/**************************************************************************** * net/route/net_cacheroute.c * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. The * ASF licenses this file to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance with the * License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the * License for the specific language governing permissions and limitations * under the License. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include "route/cacheroute.h" #include "route/route.h" #if defined(CONFIG_ROUTE_IPv4_CACHEROUTE) || defined(CONFIG_ROUTE_IPv6_CACHEROUTE) /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ /* Configuration ************************************************************/ #ifndef CONFIG_ROUTE_MAX_IPv4_CACHEROUTES # define CONFIG_ROUTE_MAX_IPv4_CACHEROUTES 4 #endif #ifndef CONFIG_ROUTE_MAX_IPv6_CACHEROUTES # define CONFIG_ROUTE_MAX_IPv6_CACHEROUTES 4 #endif /* Routing table initializer */ #define cacheroute_init(rr) \ do \ { \ (rr)->head = NULL; \ (rr)->tail = NULL; \ } \ while (0) /**************************************************************************** * Private Types ****************************************************************************/ #ifdef CONFIG_ROUTE_IPv4_CACHEROUTE /* This structure describes one entry in the routing table cache */ struct net_cache_ipv4_entry_s { struct net_route_ipv4_s entry; FAR struct net_cache_ipv4_entry_s *flink; }; /* This structure describes the head of a routing table cache list */ struct net_cache_ipv4_queue_s { FAR struct net_cache_ipv4_entry_s *head; FAR struct net_cache_ipv4_entry_s *tail; }; #endif #ifdef CONFIG_ROUTE_IPv6_CACHEROUTE /* This structure describes one entry in the routing table cache */ struct net_cache_ipv6_entry_s { struct net_route_ipv6_s entry; FAR struct net_cache_ipv6_entry_s *flink; }; /* This structure describes the head of a routing table cache list */ struct net_cache_ipv6_queue_s { FAR struct net_cache_ipv6_entry_s *head; FAR struct net_cache_ipv6_entry_s *tail; }; #endif /**************************************************************************** * Private Data ****************************************************************************/ /* These are the routing tables */ #if defined(CONFIG_ROUTE_IPv4_CACHEROUTE) /* The in-memory cache as a singly linked list. */ static struct net_cache_ipv4_queue_s g_ipv4_cache; /* List of free routing table cache entries */ static struct net_cache_ipv4_queue_s g_free_ipv4cache; /* Pre-allocated routing table cache entries */ static struct net_cache_ipv4_entry_s g_prealloc_ipv4cache[CONFIG_ROUTE_MAX_IPv4_CACHEROUTES]; /* Serializes access to the routing table cache */ static sem_t g_ipv4_cachelock; #endif #if defined(CONFIG_ROUTE_IPv6_CACHEROUTE) /* The in-memory routing tables are represented as singly linked lists. */ static struct net_cache_ipv6_queue_s g_ipv6_cache; /* List of free routing table cache entries */ static struct net_cache_ipv6_queue_s g_free_ipv6cache; /* Pre-allocated routing table cache entries */ static struct net_cache_ipv6_entry_s g_prealloc_ipv6cache[CONFIG_ROUTE_MAX_IPv6_CACHEROUTES]; /* Serializes access to the routing table cache */ static sem_t g_ipv6_cachelock; #endif /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: net_lock_ipv4_cache and net_lock_ipv6_cache * * Description: * Lock the routing table cache list. * * Input Parameters: * None * * Returned Value: * Zero (OK) is returned on success; A negated errno value is returned on * any failure. * ****************************************************************************/ #define net_lock_ipv4_cache() nxsem_wait_uninterruptible(&g_ipv4_cachelock) #define net_lock_ipv6_cache() nxsem_wait_uninterruptible(&g_ipv6_cachelock) /**************************************************************************** * Name: net_unlock_ipv4_cache and net_unlock_ipv6_cache * * Description: * Unlock the routing table cache list. * * Input Parameters: * None * * Returned Value: * None * ****************************************************************************/ #define net_unlock_ipv4_cache() (void)nxsem_post(&g_ipv4_cachelock) #define net_unlock_ipv6_cache() (void)nxsem_post(&g_ipv6_cachelock) /**************************************************************************** * Name: net_add_newest_ipv4 and net_add_newest_ipv6 * * Description: * Add a new entry to the routing table cache list. The list is ordered * by "new-ness" so this would be the entry at the head of the list. * * Input Parameters: * cache - The cache entry to add to the head of the routing table cache * list. * * Returned Value: * None * * Assumptions: * Caller has the routing table cache locked. * ****************************************************************************/ #ifdef CONFIG_ROUTE_IPv4_CACHEROUTE static void net_add_newest_ipv4(FAR struct net_cache_ipv4_entry_s *cache) { cache->flink = g_ipv4_cache.head; if (!g_ipv4_cache.head) { g_ipv4_cache.tail = cache; } g_ipv4_cache.head = cache; } #endif #ifdef CONFIG_ROUTE_IPv6_CACHEROUTE static void net_add_newest_ipv6(FAR struct net_cache_ipv6_entry_s *cache) { cache->flink = g_ipv6_cache.head; if (!g_ipv6_cache.head) { g_ipv6_cache.tail = cache; } g_ipv6_cache.head = cache; } #endif /**************************************************************************** * Name: net_remove_oldest_ipv4 and net_remove_oldest_ipv6 * * Description: * Remove the oldest entry from the routing table cache list. The list is * ordered * * Input Parameters: * None * * Returned Value: * On success, a pointer to the oldest routing table cache entry is * returned. NULL would be returned if the routing table cache is empty. * * Assumptions: * Caller has the routing table cache locked. * ****************************************************************************/ #ifdef CONFIG_ROUTE_IPv4_CACHEROUTE FAR struct net_cache_ipv4_entry_s *net_remove_oldest_ipv4(void) { FAR struct net_cache_ipv4_entry_s *cache; FAR struct net_cache_ipv4_entry_s *prev; cache = g_ipv4_cache.tail; if (cache != NULL) { if (g_ipv4_cache.head == g_ipv4_cache.tail) { g_ipv4_cache.head = NULL; g_ipv4_cache.tail = NULL; } else { for (prev = g_ipv4_cache.head; prev != NULL && prev->flink != cache; prev = prev->flink); if (prev != NULL) { prev->flink = NULL; g_ipv4_cache.tail = prev; } } cache->flink = NULL; } return cache; } #endif #ifdef CONFIG_ROUTE_IPv6_CACHEROUTE FAR struct net_cache_ipv6_entry_s *net_remove_oldest_ipv6(void) { FAR struct net_cache_ipv6_entry_s *cache; FAR struct net_cache_ipv6_entry_s *prev; cache = g_ipv6_cache.tail; if (cache != NULL) { if (g_ipv6_cache.head == g_ipv6_cache.tail) { g_ipv6_cache.head = NULL; g_ipv6_cache.tail = NULL; } else { for (prev = g_ipv6_cache.head; prev != NULL && prev->flink != cache; prev = prev->flink); if (prev != NULL) { prev->flink = NULL; g_ipv6_cache.tail = prev; } } cache->flink = NULL; } return cache; } #endif /**************************************************************************** * Name: net_alloccache_ipv4 and net_alloccache_ipv6 * * Description: * Allocate one routing table cache entry by removing it from the free * list. If the free list is empty, then remove the entry at the tail * of the current routing table cache. * * Input Parameters: * None * * Returned Value: * On success, a pointer to the newly allocated routing table cache entry * is returned. Should never fail * * Assumptions: * Caller has the routing table cache locked. * ****************************************************************************/ #ifdef CONFIG_ROUTE_IPv4_CACHEROUTE FAR struct net_cache_ipv4_entry_s *net_alloccache_ipv4(void) { FAR struct net_cache_ipv4_entry_s *cache; /* Remove the first entry from the free list */ cache = g_free_ipv4cache.head; if (cache != NULL) { g_free_ipv4cache.head = cache->flink; if (g_free_ipv4cache.head == NULL) { g_free_ipv4cache.tail = NULL; } cache->flink = NULL; } /* If the free list is empty, then remove the oldest entry at the tail of * the routing table cache. */ else { /* If the free list is empty, then the cache list cannot be empty */ cache = net_remove_oldest_ipv4(); DEBUGASSERT(cache != NULL); } return cache; } #endif #ifdef CONFIG_ROUTE_IPv6_CACHEROUTE FAR struct net_cache_ipv6_entry_s *net_alloccache_ipv6(void) { FAR struct net_cache_ipv6_entry_s *cache; /* Remove the first entry from the free list */ cache = g_free_ipv6cache.head; if (cache != NULL) { g_free_ipv6cache.head = cache->flink; if (g_free_ipv6cache.head == NULL) { g_free_ipv6cache.tail = NULL; } cache->flink = NULL; } /* If the free list is empty, then remove the oldest entry at the tail of * the routing table cache. */ else { /* If the free list is empty, then the cache list cannot be empty */ cache = net_remove_oldest_ipv6(); DEBUGASSERT(cache != NULL); } return cache; } #endif /**************************************************************************** * Name: net_reset_ipv4_cache and net_reset_ipv6_cache * * Description: * Clear the routing table cache and return the entries to the free list. * * Input Parameters: * None * * Returned Value: * None * ****************************************************************************/ #ifdef CONFIG_ROUTE_IPv4_CACHEROUTE static void net_reset_ipv4_cache(void) { int i; cacheroute_init(&g_ipv4_cache); cacheroute_init(&g_free_ipv4cache); /* Add all of the pre-allocated routing table cache entries to a free list */ for (i = 0; i < CONFIG_ROUTE_MAX_IPv4_CACHEROUTES; i++) { net_add_newest_ipv4(&g_prealloc_ipv4cache[i]); } } #endif #ifdef CONFIG_ROUTE_IPv6_CACHEROUTE static void net_reset_ipv6_cache(void) { int i; cacheroute_init(&g_ipv6_cache); cacheroute_init(&g_free_ipv6cache); /* Add all of the pre-allocated routing table entries to a free list */ for (i = 0; i < CONFIG_ROUTE_MAX_IPv6_CACHEROUTES; i++) { net_add_newest_ipv6(&g_prealloc_ipv6cache[i]); } } #endif /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: net_init_cacheroute * * Description: * Initialize the in-memory, routing table cache * * Input Parameters: * None * * Returned Value: * None * * Assumptions: * Called early in initialization so that no special protection is needed. * ****************************************************************************/ void net_init_cacheroute(void) { /* Initialize the routing table cash and the free list */ #ifdef CONFIG_ROUTE_IPv4_CACHEROUTE nxsem_init(&g_ipv4_cachelock, 0, 1); net_reset_ipv4_cache(); #endif #ifdef CONFIG_ROUTE_IPv6_CACHEROUTE nxsem_init(&g_ipv6_cachelock, 0, 1); net_reset_ipv6_cache(); #endif } /**************************************************************************** * Name: net_addcache_ipv4 and net_addcache_ipv6 * * Description: * Add one route to the routing table cache * * Input Parameters: * None * * Returned Value: * Zero (OK) is returned on success; a negated errno value is returned * on any failure. * ****************************************************************************/ #ifdef CONFIG_ROUTE_IPv4_CACHEROUTE int net_addcache_ipv4(FAR struct net_route_ipv4_s *route) { FAR struct net_cache_ipv4_entry_s *cache; FAR struct net_cache_ipv4_entry_s *prev; int ret; DEBUGASSERT(route != NULL); /* Get exclusive access to the cache */ ret = net_lock_ipv4_cache(); if (ret < 0) { return ret; } /* First, check if the route already exists in the cache. * * Visit each entry in the cache */ for (prev = NULL, cache = g_ipv4_cache.head; cache != NULL; prev = cache, cache = cache->flink) { /* To match, the masked target addresses and netmasks must be the * same. */ if (net_ipv4addr_cmp(route->target, cache->entry.target) && net_ipv4addr_cmp(route->netmask, cache->entry.netmask)) { /* If the route already exists and is already at the head of the * list, then do nothing. It is already the most recently used. */ if (prev == NULL) { net_unlock_ipv4_cache(); return OK; } /* Otherwise, remove the cache entry from the middle or end of * the list. */ prev->flink = cache->flink; if (g_ipv4_cache.tail == cache) { g_ipv4_cache.tail = prev; } cache->flink = NULL; break; } } /* If we did not find the entry in the list, then we will have to * allocate a new entry. */ if (cache == NULL) { /* Allocate a new cache entry (should never fail) */ cache = net_alloccache_ipv4(); DEBUGASSERT(cache != NULL); /* Copy the routing table entry into the allocated cache entry. */ memcpy(&cache->entry, route, sizeof(struct net_route_ipv4_s)); } /* Then add the new cache entry as the newest entry in the table */ net_add_newest_ipv4(cache); net_unlock_ipv4_cache(); return OK; } #endif #ifdef CONFIG_ROUTE_IPv6_CACHEROUTE int net_addcache_ipv6(FAR struct net_route_ipv6_s *route) { FAR struct net_cache_ipv6_entry_s *cache; FAR struct net_cache_ipv6_entry_s *prev; int ret; DEBUGASSERT(route != NULL); /* Get exclusive