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[/] [openrisc/] [trunk/] [rtos/] [freertos-6.1.1/] [Demo/] [Common/] [ethernet/] [lwIP_130/] [src/] [core/] [snmp/] [mib2.c] - Rev 606
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/** * @file * Management Information Base II (RFC1213) objects and functions. * * @note the object identifiers for this MIB-2 and private MIB tree * must be kept in sorted ascending order. This to ensure correct getnext operation. */ /* * Copyright (c) 2006 Axon Digital Design B.V., The Netherlands. * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * 3. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT * SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT * OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY * OF SUCH DAMAGE. * * Author: Christiaan Simons <christiaan.simons@axon.tv> */ #include "lwip/opt.h" #if LWIP_SNMP /* don't build if not configured for use in lwipopts.h */ #include "lwip/snmp.h" #include "lwip/netif.h" #include "lwip/ip.h" #include "lwip/ip_frag.h" #include "lwip/tcp.h" #include "lwip/udp.h" #include "lwip/snmp_asn1.h" #include "lwip/snmp_structs.h" #include "netif/etharp.h" /** * IANA assigned enterprise ID for lwIP is 26381 * @see http://www.iana.org/assignments/enterprise-numbers * * @note this enterprise ID is assigned to the lwIP project, * all object identifiers living under this ID are assigned * by the lwIP maintainers (contact Christiaan Simons)! * @note don't change this define, use snmp_set_sysobjid() * * If you need to create your own private MIB you'll need * to apply for your own enterprise ID with IANA: * http://www.iana.org/numbers.html */ #define SNMP_ENTERPRISE_ID 26381 #define SNMP_SYSOBJID_LEN 7 #define SNMP_SYSOBJID {1, 3, 6, 1, 4, 1, SNMP_ENTERPRISE_ID} #ifndef SNMP_SYSSERVICES #define SNMP_SYSSERVICES ((1 << 6) | (1 << 3) | ((IP_FORWARD) << 2)) #endif #ifndef SNMP_GET_SYSUPTIME #define SNMP_GET_SYSUPTIME(sysuptime) #endif static void system_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void system_get_value(struct obj_def *od, u16_t len, void *value); static u8_t system_set_test(struct obj_def *od, u16_t len, void *value); static void system_set_value(struct obj_def *od, u16_t len, void *value); static void interfaces_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void interfaces_get_value(struct obj_def *od, u16_t len, void *value); static void ifentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void ifentry_get_value(struct obj_def *od, u16_t len, void *value); #if !SNMP_SAFE_REQUESTS static u8_t ifentry_set_test (struct obj_def *od, u16_t len, void *value); static void ifentry_set_value (struct obj_def *od, u16_t len, void *value); #endif /* SNMP_SAFE_REQUESTS */ static void atentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void atentry_get_value(struct obj_def *od, u16_t len, void *value); static void ip_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void ip_get_value(struct obj_def *od, u16_t len, void *value); static u8_t ip_set_test(struct obj_def *od, u16_t len, void *value); static void ip_addrentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void ip_addrentry_get_value(struct obj_def *od, u16_t len, void *value); static void ip_rteentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void ip_rteentry_get_value(struct obj_def *od, u16_t len, void *value); static void ip_ntomentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void ip_ntomentry_get_value(struct obj_def *od, u16_t len, void *value); static void icmp_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void icmp_get_value(struct obj_def *od, u16_t len, void *value); #if LWIP_TCP static void tcp_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void tcp_get_value(struct obj_def *od, u16_t len, void *value); #ifdef THIS_SEEMS_UNUSED static void tcpconnentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void tcpconnentry_get_value(struct obj_def *od, u16_t len, void *value); #endif #endif static void udp_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void udp_get_value(struct obj_def *od, u16_t len, void *value); static void udpentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void udpentry_get_value(struct obj_def *od, u16_t len, void *value); static void snmp_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od); static void snmp_get_value(struct obj_def *od, u16_t len, void *value); static u8_t snmp_set_test(struct obj_def *od, u16_t len, void *value); static void snmp_set_value(struct obj_def *od, u16_t len, void *value); /* snmp .1.3.6.1.2.1.11 */ const mib_scalar_node snmp_scalar = { &snmp_get_object_def, &snmp_get_value, &snmp_set_test, &snmp_set_value, MIB_NODE_SC, 0 }; const s32_t snmp_ids[28] = { 1, 2, 3, 4, 5, 6, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 24, 25, 26, 27, 28, 29, 30 }; struct mib_node* const snmp_nodes[28] = { (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar, (struct mib_node* const)&snmp_scalar }; const struct mib_array_node snmp = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 28, snmp_ids, snmp_nodes }; /* dot3 and EtherLike MIB not planned. (transmission .1.3.6.1.2.1.10) */ /* historical (some say hysterical). (cmot .1.3.6.1.2.1.9) */ /* lwIP has no EGP, thus may not implement it. (egp .1.3.6.1.2.1.8) */ /* udp .1.3.6.1.2.1.7 */ /** index root node for udpTable */ struct mib_list_rootnode udp_root = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_LR, 0, NULL, NULL, 0 }; const s32_t udpentry_ids[2] = { 1, 2 }; struct mib_node* const udpentry_nodes[2] = { (struct mib_node* const)&udp_root, (struct mib_node* const)&udp_root, }; const struct mib_array_node udpentry = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 2, udpentry_ids, udpentry_nodes }; s32_t udptable_id = 1; struct mib_node* udptable_node = (struct mib_node* const)&udpentry; struct mib_ram_array_node udptable = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_RA, 0, &udptable_id, &udptable_node }; const mib_scalar_node udp_scalar = { &udp_get_object_def, &udp_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_SC, 0 }; const s32_t udp_ids[5] = { 1, 2, 3, 4, 5 }; struct mib_node* const udp_nodes[5] = { (struct mib_node* const)&udp_scalar, (struct mib_node* const)&udp_scalar, (struct mib_node* const)&udp_scalar, (struct mib_node* const)&udp_scalar, (struct mib_node* const)&udptable }; const struct mib_array_node udp = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 5, udp_ids, udp_nodes }; /* tcp .1.3.6.1.2.1.6 */ #if LWIP_TCP /* only if the TCP protocol is available may implement this group */ /** index root node for tcpConnTable */ struct mib_list_rootnode tcpconntree_root = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_LR, 0, NULL, NULL, 0 }; const s32_t tcpconnentry_ids[5] = { 1, 2, 3, 4, 5 }; struct mib_node* const tcpconnentry_nodes[5] = { (struct mib_node* const)&tcpconntree_root, (struct mib_node* const)&tcpconntree_root, (struct mib_node* const)&tcpconntree_root, (struct mib_node* const)&tcpconntree_root, (struct mib_node* const)&tcpconntree_root }; const struct mib_array_node tcpconnentry = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 5, tcpconnentry_ids, tcpconnentry_nodes }; s32_t tcpconntable_id = 1; struct mib_node* tcpconntable_node = (struct mib_node* const)&tcpconnentry; struct mib_ram_array_node tcpconntable = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_RA, /** @todo update maxlength when inserting / deleting from table 0 when table is empty, 1 when more than one entry */ 0, &tcpconntable_id, &tcpconntable_node }; const mib_scalar_node tcp_scalar = { &tcp_get_object_def, &tcp_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_SC, 0 }; const s32_t tcp_ids[15] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 }; struct mib_node* const tcp_nodes[15] = { (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcpconntable, (struct mib_node* const)&tcp_scalar, (struct mib_node* const)&tcp_scalar }; const struct mib_array_node tcp = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 15, tcp_ids, tcp_nodes }; #endif /* icmp .1.3.6.1.2.1.5 */ const mib_scalar_node icmp_scalar = { &icmp_get_object_def, &icmp_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_SC, 0 }; const s32_t icmp_ids[26] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26 }; struct mib_node* const icmp_nodes[26] = { (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar, (struct mib_node* const)&icmp_scalar }; const struct mib_array_node icmp = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 26, icmp_ids, icmp_nodes }; /** index root node for ipNetToMediaTable */ struct mib_list_rootnode ipntomtree_root = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_LR, 0, NULL, NULL, 0 }; const s32_t ipntomentry_ids[4] = { 1, 2, 3, 4 }; struct mib_node* const ipntomentry_nodes[4] = { (struct mib_node* const)&ipntomtree_root, (struct mib_node* const)&ipntomtree_root, (struct mib_node* const)&ipntomtree_root, (struct mib_node* const)&ipntomtree_root }; const struct mib_array_node ipntomentry = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 4, ipntomentry_ids, ipntomentry_nodes }; s32_t ipntomtable_id = 1; struct mib_node* ipntomtable_node = (struct mib_node* const)&ipntomentry; struct mib_ram_array_node ipntomtable = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_RA, 0, &ipntomtable_id, &ipntomtable_node }; /** index root node for ipRouteTable */ struct mib_list_rootnode iprtetree_root = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_LR, 0, NULL, NULL, 0 }; const s32_t iprteentry_ids[13] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13 }; struct mib_node* const iprteentry_nodes[13] = { (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root, (struct mib_node* const)&iprtetree_root }; const struct mib_array_node iprteentry = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 13, iprteentry_ids, iprteentry_nodes }; s32_t iprtetable_id = 1; struct mib_node* iprtetable_node = (struct mib_node* const)&iprteentry; struct mib_ram_array_node iprtetable = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_RA, 0, &iprtetable_id, &iprtetable_node }; /** index root node for ipAddrTable */ struct mib_list_rootnode ipaddrtree_root = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_LR, 0, NULL, NULL, 0 }; const s32_t ipaddrentry_ids[5] = { 1, 2, 3, 4, 5 }; struct mib_node* const ipaddrentry_nodes[5] = { (struct mib_node* const)&ipaddrtree_root, (struct mib_node* const)&ipaddrtree_root, (struct mib_node* const)&ipaddrtree_root, (struct mib_node* const)&ipaddrtree_root, (struct mib_node* const)&ipaddrtree_root }; const struct mib_array_node ipaddrentry = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 5, ipaddrentry_ids, ipaddrentry_nodes }; s32_t ipaddrtable_id = 1; struct mib_node* ipaddrtable_node = (struct mib_node* const)&ipaddrentry; struct mib_ram_array_node ipaddrtable = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_RA, 0, &ipaddrtable_id, &ipaddrtable_node }; /* ip .1.3.6.1.2.1.4 */ const mib_scalar_node ip_scalar = { &ip_get_object_def, &ip_get_value, &ip_set_test, &noleafs_set_value, MIB_NODE_SC, 0 }; const s32_t ip_ids[23] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23 }; struct mib_node* const ip_nodes[23] = { (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ip_scalar, (struct mib_node* const)&ipaddrtable, (struct mib_node* const)&iprtetable, (struct mib_node* const)&ipntomtable, (struct mib_node* const)&ip_scalar }; const struct mib_array_node mib2_ip = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 23, ip_ids, ip_nodes }; /** index root node for atTable */ struct mib_list_rootnode arptree_root = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_LR, 0, NULL, NULL, 0 }; const s32_t atentry_ids[3] = { 1, 2, 3 }; struct mib_node* const atentry_nodes[3] = { (struct mib_node* const)&arptree_root, (struct mib_node* const)&arptree_root, (struct mib_node* const)&arptree_root }; const struct mib_array_node atentry = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 3, atentry_ids, atentry_nodes }; const s32_t attable_id = 1; struct mib_node* const attable_node = (struct mib_node* const)&atentry; const struct mib_array_node attable = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 1, &attable_id, &attable_node }; /* at .1.3.6.1.2.1.3 */ s32_t at_id = 1; struct mib_node* mib2_at_node = (struct mib_node* const)&attable; struct mib_ram_array_node at = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_RA, 0, &at_id, &mib2_at_node }; /** index root node for ifTable */ struct mib_list_rootnode iflist_root = { &ifentry_get_object_def, &ifentry_get_value, #if SNMP_SAFE_REQUESTS &noleafs_set_test, &noleafs_set_value, #else /* SNMP_SAFE_REQUESTS */ &ifentry_set_test, &ifentry_set_value, #endif /* SNMP_SAFE_REQUESTS */ MIB_NODE_LR, 0, NULL, NULL, 0 }; const s32_t ifentry_ids[22] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22 }; struct mib_node* const ifentry_nodes[22] = { (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root, (struct mib_node* const)&iflist_root }; const struct mib_array_node ifentry = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 22, ifentry_ids, ifentry_nodes }; s32_t iftable_id = 1; struct mib_node* iftable_node = (struct mib_node* const)&ifentry; struct mib_ram_array_node iftable = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_RA, 0, &iftable_id, &iftable_node }; /* interfaces .1.3.6.1.2.1.2 */ const mib_scalar_node interfaces_scalar = { &interfaces_get_object_def, &interfaces_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_SC, 0 }; const s32_t interfaces_ids[2] = { 1, 2 }; struct mib_node* const interfaces_nodes[2] = { (struct mib_node* const)&interfaces_scalar, (struct mib_node* const)&iftable }; const struct mib_array_node interfaces = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 2, interfaces_ids, interfaces_nodes }; /* 0 1 2 3 4 5 6 */ /* system .1.3.6.1.2.1.1 */ const mib_scalar_node sys_tem_scalar = { &system_get_object_def, &system_get_value, &system_set_test, &system_set_value, MIB_NODE_SC, 0 }; const s32_t sys_tem_ids[7] = { 1, 2, 3, 4, 5, 6, 7 }; struct mib_node* const sys_tem_nodes[7] = { (struct mib_node* const)&sys_tem_scalar, (struct mib_node* const)&sys_tem_scalar, (struct mib_node* const)&sys_tem_scalar, (struct mib_node* const)&sys_tem_scalar, (struct mib_node* const)&sys_tem_scalar, (struct mib_node* const)&sys_tem_scalar, (struct mib_node* const)&sys_tem_scalar }; /* work around name issue with 'sys_tem', some compiler(s?) seem to reserve 'system' */ const struct mib_array_node sys_tem = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 7, sys_tem_ids, sys_tem_nodes }; /* mib-2 .1.3.6.1.2.1 */ #if LWIP_TCP #define MIB2_GROUPS 8 #else #define MIB2_GROUPS 7 #endif const s32_t mib2_ids[MIB2_GROUPS] = { 1, 2, 3, 4, 5, #if LWIP_TCP 6, #endif 7, 11 }; struct mib_node* const mib2_nodes[MIB2_GROUPS] = { (struct mib_node* const)&sys_tem, (struct mib_node* const)&interfaces, (struct mib_node* const)&at, (struct mib_node* const)&mib2_ip, (struct mib_node* const)&icmp, #if LWIP_TCP (struct mib_node* const)&tcp, #endif (struct mib_node* const)&udp, (struct mib_node* const)&snmp }; const struct mib_array_node mib2 = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, MIB2_GROUPS, mib2_ids, mib2_nodes }; /* mgmt .1.3.6.1.2 */ const s32_t mgmt_ids[1] = { 1 }; struct mib_node* const mgmt_nodes[1] = { (struct mib_node* const)&mib2 }; const struct mib_array_node mgmt = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 1, mgmt_ids, mgmt_nodes }; /* internet .1.3.6.1 */ #if SNMP_PRIVATE_MIB s32_t internet_ids[2] = { 2, 4 }; struct mib_node* const internet_nodes[2] = { (struct mib_node* const)&mgmt, (struct mib_node* const)&private }; const struct mib_array_node internet = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 2, internet_ids, internet_nodes }; #else const s32_t internet_ids[1] = { 2 }; struct mib_node* const internet_nodes[1] = { (struct mib_node* const)&mgmt }; const struct mib_array_node internet = { &noleafs_get_object_def, &noleafs_get_value, &noleafs_set_test, &noleafs_set_value, MIB_NODE_AR, 1, internet_ids, internet_nodes }; #endif /** mib-2.system.sysObjectID */ static struct snmp_obj_id sysobjid = {SNMP_SYSOBJID_LEN, SNMP_SYSOBJID}; /** enterprise ID for generic TRAPs, .iso.org.dod.internet.mgmt.mib-2.snmp */ static struct snmp_obj_id snmpgrp_id = {7,{1,3,6,1,2,1,11}}; /** mib-2.system.sysServices */ static const s32_t sysservices = SNMP_SYSSERVICES; /** mib-2.system.sysDescr */ static const u8_t sysdescr_len_default = 4; static const u8_t sysdescr_default[] = "lwIP"; static u8_t* sysdescr_len_ptr = (u8_t*)&sysdescr_len_default; static u8_t* sysdescr_ptr = (u8_t*)&sysdescr_default[0]; /** mib-2.system.sysContact */ static const u8_t syscontact_len_default = 0; static const u8_t syscontact_default[] = ""; static u8_t* syscontact_len_ptr = (u8_t*)&syscontact_len_default; static u8_t* syscontact_ptr = (u8_t*)&syscontact_default[0]; /** mib-2.system.sysName */ static const u8_t sysname_len_default = 8; static const u8_t sysname_default[] = "FQDN-unk"; static u8_t* sysname_len_ptr = (u8_t*)&sysname_len_default; static u8_t* sysname_ptr = (u8_t*)&sysname_default[0]; /** mib-2.system.sysLocation */ static const u8_t syslocation_len_default = 0; static const u8_t syslocation_default[] = ""; static u8_t* syslocation_len_ptr = (u8_t*)&syslocation_len_default; static u8_t* syslocation_ptr = (u8_t*)&syslocation_default[0]; /** mib-2.snmp.snmpEnableAuthenTraps */ static const u8_t snmpenableauthentraps_default = 2; /* disabled */ static u8_t* snmpenableauthentraps_ptr = (u8_t*)&snmpenableauthentraps_default; /** mib-2.interfaces.ifTable.ifEntry.ifSpecific (zeroDotZero) */ static const struct snmp_obj_id ifspecific = {2, {0, 0}}; /** mib-2.ip.ipRouteTable.ipRouteEntry.ipRouteInfo (zeroDotZero) */ static const struct snmp_obj_id iprouteinfo = {2, {0, 0}}; /* mib-2.system counter(s) */ static u32_t sysuptime = 0; /* mib-2.ip counter(s) */ static u32_t ipinreceives = 0, ipinhdrerrors = 0, ipinaddrerrors = 0, ipforwdatagrams = 0, ipinunknownprotos = 0, ipindiscards = 0, ipindelivers = 0, ipoutrequests = 0, ipoutdiscards = 0, ipoutnoroutes = 0, ipreasmreqds = 0, ipreasmoks = 0, ipreasmfails = 0, ipfragoks = 0, ipfragfails = 0, ipfragcreates = 0, iproutingdiscards = 0; /* mib-2.icmp counter(s) */ static u32_t icmpinmsgs = 0, icmpinerrors = 0, icmpindestunreachs = 0, icmpintimeexcds = 0, icmpinparmprobs = 0, icmpinsrcquenchs = 0, icmpinredirects = 0, icmpinechos = 0, icmpinechoreps = 0, icmpintimestamps = 0, icmpintimestampreps = 0, icmpinaddrmasks = 0, icmpinaddrmaskreps = 0, icmpoutmsgs = 0, icmpouterrors = 0, icmpoutdestunreachs = 0, icmpouttimeexcds = 0, icmpoutparmprobs = 0, icmpoutsrcquenchs = 0, icmpoutredirects = 0, icmpoutechos = 0, icmpoutechoreps = 0, icmpouttimestamps = 0, icmpouttimestampreps = 0, icmpoutaddrmasks = 0, icmpoutaddrmaskreps = 0; /* mib-2.tcp counter(s) */ static u32_t tcpactiveopens = 0, tcppassiveopens = 0, tcpattemptfails = 0, tcpestabresets = 0, tcpinsegs = 0, tcpoutsegs = 0, tcpretranssegs = 0, tcpinerrs = 0, tcpoutrsts = 0; /* mib-2.udp counter(s) */ static u32_t udpindatagrams = 0, udpnoports = 0, udpinerrors = 0, udpoutdatagrams = 