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author | Trygve Laugstøl <trygvis@inamo.no> | 2018-08-23 17:08:59 +0200 |
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committer | Trygve Laugstøl <trygvis@inamo.no> | 2018-08-23 17:12:21 +0200 |
commit | 3061ecca3d0fdfb87dabbf5f63c9e06c2a30f53a (patch) | |
tree | ab49cc16ed0b853452c5c2ed2d3042416d628986 /thirdparty/nRF5_SDK_15.0.0_a53641a/external/lwip/src/apps/snmp/snmp_core.c | |
download | iot-sensors-master.tar.gz iot-sensors-master.tar.bz2 iot-sensors-master.tar.xz iot-sensors-master.zip |
Diffstat (limited to 'thirdparty/nRF5_SDK_15.0.0_a53641a/external/lwip/src/apps/snmp/snmp_core.c')
-rw-r--r-- | thirdparty/nRF5_SDK_15.0.0_a53641a/external/lwip/src/apps/snmp/snmp_core.c | 1349 |
1 files changed, 1349 insertions, 0 deletions
diff --git a/thirdparty/nRF5_SDK_15.0.0_a53641a/external/lwip/src/apps/snmp/snmp_core.c b/thirdparty/nRF5_SDK_15.0.0_a53641a/external/lwip/src/apps/snmp/snmp_core.c new file mode 100644 index 0000000..c041833 --- /dev/null +++ b/thirdparty/nRF5_SDK_15.0.0_a53641a/external/lwip/src/apps/snmp/snmp_core.c @@ -0,0 +1,1349 @@ +/** + * @file + * MIB tree access/construction functions. + */ + +/* + * 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> + * Martin Hentschel <info@cl-soft.de> +*/ + +/** + * @defgroup snmp SNMPv2c agent + * @ingroup apps + * SNMPv2c compatible agent\n + * There is also a MIB compiler and a MIB viewer in lwIP contrib repository + * (lwip-contrib/apps/LwipMibCompiler).\n + * The agent implements the most important MIB2 MIBs including IPv6 support + * (interfaces, UDP, TCP, SNMP, ICMP, SYSTEM). IP MIB is an older version + * whithout IPv6 statistics (TODO).\n + * Rewritten by Martin Hentschel <info@cl-soft.de> and + * Dirk Ziegelmeier <dziegel@gmx.de>\n + * Work on SNMPv3 has started, but is not finished.\n + * + * 0 Agent Capabilities + * ==================== + * + * Features: + * --------- + * - SNMPv2c support. + * - Low RAM usage - no memory pools, stack only. + * - MIB2 implementation is separated from SNMP stack. + * - Support for multiple MIBs (snmp_set_mibs() call) - e.g. for private MIB. + * - Simple and generic API for MIB implementation. + * - Comfortable node types and helper functions for scalar arrays and tables. + * - Counter64, bit and truthvalue datatype support. + * - Callbacks for SNMP writes e.g. to implement persistency. + * - Runs on two APIs: RAW and netconn. + * - Async API is gone - the stack now supports netconn API instead, + * so blocking operations can be done in MIB calls. + * SNMP runs in a worker thread when netconn API is used. + * - Simplified thread sync support for MIBs - useful when MIBs + * need to access variables shared with other threads where no locking is + * possible. Used in MIB2 to access lwIP stats from lwIP thread. + * + * MIB compiler (code generator): + * ------------------------------ + * - Provided in lwIP contrib repository. + * - Written in C#. MIB viewer used Windows Forms. + * - Developed on Windows with Visual Studio 2010. + * - Can be compiled and used on all platforms with http://www.monodevelop.com/. + * - Based on a heavily modified version of of SharpSnmpLib (a4bd05c6afb4) + * (https://sharpsnmplib.codeplex.com/SourceControl/network/forks/Nemo157/MIBParserUpdate). + * - MIB parser, C file generation framework and LWIP code generation are cleanly + * separated, which means the code may be useful as a base for code generation + * of other SNMP agents. + * + * Notes: + * ------ + * - Stack and MIB compiler were used to implement a Profinet device. + * Compiled/implemented MIBs: LLDP-MIB, LLDP-EXT-DOT3-MIB, LLDP-EXT-PNO-MIB. + * + * SNMPv1 per RFC1157 and SNMPv2c per RFC 3416 + * ------------------------------------------- + * Note the S in SNMP stands for "Simple". Note that "Simple" is + * relative. SNMP is simple compared to the complex ISO network + * management protocols CMIP (Common Management Information Protocol) + * and CMOT (CMip Over Tcp). + * + * MIB II + * ------ + * The standard lwIP stack management information base. + * This is a required MIB, so this is always enabled. + * The groups EGP, CMOT and transmission are disabled by default. + * + * Most mib-2 objects are not writable except: + * sysName, sysLocation, sysContact, snmpEnableAuthenTraps. + * Writing to or changing the ARP and IP address and route + * tables is not possible. + * + * Note lwIP has a very limited notion of IP routing. It currently + * doen't have a route table and doesn't have a notion of the U,G,H flags. + * Instead lwIP uses the interface list with only one default interface + * acting as a single gateway interface (G) for the default route. + * + * The agent returns a "virtual table" with the default route 0.0.0.0 + * for the default interface and network routes (no H) for each + * network interface in the netif_list. + * All routes are considered to be up (U). + * + * Loading