delta param
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core/snmp/mib_structs.c
- Committer:
- klauss
- Date:
- 2015-01-08
- Revision:
- 29:da6f39d13880
- Parent:
- 0:51ac1d130fd4
File content as of revision 29:da6f39d13880:
/** * @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> */ #include "lwip/opt.h" #if LWIP_SNMP /* don't build if not configured for use in lwipopts.h */ #include "lwip/snmp_structs.h" #include "lwip/memp.h" #include "lwip/netif.h" /** .iso.org.dod.internet address prefix, @see snmp_iso_*() */ const s32_t prefix[4] = {1, 3, 6, 1}; #define NODE_STACK_SIZE (LWIP_SNMP_OBJ_ID_LEN) /** node stack entry (old news?) */ struct nse { /** right child */ struct mib_node* r_ptr; /** right child identifier */ s32_t r_id; /** right child next level */ u8_t r_nl; }; static u8_t node_stack_cnt; static struct nse node_stack[NODE_STACK_SIZE]; /** * Pushes nse struct onto stack. */ static void push_node(struct nse* node) { LWIP_ASSERT("node_stack_cnt < NODE_STACK_SIZE",node_stack_cnt < NODE_STACK_SIZE); LWIP_DEBUGF(SNMP_MIB_DEBUG,("push_node() node=%p id=%"S32_F"\n",(void*)(node->r_ptr),node->r_id)); if (node_stack_cnt < NODE_STACK_SIZE) { node_stack[node_stack_cnt] = *node; node_stack_cnt++; } } /** * Pops nse struct from stack. */ static void pop_node(struct nse* node) { if (node_stack_cnt > 0) { node_stack_cnt--; *node = node_stack[node_stack_cnt]; } LWIP_DEBUGF(SNMP_MIB_DEBUG,("pop_node() node=%p id=%"S32_F"\n",(void *)(node->r_ptr),node->r_id)); } /** * Conversion from ifIndex to lwIP netif * @param ifindex is a s32_t object sub-identifier * @param netif points to returned netif struct pointer */ void snmp_ifindextonetif(s32_t ifindex, struct netif **netif) { struct netif *nif = netif_list; s32_t i, ifidx; ifidx = ifindex - 1; i = 0; while ((nif != NULL) && (i < ifidx)) { nif = nif->next; i++; } *netif = nif; } /** * Conversion from lwIP netif to ifIndex * @param netif points to a netif struct * @param ifidx points to s32_t object sub-identifier */ void snmp_netiftoifindex(struct netif *netif, s32_t *ifidx) { struct netif *nif = netif_list; u16_t i; i = 0; while ((nif != NULL) && (nif != netif)) { nif = nif->next; i++; } *ifidx = i+1; } /** * Conversion from oid to lwIP ip_addr * @param ident points to s32_t ident[4] input * @param ip points to output struct */ void snmp_oidtoip(s32_t *ident, ip_addr_t *ip) { IP4_ADDR(ip, ident[0], ident[1], ident[2], ident[3]); } /** * Conversion from lwIP ip_addr to oid * @param ip points to input struct * @param ident points to s32_t ident[4] output */ void snmp_iptooid(ip_addr_t *ip, s32_t *ident) { ident[0] = ip4_addr1(ip); ident[1] = ip4_addr2(ip); ident[2] = ip4_addr3(ip); ident[3] = ip4_addr4(ip); } struct mib_list_node * snmp_mib_ln_alloc(s32_t id) { struct mib_list_node *ln; ln = (struct mib_list_node *)memp_malloc(MEMP_SNMP_NODE); if (ln != NULL) { ln->prev = NULL; ln->next = NULL; ln->objid = id; ln->nptr = NULL; } return ln; } void snmp_mib_ln_free(struct mib_list_node *ln) { memp_free(MEMP_SNMP_NODE, ln); } struct mib_list_rootnode * snmp_mib_lrn_alloc(void) { struct mib_list_rootnode *lrn; lrn = (struct mib_list_rootnode*)memp_malloc(MEMP_SNMP_ROOTNODE); if (lrn != NULL) { lrn->get_object_def = noleafs_get_object_def; lrn->get_value = noleafs_get_value; lrn->set_test = noleafs_set_test; lrn->set_value = noleafs_set_value; lrn->node_type = MIB_NODE_LR; lrn->maxlength = 0; lrn->head = NULL; lrn->tail = NULL; lrn->count = 0; } return lrn; } void snmp_mib_lrn_free(struct mib_list_rootnode *lrn) { memp_free(MEMP_SNMP_ROOTNODE, lrn); } /** * Inserts node in idx list in a sorted * (ascending order) fashion and * allocates the node if