/* * FreeRTOS+TCP 191100 experimental * Copyright (C) 2018 Amazon.com, Inc. or its affiliates. All Rights Reserved. * * 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 */ /* Standard includes. */ #include /* FreeRTOS includes. */ #include "FreeRTOS.h" #include "task.h" #include "queue.h" #include "list.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_DNS.h" #include "NetworkBufferManagement.h" #include "NetworkInterface.h" #include "IPTraceMacroDefaults.h" /* Exclude the entire file if DNS is not enabled. */ #if( ipconfigUSE_DNS != 0 ) #if( ipconfigBYTE_ORDER == pdFREERTOS_LITTLE_ENDIAN ) #define dnsDNS_PORT 0x3500 #define dnsONE_QUESTION 0x0100 #define dnsOUTGOING_FLAGS 0x0001 /* Standard query. */ #define dnsRX_FLAGS_MASK 0x0f80 /* The bits of interest in the flags field of incoming DNS messages. */ #define dnsEXPECTED_RX_FLAGS 0x0080 /* Should be a response, without any errors. */ #else #define dnsDNS_PORT 0x0035 #define dnsONE_QUESTION 0x0001 #define dnsOUTGOING_FLAGS 0x0100 /* Standard query. */ #define dnsRX_FLAGS_MASK 0x800f /* The bits of interest in the flags field of incoming DNS messages. */ #define dnsEXPECTED_RX_FLAGS 0x8000 /* Should be a response, without any errors. */ #endif /* ipconfigBYTE_ORDER */ /* The maximum number of times a DNS request should be sent out if a response is not received, before giving up. */ #ifndef ipconfigDNS_REQUEST_ATTEMPTS #define ipconfigDNS_REQUEST_ATTEMPTS 5 #endif /* If the top two bits in the first character of a name field are set then the name field is an offset to the string, rather than the string itself. */ #define dnsNAME_IS_OFFSET ( ( uint8_t ) 0xc0 ) /* NBNS flags. */ #define dnsNBNS_FLAGS_RESPONSE 0x8000 #define dnsNBNS_FLAGS_OPCODE_MASK 0x7800 #define dnsNBNS_FLAGS_OPCODE_QUERY 0x0000 #define dnsNBNS_FLAGS_OPCODE_REGISTRATION 0x2800 /* Host types. */ #define dnsTYPE_A_HOST 0x01 #define dnsCLASS_IN 0x01 /* LLMNR constants. */ #define dnsLLMNR_TTL_VALUE 300000 #define dnsLLMNR_FLAGS_IS_REPONSE 0x8000 /* NBNS constants. */ #define dnsNBNS_TTL_VALUE 3600 /* 1 hour valid */ #define dnsNBNS_TYPE_NET_BIOS 0x0020 #define dnsNBNS_CLASS_IN 0x01 #define dnsNBNS_NAME_FLAGS 0x6000 #define dnsNBNS_ENCODED_NAME_LENGTH 32 /* If the queried NBNS name matches with the device's name, the query will be responded to with these flags: */ #define dnsNBNS_QUERY_RESPONSE_FLAGS ( 0x8500 ) /* Flag DNS parsing errors in situations where an IPv4 address is the return type. */ #define dnsPARSE_ERROR 0UL /* * Create a socket and bind it to the standard DNS port number. Return the * the created socket - or NULL if the socket could not be created or bound. */ static Socket_t prvCreateDNSSocket( void ); /* * Create the DNS message in the zero copy buffer passed in the first parameter. */ static size_t prvCreateDNSMessage( uint8_t *pucUDPPayloadBuffer, const char *pcHostName, TickType_t xIdentifier ); /* * Simple routine that jumps over the NAME field of a resource record. */ static uint8_t *prvSkipNameField( uint8_t *pucByte, size_t xSourceLen ); /* * Process a response packet from a DNS server. */ static uint32_t prvParseDNSReply( uint8_t *pucUDPPayloadBuffer, size_t xBufferLength, TickType_t xIdentifier ); /* * Prepare and send a message to a DNS server. 'xReadTimeOut_ms' will be passed as * zero, in case the user has supplied a call-back function. */ static uint32_t prvGetHostByName( const char *pcHostName, TickType_t xIdentifier, TickType_t xReadTimeOut_ms ); /* * The NBNS and the LLMNR protocol share this reply function. */ #if( ( ipconfigUSE_NBNS == 1 ) || ( ipconfigUSE_LLMNR == 1 ) ) static void prvReplyDNSMessage( NetworkBufferDescriptor_t *pxNetworkBuffer, BaseType_t lNetLength ); #endif #if( ipconfigUSE_NBNS == 1 ) static portINLINE void prvTreatNBNS( uint8_t *pucUDPPayloadBuffer, size_t xBufferLength, uint32_t ulIPAddress ); #endif /* ipconfigUSE_NBNS */ #if( ipconfigUSE_DNS_CACHE == 1 ) static uint8_t *prvReadNameField( uint8_t *pucByte, size_t xSourceLen, char *pcName, size_t xLen ); static void prvProcessDNSCache( const char *pcName, uint32_t *pulIP, uint32_t ulTTL, BaseType_t xLookUp ); typedef struct xDNS_CACHE_TABLE_ROW { uint32_t ulIPAddress; /* The IP address of an ARP cache entry. */ char pcName[ ipconfigDNS_CACHE_NAME_LENGTH ]; /* The name of the host */ uint32_t ulTTL; /* Time-to-Live (in seconds) from the DNS server. */ uint32_t ulTimeWhenAddedInSeconds; } DNSCacheRow_t; static DNSCacheRow_t xDNSCache[ ipconfigDNS_CACHE_ENTRIES ]; void FreeRTOS_dnsclear() { memset( xDNSCache, 0x0, sizeof( xDNSCache ) ); } #endif /* ipconfigUSE_DNS_CACHE == 1 */ #if( ipconfigUSE_LLMNR == 1 ) const MACAddress_t xLLMNR_MacAdress = { { 0x01, 0x00, 0x5e, 0x00, 0x00, 0xfc } }; #endif /* ipconfigUSE_LLMNR == 1 */ /*-----------------------------------------------------------*/ #include "pack_struct_start.h" struct xDNSMessage { uint16_t usIdentifier; uint16_t usFlags; uint16_t usQuestions; uint16_t usAnswers; uint16_t usAuthorityRRs; uint16_t usAdditionalRRs; } #include "pack_struct_end.h" typedef struct xDNSMessage DNSMessage_t; /* A DNS query consists of a header, as described in 'struct xDNSMessage' It is followed by 1 or more queries, each one consisting of a name and a tail, with two fields: type and class */ #include "pack_struct_start.h" struct xDNSTail { uint16_t usType; uint16_t usClass; } #include "pack_struct_end.h" typedef struct xDNSTail DNSTail_t; /* DNS answer record header. */ #include "pack_struct_start.h" struct xDNSAnswerRecord { uint16_t usType; uint16_t usClass; uint32_t ulTTL; uint16_t usDataLength; } #include "pack_struct_end.h" typedef struct xDNSAnswerRecord DNSAnswerRecord_t; #if( ipconfigUSE_LLMNR == 1 ) #include "pack_struct_start.h" struct xLLMNRAnswer { uint8_t ucNameCode; uint8_t ucNameOffset; /* The name is not repeated in the answer, only the offset is given with "0xc0 " */ uint16_t usType; uint16_t usClass; uint32_t ulTTL; uint16_t usDataLength; uint32_t ulIPAddress; } #include "pack_struct_end.h" typedef struct xLLMNRAnswer LLMNRAnswer_t; #endif /* ipconfigUSE_LLMNR == 1 */ #if( ipconfigUSE_NBNS == 1 ) #include "pack_struct_start.h" struct xNBNSRequest { uint16_t usRequestId; uint16_t usFlags; uint16_t ulRequestCount; uint16_t usAnswerRSS; uint16_t usAuthRSS; uint16_t usAdditionalRSS; uint8_t ucNameSpace; uint8_t ucName[ dnsNBNS_ENCODED_NAME_LENGTH ]; uint8_t ucNameZero; uint16_t usType; uint16_t usClass; } #include "pack_struct_end.h" typedef struct xNBNSRequest NBNSRequest_t; #include "pack_struct_start.h" struct xNBNSAnswer { uint16_t usType; uint16_t usClass; uint32_t ulTTL; uint16_t usDataLength; uint16_t usNbFlags; /* NetBIOS flags 0x6000 : IP-address, big-endian */ uint32_t ulIPAddress; } #include "pack_struct_end.h" typedef struct xNBNSAnswer NBNSAnswer_t; #endif /* ipconfigUSE_NBNS == 1 */ /*-----------------------------------------------------------*/ #if( ipconfigUSE_DNS_CACHE == 1 ) uint32_t FreeRTOS_dnslookup( const char *pcHostName ) { uint32_t ulIPAddress = 0UL; prvProcessDNSCache( pcHostName, &ulIPAddress, 0, pdTRUE ); return ulIPAddress; } #endif /* ipconfigUSE_DNS_CACHE == 1 */ /*-----------------------------------------------------------*/ #if( ipconfigDNS_USE_CALLBACKS != 0 ) typedef struct xDNS_Callback { TickType_t xRemaningTime; /* Timeout in ms */ FOnDNSEvent pCallbackFunction; /* Function to be called when the address has been found or when a timeout has beeen reached */ TimeOut_t xTimeoutState; void *pvSearchID; struct xLIST_ITEM xListItem; char pcName[ 1 ]; } DNSCallback_t; static List_t xCallbackList; /* Define FreeRTOS_gethostbyname() as a normal blocking call. */ uint32_t FreeRTOS_gethostbyname( const char *pcHostName ) { return FreeRTOS_gethostbyname_a( pcHostName, ( FOnDNSEvent ) NULL, ( void* )NULL, 0 ); } /*-----------------------------------------------------------*/ /* Initialise the list of call-back structures. */ void vDNSInitialise( void ); void vDNSInitialise( void ) { vListInitialise( &xCallbackList ); } /*-----------------------------------------------------------*/ /* Iterate through the list of call-back structures and remove old entries which have reached a timeout. As soon as the list hase become empty, the DNS timer will be stopped In case pvSearchID is supplied, the user wants to cancel a DNS request */ void vDNSCheckCallBack( void *pvSearchID ); void vDNSCheckCallBack( void *pvSearchID ) { const ListItem_t *pxIterator; const MiniListItem_t* xEnd = ( const MiniListItem_t* )listGET_END_MARKER( &xCallbackList ); vTaskSuspendAll(); { for( pxIterator = ( const ListItem_t * ) listGET_NEXT( xEnd ); pxIterator != ( const ListItem_t * ) xEnd; ) { DNSCallback_t *pxCallback = ( DNSCallback_t * ) listGET_LIST_ITEM_OWNER( pxIterator ); /* Move to the next item because we might remove this item */ pxIterator = ( const ListItem_t * ) listGET_NEXT( pxIterator ); if( ( pvSearchID != NULL ) && ( pvSearchID == pxCallback->pvSearchID ) ) { uxListRemove( &pxCallback->xListItem ); vPortFree( pxCallback ); } else if( xTaskCheckForTimeOut( &pxCallback->xTimeoutState, &pxCallback->xRemaningTime ) != pdFALSE ) { pxCallback->pCallbackFunction( pxCallback->pcName, pxCallback->pvSearchID, 0 ); uxListRemove( &pxCallback->xListItem ); vPortFree( ( void * ) pxCallback ); } } } xTaskResumeAll(); if( listLIST_IS_EMPTY( &xCallbackList ) ) { vIPSetDnsTimerEnableState( pdFALSE ); } } /*-----------------------------------------------------------*/ void FreeRTOS_gethostbyname_cancel( void *pvSearchID ) { /* _HT_ Should better become a new API call to have the IP-task remove the callback */ vDNSCheckCallBack( pvSearchID ); } /*-----------------------------------------------------------*/ /* FreeRTOS_gethostbyname_a() was called along with callback parameters. Store them in a list for later reference. */ static void vDNSSetCallBack( const char *pcHostName, void *pvSearchID, FOnDNSEvent pCallbackFunction, TickType_t xTimeout, TickType_t xIdentifier ); static void vDNSSetCallBack( const char *pcHostName, void *pvSearchID, FOnDNSEvent