additional MIBs + * ----------------------- + * MIBs can only be added in compile-time, not in run-time. + * + * + * 1 Building the Agent + * ==================== + * First of all you'll need to add the following define + * to your local lwipopts.h: + * \#define LWIP_SNMP 1 + * + * and add the source files your makefile. + * + * Note you'll might need to adapt you network driver to update + * the mib2 variables for your interface. + * + * 2 Running the Agent + * =================== + * The following function calls must be made in your program to + * actually get the SNMP agent running. + * + * Before starting the agent you should supply pointers + * for sysContact, sysLocation, and snmpEnableAuthenTraps. + * You can do this by calling + * + * - snmp_mib2_set_syscontact() + * - snmp_mib2_set_syslocation() + * - snmp_set_auth_traps_enabled() + * + * You can register a callback which is called on successful write access: + * snmp_set_write_callback(). + * + * Additionally you may want to set + * + * - snmp_mib2_set_sysdescr() + * - snmp_set_device_enterprise_oid() + * - snmp_mib2_set_sysname() + * + * Also before starting the agent you need to setup + * one or more trap destinations using these calls: + * + * - snmp_trap_dst_enable() + * - snmp_trap_dst_ip_set() + * + * If you need more than MIB2, set the MIBs you want to use + * by snmp_set_mibs(). + * + * Finally, enable the agent by calling snmp_init() + * + * @defgroup snmp_core Core + * @ingroup snmp + * + * @defgroup snmp_traps Traps + * @ingroup snmp + */ + +#include "lwip/apps/snmp_opts.h" + +#if LWIP_SNMP /* don't build if not configured for use in lwipopts.h */ + +#include "lwip/apps/snmp.h" +#include "lwip/apps/snmp_core.h" +#include "snmp_core_priv.h" +#include "lwip/netif.h" +#include <string.h> + + +#if (LWIP_SNMP && (SNMP_TRAP_DESTINATIONS<=0)) + #error "If you want to use SNMP, you have to define SNMP_TRAP_DESTINATIONS>=1 in your lwipopts.h" +#endif +#if (!LWIP_UDP && LWIP_SNMP) + #error "If you want to use SNMP, you have to define LWIP_UDP=1 in your lwipopts.h" +#endif + +struct snmp_statistics snmp_stats; +static const struct snmp_obj_id snmp_device_enterprise_oid_default = {SNMP_DEVICE_ENTERPRISE_OID_LEN, SNMP_DEVICE_ENTERPRISE_OID}; +static const struct snmp_obj_id* snmp_device_enterprise_oid = &snmp_device_enterprise_oid_default; + +const u32_t snmp_zero_dot_zero_values[] = { 0, 0 }; +const struct snmp_obj_id_const_ref snmp_zero_dot_zero = { LWIP_ARRAYSIZE(snmp_zero_dot_zero_values), snmp_zero_dot_zero_values }; + + +#if SNMP_LWIP_MIB2 +#include "lwip/apps/snmp_mib2.h" +static const struct snmp_mib* const default_mibs[] = { &mib2 }; +static u8_t snmp_num_mibs = 1; +#else +static const struct snmp_mib* const default_mibs[] = { NULL }; +static u8_t snmp_num_mibs = 0; +#endif + +/* List of known mibs */ +static struct snmp_mib const * const *snmp_mibs = default_mibs; + +/** + * @ingroup snmp_core + * Sets the MIBs to use. + * Example: call snmp_set_mibs() as follows: + * static const struct snmp_mib *my_snmp_mibs[] = { + * &mib2, + * &private_mib + * }; + * snmp_set_mibs(my_snmp_mibs, LWIP_ARRAYSIZE(my_snmp_mibs)); + */ +void +snmp_set_mibs(const struct snmp_mib **mibs, u8_t num_mibs) +{ + LWIP_ASSERT("mibs pointer must be != NULL", (mibs != NULL)); + LWIP_ASSERT("num_mibs pointer must be != 0", (num_mibs != 0)); + snmp_mibs = mibs; + snmp_num_mibs = num_mibs; +} + +/** + * @ingroup snmp_core + * 'device enterprise oid' is used for 'device OID' field in trap PDU's (for identification of generating device) + * as well as for value returned by MIB-2 'sysObjectID' field (if internal MIB2 implementation is used). + * The 'device enterprise oid' shall point to an OID located under 'private-enterprises' branch (1.3.6.1.4.1.XXX). If a vendor + * wants to provide a custom object there, he has to get its own enterprise oid from IANA (http://www.iana.org). It + * is not allowed to use LWIP enterprise ID! + * In order to identify a specific device it is recommended to create a dedicated OID for each device type under its own + * enterprise oid. + * e.g. + * device a > 1.3.6.1.4.1.XXX(ent-oid).1(devices).1(device a) + * device b > 1.3.6.1.4.1.XXX(ent-oid).1(devices).2(device b) + * for more details see description of 'sysObjectID' field in RFC1213-MIB + */ +void snmp_set_device_enterprise_oid(const struct snmp_obj_id* device_enterprise_oid) +{ + if (device_enterprise_oid == NULL) { + snmp_device_enterprise_oid = &snmp_device_enterprise_oid_default; + } else { + snmp_device_enterprise_oid = device_enterprise_oid; + } +} + +/** + * @ingroup snmp_core + * Get 'device enterprise oid' + */ +const struct snmp_obj_id* snmp_get_device_enterprise_oid(void) +{ + return snmp_device_enterprise_oid; +} + +#if LWIP_IPV4 +/** + * Conversion from InetAddressIPv4 oid to lwIP ip4_addr + * @param oid points to u32_t ident[4] input + * @param ip points to output struct + */ +u8_t +snmp_oid_to_ip4(const