mongoose/test/freertos-tcp/FreeRTOS_ARP.c

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2021-05-11 09:12:06 +01:00
/*
* FreeRTOS+TCP V2.3.2
* Copyright (C) 2020 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
*/
/**
* @file FreeRTOS_ARP.c
* @brief Implements the Address Resolution Protocol for the FreeRTOS+TCP network stack.
*/
/* Standard includes. */
#include <stdint.h>
#include <stdio.h>
/* 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_ARP.h"
#include "FreeRTOS_UDP_IP.h"
#include "FreeRTOS_DHCP.h"
#if ( ipconfigUSE_LLMNR == 1 )
#include "FreeRTOS_DNS.h"
#endif /* ipconfigUSE_LLMNR */
#include "NetworkBufferManagement.h"
#include "NetworkInterface.h"
/** @brief When the age of an entry in the ARP table reaches this value (it counts down
* to zero, so this is an old entry) an ARP request will be sent to see if the
* entry is still valid and can therefore be refreshed. */
#define arpMAX_ARP_AGE_BEFORE_NEW_ARP_REQUEST ( 3 )
/** @brief The time between gratuitous ARPs. */
#ifndef arpGRATUITOUS_ARP_PERIOD
#define arpGRATUITOUS_ARP_PERIOD ( pdMS_TO_TICKS( 20000U ) )
#endif
/*-----------------------------------------------------------*/
/*
* Lookup an MAC address in the ARP cache from the IP address.
*/
static eARPLookupResult_t prvCacheLookup( uint32_t ulAddressToLookup,
MACAddress_t * const pxMACAddress );
/*-----------------------------------------------------------*/
/** @brief The ARP cache. */
_static ARPCacheRow_t xARPCache[ ipconfigARP_CACHE_ENTRIES ];
/** @brief The time at which the last gratuitous ARP was sent. Gratuitous ARPs are used
* to ensure ARP tables are up to date and to detect IP address conflicts. */
static TickType_t xLastGratuitousARPTime = ( TickType_t ) 0;
/*
* IP-clash detection is currently only used internally. When DHCP doesn't respond, the
* driver can try out a random LinkLayer IP address (169.254.x.x). It will send out a
* gratuitous ARP message and, after a period of time, check the variables here below:
*/
#if ( ipconfigARP_USE_CLASH_DETECTION != 0 )
/* Becomes non-zero if another device responded to a gratuitous ARP message. */
BaseType_t xARPHadIPClash;
/* MAC-address of the other device containing the same IP-address. */
MACAddress_t xARPClashMacAddress;
#endif /* ipconfigARP_USE_CLASH_DETECTION */
/*-----------------------------------------------------------*/
/**
* @brief Process the ARP packets.
*
* @param[in] pxARPFrame: The ARP Frame (the ARP packet).
*
* @return An enum which says whether to return the frame or to release it.
*/
eFrameProcessingResult_t eARPProcessPacket( ARPPacket_t * const pxARPFrame )
{
eFrameProcessingResult_t eReturn = eReleaseBuffer;
ARPHeader_t * pxARPHeader;
uint32_t ulTargetProtocolAddress, ulSenderProtocolAddress;
/* memcpy() helper variables for MISRA Rule 21.15 compliance*/
const void * pvCopySource;
void * pvCopyDest;
pxARPHeader = &( pxARPFrame->xARPHeader );
/* The field ulSenderProtocolAddress is badly aligned, copy byte-by-byte. */
/*
* Use helper variables for memcpy() to remain
* compliant with MISRA Rule 21.15. These should be
* optimized away.
*/
pvCopySource = pxARPHeader->ucSenderProtocolAddress;
pvCopyDest = &ulSenderProtocolAddress;
( void ) memcpy( pvCopyDest, pvCopySource, sizeof( ulSenderProtocolAddress ) );
/* The field ulTargetProtocolAddress is well-aligned, a 32-bits copy. */
ulTargetProtocolAddress = pxARPHeader->ulTargetProtocolAddress;
traceARP_PACKET_RECEIVED();
/* Don't do anything if the local IP address is zero because
* that means a DHCP request has not completed. */
if( *ipLOCAL_IP_ADDRESS_POINTER != 0UL )
{
switch( pxARPHeader->usOperation )
{
case ipARP_REQUEST:
/* The packet contained an ARP request. Was it for the IP
* address of the node running this code? */
if( ulTargetProtocolAddress == *ipLOCAL_IP_ADDRESS_POINTER )
{
iptraceSENDING_ARP_REPLY( ulSenderProtocolAddress );
/* The request is for the address of this node. Add the
* entry into the ARP cache, or refresh the entry if it
* already exists. */
vARPRefreshCacheEntry( &( pxARPHeader->xSenderHardwareAddress ), ulSenderProtocolAddress );
/* Generate a reply payload in the same buffer. */
pxARPHeader->usOperation = ( uint16_t ) ipARP_REPLY;
if( ulTargetProtocolAddress == ulSenderProtocolAddress )
{
/* A double IP address is detected! */
/* Give the sources MAC address the value of the broadcast address, will be swapped later */
/*
* Use helper variables for memcpy() to remain
* compliant with MISRA Rule 21.15. These should be
* optimized away.
