /// @return Pointer to the available unit, NULL if not found. CUnit* getNextAvailUnit(); void makeUnitFree(CUnit * unit); void makeUnitGood(CUnit * unit); public: inline int getIPversion() const { return m_iIPversion; } private: struct CQEntry { CUnit* m_pUnit; // unit queue char* m_pBuffer; // data buffer int m_iSize; // size of each queue CQEntry* m_pNext; } *m_pQEntry, // pointer to the first unit queue *m_pCurrQueue, // pointer to the current available queue *m_pLastQueue; // pointer to the last unit queue CUnit* m_pAvailUnit; // recent available unit int m_iSize; // total size of the unit queue, in number of packets int m_iCount; // total number of valid (occupied) packets in the queue int m_iMSS; // unit buffer size int m_iIPversion; // IP version private: CUnitQueue(const CUnitQueue&); CUnitQueue& operator=(const CUnitQueue&); }; struct CSNode { CUDT* m_pUDT; // Pointer to the instance of CUDT socket srt::sync::steady_clock::time_point m_tsTimeStamp; int m_iHeapLoc; // location on the heap, -1 means not on the heap }; class CSndUList { friend class CSndQueue; public: CSndUList(); ~CSndUList(); public: enum EReschedule { DONT_RESCHEDULE = 0, DO_RESCHEDULE = 1 }; static EReschedule rescheduleIf(bool cond) { return cond ? DO_RESCHEDULE : DONT_RESCHEDULE; } /// Update the timestamp of the UDT instance on the list. /// @param [in] u pointer to the UDT instance /// @param [in] reschedule if the timestamp should be rescheduled void update(const CUDT* u, EReschedule reschedule); /// Retrieve the next packet and peer address from the first entry, and reschedule it in the queue. /// @param [out] addr destination address of the next packet /// @param [out] pkt the next packet to be sent /// @return 1 if successfully retrieved, -1 if no packet found. int pop(sockaddr_any& addr, CPacket& pkt); /// Remove UDT instance from the list. /// @param [in] u pointer to the UDT instance void remove(const CUDT* u); /// Retrieve the next scheduled processing time. /// @return Scheduled processing time of the first UDT socket in the list. srt::sync::steady_clock::time_point getNextProcTime(); private: /// Doubles the size of the list. /// void realloc_(); /// Insert a new UDT instance into the list with realloc if required. /// /// @param [in] ts time stamp: next processing time /// @param [in] u pointer to the UDT instance void insert_(const srt::sync::steady_clock::time_point &ts, const CUDT* u); /// Insert a new UDT instance into the list without realloc. /// Should be called if there is a gauranteed space for the element. /// /// @param [in] ts time stamp: next processing time /// @param [in] u pointer to the UDT instance void insert_norealloc_(const srt::sync::steady_clock::time_point &ts, const CUDT* u); void remove_(const CUDT* u); private: CSNode** m_pHeap; // The heap array int m_iArrayLength; // physical length of the array int m_iLastEntry; // position of last entry on the heap array srt::sync::Mutex m_ListLock; srt::sync::Mutex* m_pWindowLock; srt::sync::Condition* m_pWindowCond; srt::sync::CTimer* m_pTimer; private: CSndUList(const CSndUList&); CSndUList& operator=(const CSndUList&); }; struct CRNode { CUDT* m_pUDT; // Pointer to the instance of CUDT socket srt::sync::steady_clock::time_point m_tsTimeStamp; // Time Stamp CRNode* m_pPrev; // previous link CRNode* m_pNext; // next link bool m_bOnList; // if the node is already on the list }; class CRcvUList { public: CRcvUList(); ~CRcvUList(); public: /// Insert a new UDT instance to the list. /// @param [in] u pointer to the UDT instance void insert(const CUDT* u); /// Remove the UDT instance from the list. /// @param [in] u pointer to the UDT instance void remove(const CUDT* u); /// Move the UDT instance to the end of the list, if it already exists; otherwise, do nothing. /// @param [in] u pointer to the UDT instance void update(const CUDT* u); public: CRNode* m_pUList; // the head node private: CRNode* m_pLast; // the last node private: CRcvUList(const CRcvUList&); CRcvUList& operator=(const CRcvUList&); }; class CHash { public: CHash(); ~CHash(); public: /// Initialize the hash table. /// @param [in] size hash table size void init(int size); /// Look for a UDT instance from the hash table. /// @param [in] id socket ID /// @return Pointer to a UDT instance, or NULL if not found. CUDT* lookup(int32_t id); /// Insert an entry to the hash table. /// @param [in] id socket ID /// @param [in] u pointer to the UDT instance void insert(int32_t id, CUDT* u); /// Remove an entry from the hash table. /// @param [in] id socket ID void remove(int32_t id); private: struct CBucket { int32_t m_iID; // Socket ID CUDT* m_pUDT; // Socket instance CBucket* m_pNext; // next bucket } **m_pBucket; // list of buckets (the hash table) int m_iHashSize; // size of hash table private: CHash(const CHash&); CHash& operator=(const CHash&); }; class CRendezvousQueue { public: CRendezvousQueue(); ~CRendezvousQueue(); public: void insert(const SRTSOCKET& id, CUDT* u, const sockaddr_any& addr, const srt::sync::steady_clock::time_point &ttl); // The should_lock parameter is given here to state as to whether // the lock should be applied here. If called from some internals // and the lock IS ALREADY APPLIED, use false here to prevent // double locking and deadlock in result. void remove(const SRTSOCKET& id, bool should_lock); CUDT* retrieve(const sockaddr_any& addr, SRTSOCKET& id); void updateConnStatus(EReadStatus rst, EConnectStatus, const CPacket& response); private: struct CRL { SRTSOCKET m_iID; // UDT socket ID (self) CUDT* m_pUDT; // UDT instance sockaddr_any m_PeerAddr;// UDT sonnection peer address srt::sync::steady_clock::time_point m_tsTTL; // the time that this request expires }; std::list m_lRendezvousID; // The sockets currently in rendezvous mode srt::sync::Mutex m_RIDVectorLock; }; class CSndQueue { friend class CUDT; friend class CUDTUnited; public: CSndQueue(); ~CSndQueue(); public: // XXX There's currently no way to access the socket ID set for // whatever the queue is currently working for. Required to find // some way to do this, possibly by having a "reverse pointer". // Currently just "unimplemented". std::string CONID() const { return ""; } /// Initialize the sending queue. /// @param [in] c UDP channel to be associated to the queue /// @param [in] t Timer void init(CChannel* c, srt::sync::CTimer* t); /// Send out a packet to a given address. /// @param [in] addr destination address /// @param [in] packet packet to be sent out /// @return Size of data sent out. int sendto(const sockaddr_any& addr, CPacket& packet); /// Get the IP TTL. /// @param [in] ttl IP Time To Live. /// @return TTL. int getIpTTL() const; /// Get the IP Type of Service. /// @return ToS. int getIpToS() const; #ifdef SRT_ENABLE_BINDTODEVICE bool getBind(char* dst, size_t len) const; #endif int ioctlQuery(int type) const { return m_pChannel->ioctlQuery(type); } int sockoptQuery(int level, int type) const { return m_pChannel->sockoptQuery(level, type); } void setClosing() { m_bClosing = true; } private: static void* worker(void* param); srt::sync::CThread m_WorkerThread; private: CSndUList* m_pSndUList; // List of UDT instances for data sending CChannel* m_pChannel; // The UDP channel for data sending srt::sync::CTimer* m_pTimer; // Timing facility srt::sync::Mutex m_WindowLock; srt::sync::Condition m_WindowCond; volatile bool m_bClosing; // closing the worker #if defined(SRT_DEBUG_SNDQ_HIGHRATE)//>>debug high freq worker uint64_t m_ullDbgPeriod; uint64_t m_ullDbgTime; struct { unsigned long lIteration; // unsigned long lSleepTo; //SleepTo unsigned long lNotReadyPop; //Continue unsigned long lSendTo; unsigned long lNotReadyTs; unsigned long lCondWait; //block on m_WindowCond } m_WorkerStats; #endif /* SRT_DEBUG_SNDQ_HIGHRATE */ #if ENABLE_LOGGING static int m_counter; #endif private: CSndQueue(const CSndQueue&); CSndQueue& operator=(const CSndQueue&); }; class CRcvQueue { friend class CUDT; friend class CUDTUnited; public: CRcvQueue(); ~CRcvQueue(); public: // XXX There's currently no way to access the socket ID set for // whatever the queue is currently working. Required to find // some way to do this, possibly by having a "reverse pointer". // Currently just "unimplemented". std::string CONID() const { return ""; } /// Initialize the receiving queue. /// @param [in] size queue size /// @param [in] mss maximum packet size /// @param [in] version IP version /// @param [in] hsize hash table size /// @param [in] c UDP channel to be associated to the queue /// @param [in] t timer void init(int size, int payload, int version, int hsize, CChannel* c, srt::sync::CTimer* t); /// Read a packet for a specific UDT socket id. /// @param [in] id Socket ID /// @param [out] packet received packet /// @return Data size of the packet int recvfrom(int32_t id, CPacket& to_packet); void stopWorker(); void setClosing() { m_bClosing = true; } private: static void* worker(void* param); srt::sync::CThread m_WorkerThread; // Subroutines of worker EReadStatus worker_RetrieveUnit(int32_t& id, CUnit*& unit, sockaddr_any& sa); EConnectStatus worker_ProcessConnectionRequest(CUnit* unit, const sockaddr_any& sa); EConnectStatus worker_TryAsyncRend_OrStore(int32_t id, CUnit* unit, const sockaddr_any& sa); EConnectStatus worker_ProcessAddressedPacket(int32_t id, CUnit* unit, const sockaddr_any& sa); private: CUnitQueue m_UnitQueue; // The received packet queue CRcvUList* m_pRcvUList; // List of UDT instances that will read packets from the queue CHash* m_pHash; // Hash table for UDT socket looking up CChannel* m_pChannel; // UDP channel for receving packets srt::sync::CTimer* m_pTimer; // shared timer with the snd queue int m_iPayloadSize; // packet payload size volatile bool m_bClosing; // closing the worker #if ENABLE_LOGGING static int m_counter; #endif private: int setListener(CUDT* u); void removeListener(const CUDT* u); void registerConnector(const SRTSOCKET& id, CUDT* u, const sockaddr_any& addr, const srt::sync::steady_clock::time_point& ttl); void removeConnector(const SRTSOCKET& id, bool should_lock = true); void setNewEntry(CUDT* u); bool ifNewEntry(); CUDT* getNewEntry(); void storePkt(int32_t id, CPacket* pkt); private: srt::sync::Mutex m_LSLock; CUDT* m_pListener; // pointer to the (unique, if any) listening UDT entity CRendezvousQueue* m_pRendezvousQueue; // The list of sockets in rendezvous mode std::vector m_vNewEntry; // newly added entries, to be inserted srt::sync::Mutex m_IDLock; std::map > m_mBuffer; // temporary buffer for rendezvous connection request srt::sync::Mutex m_BufferLock; srt::sync::Condition m_BufferCond; private: CRcvQueue(const CRcvQueue&); CRcvQueue& operator=(const CRcvQueue&); }; struct CMultiplexer { CSndQueue* m_pSndQueue; // The sending queue CRcvQueue* m_pRcvQueue; // The receiving queue CChannel* m_pChannel; // The UDP channel for sending and receiving srt::sync::CTimer* m_pTimer; // The timer int m_iPort; // The UDP port number of this multiplexer int m_iIPversion; // Address family (AF_INET or AF_INET6) int m_iIpTTL; int m_iIpToS; #ifdef SRT_ENABLE_BINDTODEVICE std::string m_BindToDevice; #endif int m_iMSS; // Maximum Segment Size int m_iRefCount; // number of UDT instances that are associated with this multiplexer int m_iIpV6Only; // IPV6_V6ONLY option bool m_bReusable; // if this one can be shared with others int m_iID; // multiplexer ID // Constructor should reset all pointers to NULL // to prevent dangling pointer when checking for memory alloc fails CMultiplexer() : m_pSndQueue(NULL) , m_pRcvQueue(NULL) , m_pChannel(NULL) , m_pTimer(NULL) { } void destroy(); }; #endif