u32_t *oid, ip4_addr_t *ip) +{ + if ((oid[0] > 0xFF) || + (oid[1] > 0xFF) || + (oid[2] > 0xFF) || + (oid[3] > 0xFF)) { + ip4_addr_copy(*ip, *IP4_ADDR_ANY4); + return 0; + } + + IP4_ADDR(ip, oid[0], oid[1], oid[2], oid[3]); + return 1; +} + +/** + * Convert ip4_addr to InetAddressIPv4 (no InetAddressType) + * @param ip points to input struct + * @param oid points to u32_t ident[4] output + */ +void +snmp_ip4_to_oid(const ip4_addr_t *ip, u32_t *oid) +{ + oid[0] = ip4_addr1(ip); + oid[1] = ip4_addr2(ip); + oid[2] = ip4_addr3(ip); + oid[3] = ip4_addr4(ip); +} +#endif /* LWIP_IPV4 */ + +#if LWIP_IPV6 +/** + * Conversion from InetAddressIPv6 oid to lwIP ip6_addr + * @param oid points to u32_t oid[16] input + * @param ip points to output struct + */ +u8_t +snmp_oid_to_ip6(const u32_t *oid, ip6_addr_t *ip) +{ + if ((oid[0] > 0xFF) || + (oid[1] > 0xFF) || + (oid[2] > 0xFF) || + (oid[3] > 0xFF) || + (oid[4] > 0xFF) || + (oid[5] > 0xFF) || + (oid[6] > 0xFF) || + (oid[7] > 0xFF) || + (oid[8] > 0xFF) || + (oid[9] > 0xFF) || + (oid[10] > 0xFF) || + (oid[11] > 0xFF) || + (oid[12] > 0xFF) || + (oid[13] > 0xFF) || + (oid[14] > 0xFF) || + (oid[15] > 0xFF)) { + ip6_addr_set_any(ip); + return 0; + } + + ip->addr[0] = (oid[0] << 24) | (oid[1] << 16) | (oid[2] << 8) | (oid[3] << 0); + ip->addr[1] = (oid[4] << 24) | (oid[5] << 16) | (oid[6] << 8) | (oid[7] << 0); + ip->addr[2] = (oid[8] << 24) | (oid[9] << 16) | (oid[10] << 8) | (oid[11] << 0); + ip->addr[3] = (oid[12] << 24) | (oid[13] << 16) | (oid[14] << 8) | (oid[15] << 0); + return 1; +} + +/** + * Convert ip6_addr to InetAddressIPv6 (no InetAddressType) + * @param ip points to input struct + * @param oid points to u32_t ident[16] output + */ +void +snmp_ip6_to_oid(const ip6_addr_t *ip, u32_t *oid) +{ + oid[0] = (ip->addr[0] & 0xFF000000) >> 24; + oid[1] = (ip->addr[0] & 0x00FF0000) >> 16; + oid[2] = (ip->addr[0] & 0x0000FF00) >> 8; + oid[3] = (ip->addr[0] & 0x000000FF) >> 0; + oid[4] = (ip->addr[1] & 0xFF000000) >> 24; + oid[5] = (ip->addr[1] & 0x00FF0000) >> 16; + oid[6] = (ip->addr[1] & 0x0000FF00) >> 8; + oid[7] = (ip->addr[1] & 0x000000FF) >> 0; + oid[8] = (ip->addr[2] & 0xFF000000) >> 24; + oid[9] = (ip->addr[2] & 0x00FF0000) >> 16; + oid[10] = (ip->addr[2] & 0x0000FF00) >> 8; + oid[11] = (ip->addr[2] & 0x000000FF) >> 0; + oid[12] = (ip->addr[3] & 0xFF000000) >> 24; + oid[13] = (ip->addr[3] & 0x00FF0000) >> 16; + oid[14] = (ip->addr[3] & 0x0000FF00) >> 8; + oid[15] = (ip->addr[3] & 0x000000FF) >> 0; +} +#endif /* LWIP_IPV6 */ + +#if LWIP_IPV4 || LWIP_IPV6 +/** + * Convert to InetAddressType+InetAddress+InetPortNumber + * @param ip IP address + * @param port Port + * @param oid OID + * @return OID length + */ +u8_t +snmp_ip_port_to_oid(const ip_addr_t *ip, u16_t port, u32_t *oid) +{ + u8_t idx; + + idx = snmp_ip_to_oid(ip, oid); + oid[idx] = port; + idx++; + + return idx; +} + +/** + * Convert to InetAddressType+InetAddress + * @param ip IP address + * @param oid OID + * @return OID length + */ +u8_t +snmp_ip_to_oid(const ip_addr_t *ip, u32_t *oid) +{ + if (IP_IS_ANY_TYPE_VAL(*ip)) { + oid[0] = 0; /* any */ + oid[1] = 0; /* no IP OIDs follow */ + return 2; + } else if (IP_IS_V6(ip)) { +#if LWIP_IPV6 + oid[0] = 2; /* ipv6 */ + oid[1] = 16; /* 16 InetAddressIPv6 OIDs follow */ + snmp_ip6_to_oid(ip_2_ip6(ip), &oid[2]); + return 18; +#else /* LWIP_IPV6 */ + return 0; +#endif /* LWIP_IPV6 */ + } else { +#if LWIP_IPV4 + oid[0] = 1; /* ipv4 */ + oid[1] = 4; /* 4 InetAddressIPv4 OIDs follow */ + snmp_ip4_to_oid(ip_2_ip4(ip), &oid[2]); + return 6; +#else /* LWIP_IPV4 */ + return 0; +#endif /* LWIP_IPV4 */ + } +} + +/** + * Convert from InetAddressType+InetAddress to ip_addr_t + * @param oid OID + * @param oid_len OID length + * @param ip IP address + * @return Parsed OID length + */ +u8_t +snmp_oid_to_ip(const u32_t *oid, u8_t oid_len, ip_addr_t *ip) +{ + /* InetAddressType */ + if (oid_len < 1) { + return 0; + } + + if (oid[0] == 0) { /* any */ + /* 1x InetAddressType, 1x OID len */ + if (oid_len < 2) { + return 0; + } + if (oid[1] != 0) { + return 0; + } + + memset(ip, 0, sizeof(*ip)); + IP_SET_TYPE(ip, IPADDR_TYPE_ANY); + + return 2; + } else if (oid[0] == 1) { /* ipv4 */ +#if LWIP_IPV4 + /* 1x InetAddressType, 1x OID len, 4x InetAddressIPv4 */ + if (oid_len < 6) { + return 0; + } + + /* 4x ipv4 OID */ + if (oid[1] != 4) { + return 0; + } + + IP_SET_TYPE(ip, IPADDR_TYPE_V4); + if (!snmp_oid_to_ip4(&oid[2], ip_2_ip4(ip))) { + return 0; + } + + return 6; +#else /* LWIP_IPV4 */ + return 0; +#endif /* LWIP_IPV4 */ + } else if (oid[0] == 2) { /* ipv6 */ +#if LWIP_IPV6 + /* 1x InetAddressType, 1x OID len, 16x InetAddressIPv6 */ + if (oid_len < 18) { + return 0; + } + + /* 16x ipv6 OID */ + if (oid[1] != 16) { + return 0; + } + + IP_SET_TYPE(ip, IPADDR_TYPE_V6); + if (!snmp_oid_to_ip6(&oid[2], ip_2_ip6(ip))) { + return 0; + } + + return 18; +#else /* LWIP_IPV6 */ + return 0; +#endif /* LWIP_IPV6 */ + } else { /* unsupported InetAddressType */ + return 0; + } +} + +/** + * Convert from InetAddressType+InetAddress+InetPortNumber to ip_addr_t and u16_t + * @param oid OID + * @param oid_len OID length + * @param ip IP address + * @param port Port + * @return Parsed OID length + */ +u8_t +snmp_oid_to_ip_port(const u32_t *oid, u8_t oid_len, ip_addr_t *ip, u16_t *port) +{ + u8_t idx = 0; + + /* InetAddressType + InetAddress */ + idx += snmp_oid_to_ip(&oid[idx], oid_len-idx, ip); + if (idx == 0) { + return 0; + } + + /* InetPortNumber */ + if (oid_len < (idx+1)) { + return 0; + } + if (oid[idx] > 0xffff) { + return 0; + } + *port = (u16_t)oid[idx]; + idx++; + + return idx; +} + +#endif /* LWIP_IPV4 || LWIP_IPV6 */ + +/** + * Assign an OID to struct snmp_obj_id + * @param target Assignment target + * @param oid OID + * @param oid_len OID length + */ +void +snmp_oid_assign(struct snmp_obj_id* target, const u32_t *oid, u8_t oid_len) +{ + LWIP_ASSERT("oid_len <= LWIP_SNMP_OBJ_ID_LEN", oid_len <= SNMP_MAX_OBJ_ID_LEN); + + target->len = oid_len; + + if (oid_len > 0) { + MEMCPY(target->id, oid, oid_len * sizeof(u32_t)); + } +} + +/** + * Prefix an OID to OID in struct snmp_obj_id + * @param target Assignment target to prefix + * @param oid OID + * @param oid_len OID length + */ +void +snmp_oid_prefix(struct snmp_obj_id* target, const u32_t *oid, u8_t oid_len) +{ + LWIP_ASSERT("target->len + oid_len <= LWIP_SNMP_OBJ_ID_LEN", (target->len + oid_len) <= SNMP_MAX_OBJ_ID_LEN); + + if (oid_len > 0) { + /* move existing OID to make room at the beginning for OID to insert */ + int i; + for (i = target->len-1; i>=0; i--) { + target->id[i + oid_len] = target->id[i]; + } + + /* paste oid at the beginning */ + MEMCPY(target->id, oid, oid_len * sizeof(u32_t)); + } +} + +/** + * Combine two OIDs into struct snmp_obj_id + * @param target Assignmet target + * @param oid1 OID 1 + * @param oid1_len OID 1 length + * @param oid2 OID 2 + * @param oid2_len OID 2 length + */ +void +snmp_oid_combine(struct snmp_obj_id* target, const u32_t *oid1, u8_t oid1_len, const u32_t *oid2, u8_t oid2_len) +{ + snmp_oid_assign(target, oid1, oid1_len); + snmp_oid_append(target, oid2, oid2_len); +} + +/** + * Append OIDs to struct snmp_obj_id + * @param target Assignment target to append to + * @param oid OID + * @param oid_len OID length + */ +void +snmp_oid_append(struct snmp_obj_id* target, const u32_t *oid, u8_t oid_len) +{ + LWIP_ASSERT("offset + oid_len <= LWIP_SNMP_OBJ_ID_LEN", (target->len + oid_len) <= SNMP_MAX_OBJ_ID_LEN); + + if (oid_len > 0) { + MEMCPY(&target->id[target->len], oid, oid_len * sizeof(u32_t)); + target->len += oid_len; + } +} + +/** + * Compare two OIDs + * @param oid1 OID 1 + * @param oid1_len OID 1 length + * @param oid2 OID 2 + * @param oid2_len OID 2 length + * @return -1: OID1<OID2 1: OID1 >OID2 0: equal + */ +s8_t +snmp_oid_compare(const u32_t *oid1, u8_t oid1_len, const u32_t *oid2, u8_t oid2_len) +{ + u8_t level = 0; + LWIP_ASSERT("'oid1' param must not be NULL or 'oid1_len' param be 0!", (oid1 != NULL) || (oid1_len == 0)); + LWIP_ASSERT("'oid2' param must not be NULL or 'oid2_len' param be 0!", (oid2 != NULL) || (oid2_len == 0)); + + while ((level < oid1_len) && (level < oid2_len)) { + if (*oid1 < *oid2) { + return -1; + } + if (*oid1 > *oid2) { + return 1; + } + + level++; + oid1++; + oid2++; + } + + /* common part of both OID's is equal, compare length */ + if (oid1_len < oid2_len) { + return -1; + } + if (oid1_len > oid2_len) { + return 1; + } + + /* they are equal */ + return 0; +} + + +/** + * Check of two OIDs are equal + * @param oid1 OID 1 + * @param oid1_len OID 1 length + * @param oid2 OID 2 + * @param oid2_len OID 2 length + * @return 1: equal 0: non-equal + */ +u8_t +snmp_oid_equal(const u32_t *oid1, u8_t oid1_len, const u32_t *oid2, u8_t oid2_len) +{ + return (snmp_oid_compare(oid1, oid1_len, oid2, oid2_len) == 0)? 1 : 0; +} + +/** + * Convert netif to interface index + * @param netif netif + * @return index + */ +u8_t +netif_to_num(const struct netif *netif) +{ + u8_t result = 0; + struct netif *netif_iterator = netif_list; + + while (netif_iterator != NULL) { + result++; + + if (netif_iterator == netif) { + return result; + } + + netif_iterator = netif_iterator->next; + } + + LWIP_ASSERT("netif not found in netif_list", 0); + return 0; +} + +static const struct snmp_mib* +snmp_get_mib_from_oid(const u32_t *oid, u8_t oid_len) +{ + const u32_t* list_oid; + const u32_t* searched_oid; + u8_t i, l; + + u8_t max_match_len = 0; + const struct snmp_mib* matched_mib = NULL; + + LWIP_ASSERT("'oid' param must not be NULL!", (oid != NULL)); + + if (oid_len == 0) { + return NULL; + } + + for (i = 0; i < snmp_num_mibs; i++) { + LWIP_ASSERT("MIB array not initialized correctly", (snmp_mibs[i] != NULL)); + LWIP_ASSERT("MIB array not initialized correctly - base OID is NULL", (snmp_mibs[i]->base_oid != NULL)); + + if (oid_len >= snmp_mibs[i]->base_oid_len) { + l = snmp_mibs[i]->base_oid_len; + list_oid = snmp_mibs[i]->base_oid; + searched_oid = oid; + + while (l > 0) { + if (*list_oid != *searched_oid) { + break; + } + + l--; + list_oid++; + searched_oid++; + } + + if ((l == 0) && (snmp_mibs[i]->base_oid_len > max_match_len)) { + max_match_len = snmp_mibs[i]->base_oid_len; + matched_mib = snmp_mibs[i]; + } + } + } + + return matched_mib; +} + +static const struct snmp_mib* +snmp_get_next_mib(const u32_t *oid, u8_t oid_len) +{ + u8_t i; + const struct snmp_mib* next_mib = NULL; + + LWIP_ASSERT("'oid' param must not be NULL!", (oid != NULL)); + + if (oid_len == 0) { + return NULL; + } + + for (i = 0; i < snmp_num_mibs; i++) { + if (snmp_mibs[i]->base_oid != NULL) { + /* check if mib is located behind starting point */ + if (snmp_oid_compare(snmp_mibs[i]->base_oid, snmp_mibs[i]->base_oid_len, oid, oid_len) > 0) { + if ((next_mib == NULL) || + (snmp_oid_compare(snmp_mibs[i]->base_oid, snmp_mibs[i]->base_oid_len, + next_mib->base_oid, next_mib->base_oid_len) < 0)) { + next_mib = snmp_mibs[i]; + } + } + } + } + + return next_mib; +} + +static const struct snmp_mib* +snmp_get_mib_between(const u32_t *oid1, u8_t oid1_len, const u32_t *oid2, u8_t oid2_len) +{ + const struct snmp_mib* next_mib = snmp_get_next_mib(oid1, oid1_len); + + LWIP_ASSERT("'oid2' param must not be NULL!", (oid2 != NULL)); + LWIP_ASSERT("'oid2_len' param must be greater than 0!", (oid2_len > 0)); + + if (next_mib != NULL) { + if (snmp_oid_compare(next_mib->base_oid, next_mib->base_oid_len, oid2, oid2_len) < 0) { + return next_mib; + } + } + + return NULL; +} + +u8_t +snmp_get_node_instance_from_oid(const u32_t *oid, u8_t oid_len, struct snmp_node_instance* node_instance) +{ + u8_t result = SNMP_ERR_NOSUCHOBJECT; + const struct snmp_mib *mib; + const struct snmp_node *mn = NULL; + + mib = snmp_get_mib_from_oid(oid, oid_len); + if (mib != NULL) { + u8_t oid_instance_len; + + mn = snmp_mib_tree_resolve_exact(mib, oid, oid_len, &oid_instance_len); + if ((mn != NULL) && (mn->node_type != SNMP_NODE_TREE)) { + /* get instance */ + const struct snmp_leaf_node* leaf_node = (const struct snmp_leaf_node*)(const void*)mn; + + node_instance->node = mn; + snmp_oid_assign(&node_instance->instance_oid, oid + (oid_len - oid_instance_len), oid_instance_len); + + result = leaf_node->get_instance( + oid, + oid_len - oid_instance_len, + node_instance); + +#ifdef LWIP_DEBUG + if (result == SNMP_ERR_NOERROR) { + if (((node_instance->access & SNMP_NODE_INSTANCE_ACCESS_READ) != 0) && (node_instance->get_value == NULL)) { + LWIP_DEBUGF(SNMP_DEBUG, ("SNMP inconsistent access: node is readable but no get_value function is specified\n")); + } + if (((node_instance->access & SNMP_NODE_INSTANCE_ACCESS_WRITE) != 0) && (node_instance->set_value == NULL)) { + LWIP_DEBUGF(SNMP_DEBUG, ("SNMP inconsistent access: node is writable but no set_value and/or set_test function is specified\n")); + } + } +#endif + } + } + + return result; +} + +u8_t +snmp_get_next_node_instance_from_oid(const u32_t *oid, u8_t oid_len, snmp_validate_node_instance_method validate_node_instance_method, void* validate_node_instance_arg, struct snmp_obj_id* node_oid, struct snmp_node_instance* node_instance) +{ + const struct snmp_mib *mib; + const struct snmp_node *mn = NULL; + const u32_t* start_oid = NULL; + u8_t start_oid_len = 0; + + /* resolve target MIB from passed OID */ + mib = snmp_get_mib_from_oid(oid, oid_len); + if (mib == NULL) { + /* passed OID does not reference any known MIB, start at the next closest MIB */ + mib = snmp_get_next_mib(oid, oid_len); + + if (mib != NULL) { + start_oid = mib->base_oid; + start_oid_len = mib->base_oid_len; + } + } else { + start_oid = oid; + start_oid_len = oid_len; + } + + /* resolve target node from MIB, skip to next MIB if no suitable node is found in current MIB */ + while ((mib != NULL) && (mn == NULL)) { + u8_t oid_instance_len; + + /* check if OID directly references a node inside current MIB, in this case we have to ask this node for the next instance */ + mn = snmp_mib_tree_resolve_exact(mib, start_oid, start_oid_len, &oid_instance_len); + if (mn != NULL) { + snmp_oid_assign(node_oid, start_oid, start_oid_len - oid_instance_len); /* set oid to node */ + snmp_oid_assign(&node_instance->instance_oid, start_oid + (start_oid_len - oid_instance_len), oid_instance_len); /* set (relative) instance oid */ + } else { + /* OID does not reference a node, search for the next closest node inside MIB; set instance_oid.len to zero because we want the first instance of this node */ + mn = snmp_mib_tree_resolve_next(mib, start_oid, start_oid_len, node_oid); + node_instance->instance_oid.len = 0; + } + + /* validate the node; if the node has no further instance or the returned instance is invalid, search for the next in MIB and validate again */ + node_instance->node = mn; + while (mn != NULL) { + u8_t result; + + /* clear fields which may have values from previous