*/
pvCopySource = xBroadcastMACAddress.ucBytes;
pvCopyDest = pxARPFrame->xEthernetHeader.xSourceAddress.ucBytes;
( void ) memcpy( pvCopyDest, pvCopySource, sizeof( xBroadcastMACAddress ) );
( void ) memset( pxARPHeader->xTargetHardwareAddress.ucBytes, 0, sizeof( MACAddress_t ) );
pxARPHeader->ulTargetProtocolAddress = 0UL;
}
else
{
/*
* Use helper variables for memcpy() to remain
* compliant with MISRA Rule 21.15. These should be
* optimized away.
*/
pvCopySource = pxARPHeader->xSenderHardwareAddress.ucBytes;
pvCopyDest = pxARPHeader->xTargetHardwareAddress.ucBytes;
( void ) memcpy( pvCopyDest, pvCopySource, sizeof( MACAddress_t ) );
pxARPHeader->ulTargetProtocolAddress = ulSenderProtocolAddress;
}
/*
* Use helper variables for memcpy() to remain
* compliant with MISRA Rule 21.15. These should be
* optimized away.
*/
pvCopySource = ipLOCAL_MAC_ADDRESS;
pvCopyDest = pxARPHeader->xSenderHardwareAddress.ucBytes;
( void ) memcpy( pvCopyDest, pvCopySource, sizeof( MACAddress_t ) );
pvCopySource = ipLOCAL_IP_ADDRESS_POINTER;
pvCopyDest = pxARPHeader->ucSenderProtocolAddress;
( void ) memcpy( pvCopyDest, pvCopySource, sizeof( pxARPHeader->ucSenderProtocolAddress ) );
eReturn = eReturnEthernetFrame;
}
break;
case ipARP_REPLY:
iptracePROCESSING_RECEIVED_ARP_REPLY( ulTargetProtocolAddress );
vARPRefreshCacheEntry( &( pxARPHeader->xSenderHardwareAddress ), ulSenderProtocolAddress );
/* Process received ARP frame to see if there is a clash. */
#if ( ipconfigARP_USE_CLASH_DETECTION != 0 )
{
if( ulSenderProtocolAddress == *ipLOCAL_IP_ADDRESS_POINTER )
{
xARPHadIPClash = pdTRUE;
/* Remember the MAC-address of the other device which has the same IP-address. */
( void ) memcpy( xARPClashMacAddress.ucBytes, pxARPHeader->xSenderHardwareAddress.ucBytes, sizeof( xARPClashMacAddress.ucBytes ) );
}
}
#endif /* ipconfigARP_USE_CLASH_DETECTION */
break;
default:
/* Invalid. */
break;
}
}
return eReturn;
}
/*-----------------------------------------------------------*/
#if ( ipconfigUSE_ARP_REMOVE_ENTRY != 0 )
/**
* @brief Remove an ARP cache entry that matches with .pxMACAddress.
*
* @param[in] pxMACAddress: Pointer to the MAC address whose entry shall
* be removed..
* @return When the entry was found and remove: the IP-address, otherwise zero.
*/
uint32_t ulARPRemoveCacheEntryByMac( const MACAddress_t * pxMACAddress )
{
BaseType_t x;
uint32_t lResult = 0;
configASSERT( pxMACAddress != NULL );
/* For each entry in the ARP cache table. */
for( x = 0; x < ipconfigARP_CACHE_ENTRIES; x++ )
{
if( ( memcmp( xARPCache[ x ].xMACAddress.ucBytes, pxMACAddress->ucBytes, sizeof( pxMACAddress->ucBytes ) ) == 0 ) )
{
lResult = xARPCache[ x ].ulIPAddress;
( void ) memset( &xARPCache[ x ], 0, sizeof( xARPCache[ x ] ) );
break;
}
}
return lResult;
}
#endif /* ipconfigUSE_ARP_REMOVE_ENTRY != 0 */
/*-----------------------------------------------------------*/
/**
* @brief Add/update the ARP cache entry MAC-address to IP-address mapping.
*
* @param[in] pxMACAddress: Pointer to the MAC address whose mapping is being
* updated.
