/*
* Copyright 2024 Vsevolod Stakhov
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "config.h"
#include "dns.h"
#include "spf.h"
#include "rspamd.h"
#include "message.h"
#include "utlist.h"
#include "libserver/mempool_vars_internal.h"
#include "contrib/librdns/rdns.h"
#include "contrib/mumhash/mum.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_IP4_ALT "ipv4"
#define SPF_IP6 "ip6"
#define SPF_IP6_ALT "ipv6"
#define SPF_PTR "ptr"
#define SPF_MX "mx"
#define SPF_EXISTS "exists"
#define SPF_INCLUDE "include"
#define SPF_REDIRECT "redirect"
#define SPF_EXP "exp"
struct spf_resolved_element {
GPtrArray *elts;
char *cur_domain;
gboolean redirected; /* Ignore level, it's redirected */
};
struct spf_record {
int nested;
int dns_requests;
int requests_inflight;
unsigned int ttl;
GPtrArray *resolved;
/* Array of struct spf_resolved_element */
const char *sender;
const char *sender_domain;
const char *top_record;
char *local_part;
struct rspamd_task *task;
spf_cb_t callback;
gpointer cbdata;
gboolean done;
};
struct rspamd_spf_library_ctx {
unsigned int max_dns_nesting;
unsigned int max_dns_requests;
unsigned int min_cache_ttl;
gboolean disable_ipv6;
rspamd_lru_hash_t *spf_hash;
};
struct rspamd_spf_library_ctx *spf_lib_ctx = NULL;
/**
* BNF for SPF record:
*
* spf_mech ::= +|-|~|?
*
* spf_body ::= spf=v1 <spf_command> [<spf_command>]
* spf_command ::= [spf_mech]all|a|<ip4>|<ip6>|ptr|mx|<exists>|<include>|<redirect>
*
* spf_domain ::= [:domain][/mask]
* spf_ip4 ::= ip[/mask]
* ip4 ::= ip4:<spf_ip4>
* mx ::= mx<spf_domain>
* a ::= a<spf_domain>
* ptr ::= ptr[:domain]
* exists ::= exists:domain
* include ::= include:domain
* redirect ::= redirect:domain
* exp ::= exp:domain
*
*/
#undef SPF_DEBUG
#define msg_err_spf(...) rspamd_default_log_function(G_LOG_LEVEL_CRITICAL, \
"spf", rec->task->task_pool->tag.uid, \
RSPAMD_LOG_FUNC, \
__VA_ARGS__)
#define msg_warn_spf(...) rspamd_default_log_function(G_LOG_LEVEL_WARNING, \
"spf", rec->task->task_pool->tag.uid, \
RSPAMD_LOG_FUNC, \
__VA_ARGS__)
#define msg_info_spf(...) rspamd_default_log_function(G_LOG_LEVEL_INFO, \
"spf", rec->task->task_pool->tag.uid, \
RSPAMD_LOG_FUNC, \
__VA_ARGS__)
#define msg_notice_spf(...) rspamd_default_log_function(G_LOG_LEVEL_MESSAGE, \
"spf", rec->task->task_pool->tag.uid, \
RSPAMD_LOG_FUNC, \
__VA_ARGS__)
#define msg_debug_spf(...) rspamd_conditional_debug_fast(NULL, rec->task->from_addr, \
rspamd_spf_log_id, "spf", rec->task->task_pool->tag.uid, \
RSPAMD_LOG_FUNC, \
__VA_ARGS__)
#define msg_debug_spf_flatten(...) rspamd_conditional_debug_fast_num_id(NULL, NULL, \
rspamd_spf_log_id, "spf", (flat)->digest, \
RSPAMD_LOG_FUNC, \
__VA_ARGS__)
INIT_LOG_MODULE(spf)
struct spf_dns_cb {
struct spf_record *rec;
struct spf_addr *addr;
struct spf_resolved_element *resolved;
const char *ptr_host;
spf_action_t cur_action;
gboolean in_include;
};
#define CHECK_REC(rec) \
do { \
if (spf_lib_ctx->max_dns_nesting > 0 && \
(rec)->nested > spf_lib_ctx->max_dns_nesting) { \
msg_warn_spf("spf nesting limit: %d > %d is reached, domain: %s", \
(rec)->nested, spf_lib_ctx->max_dns_nesting, \
(rec)->sender_domain); \
return FALSE; \
} \
if (spf_lib_ctx->max_dns_requests > 0 && \
(rec)->dns_requests > spf_lib_ctx->max_dns_requests) { \
msg_warn_spf("spf dns requests limit: %d > %d is reached, domain: %s", \
(rec)->dns_requests, spf_lib_ctx->max_dns_requests, \
(rec)->sender_domain); \
return FALSE; \
} \
} while (0)
RSPAMD_CONSTRUCTOR(rspamd_spf_lib_ctx_ctor)
{
spf_lib_ctx = g_malloc0(sizeof(*spf_lib_ctx));
spf_lib_ctx->max_dns_nesting = SPF_MAX_NESTING;
spf_lib_ctx->max_dns_requests = SPF_MAX_DNS_REQUESTS;
spf_lib_ctx->min_cache_ttl = SPF_MIN_CACHE_TTL;
spf_lib_ctx->disable_ipv6 = FALSE;
}
RSPAMD_DESTRUCTOR(rspamd_spf_lib_ctx_dtor)
{
if (spf_lib_ctx->spf_hash) {
rspamd_lru_hash_destroy(spf_lib_ctx->spf_hash);
}
g_free(spf_lib_ctx);
spf_lib_ctx = NULL;
}
static void
spf_record_cached_unref_dtor(gpointer p)
{
struct spf_resolved *flat = (struct spf_resolved *) p;
_spf_record_unref(flat, "LRU cache");
}
void spf_library_config(const ucl_object_t *obj)
{
