/* * SPDX-License-Identifier: GPL-3.0-or-later * * @file dnstap.c * @brief dnstap based query logging support * */ #include "lib/module.h" #include "lib/layer.h" #include "lib/resolve.h" #include "modules/dnstap/dnstap.pb-c.h" #include #include #include "contrib/cleanup.h" #define DEBUG_MSG(fmt, ...) kr_log_verbose("[dnstap] " fmt, ##__VA_ARGS__); #define CFG_SOCK_PATH "socket_path" #define CFG_IDENTITY_STRING "identity" #define CFG_VERSION_STRING "version" #define CFG_LOG_CLIENT_PKT "client" #define CFG_LOG_QR_PKT "log_queries" #define CFG_LOG_RESP_PKT "log_responses" #define DEFAULT_SOCK_PATH "/tmp/dnstap.sock" #define DNSTAP_CONTENT_TYPE "protobuf:dnstap.Dnstap" #define DNSTAP_INITIAL_BUF_SIZE 256 #define auto_destroy_uopts __attribute__((cleanup(fstrm_unix_writer_options_destroy))) #define auto_destroy_wopts __attribute__((cleanup(fstrm_writer_options_destroy))) /* * Internal processing phase * Distinguishes whether query or response should be processed */ enum dnstap_log_phase { CLIENT_QUERY_PHASE = 0, CLIENT_RESPONSE_PHASE, }; /* Internal data structure */ struct dnstap_data { char *identity; size_t identity_len; char *version; size_t version_len; bool log_qr_pkt; bool log_resp_pkt; struct fstrm_iothr *iothread; struct fstrm_iothr_queue *ioq; }; /* * dt_pack packs the dnstap message for transport * https://gitlab.nic.cz/knot/knot-dns/blob/master/src/contrib/dnstap/dnstap.c#L24 * */ uint8_t* dt_pack(const Dnstap__Dnstap *d, uint8_t **buf, size_t *sz) { ProtobufCBufferSimple sbuf = { { NULL } }; sbuf.base.append = protobuf_c_buffer_simple_append; sbuf.len = 0; sbuf.alloced = DNSTAP_INITIAL_BUF_SIZE; sbuf.data = malloc(sbuf.alloced); if (sbuf.data == NULL) { return NULL; } sbuf.must_free_data = true; *sz = dnstap__dnstap__pack_to_buffer(d, (ProtobufCBuffer *) &sbuf); *buf = sbuf.data; return *buf; } /* set_address fills in address detail in dnstap_message * https://gitlab.nic.cz/knot/knot-dns/blob/master/src/contrib/dnstap/message.c#L28 */ static void set_address(const struct sockaddr *sockaddr, ProtobufCBinaryData *addr, protobuf_c_boolean *has_addr, uint32_t *port, protobuf_c_boolean *has_port) { const char *saddr = kr_inaddr(sockaddr); if (saddr == NULL) { *has_addr = false; *has_port = false; return; } addr->data = (uint8_t *)(saddr); addr->len = kr_inaddr_len(sockaddr); *has_addr = true; *port = kr_inaddr_port(sockaddr); *has_port = true; } /* dnstap_log prepares dnstap message and sends it to fstrm * * Return codes are kr_error(E*) and unused for now. */ static int dnstap_log(kr_layer_t *ctx, enum dnstap_log_phase phase) { const struct kr_request *req = ctx->req; const struct kr_module *module = ctx->api->data; const struct kr_rplan *rplan = &req->rplan; const struct dnstap_data *dnstap_dt = module->data; if (!req->qsource.addr) { return kr_ok(); } /* check if we have a valid iothread */ if (!dnstap_dt->iothread || !dnstap_dt->ioq) { DEBUG_MSG("dnstap_dt->iothread or dnstap_dt->ioq is NULL\n"); return kr_error(EFAULT); } /* Create dnstap message */ Dnstap__Message m; memset(&m, 0, sizeof(m)); m.base.descriptor = &dnstap__message__descriptor; if (req->qsource.addr) { set_address(req->qsource.addr, &m.query_address, &m.has_query_address, &m.query_port, &m.has_query_port); } if (req->qsource.dst_addr) { if (req->qsource.flags.http) { m.socket_protocol = DNSTAP__SOCKET_PROTOCOL__DOH; } else if (req->qsource.flags.tls) { m.socket_protocol = DNSTAP__SOCKET_PROTOCOL__DOT; } else if (req->qsource.flags.tcp) { m.socket_protocol = DNSTAP__SOCKET_PROTOCOL__TCP; } else { m.socket_protocol = DNSTAP__SOCKET_PROTOCOL__UDP; } m.has_socket_protocol = true; set_address(req->qsource.dst_addr, &m.response_address, &m.has_response_address, &m.response_port, &m.has_response_port); switch (req->qsource.dst_addr->sa_family) { case AF_INET: m.socket_family = DNSTAP__SOCKET_FAMILY__INET; m.has_socket_family = true; break; case AF_INET6: m.socket_family = DNSTAP__SOCKET_FAMILY__INET6; m.has_socket_family = true; break; } } if (phase == CLIENT_QUERY_PHASE) { m.type = DNSTAP__MESSAGE__TYPE__CLIENT_QUERY; if (dnstap_dt->log_qr_pkt) { const knot_pkt_t *qpkt = req->qsource.packet; m.has_query_message = qpkt != NULL; if (qpkt != NULL) { m.query_message.len = qpkt->size; m.query_message.data = (uint8_t *)qpkt->wire; } } /* set query time to the timestamp of the first kr_query */ if (rplan->initial) { struct kr_query *first = rplan->initial; m.query_time_sec = first->timestamp.tv_sec; m.has_query_time_sec = true; m.query_time_nsec = first->timestamp.tv_usec * 1000; m.has_query_time_nsec = true; } } else if (phase == CLIENT_RESPONSE_PHASE) { m.type = DNSTAP__MESSAGE__TYPE__CLIENT_RESPONSE; /* current time */ struct timeval now; gettimeofday(&now, NULL); if (dnstap_dt->log_resp_pkt) { const knot_pkt_t *rpkt = req->answer; m.has_response_message = rpkt != NULL; if (rpkt != NULL) { m.response_message.len = rpkt->size; m.response_message.data = rpkt->wire; } } /* Set response time to now */ m.response_time_sec = now.tv_sec; m.has_response_time_sec = true; m.response_time_nsec = now.tv_usec * 1000; m.has_response_time_nsec = true; } /* Create a dnstap Message */ Dnstap__Dnstap dnstap = DNSTAP__DNSTAP__INIT; dnstap.type = DNSTAP__DNSTAP__TYPE__MESSAGE; dnstap.message = &m; if (dnstap_dt->identity) { dnstap.identity.data = (uint8_t*)dnstap_dt->identity; dnstap.identity.len = dnstap_dt->identity_len; dnstap.has_identity = true; } if (dnstap_dt->version) { dnstap.version.data = (uint8_t*)dnstap_dt->version; dnstap.version.len = dnstap_dt->version_len; dnstap.has_version = true; } /* Pack the message */ uint8_t *frame = NULL; size_t size = 0; dt_pack(&dnstap, &frame, &size); if (!frame) { return kr_error(ENOMEM); } /* Submit a request to send message to fstrm_iothr*/ fstrm_res res = fstrm_iothr_submit(dnstap_dt->iothread, dnstap_dt->ioq, frame, size, fstrm_free_wrapper, NULL); if (res != fstrm_res_success) { DEBUG_MSG("Error submitting dnstap message to iothr\n"); free(frame); return kr_error(EBUSY); } return kr_ok(); } /* dnstap_log_query prepares dnstap CLIENT_QUERY message and sends it to fstrm */ static int dnstap_log_query(kr_layer_t *ctx) { dnstap_log(ctx, CLIENT_QUERY_PHASE); return ctx->state; } /* dnstap_log_response prepares dnstap CLIENT_RESPONSE message and sends it to fstrm */ static int dnstap_log_response(kr_layer_t *ctx) { dnstap_log(ctx, CLIENT_RESPONSE_PHASE); return ctx->state; } KR_EXPORT int dnstap_init(struct kr_module *module) { static kr_layer_api_t layer = { .begin = &dnstap_log_query, .finish = &dnstap_log_response, }; /* Store module reference */ layer.data = module; module->layer = &layer; /* allocated memory for internal data */ struct dnstap_data *data = calloc(1, sizeof(*data)); if (!data) { return kr_error(ENOMEM); } /* save pointer to internal struct in module for future reference */ module->data = data; return kr_ok(); } KR_EXPORT int dnstap_deinit(struct kr_module *module) { struct dnstap_data *data = module->data; /* Free allocated memory */ if (data) { free(data->identity); free(data->version); fstrm_iothr_destroy(&data->iothread); DEBUG_MSG("fstrm iothread destroyed\n"); free(data); } return kr_ok(); } /* dnstap_unix_writer returns a unix fstream writer * https://gitlab.nic.cz/knot/knot-dns/blob/master/src/knot/modules/dnstap.c#L159 */ static struct fstrm_writer* dnstap_unix_writer(const char *path) { auto_destroy_uopts struct fstrm_unix_writer_options *opt = fstrm_unix_writer_options_init(); if (!opt) { return NULL; } fstrm_unix_writer_options_set_socket_path(opt, path); auto_destroy_wopts struct fstrm_writer_options *wopt = fstrm_writer_options_init(); if (!wopt) { fstrm_unix_writer_options_destroy(&opt); return NULL; } fstrm_writer_options_add_content_type(wopt, DNSTAP_CONTENT_TYPE, strlen(DNSTAP_CONTENT_TYPE)); struct fstrm_writer *writer = fstrm_unix_writer_init(opt, wopt); fstrm_unix_writer_options_destroy(&opt); fstrm_writer_options_destroy(&wopt); if (!writer) { return NULL; } fstrm_res res = fstrm_writer_open(writer); if (res != fstrm_res_success) { DEBUG_MSG("fstrm_writer_open returned %d\n", res); fstrm_writer_destroy(&writer); return NULL; } return writer; } /* find_string * create a new string from json * *var is set to pointer of new string * node must of type JSON_STRING * new string can be at most len bytes */ static int find_string(const JsonNode *node, char **val, size_t len) { if (!node || !node->key) { return kr_error(EINVAL); } assert(node->tag == JSON_STRING); *val = strndup(node->string_, len); assert(*val != NULL); return kr_ok(); } /* find_bool returns bool from json */ static bool find_bool(const JsonNode *node) { if (!node || !node->key) { return false; } assert(node->tag == JSON_BOOL); return node->bool_; } /* parse config */ KR_EXPORT int dnstap_config(struct kr_module *module, const char *conf) { struct dnstap_data *data = module->data; auto_free char *sock_path = NULL; /* Empty conf passed, set default */ if (!conf || strlen(conf) < 1) { sock_path = strndup(DEFAULT_SOCK_PATH, PATH_MAX); } else { JsonNode *root_node = json_decode(conf); if (!root_node) { DEBUG_MSG("error parsing json\n"); return kr_error(EINVAL); } JsonNode *node; /* dnstapPath key */ node = json_find_member(root_node, CFG_SOCK_PATH); if (!node || find_string(node, &sock_path, PATH_MAX) != kr_ok()) { sock_path = strndup(DEFAULT_SOCK_PATH, PATH_MAX); } /* identity string key */ node = json_find_member(root_node, CFG_IDENTITY_STRING); if (!node || find_string(node, &data->identity, KR_EDNS_PAYLOAD) != kr_ok()) { data->identity = NULL; data->identity_len = 0; } else { data->identity_len = strlen(data->identity); } /* version string key */ node = json_find_member(root_node, CFG_VERSION_STRING); if (!node || find_string(node, &data->version, KR_EDNS_PAYLOAD) != kr_ok()) { data->version = strdup("Knot Resolver " PACKAGE_VERSION); if (data->version) { data->version_len = strlen(data->version); } } else { data->version_len = strlen(data->version); } node = json_find_member(root_node, CFG_LOG_CLIENT_PKT); if (node) { JsonNode *subnode; /* logRespPkt key */ subnode = json_find_member(node, CFG_LOG_RESP_PKT); if (subnode) { data->log_resp_pkt = find_bool(subnode); } else { data->log_resp_pkt = false; } /* logQrPkt key */ subnode = json_find_member(node, CFG_LOG_QR_PKT); if (subnode) { data->log_qr_pkt = find_bool(subnode); } else { data->log_qr_pkt = false; } } else { data->log_qr_pkt = false; data->log_resp_pkt = false; } /* clean up json, we don't need it no more */ json_delete(root_node); } DEBUG_MSG("opening sock file %s\n",sock_path); struct fstrm_writer *writer = dnstap_unix_writer(sock_path); if (!writer) { DEBUG_MSG("can't create unix writer\n"); return kr_error(EINVAL); } struct fstrm_iothr_options *opt = fstrm_iothr_options_init(); if (!opt) { DEBUG_MSG("can't init fstrm options\n"); fstrm_writer_destroy(&writer); return kr_error(EINVAL); } /* Create the I/O thread. */ data->iothread = fstrm_iothr_init(opt, &writer); fstrm_iothr_options_destroy(&opt); if (!data->iothread) { DEBUG_MSG("can't init fstrm_iothr\n"); fstrm_writer_destroy(&writer); return kr_error(ENOMEM); } /* Get fstrm thread handle * We only have one input queue, hence idx=0 */ data->ioq = fstrm_iothr_get_input_queue_idx(data->iothread, 0); if (!data->ioq) { fstrm_iothr_destroy(&data->iothread); DEBUG_MSG("can't get fstrm queue\n"); return kr_error(EBUSY); } return kr_ok(); } KR_MODULE_EXPORT(dnstap)