/* * FreeRTOS+TCP * Copyright (C) 2021 Amazon.com, Inc. or its affiliates. All Rights Reserved. * * SPDX-License-Identifier: MIT * * Permission is hereby granted, free of charge, to any person obtaining a copy of * this software and associated documentation files (the "Software"), to deal in * the Software without restriction, including without limitation the rights to * use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of * the Software, and to permit persons to whom the Software is furnished to do so, * subject to the following conditions: * * The above copyright notice and this permission notice shall be included in all * copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS * FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR * COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER * IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. * * http://aws.amazon.com/freertos * http://www.FreeRTOS.org */ /** * @file FreeRTOS_TCP_IP.c * @brief Module which handles the TCP connections for FreeRTOS+TCP. * It depends on FreeRTOS_TCP_WIN.c, which handles the TCP windowing * schemes. * * Endianness: in this module all ports and IP addresses are stored in * host byte-order, except fields in the IP-packets */ /* Standard includes. */ #include #include /* FreeRTOS includes. */ #include "FreeRTOS.h" #include "task.h" #include "queue.h" #include "semphr.h" /* FreeRTOS+TCP includes. */ #include "FreeRTOS_IP.h" #include "FreeRTOS_Sockets.h" #include "FreeRTOS_IP_Private.h" #include "FreeRTOS_UDP_IP.h" #include "FreeRTOS_DHCP.h" #include "NetworkInterface.h" #include "NetworkBufferManagement.h" #include "FreeRTOS_ARP.h" #include "FreeRTOS_TCP_Reception.h" #include "FreeRTOS_TCP_Transmission.h" #include "FreeRTOS_TCP_State_Handling.h" #include "FreeRTOS_TCP_Utils.h" /* Just make sure the contents doesn't get compiled if TCP is not enabled. */ #if ipconfigUSE_TCP == 1 /* declared global for unit testing purposes */ /* coverity[misra_c_2012_rule_8_9_violation] */ /** @brief Socket which needs to be closed in next iteration. */ static FreeRTOS_Socket_t * xPreviousSocket = NULL; /* * For anti-hang protection and TCP keep-alive messages. Called in two places: * after receiving a packet and after a state change. The socket's alive timer * may be reset. */ static void prvTCPTouchSocket( FreeRTOS_Socket_t * pxSocket ); /* * Calculate when this socket needs to be checked to do (re-)transmissions. */ static TickType_t prvTCPNextTimeout( FreeRTOS_Socket_t * pxSocket ); #if ( ipconfigHAS_DEBUG_PRINTF != 0 ) /* * For logging and debugging: make a string showing the TCP flags. */ const char * prvTCPFlagMeaning( UBaseType_t xFlags ); #endif /* ipconfigHAS_DEBUG_PRINTF != 0 */ /*-----------------------------------------------------------*/ /** @brief Close the socket another time. * * @param[in] pxSocket: The socket to be checked. */ void vSocketCloseNextTime( FreeRTOS_Socket_t * pxSocket ) { if( ( xPreviousSocket != NULL ) && ( xPreviousSocket != pxSocket ) ) { ( void ) vSocketClose( xPreviousSocket ); } xPreviousSocket = pxSocket; } /*-----------------------------------------------------------*/ /** * @brief As soon as a TCP socket timer expires, this function will be called * (from xTCPTimerCheck). It can send a delayed ACK or new data. * * @param[in] pxSocket: socket to be