const ucl_object_t *value;
int64_t ival;
bool bval;
if (obj == NULL) {
/* No specific config */
return;
}
if ((value = ucl_object_find_key(obj, "min_cache_ttl")) != NULL) {
if (ucl_object_toint_safe(value, &ival) && ival >= 0) {
spf_lib_ctx->min_cache_ttl = ival;
}
}
if ((value = ucl_object_find_key(obj, "max_dns_nesting")) != NULL) {
if (ucl_object_toint_safe(value, &ival) && ival >= 0) {
spf_lib_ctx->max_dns_nesting = ival;
}
}
if ((value = ucl_object_find_key(obj, "max_dns_requests")) != NULL) {
if (ucl_object_toint_safe(value, &ival) && ival >= 0) {
spf_lib_ctx->max_dns_requests = ival;
}
}
if ((value = ucl_object_find_key(obj, "disable_ipv6")) != NULL) {
if (ucl_object_toboolean_safe(value, &bval)) {
spf_lib_ctx->disable_ipv6 = bval;
}
}
if (spf_lib_ctx->spf_hash) {
rspamd_lru_hash_destroy(spf_lib_ctx->spf_hash);
spf_lib_ctx->spf_hash = NULL;
}
if ((value = ucl_object_find_key(obj, "spf_cache_size")) != NULL) {
if (ucl_object_toint_safe(value, &ival) && ival > 0) {
spf_lib_ctx->spf_hash = rspamd_lru_hash_new(
ival,
g_free,
spf_record_cached_unref_dtor);
}
}
else {
/* Preserve compatibility */
spf_lib_ctx->spf_hash = rspamd_lru_hash_new(
2048,
g_free,
spf_record_cached_unref_dtor);
}
}
static gboolean start_spf_parse(struct spf_record *rec,
struct spf_resolved_element *resolved, char *begin);
/* Determine spf mech */
static spf_mech_t
check_spf_mech(const char *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 const char *
rspamd_spf_dns_action_to_str(spf_action_t act)
{
const char *ret = "unknown";
switch (act) {
case SPF_RESOLVE_MX:
ret = "MX";
break;
case SPF_RESOLVE_A:
ret = "A";
break;
case SPF_RESOLVE_PTR:
ret = "PTR";
break;
case SPF_RESOLVE_AAA:
ret = "AAAA";
break;
case SPF_RESOLVE_REDIRECT:
ret = "REDIRECT";
break;
case SPF_RESOLVE_INCLUDE:
ret = "INCLUDE";
break;
case SPF_RESOLVE_EXISTS:
ret = "EXISTS";
break;
case SPF_RESOLVE_EXP:
ret = "EXP";
break;
}
return ret;
}
static struct spf_addr *
rspamd_spf_new_addr(struct spf_record *rec,
struct spf_resolved_element *resolved, const char *elt)
{
gboolean need_shift = FALSE;
struct spf_addr *naddr;
naddr = g_malloc0(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);
naddr->prev = naddr;
naddr->next = NULL;
return naddr;
}
static void
rspamd_spf_free_addr(gpointer a)
{
struct spf_addr *addr = a, *tmp, *cur;
if (addr) {
g_free(addr->spf_string);
DL_FOREACH_SAFE(addr, cur, tmp)
{
g_free(cur);
}
}
}
static struct spf_resolved_element *
rspamd_spf_new_addr_list(struct spf_record *rec, const char *domain)
{
struct spf_resolved_element *resolved;
resolved = g_malloc0(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;
unsigned int 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_free(elt);
}
g_ptr_array_free(rec->resolved, TRUE);
}
}
static void
rspamd_flatten_record_dtor(struct spf_resolved *r)
{
struct spf_addr *addr;
unsigned int 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->top_record);
g_free(r->domain);
g_array_free(r->elts, TRUE);
g_free(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, *relt;
struct spf_addr *cur = NULL, taddr, *cur_addr;
unsigned int 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);
}
if (rec->ttl < target->ttl) {
msg_debug_spf("reducing ttl from %d to %d after subrecord processing %s",
target->ttl, rec->ttl, rec->sender_domain);
target->ttl = rec->ttl;
}
if (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_REDIRECT) {
break;
}
}
g_assert(cur != NULL);
if (!(cur->flags & (RSPAMD_SPF_FLAG_PARSED | RSPAMD_SPF_FLAG_RESOLVED))) {
/* Unresolved redirect */
msg_info_spf("redirect to %s cannot be resolved for domain %s", cur->spf_string, rec->sender_domain);
}
else {
g_assert(cur->flags & RSPAMD_SPF_FLAG_REFERENCE);
g_assert(cur->m.idx < rec->resolved->len);
relt = g_ptr_array_index(rec->resolved, cur->m.idx);
msg_debug_spf("domain %s is redirected to %s", elt->cur_domain,
relt->cur_domain);
}
}
for (i = 0; i < elt->elts->len; i++) {
cur = g_ptr_array_index(elt->elts, i);
if (cur->flags & RSPAMD_SPF_FLAG_TEMPFAIL) {
target->flags |= RSPAMD_SPF_RESOLVED_TEMP_FAILED;
continue;
}