* @param[in] ulIPAddress: 32-bit representation of the IP-address whose mapping
* is being updated.
*/
void vARPRefreshCacheEntry( const MACAddress_t * pxMACAddress,
const uint32_t ulIPAddress )
{
BaseType_t x = 0;
BaseType_t xIpEntry = -1;
BaseType_t xMacEntry = -1;
BaseType_t xUseEntry = 0;
uint8_t ucMinAgeFound = 0U;
#if ( ipconfigARP_STORES_REMOTE_ADDRESSES == 0 )
/* Only process the IP address if it is on the local network.
* Unless: when '*ipLOCAL_IP_ADDRESS_POINTER' equals zero, the IP-address
* and netmask are still unknown. */
if( ( ( ulIPAddress & xNetworkAddressing.ulNetMask ) == ( ( *ipLOCAL_IP_ADDRESS_POINTER ) & xNetworkAddressing.ulNetMask ) ) ||
( *ipLOCAL_IP_ADDRESS_POINTER == 0UL ) )
#else
/* If ipconfigARP_STORES_REMOTE_ADDRESSES is non-zero, IP addresses with
* a different netmask will also be stored. After when replying to a UDP
* message from a different netmask, the IP address can be looped up and a
* reply sent. This option is useful for systems with multiple gateways,
* the reply will surely arrive. If ipconfigARP_STORES_REMOTE_ADDRESSES is
* zero the the gateway address is the only option. */
if( pdTRUE )
#endif
{
/* Start with the maximum possible number. */
ucMinAgeFound--;
/* For each entry in the ARP cache table. */
for( x = 0; x < ipconfigARP_CACHE_ENTRIES; x++ )
{
BaseType_t xMatchingMAC;
if( pxMACAddress != NULL )
{
if( memcmp( xARPCache[ x ].xMACAddress.ucBytes, pxMACAddress->ucBytes, sizeof( pxMACAddress->ucBytes ) ) == 0 )
{
xMatchingMAC = pdTRUE;
}
else
{
xMatchingMAC = pdFALSE;
}
}
else
{
xMatchingMAC = pdFALSE;
}
/* Does this line in the cache table hold an entry for the IP
* address being queried? */
if( xARPCache[ x ].ulIPAddress == ulIPAddress )
{
if( pxMACAddress == NULL )
{
/* In case the parameter pxMACAddress is NULL, an entry will be reserved to
* indicate that there is an outstanding ARP request, This entry will have
* "ucValid == pdFALSE". */
xIpEntry = x;
break;
}
/* See if the MAC-address also matches. */
if( xMatchingMAC != pdFALSE )
{
/* This function will be called for each received packet
* As this is by far the most common path the coding standard
* is relaxed in this case and a return is permitted as an
* optimisation. */
xARPCache[ x ].ucAge = ( uint8_t ) ipconfigMAX_ARP_AGE;
xARPCache[ x ].ucValid = ( uint8_t ) pdTRUE;
return;
}
/* Found an entry containing ulIPAddress, but the MAC address
* doesn't match. Might be an entry with ucValid=pdFALSE, waiting
* for an ARP reply. Still want to see if there is match with the
* given MAC address.ucBytes. If found, either of the two entries
* must be cleared. */
xIpEntry = x;
}
else if( xMatchingMAC != pdFALSE )
{
/* Found an entry with the given MAC-address, but the IP-address
* is different. Continue looping to find a possible match with
* ulIPAddress. */
#if ( ipconfigARP_STORES_REMOTE_ADDRESSES != 0 )
/* If ARP stores the MAC address of IP addresses outside the
* network, than the MAC address of the gateway should not be
* overwritten. */
BaseType_t bIsLocal[ 2 ];
bIsLocal[ 0 ] = ( ( xARPCache[ x ].ulIPAddress & xNetworkAddressing.ulNetMask ) == ( ( *ipLOCAL_IP_ADDRESS_POINTER ) & xNetworkAddressing.ulNetMask ) );
bIsLocal[ 1 ] = ( ( ulIPAddress & xNetworkAddressing.ulNetMask ) == ( ( *ipLOCAL_IP_ADDRESS_POINTER ) & xNetworkAddressing.ulNetMask ) );
if( bIsLocal[ 0 ] == bIsLocal[ 1 ] )
{
xMacEntry = x;
}
#else /* if ( ipconfigARP_STORES_REMOTE_ADDRESSES != 0 ) */
xMacEntry = x;
#endif /* if ( ipconfigARP_STORES_REMOTE_ADDRESSES != 0 ) */