0; /* mib-2.snmp counter(s) */ static u32_t snmpinpkts = 0, snmpoutpkts = 0, snmpinbadversions = 0, snmpinbadcommunitynames = 0, snmpinbadcommunityuses = 0, snmpinasnparseerrs = 0, snmpintoobigs = 0, snmpinnosuchnames = 0, snmpinbadvalues = 0, snmpinreadonlys = 0, snmpingenerrs = 0, snmpintotalreqvars = 0, snmpintotalsetvars = 0, snmpingetrequests = 0, snmpingetnexts = 0, snmpinsetrequests = 0, snmpingetresponses = 0, snmpintraps = 0, snmpouttoobigs = 0, snmpoutnosuchnames = 0, snmpoutbadvalues = 0, snmpoutgenerrs = 0, snmpoutgetrequests = 0, snmpoutgetnexts = 0, snmpoutsetrequests = 0, snmpoutgetresponses = 0, snmpouttraps = 0; /* prototypes of the following functions are in lwip/src/include/lwip/snmp.h */ /** * Copy octet string. * * @param dst points to destination * @param src points to source * @param n number of octets to copy. */ void ocstrncpy(u8_t *dst, u8_t *src, u8_t n) { while (n > 0) { n--; *dst++ = *src++; } } /** * Copy object identifier (s32_t) array. * * @param dst points to destination * @param src points to source * @param n number of sub identifiers to copy. */ void objectidncpy(s32_t *dst, s32_t *src, u8_t n) { while(n > 0) { n--; *dst++ = *src++; } } /** * Initializes sysDescr pointers. * * @param str if non-NULL then copy str pointer * @param len points to string length, excluding zero terminator */ void snmp_set_sysdesr(u8_t *str, u8_t *len) { if (str != NULL) { sysdescr_ptr = str; sysdescr_len_ptr = len; } } void snmp_get_sysobjid_ptr(struct snmp_obj_id **oid) { *oid = &sysobjid; } /** * Initializes sysObjectID value. * * @param oid points to stuct snmp_obj_id to copy */ void snmp_set_sysobjid(struct snmp_obj_id *oid) { sysobjid = *oid; } /** * Must be called at regular 10 msec interval from a timer interrupt * or signal handler depending on your runtime environment. */ void snmp_inc_sysuptime(void) { sysuptime++; } void snmp_add_sysuptime(u32_t value) { sysuptime+=value; } void snmp_get_sysuptime(u32_t *value) { SNMP_GET_SYSUPTIME(sysuptime); *value = sysuptime; } /** * Initializes sysContact pointers, * e.g. ptrs to non-volatile memory external to lwIP. * * @param ocstr if non-NULL then copy str pointer * @param ocstrlen points to string length, excluding zero terminator */ void snmp_set_syscontact(u8_t *ocstr, u8_t *ocstrlen) { if (ocstr != NULL) { syscontact_ptr = ocstr; syscontact_len_ptr = ocstrlen; } } /** * Initializes sysName pointers, * e.g. ptrs to non-volatile memory external to lwIP. * * @param ocstr if non-NULL then copy str pointer * @param ocstrlen points to string length, excluding zero terminator */ void snmp_set_sysname(u8_t *ocstr, u8_t *ocstrlen) { if (ocstr != NULL) { sysname_ptr = ocstr; sysname_len_ptr = ocstrlen; } } /** * Initializes sysLocation pointers, * e.g. ptrs to non-volatile memory external to lwIP. * * @param ocstr if non-NULL then copy str pointer * @param ocstrlen points to string length, excluding zero terminator */ void snmp_set_syslocation(u8_t *ocstr, u8_t *ocstrlen) { if (ocstr != NULL) { syslocation_ptr = ocstr; syslocation_len_ptr = ocstrlen; } } void snmp_add_ifinoctets(struct netif *ni, u32_t value) { ni->ifinoctets += value; } void snmp_inc_ifinucastpkts(struct netif *ni) { (ni->ifinucastpkts)++; } void snmp_inc_ifinnucastpkts(struct netif *ni) { (ni->ifinnucastpkts)++; } void snmp_inc_ifindiscards(struct netif *ni) { (ni->ifindiscards)++; } void snmp_add_ifoutoctets(struct netif *ni, u32_t value) { ni->ifoutoctets += value; } void snmp_inc_ifoutucastpkts(struct netif *ni) { (ni->ifoutucastpkts)++; } void snmp_inc_ifoutnucastpkts(struct netif *ni) { (ni->ifoutnucastpkts)++; } void snmp_inc_ifoutdiscards(struct netif *ni) { (ni->ifoutdiscards)++; } void snmp_inc_iflist(void) { struct mib_list_node *if_node = NULL; snmp_mib_node_insert(&iflist_root, iflist_root.count + 1, &if_node); /* enable getnext traversal on filled table */ iftable.maxlength = 1; } void snmp_dec_iflist(void) { snmp_mib_node_delete(&iflist_root, iflist_root.tail); /* disable getnext traversal on empty table */ if(iflist_root.count == 0) iftable.maxlength = 0; } /** * Inserts ARP table indexes (.xIfIndex.xNetAddress) * into arp table index trees (both atTable and ipNetToMediaTable). */ void snmp_insert_arpidx_tree(struct netif *ni, struct ip_addr *ip) { struct mib_list_rootnode *at_rn; struct mib_list_node *at_node; struct ip_addr hip; s32_t arpidx[5]; u8_t level, tree; LWIP_ASSERT("ni != NULL", ni != NULL); snmp_netiftoifindex(ni, &arpidx[0]); hip.addr = ntohl(ip->addr); snmp_iptooid(&hip, &arpidx[1]); for (tree = 0; tree < 2; tree++) { if (tree == 0) { at_rn = &arptree_root; } else { at_rn = &ipntomtree_root; } for (level = 0; level < 5; level++) { at_node = NULL; snmp_mib_node_insert(at_rn, arpidx[level], &at_node); if ((level != 4) && (at_node != NULL)) { if (at_node->nptr == NULL) { at_rn = snmp_mib_lrn_alloc(); at_node->nptr = (struct mib_node*)at_rn; if (at_rn != NULL) { if (level == 3) { if (tree == 0) { at_rn->get_object_def = atentry_get_object_def; at_rn->get_value = atentry_get_value; } else { at_rn->get_object_def = ip_ntomentry_get_object_def; at_rn->get_value = ip_ntomentry_get_value; } at_rn->set_test = noleafs_set_test; at_rn->set_value = noleafs_set_value; } } else { /* at_rn == NULL, malloc failure */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("snmp_insert_arpidx_tree() insert failed, mem full")); break; } } else { at_rn = (struct mib_list_rootnode*)at_node->nptr; } } } } /* enable getnext traversal on filled tables */ at.maxlength = 1; ipntomtable.maxlength = 1; } /** * Removes ARP table indexes (.xIfIndex.xNetAddress) * from arp table index trees. */ void snmp_delete_arpidx_tree(struct netif *ni, struct ip_addr *ip) { struct mib_list_rootnode *at_rn, *next, *del_rn[5]; struct mib_list_node *at_n, *del_n[5]; struct ip_addr hip; s32_t arpidx[5]; u8_t fc, tree, level, del_cnt; snmp_netiftoifindex(ni, &arpidx[0]); hip.addr = ntohl(ip->addr); snmp_iptooid(&hip, &arpidx[1]); for (tree = 0; tree < 2; tree++) { /* mark nodes for deletion */ if (tree == 0) { at_rn = &arptree_root; } else { at_rn = &ipntomtree_root; } level = 0; del_cnt = 0; while ((level < 5) && (at_rn != NULL)) { fc = snmp_mib_node_find(at_rn, arpidx[level], &at_n); if (fc == 0) { /* arpidx[level] does not exist */ del_cnt = 0; at_rn = NULL; } else if (fc == 1) { del_rn[del_cnt] = at_rn; del_n[del_cnt] = at_n; del_cnt++; at_rn = (struct mib_list_rootnode*)(at_n->nptr); } else if (fc == 2) { /* reset delete (2 or more childs) */ del_cnt = 0; at_rn = (struct mib_list_rootnode*)(at_n->nptr); } level++; } /* delete marked index nodes */ while (del_cnt > 0) { del_cnt--; at_rn = del_rn[del_cnt]; at_n = del_n[del_cnt]; next = snmp_mib_node_delete(at_rn, at_n); if (next != NULL) { LWIP_ASSERT("next_count == 0",next->count == 0); snmp_mib_lrn_free(next); } } } /* disable getnext traversal on empty tables */ if(arptree_root.count == 0) at.maxlength = 0; if(ipntomtree_root.count == 0) ipntomtable.maxlength = 0; } void snmp_inc_ipinreceives(void) { ipinreceives++; } void snmp_inc_ipinhdrerrors(void) { ipinhdrerrors++; } void snmp_inc_ipinaddrerrors(void) { ipinaddrerrors++; } void snmp_inc_ipforwdatagrams(void) { ipforwdatagrams++; } void snmp_inc_ipinunknownprotos(void) { ipinunknownprotos++; } void snmp_inc_ipindiscards(void) { ipindiscards++; } void snmp_inc_ipindelivers(void) { ipindelivers++; } void snmp_inc_ipoutrequests(void) { ipoutrequests++; } void snmp_inc_ipoutdiscards(void) { ipoutdiscards++; } void snmp_inc_ipoutnoroutes(void) { ipoutnoroutes++; } void snmp_inc_ipreasmreqds(void) { ipreasmreqds++; } void snmp_inc_ipreasmoks(void) { ipreasmoks++; } void snmp_inc_ipreasmfails(void) { ipreasmfails++; } void snmp_inc_ipfragoks(void) { ipfragoks++; } void snmp_inc_ipfragfails(void) { ipfragfails++; } void snmp_inc_ipfragcreates(void) { ipfragcreates++; } void snmp_inc_iproutingdiscards(void) { iproutingdiscards++; } /** * Inserts ipAddrTable indexes (.ipAdEntAddr) * into index tree. */ void snmp_insert_ipaddridx_tree(struct netif *ni) { struct mib_list_rootnode *ipa_rn; struct mib_list_node *ipa_node; struct ip_addr ip; s32_t ipaddridx[4]; u8_t level; LWIP_ASSERT("ni != NULL", ni != NULL); ip.addr = ntohl(ni->ip_addr.addr); snmp_iptooid(&ip, &ipaddridx[0]); level = 0; ipa_rn = &ipaddrtree_root; while (level < 4) { ipa_node = NULL; snmp_mib_node_insert(ipa_rn, ipaddridx[level], &ipa_node); if ((level != 3) && (ipa_node != NULL)) { if (ipa_node->nptr == NULL) { ipa_rn = snmp_mib_lrn_alloc(); ipa_node->nptr = (struct mib_node*)ipa_rn; if (ipa_rn != NULL) { if (level == 2) { ipa_rn->get_object_def = ip_addrentry_get_object_def; ipa_rn->get_value = ip_addrentry_get_value; ipa_rn->set_test = noleafs_set_test; ipa_rn->set_value = noleafs_set_value; } } else { /* ipa_rn == NULL, malloc failure */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("snmp_insert_ipaddridx_tree() insert failed, mem full")); break; } } else { ipa_rn = (struct mib_list_rootnode*)ipa_node->nptr; } } level++; } /* enable getnext traversal on filled table */ ipaddrtable.maxlength = 1; } /** * Removes ipAddrTable indexes (.ipAdEntAddr) * from index tree. */ void snmp_delete_ipaddridx_tree(struct netif *ni) { struct mib_list_rootnode *ipa_rn, *next, *del_rn[4]; struct mib_list_node *ipa_n, *del_n[4]; struct ip_addr ip; s32_t ipaddridx[4]; u8_t fc, level, del_cnt; LWIP_ASSERT("ni != NULL", ni != NULL); ip.addr = ntohl(ni->ip_addr.addr); snmp_iptooid(&ip, &ipaddridx[0]); /* mark nodes for deletion */ level = 0; del_cnt = 0; ipa_rn = &ipaddrtree_root; while ((level < 4) && (ipa_rn != NULL)) { fc = snmp_mib_node_find(ipa_rn, ipaddridx[level], &ipa_n); if (fc == 0) { /* ipaddridx[level] does not exist */ del_cnt = 0; ipa_rn = NULL; } else if (fc == 1) { del_rn[del_cnt] = ipa_rn; del_n[del_cnt] = ipa_n; del_cnt++; ipa_rn = (struct mib_list_rootnode*)(ipa_n->nptr); } else if (fc == 2) { /* reset delete (2 or more childs) */ del_cnt = 0; ipa_rn = (struct mib_list_rootnode*)(ipa_n->nptr); } level++; } /* delete marked index nodes */ while (del_cnt > 0) { del_cnt--; ipa_rn = del_rn[del_cnt]; ipa_n = del_n[del_cnt]; next = snmp_mib_node_delete(ipa_rn, ipa_n); if (next != NULL) { LWIP_ASSERT("next_count == 0",next->count == 0); snmp_mib_lrn_free(next); } } /* disable getnext traversal on empty table */ if (ipaddrtree_root.count == 0) ipaddrtable.maxlength = 0; } /** * Inserts ipRouteTable indexes (.ipRouteDest) * into index tree. * * @param dflt non-zero for the default rte, zero for network rte * @param ni points to network interface for this rte * * @todo record sysuptime for _this_ route when it is installed * (needed for ipRouteAge) in the netif. */ void snmp_insert_iprteidx_tree(u8_t dflt, struct netif *ni) { u8_t insert = 0; struct ip_addr dst; if (dflt != 0) { /* the default route 0.0.0.0 */ dst.addr = 0; insert = 1; } else { /* route to the network address */ dst.addr = ntohl(ni->ip_addr.addr & ni->netmask.addr); /* exclude 0.0.0.0 network (reserved for default rte) */ if (dst.addr != 0) insert = 1; } if (insert) { struct mib_list_rootnode *iprte_rn; struct mib_list_node *iprte_node; s32_t iprteidx[4]; u8_t level; snmp_iptooid(&dst, &iprteidx[0]); level = 0; iprte_rn = &iprtetree_root; while (level < 4) { iprte_node = NULL; snmp_mib_node_insert(iprte_rn, iprteidx[level], &iprte_node); if ((level != 3) && (iprte_node != NULL)) { if (iprte_node->nptr == NULL) { iprte_rn = snmp_mib_lrn_alloc(); iprte_node->nptr = (struct mib_node*)iprte_rn; if (iprte_rn != NULL) { if (level == 2) { iprte_rn->get_object_def = ip_rteentry_get_object_def; iprte_rn->get_value = ip_rteentry_get_value; iprte_rn->set_test = noleafs_set_test; iprte_rn->set_value = noleafs_set_value; } } else { /* iprte_rn == NULL, malloc failure */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("snmp_insert_iprteidx_tree() insert failed, mem full")); break; } } else { iprte_rn = (struct mib_list_rootnode*)iprte_node->nptr; } } level++; } } /* enable getnext traversal on filled table */ iprtetable.maxlength = 1; } /** * Removes ipRouteTable indexes (.ipRouteDest) * from index tree. * * @param dflt non-zero for the default rte, zero for network rte * @param ni points to network interface for this rte or NULL * for default route to be removed. */ void snmp_delete_iprteidx_tree(u8_t dflt, struct netif *ni) { u8_t delete = 0; struct ip_addr dst; if (dflt != 0) { /* the default route 0.0.0.0 */ dst.addr = 0; delete = 1; } else { /* route to the network address */ dst.addr = ntohl(ni->ip_addr.addr & ni->netmask.addr); /* exclude 0.0.0.0 network (reserved for default rte) */ if (dst.addr != 0) delete = 1; } if (delete) { struct mib_list_rootnode *iprte_rn, *next, *del_rn[4]; struct mib_list_node *iprte_n, *del_n[4]; s32_t iprteidx[4]; u8_t fc, level, del_cnt; snmp_iptooid(&dst, &iprteidx[0]); /* mark nodes for deletion */ level = 0; del_cnt = 0; iprte_rn = &iprtetree_root; while ((level < 4) && (iprte_rn != NULL)) { fc = snmp_mib_node_find(iprte_rn, iprteidx[level], &iprte_n); if (fc == 0) { /* iprteidx[level] does not exist */ del_cnt = 0; iprte_rn = NULL; } else if (fc == 1) { del_rn[del_cnt] = iprte_rn; del_n[del_cnt] = iprte_n; del_cnt++; iprte_rn = (struct mib_list_rootnode*)(iprte_n->nptr); } else if (fc == 2) { /* reset delete (2 or more childs) */ del_cnt = 0; iprte_rn = (struct mib_list_rootnode*)(iprte_n->nptr); } level++; } /* delete marked index nodes */ while (del_cnt > 0) { del_cnt--; iprte_rn = del_rn[del_cnt]; iprte_n = del_n[del_cnt]; next = snmp_mib_node_delete(iprte_rn, iprte_n); if (next != NULL) { LWIP_ASSERT("next_count == 0",next->count == 0); snmp_mib_lrn_free(next); } } } /* disable getnext traversal on empty table */ if (iprtetree_root.count == 0) iprtetable.maxlength = 0; } void snmp_inc_icmpinmsgs(void) { icmpinmsgs++; } void snmp_inc_icmpinerrors(void) { icmpinerrors++; } void snmp_inc_icmpindestunreachs(void) { icmpindestunreachs++; } void snmp_inc_icmpintimeexcds(void) { icmpintimeexcds++; } void snmp_inc_icmpinparmprobs(void) { icmpinparmprobs++; } void snmp_inc_icmpinsrcquenchs(void) { icmpinsrcquenchs++; } void snmp_inc_icmpinredirects(void) { icmpinredirects++; } void snmp_inc_icmpinechos(void) { icmpinechos++; } void snmp_inc_icmpinechoreps(void) { icmpinechoreps++; } void snmp_inc_icmpintimestamps(void) { icmpintimestamps++; } void snmp_inc_icmpintimestampreps(void) { icmpintimestampreps++; } void snmp_inc_icmpinaddrmasks(void) { icmpinaddrmasks++; } void snmp_inc_icmpinaddrmaskreps(void) { icmpinaddrmaskreps++; } void snmp_inc_icmpoutmsgs(void) { icmpoutmsgs++; } void snmp_inc_icmpouterrors(void) { icmpouterrors++; } void snmp_inc_icmpoutdestunreachs(void) { icmpoutdestunreachs++; } void snmp_inc_icmpouttimeexcds(void) { icmpouttimeexcds++; } void snmp_inc_icmpoutparmprobs(void) { icmpoutparmprobs++; } void snmp_inc_icmpoutsrcquenchs(void) { icmpoutsrcquenchs++; } void snmp_inc_icmpoutredirects(void) { icmpoutredirects++; } void snmp_inc_icmpoutechos(void) { icmpoutechos++; } void snmp_inc_icmpoutechoreps(void) { icmpoutechoreps++; } void snmp_inc_icmpouttimestamps(void) { icmpouttimestamps++; } void snmp_inc_icmpouttimestampreps(void) { icmpouttimestampreps++; } void snmp_inc_icmpoutaddrmasks(void) { icmpoutaddrmasks++; } void snmp_inc_icmpoutaddrmaskreps(void) { icmpoutaddrmaskreps++; } void snmp_inc_tcpactiveopens(void) { tcpactiveopens++; } void snmp_inc_tcppassiveopens(void) { tcppassiveopens++; } void snmp_inc_tcpattemptfails(void) { tcpattemptfails++; } void snmp_inc_tcpestabresets(void) { tcpestabresets++; } void snmp_inc_tcpinsegs(void) { tcpinsegs++; } void snmp_inc_tcpoutsegs(void) { tcpoutsegs++; } void snmp_inc_tcpretranssegs(void) { tcpretranssegs++; } void snmp_inc_tcpinerrs(void) { tcpinerrs++; } void snmp_inc_tcpoutrsts(void) { tcpoutrsts++; } void snmp_inc_udpindatagrams(void) { udpindatagrams++; } void snmp_inc_udpnoports(void) { udpnoports++; } void snmp_inc_udpinerrors(void) { udpinerrors++; } void snmp_inc_udpoutdatagrams(void) { udpoutdatagrams++; } /** * Inserts udpTable indexes (.udpLocalAddress.udpLocalPort) * into index tree. */ void snmp_insert_udpidx_tree(struct udp_pcb *pcb) { struct mib_list_rootnode *udp_rn; struct mib_list_node *udp_node; struct ip_addr ip; s32_t udpidx[5]; u8_t level; LWIP_ASSERT("pcb != NULL", pcb != NULL); ip.addr = ntohl(pcb->local_ip.addr); snmp_iptooid(&ip, &udpidx[0]); udpidx[4] = pcb->local_port; udp_rn = &udp_root; for (level = 0; level < 5; level++) { udp_node = NULL; snmp_mib_node_insert(udp_rn, udpidx[level], &udp_node); if ((level != 4) && (udp_node != NULL)) { if (udp_node->nptr == NULL) { udp_rn = snmp_mib_lrn_alloc(); udp_node->nptr = (struct mib_node*)udp_rn; if (udp_rn != NULL) { if (level == 3) { udp_rn->get_object_def = udpentry_get_object_def; udp_rn->get_value = udpentry_get_value; udp_rn->set_test = noleafs_set_test; udp_rn->set_value = noleafs_set_value; } } else { /* udp_rn == NULL, malloc failure */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("snmp_insert_udpidx_tree() insert failed, mem full")); break; } } else { udp_rn = (struct mib_list_rootnode*)udp_node->nptr; } } } udptable.maxlength = 1; } /** * Removes udpTable indexes (.udpLocalAddress.udpLocalPort) * from index tree. */ void snmp_delete_udpidx_tree(struct udp_pcb *pcb) { struct mib_list_rootnode *udp_rn, *next, *del_rn[5]; struct mib_list_node *udp_n, *del_n[5]; struct ip_addr ip; s32_t udpidx[5]; u8_t bindings, fc, level, del_cnt; LWIP_ASSERT("pcb != NULL", pcb != NULL); ip.addr = ntohl(pcb->local_ip.addr); snmp_iptooid(&ip, &udpidx[0]); udpidx[4] = pcb->local_port; /* count PCBs for a given binding (e.g. when reusing ports or for temp output PCBs) */ bindings = 0; pcb = udp_pcbs; while ((pcb != NULL)) { if ((pcb->local_ip.addr == ip.addr) && (pcb->local_port == udpidx[4])) { bindings++; } pcb = pcb->next; } if (bindings == 1) { /* selectively remove */ /* mark nodes for deletion */ level = 0; del_cnt = 0; udp_rn = &udp_root; while ((level < 5) && (udp_rn != NULL)) { fc = snmp_mib_node_find(udp_rn, udpidx[level], &udp_n); if (fc == 0) { /* udpidx[level] does not exist */ del_cnt = 0; udp_rn = NULL; } else if (fc == 1) { del_rn[del_cnt] = udp_rn; del_n[del_cnt] = udp_n; del_cnt++; udp_rn = (struct mib_list_rootnode*)(udp_n->nptr); } else if (fc == 2) { /* reset delete (2 or more childs) */ del_cnt = 0; udp_rn = (struct mib_list_rootnode*)(udp_n->nptr); } level++; } /* delete marked index nodes */ while (del_cnt > 0) { del_cnt--; udp_rn = del_rn[del_cnt]; udp_n = del_n[del_cnt]; next = snmp_mib_node_delete(udp_rn, udp_n); if (next != NULL) { LWIP_ASSERT("next_count == 0",next->count == 0); snmp_mib_lrn_free(next); } } } /* disable getnext traversal on empty table */ if (udp_root.count == 0) udptable.maxlength = 0; } void snmp_inc_snmpinpkts(void) { snmpinpkts++; } void snmp_inc_snmpoutpkts(void) { snmpoutpkts++; } void snmp_inc_snmpinbadversions(void) { snmpinbadversions++; } void snmp_inc_snmpinbadcommunitynames(void) { snmpinbadcommunitynames++; } void snmp_inc_snmpinbadcommunityuses(void) { snmpinbadcommunityuses++; } void snmp_inc_snmpinasnparseerrs(void) { snmpinasnparseerrs++; } void snmp_inc_snmpintoobigs(void) { snmpintoobigs++; } void snmp_inc_snmpinnosuchnames(void) { snmpinnosuchnames++; } void snmp_inc_snmpinbadvalues(void) { snmpinbadvalues++; } void