if (cur->flags & RSPAMD_SPF_FLAG_PERMFAIL) {
if (cur->flags & RSPAMD_SPF_FLAG_REDIRECT) {
target->flags |= RSPAMD_SPF_RESOLVED_PERM_FAILED;
}
continue;
}
if (cur->flags & RSPAMD_SPF_FLAG_NA) {
target->flags |= RSPAMD_SPF_RESOLVED_NA;
continue;
}
if (cur->flags & RSPAMD_SPF_FLAG_PLUSALL) {
target->flags |= RSPAMD_SPF_RESOLVED_PLUSALL;
}
if (cur->flags & RSPAMD_SPF_FLAG_INVALID) {
/* Ignore invalid elements */
continue;
}
if ((cur->flags & (RSPAMD_SPF_FLAG_PARSED | RSPAMD_SPF_FLAG_RESOLVED)) !=
(RSPAMD_SPF_FLAG_RESOLVED | RSPAMD_SPF_FLAG_PARSED)) {
/* Ignore unparsed addrs */
continue;
}
if (cur->flags & RSPAMD_SPF_FLAG_REFERENCE) {
/* Process reference */
if (cur->flags & RSPAMD_SPF_FLAG_REDIRECT) {
/* Stop on redirected domain */
rspamd_spf_process_reference(target, cur, rec, top);
break;
}
else {
rspamd_spf_process_reference(target, cur, rec, FALSE);
}
}
else {
if ((cur->flags & RSPAMD_SPF_FLAG_ANY) && !top) {
/* Ignore wide policies in includes */
continue;
}
DL_FOREACH(cur, cur_addr)
{
memcpy(&taddr, cur_addr, sizeof(taddr));
taddr.spf_string = g_strdup(cur_addr->spf_string);
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_malloc0(sizeof(*res));
res->domain = g_strdup(rec->sender_domain);
res->ttl = rec->ttl;
/* Not precise but okay */
res->timestamp = rec->task->task_timestamp;
res->digest = mum_hash_init(0xa4aa40bbeec59e2bULL);
res->top_record = g_strdup(rec->top_record);
REF_INIT_RETAIN(res, rspamd_flatten_record_dtor);
if (rec->resolved) {
res->elts = g_array_sized_new(FALSE, FALSE, sizeof(struct spf_addr),
rec->resolved->len);
if (rec->resolved->len > 0) {
rspamd_spf_process_reference(res, NULL, rec, TRUE);
}
}
else {
res->elts = g_array_new(FALSE, FALSE, sizeof(struct spf_addr));
}
return res;
}
static int
rspamd_spf_elts_cmp(gconstpointer a, gconstpointer b)
{
struct spf_addr *addr_a, *addr_b;
addr_a = (struct spf_addr *) a;
addr_b = (struct spf_addr *) b;
if (addr_a->flags == addr_b->flags) {
if (addr_a->flags & RSPAMD_SPF_FLAG_ANY) {
return 0;
}
else if (addr_a->flags & RSPAMD_SPF_FLAG_IPV4) {
return (addr_a->m.dual.mask_v4 - addr_b->m.dual.mask_v4) ||
memcmp(addr_a->addr4, addr_b->addr4, sizeof(addr_a->addr4));
}
else if (addr_a->flags & RSPAMD_SPF_FLAG_IPV6) {
return (addr_a->m.dual.mask_v6 - addr_b->m.dual.mask_v6) ||
memcmp(addr_a->addr6, addr_b->addr6, sizeof(addr_a->addr6));
}
else {
return 0;
}
}
else {
if (addr_a->flags & RSPAMD_SPF_FLAG_ANY) {
return 1;
}
else if (addr_b->flags & RSPAMD_SPF_FLAG_ANY) {
return -1;
}
else if (addr_a->flags & RSPAMD_SPF_FLAG_IPV4) {
return -1;
}
return 1;
}
}
static void
rspamd_spf_record_postprocess(struct spf_resolved *rec, struct rspamd_task *task)
{
g_array_sort(rec->elts, rspamd_spf_elts_cmp);
for (unsigned int i = 0; i < rec->elts->len; i++) {
struct spf_addr *cur_addr = &g_array_index(rec->elts, struct spf_addr, i);
if (cur_addr->flags & RSPAMD_SPF_FLAG_IPV6) {
uint64_t t[3];
/*
* Fill hash entry for ipv6 addr with 2 int64 from ipv6 address,
* the remaining int64 has mech + mask
*/
memcpy(t, cur_addr->addr6, sizeof(uint64_t) * 2);
t[2] = ((uint64_t) (cur_addr->mech)) << 48u;
t[2] |= cur_addr->m.dual.mask_v6;
for (unsigned int j = 0; j < G_N_ELEMENTS(t); j++) {
rec->digest = mum_hash_step(rec->digest, t[j]);
}
}
else if (cur_addr->flags & RSPAMD_SPF_FLAG_IPV4) {
uint64_t t = 0;
memcpy(&t, cur_addr->addr4, sizeof(uint32_t));
t |= ((uint64_t) (cur_addr->mech)) << 48u;
t |= ((uint64_t) cur_addr->m.dual.mask_v4) << 32u;
rec->digest = mum_hash_step(rec->digest, t);
}
}
if (spf_lib_ctx->min_cache_ttl > 0) {
if (rec->ttl != 0 && rec->ttl < spf_lib_ctx->min_cache_ttl) {
msg_info_task("increasing ttl from %d to %d as it lower than a limit",
rec->ttl, spf_lib_ctx->min_cache_ttl);
rec->ttl = spf_lib_ctx->min_cache_ttl;
}
}
}
static void
rspamd_spf_maybe_return(struct spf_record *rec)
{
struct spf_resolved *flat;
struct rspamd_task *task = rec->task;
bool cached = false;
if (rec->requests_inflight == 0 && !rec->done) {
flat = rspamd_spf_record_flatten(rec);
rspamd_spf_record_postprocess(flat, rec->task);
if (flat->ttl > 0 && flat->flags == 0) {
if (spf_lib_ctx->spf_hash) {