checked. * * @return 0 on success, a negative error code on failure. A negative value will be * returned in case the hang-protection has put the socket in a wait-close state. * * @note Sequence of calling (normally) : * IP-Task: * xTCPTimerCheck() // Check all sockets ( declared in FreeRTOS_Sockets.c ) * xTCPSocketCheck() // Either send a delayed ACK or call prvTCPSendPacket() * prvTCPSendPacket() // Either send a SYN or call prvTCPSendRepeated ( regular messages ) * prvTCPSendRepeated() // Send at most 8 messages on a row * prvTCPReturnPacket() // Prepare for returning * xNetworkInterfaceOutput() // Sends data to the NIC ( declared in portable/NetworkInterface/xxx ) */ BaseType_t xTCPSocketCheck( FreeRTOS_Socket_t * pxSocket ) { BaseType_t xResult = 0; BaseType_t xReady = pdFALSE; if( ( pxSocket->u.xTCP.eTCPState >= eESTABLISHED ) && ( pxSocket->u.xTCP.txStream != NULL ) ) { /* The API FreeRTOS_send() might have added data to the TX stream. Add * this data to the windowing system so it can be transmitted. */ prvTCPAddTxData( pxSocket ); } #if ( ipconfigUSE_TCP_WIN == 1 ) { if( pxSocket->u.xTCP.pxAckMessage != NULL ) { /* The first task of this regular socket check is to send-out delayed * ACK's. */ if( pxSocket->u.xTCP.bits.bUserShutdown == pdFALSE_UNSIGNED ) { /* Earlier data was received but not yet acknowledged. This * function is called when the TCP timer for the socket expires, the * ACK may be sent now. */ if( pxSocket->u.xTCP.eTCPState != eCLOSED ) { if( ( xTCPWindowLoggingLevel > 1 ) && ipconfigTCP_MAY_LOG_PORT( pxSocket->usLocalPort ) ) { FreeRTOS_debug_printf( ( "Send[%u->%u] del ACK %u SEQ %u (len %u)\n", pxSocket->usLocalPort, pxSocket->u.xTCP.usRemotePort, ( unsigned ) ( pxSocket->u.xTCP.xTCPWindow.rx.ulCurrentSequenceNumber - pxSocket->u.xTCP.xTCPWindow.rx.ulFirstSequenceNumber ), ( unsigned ) ( pxSocket->u.xTCP.xTCPWindow.ulOurSequenceNumber - pxSocket->u.xTCP.xTCPWindow.tx.ulFirstSequenceNumber ), ( unsigned ) ( ipSIZE_OF_IPv4_HEADER + ipSIZE_OF_TCP_HEADER ) ) ); } prvTCPReturnPacket( pxSocket, pxSocket->u.xTCP.pxAckMessage, ipSIZE_OF_IPv4_HEADER + ipSIZE_OF_TCP_HEADER, ipconfigZERO_COPY_TX_DRIVER ); #if ( ipconfigZERO_COPY_TX_DRIVER != 0 ) { /* The ownership has been passed to the SEND routine, * clear the pointer to it. */ pxSocket->u.xTCP.pxAckMessage = NULL; } #endif /* ipconfigZERO_COPY_TX_DRIVER */ } if( prvTCPNextTimeout( pxSocket ) > 1U ) { /* Tell the code below that this function is ready. */ xReady = pdTRUE; } } else { /* The user wants to perform an active shutdown(), skip sending * the delayed ACK. The function prvTCPSendPacket() will send the * FIN along with the ACK's. */ } if( pxSocket->u.xTCP.pxAckMessage != NULL ) { vReleaseNetworkBufferAndDescriptor( pxSocket->u.xTCP.pxAckMessage ); pxSocket->u.xTCP.pxAckMessage = NULL; } } } #endif /* ipconfigUSE_TCP_WIN */ if( xReady == pdFALSE ) { /* The second task of this regular socket check is sending out data. */ if( ( pxSocket->u.xTCP.eTCPState >= eESTABLISHED ) || ( pxSocket->u.xTCP.eTCPState == eCONNECT_SYN ) ) { ( void ) prvTCPSendPacket( pxSocket ); } /* Set the time-out for the next wakeup for this socket. */ ( void ) prvTCPNextTimeout( pxSocket ); #if ( ipconfigTCP_HANG_PROTECTION == 1 ) { /* In all (non-connected) states in which keep-alive messages can not be sent * the anti-hang protocol will