/* * Copyright (c) 2009-2012, Vsevolod Stakhov * All rights reserved. * * 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. * * THIS SOFTWARE IS PROVIDED BY 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 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. */ #include "config.h" #include "dns.h" #include "spf.h" #include "main.h" #include "message.h" #include "filter.h" #include "utlist.h" #define SPF_VER1_STR "v=spf1" #define SPF_VER2_STR "spf2." #define SPF_SCOPE_PRA "pra" #define SPF_SCOPE_MFROM "mfrom" #define SPF_ALL "all" #define SPF_A "a" #define SPF_IP4 "ip4" #define SPF_IP6 "ip6" #define SPF_PTR "ptr" #define SPF_MX "mx" #define SPF_EXISTS "exists" #define SPF_INCLUDE "include" #define SPF_REDIRECT "redirect" #define SPF_EXP "exp" /** SPF limits for avoiding abuse **/ #define SPF_MAX_NESTING 10 #define SPF_MAX_DNS_REQUESTS 30 struct spf_resolved_element { GPtrArray *elts; gchar *cur_domain; gboolean redirected; /* Ingnore level, it's redirected */ }; struct spf_record { gint nested; gint dns_requests; gint requests_inflight; guint ttl; GPtrArray *resolved; /* Array of struct spf_resolved_element */ const gchar *sender; const gchar *sender_domain; gchar *local_part; struct rspamd_task *task; spf_cb_t callback; gboolean done; }; /** * BNF for SPF record: * * spf_mech ::= +|-|~|? * * spf_body ::= spf=v1 [] * spf_command ::= [spf_mech]all|a|||ptr|mx||| * * spf_domain ::= [:domain][/mask] * spf_ip4 ::= ip[/mask] * ip4 ::= ip4: * mx ::= mx * a ::= a * ptr ::= ptr[:domain] * exists ::= exists:domain * include ::= include:domain * redirect ::= redirect:domain * exp ::= exp:domain * */ #undef SPF_DEBUG struct spf_dns_cb { struct spf_record *rec; struct spf_addr *addr; struct spf_resolved_element *resolved; gchar *ptr_host; spf_action_t cur_action; gboolean in_include; }; #define CHECK_REC(rec) \ do { \ if ((rec)->nested > SPF_MAX_NESTING || \ (rec)->dns_requests > SPF_MAX_DNS_REQUESTS) { \ msg_info ("<%s> spf recursion limit %d is reached, domain: %s", \ (rec)->task->message_id, (rec)->dns_requests, \ (rec)->sender_domain); \ return FALSE; \ } \ } while (0) \ static gboolean start_spf_parse (struct spf_record *rec, struct spf_resolved_element *resolved, gchar *begin); /* Determine spf mech */ static spf_mech_t check_spf_mech (const gchar *elt, gboolean *need_shift) { g_assert (elt != NULL); *need_shift = TRUE; switch (*elt) { case '-': return SPF_FAIL; case '~': return SPF_SOFT_FAIL; case '+': return SPF_PASS; case '?': return SPF_NEUTRAL; default: *need_shift = FALSE; return SPF_PASS; } } static struct spf_addr * rspamd_spf_new_addr (struct spf_record *rec, struct spf_resolved_element *resolved, const gchar *elt) { gboolean need_shift = FALSE; struct spf_addr *naddr; naddr = g_slice_alloc0 (sizeof (*naddr)); naddr->mech = check_spf_mech (elt, &need_shift); if (need_shift) { naddr->spf_string = g_strdup (elt + 1); } else { naddr->spf_string = g_strdup (elt); } g_ptr_array_add (resolved->elts, naddr); return naddr; } static void rspamd_spf_free_addr (gpointer a) { struct spf_addr *addr = a; if (addr) { g_free (addr->spf_string); g_slice_free1 (sizeof (*addr), addr); } } static struct spf_resolved_element * rspamd_spf_new_addr_list (struct spf_record *rec, const gchar *domain) { struct spf_resolved_element *resolved; resolved = g_slice_alloc (sizeof (*resolved)); resolved->redirected = FALSE; resolved->cur_domain = g_strdup (domain); resolved->elts = g_ptr_array_new_full (8, rspamd_spf_free_addr); g_ptr_array_add (rec->resolved, resolved); return g_ptr_array_index (rec->resolved, rec->resolved->len - 1); } /* * Destructor for spf record */ static void spf_record_destructor (gpointer r) { struct spf_record *rec = r; struct spf_resolved_element *elt; guint i; if (rec) { for (i = 0; i < rec->resolved->len; i ++) { elt = g_ptr_array_index (rec->resolved, i); g_ptr_array_free (elt->elts, TRUE); g_free (elt->cur_domain); g_slice_free1 (sizeof (*elt), elt); } g_ptr_array_free (rec->resolved, TRUE); } } static void rspamd_flatten_record_dtor (struct spf_resolved *r) { struct spf_addr *addr; guint i; for (i = 0; i < r->elts->len; i ++) { addr = &g_array_index (r->elts, struct spf_addr, i); g_free (addr->spf_string); } g_free (r->domain); g_array_free (r->elts, TRUE); g_slice_free1 (sizeof (*r), r); } static void rspamd_spf_process_reference (struct spf_resolved *target, struct spf_addr *addr, struct spf_record *rec, gboolean top) { struct spf_resolved_element *elt; struct spf_addr *cur = NULL, taddr; guint i; if (addr) { g_assert (addr->m.idx < rec->resolved->len); elt = g_ptr_array_index (rec->resolved, addr->m.idx); } else { elt = g_ptr_array_index (rec->resolved, 0); } while (elt->redirected) { g_assert (elt->elts->len > 0); for (i = 0; i < elt->elts->len; i ++) { cur = g_ptr_array_index (elt->elts, i); if (cur->flags & RSPAMD_SPF_FLAG_PARSED) { break; } } g_assert (cur != NULL); if (!(cur->flags & RSPAMD_SPF_FLAG_PARSED)) { /* Unresolved redirect */ msg_info ("redirect to %s cannot be resolved", cur->spf_string); return; } g_assert (cur->flags & RSPAMD_SPF_FLAG_REFRENCE); g_assert (cur->m.idx < rec->resolved->len); elt = g_ptr_array_index (rec->resolved, cur->m.idx); } for (i = 0; i < elt->elts->len; i ++) { cur = g_ptr_array_index (elt->elts, i); if (!(cur->flags & RSPAMD_SPF_FLAG_PARSED)) { /* Ignore unparsed addrs */ continue; } else if (cur->flags & RSPAMD_SPF_FLAG_REFRENCE) { /* Process reference */ rspamd_spf_process_reference (target, cur, rec, FALSE); } else { if ((cur->flags & RSPAMD_SPF_FLAG_ANY) && !top) { /* Ignore wide policies in includes */ continue; } memcpy (&taddr, cur, sizeof (taddr)); /* Steal element */ cur->spf_string = NULL; g_array_append_val (target->elts, taddr); } } } /* * Parse record and flatten it to a simple structure */ static struct spf_resolved * rspamd_spf_record_flatten (struct spf_record *rec) { struct spf_resolved *res; g_assert (rec != NULL); res = g_slice_alloc (sizeof (*res)); res->elts = g_array_sized_new (FALSE, FALSE, sizeof (struct spf_addr), rec->resolved->len); res->domain = g_strdup (rec->sender_domain); res->ttl = rec->ttl; REF_INIT_RETAIN (res, rspamd_flatten_record_dtor); if (rec->resolved->len > 0) { rspamd_spf_process_reference (res, NULL, rec, TRUE); } return res; } static void rspamd_spf_maybe_return (struct spf_record *rec) { struct spf_resolved *flat; if (rec->requests_inflight == 0 && !rec->done) { flat = rspamd_spf_record_flatten (rec); rec->callback (flat, rec->task); REF_RELEASE (flat); rec->done = TRUE; } } static gboolean spf_check_ptr_host (struct spf_dns_cb *cb, const char *name) { const char *dend, *nend, *dstart, *nstart; if (name == NULL) { return FALSE; } if (cb->ptr_host != NULL) { dstart = cb->ptr_host; } else { dstart = cb->resolved->cur_domain; } msg_debug ("check ptr %s vs %s", name, dstart); /* We need to check whether `cur_domain` is a subdomain for `name` */ dend = dstart + strlen (dstart) - 1; nstart = name; nend = nstart + strlen (nstart) - 1; if (nend == nstart || dend == dstart) { return FALSE; } /* Strip last '.' from names */ if (*nend == '.') { nend --; } if (*dend == '.') { dend --; } /* Now compare from end to start */ for (;;) { if (g_ascii_tolower (*dend) != g_ascii_tolower (*nend)) { msg_debug ("ptr records mismatch: %s and %s", dend, nend); return FALSE; } if (dend == dstart) { break; } if (nend == nstart) { /* Name is shorter than cur_domain */ return FALSE; } nend --; dend --; } if (nend != nstart && *(nend - 1) != '.') { /* Not a subdomain */ return FALSE; } return TRUE; } static void spf_record_process_addr (struct spf_addr *addr, struct rdns_reply_entry *reply) { if (reply->type == RDNS_REQUEST_AAAA) { memcpy (addr->addr6, &reply->content.aaa.addr, sizeof (addr->addr6)); addr->flags |= RSPAMD_SPF_FLAG_IPV6; } else if (reply->type == RDNS_REQUEST_A) { memcpy (addr->addr4, &reply->content.a.addr, sizeof (addr->addr4)); addr->flags |= RSPAMD_SPF_FLAG_IPV4; } else { msg_err ("internal error, bad DNS reply is treated as address: %s", rdns_strtype (reply->type)); } } static void spf_record_addr_set (struct spf_addr *addr, gboolean allow_any) { guchar fill; guint maskv4, maskv6; if (allow_any) { fill = 0; maskv4 = 0; maskv6 = 0; } else { fill = 0xff; maskv4 = 32; maskv6 = 128; } memset (addr->addr4, fill, sizeof (addr->addr4)); memset (addr->addr6, fill, sizeof (addr->addr6)); addr->m.dual.mask_v4 = maskv4; addr->m.dual.mask_v6 = maskv6; addr->flags |= RSPAMD_SPF_FLAG_IPV4; addr->flags |= RSPAMD_SPF_FLAG_IPV6; } static void spf_record_dns_callback (struct rdns_reply *reply, gpointer arg) { struct spf_dns_cb *cb = arg; gchar *begin; struct rdns_reply_entry *elt_data; struct rspamd_task *task; struct spf_addr *addr; gboolean ret; task = cb->rec->task; cb->rec->requests_inflight--; addr = cb->addr; if (reply->code == RDNS_RC_NOERROR) { /* Add all logic for all DNS states here */ LL_FOREACH (reply->entries, elt_data) { switch (cb->cur_action) { case SPF_RESOLVE_MX: if (elt_data->type == RDNS_REQUEST_MX) { /* Now resolve A record for this MX */ msg_debug ("resolve %s after resolving of MX", elt_data->content.mx.name); if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_A, elt_data->content.mx.name)) { task->dns_requests++; cb->rec->requests_inflight++; } if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_AAAA, elt_data->content.mx.name)) { task->dns_requests++; cb->rec->requests_inflight++; } } else { spf_record_process_addr (addr, elt_data); } break; case SPF_RESOLVE_A: case SPF_RESOLVE_AAA: spf_record_process_addr (addr, elt_data); break; case SPF_RESOLVE_PTR: if (elt_data->type == RDNS_REQUEST_PTR) { /* Validate returned records prior to making A requests */ if (spf_check_ptr_host (cb, elt_data->content.ptr.name)) { msg_debug ("resolve %s after resolving of PTR", elt_data->content.ptr.name); if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_A, elt_data->content.ptr.name)) { task->dns_requests++; cb->rec->requests_inflight++; } if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_AAAA, elt_data->content.ptr.name)) { task->dns_requests++; cb->rec->requests_inflight++; } } } else { spf_record_process_addr (addr, elt_data); } break; case SPF_RESOLVE_REDIRECT: if (elt_data->type == RDNS_REQUEST_TXT) { begin = elt_data->content.txt.data; ret = start_spf_parse (cb->rec, cb->resolved, begin); if (ret) { cb->addr->flags |= RSPAMD_SPF_FLAG_PARSED; } else { cb->addr->flags &= ~RSPAMD_SPF_FLAG_PARSED; } } break; case SPF_RESOLVE_INCLUDE: if (elt_data->type == RDNS_REQUEST_TXT) { begin = elt_data->content.txt.data; ret = start_spf_parse (cb->rec, cb->resolved, begin); if (ret) { cb->addr->flags |= RSPAMD_SPF_FLAG_PARSED; } else { cb->addr->flags &= ~RSPAMD_SPF_FLAG_PARSED; } } break; case SPF_RESOLVE_EXP: break; case SPF_RESOLVE_EXISTS: if (elt_data->type == RDNS_REQUEST_A || elt_data->type == RDNS_REQUEST_AAAA) { /* If specified address resolves, we can accept connection from every IP */ spf_record_addr_set (addr, TRUE); } break; } } } else if (reply->code == RDNS_RC_NXDOMAIN) { switch (cb->cur_action) { case SPF_RESOLVE_MX: if (rdns_request_has_type (reply->request, RDNS_REQUEST_MX)) { msg_info ( "<%s>: spf error for domain %s: cannot find MX record for %s", task->message_id, cb->rec->sender_domain, cb->resolved->cur_domain); spf_record_addr_set (addr, FALSE); } else { msg_info ( "<%s>: spf error for domain %s: cannot resolve MX record for %s", task->message_id, cb->rec->sender_domain, cb->resolved->cur_domain); spf_record_addr_set (addr, FALSE); } break; case SPF_RESOLVE_A: if (rdns_request_has_type (reply->request, RDNS_REQUEST_A)) { spf_record_addr_set (addr, FALSE); } break; case SPF_RESOLVE_AAA: if (rdns_request_has_type (reply->request, RDNS_REQUEST_AAAA)) { spf_record_addr_set (addr, FALSE); } break; case SPF_RESOLVE_PTR: spf_record_addr_set (addr, FALSE); break; case SPF_RESOLVE_REDIRECT: msg_info ( "<%s>: spf error for domain %s: cannot resolve TXT record for %s", task->message_id, cb->rec->sender_domain, cb->resolved->cur_domain); cb->addr->flags &= ~RSPAMD_SPF_FLAG_PARSED; break; case SPF_RESOLVE_INCLUDE: msg_info ( "<%s>: spf error for domain %s: cannot resolve TXT record for %s", task->message_id, cb->rec->sender_domain, cb->resolved->cur_domain); cb->addr->flags &= ~RSPAMD_SPF_FLAG_PARSED; break; case SPF_RESOLVE_EXP: break; case SPF_RESOLVE_EXISTS: spf_record_addr_set (addr, FALSE); break; } } rspamd_spf_maybe_return (cb->rec); } /* * The syntax defined by the following BNF: * [ ":" domain-spec ] [ dual-cidr-length ] * ip4-cidr-length = "/" 1*DIGIT * ip6-cidr-length = "/" 1*DIGIT * dual-cidr-length = [ ip4-cidr-length ] [ "/" ip6-cidr-length ] */ static const gchar * parse_spf_domain_mask (struct spf_record *rec, struct spf_addr *addr, gboolean allow_mask) { struct spf_resolved_element *resolved; struct rspamd_task *task = rec->task; enum { parse_spf_elt = 0, parse_semicolon, parse_domain, parse_slash, parse_ipv4_mask, parse_second_slash, parse_ipv6_mask, skip_garbadge } state = 0; const gchar *p = addr->spf_string, *host, *c; gchar *hostbuf; gchar t; guint16 cur_mask = 0; resolved = g_ptr_array_index (rec->resolved, rec->resolved->len - 1); host = resolved->cur_domain; c = p; while (*p) { t = *p; switch (state) { case parse_spf_elt: if (t == ':') { state = parse_semicolon; } else if (t == '/') { /* No domain but mask */ state = parse_slash; } p ++; break; case parse_semicolon: if (t == '/') { /* Empty domain, technically an error */ state = parse_slash; } c = p; state = parse_domain; break; case parse_domain: if (t == '/') { hostbuf = rspamd_mempool_alloc (task->task_pool, p - c + 1); rspamd_strlcpy (hostbuf, c, p - c + 1); host = hostbuf; state = parse_slash; } p ++; break; case parse_slash: c = p; if (allow_mask) { state = parse_ipv4_mask; } else { state = skip_garbadge; } cur_mask = 0; break; case parse_ipv4_mask: if (g_ascii_isdigit (t)) { /* Ignore errors here */ cur_mask = cur_mask * 10 + (t - '0'); } else if (t == '/') { if (cur_mask <= 32) { addr->m.dual.mask_v4 = cur_mask; } else { msg_info ("bad ipv4 mask: %d", cur_mask); } state = parse_second_slash; } p ++; break; case parse_second_slash: c = p; state = parse_ipv6_mask; cur_mask = 0; break; case parse_ipv6_mask: if (g_ascii_isdigit (t)) { /* Ignore errors here */ cur_mask = cur_mask * 10 + (t - '0'); } p ++; break; case skip_garbadge: p++; break; } } /* Process end states */ if (state == parse_ipv4_mask) { if (cur_mask <= 32) { addr->m.dual.mask_v4 = cur_mask; } else { msg_info ("bad ipv4 mask: %d", cur_mask); } } else if (state == parse_ipv6_mask) { if (cur_mask <= 128) { addr->m.dual.mask_v6 = cur_mask; } else { msg_info ("bad ipv6 mask: %d", cur_mask); } } else if (state == parse_domain && p - c > 0) { hostbuf = rspamd_mempool_alloc (task->task_pool, p - c + 1); rspamd_strlcpy (hostbuf, c, p - c + 1); host = hostbuf; } return host; } static gboolean parse_spf_a (struct spf_record *rec, struct spf_addr *addr) { struct spf_dns_cb *cb; const gchar *host = NULL; struct rspamd_task *task = rec->task; struct spf_resolved_element *resolved; resolved = g_ptr_array_index (rec->resolved, rec->resolved->len - 1); CHECK_REC (rec); host = parse_spf_domain_mask (rec, addr, TRUE); if (host == NULL) { return FALSE; } rec->dns_requests++; cb = rspamd_mempool_alloc (task->task_pool, sizeof (struct spf_dns_cb)); cb->rec = rec; cb->addr = addr; cb->cur_action = SPF_RESOLVE_A; cb->resolved = resolved; msg_debug ("resolve a %s", host); if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_A, host)) { task->dns_requests++; rec->requests_inflight++; return TRUE; } return FALSE; } static gboolean parse_spf_ptr (struct spf_record *rec, struct spf_addr *addr) { struct spf_dns_cb *cb; const gchar *host; gchar *ptr; struct rspamd_task *task = rec->task; struct spf_resolved_element *resolved; resolved = g_ptr_array_index (rec->resolved, rec->resolved->len - 1); CHECK_REC (rec); host = parse_spf_domain_mask (rec, addr, FALSE); rec->dns_requests++; cb = rspamd_mempool_alloc (task->task_pool, sizeof (struct spf_dns_cb)); cb->rec = rec; cb->addr = addr; cb->cur_action = SPF_RESOLVE_PTR; cb->resolved = resolved; cb->ptr_host = rspamd_mempool_strdup (task->task_pool, host); ptr = rdns_generate_ptr_from_str (rspamd_inet_address_to_string ( task->from_addr)); if (ptr == NULL) { return FALSE; } rspamd_mempool_add_destructor (task->task_pool, free, ptr); msg_debug ("resolve ptr %s for %s", ptr, host); if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_PTR, ptr)) { task->dns_requests++; rec->requests_inflight++; return TRUE; } return FALSE; } static gboolean parse_spf_mx (struct spf_record *rec, struct spf_addr *addr) { struct spf_dns_cb *cb; const gchar *host; struct rspamd_task *task = rec->task; struct spf_resolved_element *resolved; resolved = g_ptr_array_index (rec->resolved, rec->resolved->len - 1); CHECK_REC (rec); host = parse_spf_domain_mask (rec, addr, TRUE); if (host == NULL) { return FALSE; } rec->dns_requests++; cb = rspamd_mempool_alloc (task->task_pool, sizeof (struct spf_dns_cb)); cb->rec = rec; cb->addr = addr; cb->cur_action = SPF_RESOLVE_MX; cb->resolved = resolved; msg_debug ("resolve mx for %s", host); if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_MX, host)) { task->dns_requests++; rec->requests_inflight++; return TRUE; } return FALSE; } static gboolean parse_spf_all (struct spf_record *rec, struct spf_addr *addr) { /* All is 0/0 */ memset (&addr->addr4, 0, sizeof (addr->addr4)); memset (&addr->addr6, 0, sizeof (addr->addr6)); /* Here we set all masks to 0 */ addr->m.idx = 0; addr->flags |= RSPAMD_SPF_FLAG_ANY; return TRUE; } static gboolean parse_spf_ip4 (struct spf_record *rec, struct spf_addr *addr) { /* ip4:addr[/mask] */ const gchar *semicolon, *slash; gsize len; gchar ipbuf[INET_ADDRSTRLEN + 1]; guint32 mask; CHECK_REC (rec); semicolon = strchr (addr->spf_string, ':'); if (semicolon == NULL) { return FALSE; } semicolon ++; slash = strchr (semicolon, '/'); if (slash) { len = slash - semicolon; } else { len = strlen (semicolon); } rspamd_strlcpy (ipbuf, semicolon, MIN (len + 1, sizeof (ipbuf))); if (inet_pton (AF_INET, ipbuf, addr->addr4) != 1) { return FALSE; } if (slash) { mask = strtoul (slash + 1, NULL, 10); if (mask > 32) { return FALSE; } addr->m.dual.mask_v4 = mask; } else { addr->m.dual.mask_v4 = 32; } addr->flags |= RSPAMD_SPF_FLAG_IPV4; return TRUE; } static gboolean parse_spf_ip6 (struct spf_record *rec, struct spf_addr *addr) { /* ip6:addr[/mask] */ const gchar *semicolon, *slash; gsize len; gchar ipbuf[INET6_ADDRSTRLEN + 1]; guint32 mask; CHECK_REC (rec); semicolon = strchr (addr->spf_string, ':'); if (semicolon == NULL) { return FALSE; } semicolon ++; slash = strchr (semicolon, '/'); if (slash) { len = slash - semicolon; } else { len = strlen (semicolon); } rspamd_strlcpy (ipbuf, semicolon, MIN (len + 1, sizeof (ipbuf))); if (inet_pton (AF_INET6, ipbuf, addr->addr6) != 1) { return FALSE; } if (slash) { mask = strtoul (slash + 1, NULL, 10); if (mask > 128) { return FALSE; } addr->m.dual.mask_v6 = mask; } else { addr->m.dual.mask_v6 = 128; } addr->flags |= RSPAMD_SPF_FLAG_IPV6; return TRUE; } static gboolean parse_spf_include (struct spf_record *rec, struct spf_addr *addr) { struct spf_dns_cb *cb; const gchar *domain; struct rspamd_task *task = rec->task; CHECK_REC (rec); domain = strchr (addr->spf_string, ':'); if (domain == NULL) { return FALSE; } domain++; rec->dns_requests++; cb = rspamd_mempool_alloc (task->task_pool, sizeof (struct spf_dns_cb)); cb->rec = rec; cb->addr = addr; cb->cur_action = SPF_RESOLVE_INCLUDE; addr->m.idx = rec->resolved->len; cb->resolved = rspamd_spf_new_addr_list (rec, domain); /* Set reference */ addr->flags |= RSPAMD_SPF_FLAG_REFRENCE; msg_debug ("resolve include %s", domain); if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_TXT, domain)) { task->dns_requests++; rec->requests_inflight++; return TRUE; } return FALSE; } static gboolean parse_spf_exp (struct spf_record *rec, struct spf_addr *addr) { CHECK_REC (rec); msg_info ("exp record is ignored"); return TRUE; } static gboolean parse_spf_redirect (struct spf_record *rec, struct spf_resolved_element *resolved, struct spf_addr *addr) { struct spf_dns_cb *cb; const gchar *domain; struct spf_addr *cur; struct rspamd_task *task = rec->task; guint i; CHECK_REC (rec); domain = strchr (addr->spf_string, '='); if (domain == NULL) { return FALSE; } domain++; rec->dns_requests++; resolved->redirected = TRUE; /* Now clear all elements but this one */ for (i = 0; i < resolved->elts->len; i ++) { cur = g_ptr_array_index (resolved->elts, i); if (cur != addr) { cur->flags &= ~RSPAMD_SPF_FLAG_PARSED; } } cb = rspamd_mempool_alloc (task->task_pool, sizeof (struct spf_dns_cb)); /* Set reference */ addr->flags |= RSPAMD_SPF_FLAG_REFRENCE; addr->m.idx = rec->resolved->len; cb->rec = rec; cb->addr = addr; cb->cur_action = SPF_RESOLVE_REDIRECT; cb->resolved = rspamd_spf_new_addr_list (rec, domain); msg_debug ("resolve redirect %s", domain); if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_TXT, domain)) { task->dns_requests++; rec->requests_inflight++; return TRUE; } return FALSE; } static gboolean parse_spf_exists (struct spf_record *rec, struct spf_addr *addr) { struct spf_dns_cb *cb; const gchar *host; struct rspamd_task *task = rec->task; struct spf_resolved_element *resolved; resolved = g_ptr_array_index (rec->resolved, rec->resolved->len - 1); CHECK_REC (rec); host = strchr (addr->spf_string, ':'); if (host == NULL) { msg_info ("bad SPF exist record: %s", addr->spf_string); return FALSE; } host ++; rec->dns_requests++; cb = rspamd_mempool_alloc (task->task_pool, sizeof (struct spf_dns_cb)); cb->rec = rec; cb->addr = addr; cb->cur_action = SPF_RESOLVE_EXISTS; cb->resolved = resolved; msg_debug ("resolve exists %s", host); if (make_dns_request (task->resolver, task->s, task->task_pool, spf_record_dns_callback, (void *)cb, RDNS_REQUEST_A, host)) { task->dns_requests++; rec->requests_inflight++; return TRUE; } return FALSE; } static void reverse_spf_ip (gchar *ip, gint len) { gchar ipbuf[sizeof("255.255.255.255") - 1], *p, *c; gint t = 0, l = len; if (len > (gint)sizeof (ipbuf)) { msg_info ("cannot reverse string of length %d", len); return; } p = ipbuf + len; c = ip; while (--l) { if (*c == '.') { memcpy (p, c - t, t); *--p = '.'; c++; t = 0; continue; } t++; c++; p--; } memcpy (p - 1, c - t, t + 1); memcpy (ip, ipbuf, len); } static const gchar * expand_spf_macro (struct spf_record *rec, const gchar *begin) { const gchar *p; gchar *c, *new, *tmp; gint len = 0, slen = 0, state = 0; gchar ip_buf[INET6_ADDRSTRLEN]; gboolean need_expand = FALSE; struct rspamd_task *task; struct spf_resolved_element *resolved; g_assert (rec != NULL); g_assert (begin != NULL); task = rec->task; resolved = g_ptr_array_index (rec->resolved, rec->resolved->len - 1); p = begin; /* Calculate length */ while (*p) { switch (state) { case 0: /* Skip any character and wait for % in input */ if (*p == '%') { state = 1; } else { len++; } slen++; p++; break; case 1: /* We got % sign, so we should whether wait for { or for - or for _ or for % */ if (*p == '%' || *p == '_') { /* Just a single % sign or space */ len++; state = 0; } else if (*p == '-') { /* %20 */ len += sizeof ("%20") - 1; state = 0; } else if (*p == '{') { state = 2; } else { /* Something unknown */ msg_info ("<%s>: spf error for domain %s: unknown spf element", task->message_id, rec->sender_domain); return begin; } p++; slen++; break; case 2: /* Read macro name */ switch (g_ascii_tolower (*p)) { case 'i': len += INET6_ADDRSTRLEN - 1; break; case 's': len += strlen (rec->sender); break; case 'l': len += strlen (rec->local_part); break; case 'o': len += strlen (rec->sender_domain); break; case 'd': len += strlen (resolved->cur_domain); break; case 'v': len += sizeof ("in-addr") - 1; break; case 'h': if (task->helo) { len += strlen (task->helo); } break; default: msg_info ( "<%s>: spf error for domain %s: unknown or unsupported spf macro %c in %s", task->message_id, rec->sender_domain, *p, begin); return begin; } p++; slen++; state = 3; break; case 3: /* Read modifier */ if (*p == '}') { state = 0; need_expand = TRUE; } else if (*p != 'r' && !g_ascii_isdigit (*p)) { msg_info ( "<%s>: spf error for domain %s: unknown or unsupported spf modifier %c in %s", task->message_id, rec->sender_domain, *p, begin); return begin; } p++; slen++; break; } } if (!need_expand) { /* No expansion needed */ return begin; } new = rspamd_mempool_alloc (task->task_pool, len + 1); c = new; p = begin; state = 0; /* Begin macro expansion */ while (*p) { switch (state) { case 0: /* Skip any character and wait for % in input */ if (*p == '%') { state = 1; } else { *c = *p; c++; } p++; break; case 1: /* We got % sign, so we should whether wait for { or for - or for _ or for % */ if (*p == '%') { /* Just a single % sign or space */ *c++ = '%'; state = 0; } else if (*p == '_') { *c++ = ' '; state = 0; } else if (*p == '-') { /* %20 */ *c++ = '%'; *c++ = '2'; *c++ = '0'; state = 0; } else if (*p == '{') { state = 2; } else { /* Something unknown */ msg_info ("<%s>: spf error for domain %s: unknown spf element", task->message_id, rec->sender_domain); return begin; } p++; break; case 2: /* Read