snmp_inc_snmpinreadonlys(void) { snmpinreadonlys++; } void snmp_inc_snmpingenerrs(void) { snmpingenerrs++; } void snmp_add_snmpintotalreqvars(u8_t value) { snmpintotalreqvars += value; } void snmp_add_snmpintotalsetvars(u8_t value) { snmpintotalsetvars += value; } void snmp_inc_snmpingetrequests(void) { snmpingetrequests++; } void snmp_inc_snmpingetnexts(void) { snmpingetnexts++; } void snmp_inc_snmpinsetrequests(void) { snmpinsetrequests++; } void snmp_inc_snmpingetresponses(void) { snmpingetresponses++; } void snmp_inc_snmpintraps(void) { snmpintraps++; } void snmp_inc_snmpouttoobigs(void) { snmpouttoobigs++; } void snmp_inc_snmpoutnosuchnames(void) { snmpoutnosuchnames++; } void snmp_inc_snmpoutbadvalues(void) { snmpoutbadvalues++; } void snmp_inc_snmpoutgenerrs(void) { snmpoutgenerrs++; } void snmp_inc_snmpoutgetrequests(void) { snmpoutgetrequests++; } void snmp_inc_snmpoutgetnexts(void) { snmpoutgetnexts++; } void snmp_inc_snmpoutsetrequests(void) { snmpoutsetrequests++; } void snmp_inc_snmpoutgetresponses(void) { snmpoutgetresponses++; } void snmp_inc_snmpouttraps(void) { snmpouttraps++; } void snmp_get_snmpgrpid_ptr(struct snmp_obj_id **oid) { *oid = &snmpgrp_id; } void snmp_set_snmpenableauthentraps(u8_t *value) { if (value != NULL) { snmpenableauthentraps_ptr = value; } } void snmp_get_snmpenableauthentraps(u8_t *value) { *value = *snmpenableauthentraps_ptr; } void noleafs_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { if (ident_len){} if (ident){} od->instance = MIB_OBJECT_NONE; } void noleafs_get_value(struct obj_def *od, u16_t len, void *value) { if (od){} if (len){} if (value){} } u8_t noleafs_set_test(struct obj_def *od, u16_t len, void *value) { if (od){} if (len){} if (value){} /* can't set */ return 0; } void noleafs_set_value(struct obj_def *od, u16_t len, void *value) { if (od){} if (len){} if (value){} } /** * Returns systems object definitions. * * @param ident_len the address length (2) * @param ident points to objectname.0 (object id trailer) * @param od points to object definition. */ static void system_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { u8_t id; /* return to object name, adding index depth (1) */ ident_len += 1; ident -= 1; if (ident_len == 2) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; id = ident[0]; LWIP_DEBUGF(SNMP_MIB_DEBUG,("get_object_def system.%"U16_F".0\n",(u16_t)id)); switch (id) { case 1: /* sysDescr */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OC_STR); od->v_len = *sysdescr_len_ptr; break; case 2: /* sysObjectID */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OBJ_ID); od->v_len = sysobjid.len * sizeof(s32_t); break; case 3: /* sysUpTime */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_TIMETICKS); od->v_len = sizeof(u32_t); break; case 4: /* sysContact */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OC_STR); od->v_len = *syscontact_len_ptr; break; case 5: /* sysName */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OC_STR); od->v_len = *sysname_len_ptr; break; case 6: /* sysLocation */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OC_STR); od->v_len = *syslocation_len_ptr; break; case 7: /* sysServices */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("system_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; }; } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("system_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } /** * Returns system object value. * * @param ident_len the address length (2) * @param ident points to objectname.0 (object id trailer) * @param len return value space (in bytes) * @param value points to (varbind) space to copy value into. */ static void system_get_value(struct obj_def *od, u16_t len, void *value) { u8_t id; id = od->id_inst_ptr[0]; switch (id) { case 1: /* sysDescr */ ocstrncpy(value,sysdescr_ptr,len); break; case 2: /* sysObjectID */ objectidncpy((s32_t*)value,(s32_t*)sysobjid.id,len / sizeof(s32_t)); break; case 3: /* sysUpTime */ { snmp_get_sysuptime(value); } break; case 4: /* sysContact */ ocstrncpy(value,syscontact_ptr,len); break; case 5: /* sysName */ ocstrncpy(value,sysname_ptr,len); break; case 6: /* sysLocation */ ocstrncpy(value,syslocation_ptr,len); break; case 7: /* sysServices */ { s32_t *sint_ptr = value; *sint_ptr = sysservices; } break; }; } static u8_t system_set_test(struct obj_def *od, u16_t len, void *value) { u8_t id, set_ok; if (value) {} set_ok = 0; id = od->id_inst_ptr[0]; switch (id) { case 4: /* sysContact */ if ((syscontact_ptr != syscontact_default) && (len <= 255)) { set_ok = 1; } break; case 5: /* sysName */ if ((sysname_ptr != sysname_default) && (len <= 255)) { set_ok = 1; } break; case 6: /* sysLocation */ if ((syslocation_ptr != syslocation_default) && (len <= 255)) { set_ok = 1; } break; }; return set_ok; } static void system_set_value(struct obj_def *od, u16_t len, void *value) { u8_t id; id = od->id_inst_ptr[0]; switch (id) { case 4: /* sysContact */ ocstrncpy(syscontact_ptr,value,len); *syscontact_len_ptr = len; break; case 5: /* sysName */ ocstrncpy(sysname_ptr,value,len); *sysname_len_ptr = len; break; case 6: /* sysLocation */ ocstrncpy(syslocation_ptr,value,len); *syslocation_len_ptr = len; break; }; } /** * Returns interfaces.ifnumber object definition. * * @param ident_len the address length (2) * @param ident points to objectname.index * @param od points to object definition. */ static void interfaces_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { /* return to object name, adding index depth (1) */ ident_len += 1; ident -= 1; if (ident_len == 2) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("interfaces_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } /** * Returns interfaces.ifnumber object value. * * @param ident_len the address length (2) * @param ident points to objectname.0 (object id trailer) * @param len return value space (in bytes) * @param value points to (varbind) space to copy value into. */ static void interfaces_get_value(struct obj_def *od, u16_t len, void *value) { if (len){} if (od->id_inst_ptr[0] == 1) { s32_t *sint_ptr = value; *sint_ptr = iflist_root.count; } } /** * Returns ifentry object definitions. * * @param ident_len the address length (2) * @param ident points to objectname.index * @param od points to object definition. */ static void ifentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { u8_t id; /* return to object name, adding index depth (1) */ ident_len += 1; ident -= 1; if (ident_len == 2) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; id = ident[0]; LWIP_DEBUGF(SNMP_MIB_DEBUG,("get_object_def ifentry.%"U16_F"\n",(u16_t)id)); switch (id) { case 1: /* ifIndex */ case 3: /* ifType */ case 4: /* ifMtu */ case 8: /* ifOperStatus */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; case 2: /* ifDescr */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OC_STR); /** @todo this should be some sort of sizeof(struct netif.name) */ od->v_len = 2; break; case 5: /* ifSpeed */ case 21: /* ifOutQLen */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_GAUGE); od->v_len = sizeof(u32_t); break; case 6: /* ifPhysAddress */ { struct netif *netif; snmp_ifindextonetif(ident[1], &netif); od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OC_STR); od->v_len = netif->hwaddr_len; } break; case 7: /* ifAdminStatus */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; case 9: /* ifLastChange */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_TIMETICKS); od->v_len = sizeof(u32_t); break; case 10: /* ifInOctets */ case 11: /* ifInUcastPkts */ case 12: /* ifInNUcastPkts */ case 13: /* ifInDiscarts */ case 14: /* ifInErrors */ case 15: /* ifInUnkownProtos */ case 16: /* ifOutOctets */ case 17: /* ifOutUcastPkts */ case 18: /* ifOutNUcastPkts */ case 19: /* ifOutDiscarts */ case 20: /* ifOutErrors */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_COUNTER); od->v_len = sizeof(u32_t); break; case 22: /* ifSpecific */ /** @note returning zeroDotZero (0.0) no media specific MIB support */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OBJ_ID); od->v_len = ifspecific.len * sizeof(s32_t); break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("ifentry_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; }; } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("ifentry_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } /** * Returns ifentry object value. * * @param ident_len the address length (2) * @param ident points to objectname.0 (object id trailer) * @param len return value space (in bytes) * @param value points to (varbind) space to copy value into. */ static void ifentry_get_value(struct obj_def *od, u16_t len, void *value) { struct netif *netif; u8_t id; snmp_ifindextonetif(od->id_inst_ptr[1], &netif); id = od->id_inst_ptr[0]; switch (id) { case 1: /* ifIndex */ { s32_t *sint_ptr = value; *sint_ptr = od->id_inst_ptr[1]; } break; case 2: /* ifDescr */ ocstrncpy(value,(u8_t*)netif->name,len); break; case 3: /* ifType */ { s32_t *sint_ptr = value; *sint_ptr = netif->link_type; } break; case 4: /* ifMtu */ { s32_t *sint_ptr = value; *sint_ptr = netif->mtu; } break; case 5: /* ifSpeed */ { u32_t *uint_ptr = value; *uint_ptr = netif->link_speed; } break; case 6: /* ifPhysAddress */ ocstrncpy(value,netif->hwaddr,len); break; case 7: /* ifAdminStatus */ #if LWIP_NETIF_LINK_CALLBACK { s32_t *sint_ptr = value; if (netif_is_up(netif)) { if (netif_is_link_up(netif)) { *sint_ptr = 1; /* up */ } else { *sint_ptr = 7; /* lowerLayerDown */ } } else { *sint_ptr = 2; /* down */ } } break; #endif case 8: /* ifOperStatus */ { s32_t *sint_ptr = value; if (netif_is_up(netif)) { *sint_ptr = 1; } else { *sint_ptr = 2; } } break; case 9: /* ifLastChange */ { u32_t *uint_ptr = value; *uint_ptr = netif->ts; } break; case 10: /* ifInOctets */ { u32_t *uint_ptr = value; *uint_ptr = netif->ifinoctets; } break; case 11: /* ifInUcastPkts */ { u32_t *uint_ptr = value; *uint_ptr = netif->ifinucastpkts; } break; case 12: /* ifInNUcastPkts */ { u32_t *uint_ptr = value; *uint_ptr = netif->ifinnucastpkts; } break; case 13: /* ifInDiscarts */ { u32_t *uint_ptr = value; *uint_ptr = netif->ifindiscards; } break; case 14: /* ifInErrors */ case 15: /* ifInUnkownProtos */ /** @todo add these counters! */ { u32_t *uint_ptr = value; *uint_ptr = 0; } break; case 16: /* ifOutOctets */ { u32_t *uint_ptr = value; *uint_ptr = netif->ifoutoctets; } break; case 17: /* ifOutUcastPkts */ { u32_t *uint_ptr = value; *uint_ptr = netif->ifoutucastpkts; } break; case 18: /* ifOutNUcastPkts */ { u32_t *uint_ptr = value; *uint_ptr = netif->ifoutnucastpkts; } break; case 19: /* ifOutDiscarts */ { u32_t *uint_ptr = value; *uint_ptr = netif->ifoutdiscards; } break; case 20: /* ifOutErrors */ /** @todo add this counter! */ { u32_t *uint_ptr = value; *uint_ptr = 0; } break; case 21: /* ifOutQLen */ /** @todo figure out if this must be 0 (no queue) or 1? */ { u32_t *uint_ptr = value; *uint_ptr = 0; } break; case 22: /* ifSpecific */ objectidncpy((s32_t*)value,(s32_t*)ifspecific.id,len / sizeof(s32_t)); break; }; } #if !SNMP_SAFE_REQUESTS static u8_t ifentry_set_test (struct obj_def *od, u16_t len, void *value) { struct netif *netif; u8_t id, set_ok; set_ok = 0; snmp_ifindextonetif(od->id_inst_ptr[1], &netif); id = od->id_inst_ptr[0]; switch (id) { case 7: /* ifAdminStatus */ { s32_t *sint_ptr = value; if (*sint_ptr == 1 || *sint_ptr == 2) set_ok = 1; } break; } return set_ok; } static void ifentry_set_value (struct obj_def *od, u16_t len, void *value) { struct netif *netif; u8_t id; snmp_ifindextonetif(od->id_inst_ptr[1], &netif); id = od->id_inst_ptr[0]; switch (id) { case 7: /* ifAdminStatus */ { s32_t *sint_ptr = value; if (*sint_ptr == 1) { netif_set_up(netif); } else if (*sint_ptr == 2) { netif_set_down(netif); } } break; } } #endif /* SNMP_SAFE_REQUESTS */ /** * Returns atentry object definitions. * * @param ident_len the address length (6) * @param ident points to objectname.atifindex.atnetaddress * @param od points to object definition. */ static void atentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { /* return to object name, adding index depth (5) */ ident_len += 5; ident -= 5; if (ident_len == 6) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; switch (ident[0]) { case 1: /* atIfIndex */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; case 2: /* atPhysAddress */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OC_STR); od->v_len = 6; /** @todo try to use netif::hwaddr_len */ break; case 3: /* atNetAddress */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_IPADDR); od->v_len = 4; break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("atentry_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; } } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("atentry_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void atentry_get_value(struct obj_def *od, u16_t len, void *value) { #if LWIP_ARP u8_t id; struct eth_addr* ethaddr_ret; struct ip_addr* ipaddr_ret; #endif /* LWIP_ARP */ struct ip_addr ip; struct netif *netif; if (len) {} snmp_ifindextonetif(od->id_inst_ptr[1], &netif); snmp_oidtoip(&od->id_inst_ptr[2], &ip); ip.addr = htonl(ip.addr); #if LWIP_ARP /** @todo implement a netif_find_addr */ if (etharp_find_addr(netif, &ip, ðaddr_ret, &ipaddr_ret) > -1) { id = od->id_inst_ptr[0]; switch (id) { case 1: /* atIfIndex */ { s32_t *sint_ptr = value; *sint_ptr = od->id_inst_ptr[1]; } break; case 2: /* atPhysAddress */ { struct eth_addr *dst = value; *dst = *ethaddr_ret; } break; case 3: /* atNetAddress */ { struct ip_addr *dst = value; *dst = *ipaddr_ret; } break; } } #endif /* LWIP_ARP */ } static void ip_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { u8_t id; /* return to object name, adding index depth (1) */ ident_len += 1; ident -= 1; if (ident_len == 2) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; id = ident[0]; LWIP_DEBUGF(SNMP_MIB_DEBUG,("get_object_def ip.%"U16_F".0\n",(u16_t)id)); switch (id) { case 1: /* ipForwarding */ case 2: /* ipDefaultTTL */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; case 3: /* ipInReceives */ case 4: /* ipInHdrErrors */ case 5: /* ipInAddrErrors */ case 6: /* ipForwDatagrams */ case 7: /* ipInUnknownProtos */ case 8: /* ipInDiscards */ case 9: /* ipInDelivers */ case 10: /* ipOutRequests */ case 11: /* ipOutDiscards */ case 12: /* ipOutNoRoutes */ case 14: /* ipReasmReqds */ case 15: /* ipReasmOKs */ case 16: /* ipReasmFails */ case 17: /* ipFragOKs */ case 18: /* ipFragFails */ case 19: /* ipFragCreates */ case 23: /* ipRoutingDiscards */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_COUNTER); od->v_len = sizeof(u32_t); break; case 13: /* ipReasmTimeout */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("ip_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; }; } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("ip_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void ip_get_value(struct obj_def *od, u16_t len, void *value) { u8_t id; if (len) {} id = od->id_inst_ptr[0]; switch (id) { case 1: /* ipForwarding */ { s32_t *sint_ptr = value; #if IP_FORWARD /* forwarding */ *sint_ptr = 1; #else /* not-forwarding */ *sint_ptr = 2; #endif } break; case 2: /* ipDefaultTTL */ { s32_t *sint_ptr = value; *sint_ptr = IP_DEFAULT_TTL; } break; case 3: /* ipInReceives */ { u32_t *uint_ptr = value; *uint_ptr = ipinreceives; } break; case 4: /* ipInHdrErrors */ { u32_t *uint_ptr = value; *uint_ptr = ipinhdrerrors; } break; case 5: /* ipInAddrErrors */ { u32_t *uint_ptr = value; *uint_ptr = ipinaddrerrors; } break; case 6: /* ipForwDatagrams */ { u32_t *uint_ptr = value; *uint_ptr = ipforwdatagrams; } break; case 7: /* ipInUnknownProtos */ { u32_t *uint_ptr = value; *uint_ptr = ipinunknownprotos; } break; case 8: /* ipInDiscards */ { u32_t *uint_ptr = value; *uint_ptr = ipindiscards; } break; case 9: /* ipInDelivers */ { u32_t *uint_ptr = value; *uint_ptr = ipindelivers; } break; case 10: /* ipOutRequests */ { u32_t *uint_ptr = value; *uint_ptr = ipoutrequests; } break; case 11: /* ipOutDiscards */ { u32_t *uint_ptr = value; *uint_ptr = ipoutdiscards; } break; case 12: /* ipOutNoRoutes */ { u32_t *uint_ptr = value; *uint_ptr = ipoutnoroutes; } break; case 13: /* ipReasmTimeout */ { s32_t *sint_ptr = value; #if IP_REASSEMBLY *sint_ptr = IP_REASS_MAXAGE; #else *sint_ptr = 0; #endif } break; case 14: /* ipReasmReqds */ { u32_t *uint_ptr = value; *uint_ptr = ipreasmreqds; } break; case 15: /* ipReasmOKs */ { u32_t *uint_ptr = value; *uint_ptr = ipreasmoks; } break; case 16: /* ipReasmFails */ { u32_t *uint_ptr = value; *uint_ptr = ipreasmfails; } break; case 17: /* ipFragOKs */ { u32_t *uint_ptr = value; *uint_ptr = ipfragoks; } break; case 18: /* ipFragFails */ { u32_t *uint_ptr = value; *uint_ptr = ipfragfails; } break; case 19: /* ipFragCreates */ { u32_t *uint_ptr = value; *uint_ptr = ipfragcreates; } break; case 23: /* ipRoutingDiscards */ /** @todo can lwIP discard routes at all?? hardwire this to 0?? */ { u32_t *uint_ptr = value; *uint_ptr = iproutingdiscards; } break; }; } /** * Test ip object value before setting. * * @param od is the object definition * @param len return value space (in bytes) * @param value points to (varbind) space to copy value from. * * @note we allow set if the value matches the hardwired value, * otherwise return badvalue. */ static u8_t ip_set_test(struct obj_def *od, u16_t len, void *value) { u8_t id, set_ok; s32_t *sint_ptr = value; if (len) {} set_ok = 0; id = od->id_inst_ptr[0]; switch (id) { case 1: /* ipForwarding */ #if IP_FORWARD /* forwarding */ if (*sint_ptr == 1) #else /* not-forwarding */ if (*sint_ptr == 2) #endif { set_ok = 1; } break; case 2: /* ipDefaultTTL */ if (*sint_ptr == IP_DEFAULT_TTL) { set_ok = 1; } break; }; return set_ok; } static void ip_addrentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { /* return to object name, adding index depth (4) */ ident_len += 4; ident -= 4; if (ident_len == 5) { u8_t id; od->id_inst_len = ident_len; od->id_inst_ptr = ident; id = ident[0]; switch (id) { case 1: /* ipAdEntAddr */ case 3: /* ipAdEntNetMask */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_IPADDR); od->v_len = 4; break; case 2: /* ipAdEntIfIndex */ case 4: /* ipAdEntBcastAddr */ case 5: /* ipAdEntReasmMaxSize */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("ip_addrentry_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; } } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("ip_addrentry_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void ip_addrentry_get_value(struct obj_def *od, u16_t len, void *value) { u8_t id; u16_t ifidx; struct ip_addr ip; struct netif *netif = netif_list; if (len) {} snmp_oidtoip(&od->id_inst_ptr[1], &ip); ip.addr = htonl(ip.addr); ifidx = 0; while ((netif != NULL) && !ip_addr_cmp(&ip, &netif->ip_addr)) { netif = netif->next; ifidx++; } if (netif != NULL) { id = od->id_inst_ptr[0]; switch (id) { case 1: /* ipAdEntAddr */ { struct ip_addr *dst = value; *dst = netif->ip_addr; } break; case 2: /* ipAdEntIfIndex */ { s32_t *sint_ptr = value; *sint_ptr = ifidx + 1; } break; case 3: /* ipAdEntNetMask */ { struct ip_addr *dst = value; *dst = netif->netmask; } break; case 4: /* ipAdEntBcastAddr */ { s32_t *sint_ptr = value; /* lwIP oddity, there's no broadcast address in the netif we can rely on */ *sint_ptr = ip_addr_broadcast.addr & 1; } break; case 5: /* ipAdEntReasmMaxSize */ { s32_t *sint_ptr = value; #if IP_REASSEMBLY /* @todo The theoretical maximum is IP_REASS_MAX_PBUFS * size of the pbufs, * but only if receiving one fragmented packet at a time. * The current solution is to calculate for 2 simultaneous packets... */ *sint_ptr = (IP_HLEN + ((IP_REASS_MAX_PBUFS/2) * (PBUF_POOL_BUFSIZE - PBUF_LINK_HLEN - IP_HLEN))); #else /** @todo returning MTU would be a bad thing and returning a wild guess like '576' isn't good either */ *sint_ptr = 0; #endif } break; } } } /** * @note * lwIP IP routing is currently using the network addresses in netif_list. * if no suitable network IP is found in netif_list, the default_netif is used. */ static void ip_rteentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { u8_t id; /* return to object name, adding index depth (4) */ ident_len += 4; ident -= 4; if (ident_len == 5) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; id = ident[0]; switch (id) { case 1: /* ipRouteDest */ case 7: /* ipRouteNextHop */ case 11: /* ipRouteMask */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_IPADDR); od->v_len = 4; break; case 2: /* ipRouteIfIndex */ case 3: /* ipRouteMetric1 */ case 4: /* ipRouteMetric2 */ case 5: /* ipRouteMetric3 */ case 6: /* ipRouteMetric4 */ case 8: /* ipRouteType */ case 10: /* ipRouteAge */ case 12: /* ipRouteMetric5 */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; case 9: /* ipRouteProto */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; case 13: /* ipRouteInfo */ /** @note returning zeroDotZero (0.0) no routing protocol specific MIB */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OBJ_ID); od->v_len = iprouteinfo.len * sizeof(s32_t); break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("ip_rteentry_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; } } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("ip_rteentry_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void ip_rteentry_get_value(struct obj_def *od, u16_t len, void *value) { struct netif *netif; struct ip_addr dest; s32_t *ident; u8_t id; ident = od->id_inst_ptr; snmp_oidtoip(&ident[1], &dest); dest.addr = htonl(dest.addr); if (dest.addr == 0) { /* ip_route() uses default netif for default route */ netif = netif_default; } else { /* not using ip_route(), need exact match! */ netif = netif_list; while ((netif != NULL) && !ip_addr_netcmp(&dest, &(netif->ip_addr), &(netif->netmask)) ) { netif = netif->next; } } if (netif != NULL) { id = ident[0]; switch (id) { case 1: /* ipRouteDest */ { struct ip_addr *dst = value; if (dest.addr == 0) { /* default rte has 0.0.0.0 dest */ dst->addr = 0; } else { /* netifs have netaddress dest */ dst->addr = netif->ip_addr.addr & netif->netmask.addr; } } break; case 2: /* ipRouteIfIndex */ { s32_t *sint_ptr = value; snmp_netiftoifindex(netif, sint_ptr); } break; case 3: /* ipRouteMetric1 */ { s32_t *sint_ptr = value; if (dest.addr == 0) { /* default rte has metric 1 */ *sint_ptr = 1; } else { /* other rtes have metric 0 */ *sint_ptr = 0; } } break; case 4: /* ipRouteMetric2 */ case 5: /* ipRouteMetric3 */ case 6: /* ipRouteMetric4 */ case 12: /* ipRouteMetric5 */ { s32_t *sint_ptr = value; /* not used */ *sint_ptr = -1; } break; case 7: /* ipRouteNextHop */ { struct ip_addr *dst = value; if (dest.addr == 0) { /* default rte: gateway */ *dst = netif->gw; } else { /* other rtes: netif ip_addr */ *dst = netif->ip_addr; } } break; case 8: /* ipRouteType */ { s32_t *sint_ptr = value; if (dest.addr == 0) { /* default rte is indirect */ *sint_ptr = 4; } else { /* other rtes are direct */ *sint_ptr = 3; } } break; case 9: /* ipRouteProto */ { s32_t *sint_ptr = value; /* locally defined routes */ *sint_ptr = 2; } break; case 10: /* ipRouteAge */ { s32_t *sint_ptr = value; /** @todo (sysuptime - timestamp last change) / 100 @see snmp_insert_iprteidx_tree() */ *sint_ptr = 0; } break; case 11: /* ipRouteMask */ { struct ip_addr *dst = value; if (dest.addr == 0) { /* default rte use 0.0.0.0 mask */ dst->addr = 0; } else { /* other rtes use netmask */ *dst = netif->netmask; } } break; case 13: /* ipRouteInfo */ objectidncpy((s32_t*)value,(s32_t*)iprouteinfo.id,len / sizeof(s32_t)); break; } } } static void ip_ntomentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { /* return to object name, adding index depth (5) */ ident_len += 5; ident -= 5; if (ident_len == 6) { u8_t id; od->id_inst_len = ident_len; od->id_inst_ptr = ident; id = ident[0]; switch (id) { case 1: /* ipNetToMediaIfIndex */ case 4: /* ipNetToMediaType */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; case 2: /* ipNetToMediaPhysAddress */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_OC_STR); od->v_len = 6; /** @todo try to use netif::hwaddr_len */ break; case 3: /* ipNetToMediaNetAddress */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_IPADDR); od->v_len = 4; break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("ip_ntomentry_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; } } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("ip_ntomentry_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void ip_ntomentry_get_value(struct obj_def *od, u16_t len, void *value) { #if LWIP_ARP u8_t id; struct eth_addr* ethaddr_ret; struct ip_addr* ipaddr_ret; #endif /* LWIP_ARP */ struct ip_addr ip; struct netif *netif; if (len) {} snmp_ifindextonetif(od->id_inst_ptr[1], &netif); snmp_oidtoip(&od->id_inst_ptr[2], &ip); ip.addr = htonl(ip.addr); #if LWIP_ARP /** @todo implement a netif_find_addr */ if (etharp_find_addr(netif, &ip, ðaddr_ret, &ipaddr_ret) > -1) { id = od->id_inst_ptr[0]; switch (id) { case 1: /* ipNetToMediaIfIndex */ { s32_t *sint_ptr = value; *sint_ptr = od->id_inst_ptr[1]; } break; case 2: /* ipNetToMediaPhysAddress */ { struct eth_addr *dst = value; *dst = *ethaddr_ret; } break; case 3: /* ipNetToMediaNetAddress */ { struct ip_addr *dst = value; *dst = *ipaddr_ret; } break; case 4: /* ipNetToMediaType */ { s32_t *sint_ptr = value; /* dynamic (?) */ *sint_ptr = 3; } break; } } #endif /* LWIP_ARP */ } static void icmp_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { /* return to object name, adding index depth (1) */ ident_len += 1; ident -= 1; if ((ident_len == 2) && (ident[0] > 0) && (ident[0] < 27)) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_COUNTER); od->v_len = sizeof(u32_t); } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("icmp_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void icmp_get_value(struct obj_def *od, u16_t len, void *value) { u32_t *uint_ptr = value; u8_t id; if (len){} id = od->id_inst_ptr[0]; switch (id) { case 1: /* icmpInMsgs */ *uint_ptr = icmpinmsgs; break; case 2: /* icmpInErrors */ *uint_ptr = icmpinerrors; break; case 3: /* icmpInDestUnreachs */ *uint_ptr = icmpindestunreachs; break; case 4: /* icmpInTimeExcds */ *uint_ptr = icmpintimeexcds; break; case 5: /* icmpInParmProbs */ *uint_ptr = icmpinparmprobs; break; case 6: /* icmpInSrcQuenchs */ *uint_ptr = icmpinsrcquenchs; break; case 7: /* icmpInRedirects */ *uint_ptr = icmpinredirects; break; case 8: /* icmpInEchos */ *uint_ptr = icmpinechos; break; case 9: /* icmpInEchoReps */ *uint_ptr = icmpinechoreps; break; case 10: /* icmpInTimestamps */ *uint_ptr = icmpintimestamps; break; case 11: /* icmpInTimestampReps */ *uint_ptr = icmpintimestampreps; break; case 12: /* icmpInAddrMasks */ *uint_ptr = icmpinaddrmasks; break; case 13: /* icmpInAddrMaskReps */ *uint_ptr = icmpinaddrmaskreps; break; case 14: /* icmpOutMsgs */ *uint_ptr = icmpoutmsgs; break; case 15: /* icmpOutErrors */ *uint_ptr = icmpouterrors; break; case 16: /* icmpOutDestUnreachs */ *uint_ptr = icmpoutdestunreachs; break; case 17: /* icmpOutTimeExcds */ *uint_ptr = icmpouttimeexcds; break; case 18: /* icmpOutParmProbs */ *uint_ptr = icmpoutparmprobs; break; case 19: /* icmpOutSrcQuenchs */ *uint_ptr = icmpoutsrcquenchs; break; case 20: /* icmpOutRedirects */ *uint_ptr = icmpoutredirects; break; case 21: /* icmpOutEchos */ *uint_ptr = icmpoutechos; break; case 22: /* icmpOutEchoReps */ *uint_ptr = icmpoutechoreps; break; case 23: /* icmpOutTimestamps */ *uint_ptr = icmpouttimestamps; break; case 24: /* icmpOutTimestampReps */ *uint_ptr = icmpouttimestampreps; break; case 25: /* icmpOutAddrMasks */ *uint_ptr = icmpoutaddrmasks; break; case 26: /* icmpOutAddrMaskReps */ *uint_ptr = icmpoutaddrmaskreps; break; } } #if LWIP_TCP /** @todo tcp grp */ static void tcp_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { u8_t id; /* return to object name, adding index depth (1) */ ident_len += 1; ident -= 1; if (ident_len == 2) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; id = ident[0]; LWIP_DEBUGF(SNMP_MIB_DEBUG,("get_object_def tcp.