loops */ + node_instance->asn1_type = 0; + node_instance->access = SNMP_NODE_INSTANCE_NOT_ACCESSIBLE; + node_instance->get_value = NULL; + node_instance->set_test = NULL; + node_instance->set_value = NULL; + node_instance->release_instance = NULL; + node_instance->reference.ptr = NULL; + node_instance->reference_len = 0; + + result = ((const struct snmp_leaf_node*)(const void*)mn)->get_next_instance( + node_oid->id, + node_oid->len, + node_instance); + + if (result == SNMP_ERR_NOERROR) { +#ifdef LWIP_DEBUG + if (((node_instance->access & SNMP_NODE_INSTANCE_ACCESS_READ) != 0) && (node_instance->get_value == NULL)) { + LWIP_DEBUGF(SNMP_DEBUG, ("SNMP inconsistent access: node is readable but no get_value function is specified\n")); + } + if (((node_instance->access & SNMP_NODE_INSTANCE_ACCESS_WRITE) != 0) && (node_instance->set_value == NULL)) { + LWIP_DEBUGF(SNMP_DEBUG, ("SNMP inconsistent access: node is writable but no set_value function is specified\n")); + } +#endif + + /* validate node because the node may be not accessible for example (but let the caller decide what is valid */ + if ((validate_node_instance_method == NULL) || + (validate_node_instance_method(node_instance, validate_node_instance_arg) == SNMP_ERR_NOERROR)) { + /* node_oid "returns" the full result OID (including the instance part) */ + snmp_oid_append(node_oid, node_instance->instance_oid.id, node_instance->instance_oid.len); + break; + } + + if (node_instance->release_instance != NULL) { + node_instance->release_instance(node_instance); + } + /* + the instance itself is not valid, ask for next instance from same node. + we don't have to change any variables because node_instance->instance_oid is used as input (starting point) + as well as output (resulting next OID), so we have to simply call get_next_instance method again + */ + } else { + if (node_instance->release_instance != NULL) { + node_instance->release_instance(node_instance); + } + + /* the node has no further instance, skip to next node */ + mn = snmp_mib_tree_resolve_next(mib, node_oid->id, node_oid->len, &node_instance->instance_oid); /* misuse node_instance->instance_oid as tmp buffer */ + if (mn != NULL) { + /* prepare for next loop */ + snmp_oid_assign(node_oid, node_instance->instance_oid.id, node_instance->instance_oid.len); + node_instance->instance_oid.len = 0; + node_instance->node = mn; + } + } + } + + if (mn != NULL) { + /* + we found a suitable next node, + now we have to check if a inner MIB is located between the searched OID and the resulting OID. + this is possible because MIB's may be located anywhere in the global tree, that means also in + the subtree of another MIB (e.g. if searched OID is .2 and resulting OID is .4, then another + MIB having .3 as root node may exist) + */ + const struct snmp_mib *intermediate_mib; + intermediate_mib = snmp_get_mib_between(start_oid, start_oid_len, node_oid->id, node_oid->len); + + if (intermediate_mib != NULL) { + /* search for first node inside intermediate mib in next loop */ + if (node_instance->release_instance != NULL) { + node_instance->release_instance(node_instance); + } + + mn = NULL; + mib = intermediate_mib; + start_oid = mib->base_oid; + start_oid_len = mib->base_oid_len; + } + /* else { we found out target node } */ + } else { + /* + there is no further (suitable) node inside this MIB, search for the next MIB with following priority + 1. search for inner MIB's (whose root is located inside tree of current MIB) + 2. search for surrouding MIB's (where the current MIB is the inner MIB) and continue there if any + 3. take the next closest MIB (not being related to the current MIB) + */ + const struct snmp_mib *next_mib; + next_mib = snmp_get_next_mib(start_oid, start_oid_len); /* returns MIB's related to point 1 and 3 */ + + /* is the found MIB an inner MIB? (point 1) */ + if ((next_mib != NULL) && (next_mib->base_oid_len > mib->base_oid_len) && + (snmp_oid_compare(next_mib->base_oid, mib->base_oid_len, mib->base_oid, mib->base_oid_len) == 0)) { + /* yes it is -> continue at inner MIB */ + mib = next_mib; + start_oid = mib->base_oid; + start_oid_len = mib->base_oid_len; + } else { + /* check if there is a surrounding mib where to continue (point 2) (only possible if OID length > 1) */ + if (mib->base_oid_len > 1) { + mib = snmp_get_mib_from_oid(mib->base_oid, mib->base_oid_len - 1); + + if (mib == NULL) { + /* no surrounding mib, use next mib encountered above (point 3) */ + mib = next_mib; + + if (mib != NULL) { + start_oid = mib->base_oid; + start_oid_len = mib->base_oid_len; + } + } + /* else { start_oid stays the same because we want to continue from current offset in surrounding mib (point 2) } */ + } + } + } + } + + if (mib == NULL) { + /* loop is only left when mib == null (error) or mib_node != NULL (success) */ + return SNMP_ERR_ENDOFMIBVIEW; + } + + return SNMP_ERR_NOERROR; +} + +/** + * Searches tree for the supplied object