macro name */ switch (g_ascii_tolower (*p)) { case 'i': len = rspamd_strlcpy (ip_buf, rspamd_inet_address_to_string (task->from_addr), sizeof (ip_buf)); memcpy (c, ip_buf, len); c += len; break; case 's': len = strlen (rec->sender); memcpy (c, rec->sender, len); c += len; break; case 'l': len = strlen (rec->local_part); memcpy (c, rec->local_part, len); c += len; break; case 'o': len = strlen (rec->sender_domain); memcpy (c, rec->sender_domain, len); c += len; break; case 'd': len = strlen (resolved->cur_domain); memcpy (c, resolved->cur_domain, len); c += len; break; case 'v': len = sizeof ("in-addr") - 1; memcpy (c, "in-addr", len); c += len; break; case 'h': if (task->helo) { tmp = strchr (task->helo, '@'); if (tmp) { len = strlen (tmp + 1); memcpy (c, tmp + 1, len); c += len; } } break; default: msg_info ( "<%s>: spf error for domain %s: unknown or unsupported spf macro %c in %s", task->message_id, rec->sender_domain, *p, begin); return begin; } p++; state = 3; break; case 3: /* Read modifier */ if (*p == '}') { state = 0; } else if (*p == 'r' && len != 0) { reverse_spf_ip (c - len, len); len = 0; } else if (g_ascii_isdigit (*p)) { /*XXX: try to implement domain trimming */ } else { msg_info ( "<%s>: spf error for domain %s: unknown or unsupported spf macro %c in %s", task->message_id, rec->sender_domain, *p, begin); return begin; } p++; break; } } /* Null terminate */ *c = '\0'; return new; } /* Read current element and try to parse record */ static gboolean parse_spf_record (struct spf_record *rec, struct spf_resolved_element *resolved, const gchar *elt) { struct spf_addr *addr = NULL; gboolean res = FALSE; const gchar *begin; struct rspamd_task *task; gchar t; g_assert (elt != NULL); g_assert (rec != NULL); if (*elt == '\0' || resolved->redirected) { return TRUE; } task = rec->task; begin = expand_spf_macro (rec, elt); addr = rspamd_spf_new_addr (rec, resolved, begin); g_assert (addr != NULL); t = g_ascii_tolower (addr->spf_string[0]); begin = addr->spf_string; /* Now check what we have */ switch (t) { case 'a': /* all or a */ if (g_ascii_strncasecmp (begin, SPF_ALL, sizeof (SPF_ALL) - 1) == 0) { res = parse_spf_all (rec, addr); } else if (g_ascii_strncasecmp (begin, SPF_A, sizeof (SPF_A) - 1) == 0) { res = parse_spf_a (rec, addr); } else { msg_info ("<%s>: spf error for domain %s: bad spf command %s", task->message_id, rec->sender_domain, begin); } break; case 'i': /* include or ip4 */ if (g_ascii_strncasecmp (begin, SPF_IP4, sizeof (SPF_IP4) - 1) == 0) { res = parse_spf_ip4 (rec, addr); } else if (g_ascii_strncasecmp (begin, SPF_INCLUDE, sizeof (SPF_INCLUDE) - 1) == 0) { res = parse_spf_include (rec, addr); } else if (g_ascii_strncasecmp (begin, SPF_IP6, sizeof (SPF_IP6) - 1) == 0) { res = parse_spf_ip6 (rec, addr); } else { msg_info ("<%s>: spf error for domain %s: bad spf command %s", task->message_id, rec->sender_domain, begin); } break; case 'm': /* mx */ if (g_ascii_strncasecmp (begin, SPF_MX, sizeof (SPF_MX) - 1) == 0) { res = parse_spf_mx (rec, addr); } else { msg_info ("<%s>: spf error for domain %s: bad spf command %s", task->message_id, rec->sender_domain, begin); } break; case 'p': /* ptr */ if (g_ascii_strncasecmp (begin, SPF_PTR, sizeof (SPF_PTR) - 1) == 0) { res = parse_spf_ptr (rec, addr); } else { msg_info ("<%s>: spf error for domain %s: bad spf command %s", task->message_id, rec->sender_domain, begin); } break; case 'e': /* exp or exists */ if (g_ascii_strncasecmp (begin, SPF_EXP, sizeof (SPF_EXP) - 1) == 0) { res = parse_spf_exp (rec, addr); } else if (g_ascii_strncasecmp (begin, SPF_EXISTS, sizeof (SPF_EXISTS) - 1) == 0) { res = parse_spf_exists (rec, addr); } else { msg_info ("<%s>: spf error for domain %s: bad spf command %s", task->message_id, rec->sender_domain, begin); } break; case 'r': /* redirect */ if (g_ascii_strncasecmp (begin, SPF_REDIRECT, sizeof (SPF_REDIRECT) - 1) == 0) { res = parse_spf_redirect (rec, resolved, addr); } else { msg_info ("<%s>: spf error for domain %s: bad spf command %s", task->message_id, rec->sender_domain, begin); } break; case 'v': if (g_ascii_strncasecmp (begin, "v=spf", sizeof ("v=spf") - 1) == 0) { /* Skip this element till the end of record */ while (*begin && !g_ascii_isspace (*begin)) { begin++; } } break; default: msg_info ("<%s>: spf error for domain %s: bad spf command %s", task->message_id, rec->sender_domain, begin); break; } if (res) { addr->flags |= RSPAMD_SPF_FLAG_PARSED; } return res; } static void parse_spf_scopes (struct spf_record *rec, gchar **begin) { for (;; ) { if (g_ascii_strncasecmp (*begin, SPF_SCOPE_PRA, sizeof (SPF_SCOPE_PRA) - 1) == 0) { *begin += sizeof (SPF_SCOPE_PRA) - 1; /* XXX: Implement actual PRA check */ /* extract_pra_info (rec); */ continue; } else if (g_ascii_strncasecmp (*begin, SPF_SCOPE_MFROM, sizeof (SPF_SCOPE_MFROM) - 1) == 0) { /* mfrom is standart spf1 check */ *begin += sizeof (SPF_SCOPE_MFROM) - 1; continue; } else if (**begin != ',') { break; } (*begin)++; } } static gboolean start_spf_parse (struct spf_record *rec, struct spf_resolved_element *resolved, gchar *begin) { gchar **elts, **cur_elt; /* Skip spaces */ while (g_ascii_isspace (*begin)) { begin++; } if (g_ascii_strncasecmp (begin, SPF_VER1_STR, sizeof (SPF_VER1_STR) - 1) == 0) { begin += sizeof (SPF_VER1_STR) - 1; while (g_ascii_isspace (*begin) && *begin) { begin++; } } else if (g_ascii_strncasecmp (begin, SPF_VER2_STR, sizeof (SPF_VER2_STR) - 1) == 0) { /* Skip one number of record, so no we are here spf2.0/ */ begin += sizeof (SPF_VER2_STR); if (*begin != '/') { msg_info ("<%s>: spf error for domain %s: sender id is invalid", rec->task->message_id, rec->sender_domain); } else { begin++; parse_spf_scopes (rec, &begin); } /* Now common spf record */ } else { msg_debug ("<%s>: spf error for domain %s: bad spf record version: %*s", rec->task->message_id, rec->sender_domain, sizeof (SPF_VER1_STR) - 1, begin); return FALSE; } while (g_ascii_isspace (*begin) && *begin) { begin++; } elts = g_strsplit_set (begin, " ", 0); if (elts) { cur_elt = elts; while (*cur_elt) { parse_spf_record (rec, resolved, *cur_elt); cur_elt ++; } g_strfreev (elts); } rspamd_spf_maybe_return (rec); return TRUE; } static void spf_dns_callback (struct rdns_reply *reply, gpointer arg) { struct spf_record *rec = arg; struct rdns_reply_entry *elt; struct spf_resolved_element *resolved; rec->requests_inflight--; if (reply->code == RDNS_RC_NOERROR) { resolved = rspamd_spf_new_addr_list (rec, rec->sender_domain); if (rec->resolved->len == 1) { /* Top level resolved element */ rec->ttl = reply->entries->ttl; } LL_FOREACH (reply->entries, elt) { if (start_spf_parse (rec, resolved, elt->content.txt.data)) { break; } } } rspamd_spf_maybe_return (rec); } const gchar * get_spf_domain (struct rspamd_task *task) { const gchar *domain, *res = NULL; const gchar *sender; sender = rspamd_task_get_sender (task); if (sender != NULL) { domain = strchr (sender, '@'); if (domain) { res = domain + 1; } } return res; } gboolean resolve_spf (struct rspamd_task *task, spf_cb_t callback) { struct spf_record *rec; gchar *domain; const gchar *sender; sender = rspamd_task_get_sender (task); rec = rspamd_mempool_alloc0 (task->task_pool, sizeof (struct spf_record)); rec->task = task; rec->callback = callback; rec->resolved = g_ptr_array_sized_new (8); /* Add destructor */ rspamd_mempool_add_destructor (task->task_pool, (rspamd_mempool_destruct_t)spf_record_destructor, rec); /* Extract from data */ if (sender != NULL && (domain = strchr (sender, '@')) != NULL) { rec->sender = sender; rec->local_part = rspamd_mempool_alloc (task->task_pool, domain - sender); rspamd_strlcpy (rec->local_part, sender, domain - sender); rec->sender_domain = domain + 1; } else if (task->helo != NULL && strchr (task->helo, '.') != NULL) { /* For notifies we can check HELO identity and check SPF accordingly */ /* XXX: very poor check */ rec->local_part = rspamd_mempool_strdup (task->task_pool, "postmaster"); rec->sender_domain = task->helo; } else { return FALSE; } if (make_dns_request (task->resolver, task->s, task->task_pool, spf_dns_callback, (void *)rec, RDNS_REQUEST_TXT, rec->sender_domain)) { task->dns_requests++; rec->requests_inflight++; return TRUE; } return FALSE; } struct spf_resolved * spf_record_ref (struct spf_resolved *rec) { REF_RETAIN (rec); return rec; } void spf_record_unref (struct spf_resolved *rec) { REF_RELEASE (rec); }