close sockets that are 'hanging'. */ xResult = prvTCPStatusAgeCheck( pxSocket ); } #endif } return xResult; } /*-----------------------------------------------------------*/ /** * @brief 'Touch' the socket to keep it alive/updated. * * @param[in] pxSocket: The socket to be updated. * * @note This is used for anti-hanging protection and TCP keep-alive messages. * Called in two places: after receiving a packet and after a state change. * The socket's alive timer may be reset. */ static void prvTCPTouchSocket( FreeRTOS_Socket_t * pxSocket ) { #if ( ipconfigTCP_HANG_PROTECTION == 1 ) { pxSocket->u.xTCP.xLastActTime = xTaskGetTickCount(); } #endif #if ( ipconfigTCP_KEEP_ALIVE == 1 ) { pxSocket->u.xTCP.bits.bWaitKeepAlive = pdFALSE_UNSIGNED; pxSocket->u.xTCP.bits.bSendKeepAlive = pdFALSE_UNSIGNED; pxSocket->u.xTCP.ucKeepRepCount = 0U; pxSocket->u.xTCP.xLastAliveTime = xTaskGetTickCount(); } #endif ( void ) pxSocket; } /*-----------------------------------------------------------*/ /** * @brief Changing to a new state. Centralised here to do specific actions such as * resetting the alive timer, calling the user's OnConnect handler to notify * that a socket has got (dis)connected, and setting bit to unblock a call to * FreeRTOS_select(). * * @param[in] pxSocket: The socket whose state we are trying to change. * @param[in] eTCPState: The state to which we want to change to. */ void vTCPStateChange( FreeRTOS_Socket_t * pxSocket, enum eTCP_STATE eTCPState ) { FreeRTOS_Socket_t * xParent = NULL; BaseType_t bBefore = tcpNOW_CONNECTED( ( BaseType_t ) pxSocket->u.xTCP.eTCPState ); /* Was it connected ? */ BaseType_t bAfter = tcpNOW_CONNECTED( ( BaseType_t ) eTCPState ); /* Is it connected now ? */ #if ( ipconfigHAS_DEBUG_PRINTF != 0 ) BaseType_t xPreviousState = ( BaseType_t ) pxSocket->u.xTCP.eTCPState; #endif #if ( ipconfigUSE_CALLBACKS == 1 ) FreeRTOS_Socket_t * xConnected = NULL; #endif /* Has the connected status changed? */ if( bBefore != bAfter ) { /* Is the socket connected now ? */ if( bAfter != pdFALSE ) { /* if bPassQueued is true, this socket is an orphan until it gets connected. */ if( pxSocket->u.xTCP.bits.bPassQueued != pdFALSE_UNSIGNED ) { /* Now that it is connected, find it's parent. */ if( pxSocket->u.xTCP.bits.bReuseSocket != pdFALSE_UNSIGNED ) { xParent = pxSocket; } else { xParent = pxSocket->u.xTCP.pxPeerSocket; configASSERT( xParent != NULL ); } if( xParent != NULL ) { if( xParent->u.xTCP.pxPeerSocket == NULL ) { xParent->u.xTCP.pxPeerSocket = pxSocket; } xParent->xEventBits |= ( EventBits_t ) eSOCKET_ACCEPT; #if ( ipconfigSUPPORT_SELECT_FUNCTION == 1 ) { /* Library support FreeRTOS_select(). Receiving a new * connection is being translated as a READ event. */ if( ( xParent->xSelectBits & ( ( EventBits_t ) eSELECT_READ ) ) != 0U ) { xParent->xEventBits |= ( ( EventBits_t ) eSELECT_READ ) << SOCKET_EVENT_BIT_COUNT; } } #endif #if ( ipconfigUSE_CALLBACKS == 1 ) { if( ( ipconfigIS_VALID_PROG_ADDRESS( xParent->u.xTCP.pxHandleConnected ) ) && ( xParent->u.xTCP.bits.bReuseSocket == pdFALSE_UNSIGNED ) ) { /* The listening socket does not become connected itself, in stead * a child socket is created. * Postpone a call the OnConnect event until the end of this function. */ xConnected = xParent; } } #endif } /* Don't need to access the parent socket anymore, so the * reference 'pxPeerSocket' may be cleared. */ pxSocket->u.xTCP.pxPeerSocket = NULL; pxSocket->u.xTCP.bits.bPassQueued = pdFALSE_UNSIGNED; /* When true, this socket may be returned in a call to accept(). */ pxSocket->u.xTCP.bits.bPassAccept = pdTRUE_UNSIGNED; } else { pxSocket->xEventBits |= ( EventBits_t ) eSOCKET_CONNECT; #if ( ipconfigSUPPORT_SELECT_FUNCTION == 1 ) { if( ( pxSocket->xSelectBits & ( ( EventBits_t ) eSELECT_WRITE ) ) != 0U ) { pxSocket->xEventBits |= ( ( EventBits_t ) eSELECT_WRITE ) << SOCKET_EVENT_BIT_COUNT; } } #endif } } else /* bAfter == pdFALSE, connection is closed. */ { /* Notify/wake-up the socket-owner by setting a semaphore. */ pxSocket->xEventBits |= ( EventBits_t ) eSOCKET_CLOSED; #if ( ipconfigSUPPORT_SELECT_FUNCTION == 1 ) { if( ( pxSocket->xSelectBits & ( EventBits_t ) eSELECT_EXCEPT ) != 0U ) { pxSocket->xEventBits |= ( ( EventBits_t ) eSELECT_EXCEPT ) << SOCKET_EVENT_BIT_COUNT; } } #endif } #if ( ipconfigUSE_CALLBACKS == 1 ) { if( ( ipconfigIS_VALID_PROG_ADDRESS( pxSocket->u.xTCP.pxHandleConnected ) ) && ( xConnected == NULL ) ) { /* The 'connected' state has changed, call the user handler. */ xConnected = pxSocket; } } #endif /* ipconfigUSE_CALLBACKS */ if( prvTCPSocketIsActive( pxSocket->u.xTCP.eTCPState ) == 0 ) { /* Now the socket isn't in an active state anymore so it * won't need further attention of the IP-task. * Setting time-out to zero means that the socket won't get checked during * timer events. */ pxSocket->u.xTCP.usTimeout = 0U; } } else { if( ( eTCPState == eCLOSED ) || ( eTCPState == eCLOSE_WAIT ) ) { /* Socket goes to status eCLOSED because of a RST. * When nobody owns the socket yet, delete it. */ if( ( pxSocket->u.xTCP.bits.bPassQueued != pdFALSE_UNSIGNED ) || ( pxSocket->u.xTCP.bits.bPassAccept != pdFALSE_UNSIGNED ) ) { FreeRTOS_debug_printf( ( "vTCPStateChange: Closing socket\n" ) ); if( pxSocket->u.xTCP.bits.bReuseSocket == pdFALSE_UNSIGNED ) { configASSERT( xIsCallingFromIPTask() != pdFALSE ); vSocketCloseNextTime( pxSocket ); } } } } /* Fill in the new state. */ pxSocket->u.xTCP.eTCPState = eTCPState; /* Touch the alive timers because moving to another state. */ prvTCPTouchSocket( pxSocket ); #if ( ipconfigHAS_DEBUG_PRINTF == 1 ) { if( ( xTCPWindowLoggingLevel >= 0 ) && ( ipconfigTCP_MAY_LOG_PORT( pxSocket->usLocalPort ) ) ) { FreeRTOS_debug_printf( ( "Socket %u -> %xip:%u State %s->%s\n", pxSocket->usLocalPort, ( unsigned ) pxSocket->u.xTCP.ulRemoteIP, pxSocket->u.xTCP.usRemotePort, FreeRTOS_GetTCPStateName( ( UBaseType_t ) xPreviousState ), FreeRTOS_GetTCPStateName( ( UBaseType_t ) eTCPState ) ) ); } } #endif /* ipconfigHAS_DEBUG_PRINTF */ #if ( ipconfigUSE_CALLBACKS == 1 ) { if( xConnected != NULL ) { /* The 'connected' state has changed, call the OnConnect handler of the parent. */ xConnected->u.xTCP.pxHandleConnected( ( Socket_t ) xConnected, bAfter ); } } #endif if( xParent != NULL ) { vSocketWakeUpUser( xParent ); } } /*-----------------------------------------------------------*/ /** * @brief Calculate after how much time this socket needs to be checked again. * * @param[in] pxSocket: The socket to be checked. * * @return The number of clock ticks before the timer expires. */ static TickType_t prvTCPNextTimeout( FreeRTOS_Socket_t * pxSocket ) { TickType_t ulDelayMs = ( TickType_t ) tcpMAXIMUM_TCP_WAKEUP_TIME_MS; if( pxSocket->u.xTCP.eTCPState == eCONNECT_SYN ) { /* The socket is actively connecting to a peer. */ if( pxSocket->u.xTCP.bits.bConnPrepared != pdFALSE_UNSIGNED ) { /* Ethernet address has been found, use progressive timeout for * active connect(). */ if( pxSocket->u.xTCP.ucRepCount < 3U ) { ulDelayMs = ( ( ( uint32_t ) 3000U ) << ( pxSocket->u.xTCP.ucRepCount - 1U ) ); } else { ulDelayMs = 11000U; } } else { /* Still in the ARP phase: check every half second. */ ulDelayMs = 500U; } FreeRTOS_debug_printf( ( "Connect[%xip:%u]: next timeout %u: %u ms\n", ( unsigned ) pxSocket->u.xTCP.ulRemoteIP, pxSocket->u.xTCP.usRemotePort, pxSocket->u.xTCP.ucRepCount, ( unsigned ) ulDelayMs ) ); pxSocket->u.xTCP.usTimeout = ( uint16_t ) ipMS_TO_MIN_TICKS( ulDelayMs ); } else if( pxSocket->u.xTCP.usTimeout == 0U ) { /* Let the sliding window mechanism decide what time-out is appropriate. */ BaseType_t xResult = xTCPWindowTxHasData( &pxSocket->u.xTCP.xTCPWindow, pxSocket->u.xTCP.ulWindowSize, &ulDelayMs ); if( ulDelayMs == 0U ) { if( xResult != ( BaseType_t ) 0 ) { ulDelayMs = 1U; } else { ulDelayMs = tcpMAXIMUM_TCP_WAKEUP_TIME_MS; } } else { /* ulDelayMs contains the time to wait before a re-transmission. */ } pxSocket->u.xTCP.usTimeout = ( uint16_t ) ipMS_TO_MIN_TICKS( ulDelayMs ); /* LCOV_EXCL_BR_LINE ulDelayMs will not be smaller than 1 */ } else { /* field '.usTimeout' has already been set (by the * keep-alive/delayed-ACK mechanism). */ } /* Return the number of clock ticks before the timer expires. */ return ( TickType_t ) pxSocket->u.xTCP.usTimeout; } /*-----------------------------------------------------------*/ /** * @brief Process the received TCP packet. * * @param[in] pxDescriptor: The descriptor in which the TCP packet is held. * * @return If the processing of the packet was successful, then pdPASS is returned * or else pdFAIL. * * @note FreeRTOS_TCP_IP has only 2 public functions, this is the second one: * xProcessReceivedTCPPacket() * prvTCPHandleState() * prvTCPPrepareSend() * prvTCPReturnPacket() * xNetworkInterfaceOutput() // Sends data to the NIC * prvTCPSendRepeated() * prvTCPReturnPacket() // Prepare for returning * xNetworkInterfaceOutput() // Sends data to the NIC */ BaseType_t xProcessReceivedTCPPacket( NetworkBufferDescriptor_t * pxDescriptor ) { /* Function might modify the parameter. */ NetworkBufferDescriptor_t * pxNetworkBuffer = pxDescriptor; configASSERT( pxNetworkBuffer != NULL ); configASSERT( pxNetworkBuffer->pucEthernetBuffer != NULL ); /* Map the buffer onto a ProtocolHeaders_t struct for easy access to the fields. */ /* MISRA C-2012 Rule 11.3 warns about casting pointer type to a different data type. * The struct to be casted to is defined as a packed struct. The cast won't cause misalignment. */ /* coverity[misra_c_2012_rule_11_3_violation] */ const ProtocolHeaders_t * pxProtocolHeaders = ( ( const ProtocolHeaders_t * ) &( pxNetworkBuffer->pucEthernetBuffer[ ipSIZE_OF_ETH_HEADER + xIPHeaderSize( pxNetworkBuffer ) ] ) ); FreeRTOS_Socket_t * pxSocket; uint16_t ucTCPFlags = pxProtocolHeaders->xTCPHeader.ucTCPFlags; uint32_t ulLocalIP; uint16_t usLocalPort = FreeRTOS_htons( pxProtocolHeaders->xTCPHeader.usDestinationPort ); uint16_t usRemotePort = FreeRTOS_htons( pxProtocolHeaders->xTCPHeader.usSourcePort ); uint32_t ulRemoteIP; uint32_t ulSequenceNumber = FreeRTOS_ntohl( pxProtocolHeaders->xTCPHeader.ulSequenceNumber ); uint32_t ulAckNumber = FreeRTOS_ntohl( pxProtocolHeaders->xTCPHeader.ulAckNr ); BaseType_t xResult = pdPASS; const IPHeader_t * pxIPHeader; /* Check for a minimum packet size. */ if( pxNetworkBuffer->xDataLength < ( ipSIZE_OF_ETH_HEADER + xIPHeaderSize( pxNetworkBuffer ) + ipSIZE_OF_TCP_HEADER ) ) { xResult = pdFAIL; } else { /* Map the ethernet buffer onto the IPHeader_t struct for easy access to the fields. */ /* MISRA C-2012 Rule 11.3 warns about casting pointer type to a different data type. * The struct to be casted to is defined as a packed struct. The cast won't cause misalignment. */ /* coverity[misra_c_2012_rule_11_3_violation] */ pxIPHeader = ( ( const IPHeader_t * ) &( pxNetworkBuffer->pucEthernetBuffer[ ipSIZE_OF_ETH_HEADER ] ) ); ulLocalIP = FreeRTOS_htonl( pxIPHeader->ulDestinationIPAddress ); ulRemoteIP = FreeRTOS_htonl( pxIPHeader->ulSourceIPAddress ); /* Find the destination socket, and if not found: return a socket listing to * the destination PORT. */ pxSocket = ( FreeRTOS_Socket_t * ) pxTCPSocketLookup( ulLocalIP, usLocalPort, ulRemoteIP, usRemotePort ); if( ( pxSocket == NULL ) || ( prvTCPSocketIsActive( pxSocket->u.xTCP.eTCPState ) == pdFALSE ) ) { /* A TCP messages is received but either there is no socket with the * given port number or the there is a socket, but it is in one of these * non-active states: eCLOSED, eCLOSE_WAIT, eFIN_WAIT_2, eCLOSING, or * eTIME_WAIT. */ FreeRTOS_debug_printf( ( "TCP: No active socket on port %d (%xip:%d)\n", usLocalPort, ( unsigned ) ulRemoteIP, usRemotePort ) ); /* Send a RST to all packets that can not be handled. As a result * the other party will get a ECONN error. There are two exceptions: * 1) A packet that already has the RST flag set. * 2) A packet that only has the ACK flag set. * A packet with only the ACK flag set might be the last ACK in * a three-way hand-shake that closes a connection. */ if( ( ( ucTCPFlags & tcpTCP_FLAG_CTRL ) != tcpTCP_FLAG_ACK ) && ( ( ucTCPFlags & tcpTCP_FLAG_RST ) == 0U ) ) { ( void ) prvTCPSendReset( pxNetworkBuffer ); } /* The packet can't be handled. */ xResult = pdFAIL; } else { pxSocket->u.xTCP.ucRepCount = 0U; if( pxSocket->u.xTCP.eTCPState == eTCP_LISTEN ) { /* The matching socket is in a listening state. Test if the peer * has set the SYN flag. */ if( ( ucTCPFlags & tcpTCP_FLAG_CTRL ) != tcpTCP_FLAG_SYN ) { /* What happens: maybe after a reboot, a client doesn't know the * connection had gone. Send a RST in order to get a new connect * request. */ #if ( ipconfigHAS_DEBUG_PRINTF == 1 ) { FreeRTOS_debug_printf( ( "TCP: Server can't handle flags: %s from %xip:%u to port %u\n", prvTCPFlagMeaning( ( UBaseType_t ) ucTCPFlags ), ( unsigned ) ulRemoteIP, usRemotePort, usLocalPort ) ); } #endif /* ipconfigHAS_DEBUG_PRINTF */ if( ( ucTCPFlags & tcpTCP_FLAG_RST ) == 0U ) { ( void ) prvTCPSendReset( pxNetworkBuffer ); } xResult = pdFAIL; } else { /* prvHandleListen() will either return a newly created socket * (if bReuseSocket is false), otherwise it returns the current * socket which will later get connected. */ pxSocket = prvHandleListen( pxSocket, pxNetworkBuffer ); if( pxSocket == NULL ) { xResult = pdFAIL; } } } /* if( pxSocket->u.xTCP.eTCPState == eTCP_LISTEN ). */ else { /* This is not a socket in listening