identifier. + * + */ +const struct snmp_node * +snmp_mib_tree_resolve_exact(const struct snmp_mib *mib, const u32_t *oid, u8_t oid_len, u8_t* oid_instance_len) +{ + const struct snmp_node* const* node = &mib->root_node; + u8_t oid_offset = mib->base_oid_len; + + while ((oid_offset < oid_len) && ((*node)->node_type == SNMP_NODE_TREE)) { + /* search for matching sub node */ + u32_t subnode_oid = *(oid + oid_offset); + + u32_t i = (*(const struct snmp_tree_node* const*)node)->subnode_count; + node = (*(const struct snmp_tree_node* const*)node)->subnodes; + while ((i > 0) && ((*node)->oid != subnode_oid)) { + node++; + i--; + } + + if (i == 0) { + /* no matching subnode found */ + return NULL; + } + + oid_offset++; + } + + if ((*node)->node_type != SNMP_NODE_TREE) { + /* we found a leaf node */ + *oid_instance_len = oid_len - oid_offset; + return (*node); + } + + return NULL; +} + +const struct snmp_node* +snmp_mib_tree_resolve_next(const struct snmp_mib *mib, const u32_t *oid, u8_t oid_len, struct snmp_obj_id* oidret) +{ + u8_t oid_offset = mib->base_oid_len; + const struct snmp_node* const* node; + const struct snmp_tree_node* node_stack[SNMP_MAX_OBJ_ID_LEN]; + s32_t nsi = 0; /* NodeStackIndex */ + u32_t subnode_oid; + + if (mib->root_node->node_type != SNMP_NODE_TREE) { + /* a next operation on a mib with only a leaf node will always return NULL because there is no other node */ + return NULL; + } + + /* first build node stack related to passed oid (as far as possible), then go backwards to determine the next node */ + node_stack[nsi] = (const struct snmp_tree_node*)(const void*)mib->root_node; + while (oid_offset < oid_len) { + /* search for matching sub node */ + u32_t i = node_stack[nsi]->subnode_count; + node = node_stack[nsi]->subnodes; + + subnode_oid = *(oid + oid_offset); + + while ((i > 0) && ((*node)->oid != subnode_oid)) { + node++; + i--; + } + + if ((i == 0) || ((*node)->node_type != SNMP_NODE_TREE)) { + /* no (matching) tree-subnode found */ + break; + } + nsi++; + node_stack[nsi] = (const struct snmp_tree_node*)(const void*)(*node); + + oid_offset++; + } + + + if (oid_offset >= oid_len) { + /* passed oid references a tree node -> return first useable sub node of it */ + subnode_oid = 0; + } else { + subnode_oid = *(oid + oid_offset) + 1; + } + + while (nsi >= 0) { + const struct snmp_node* subnode = NULL; + + /* find next node on current level */ + s32_t i = node_stack[nsi]->subnode_count; + node = node_stack[nsi]->subnodes; + while (i > 0) { + if ((*node)->oid == subnode_oid) { + subnode = *node; + break; + } else if (((*node)->oid > subnode_oid) && ((subnode == NULL) || ((*node)->oid < subnode->oid))) { + subnode = *node; + } + + node++; + i--; + } + + if (subnode == NULL) { + /* no further node found on this level, go one level up and start searching with index of current node*/ + subnode_oid = node_stack[nsi]->node.oid + 1; + nsi--; + } else { + if (subnode->node_type == SNMP_NODE_TREE) { + /* next is a tree node, go into it and start searching */ + nsi++; + node_stack[nsi] = (const struct snmp_tree_node*)(const void*)subnode; + subnode_oid = 0; + } else { + /* we found a leaf node -> fill oidret and return it */ + snmp_oid_assign(oidret, mib->base_oid, mib->base_oid_len); + i = 1; + while (i <= nsi) { + oidret->id[oidret->len] = node_stack[i]->node.oid; + oidret->len++; + i++; + } + + oidret->id[oidret->len] = subnode->oid; + oidret->len++; + + return subnode; + } + } + } + + return NULL; +} + +/** initialize struct next_oid_state using this function before passing it to next_oid_check */ +void +snmp_next_oid_init(struct snmp_next_oid_state *state, + const u32_t *start_oid, u8_t start_oid_len, + u32_t *next_oid_buf, u8_t next_oid_max_len) +{ + state->start_oid = start_oid; + state->start_oid_len = start_oid_len; + state->next_oid = next_oid_buf; + state->next_oid_len = 0; + state->next_oid_max_len = next_oid_max_len; + state->status = SNMP_NEXT_OID_STATUS_NO_MATCH; +} + +/** checks if the passed incomplete OID may be a possible candidate for snmp_next_oid_check(); +this methid is intended if the complete OID is not yet known but it is very expensive to build it up, +so it is possible to test the starting part before building up the complete oid and pass it to snmp_next_oid_check()*/ +u8_t +snmp_next_oid_precheck(struct snmp_next_oid_state *state, const u32_t *oid, const u8_t oid_len) +{ + if (state->status != SNMP_NEXT_OID_STATUS_BUF_TO_SMALL) { + u8_t start_oid_len = (oid_len < state->start_oid_len) ? oid_len : state->start_oid_len; + + /* check passed OID is located behind start offset */ + if (snmp_oid_compare(oid, oid_len, state->start_oid, start_oid_len) >= 0) { + /* check if new oid is located closer to start oid than current closest oid */ + if ((state->status == SNMP_NEXT_OID_STATUS_NO_MATCH) || + (snmp_oid_compare(oid, oid_len, state->next_oid, state->next_oid_len) < 0)) { + return 1; + } + } + } + + return 0; +} + +/** checks the passed OID if it is a candidate to be the next one (get_next); returns !