}
/* _HT_
* Shouldn't we test for xARPCache[ x ].ucValid == pdFALSE here ? */
else if( xARPCache[ x ].ucAge < ucMinAgeFound )
{
/* As the table is traversed, remember the table row that
* contains the oldest entry (the lowest age count, as ages are
* decremented to zero) so the row can be re-used if this function
* needs to add an entry that does not already exist. */
ucMinAgeFound = xARPCache[ x ].ucAge;
xUseEntry = x;
}
else
{
/* Nothing happens to this cache entry for now. */
}
}
if( xMacEntry >= 0 )
{
xUseEntry = xMacEntry;
if( xIpEntry >= 0 )
{
/* Both the MAC address as well as the IP address were found in
* different locations: clear the entry which matches the
* IP-address */
( void ) memset( &( xARPCache[ xIpEntry ] ), 0, sizeof( ARPCacheRow_t ) );
}
}
else if( xIpEntry >= 0 )
{
/* An entry containing the IP-address was found, but it had a different MAC address */
xUseEntry = xIpEntry;
}
else
{
/* No matching entry found. */
}
/* If the entry was not found, we use the oldest entry and set the IPaddress */
xARPCache[ xUseEntry ].ulIPAddress = ulIPAddress;
if( pxMACAddress != NULL )
{
( void ) memcpy( xARPCache[ xUseEntry ].xMACAddress.ucBytes, pxMACAddress->ucBytes, sizeof( pxMACAddress->ucBytes ) );
iptraceARP_TABLE_ENTRY_CREATED( ulIPAddress, ( *pxMACAddress ) );
/* And this entry does not need immediate attention */
xARPCache[ xUseEntry ].ucAge = ( uint8_t ) ipconfigMAX_ARP_AGE;
xARPCache[ xUseEntry ].ucValid = ( uint8_t ) pdTRUE;
}
else if( xIpEntry < 0 )
{
xARPCache[ xUseEntry ].ucAge = ( uint8_t ) ipconfigMAX_ARP_RETRANSMISSIONS;
xARPCache[ xUseEntry ].ucValid = ( uint8_t ) pdFALSE;
}
else
{
/* Nothing will be stored. */
}
}
}
/*-----------------------------------------------------------*/
#if ( ipconfigUSE_ARP_REVERSED_LOOKUP == 1 )
/**
* @brief Retrieve an entry from the cache table
*
* @param[in] pxMACAddress: The MAC-address of the entry of interest.
* @param[out] pulIPAddress: set to the IP-address found, or unchanged when not found.
*
* @return Either eARPCacheMiss or eARPCacheHit.
*/
eARPLookupResult_t eARPGetCacheEntryByMac( MACAddress_t * const pxMACAddress,
uint32_t * pulIPAddress )
{
BaseType_t x;
eARPLookupResult_t eReturn = eARPCacheMiss;
configASSERT( pxMACAddress != NULL );
configASSERT( pulIPAddress != NULL );
/* Loop through each entry in the ARP cache. */
for( x = 0; x < ipconfigARP_CACHE_ENTRIES; x++ )
{
/* Does this row in the ARP cache table hold an entry for the MAC
* address being searched? */
if( memcmp( pxMACAddress->ucBytes, xARPCache[ x ].xMACAddress.ucBytes, sizeof( MACAddress_t ) ) == 0 )
{
*pulIPAddress = xARPCache[ x ].ulIPAddress;
eReturn = eARPCacheHit;
break;
}
}
return eReturn;
}
#endif /* ipconfigUSE_ARP_REVERSED_LOOKUP */
/*-----------------------------------------------------------*/
/**
* @brief Look for ulIPAddress in the ARP cache.
*
* @param[in,out] pulIPAddress: Pointer to the IP-address to be queried to the ARP cache.
* @param[in,out] pxMACAddress: Pointer to a MACAddress_t variable where the MAC address
* will be stored, if found.
*
* @return If the IP address exists, copy the associated MAC address into pxMACAddress,
* refresh the ARP cache entry's age, and return eARPCacheHit. If the IP
* address does not exist in the ARP cache return eARPCacheMiss. If the packet
* cannot be sent for any reason (maybe DHCP is still in process, or the
* addressing needs a gateway but there isn't a gateway defined) then return
* eCantSendPacket.