mode. Check for the RST * flag. */ if( ( ucTCPFlags & tcpTCP_FLAG_RST ) != 0U ) { FreeRTOS_debug_printf( ( "TCP: RST received from %xip:%u for %u\n", ( unsigned ) ulRemoteIP, usRemotePort, usLocalPort ) ); /* Implement https://tools.ietf.org/html/rfc5961#section-3.2. */ if( pxSocket->u.xTCP.eTCPState == eCONNECT_SYN ) { /* Per the above RFC, "In the SYN-SENT state ... the RST is * acceptable if the ACK field acknowledges the SYN." */ if( ulAckNumber == ( pxSocket->u.xTCP.xTCPWindow.ulOurSequenceNumber + 1U ) ) { vTCPStateChange( pxSocket, eCLOSED ); } } else { /* Check whether the packet matches the next expected sequence number. */ if( ulSequenceNumber == pxSocket->u.xTCP.xTCPWindow.rx.ulCurrentSequenceNumber ) { vTCPStateChange( pxSocket, eCLOSED ); } /* Otherwise, check whether the packet is within the receive window. */ else if( ( xSequenceGreaterThan( ulSequenceNumber, pxSocket->u.xTCP.xTCPWindow.rx.ulCurrentSequenceNumber ) != pdFALSE ) && ( xSequenceLessThan( ulSequenceNumber, pxSocket->u.xTCP.xTCPWindow.rx.ulCurrentSequenceNumber + pxSocket->u.xTCP.xTCPWindow.xSize.ulRxWindowLength ) != pdFALSE ) ) { /* Send a challenge ACK. */ ( void ) prvTCPSendChallengeAck( pxNetworkBuffer ); } else { /* Nothing. */ } } /* Otherwise, do nothing. In any case, the packet cannot be handled. */ xResult = pdFAIL; } /* Check whether there is a pure SYN amongst the TCP flags while the connection is established. */ else if( ( ( ucTCPFlags & tcpTCP_FLAG_CTRL ) == tcpTCP_FLAG_SYN ) && ( pxSocket->u.xTCP.eTCPState >= eESTABLISHED ) ) { /* SYN flag while this socket is already connected. */ FreeRTOS_debug_printf( ( "TCP: SYN unexpected from %xip:%u\n", ( unsigned ) ulRemoteIP, usRemotePort ) ); /* The packet cannot be handled. */ xResult = pdFAIL; } else { /* Update the copy of the TCP header only (skipping eth and IP * headers). It might be used later on, whenever data must be sent * to the peer. */ const size_t uxOffset = ipSIZE_OF_ETH_HEADER + uxIPHeaderSizeSocket( pxSocket ); ( void ) memcpy( ( void * ) ( &( pxSocket->u.xTCP.xPacket.u.ucLastPacket[ uxOffset ] ) ), ( const void * ) ( &( pxNetworkBuffer->pucEthernetBuffer[ uxOffset ] ) ), ipSIZE_OF_TCP_HEADER ); /* Clear flags that are set by the peer, and set the ACK flag. */ pxSocket->u.xTCP.xPacket.u.ucLastPacket[ uxOffset + ipTCP_FLAGS_OFFSET ] = tcpTCP_FLAG_ACK; } } } if( xResult != pdFAIL ) { uint16_t usWindow; /* pxSocket is not NULL when xResult != pdFAIL. */ configASSERT( pxSocket != NULL ); /* LCOV_EXCL_LINE ,this branch will not be hit*/ /* Touch the alive timers because we received a message for this * socket. */ prvTCPTouchSocket( pxSocket ); /* Parse the TCP option(s), if present. */ /* _HT_ : if we're in the SYN phase, and peer does not send a MSS option, * then we MUST assume an MSS size of 536 bytes for backward compatibility. */ /* When there are no TCP options, the TCP offset equals 20 bytes, which is stored as * the number 5 (words) in the higher nibble of the TCP-offset byte. */ if( ( pxProtocolHeaders->xTCPHeader.ucTCPOffset & tcpTCP_OFFSET_LENGTH_BITS ) > tcpTCP_OFFSET_STANDARD_LENGTH ) { xResult = prvCheckOptions( pxSocket, pxNetworkBuffer ); } if( xResult != pdFAIL ) { usWindow = FreeRTOS_ntohs( pxProtocolHeaders->xTCPHeader.usWindow ); pxSocket->u.xTCP.ulWindowSize = ( uint32_t ) usWindow; #if ( ipconfigUSE_TCP_WIN == 1 ) { /* rfc1323 : The Window field in a SYN (i.e., a or ) * segment itself is never scaled. */ if( ( ucTCPFlags & ( uint8_t ) tcpTCP_FLAG_SYN ) == 0U ) { pxSocket->u.xTCP.ulWindowSize = ( pxSocket->u.xTCP.ulWindowSize << pxSocket->u.xTCP.ucPeerWinScaleFactor ); } } #endif /* ipconfigUSE_TCP_WIN */ /* In prvTCPHandleState() the incoming messages will be handled * depending on the current state of the connection. */ if( prvTCPHandleState( pxSocket, &pxNetworkBuffer ) > 0 ) { /* prvTCPHandleState() has sent a message, see if there are more to * be transmitted. */ #if ( ipconfigUSE_TCP_WIN == 1 ) { ( void ) prvTCPSendRepeated( pxSocket, &pxNetworkBuffer ); } #endif /* ipconfigUSE_TCP_WIN */ } if( pxNetworkBuffer != NULL ) { /* We must check if the buffer is unequal to NULL, because the * socket might keep a reference to it in case a delayed ACK must be * sent. */ vReleaseNetworkBufferAndDescriptor( pxNetworkBuffer ); #ifndef _lint /* Clear pointers that are freed. */ pxNetworkBuffer = NULL; #endif } /* And finally, calculate when this socket wants to be woken up. */ ( void ) prvTCPNextTimeout( pxSocket ); } } } /* pdPASS being returned means the buffer has been consumed. */ return xResult; } /*-----------------------------------------------------------*/ /** * @brief In the API accept(), the user asks is there is a new client? As API's can * not walk through the xBoundTCPSocketsList the IP-task will do this. * * @param[in] pxSocket: The socket for which the bound socket list will be iterated. * * @return if there is a new client, then pdTRUE is returned or else, pdFALSE. */ BaseType_t xTCPCheckNewClient( FreeRTOS_Socket_t * pxSocket ) { TickType_t uxLocalPort = ( TickType_t ) FreeRTOS_htons( pxSocket->usLocalPort ); const ListItem_t * pxIterator; FreeRTOS_Socket_t * pxFound; BaseType_t xResult = pdFALSE; /* MISRA C-2012 Rule 11.3 warns about casting pointer type to a different data type. * The struct to be casted to is defined as a packed struct. The cast won't cause misalignment. */ /* coverity[misra_c_2012_rule_11_3_violation] */ const ListItem_t * pxEndTCP = ( ( const ListItem_t * ) &( xBoundTCPSocketsList.xListEnd ) ); /* Here xBoundTCPSocketsList can be accessed safely IP-task is the only one * who has access. */ for( pxIterator = ( const ListItem_t * ) listGET_HEAD_ENTRY( &xBoundTCPSocketsList ); pxIterator != pxEndTCP; pxIterator = ( const ListItem_t * ) listGET_NEXT( pxIterator ) ) { if( listGET_LIST_ITEM_VALUE( pxIterator ) == ( configLIST_VOLATILE TickType_t ) uxLocalPort ) { pxFound = ( ( FreeRTOS_Socket_t * ) listGET_LIST_ITEM_OWNER( pxIterator ) ); if( ( pxFound->ucProtocol == ( uint8_t ) FREERTOS_IPPROTO_TCP ) && ( pxFound->u.xTCP.bits.bPassAccept != pdFALSE_UNSIGNED ) ) { pxSocket->u.xTCP.pxPeerSocket = pxFound; FreeRTOS_debug_printf( ( "xTCPCheckNewClient[0]: client on port %u\n", pxSocket->usLocalPort ) ); xResult = pdTRUE; break; } } } return xResult; } /*-----------------------------------------------------------*/ #endif /* ipconfigUSE_TCP == 1 */ /* Provide access to private members for testing. */ #ifdef FREERTOS_ENABLE_UNIT_TESTS #include "freertos_tcp_test_access_tcp_define.h" #endif /* Provide access to private members for verification. */ #ifdef FREERTOS_TCP_ENABLE_VERIFICATION #include "aws_freertos_tcp_verification_access_tcp_define.h" #endif