/* * libunbound/context.c - validating context for unbound internal use * * Copyright (c) 2007, NLnet Labs. All rights reserved. * * This software is open source. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 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. * * Neither the name of the NLNET LABS nor the names of its contributors may * be used to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "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 COPYRIGHT * HOLDER OR CONTRIBUTORS 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. */ /** * \file * * This file contains the validator context structure. */ #include "config.h" #include "libunbound/context.h" #include "util/module.h" #include "util/config_file.h" #include "util/net_help.h" #include "services/modstack.h" #include "services/localzone.h" #include "services/cache/rrset.h" #include "services/cache/infra.h" #include "services/authzone.h" #include "services/listen_dnsport.h" #include "util/data/msgreply.h" #include "util/storage/slabhash.h" #include "util/edns.h" #include "sldns/sbuffer.h" #include "iterator/iter_fwd.h" #include "iterator/iter_hints.h" int context_finalize(struct ub_ctx* ctx) { int is_rpz = 0; struct config_file* cfg = ctx->env->cfg; verbosity = cfg->verbosity; if(ctx_logfile_overridden && !ctx->logfile_override) { log_file(NULL); /* clear that override */ ctx_logfile_overridden = 0; } if(ctx->logfile_override) { ctx_logfile_overridden = 1; log_file(ctx->log_out); } else { log_init(cfg->logfile, cfg->use_syslog, NULL); } ctx->pipe_pid = getpid(); cfg_apply_local_port_policy(cfg, 65536); config_apply(cfg); if(!modstack_call_startup(&ctx->mods, cfg->module_conf, ctx->env)) return UB_INITFAIL; if(!modstack_call_init(&ctx->mods, cfg->module_conf, ctx->env)) return UB_INITFAIL; listen_setup_locks(); log_edns_known_options(VERB_ALGO, ctx->env); ctx->local_zones = local_zones_create(); if(!ctx->local_zones) return UB_NOMEM; if(!local_zones_apply_cfg(ctx->local_zones, cfg)) return UB_INITFAIL; if(!auth_zones_apply_cfg(ctx->env->auth_zones, cfg, 1, &is_rpz, ctx->env, &ctx->mods)) return UB_INITFAIL; if(!(ctx->env->fwds = forwards_create()) || !forwards_apply_cfg(ctx->env->fwds, cfg)) return UB_INITFAIL; if(!(ctx->env->hints = hints_create()) || !hints_apply_cfg(ctx->env->hints, cfg)) return UB_INITFAIL; if(!edns_strings_apply_cfg(ctx->env->edns_strings, cfg)) return UB_INITFAIL; if(!slabhash_is_size(ctx->env->msg_cache, cfg->msg_cache_size, cfg->msg_cache_slabs)) { slabhash_delete(ctx->env->msg_cache); ctx->env->msg_cache = slabhash_create(cfg->msg_cache_slabs, HASH_DEFAULT_STARTARRAY, cfg->msg_cache_size, msgreply_sizefunc, query_info_compare, query_entry_delete, reply_info_delete, NULL); if(!ctx->env->msg_cache) return UB_NOMEM; } ctx->env->rrset_cache = rrset_cache_adjust(ctx->env->rrset_cache, ctx->env->cfg, ctx->env->alloc); if(!ctx->env->rrset_cache) return UB_NOMEM; ctx->env->infra_cache = infra_adjust(ctx->env->infra_cache, cfg); if(!ctx->env->infra_cache) return UB_NOMEM; ctx->finalized = 1; return UB_NOERROR; } int context_query_cmp(const void* a, const void* b) { if( *(int*)a < *(int*)b ) return -1; if( *(int*)a > *(int*)b ) return 1; return 0; } void context_query_delete(struct ctx_query* q) { if(!q) return; ub_resolve_free(q->res); free(q->msg); free(q); } /** How many times to try to find an unused query-id-number for async */ #define NUM_ID_TRIES 100000 /** find next useful id number of 0 on error */ static int find_id(struct ub_ctx* ctx, int* id) { size_t tries = 0; ctx->next_querynum++; while(rbtree_search(&ctx->queries, &ctx->next_querynum)) { ctx->next_querynum++; /* numerical