*/
eARPLookupResult_t eARPGetCacheEntry( uint32_t * pulIPAddress,
MACAddress_t * const pxMACAddress )
{
eARPLookupResult_t eReturn;
uint32_t ulAddressToLookup;
ulAddressToLookup = *pulIPAddress;
#if ( ipconfigUSE_LLMNR == 1 )
if( ulAddressToLookup == ipLLMNR_IP_ADDR ) /* Is in network byte order. */
{
/* The LLMNR IP-address has a fixed virtual MAC address. */
( void ) memcpy( pxMACAddress->ucBytes, xLLMNR_MacAdress.ucBytes, sizeof( MACAddress_t ) );
eReturn = eARPCacheHit;
}
else
#endif
if( xIsIPv4Multicast( ulAddressToLookup ) != 0 )
{
/* Get the lowest 23 bits of the IP-address. */
vSetMultiCastIPv4MacAddress( ulAddressToLookup, pxMACAddress );
eReturn = eARPCacheHit;
}
else if( ( *pulIPAddress == ipBROADCAST_IP_ADDRESS ) || /* Is it the general broadcast address 255.255.255.255? */
( *pulIPAddress == xNetworkAddressing.ulBroadcastAddress ) ) /* Or a local broadcast address, eg 192.168.1.255? */
{
/* This is a broadcast so it uses the broadcast MAC address. */
( void ) memcpy( pxMACAddress->ucBytes, xBroadcastMACAddress.ucBytes, sizeof( MACAddress_t ) );
eReturn = eARPCacheHit;
}
else if( *ipLOCAL_IP_ADDRESS_POINTER == 0UL )
{
/* The IP address has not yet been assigned, so there is nothing that
* can be done. */
eReturn = eCantSendPacket;
}
else
{
eReturn = eARPCacheMiss;
if( ( *pulIPAddress & xNetworkAddressing.ulNetMask ) != ( ( *ipLOCAL_IP_ADDRESS_POINTER ) & xNetworkAddressing.ulNetMask ) )
{
/* No matching end-point is found, look for a gateway. */
#if ( ipconfigARP_STORES_REMOTE_ADDRESSES == 1 )
eReturn = prvCacheLookup( *pulIPAddress, pxMACAddress );
if( eReturn == eARPCacheHit )
{
/* The stack is configured to store 'remote IP addresses', i.e. addresses
* belonging to a different the netmask. prvCacheLookup() returned a hit, so
* the MAC address is known. */
}
else
#endif
{
/* The IP address is off the local network, so look up the
* hardware address of the router, if any. */
if( xNetworkAddressing.ulGatewayAddress != ( uint32_t ) 0U )
{
ulAddressToLookup = xNetworkAddressing.ulGatewayAddress;
}
else
{
ulAddressToLookup = *pulIPAddress;
}
}
}
else
{
/* The IP address is on the local network, so lookup the requested
* IP address directly. */
ulAddressToLookup = *pulIPAddress;
}
#if ( ipconfigARP_STORES_REMOTE_ADDRESSES == 1 )
if( eReturn == eARPCacheMiss ) /*lint !e774: (Info -- Boolean within 'if' always evaluates to True, depending on configuration. */
#else
/* No cache look-up was done, so the result is still 'eARPCacheMiss'. */
#endif
{
if( ulAddressToLookup == 0UL )
{
/* The address is not on the local network, and there is not a
* router. */
eReturn = eCantSendPacket;
}
else
{
eReturn = prvCacheLookup( ulAddressToLookup, pxMACAddress );
if( eReturn == eARPCacheMiss )
{
/* It might be that the ARP has to go to the gateway. */
*pulIPAddress = ulAddressToLookup;
}
}
}
}
return eReturn;
}
/*-----------------------------------------------------------*/
/**
* @brief Lookup an IP address in the ARP cache.
*
* @param[in] ulAddressToLookup: The 32-bit representation of an IP address to
* lookup.
* @param[out] pxMACAddress: A pointer to MACAddress_t variable where, if there
* is an ARP cache hit, the MAC address corresponding to
* the IP address will be stored.
*
* @return When the IP-address is found: eARPCacheHit, when not found: eARPCacheMiss,
* and when waiting for a ARP reply: eCantSendPacket.
*/
static eARPLookupResult_t prvCacheLookup( uint32_t ulAddressToLookup,
MACAddress_t * const pxMACAddress )
{
BaseType_t x;
eARPLookupResult_t eReturn = eARPCacheMiss;
/* Loop through each entry in the ARP cache. */
for( x = 0; x < ipconfigARP_CACHE_ENTRIES; x++ )
{
/* Does this row in the ARP cache table hold an entry for the IP address
* being queried? */
if( xARPCache[ x ].ulIPAddress == ulAddressToLookup )
{
/* A matching valid entry was found. */
if( xARPCache[ x ].ucValid == ( uint8_t ) pdFALSE )
{
/* This entry is waiting an ARP reply, so is not valid. */
eReturn = eCantSendPacket;
}
else
{
/* A valid entry was found. */
( void ) memcpy( pxMACAddress->ucBytes, xARPCache[ x ].xMACAddress.ucBytes, sizeof( MACAddress_t ) );
eReturn = eARPCacheHit;
}
break;
}
}
return eReturn;
}
/*-----------------------------------------------------------*/
/**
* @brief A call to this function will update (or 'Age') the ARP cache entries.