access to the cache */ ret = net_lock_ipv6_cache(); if (ret < 0) { return ret; } /* First, check if the route already exists in the cache. * * Visit each entry in the cache. */ for (prev = NULL, cache = g_ipv6_cache.head; cache != NULL; prev = cache, cache = cache->flink) { /* To match, the masked target addresses and netmasks must be the * same. */ if (net_ipv6addr_cmp(route->target, cache->entry.target) && net_ipv6addr_cmp(route->netmask, cache->entry.netmask)) { /* If the route already exists and is already at the head of the * list, then do nothing. It is already the most recently used. */ if (prev == NULL) { net_unlock_ipv6_cache(); return OK; } /* Otherwise, remove the cache entry from the middle or end of * the list. */ prev->flink = cache->flink; if (g_ipv6_cache.tail == cache) { g_ipv6_cache.tail = prev; } cache->flink = NULL; break; } } /* If we did not find the entry in the list, then we will have to * allocate a new entry. */ if (cache == NULL) { /* Allocate a new cache entry (should never fail) */ cache = net_alloccache_ipv6(); DEBUGASSERT(cache != NULL); /* Copy the routing table entry into the allocated cache entry */ memcpy(&cache->entry, route, sizeof(struct net_route_ipv6_s)); } /* Then add the new cache entry as the newest entry in the table */ net_add_newest_ipv6(cache); net_unlock_ipv6_cache(); return OK; } #endif /**************************************************************************** * Name: net_foreachcache_ipv4/net_foreachcache_ipv6 * * Description: * Traverse the routing table cache * * Input Parameters: * handler - Will be called for each route in the routing table cache. * arg - An arbitrary value that will be passed tot he handler. * * Returned Value: * Zero (OK) returned if the entire table was searched. A negated errno * value will be returned in the event of a failure. Handlers may also * terminate the search early with any non-zero value. * ****************************************************************************/ #ifdef CONFIG_NET_IPv4 int net_foreachcache_ipv4(route_handler_ipv4_t handler, FAR void *arg) { FAR struct net_cache_ipv4_entry_s *cache; FAR struct net_cache_ipv4_entry_s *next; int ret = 0; /* Get exclusive access to the cache */ ret = net_lock_ipv4_cache(); if (ret < 0) { return ret; } /* Visit each entry in the routing table */ for (cache = g_ipv4_cache.head; ret == 0 && cache != NULL; cache = next) { /* Get the next entry in the to visit. We do this BEFORE calling the * handler because the handler may delete this entry. */ next = cache->flink; ret = handler(&cache->entry, arg); } /* Unlock the cache */ net_unlock_ipv4_cache(); return ret; } #endif #ifdef CONFIG_NET_IPv6 int net_foreachcache_ipv6(route_handler_ipv6_t handler, FAR void *arg) { FAR struct net_cache_ipv6_entry_s *cache; FAR struct net_cache_ipv6_entry_s *next; int ret = 0; /* Get exclusive access to the cache */ ret = net_lock_ipv6_cache(); if (ret < 0) { return ret; } /* Visit each entry in the routing table */ for (cache = g_ipv6_cache.head; ret == 0 && cache != NULL; cache = next) { /* Get the next entry in the to visit. We do this BEFORE calling the * handler because the handler may delete this entry. */ next = cache->flink; ret = handler(&cache->entry, arg); } /* Unlock the cache */ net_unlock_ipv6_cache(); return ret; } #endif /**************************************************************************** * Name: net_flushcache_ipv4 and net_flushcache_ipv6 * * Description: * Flush the content of the routing table cache * * Input Parameters: * None * * Returned Value: * None * ****************************************************************************/ #ifdef CONFIG_ROUTE_IPv4_CACHEROUTE void net_flushcache_ipv4(void) { int ret; /* Get exclusive access to the cache */ ret = net_lock_ipv4_cache(); if (ret >= 0) { /* Reset the cache */ net_reset_ipv4_cache(); /* Unlock the cache */ net_unlock_ipv4_cache(); } } #endif #ifdef CONFIG_ROUTE_IPv6_CACHEROUTE void net_flushcache_ipv6(void) { int ret; /* Get exclusive access to the cache */ ret = net_lock_ipv6_cache(); if (ret >= 0) { /* Reset the cache */ net_reset_ipv6_cache(); /* Unlock the cache */ net_unlock_ipv6_cache(); } } #endif #endif /* CONFIG_ROUTE_IPv4_CACHEROUTE || CONFIG_ROUTE_IPv6_CACHEROUTE */