wraparound is fine */ if(tries++ > NUM_ID_TRIES) return 0; } *id = ctx->next_querynum; return 1; } struct ctx_query* context_new(struct ub_ctx* ctx, const char* name, int rrtype, int rrclass, ub_callback_type cb, ub_event_callback_type cb_event, void* cbarg) { struct ctx_query* q = (struct ctx_query*)calloc(1, sizeof(*q)); if(!q) return NULL; lock_basic_lock(&ctx->cfglock); if(!find_id(ctx, &q->querynum)) { lock_basic_unlock(&ctx->cfglock); free(q); return NULL; } lock_basic_unlock(&ctx->cfglock); q->node.key = &q->querynum; q->async = (cb != NULL || cb_event != NULL); q->cb = cb; q->cb_event = cb_event; q->cb_arg = cbarg; q->res = (struct ub_result*)calloc(1, sizeof(*q->res)); if(!q->res) { free(q); return NULL; } q->res->qname = strdup(name); if(!q->res->qname) { free(q->res); free(q); return NULL; } q->res->qtype = rrtype; q->res->qclass = rrclass; /* add to query list */ lock_basic_lock(&ctx->cfglock); if(q->async) ctx->num_async ++; (void)rbtree_insert(&ctx->queries, &q->node); lock_basic_unlock(&ctx->cfglock); return q; } struct alloc_cache* context_obtain_alloc(struct ub_ctx* ctx, int locking) { struct alloc_cache* a; int tnum = 0; if(locking) { lock_basic_lock(&ctx->cfglock); } a = ctx->alloc_list; if(a) ctx->alloc_list = a->super; /* snip off list */ else tnum = ctx->thr_next_num++; if(locking) { lock_basic_unlock(&ctx->cfglock); } if(a) { a->super = &ctx->superalloc; return a; } a = (struct alloc_cache*)calloc(1, sizeof(*a)); if(!a) return NULL; alloc_init(a, &ctx->superalloc, tnum); return a; } void context_release_alloc(struct ub_ctx* ctx, struct alloc_cache* alloc, int locking) { if(!ctx || !alloc) return; if(locking) { lock_basic_lock(&ctx->cfglock); } alloc->super = ctx->alloc_list; ctx->alloc_list = alloc; if(locking) { lock_basic_unlock(&ctx->cfglock); } } uint8_t* context_serialize_new_query(struct ctx_query* q, uint32_t* len) { /* format for new query is * o uint32 cmd * o uint32 id * o uint32 type * o uint32 class * o rest queryname (string) */ uint8_t* p; size_t slen = strlen(q->res->qname) + 1/*end of string*/; *len = sizeof(uint32_t)*4 + slen; p = (uint8_t*)malloc(*len); if(!p) return NULL; sldns_write_uint32(p, UB_LIBCMD_NEWQUERY); sldns_write_uint32(p+sizeof(uint32_t), (uint32_t)q->querynum); sldns_write_uint32(p+2*sizeof(uint32_t), (uint32_t)q->res->qtype); sldns_write_uint32(p+3*sizeof(uint32_t), (uint32_t)q->res->qclass); memmove(p+4*sizeof(uint32_t), q->res->qname, slen); return p; } struct ctx_query* context_deserialize_new_query(struct ub_ctx* ctx, uint8_t* p, uint32_t len) { struct ctx_query* q = (struct ctx_query*)calloc(1, sizeof(*q)); if(!q) return NULL; if(len < 4*sizeof(uint32_t)+1) { free(q); return NULL; } log_assert( sldns_read_uint32(p) == UB_LIBCMD_NEWQUERY); q->querynum = (int)sldns_read_uint32(p+sizeof(uint32_t)); q->node.key = &q->querynum; q->async = 1; q->res = (struct ub_result*)calloc(1, sizeof(*q->res)); if(!q->res) { free(q); return NULL; } q->res->qtype = (int)sldns_read_uint32(p+2*sizeof(uint32_t)); q->res->qclass = (int)sldns_read_uint32(p+3*sizeof(uint32_t)); q->res->qname = strdup((char*)(p+4*sizeof(uint32_t))); if(!q->res->qname) { free(q->res); free(q); return NULL; } /** add to query list */ ctx->num_async++; (void)rbtree_insert(&ctx->queries, &q->node); return q; } struct ctx_query* context_lookup_new_query(struct ub_ctx* ctx, uint8_t* p, uint32_t len) { struct ctx_query* q; int querynum; if(len < 4*sizeof(uint32_t)+1) { return NULL; } log_assert( sldns_read_uint32(p) == UB_LIBCMD_NEWQUERY); querynum = (int)sldns_read_uint32(p+sizeof(uint32_t)); q = (struct ctx_query*)rbtree_search(&ctx->queries, &querynum); if(!q) { return NULL; } log_assert(q->async); return q; } uint8_t* context_serialize_answer(struct ctx_query* q, int err, sldns_buffer* pkt, uint32_t* len) { /* answer format * o uint32 cmd * o uint32 id * o uint32 error_code * o uint32 msg_security * o uint32 was_ratelimited * o uint32 length of why_bogus string (+1 for eos); 0 absent. * o why_bogus_string * o the remainder is the answer msg from resolver lookup. * remainder can be length 0. */ size_t size_of_uint32s = 6 * sizeof(uint32_t); size_t pkt_len = pkt?sldns_buffer_remaining(pkt):0; size_t wlen = (pkt&&q->res->why_bogus)?strlen(q->res->why_bogus)+1:0; uint8_t* p; *len = size_of_uint32s + pkt_len + wlen; p = (uint8_t*)malloc(*len); if(!p) return NULL; sldns_write_uint32(p, UB_LIBCMD_ANSWER); sldns_write_uint32(p+sizeof(uint32_t), (uint32_t)q->querynum); sldns_write_uint32(p+2*sizeof(uint32_t), (uint32_t)err); sldns_write_uint32(p+3*sizeof(uint32_t), (uint32_t)q->msg_security); sldns_write_uint32(p+4*sizeof(uint32_t), (uint32_t)q->res->was_ratelimited); sldns_write_uint32(p+5*sizeof(uint32_t), (uint32_t)wlen); if(wlen > 0) memmove(p+size_of_uint32s, q->res->why_bogus, wlen); if(pkt_len > 0) memmove(p+size_of_uint32s+wlen, sldns_buffer_begin(pkt), pkt_len); return p; } struct ctx_query* context_deserialize_answer(struct ub_ctx* ctx, uint8_t* p, uint32_t len, int* err) { size_t size_of_uint32s = 6 * sizeof(uint32_t); struct ctx_query* q = NULL ; int id; size_t wlen; if(len < size_of_uint32s) return NULL; log_assert( sldns_read_uint32(p) == UB_LIBCMD_ANSWER); id = (int)sldns_read_uint32(p+sizeof(uint32_t)); q = (struct ctx_query*)rbtree_search(&ctx->queries, &id); if(!q) return NULL; *err = (int)sldns_read_uint32(p+2*sizeof(uint32_t)); q->msg_security = sldns_read_uint32(p+3*sizeof(uint32_t)); q->res->was_ratelimited = (int)sldns_read_uint32(p+4*sizeof(uint32_t)); wlen = (size_t)sldns_read_uint32(p+5*sizeof(uint32_t)); if(len > size_of_uint32s && wlen > 0) { if(len >= size_of_uint32s+wlen) q->res->why_bogus = (char*)memdup( p+size_of_uint32s, wlen); if(!q->res->why_bogus) { /* pass malloc failure to the user callback */ q->msg_len = 0; *err = UB_NOMEM; return q; } q->res->why_bogus[wlen-1] = 0; /* zero terminated for sure */ } if(len > size_of_uint32s+wlen) { q->msg_len = len - size_of_uint32s - wlen; q->msg = (uint8_t*)memdup(p+size_of_uint32s+wlen, q->msg_len); if(!q->msg) { /* pass malloc failure to the user callback */ q->msg_len = 0; *err = UB_NOMEM; return q; } } return q; } uint8_t* context_serialize_cancel(struct ctx_query* q, uint32_t* len) { /* format of cancel: * o uint32 cmd * o uint32 async-id */ uint8_t* p = (uint8_t*)reallocarray(NULL, 2, sizeof(uint32_t)); if(!p) return NULL; *len = 2*sizeof(uint32_t); sldns_write_uint32(p, UB_LIBCMD_CANCEL); sldns_write_uint32(p+sizeof(uint32_t), (uint32_t)q->querynum); return p; } struct ctx_query* context_deserialize_cancel(struct ub_ctx* ctx, uint8_t* p, uint32_t len) { struct ctx_query* q; int id; if(len != 2*sizeof(uint32_t)) return NULL; log_assert( sldns_read_uint32(p) == UB_LIBCMD_CANCEL); id = (int)sldns_read_uint32(p+sizeof(uint32_t)); q = (struct ctx_query*)rbtree_search(&ctx->queries, &id); return q; } uint8_t* context_serialize_quit(uint32_t* len) { uint32_t* p = (uint32_t*)malloc(sizeof(uint32_t)); if(!p) return NULL; *len = sizeof(uint32_t); sldns_write_uint32(p, UB_LIBCMD_QUIT); return (uint8_t*)p; } enum ub_ctx_cmd context_serial_getcmd(uint8_t* p, uint32_t len) { uint32_t v; if((size_t)len < sizeof(v)) return UB_LIBCMD_QUIT; v = sldns_read_uint32(p); return v; }