* The function will also try to prevent a removal of entry by sending
* an ARP query. It will also check whether we are waiting on an ARP
* reply - if we are, then an ARP request will be re-sent.
* In case an ARP entry has 'Aged' to 0, it will be removed from the ARP
* cache.
*/
void vARPAgeCache( void )
{
BaseType_t x;
TickType_t xTimeNow;
/* Loop through each entry in the ARP cache. */
for( x = 0; x < ipconfigARP_CACHE_ENTRIES; x++ )
{
/* If the entry is valid (its age is greater than zero). */
if( xARPCache[ x ].ucAge > 0U )
{
/* Decrement the age value of the entry in this ARP cache table row.
* When the age reaches zero it is no longer considered valid. */
( xARPCache[ x ].ucAge )--;
/* If the entry is not yet valid, then it is waiting an ARP
* reply, and the ARP request should be retransmitted. */
if( xARPCache[ x ].ucValid == ( uint8_t ) pdFALSE )
{
FreeRTOS_OutputARPRequest( xARPCache[ x ].ulIPAddress );
}
else if( xARPCache[ x ].ucAge <= ( uint8_t ) arpMAX_ARP_AGE_BEFORE_NEW_ARP_REQUEST )
{
/* This entry will get removed soon. See if the MAC address is
* still valid to prevent this happening. */
iptraceARP_TABLE_ENTRY_WILL_EXPIRE( xARPCache[ x ].ulIPAddress );
FreeRTOS_OutputARPRequest( xARPCache[ x ].ulIPAddress );
}
else
{
/* The age has just ticked down, with nothing to do. */
}
if( xARPCache[ x ].ucAge == 0U )
{
/* The entry is no longer valid. Wipe it out. */
iptraceARP_TABLE_ENTRY_EXPIRED( xARPCache[ x ].ulIPAddress );
xARPCache[ x ].ulIPAddress = 0UL;
}
}
}
xTimeNow = xTaskGetTickCount();
if( ( xLastGratuitousARPTime == ( TickType_t ) 0 ) || ( ( xTimeNow - xLastGratuitousARPTime ) > ( TickType_t ) arpGRATUITOUS_ARP_PERIOD ) )
{
FreeRTOS_OutputARPRequest( *ipLOCAL_IP_ADDRESS_POINTER );
xLastGratuitousARPTime = xTimeNow;
}
}
/*-----------------------------------------------------------*/
/**
* @brief Send a Gratuitous ARP packet to allow this node to announce the IP-MAC
* mapping to the entire network.
*/
void vARPSendGratuitous( void )
{
/* Setting xLastGratuitousARPTime to 0 will force a gratuitous ARP the next
* time vARPAgeCache() is called. */
xLastGratuitousARPTime = ( TickType_t ) 0;
/* Let the IP-task call vARPAgeCache(). */
( void ) xSendEventToIPTask( eARPTimerEvent );
}
/*-----------------------------------------------------------*/
/**
* @brief Create and send an ARP request packet.
*
* @param[in] ulIPAddress: A 32-bit representation of the IP-address whose
* physical (MAC) address is required.
*/
void FreeRTOS_OutputARPRequest( uint32_t ulIPAddress )
{
NetworkBufferDescriptor_t * pxNetworkBuffer;
/* This is called from the context of the IP event task, so a block time
* must not be used. */
pxNetworkBuffer = pxGetNetworkBufferWithDescriptor( sizeof( ARPPacket_t ), ( TickType_t ) 0U );
if( pxNetworkBuffer != NULL )
{
pxNetworkBuffer->ulIPAddress = ulIPAddress;
vARPGenerateRequestPacket( pxNetworkBuffer );
#if defined( ipconfigETHERNET_MINIMUM_PACKET_BYTES )
{
if( pxNetworkBuffer->xDataLength < ( size_t ) ipconfigETHERNET_MINIMUM_PACKET_BYTES )
{
BaseType_t xIndex;
for( xIndex = ( BaseType_t ) pxNetworkBuffer->xDataLength; xIndex < ( BaseType_t ) ipconfigETHERNET_MINIMUM_PACKET_BYTES; xIndex++ )
{
pxNetworkBuffer->pucEthernetBuffer[ xIndex ] = 0U;
}
pxNetworkBuffer->xDataLength = ( size_t ) ipconfigETHERNET_MINIMUM_PACKET_BYTES;
}
}
#endif /* if defined( ipconfigETHERNET_MINIMUM_PACKET_BYTES ) */
if( xIsCallingFromIPTask() != 0 )
{
iptraceNETWORK_INTERFACE_OUTPUT( pxNetworkBuffer->xDataLength, pxNetworkBuffer->pucEthernetBuffer );
/* Only the IP-task is allowed to call this function directly. */
( void ) xNetworkInterfaceOutput( pxNetworkBuffer, pdTRUE );
}
else
{
IPStackEvent_t xSendEvent;
/* Send a message to the IP-task to send this ARP packet. */
xSendEvent.eEventType = eNetworkTxEvent;
xSendEvent.pvData = pxNetworkBuffer;
if( xSendEventStructToIPTask( &xSendEvent, ( TickType_t ) portMAX_DELAY ) == pdFAIL )
{
/* Failed to send the message, so release the network buffer. */
vReleaseNetworkBufferAndDescriptor( pxNetworkBuffer );
}
}
}
}
/*--------------------------------------*/
/**
* @brief Generate an ARP request packet by copying various constant details to
* the buffer.