needed. * * @param rn points to the root node * @param objid is the object sub identifier * @param insn points to a pointer to the inserted node * used for constructing the tree. * @return -1 if failed, 1 if inserted, 2 if present. */ s8_t snmp_mib_node_insert(struct mib_list_rootnode *rn, s32_t objid, struct mib_list_node **insn) { struct mib_list_node *nn; s8_t insert; LWIP_ASSERT("rn != NULL",rn != NULL); /* -1 = malloc failure, 0 = not inserted, 1 = inserted, 2 = was present */ insert = 0; if (rn->head == NULL) { /* empty list, add first node */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("alloc empty list objid==%"S32_F"\n",objid)); nn = snmp_mib_ln_alloc(objid); if (nn != NULL) { rn->head = nn; rn->tail = nn; *insn = nn; insert = 1; } else { insert = -1; } } else { struct mib_list_node *n; /* at least one node is present */ n = rn->head; while ((n != NULL) && (insert == 0)) { if (n->objid == objid) { /* node is already there */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("node already there objid==%"S32_F"\n",objid)); *insn = n; insert = 2; } else if (n->objid < objid) { if (n->next == NULL) { /* alloc and insert at the tail */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("alloc ins tail objid==%"S32_F"\n",objid)); nn = snmp_mib_ln_alloc(objid); if (nn != NULL) { nn->next = NULL; nn->prev = n; n->next = nn; rn->tail = nn; *insn = nn; insert = 1; } else { /* insertion failure */ insert = -1; } } else { /* there's more to explore: traverse list */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("traverse list\n")); n = n->next; } } else { /* n->objid > objid */ /* alloc and insert between n->prev and n */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("alloc ins n->prev, objid==%"S32_F", n\n",objid)); nn = snmp_mib_ln_alloc(objid); if (nn != NULL) { if (n->prev == NULL) { /* insert at the head */ nn->next = n; nn->prev = NULL; rn->head = nn; n->prev = nn; } else { /* insert in the middle */ nn->next = n; nn->prev = n->prev; n->prev->next = nn; n->prev = nn; } *insn = nn; insert = 1; } else { /* insertion failure */ insert = -1; } } } } if (insert == 1) { rn->count += 1; } LWIP_ASSERT("insert != 0",insert != 0); return insert; } /** * Finds node in idx list and returns deletion mark. * * @param rn points to the root node * @param objid is the object sub identifier * @param fn returns pointer to found node * @return 0 if not found, 1 if deletable, * 2 can't delete (2 or more children), 3 not a list_node */ s8_t snmp_mib_node_find(struct mib_list_rootnode *rn, s32_t objid, struct mib_list_node **fn) { s8_t fc; struct mib_list_node *n; LWIP_ASSERT("rn != NULL",rn != NULL); n = rn->head; while ((n != NULL) && (n->objid != objid)) { n = n->next; } if (n == NULL) { fc = 0; } else if (n->nptr == NULL) { /* leaf, can delete node */ fc = 1; } else { struct mib_list_rootnode *r; if (n->nptr->node_type == MIB_NODE_LR) { r = (struct mib_list_rootnode *)n->nptr; if (r->count > 1) { /* can't delete node */ fc = 2; } else { /* count <= 1, can delete node */ fc = 1; } } else { /* other node type */ fc = 3; } } *fn = n; return fc; } /** * Removes node from idx list * if it has a single child left. * * @param rn points to the root node * @param n points to the node to delete * @return the nptr to be freed by caller */ struct mib_list_rootnode * snmp_mib_node_delete(struct mib_list_rootnode *rn, struct mib_list_node *n) { struct mib_list_rootnode *next; LWIP_ASSERT("rn != NULL",rn != NULL); LWIP_ASSERT("n != NULL",n != NULL); /* caller must remove this sub-tree */ next = (struct mib_list_rootnode*)(n->nptr); rn->count -= 1; if (n == rn->head) { rn->head = n->next; if (n->next != NULL) { /* not last node, new list begin */ n->next->prev = NULL; } } else if (n == rn->tail) { rn->tail = n->prev; if (n->prev != NULL) { /* not last node, new list end */ n->prev->next = NULL; } } else { /* node must be in the middle */ n->prev->next = n->next; n->next->prev = n->prev; } LWIP_DEBUGF(SNMP_MIB_DEBUG,("free list objid==%"S32_F"\n",n->objid)); snmp_mib_ln_free(n); if (rn->count == 0) { rn->head = NULL; rn->tail = NULL; } return next; } /** * Searches tree for the supplied (scalar?) object identifier. * * @param node points to the root of the tree ('.internet') * @param ident_len the length of the supplied object identifier * @param ident points to the array of sub identifiers * @param np points to the found object instance (return) * @return pointer to the requested parent (!) node if success, NULL otherwise */ struct mib_node * snmp_search_tree(struct mib_node *node, u8_t ident_len, s32_t *ident, struct snmp_name_ptr *np) { u8_t node_type, ext_level; ext_level = 0; LWIP_DEBUGF(SNMP_MIB_DEBUG,("node==%p *ident==%"S32_F"\n",(void*)node,*ident)); while (node != NULL) { node_type = node->node_type; if ((node_type == MIB_NODE_AR) || (node_type == MIB_NODE_RA)) { struct mib_array_node *an; u16_t i; if (ident_len > 0) { /* array node (internal ROM or RAM, fixed length) */ an = (struct mib_array_node *)node; i = 0; while ((i < an->maxlength) && (an->objid[i] != *ident)) { i++; } if (i < an->maxlength) { /* found it, if available proceed to child, otherwise inspect leaf */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("an->objid[%"U16_F"]==%"S32_F" *ident==%"S32_F"\n",i,an->objid[i],*ident)); if (an->nptr[i] == NULL) { /* a scalar leaf OR table, inspect remaining instance number / table index */ np->ident_len = ident_len; np->ident = ident; return (struct mib_node*)an; } else { /* follow next child pointer */ ident++; ident_len--; node = an->nptr[i]; } } else { /* search failed, identifier mismatch (nosuchname) */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("an search failed *ident==%"S32_F"\n",*ident)); return NULL; } } else { /* search failed, short object identifier (nosuchname) */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("an search failed, short object identifier\n")); return NULL; } } else if(node_type == MIB_NODE_LR) { struct mib_list_rootnode *lrn; struct mib_list_node *ln; if (ident_len > 0) { /* list root node (internal 'RAM', variable length) */ lrn = (struct mib_list_rootnode *)node; ln = lrn->head; /* iterate over list, head to tail */ while ((ln != NULL) && (ln->objid != *ident)) { ln = ln->next; } if (ln != NULL) { /* found it, proceed to child */; LWIP_DEBUGF(SNMP_MIB_DEBUG,("ln->objid==%"S32_F" *ident==%"S32_F"\n",ln->objid,*ident)); if (ln->nptr == NULL) { np->ident_len = ident_len; np->ident = ident; return (struct mib_node*)lrn; } else { /* follow next child pointer */ ident_len--; ident++; node = ln->nptr; } } else { /* search failed */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("ln search failed *ident==%"S32_F"\n",*ident)); return NULL; } } else { /* search failed, short object identifier (nosuchname) */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("ln search failed, short object identifier\n")); return NULL; } } else if(node_type == MIB_NODE_EX) { struct mib_external_node *en; u16_t i, len; if (ident_len > 0) { /* external node (addressing and access via functions) */ en = (struct mib_external_node *)node; i = 0; len = en->level_length(en->addr_inf,ext_level); while ((i < len) && (en->ident_cmp(en->addr_inf,ext_level,i,*ident) != 0)) { i++; } if (i < len) { s32_t