%"U16_F".0\n",(u16_t)id)); switch (id) { case 1: /* tcpRtoAlgorithm */ case 2: /* tcpRtoMin */ case 3: /* tcpRtoMax */ case 4: /* tcpMaxConn */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; case 5: /* tcpActiveOpens */ case 6: /* tcpPassiveOpens */ case 7: /* tcpAttemptFails */ case 8: /* tcpEstabResets */ case 10: /* tcpInSegs */ case 11: /* tcpOutSegs */ case 12: /* tcpRetransSegs */ case 14: /* tcpInErrs */ case 15: /* tcpOutRsts */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_COUNTER); od->v_len = sizeof(u32_t); break; case 9: /* tcpCurrEstab */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_GAUGE); od->v_len = sizeof(u32_t); break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("tcp_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; }; } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("tcp_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void tcp_get_value(struct obj_def *od, u16_t len, void *value) { u32_t *uint_ptr = value; s32_t *sint_ptr = value; u8_t id; if (len){} id = od->id_inst_ptr[0]; switch (id) { case 1: /* tcpRtoAlgorithm, vanj(4) */ *sint_ptr = 4; break; case 2: /* tcpRtoMin */ /* @todo not the actual value, a guess, needs to be calculated */ *sint_ptr = 1000; break; case 3: /* tcpRtoMax */ /* @todo not the actual value, a guess, needs to be calculated */ *sint_ptr = 60000; break; case 4: /* tcpMaxConn */ *sint_ptr = MEMP_NUM_TCP_PCB; break; case 5: /* tcpActiveOpens */ *uint_ptr = tcpactiveopens; break; case 6: /* tcpPassiveOpens */ *uint_ptr = tcppassiveopens; break; case 7: /* tcpAttemptFails */ *uint_ptr = tcpattemptfails; break; case 8: /* tcpEstabResets */ *uint_ptr = tcpestabresets; break; case 9: /* tcpCurrEstab */ { u16_t tcpcurrestab = 0; struct tcp_pcb *pcb = tcp_active_pcbs; while (pcb != NULL) { if ((pcb->state == ESTABLISHED) || (pcb->state == CLOSE_WAIT)) { tcpcurrestab++; } pcb = pcb->next; } *uint_ptr = tcpcurrestab; } break; case 10: /* tcpInSegs */ *uint_ptr = tcpinsegs; break; case 11: /* tcpOutSegs */ *uint_ptr = tcpoutsegs; break; case 12: /* tcpRetransSegs */ *uint_ptr = tcpretranssegs; break; case 14: /* tcpInErrs */ *uint_ptr = tcpinerrs; break; case 15: /* tcpOutRsts */ *uint_ptr = tcpoutrsts; break; } } #ifdef THIS_SEEMS_UNUSED static void tcpconnentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { /* return to object name, adding index depth (10) */ ident_len += 10; ident -= 10; if (ident_len == 11) { u8_t id; od->id_inst_len = ident_len; od->id_inst_ptr = ident; id = ident[0]; LWIP_DEBUGF(SNMP_MIB_DEBUG,("get_object_def tcp.%"U16_F".0\n",(u16_t)id)); switch (id) { case 1: /* tcpConnState */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; case 2: /* tcpConnLocalAddress */ case 4: /* tcpConnRemAddress */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_IPADDR); od->v_len = 4; break; case 3: /* tcpConnLocalPort */ case 5: /* tcpConnRemPort */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("tcpconnentry_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; }; } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("tcpconnentry_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; } } static void tcpconnentry_get_value(struct obj_def *od, u16_t len, void *value) { struct ip_addr lip, rip; u16_t lport, rport; s32_t *ident; ident = od->id_inst_ptr; snmp_oidtoip(&ident[1], &lip); lip.addr = htonl(lip.addr); lport = ident[5]; snmp_oidtoip(&ident[6], &rip); rip.addr = htonl(rip.addr); rport = ident[10]; /** @todo find matching PCB */ } #endif /* if 0 */ #endif static void udp_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { /* return to object name, adding index depth (1) */ ident_len += 1; ident -= 1; if ((ident_len == 2) && (ident[0] > 0) && (ident[0] < 6)) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_COUNTER); od->v_len = sizeof(u32_t); } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("udp_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void udp_get_value(struct obj_def *od, u16_t len, void *value) { u32_t *uint_ptr = value; u8_t id; if (len){} id = od->id_inst_ptr[0]; switch (id) { case 1: /* udpInDatagrams */ *uint_ptr = udpindatagrams; break; case 2: /* udpNoPorts */ *uint_ptr = udpnoports; break; case 3: /* udpInErrors */ *uint_ptr = udpinerrors; break; case 4: /* udpOutDatagrams */ *uint_ptr = udpoutdatagrams; break; } } static void udpentry_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { /* return to object name, adding index depth (5) */ ident_len += 5; ident -= 5; if (ident_len == 6) { od->id_inst_len = ident_len; od->id_inst_ptr = ident; switch (ident[0]) { case 1: /* udpLocalAddress */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_IPADDR); od->v_len = 4; break; case 2: /* udpLocalPort */ od->instance = MIB_OBJECT_TAB; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("udpentry_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; } } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("udpentry_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void udpentry_get_value(struct obj_def *od, u16_t len, void *value) { u8_t id; struct udp_pcb *pcb; struct ip_addr ip; u16_t port; if (len){} snmp_oidtoip(&od->id_inst_ptr[1], &ip); ip.addr = htonl(ip.addr); port = od->id_inst_ptr[5]; pcb = udp_pcbs; while ((pcb != NULL) && !((pcb->local_ip.addr == ip.addr) && (pcb->local_port == port))) { pcb = pcb->next; } if (pcb != NULL) { id = od->id_inst_ptr[0]; switch (id) { case 1: /* udpLocalAddress */ { struct ip_addr *dst = value; *dst = pcb->local_ip; } break; case 2: /* udpLocalPort */ { s32_t *sint_ptr = value; *sint_ptr = pcb->local_port; } break; } } } static void snmp_get_object_def(u8_t ident_len, s32_t *ident, struct obj_def *od) { /* return to object name, adding index depth (1) */ ident_len += 1; ident -= 1; if (ident_len == 2) { u8_t id; od->id_inst_len = ident_len; od->id_inst_ptr = ident; id = ident[0]; switch (id) { case 1: /* snmpInPkts */ case 2: /* snmpOutPkts */ case 3: /* snmpInBadVersions */ case 4: /* snmpInBadCommunityNames */ case 5: /* snmpInBadCommunityUses */ case 6: /* snmpInASNParseErrs */ case 8: /* snmpInTooBigs */ case 9: /* snmpInNoSuchNames */ case 10: /* snmpInBadValues */ case 11: /* snmpInReadOnlys */ case 12: /* snmpInGenErrs */ case 13: /* snmpInTotalReqVars */ case 14: /* snmpInTotalSetVars */ case 15: /* snmpInGetRequests */ case 16: /* snmpInGetNexts */ case 17: /* snmpInSetRequests */ case 18: /* snmpInGetResponses */ case 19: /* snmpInTraps */ case 20: /* snmpOutTooBigs */ case 21: /* snmpOutNoSuchNames */ case 22: /* snmpOutBadValues */ case 24: /* snmpOutGenErrs */ case 25: /* snmpOutGetRequests */ case 26: /* snmpOutGetNexts */ case 27: /* snmpOutSetRequests */ case 28: /* snmpOutGetResponses */ case 29: /* snmpOutTraps */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_ONLY; od->asn_type = (SNMP_ASN1_APPLIC | SNMP_ASN1_PRIMIT | SNMP_ASN1_COUNTER); od->v_len = sizeof(u32_t); break; case 30: /* snmpEnableAuthenTraps */ od->instance = MIB_OBJECT_SCALAR; od->access = MIB_OBJECT_READ_WRITE; od->asn_type = (SNMP_ASN1_UNIV | SNMP_ASN1_PRIMIT | SNMP_ASN1_INTEG); od->v_len = sizeof(s32_t); break; default: LWIP_DEBUGF(SNMP_MIB_DEBUG,("snmp_get_object_def: no such object\n")); od->instance = MIB_OBJECT_NONE; break; }; } else { LWIP_DEBUGF(SNMP_MIB_DEBUG,("snmp_get_object_def: no scalar\n")); od->instance = MIB_OBJECT_NONE; } } static void snmp_get_value(struct obj_def *od, u16_t len, void *value) { u32_t *uint_ptr = value; u8_t id; if (len){} id = od->id_inst_ptr[0]; switch (id) { case 1: /* snmpInPkts */ *uint_ptr = snmpinpkts; break; case 2: /* snmpOutPkts */ *uint_ptr = snmpoutpkts; break; case 3: /* snmpInBadVersions */ *uint_ptr = snmpinbadversions; break; case 4: /* snmpInBadCommunityNames */ *uint_ptr = snmpinbadcommunitynames; break; case 5: /* snmpInBadCommunityUses */ *uint_ptr = snmpinbadcommunityuses; break; case 6: /* snmpInASNParseErrs */ *uint_ptr = snmpinasnparseerrs; break; case 8: /* snmpInTooBigs */ *uint_ptr = snmpintoobigs; break; case 9: /* snmpInNoSuchNames */ *uint_ptr = snmpinnosuchnames; break; case 10: /* snmpInBadValues */ *uint_ptr = snmpinbadvalues; break; case 11: /* snmpInReadOnlys */ *uint_ptr = snmpinreadonlys; break; case 12: /* snmpInGenErrs */ *uint_ptr = snmpingenerrs; break; case 13: /* snmpInTotalReqVars */ *uint_ptr = snmpintotalreqvars; break; case 14: /* snmpInTotalSetVars */ *uint_ptr = snmpintotalsetvars; break; case 15: /* snmpInGetRequests */ *uint_ptr = snmpingetrequests; break; case 16: /* snmpInGetNexts */ *uint_ptr = snmpingetnexts; break; case 17: /* snmpInSetRequests */ *uint_ptr = snmpinsetrequests; break; case 18: /* snmpInGetResponses */ *uint_ptr = snmpingetresponses; break; case 19: /* snmpInTraps */ *uint_ptr = snmpintraps; break; case 20: /* snmpOutTooBigs */ *uint_ptr = snmpouttoobigs; break; case 21: /* snmpOutNoSuchNames */ *uint_ptr = snmpoutnosuchnames; break; case 22: /* snmpOutBadValues */ *uint_ptr = snmpoutbadvalues; break; case 24: /* snmpOutGenErrs */ *uint_ptr = snmpoutgenerrs; break; case 25: /* snmpOutGetRequests */ *uint_ptr = snmpoutgetrequests; break; case 26: /* snmpOutGetNexts */ *uint_ptr = snmpoutgetnexts; break; case 27: /* snmpOutSetRequests */ *uint_ptr = snmpoutsetrequests; break; case 28: /* snmpOutGetResponses */ *uint_ptr = snmpoutgetresponses; break; case 29: /* snmpOutTraps */ *uint_ptr = snmpouttraps; break; case 30: /* snmpEnableAuthenTraps */ *uint_ptr = *snmpenableauthentraps_ptr; break; }; } /** * Test snmp object value before setting. * * @param od is the object definition * @param len return value space (in bytes) * @param value points to (varbind) space to copy value from. */ static u8_t snmp_set_test(struct obj_def *od, u16_t len, void *value) { u8_t id, set_ok; if (len) {} set_ok = 0; id = od->id_inst_ptr[0]; if (id == 30) { /* snmpEnableAuthenTraps */ s32_t *sint_ptr = value; if (snmpenableauthentraps_ptr != &snmpenableauthentraps_default) { /* we should have writable non-volatile mem here */ if ((*sint_ptr == 1) || (*sint_ptr == 2)) { set_ok = 1; } } else { /* const or hardwired value */ if (*sint_ptr == snmpenableauthentraps_default) { set_ok = 1; } } } return set_ok; } static void snmp_set_value(struct obj_def *od, u16_t len, void *value) { u8_t id; if (len) {} id = od->id_inst_ptr[0]; if (id == 30) { /* snmpEnableAuthenTraps */ s32_t *sint_ptr = value; *snmpenableauthentraps_ptr = *sint_ptr; } } #endif /* LWIP_SNMP */