*
* @param[in,out] pxNetworkBuffer: Pointer to the buffer which has to be filled with
* the ARP request packet details.
*/
void vARPGenerateRequestPacket( NetworkBufferDescriptor_t * const pxNetworkBuffer )
{
/* Part of the Ethernet and ARP headers are always constant when sending an IPv4
* ARP packet. This array defines the constant parts, allowing this part of the
* packet to be filled in using a simple memcpy() instead of individual writes. */
static const uint8_t xDefaultPartARPPacketHeader[] =
{
0xff, 0xff, 0xff, 0xff, 0xff, 0xff, /* Ethernet destination address. */
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* Ethernet source address. */
0x08, 0x06, /* Ethernet frame type (ipARP_FRAME_TYPE). */
0x00, 0x01, /* usHardwareType (ipARP_HARDWARE_TYPE_ETHERNET). */
0x08, 0x00, /* usProtocolType. */
ipMAC_ADDRESS_LENGTH_BYTES, /* ucHardwareAddressLength. */
ipIP_ADDRESS_LENGTH_BYTES, /* ucProtocolAddressLength. */
0x00, 0x01, /* usOperation (ipARP_REQUEST). */
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* xSenderHardwareAddress. */
0x00, 0x00, 0x00, 0x00, /* ulSenderProtocolAddress. */
0x00, 0x00, 0x00, 0x00, 0x00, 0x00 /* xTargetHardwareAddress. */
};
ARPPacket_t * pxARPPacket;
/* memcpy() helper variables for MISRA Rule 21.15 compliance*/
const void * pvCopySource;
void * pvCopyDest;
/* Buffer allocation ensures that buffers always have space
* for an ARP packet. See buffer allocation implementations 1
* and 2 under portable/BufferManagement. */
configASSERT( pxNetworkBuffer != NULL );
configASSERT( pxNetworkBuffer->xDataLength >= sizeof( ARPPacket_t ) );
pxARPPacket = ipCAST_PTR_TO_TYPE_PTR( ARPPacket_t, pxNetworkBuffer->pucEthernetBuffer );
/* memcpy the const part of the header information into the correct
* location in the packet. This copies:
* xEthernetHeader.ulDestinationAddress
* xEthernetHeader.usFrameType;
* xARPHeader.usHardwareType;
* xARPHeader.usProtocolType;
* xARPHeader.ucHardwareAddressLength;
* xARPHeader.ucProtocolAddressLength;
* xARPHeader.usOperation;
* xARPHeader.xTargetHardwareAddress;
*/
/*
* Use helper variables for memcpy() to remain
* compliant with MISRA Rule 21.15. These should be
* optimized away.
*/
pvCopySource = xDefaultPartARPPacketHeader;
pvCopyDest = pxARPPacket;
( void ) memcpy( pvCopyDest, pvCopySource, sizeof( xDefaultPartARPPacketHeader ) );
pvCopySource = ipLOCAL_MAC_ADDRESS;
pvCopyDest = pxARPPacket->xEthernetHeader.xSourceAddress.ucBytes;
( void ) memcpy( pvCopyDest, pvCopySource, ipMAC_ADDRESS_LENGTH_BYTES );
pvCopySource = ipLOCAL_MAC_ADDRESS;
pvCopyDest = pxARPPacket->xARPHeader.xSenderHardwareAddress.ucBytes;
( void ) memcpy( pvCopyDest, pvCopySource, ipMAC_ADDRESS_LENGTH_BYTES );
pvCopySource = ipLOCAL_IP_ADDRESS_POINTER;
pvCopyDest = pxARPPacket->xARPHeader.ucSenderProtocolAddress;
( void ) memcpy( pvCopyDest, pvCopySource, sizeof( pxARPPacket->xARPHeader.ucSenderProtocolAddress ) );
pxARPPacket->xARPHeader.ulTargetProtocolAddress = pxNetworkBuffer->ulIPAddress;
pxNetworkBuffer->xDataLength = sizeof( ARPPacket_t );
iptraceCREATING_ARP_REQUEST( pxNetworkBuffer->ulIPAddress );
}
/*-----------------------------------------------------------*/
/**
* @brief A call to this function will clear the ARP cache.