rspamd_lru_hash_insert(spf_lib_ctx->spf_hash,
g_strdup(flat->domain),
spf_record_ref(flat),
flat->timestamp, flat->ttl);
msg_info_task("stored SPF record for %s (0x%xuL) in LRU cache for %d seconds, "
"%d/%d elements in the cache",
flat->domain,
flat->digest,
flat->ttl,
rspamd_lru_hash_size(spf_lib_ctx->spf_hash),
rspamd_lru_hash_capacity(spf_lib_ctx->spf_hash));
cached = true;
}
}
if (!cached) {
/* Still write a log line */
msg_info_task("not stored SPF record for %s (0x%xuL) in LRU cache; flags=%d; ttl=%d",
flat->domain,
flat->digest,
flat->flags,
flat->ttl);
}
rec->callback(flat, rec->task, rec->cbdata);
spf_record_unref(flat);
rec->done = TRUE;
}
}
static gboolean
spf_check_ptr_host(struct spf_dns_cb *cb, const char *name)
{
const char *dend, *nend, *dstart, *nstart;
struct spf_record *rec = cb->rec;
if (cb->ptr_host != NULL) {
dstart = cb->ptr_host;
}
else {
dstart = cb->resolved->cur_domain;
}
if (name == NULL || dstart == NULL) {
return FALSE;
}
msg_debug_spf("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--;
}
if (nend <= nstart || dend <= dstart) {
return FALSE;
}
/* Now compare from end to start */
for (;;) {
if (g_ascii_tolower(*dend) != g_ascii_tolower(*nend)) {
msg_debug_spf("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_record *rec, struct spf_addr *addr, struct rdns_reply_entry *reply)
{
struct spf_addr *naddr;
if (!(addr->flags & RSPAMD_SPF_FLAG_PROCESSED)) {
/* That's the first address */
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_spf(
"internal error, bad DNS reply is treated as address: %s; domain: %s",
rdns_strtype(reply->type),
rec->sender_domain);
}
addr->flags |= RSPAMD_SPF_FLAG_PROCESSED;
}
else {
/* We need to create a new address */
naddr = g_malloc0(sizeof(*naddr));
memcpy(naddr, addr, sizeof(*naddr));
naddr->next = NULL;
naddr->prev = NULL;
if (reply->type == RDNS_REQUEST_AAAA) {
memcpy(naddr->addr6,
&reply->content.aaa.addr,
sizeof(addr->addr6));
naddr->flags |= RSPAMD_SPF_FLAG_IPV6;
}
else if (reply->type == RDNS_REQUEST_A) {
memcpy(naddr->addr4, &reply->content.a.addr, sizeof(addr->addr4));
naddr->flags |= RSPAMD_SPF_FLAG_IPV4;
}
else {
msg_err_spf(
"internal error, bad DNS reply is treated as address: %s; domain: %s",
rdns_strtype(reply->type),
rec->sender_domain);
}
DL_APPEND(addr, naddr);
}
}
static void
spf_record_addr_set(struct spf_addr *addr, gboolean allow_any)
{
unsigned char fill;
if (!(addr->flags & RSPAMD_SPF_FLAG_PROCESSED)) {
if (allow_any) {
fill = 0;
addr->m.dual.mask_v4 = 0;
addr->m.dual.mask_v6 = 0;
}
else {
fill = 0xff;
}
memset(addr->addr4, fill, sizeof(addr->addr4));
memset(addr->addr6, fill, sizeof(addr->addr6));
addr->flags |= RSPAMD_SPF_FLAG_IPV4;
addr->flags |= RSPAMD_SPF_FLAG_IPV6;
}
}
static gboolean
spf_process_txt_record(struct spf_record *rec, struct spf_resolved_element *resolved,
struct rdns_reply *reply, struct rdns_reply_entry **pselected)
{
struct rdns_reply_entry *elt, *selected = NULL;
gboolean ret = FALSE;
/*
* We prefer spf version 1 as other records are mostly likely garbage
* or incorrect records (e.g. spf2 records)
*/
LL_FOREACH(reply->entries, elt)
{
if (elt->type == RDNS_REQUEST_TXT) {
if (strncmp(elt->content.txt.data, "v=spf1", sizeof("v=spf1") - 1) == 0) {
selected = elt;
if (pselected != NULL) {
*pselected = selected;
}
break;
}
}
}
if (!selected) {
LL_FOREACH(reply->entries, elt)
{
/*
* Rubbish spf record? Let's still try to process it, but merely for
* TXT RRs
*/
if (elt->type == RDNS_REQUEST_TXT) {
if (start_spf_parse(rec, resolved, elt->content.txt.data)) {
ret = TRUE;
if (pselected != NULL) {
*pselected = elt;
}
break;
}
}
}
}
else {
ret = start_spf_parse(rec, resolved, selected->content.txt.data);
}
return ret;
}
static void
spf_record_dns_callback(struct rdns_reply *reply, gpointer arg)
{
struct spf_dns_cb *cb = arg;
struct rdns_reply_entry *elt_data;
struct rspamd_task *task;
struct spf_addr *addr;
struct spf_record *rec;
const struct rdns_request_name *req_name;
bool truncated = false;
rec = cb->rec;
task = rec->task;
cb->rec->requests_inflight--;
addr = cb->addr;