pCallbackFunction, TickType_t xTimeout, TickType_t xIdentifier ) { size_t lLength = strlen( pcHostName ); DNSCallback_t *pxCallback = ( DNSCallback_t * )pvPortMalloc( sizeof( *pxCallback ) + lLength ); /* Translate from ms to number of clock ticks. */ xTimeout /= portTICK_PERIOD_MS; if( pxCallback != NULL ) { if( listLIST_IS_EMPTY( &xCallbackList ) ) { /* This is the first one, start the DNS timer to check for timeouts */ vIPReloadDNSTimer( FreeRTOS_min_uint32( 1000U, xTimeout ) ); } strcpy( pxCallback->pcName, pcHostName ); pxCallback->pCallbackFunction = pCallbackFunction; pxCallback->pvSearchID = pvSearchID; pxCallback->xRemaningTime = xTimeout; vTaskSetTimeOutState( &pxCallback->xTimeoutState ); listSET_LIST_ITEM_OWNER( &( pxCallback->xListItem ), ( void* ) pxCallback ); listSET_LIST_ITEM_VALUE( &( pxCallback->xListItem ), xIdentifier ); vTaskSuspendAll(); { vListInsertEnd( &xCallbackList, &pxCallback->xListItem ); } xTaskResumeAll(); } } /*-----------------------------------------------------------*/ /* A DNS reply was received, see if there is any matching entry and call the handler. */ static void vDNSDoCallback( TickType_t xIdentifier, const char *pcName, uint32_t ulIPAddress ); static void vDNSDoCallback( TickType_t xIdentifier, const char *pcName, uint32_t ulIPAddress ) { const ListItem_t *pxIterator; const MiniListItem_t* xEnd = ( const MiniListItem_t* )listGET_END_MARKER( &xCallbackList ); vTaskSuspendAll(); { for( pxIterator = ( const ListItem_t * ) listGET_NEXT( xEnd ); pxIterator != ( const ListItem_t * ) xEnd; pxIterator = ( const ListItem_t * ) listGET_NEXT( pxIterator ) ) { if( listGET_LIST_ITEM_VALUE( pxIterator ) == xIdentifier ) { DNSCallback_t *pxCallback = ( DNSCallback_t * ) listGET_LIST_ITEM_OWNER( pxIterator ); pxCallback->pCallbackFunction( pcName, pxCallback->pvSearchID, ulIPAddress ); uxListRemove( &pxCallback->xListItem ); vPortFree( pxCallback ); if( listLIST_IS_EMPTY( &xCallbackList ) ) { vIPSetDnsTimerEnableState( pdFALSE ); } break; } } } xTaskResumeAll(); } #endif /* ipconfigDNS_USE_CALLBACKS != 0 */ /*-----------------------------------------------------------*/ #if( ipconfigDNS_USE_CALLBACKS == 0 ) uint32_t FreeRTOS_gethostbyname( const char *pcHostName ) #else uint32_t FreeRTOS_gethostbyname_a( const char *pcHostName, FOnDNSEvent pCallback, void *pvSearchID, TickType_t xTimeout ) #endif { uint32_t ulIPAddress = 0UL; TickType_t xReadTimeOut_ms = ipconfigSOCK_DEFAULT_RECEIVE_BLOCK_TIME; TickType_t xIdentifier = 0; /* If the supplied hostname is IP address, convert it to uint32_t and return. */ #if( ipconfigINCLUDE_FULL_INET_ADDR == 1 ) { ulIPAddress = FreeRTOS_inet_addr( pcHostName ); } #endif /* ipconfigINCLUDE_FULL_INET_ADDR == 1 */ /* If a DNS cache is used then check the cache before issuing another DNS request. */ #if( ipconfigUSE_DNS_CACHE == 1 ) { if( ulIPAddress == 0UL ) { ulIPAddress = FreeRTOS_dnslookup( pcHostName ); if( ulIPAddress != 0 ) { FreeRTOS_debug_printf( ( "FreeRTOS_gethostbyname: found '%s' in cache: %lxip\n", pcHostName, ulIPAddress ) ); } else { /* prvGetHostByName will be called to start a DNS lookup */ } } } #endif /* ipconfigUSE_DNS_CACHE == 1 */ /* Generate a unique identifier. */ if( 0 == ulIPAddress ) { xIdentifier = ( TickType_t )ipconfigRAND32( ); } #if( ipconfigDNS_USE_CALLBACKS != 0 ) { if( pCallback != NULL ) { if( ulIPAddress == 0UL ) { /* The user has provided a callback function, so do not block on recvfrom() */ if( 0 != xIdentifier ) { xReadTimeOut_ms = 0; vDNSSetCallBack( pcHostName, pvSearchID, pCallback, xTimeout, ( TickType_t )xIdentifier ); } } else { /* The IP address is known, do the call-back now. */ pCallback( pcHostName, pvSearchID, ulIPAddress ); } } } #endif if( ( ulIPAddress == 0UL ) && ( 0 != xIdentifier ) ) { ulIPAddress = prvGetHostByName( pcHostName, xIdentifier, xReadTimeOut_ms ); } return ulIPAddress; } /*-----------------------------------------------------------*/ static uint32_t prvGetHostByName( const char *pcHostName, TickType_t xIdentifier, TickType_t xReadTimeOut_ms ) { struct freertos_sockaddr xAddress; Socket_t xDNSSocket; uint32_t ulIPAddress = 0UL; uint8_t *pucUDPPayloadBuffer; uint32_t ulAddressLength = sizeof( struct freertos_sockaddr ); BaseType_t xAttempt; int32_t lBytes; size_t xPayloadLength, xExpectedPayloadLength; TickType_t xWriteTimeOut_ms = ipconfigSOCK_DEFAULT_SEND_BLOCK_TIME; #if( ipconfigUSE_LLMNR == 1 ) BaseType_t bHasDot = pdFALSE; #endif /* ipconfigUSE_LLMNR == 1 */ /* If LLMNR is being used then determine if the host name includes a '.' - if not then LLMNR can be used as the lookup method. */ #if( ipconfigUSE_LLMNR == 1 ) { const char *pucPtr; for( pucPtr = pcHostName; *pucPtr; pucPtr++ ) { if( *pucPtr == '.' ) { bHasDot = pdTRUE; break; } } } #endif /* ipconfigUSE_LLMNR == 1 */ /* Two is added at the end for the count of characters in the first subdomain part and the string end byte. */ xExpectedPayloadLength = sizeof( DNSMessage_t ) + strlen( pcHostName ) + sizeof( uint16_t ) + sizeof( uint16_t ) + 2u; xDNSSocket = prvCreateDNSSocket(); if( xDNSSocket != NULL ) { FreeRTOS_setsockopt( xDNSSocket, 0, FREERTOS_SO_SNDTIMEO, ( void * ) &xWriteTimeOut_ms, sizeof( TickType_t ) ); FreeRTOS_setsockopt( xDNSSocket, 0, FREERTOS_SO_RCVTIMEO, ( void * ) &xReadTimeOut_ms, sizeof( TickType_t ) ); for( xAttempt = 0; xAttempt < ipconfigDNS_REQUEST_ATTEMPTS; xAttempt++ ) { /* Get a buffer. This uses a maximum delay, but the delay will be capped to ipconfigUDP_MAX_SEND_BLOCK_TIME_TICKS so the return value still needs to be tested. */ pucUDPPayloadBuffer = ( uint8_t * ) FreeRTOS_GetUDPPayloadBuffer( xExpectedPayloadLength, portMAX_DELAY ); if( pucUDPPayloadBuffer != NULL ) { /* Create the message in the obtained buffer. */ xPayloadLength = prvCreateDNSMessage( pucUDPPayloadBuffer, pcHostName, xIdentifier ); iptraceSENDING_DNS_REQUEST(); /* Obtain the DNS server address. */ FreeRTOS_GetAddressConfiguration( NULL, NULL, NULL, &ulIPAddress ); /* Send the DNS message. */ #if( ipconfigUSE_LLMNR == 1 ) if( bHasDot == pdFALSE ) { /* Use LLMNR addressing. */ ( ( DNSMessage_t * ) pucUDPPayloadBuffer) -> usFlags = 0; xAddress.sin_addr = ipLLMNR_IP_ADDR; /* Is in network byte order. */ xAddress.sin_port = FreeRTOS_ntohs( ipLLMNR_PORT ); } else #endif { /* Use DNS server. */ xAddress.sin_addr = ulIPAddress; xAddress.sin_port = dnsDNS_PORT; } ulIPAddress = 0UL; if( FreeRTOS_sendto( xDNSSocket, pucUDPPayloadBuffer, xPayloadLength, FREERTOS_ZERO_COPY, &xAddress, sizeof( xAddress ) ) != 0 ) { /* Wait for the reply. */ lBytes = FreeRTOS_recvfrom( xDNSSocket, &pucUDPPayloadBuffer, 0, FREERTOS_ZERO_COPY, &xAddress, &ulAddressLength ); if( lBytes > 0 ) { /* The reply was received. Process it. */ ulIPAddress = prvParseDNSReply( pucUDPPayloadBuffer, lBytes, xIdentifier ); /* Finished with the buffer. The zero copy interface is being used, so the buffer must be freed by the task. */ FreeRTOS_ReleaseUDPPayloadBuffer( ( void * ) pucUDPPayloadBuffer ); if( ulIPAddress != 0UL ) { /* All done. */ break; } } } else { /* The message was not sent so the stack will not be releasing the zero copy - it must be released here. */ FreeRTOS_ReleaseUDPPayloadBuffer( ( void * ) pucUDPPayloadBuffer ); } } } /* Finished with the socket. */ FreeRTOS_closesocket( xDNSSocket ); } return ulIPAddress; } /*-----------------------------------------------------------*/ static size_t prvCreateDNSMessage( uint8_t *pucUDPPayloadBuffer, const char *pcHostName, TickType_t xIdentifier ) { DNSMessage_t *pxDNSMessageHeader; uint8_t *pucStart, *pucByte; DNSTail_t *pxTail; static const DNSMessage_t xDefaultPartDNSHeader = { 0, /* The identifier will be overwritten. */ dnsOUTGOING_FLAGS, /* Flags set for standard query. */ dnsONE_QUESTION, /* One question is being asked. */ 0, /* No replies are included. */ 0, /* No authorities. */ 0 /* No additional authorities. */ }; /* Copy in the const part of the header. */ memcpy( ( void * ) pucUDPPayloadBuffer, ( void * ) &xDefaultPartDNSHeader, sizeof( xDefaultPartDNSHeader ) ); /* Write in a unique identifier. */ pxDNSMessageHeader = ( DNSMessage_t * ) pucUDPPayloadBuffer; pxDNSMessageHeader->usIdentifier = ( uint16_t ) xIdentifier; /* Create the resource record at the end of the header. First find the end of the header. */ pucStart = pucUDPPayloadBuffer + sizeof( xDefaultPartDNSHeader ); /* Leave a gap for the first length bytes. */ pucByte = pucStart + 1; /* Copy in the host name. */ strcpy( ( char * ) pucByte, pcHostName ); /* Mark the end of the string. */ pucByte += strlen( pcHostName ); *pucByte = 0x00u; /* Walk the string to replace the '.' characters with byte counts. pucStart holds the address of the byte count. Walking the string starts after the byte count position. */ pucByte = pucStart; do { pucByte++; while( ( *pucByte != 0x00 ) && ( *pucByte != '.' ) ) { pucByte++; } /* Fill in the byte count, then move the pucStart pointer up to the found byte position. */ *pucStart = ( uint8_t ) ( ( uint32_t ) pucByte - ( uint32_t ) pucStart ); ( *pucStart )--; pucStart = pucByte; } while( *pucByte != 0x00 ); /* Finish off the record. */ pxTail = (DNSTail_t *)( pucByte + 1 ); vSetField16( pxTail, DNSTail_t, usType, dnsTYPE_A_HOST ); /* Type A: host */ vSetField16( pxTail, DNSTail_t, usClass, dnsCLASS_IN ); /* 1: Class IN */ /* Return the total size of the generated message, which is the space from the last written byte to the beginning of the buffer. */ return ( ( uint32_t ) pucByte - ( uint32_t ) pucUDPPayloadBuffer + 1 ) + sizeof( *pxTail ); } /*-----------------------------------------------------------*/ #if( ipconfigUSE_DNS_CACHE == 1 ) static uint8_t *prvReadNameField( uint8_t *pucByte, size_t xSourceLen, char *pcName, size_t xDestLen ) { size_t xNameLen = 0; BaseType_t xCount; if( 0 == xSourceLen ) { return NULL; } /* Determine if the name is the fully coded name, or an offset to the name elsewhere in the message. */ if( ( *pucByte & dnsNAME_IS_OFFSET ) == dnsNAME_IS_OFFSET ) { /* Jump over the two byte offset. */ if( xSourceLen > sizeof( uint16_t ) ) { pucByte += sizeof( uint16_t ); } else { pucByte = NULL; } } else { /* pucByte points to the full name. Walk over the string. */ while( ( NULL != pucByte ) && ( *pucByte != 0x00 ) && ( xSourceLen > 1 ) ) { /* If this is not the first time through the loop, then add a separator in the output. */ if( ( xNameLen > 0 ) && ( xNameLen < ( xDestLen - 1 ) ) ) { pcName[ xNameLen++ ] = '.'; } /* Process the first/next sub-string. */ for( xCount = *(pucByte++), xSourceLen--; xCount-- && xSourceLen > 1; pucByte++, xSourceLen-- ) { if( xNameLen < xDestLen - 1 ) { pcName[ xNameLen++ ] = *( ( char * )pucByte ); } else { /* DNS name is too big for the provided buffer. */ pucByte = NULL; break; } } } /* Confirm that a fully formed name was found. */ if( NULL != pucByte ) { if( 0x00 == *pucByte ) { pucByte++; xSourceLen--; pcName[ xNameLen++ ] = '\0'; } else { pucByte = NULL; } } } return pucByte; } #endif /* ipconfigUSE_DNS_CACHE == 1 */ /*-----------------------------------------------------------*/ static uint8_t *prvSkipNameField( uint8_t *pucByte, size_t xSourceLen ) { size_t xChunkLength; if( 0 == xSourceLen ) { return NULL; } /* Determine if the name is the fully coded name, or an offset to the name elsewhere in the message. */ if( ( *pucByte & dnsNAME_IS_OFFSET ) == dnsNAME_IS_OFFSET ) { /* Jump over the two byte offset. */ if( xSourceLen > sizeof( uint16_t ) ) { pucByte += sizeof( uint16_t ); } else { pucByte = NULL; } } else { /* pucByte points to the full name. Walk over the string. */ while( ( *pucByte != 0x00 ) && ( xSourceLen > 1 ) ) { xChunkLength = *pucByte + 1; if( xSourceLen > xChunkLength ) { xSourceLen -= xChunkLength; pucByte += xChunkLength; } else { pucByte = NULL; break; } } /* Confirm that a fully formed name was found. */ if( NULL != pucByte ) { if( 0x00 == *pucByte ) { pucByte++; } else { pucByte = NULL; } } } return pucByte; } /*-----------------------------------------------------------*/ uint32_t ulDNSHandlePacket( NetworkBufferDescriptor_t *pxNetworkBuffer ) { DNSMessage_t *pxDNSMessageHeader; if( pxNetworkBuffer->xDataLength >= sizeof( DNSMessage_t ) ) { pxDNSMessageHeader = ( DNSMessage_t * )( pxNetworkBuffer->pucEthernetBuffer + sizeof( UDPPacket_t ) ); prvParseDNSReply( ( uint8_t * )pxDNSMessageHeader, pxNetworkBuffer->xDataLength, ( uint32_t )pxDNSMessageHeader->usIdentifier ); } /* The packet was not consumed. */ return pdFAIL; } /*-----------------------------------------------------------*/ #if( ipconfigUSE_NBNS == 1 ) uint32_t ulNBNSHandlePacket (NetworkBufferDescriptor_t *pxNetworkBuffer ) { UDPPacket_t *pxUDPPacket = ( UDPPacket_t * ) pxNetworkBuffer->pucEthernetBuffer; uint8_t *pucUDPPayloadBuffer = pxNetworkBuffer->pucEthernetBuffer + sizeof( UDPPacket_t ); /* The network buffer data length has already been set to the length of the UDP payload. */ prvTreatNBNS( pucUDPPayloadBuffer, pxNetworkBuffer->xDataLength, pxUDPPacket->xIPHeader.ulSourceIPAddress ); /* The packet was not consumed. */ return pdFAIL; } #endif /* ipconfigUSE_NBNS */ /*-----------------------------------------------------------*/ static uint32_t prvParseDNSReply( uint8_t *pucUDPPayloadBuffer, size_t xBufferLength, TickType_t xIdentifier ) { DNSMessage_t *pxDNSMessageHeader; DNSAnswerRecord_t *pxDNSAnswerRecord; uint32_t ulIPAddress = 0UL; #if( ipconfigUSE_LLMNR == 1 ) char *pcRequestedName = NULL; #endif uint8_t *pucByte; size_t xSourceBytesRemaining; uint16_t x, usDataLength, usQuestions; #if( ipconfigUSE_LLMNR == 1 ) uint16_t usType = 0, usClass = 0; #endif #if( ipconfigUSE_DNS_CACHE == 1 ) char pcName[ ipconfigDNS_CACHE_NAME_LENGTH ] = ""; #endif /* Ensure that the buffer is of at least minimal DNS message length. */ if( xBufferLength < sizeof( DNSMessage_t ) ) { return dnsPARSE_ERROR; } else { xSourceBytesRemaining = xBufferLength; } /* Parse the DNS message header. */ pxDNSMessageHeader = ( DNSMessage_t * ) pucUDPPayloadBuffer; if( pxDNSMessageHeader->usIdentifier == ( uint16_t ) xIdentifier ) { /* Start at the first byte after the header. */ pucByte = pucUDPPayloadBuffer + sizeof( DNSMessage_t ); xSourceBytesRemaining -= sizeof( DNSMessage_t ); /* Skip any question records. */ usQuestions = FreeRTOS_ntohs( pxDNSMessageHeader->usQuestions ); for( x = 0; x < usQuestions; x++ ) { #if( ipconfigUSE_LLMNR == 1 ) { if( x == 0 ) { pcRequestedName = ( char * ) pucByte; } } #endif #if( ipconfigUSE_DNS_CACHE == 1 ) if( x == 0 ) { pucByte = prvReadNameField( pucByte, xSourceBytesRemaining, pcName, sizeof( pcName ) ); /* Check for a malformed response. */ if( NULL == pucByte ) { return dnsPARSE_ERROR; } else { xSourceBytesRemaining = ( pucUDPPayloadBuffer + xBufferLength ) - pucByte; } } else #endif /* ipconfigUSE_DNS_CACHE */ { /* Skip the variable length pcName field. */ pucByte = prvSkipNameField( pucByte, xSourceBytesRemaining ); /* Check for a malformed response. */ if( NULL == pucByte ) { return dnsPARSE_ERROR; } else { xSourceBytesRemaining = pucUDPPayloadBuffer + xBufferLength - pucByte; } } /* Check the remaining buffer size. */ if( xSourceBytesRemaining >= sizeof( uint32_t ) ) { #if( ipconfigUSE_LLMNR == 1 ) { /* usChar2u16 returns value in host endianness */ usType = usChar2u16( pucByte ); usClass = usChar2u16( pucByte + 2 ); } #endif /* ipconfigUSE_LLMNR */ /* Skip the type and class fields. */ pucByte += sizeof( uint32_t ); xSourceBytesRemaining -= sizeof( uint32_t ); } else { /* Malformed response. */ return dnsPARSE_ERROR; } } /* Search through the answer records. */ pxDNSMessageHeader->usAnswers = FreeRTOS_ntohs( pxDNSMessageHeader->usAnswers ); if( ( pxDNSMessageHeader->usFlags & dnsRX_FLAGS_MASK ) == dnsEXPECTED_RX_FLAGS ) { for( x = 0; x < pxDNSMessageHeader->usAnswers; x++ ) { pucByte = prvSkipNameField( pucByte, xSourceBytesRemaining ); /* Check for a malformed response. */ if( NULL == pucByte ) { return dnsPARSE_ERROR; } else { xSourceBytesRemaining = pucUDPPayloadBuffer + xBufferLength - pucByte; } /* Is there enough data for an IPv4 A record answer and, if so, is this an A record? */ if( xSourceBytesRemaining >= sizeof( DNSAnswerRecord_t ) + sizeof( uint32_t ) && usChar2u16( pucByte ) == dnsTYPE_A_HOST ) { /* This is the required record type and is of sufficient size. */ pxDNSAnswerRecord = ( DNSAnswerRecord_t * )pucByte; /* Sanity check the data length of an IPv4 answer. */ if( FreeRTOS_ntohs( pxDNSAnswerRecord->usDataLength ) == sizeof( uint32_t ) ) { /* Copy the IP address out of the record. */ memcpy( &ulIPAddress, pucByte + sizeof( DNSAnswerRecord_t ), sizeof( uint32_t ) ); #if( ipconfigUSE_DNS_CACHE == 1 ) { prvProcessDNSCache( pcName, &ulIPAddress, pxDNSAnswerRecord->ulTTL, pdFALSE ); } #endif /* ipconfigUSE_DNS_CACHE */ #if( ipconfigDNS_USE_CALLBACKS != 0 ) { /* See if any asynchronous call was made to FreeRTOS_gethostbyname_a() */ vDNSDoCallback( ( TickType_t ) pxDNSMessageHeader->usIdentifier, pcName, ulIPAddress ); } #endif /* ipconfigDNS_USE_CALLBACKS != 0 */ } pucByte += sizeof( DNSAnswerRecord_t ) + sizeof( uint32_t ); xSourceBytesRemaining -= ( sizeof( DNSAnswerRecord_t ) + sizeof( uint32_t ) ); break; } else if( xSourceBytesRemaining >= sizeof( DNSAnswerRecord_t ) ) { /* It's not an A record, so skip it. Get the header location and then jump over the header. */ pxDNSAnswerRecord = ( DNSAnswerRecord_t * )pucByte; pucByte += sizeof( DNSAnswerRecord_t ); xSourceBytesRemaining -= sizeof( DNSAnswerRecord_t ); /* Determine the length of the answer data from the header. */ usDataLength = FreeRTOS_ntohs( pxDNSAnswerRecord->usDataLength ); /* Jump over the answer. */ if( xSourceBytesRemaining >= usDataLength ) { pucByte += usDataLength; xSourceBytesRemaining -= usDataLength; } else { /* Malformed response. */ return dnsPARSE_ERROR; } } } } #if( ipconfigUSE_LLMNR == 1 ) else if( usQuestions && ( usType == dnsTYPE_A_HOST ) && ( usClass == dnsCLASS_IN ) ) { /* If this is not a reply to our DNS request, it might an LLMNR request. */ if( xApplicationDNSQueryHook ( ( pcRequestedName + 1 ) ) ) { int16_t usLength; NetworkBufferDescriptor_t *pxNewBuffer = NULL; NetworkBufferDescriptor_t *pxNetworkBuffer = pxUDPPayloadBuffer_to_NetworkBuffer( pucUDPPayloadBuffer ); LLMNRAnswer_t *pxAnswer; if( ( xBufferAllocFixedSize == pdFALSE ) && ( pxNetworkBuffer != NULL ) ) { BaseType_t xDataLength = xBufferLength + sizeof( UDPHeader_t ) + sizeof( EthernetHeader_t ) + sizeof( IPHeader_t ); /* The field xDataLength was set to the length of the UDP payload. The answer (reply) will be longer than the request, so the packet must be duplicaed into a bigger buffer */ pxNetworkBuffer->xDataLength = xDataLength; pxNewBuffer = pxDuplicateNetworkBufferWithDescriptor( pxNetworkBuffer, xDataLength + 16 ); if( pxNewBuffer != NULL ) { BaseType_t xOffset1, xOffset2; xOffset1 = ( BaseType_t ) ( pucByte - pucUDPPayloadBuffer ); xOffset2 = ( BaseType_t ) ( ( ( uint8_t * ) pcRequestedName ) - pucUDPPayloadBuffer ); pxNetworkBuffer = pxNewBuffer; pucUDPPayloadBuffer = pxNetworkBuffer->pucEthernetBuffer + ipUDP_PAYLOAD_OFFSET_IPv4; pucByte = pucUDPPayloadBuffer + xOffset1; pcRequestedName = ( char * ) ( pucUDPPayloadBuffer + xOffset2 ); pxDNSMessageHeader = ( DNSMessage_t * ) pucUDPPayloadBuffer; } else { /* Just to indicate that the message may not be answered. */ pxNetworkBuffer = NULL; } } if( pxNetworkBuffer != NULL ) { pxAnswer = (LLMNRAnswer_t *)pucByte; /* We leave 'usIdentifier' and 'usQuestions' untouched */ vSetField16( pxDNSMessageHeader, DNSMessage_t, usFlags, dnsLLMNR_FLAGS_IS_REPONSE ); /* Set the response flag */ vSetField16( pxDNSMessageHeader, DNSMessage_t, usAnswers, 1 ); /* Provide a single answer */ vSetField16( pxDNSMessageHeader, DNSMessage_t, usAuthorityRRs, 0 ); /* No authority */ vSetField16( pxDNSMessageHeader, DNSMessage_t, usAdditionalRRs, 0 ); /* No additional info */ pxAnswer->ucNameCode = dnsNAME_IS_OFFSET; pxAnswer->ucNameOffset = ( uint8_t )( pcRequestedName - ( char * ) pucUDPPayloadBuffer ); vSetField16( pxAnswer, LLMNRAnswer_t, usType, dnsTYPE_A_HOST ); /* Type A: host */ vSetField16( pxAnswer, LLMNRAnswer_t, usClass, dnsCLASS_IN ); /* 1: Class IN */ vSetField32( pxAnswer, LLMNRAnswer_t, ulTTL, dnsLLMNR_TTL_VALUE ); vSetField16( pxAnswer, LLMNRAnswer_t, usDataLength, 4 ); vSetField32( pxAnswer, LLMNRAnswer_t, ulIPAddress, FreeRTOS_ntohl( *ipLOCAL_IP_ADDRESS_POINTER ) ); usLength = ( int16_t ) ( sizeof( *pxAnswer ) + ( size_t ) ( pucByte - pucUDPPayloadBuffer ) ); prvReplyDNSMessage( pxNetworkBuffer, usLength ); if( pxNewBuffer != NULL ) { vReleaseNetworkBufferAndDescriptor( pxNewBuffer ); } } } } #endif /* ipconfigUSE_LLMNR == 1 */ } return ulIPAddress; } /*-----------------------------------------------------------*/ #if( ipconfigUSE_NBNS == 1 ) static void prvTreatNBNS( uint8_t *pucUDPPayloadBuffer, size_t xBufferLength, uint32_t ulIPAddress ) { uint16_t usFlags, usType, usClass; uint8_t *pucSource, *pucTarget; uint8_t ucByte; uint8_t ucNBNSName[ 17 ]; /* Check for minimum buffer size. */ if( xBufferLength < sizeof( NBNSRequest_t ) ) { return; } /* Read the request flags in host endianness. */ usFlags = usChar2u16( pucUDPPayloadBuffer + offsetof( NBNSRequest_t, usFlags ) ); if( ( usFlags & dnsNBNS_FLAGS_OPCODE_MASK ) == dnsNBNS_FLAGS_OPCODE_QUERY ) { usType = usChar2u16( pucUDPPayloadBuffer + offsetof( NBNSRequest_t, usType ) ); usClass = usChar2u16( pucUDPPayloadBuffer + offsetof( NBNSRequest_t, usClass ) ); /* Not used for now */ ( void )usClass; /* For NBNS a name is 16 bytes long, written with capitals only. Make sure that the copy is terminated with a zero. */ pucTarget = ucNBNSName + sizeof(ucNBNSName ) - 2; pucTarget[ 1 ] = '\0'; /* Start with decoding the last 2 bytes. */ pucSource = pucUDPPayloadBuffer + ( offsetof( NBNSRequest_t, ucName ) + ( dnsNBNS_ENCODED_NAME_LENGTH - 2 ) ); for( ;; ) { ucByte = ( uint8_t ) ( ( ( pucSource[ 0 ] - 0x41 ) << 4 ) | ( pucSource[ 1 ] - 0x41 ) ); /* Make sure there are no trailing spaces in the name. */ if( ( ucByte == ' ' ) && ( pucTarget[ 1 ] == '\0' ) ) { ucByte = '\0'; } *pucTarget = ucByte; if( pucTarget == ucNBNSName ) { break; } pucTarget -= 1; pucSource -= 2; } #if( ipconfigUSE_DNS_CACHE == 1 ) { if( ( usFlags & dnsNBNS_FLAGS_RESPONSE ) != 0 ) { /* If this is a response from another device, add the name to the DNS cache */ prvProcessDNSCache( ( char * ) ucNBNSName, &ulIPAddress, 0, pdFALSE ); } } #else { /* Avoid compiler warnings. */ ( void ) ulIPAddress; } #endif /* ipconfigUSE_DNS_CACHE */ if( ( ( usFlags & dnsNBNS_FLAGS_RESPONSE ) == 0 ) && ( usType == dnsNBNS_TYPE_NET_BIOS ) && ( xApplicationDNSQueryHook( ( const char * ) ucNBNSName ) != pdFALSE ) ) { uint16_t usLength; DNSMessage_t *pxMessage; NBNSAnswer_t *pxAnswer; /* Someone is looking for a device with ucNBNSName, prepare a positive reply. */ NetworkBufferDescriptor_t *pxNetworkBuffer = pxUDPPayloadBuffer_to_NetworkBuffer( pucUDPPayloadBuffer ); if( ( xBufferAllocFixedSize == pdFALSE ) && ( pxNetworkBuffer != NULL ) ) { NetworkBufferDescriptor_t *pxNewBuffer; BaseType_t xDataLength = pxNetworkBuffer->xDataLength + sizeof( UDPHeader_t ) + sizeof( EthernetHeader_t ) + sizeof( IPHeader_t ); /* The field xDataLength was set to the length of the UDP payload. The answer (reply) will be longer than the request, so the packet must be duplicated into a bigger buffer */ pxNetworkBuffer->xDataLength = xDataLength; pxNewBuffer = pxDuplicateNetworkBufferWithDescriptor( pxNetworkBuffer, xDataLength + 16 ); if( pxNewBuffer != NULL ) { pucUDPPayloadBuffer = pxNewBuffer->pucEthernetBuffer + sizeof( UDPPacket_t ); pxNetworkBuffer = pxNewBuffer; } else { /* Just prevent that a reply will be sent */ pxNetworkBuffer = NULL; } } /* Should not occur: pucUDPPayloadBuffer is part of a xNetworkBufferDescriptor */ if( pxNetworkBuffer != NULL ) { pxMessage = (DNSMessage_t *)pucUDPPayloadBuffer; /* As the fields in the structures are not word-aligned, we have to copy the values byte-by-byte using macro's vSetField16() and vSetField32() */ vSetField16( pxMessage, DNSMessage_t, usFlags, dnsNBNS_QUERY_RESPONSE_FLAGS ); /* 0x8500 */ vSetField16( pxMessage, DNSMessage_t, usQuestions, 0 ); vSetField16( pxMessage, DNSMessage_t, usAnswers, 1 ); vSetField16( pxMessage, DNSMessage_t, usAuthorityRRs, 0 ); vSetField16( pxMessage, DNSMessage_t, usAdditionalRRs, 0 ); pxAnswer = (NBNSAnswer_t *)( pucUDPPayloadBuffer + offsetof( NBNSRequest_t, usType ) ); vSetField16( pxAnswer, NBNSAnswer_t, usType, usType ); /* Type */ vSetField16( pxAnswer, NBNSAnswer_t, usClass, dnsNBNS_CLASS_IN ); /* Class */ vSetField32( pxAnswer, NBNSAnswer_t, ulTTL, dnsNBNS_TTL_VALUE ); vSetField16( pxAnswer, NBNSAnswer_t, usDataLength, 6 ); /* 6 bytes including the length field */ vSetField16( pxAnswer, NBNSAnswer_t, usNbFlags, dnsNBNS_NAME_FLAGS ); vSetField32( pxAnswer, NBNSAnswer_t, ulIPAddress, FreeRTOS_ntohl( *ipLOCAL_IP_ADDRESS_POINTER ) ); usLength = ( uint16_t ) ( offsetof( NBNSRequest_t, usType ) + sizeof( NBNSAnswer_t ) ); prvReplyDNSMessage( pxNetworkBuffer, usLength ); } } } } #endif /* ipconfigUSE_NBNS */ /*-----------------------------------------------------------*/ static Socket_t prvCreateDNSSocket( void ) { Socket_t xSocket = NULL; struct freertos_sockaddr xAddress; BaseType_t xReturn; TickType_t xTimeoutTime = pdMS_TO_TICKS( 200 ); /* This must be the first time this function has been called. Create the socket. */ xSocket = FreeRTOS_socket( FREERTOS_AF_INET, FREERTOS_SOCK_DGRAM, FREERTOS_IPPROTO_UDP ); /* Auto bind the port. */ xAddress.sin_port = 0u; xReturn = FreeRTOS_bind( xSocket, &xAddress, sizeof( xAddress ) ); /* Check the bind was successful, and clean up if not. */ if( xReturn != 0 ) { FreeRTOS_closesocket( xSocket ); xSocket = NULL; } else { /* Set the send and receive timeouts. */ FreeRTOS_setsockopt( xSocket, 0, FREERTOS_SO_RCVTIMEO, ( void * ) &xTimeoutTime, sizeof( TickType_t ) ); FreeRTOS_setsockopt( xSocket, 0, FREERTOS_SO_SNDTIMEO, ( void * ) &xTimeoutTime, sizeof( TickType_t ) ); } return xSocket; } /*-----------------------------------------------------------*/ #if( ( ipconfigUSE_NBNS == 1 ) || ( ipconfigUSE_LLMNR == 1 ) ) static void prvReplyDNSMessage( NetworkBufferDescriptor_t *pxNetworkBuffer, BaseType_t lNetLength ) { UDPPacket_t *pxUDPPacket; IPHeader_t *pxIPHeader; UDPHeader_t *pxUDPHeader; pxUDPPacket = (UDPPacket_t *) pxNetworkBuffer->pucEthernetBuffer; pxIPHeader = &pxUDPPacket->xIPHeader; pxUDPHeader = &pxUDPPacket->xUDPHeader; /* HT: started using defines like 'ipSIZE_OF_xxx' */ pxIPHeader->usLength = FreeRTOS_htons( lNetLength + ipSIZE_OF_IPv4_HEADER + ipSIZE_OF_UDP_HEADER ); /* HT:endian: should not be translated, copying from packet to packet */ pxIPHeader->ulDestinationIPAddress = pxIPHeader->ulSourceIPAddress; pxIPHeader->ulSourceIPAddress = *ipLOCAL_IP_ADDRESS_POINTER; pxIPHeader->ucTimeToLive = ipconfigUDP_TIME_TO_LIVE; pxIPHeader->usIdentification = FreeRTOS_htons( usPacketIdentifier ); usPacketIdentifier++; pxUDPHeader->usLength = FreeRTOS_htons( lNetLength + ipSIZE_OF_UDP_HEADER ); vFlip_16( pxUDPPacket->xUDPHeader.usSourcePort, pxUDPPacket->xUDPHeader.usDestinationPort ); /* Important: tell NIC driver how many bytes must be sent */ pxNetworkBuffer->xDataLength = ( size_t ) ( lNetLength + ipSIZE_OF_IPv4_HEADER + ipSIZE_OF_UDP_HEADER + ipSIZE_OF_ETH_HEADER ); #if( ipconfigDRIVER_INCLUDED_TX_IP_CHECKSUM == 0 ) { /* calculate the IP header checksum */ pxIPHeader->usHeaderChecksum = 0x00; pxIPHeader->usHeaderChecksum = usGenerateChecksum( 0UL, ( uint8_t * ) &( pxIPHeader->ucVersionHeaderLength ), ipSIZE_OF_IPv4_HEADER ); pxIPHeader->usHeaderChecksum = ~FreeRTOS_htons( pxIPHeader->usHeaderChecksum ); /* calculate the UDP checksum for outgoing package */ usGenerateProtocolChecksum( ( uint8_t* ) pxUDPPacket, pxNetworkBuffer->xDataLength, pdTRUE ); } #endif /* This function will fill in the eth addresses and send the packet */ vReturnEthernetFrame( pxNetworkBuffer, pdFALSE ); } #endif /* ipconfigUSE_NBNS == 1 || ipconfigUSE_LLMNR == 1 */ /*-----------------------------------------------------------*/ #if( ipconfigUSE_DNS_CACHE == 1 ) static void prvProcessDNSCache( const char *pcName, uint32_t *pulIP, uint32_t ulTTL, BaseType_t xLookUp ) { BaseType_t x; BaseType_t xFound = pdFALSE; uint32_t ulCurrentTimeSeconds = ( xTaskGetTickCount() / portTICK_PERIOD_MS ) / 1000; static BaseType_t xFreeEntry = 0; configASSERT(pcName); /* For each entry in the DNS cache table. */ for( x = 0; x < ipconfigDNS_CACHE_ENTRIES; x++ ) { if( xDNSCache[ x ].pcName[ 0 ] == 0 ) { continue; } if( 0 == strcmp( xDNSCache[ x ].pcName, pcName ) ) { /* Is this function called for a lookup or to add/update an IP address? */ if( xLookUp != pdFALSE ) { /* Confirm that the record is still fresh. */ if( ulCurrentTimeSeconds < ( xDNSCache[ x ].ulTimeWhenAddedInSeconds + FreeRTOS_ntohl( xDNSCache[ x ].ulTTL ) ) ) { *pulIP = xDNSCache[ x ].ulIPAddress; } else { /* Age out the old cached record. */ xDNSCache[ x ].pcName[ 0 ] = 0; } } else { xDNSCache[ x ].ulIPAddress = *pulIP; xDNSCache[ x ].ulTTL = ulTTL; xDNSCache[ x ].ulTimeWhenAddedInSeconds = ulCurrentTimeSeconds; } xFound = pdTRUE; break; } } if( xFound == pdFALSE ) { if( xLookUp != pdFALSE ) { *pulIP = 0; } else { /* Add or update the item. */ if( strlen( pcName ) < ipconfigDNS_CACHE_NAME_LENGTH ) { strcpy( xDNSCache[ xFreeEntry ].pcName, pcName ); xDNSCache[ xFreeEntry ].ulIPAddress = *pulIP; xDNSCache[ xFreeEntry ].ulTTL = ulTTL; xDNSCache[ xFreeEntry ].ulTimeWhenAddedInSeconds = ulCurrentTimeSeconds; xFreeEntry++; if( xFreeEntry == ipconfigDNS_CACHE_ENTRIES ) { xFreeEntry = 0; } } } } if( ( xLookUp == 0 ) || ( *pulIP != 0 ) ) { FreeRTOS_debug_printf( ( "prvProcessDNSCache: %s: '%s' @ %lxip\n", xLookUp ? "look-up" : "add", pcName, FreeRTOS_ntohl( *pulIP ) ) ); } } #endif /* ipconfigUSE_DNS_CACHE */ #endif /* ipconfigUSE_DNS != 0 */ /*-----------------------------------------------------------*/ /* Provide access to private members for testing. */ #ifdef AMAZON_FREERTOS_ENABLE_UNIT_TESTS #include "iot_freertos_tcp_test_access_dns_define.h" #endif