debug_id; en->get_objid(en->addr_inf,ext_level,i,&debug_id); LWIP_DEBUGF(SNMP_MIB_DEBUG,("en->objid==%"S32_F" *ident==%"S32_F"\n",debug_id,*ident)); if ((ext_level + 1) == en->tree_levels) { np->ident_len = ident_len; np->ident = ident; return (struct mib_node*)en; } else { /* found it, proceed to child */ ident_len--; ident++; ext_level++; } } else { /* search failed */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("en search failed *ident==%"S32_F"\n",*ident)); return NULL; } } else { /* search failed, short object identifier (nosuchname) */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("en search failed, short object identifier\n")); return NULL; } } else if (node_type == MIB_NODE_SC) { mib_scalar_node *sn; sn = (mib_scalar_node *)node; if ((ident_len == 1) && (*ident == 0)) { np->ident_len = ident_len; np->ident = ident; return (struct mib_node*)sn; } else { /* search failed, short object identifier (nosuchname) */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("search failed, invalid object identifier length\n")); return NULL; } } else { /* unknown node_type */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("search failed node_type %"U16_F" unkown\n",(u16_t)node_type)); return NULL; } } /* done, found nothing */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("search failed node==%p\n",(void*)node)); return NULL; } /** * Test table for presence of at least one table entry. */ static u8_t empty_table(struct mib_node *node) { u8_t node_type; u8_t empty = 0; if (node != NULL) { node_type = node->node_type; if (node_type == MIB_NODE_LR) { struct mib_list_rootnode *lrn; lrn = (struct mib_list_rootnode *)node; if ((lrn->count == 0) || (lrn->head == NULL)) { empty = 1; } } else if ((node_type == MIB_NODE_AR) || (node_type == MIB_NODE_RA)) { struct mib_array_node *an; an = (struct mib_array_node *)node; if ((an->maxlength == 0) || (an->nptr == NULL)) { empty = 1; } } else if (node_type == MIB_NODE_EX) { struct mib_external_node *en; en = (struct mib_external_node *)node; if (en->tree_levels == 0) { empty = 1; } } } return empty; } /** * Tree expansion. */ struct mib_node * snmp_expand_tree(struct mib_node *node, u8_t ident_len, s32_t *ident, struct snmp_obj_id *oidret) { u8_t node_type, ext_level, climb_tree; ext_level = 0; /* reset node stack */ node_stack_cnt = 0; while (node != NULL) { climb_tree = 0; node_type = node->node_type; if ((node_type == MIB_NODE_AR) || (node_type == MIB_NODE_RA)) { struct mib_array_node *an; u16_t i; /* array node (internal ROM or RAM, fixed length) */ an = (struct mib_array_node *)node; if (ident_len > 0) { i = 0; while ((i < an->maxlength) && (an->objid[i] < *ident)) { i++; } if (i < an->maxlength) { LWIP_DEBUGF(SNMP_MIB_DEBUG,("an->objid[%"U16_F"]==%"S32_F" *ident==%"S32_F"\n",i,an->objid[i],*ident)); /* add identifier to oidret */ oidret->id[oidret->len] = an->objid[i]; (oidret->len)++; if (an->nptr[i] == NULL) { LWIP_DEBUGF(SNMP_MIB_DEBUG,("leaf node\n")); /* leaf node (e.g. in a fixed size table) */ if (an->objid[i] > *ident) { return (struct mib_node*)an; } else if ((i + 1) < an->maxlength) { /* an->objid[i] == *ident */ (oidret->len)--; oidret->id[oidret->len] = an->objid[i + 1]; (oidret->len)++; return (struct mib_node*)an; } else { /* (i + 1) == an->maxlength */ (oidret->len)--; climb_tree = 1; } } else { u8_t j; struct nse cur_node; LWIP_DEBUGF(SNMP_MIB_DEBUG,("non-leaf node\n")); /* non-leaf, store right child ptr and id */ LWIP_ASSERT("i < 0xff", i < 0xff); j = (u8_t)i + 1; while ((j < an->maxlength) && (empty_table(an->nptr[j]))) { j++; } if (j < an->maxlength) { cur_node.r_ptr = an->nptr[j]; cur_node.r_id = an->objid[j]; cur_node.r_nl = 0; } else { cur_node.r_ptr = NULL; } push_node(&cur_node); if (an->objid[i] == *ident) { ident_len--; ident++; } else { /* an->objid[i] < *ident */ ident_len = 0; } /* follow next child pointer */ node = an->nptr[i]; } } else { /* i == an->maxlength */ climb_tree = 1; } } else { u8_t j; /* ident_len == 0, complete with leftmost '.thing' */ j = 0; while ((j < an->maxlength) && empty_table(an->nptr[j])) { j++; } if (j < an->maxlength) { LWIP_DEBUGF(SNMP_MIB_DEBUG,("left an->objid[j]==%"S32_F"\n",an->objid[j])); oidret->id[oidret->len] = an->objid[j]; (oidret->len)++; if (an->nptr[j] == NULL) { /* leaf node */ return (struct mib_node*)an; } else { /* no leaf, continue */ node = an->nptr[j]; } } else { /* j == an->maxlength */ climb_tree = 1; } } } else if(node_type == MIB_NODE_LR) { struct mib_list_rootnode *lrn; struct mib_list_node *ln; /* list root node (internal 'RAM', variable length) */ lrn = (struct mib_list_rootnode *)node; if (ident_len > 0) { ln = lrn->head; /* iterate over list, head to tail */ while ((ln != NULL) && (ln->objid < *ident)) { ln = ln->next; } if (ln != NULL) { LWIP_DEBUGF(SNMP_MIB_DEBUG,("ln->objid==%"S32_F" *ident==%"S32_F"\n",ln->objid,*ident)); oidret->id[oidret->len] = ln->objid; (oidret->len)++; if (ln->nptr == NULL) { /* leaf node */ if (ln->objid > *ident) { return (struct mib_node*)lrn; } else if (ln->next != NULL) { /* ln->objid == *ident */ (oidret->len)--; oidret->id[oidret->len] = ln->next->objid; (oidret->len)++; return (struct mib_node*)lrn; } else { /* ln->next == NULL */ (oidret->len)--; climb_tree = 1; } } else { struct mib_list_node *jn; struct nse cur_node; /* non-leaf, store right child ptr and id */ jn = ln->next; while ((jn != NULL) && empty_table(jn->nptr)) { jn = jn->next; } if (jn != NULL) { cur_node.r_ptr = jn->nptr; cur_node.r_id = jn->objid; cur_node.r_nl = 0; } else { cur_node.r_ptr = NULL; } push_node(&cur_node); if (ln->objid == *ident) { ident_len--; ident++; } else { /* ln->objid < *ident */ ident_len = 0; } /* follow next child pointer */ node = ln->nptr; } } else { /* ln == NULL */ climb_tree = 1; } } else { struct mib_list_node *jn; /* ident_len == 0, complete with leftmost '.thing' */ jn = lrn->head; while ((jn != NULL) && empty_table(jn->nptr)) { jn = jn->next; } if (jn != NULL) { LWIP_DEBUGF(SNMP_MIB_DEBUG,("left jn->objid==%"S32_F"\n",jn->objid)); oidret->id[oidret->len] = jn->objid; (oidret->len)++; if (jn->nptr == NULL) { /* leaf node */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("jn->nptr == NULL\n")); return (struct mib_node*)lrn; } else { /* no leaf, continue */ node = jn->nptr; } } else { /* jn == NULL */ climb_tree = 1; } } } else if(node_type == MIB_NODE_EX) { struct mib_external_node *en; s32_t ex_id; /* external node (addressing and access via functions) */ en = (struct mib_external_node *)node; if (ident_len > 0) { u16_t i, len; i = 0; len = en->level_length(en->addr_inf,ext_level); while ((i < len) && (en->ident_cmp(en->addr_inf,ext_level,i,*ident) < 0)) { i++; } if (i < len) { /* add identifier to oidret */ en->get_objid(en->addr_inf,ext_level,i,&ex_id); LWIP_DEBUGF(SNMP_MIB_DEBUG,("en->objid[%"U16_F"]==%"S32_F" *ident==%"S32_F"\n",i,ex_id,*ident)); oidret->id[oidret->len] = ex_id; (oidret->len)++; if ((ext_level + 1) == en->tree_levels) { LWIP_DEBUGF(SNMP_MIB_DEBUG,("leaf node\n")); /* leaf node */ if (ex_id > *ident) { return (struct mib_node*)en; } else if ((i + 1) < len) { /* ex_id == *ident */ en->get_objid(en->addr_inf,ext_level,i + 1,&ex_id); (oidret->len)--; oidret->id[oidret->len] = ex_id; (oidret->len)++; return (struct mib_node*)en; } else { /* (i + 1) == len */ (oidret->len)--; climb_tree = 1; } } else { u8_t j; struct nse