=0 if passed oid is currently closest, otherwise 0 */ +u8_t +snmp_next_oid_check(struct snmp_next_oid_state *state, const u32_t *oid, const u8_t oid_len, void* reference) +{ + /* do not overwrite a fail result */ + if (state->status != SNMP_NEXT_OID_STATUS_BUF_TO_SMALL) { + /* check passed OID is located behind start offset */ + if (snmp_oid_compare(oid, oid_len, state->start_oid, state->start_oid_len) > 0) { + /* check if new oid is located closer to start oid than current closest oid */ + if ((state->status == SNMP_NEXT_OID_STATUS_NO_MATCH) || + (snmp_oid_compare(oid, oid_len, state->next_oid, state->next_oid_len) < 0)) { + if (oid_len <= state->next_oid_max_len) { + MEMCPY(state->next_oid, oid, oid_len * sizeof(u32_t)); + state->next_oid_len = oid_len; + state->status = SNMP_NEXT_OID_STATUS_SUCCESS; + state->reference = reference; + return 1; + } else { + state->status = SNMP_NEXT_OID_STATUS_BUF_TO_SMALL; + } + } + } + } + + return 0; +} + +u8_t +snmp_oid_in_range(const u32_t *oid_in, u8_t oid_len, const struct snmp_oid_range *oid_ranges, u8_t oid_ranges_len) +{ + u8_t i; + + if (oid_len != oid_ranges_len) { + return 0; + } + + for (i = 0; i < oid_ranges_len; i++) { + if ((oid_in[i] < oid_ranges[i].min) || (oid_in[i] > oid_ranges[i].max)) { + return 0; + } + } + + return 1; +} + +snmp_err_t +snmp_set_test_ok(struct snmp_node_instance* instance, u16_t value_len, void* value) +{ + LWIP_UNUSED_ARG(instance); + LWIP_UNUSED_ARG(value_len); + LWIP_UNUSED_ARG(value); + + return SNMP_ERR_NOERROR; +} + +/** + * Decodes BITS pseudotype value from ASN.1 OctetString. + * + * @note Because BITS pseudo type is encoded as OCTET STRING, it cannot directly + * be encoded/decoded by the agent. Instead call this function as required from + * get/test/set methods. + * + * @param buf points to a buffer holding the ASN1 octet string + * @param buf_len length of octet string + * @param bit_value decoded Bit value with Bit0 == LSB + * @return ERR_OK if successful, ERR_ARG if bit value contains more than 32 bit + */ +err_t +snmp_decode_bits(const u8_t *buf, u32_t buf_len, u32_t *bit_value) +{ + u8_t b; + u8_t bits_processed = 0; + *bit_value = 0; + + while (buf_len > 0) { + /* any bit set in this byte? */ + if (*buf != 0x00) { + if (bits_processed >= 32) { + /* accept more than 4 bytes, but only when no bits are set */ + return ERR_VAL; + } + + b = *buf; + do { + if (b & 0x80) { + *bit_value |= (1 << bits_processed); + } + bits_processed++; + b <<= 1; + } + while ((bits_processed & 0x07) != 0); /* &0x07 -> % 8 */ + } else { + bits_processed += 8; + } + + buf_len--; + buf++; + } + + return ERR_OK; +} + +err_t +snmp_decode_truthvalue(const s32_t *asn1_value, u8_t *bool_value) +{ + /* defined by RFC1443: + TruthValue ::= TEXTUAL-CONVENTION + STATUS current + DESCRIPTION + "Represents a boolean value." + SYNTAX INTEGER { true(1), false(2) } + */ + + if ((asn1_value == NULL) || (bool_value == NULL)) { + return ERR_ARG; + } + + if (*asn1_value == 1) { + *bool_value = 1; + } else if (*asn1_value == 2) { + *bool_value = 0; + } else { + return ERR_VAL; + } + + return ERR_OK; +} + +/** + * Encodes BITS pseudotype value into ASN.1 OctetString. + * + * @note Because BITS pseudo type is encoded as OCTET STRING, it cannot directly + * be encoded/decoded by the agent. Instead call this function as required from + * get/test/set methods. + * + * @param buf points to a buffer where the resulting ASN1 octet string is stored to + * @param buf_len max length of the bufffer + * @param bit_value Bit value to encode with Bit0 == LSB + * @param bit_count Number of possible bits for the bit value (according to rfc we have to send all bits independant from their truth value) + * @return number of bytes used from buffer to store the resulting OctetString + */ +u8_t +snmp_encode_bits(u8_t *buf, u32_t buf_len, u32_t bit_value, u8_t bit_count) +{ + u8_t len = 0; + u8_t min_bytes = (bit_count + 7) >> 3; /* >>3 -> / 8 */ + + while ((buf_len > 0) && (bit_value != 0x00)) { + s8_t i = 7; + *buf = 0x00; + while (i >= 0) { + if (bit_value & 0x01) { + *buf |= 0x01; + } + + if (i > 0) { + *buf <<= 1; + } + + bit_value >>= 1; + i--; + } + + buf++; + buf_len--; + len++; + } + + if (len < min_bytes) { + buf += len; + buf_len -= len; + + while ((len < min_bytes) && (buf_len > 0)) { + *buf = 0x00; + buf++; + buf_len--; + len++; + } + } + + return len; +} + +u8_t +snmp_encode_truthvalue(s32_t *asn1_value, u32_t bool_value) +{ + /* defined by RFC1443: + TruthValue ::= TEXTUAL-CONVENTION + STATUS current + DESCRIPTION + "Represents a boolean value." + SYNTAX INTEGER { true(1), false(2) } + */ + + if (asn1_value == NULL) { + return 0; + } + + if (bool_value) { + *asn1_value = 1; /* defined by RFC1443 */ + } else { + *asn1_value = 2; /* defined by RFC1443 */ + } + + return sizeof(s32_t); +} + +#endif /* LWIP_SNMP */ |