req_name = rdns_request_get_name(reply->request, NULL);
if (reply->flags & RDNS_TRUNCATED) {
/* Do not process truncated DNS replies */
truncated = true;
if (req_name) {
msg_notice_spf("got a truncated record when trying to resolve %s (%s type) for SPF domain %s",
req_name->name, rdns_str_from_type(req_name->type),
rec->sender_domain);
}
else {
msg_notice_spf("got a truncated record when trying to resolve ??? "
"(internal error) for SPF domain %s",
rec->sender_domain);
}
}
if (reply->code == RDNS_RC_NOERROR && !truncated) {
LL_FOREACH(reply->entries, elt_data)
{
/* Adjust ttl if a resolved record has lower ttl than spf record itself */
if ((unsigned int) elt_data->ttl < rec->ttl) {
msg_debug_spf("reducing ttl from %d to %d after DNS resolving",
rec->ttl, elt_data->ttl);
rec->ttl = elt_data->ttl;
}
if (elt_data->type == RDNS_REQUEST_CNAME) {
/* Skip cname aliases - it must be handled by a recursor */
continue;
}
switch (cb->cur_action) {
case SPF_RESOLVE_MX:
if (elt_data->type == RDNS_REQUEST_MX) {
/* Now resolve A record for this MX */
msg_debug_spf("resolve %s after resolving of MX",
elt_data->content.mx.name);
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb,
RDNS_REQUEST_A,
elt_data->content.mx.name)) {
cb->rec->requests_inflight++;
}
if (!spf_lib_ctx->disable_ipv6) {
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb,
RDNS_REQUEST_AAAA,
elt_data->content.mx.name)) {
cb->rec->requests_inflight++;
}
}
else {
msg_debug_spf("skip AAAA request for MX resolution");
}
}
else {
cb->addr->flags |= RSPAMD_SPF_FLAG_RESOLVED;
cb->addr->flags &= ~RSPAMD_SPF_FLAG_PERMFAIL;
msg_debug_spf("resolved MX addr");
spf_record_process_addr(rec, addr, elt_data);
}
break;
case SPF_RESOLVE_A:
case SPF_RESOLVE_AAA:
cb->addr->flags |= RSPAMD_SPF_FLAG_RESOLVED;
cb->addr->flags &= ~RSPAMD_SPF_FLAG_PERMFAIL;
spf_record_process_addr(rec, 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_spf("resolve PTR %s after resolving of PTR",
elt_data->content.ptr.name);
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb,
RDNS_REQUEST_A,
elt_data->content.ptr.name)) {
cb->rec->requests_inflight++;
}
if (!spf_lib_ctx->disable_ipv6) {
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb,
RDNS_REQUEST_AAAA,
elt_data->content.ptr.name)) {
cb->rec->requests_inflight++;
}
}
else {
msg_debug_spf("skip AAAA request for PTR resolution");
}
}
else {
cb->addr->flags |= RSPAMD_SPF_FLAG_RESOLVED;
cb->addr->flags &= ~RSPAMD_SPF_FLAG_PERMFAIL;
}
}
else {
cb->addr->flags |= RSPAMD_SPF_FLAG_RESOLVED;
cb->addr->flags &= ~RSPAMD_SPF_FLAG_PERMFAIL;
spf_record_process_addr(rec, addr, elt_data);
}
break;
case SPF_RESOLVE_REDIRECT:
if (elt_data->type == RDNS_REQUEST_TXT) {
cb->addr->flags |= RSPAMD_SPF_FLAG_RESOLVED;
if (reply->entries) {
msg_debug_spf("got redirection record for %s: '%s'",
req_name->name,
reply->entries[0].content.txt.data);
}
if (!spf_process_txt_record(rec, cb->resolved, reply, NULL)) {
cb->addr->flags |= RSPAMD_SPF_FLAG_PERMFAIL;
}
}
goto end;
break;
case SPF_RESOLVE_INCLUDE:
if (elt_data->type == RDNS_REQUEST_TXT) {
struct rdns_reply_entry *selected = NULL;
cb->addr->flags |= RSPAMD_SPF_FLAG_RESOLVED;
spf_process_txt_record(rec, cb->resolved, reply, &selected);
if (selected) {
msg_debug_spf("got include record for %s: '%s'",
req_name->name,
selected->content.txt.data);
}
else {
msg_debug_spf("no include record for %s",
req_name->name);
}
}
goto end;
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
*/
addr->flags |= RSPAMD_SPF_FLAG_RESOLVED;
spf_record_addr_set(addr, TRUE);
}
break;
}
}
}
else if (reply->code == RDNS_RC_NXDOMAIN || reply->code == RDNS_RC_NOREC) {
switch (cb->cur_action) {
case SPF_RESOLVE_MX:
if (!(cb->addr->flags & RSPAMD_SPF_FLAG_RESOLVED)) {
cb->addr->flags |= RSPAMD_SPF_FLAG_PERMFAIL;
msg_info_spf(
"spf error for domain %s: cannot find MX"
" record for %s: %s",
cb->rec->sender_domain,
cb->resolved->cur_domain,
rdns_strerror(reply->code));
spf_record_addr_set(addr, FALSE);
}
break;
case SPF_RESOLVE_A:
if (!(cb->addr->flags & RSPAMD_SPF_FLAG_RESOLVED)) {
cb->addr->flags |= RSPAMD_SPF_FLAG_PERMFAIL;
msg_info_spf(