cur_node; LWIP_DEBUGF(SNMP_MIB_DEBUG,("non-leaf node\n")); /* non-leaf, store right child ptr and id */ LWIP_ASSERT("i < 0xff", i < 0xff); j = (u8_t)i + 1; if (j < len) { /* right node is the current external node */ cur_node.r_ptr = node; en->get_objid(en->addr_inf,ext_level,j,&cur_node.r_id); cur_node.r_nl = ext_level + 1; } else { cur_node.r_ptr = NULL; } push_node(&cur_node); if (en->ident_cmp(en->addr_inf,ext_level,i,*ident) == 0) { ident_len--; ident++; } else { /* external id < *ident */ ident_len = 0; } /* proceed to child */ ext_level++; } } else { /* i == len (en->level_len()) */ climb_tree = 1; } } else { /* ident_len == 0, complete with leftmost '.thing' */ en->get_objid(en->addr_inf,ext_level,0,&ex_id); LWIP_DEBUGF(SNMP_MIB_DEBUG,("left en->objid==%"S32_F"\n",ex_id)); oidret->id[oidret->len] = ex_id; (oidret->len)++; if ((ext_level + 1) == en->tree_levels) { /* leaf node */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("(ext_level + 1) == en->tree_levels\n")); return (struct mib_node*)en; } else { /* no leaf, proceed to child */ ext_level++; } } } else if(node_type == MIB_NODE_SC) { mib_scalar_node *sn; /* scalar node */ sn = (mib_scalar_node *)node; if (ident_len > 0) { /* at .0 */ climb_tree = 1; } else { /* ident_len == 0, complete object identifier */ oidret->id[oidret->len] = 0; (oidret->len)++; /* leaf node */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("completed scalar leaf\n")); return (struct mib_node*)sn; } } else { /* unknown/unhandled node_type */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("expand failed node_type %"U16_F" unkown\n",(u16_t)node_type)); return NULL; } if (climb_tree) { struct nse child; /* find right child ptr */ child.r_ptr = NULL; child.r_id = 0; child.r_nl = 0; while ((node_stack_cnt > 0) && (child.r_ptr == NULL)) { pop_node(&child); /* trim returned oid */ (oidret->len)--; } if (child.r_ptr != NULL) { /* incoming ident is useless beyond this point */ ident_len = 0; oidret->id[oidret->len] = child.r_id; oidret->len++; node = child.r_ptr; ext_level = child.r_nl; } else { /* tree ends here ... */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("expand failed, tree ends here\n")); return NULL; } } } /* done, found nothing */ LWIP_DEBUGF(SNMP_MIB_DEBUG,("expand failed node==%p\n",(void*)node)); return NULL; } /** * Test object identifier for the iso.org.dod.internet prefix. * * @param ident_len the length of the supplied object identifier * @param ident points to the array of sub identifiers * @return 1 if it matches, 0 otherwise */ u8_t snmp_iso_prefix_tst(u8_t ident_len, s32_t *ident) { if ((ident_len > 3) && (ident[0] == 1) && (ident[1] == 3) && (ident[2] == 6) && (ident[3] == 1)) { return 1; } else { return 0; } } /** * Expands object identifier to the iso.org.dod.internet * prefix for use in getnext operation. * * @param ident_len the length of the supplied object identifier * @param ident points to the array of sub identifiers * @param oidret points to returned expanded object identifier * @return 1 if it matches, 0 otherwise * * @note ident_len 0 is allowed, expanding to the first known object id!! */ u8_t snmp_iso_prefix_expand(u8_t ident_len, s32_t *ident, struct snmp_obj_id *oidret) { const s32_t *prefix_ptr; s32_t *ret_ptr; u8_t i; i = 0; prefix_ptr = &prefix[0]; ret_ptr = &oidret->id[0]; ident_len = ((ident_len < 4)?ident_len:4); while ((i < ident_len) && ((*ident) <= (*prefix_ptr))) { *ret_ptr++ = *prefix_ptr++; ident++; i++; } if (i == ident_len) { /* match, complete missing bits */ while (i < 4) { *ret_ptr++ = *prefix_ptr++; i++; } oidret->len = i; return 1; } else { /* i != ident_len */ return 0; } } #endif /* LWIP_SNMP */