*/
void FreeRTOS_ClearARP( void )
{
( void ) memset( xARPCache, 0, sizeof( xARPCache ) );
}
/*-----------------------------------------------------------*/
#if 1
/**
* @brief This function will check if the target IP-address belongs to this device.
* If so, the packet will be passed to the IP-stack, who will answer it.
* The function is to be called within the function xNetworkInterfaceOutput().
*
* @param[in] pxDescriptor: The network buffer which is to be checked for loop-back.
* @param[in] bReleaseAfterSend: pdTRUE: Driver is allowed to transfer ownership of descriptor.
* pdFALSE: Driver is not allowed to take ownership of descriptor,
* make a copy of it.
*
* @return pdTRUE/pdFALSE: There is/isn't a loopback address in the packet.
*/
BaseType_t xCheckLoopback( NetworkBufferDescriptor_t * const pxDescriptor,
BaseType_t bReleaseAfterSend )
{
BaseType_t xResult = pdFALSE;
NetworkBufferDescriptor_t * pxUseDescriptor = pxDescriptor;
const IPPacket_t * pxIPPacket = ipCAST_PTR_TO_TYPE_PTR( IPPacket_t, pxUseDescriptor->pucEthernetBuffer );
if( pxIPPacket->xEthernetHeader.usFrameType == ipIPv4_FRAME_TYPE )
{
if( memcmp( pxIPPacket->xEthernetHeader.xDestinationAddress.ucBytes, ipLOCAL_MAC_ADDRESS, ipMAC_ADDRESS_LENGTH_BYTES ) == 0 )
{
xResult = pdTRUE;
if( bReleaseAfterSend == pdFALSE )
{
/* Driver is not allowed to transfer the ownership
* of descriptor, so make a copy of it */
pxUseDescriptor =
pxDuplicateNetworkBufferWithDescriptor( pxDescriptor, pxDescriptor->xDataLength );
}
if( pxUseDescriptor != NULL )
{
IPStackEvent_t xRxEvent;
xRxEvent.eEventType = eNetworkRxEvent;
xRxEvent.pvData = pxUseDescriptor;
if( xSendEventStructToIPTask( &xRxEvent, 0U ) != pdTRUE )
{
vReleaseNetworkBufferAndDescriptor( pxUseDescriptor );
iptraceETHERNET_RX_EVENT_LOST();
FreeRTOS_printf( ( "prvEMACRxPoll: Can not queue return packet!\n" ) );
}
}
}
}
return xResult;
}
#endif /* 0 */
/*-----------------------------------------------------------*/
#if ( ipconfigHAS_PRINTF != 0 ) || ( ipconfigHAS_DEBUG_PRINTF != 0 )
void FreeRTOS_PrintARPCache( void )
{
BaseType_t x, xCount = 0;
/* Loop through each entry in the ARP cache. */
for( x = 0; x < ipconfigARP_CACHE_ENTRIES; x++ )
{
if( ( xARPCache[ x ].ulIPAddress != 0UL ) && ( xARPCache[ x ].ucAge > ( uint8_t ) 0U ) )
{
/* See if the MAC-address also matches, and we're all happy */
FreeRTOS_printf( ( "Arp %2ld: %3u - %16lxip : %02x:%02x:%02x : %02x:%02x:%02x\n",
x,
xARPCache[ x ].ucAge,
xARPCache[ x ].ulIPAddress,
xARPCache[ x ].xMACAddress.ucBytes[ 0 ],
xARPCache[ x ].xMACAddress.ucBytes[ 1 ],
xARPCache[ x ].xMACAddress.ucBytes[ 2 ],
xARPCache[ x ].xMACAddress.ucBytes[ 3 ],
xARPCache[ x ].xMACAddress.ucBytes[ 4 ],
xARPCache[ x ].xMACAddress.ucBytes[ 5 ] ) );
xCount++;
}
}
FreeRTOS_printf( ( "Arp has %ld entries\n", xCount ) );
}
#endif /* ( ipconfigHAS_PRINTF != 0 ) || ( ipconfigHAS_DEBUG_PRINTF != 0 ) */