"spf error for domain %s: cannot resolve A"
" record for %s: %s",
cb->rec->sender_domain,
cb->resolved->cur_domain,
rdns_strerror(reply->code));
if (rdns_request_has_type(reply->request, RDNS_REQUEST_A)) {
spf_record_addr_set(addr, FALSE);
}
}
break;
case SPF_RESOLVE_AAA:
if (!(cb->addr->flags & RSPAMD_SPF_FLAG_RESOLVED)) {
cb->addr->flags |= RSPAMD_SPF_FLAG_PERMFAIL;
msg_info_spf(
"spf error for domain %s: cannot resolve AAAA"
" record for %s: %s",
cb->rec->sender_domain,
cb->resolved->cur_domain,
rdns_strerror(reply->code));
if (rdns_request_has_type(reply->request, RDNS_REQUEST_AAAA)) {
spf_record_addr_set(addr, FALSE);
}
}
break;
case SPF_RESOLVE_PTR:
if (!(cb->addr->flags & RSPAMD_SPF_FLAG_RESOLVED)) {
msg_info_spf(
"spf error for domain %s: cannot resolve PTR"
" record for %s: %s",
cb->rec->sender_domain,
cb->resolved->cur_domain,
rdns_strerror(reply->code));
cb->addr->flags |= RSPAMD_SPF_FLAG_PERMFAIL;
spf_record_addr_set(addr, FALSE);
}
break;
case SPF_RESOLVE_REDIRECT:
if (!(cb->addr->flags & RSPAMD_SPF_FLAG_RESOLVED)) {
cb->addr->flags |= RSPAMD_SPF_FLAG_PERMFAIL;
msg_info_spf(
"spf error for domain %s: cannot resolve REDIRECT"
" record for %s: %s",
cb->rec->sender_domain,
cb->resolved->cur_domain,
rdns_strerror(reply->code));
}
break;
case SPF_RESOLVE_INCLUDE:
if (!(cb->addr->flags & RSPAMD_SPF_FLAG_RESOLVED)) {
msg_info_spf(
"spf error for domain %s: cannot resolve INCLUDE"
" record for %s: %s",
cb->rec->sender_domain,
cb->resolved->cur_domain,
rdns_strerror(reply->code));
cb->addr->flags |= RSPAMD_SPF_FLAG_PERMFAIL;
}
break;
case SPF_RESOLVE_EXP:
break;
case SPF_RESOLVE_EXISTS:
if (!(cb->addr->flags & RSPAMD_SPF_FLAG_RESOLVED)) {
msg_debug_spf(
"spf macro resolution for domain %s: cannot resolve EXISTS"
" macro for %s: %s",
cb->rec->sender_domain,
cb->resolved->cur_domain,
rdns_strerror(reply->code));
spf_record_addr_set(addr, FALSE);
}
break;
}
}
else {
cb->addr->flags |= RSPAMD_SPF_FLAG_TEMPFAIL;
msg_info_spf(
"spf error for domain %s: cannot resolve %s DNS record for"
" %s: %s",
cb->rec->sender_domain,
rspamd_spf_dns_action_to_str(cb->cur_action),
cb->ptr_host,
rdns_strerror(reply->code));
}
end:
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 char *
parse_spf_domain_mask(struct spf_record *rec, struct spf_addr *addr,
struct spf_resolved_element *resolved,
gboolean allow_mask)
{
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_garbage
} state = 0;
const char *p = addr->spf_string, *host, *c;
char *hostbuf;
char t;
uint16_t cur_mask = 0;
host = resolved->cur_domain;
c = p;
while (*p) {
t = *p;
switch (state) {
case parse_spf_elt:
if (t == ':' || 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;
}
else {
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_garbage;
}
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_notice_spf("bad ipv4 mask for %s: %d",
rec->sender_domain, 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_garbage:
p++;
break;
}
}
/* Process end states */
if (state == parse_ipv4_mask) {
if (cur_mask <= 32) {
addr->m.dual.mask_v4 = cur_mask;
}
else {
msg_notice_spf("bad ipv4 mask for %s: %d", rec->sender_domain, cur_mask);
}
}
else if (state == parse_ipv6_mask) {
if (cur_mask <= 128) {
addr->m.dual.mask_v6 = cur_mask;
}
else {
msg_notice_spf("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;
}
if (cur_mask == 0) {
addr->m.dual.mask_v4 = 32;
addr->m.dual.mask_v6 = 64;
}
return host;
}
static gboolean
parse_spf_a(struct spf_record *rec,
struct spf_resolved_element *resolved, struct spf_addr *addr)
{
struct spf_dns_cb *cb;
const char *host = NULL;
struct rspamd_task *task = rec->task;
CHECK_REC(rec);
host = parse_spf_domain_mask(rec, addr, resolved, 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->ptr_host = host;
cb->addr = addr;
cb->cur_action = SPF_RESOLVE_A;
cb->resolved = resolved;
msg_debug_spf("resolve a %s", host);
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb, RDNS_REQUEST_A, host)) {
rec->requests_inflight++;
cb = rspamd_mempool_alloc(task->task_pool, sizeof(struct spf_dns_cb));
cb->rec = rec;
cb->ptr_host = host;
cb->addr = addr;
cb->cur_action = SPF_RESOLVE_AAA;
cb->resolved = resolved;
if (!spf_lib_ctx->disable_ipv6) {
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb, RDNS_REQUEST_AAAA, host)) {
rec->requests_inflight++;
}
}
else {
msg_debug_spf("skip AAAA request for a record resolution");
}
return TRUE;
}
else {
msg_notice_spf("unresolvable A element for %s: %s", addr->spf_string,
rec->sender_domain);
}
return FALSE;
}
static gboolean
parse_spf_ptr(struct spf_record *rec,
struct spf_resolved_element *resolved, struct spf_addr *addr)
{
struct spf_dns_cb *cb;
const char *host;
char *ptr;
struct rspamd_task *task = rec->task;
CHECK_REC(rec);
host = parse_spf_domain_mask(rec, addr, resolved, 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_spf("resolve ptr %s for %s", ptr, host);
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb, RDNS_REQUEST_PTR, ptr)) {
rec->requests_inflight++;
rec->ttl = 0;
msg_debug_spf("disable SPF caching as there is PTR expansion");
return TRUE;
}
else {
msg_notice_spf("unresolvable PTR element for %s: %s", addr->spf_string,
rec->sender_domain);
}
return FALSE;
}
static gboolean
parse_spf_mx(struct spf_record *rec,
struct spf_resolved_element *resolved, struct spf_addr *addr)
{
struct spf_dns_cb *cb;
const char *host;
struct rspamd_task *task = rec->task;
CHECK_REC(rec);
host = parse_spf_domain_mask(rec, addr, resolved, 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->ptr_host = host;
cb->resolved = resolved;
msg_debug_spf("resolve mx for %s", host);
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb, RDNS_REQUEST_MX, host)) {
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 | RSPAMD_SPF_FLAG_RESOLVED;
msg_debug_spf("parsed all elt");
/* Disallow +all */
if (addr->mech == SPF_PASS) {
addr->flags |= RSPAMD_SPF_FLAG_PLUSALL;
msg_notice_spf("domain %s allows any SPF (+all), ignore SPF record completely",
rec->sender_domain);
}
return TRUE;
}
static gboolean
parse_spf_ip4(struct spf_record *rec, struct spf_addr *addr)
{
/* ip4:addr[/mask] */
const char *semicolon, *slash;
gsize len;
char ipbuf[INET_ADDRSTRLEN + 1];
uint32_t mask;
static const uint32_t min_valid_mask = 8;
semicolon = strchr(addr->spf_string, ':');
if (semicolon == NULL) {
semicolon = strchr(addr->spf_string, '=');
if (semicolon == NULL) {
msg_notice_spf("invalid ip4 element for %s: %s, no '=' or ':'", addr->spf_string,
rec->sender_domain);
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) {
msg_notice_spf("invalid ip4 element for %s: %s", addr->spf_string,
rec->sender_domain);
return FALSE;
}
if (slash) {
char *end = NULL;
mask = strtoul(slash + 1, &end, 10);
if (mask > 32) {
msg_notice_spf("invalid mask for ip4 element for %s: %s", addr->spf_string,
rec->sender_domain);
return FALSE;
}
if (end != NULL && !g_ascii_isspace(*end) && *end != '\0') {
/* Invalid mask definition */
msg_notice_spf("invalid mask for ip4 element for %s: %s", addr->spf_string,
rec->sender_domain);
return FALSE;
}
addr->m.dual.mask_v4 = mask;
if (mask < min_valid_mask) {
addr->flags |= RSPAMD_SPF_FLAG_INVALID;
msg_notice_spf("too wide SPF record for %s: %s/%d",
rec->sender_domain,
ipbuf, addr->m.dual.mask_v4);
}
}
else {
addr->m.dual.mask_v4 = 32;
}
addr->flags |= RSPAMD_SPF_FLAG_IPV4 | RSPAMD_SPF_FLAG_RESOLVED;
msg_debug_spf("parsed ipv4 record %s/%d", ipbuf, addr->m.dual.mask_v4);
return TRUE;
}
static gboolean
parse_spf_ip6(struct spf_record *rec, struct spf_addr *addr)
{
/* ip6:addr[/mask] */
const char *semicolon, *slash;
gsize len;
char ipbuf[INET6_ADDRSTRLEN + 1];
uint32_t mask;
static const uint32_t min_valid_mask = 8;
semicolon = strchr(addr->spf_string, ':');
if (semicolon == NULL) {
semicolon = strchr(addr->spf_string, '=');
if (semicolon == NULL) {
msg_notice_spf("invalid ip6 element for %s: %s", addr->spf_string,
rec->sender_domain);
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) {
msg_notice_spf("invalid ip6 element for %s: %s", addr->spf_string,
rec->sender_domain);
return FALSE;
}
if (slash) {
char *end = NULL;
mask = strtoul(slash + 1, &end, 10);
if (mask > 128) {
msg_notice_spf("invalid mask for ip6 element for %s: %s", addr->spf_string,
rec->sender_domain);
return FALSE;
}
if (end != NULL && !g_ascii_isspace(*end) && *end != '\0') {
/* Invalid mask definition */
msg_notice_spf("invalid mask for ip4 element for %s: %s", addr->spf_string,
rec->sender_domain);
return FALSE;
}
addr->m.dual.mask_v6 = mask;
if (mask < min_valid_mask) {
addr->flags |= RSPAMD_SPF_FLAG_INVALID;
msg_notice_spf("too wide SPF record for %s: %s/%d",
rec->sender_domain,
ipbuf, addr->m.dual.mask_v6);
}
}
else {
addr->m.dual.mask_v6 = 128;
}
addr->flags |= RSPAMD_SPF_FLAG_IPV6 | RSPAMD_SPF_FLAG_RESOLVED;
msg_debug_spf("parsed ipv6 record %s/%d", ipbuf, addr->m.dual.mask_v6);
return TRUE;
}
static gboolean
parse_spf_include(struct spf_record *rec, struct spf_addr *addr)
{
struct spf_dns_cb *cb;
const char *domain;
struct rspamd_task *task = rec->task;
CHECK_REC(rec);
domain = strchr(addr->spf_string, ':');
if (domain == NULL) {
/* Common mistake */
domain = strchr(addr->spf_string, '=');
if (domain == NULL) {
msg_notice_spf("invalid include element for %s: %s", addr->spf_string,
rec->sender_domain);
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);
cb->ptr_host = domain;
/* Set reference */
addr->flags |= RSPAMD_SPF_FLAG_REFERENCE;
msg_debug_spf("resolve include %s", domain);
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb, RDNS_REQUEST_TXT, domain)) {
rec->requests_inflight++;
return TRUE;
}
else {
msg_notice_spf("unresolvable include element for %s: %s", addr->spf_string,
rec->sender_domain);
}
return FALSE;
}
static gboolean
parse_spf_exp(struct spf_record *rec, struct spf_addr *addr)
{
msg_info_spf("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 char *domain;
struct rspamd_task *task = rec->task;
CHECK_REC(rec);
domain = strchr(addr->spf_string, '=');
if (domain == NULL) {
/* Common mistake */
domain = strchr(addr->spf_string, ':');
if (domain == NULL) {
msg_notice_spf("invalid redirect element for %s: %s", addr->spf_string,
rec->sender_domain);
return FALSE;
}
}
domain++;
rec->dns_requests++;
resolved->redirected = TRUE;
cb = rspamd_mempool_alloc(task->task_pool, sizeof(struct spf_dns_cb));
/* Set reference */
addr->flags |= RSPAMD_SPF_FLAG_REFERENCE | RSPAMD_SPF_FLAG_REDIRECT;
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);
cb->ptr_host = domain;
msg_debug_spf("resolve redirect %s", domain);
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb, RDNS_REQUEST_TXT, domain)) {
rec->requests_inflight++;
return TRUE;
}
else {
msg_notice_spf("unresolvable redirect element for %s: %s", addr->spf_string,
rec->sender_domain);
}
return FALSE;
}
static gboolean
parse_spf_exists(struct spf_record *rec, struct spf_addr *addr)
{
struct spf_dns_cb *cb;
const char *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) {
host = strchr(addr->spf_string, '=');
if (host == NULL) {
msg_notice_spf("invalid exists element for %s: %s", addr->spf_string,
rec->sender_domain);
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;
cb->ptr_host = host;
msg_debug_spf("resolve exists %s", host);
if (rspamd_dns_resolver_request_task_forced(task,
spf_record_dns_callback, (void *) cb, RDNS_REQUEST_A, host)) {
rec->requests_inflight++;
return TRUE;
}
else {
msg_notice_spf("unresolvable exists element for %s: %s", addr->spf_string,
rec->sender_domain);
}
return FALSE;
}
static gsize
rspamd_spf_split_elt(const char *val, gsize len, int *pos,
gsize poslen, char delim)
{
const char *p, *end;
unsigned int cur_pos = 0, cur_st = 0, nsub = 0;
p = val;
end = val + len;
while (p < end && cur_pos + 2 < poslen) {
if (*p == delim) {
if (p - val > cur_st) {
pos[cur_pos] = cur_st;
pos[cur_pos + 1] = p - val;
cur_st = p - val + 1;
cur_pos += 2;
nsub++;
}
p++;
}
else {
p++;
}
}
if (cur_pos + 2 < poslen) {
if (end - val > cur_st) {
pos[cur_pos] = cur_st;
pos[cur_pos + 1] = end - val;
nsub++;
}
}
else {
pos[cur_pos] = p - val;
pos[cur_pos + 1] = end - val;
nsub++;
}
return nsub;
}
static gsize
rspamd_spf_process_substitution(const char *macro_value,
gsize macro_len, unsigned int ndelim, char delim, gboolean reversed,
char *dest)
{
char *d = dest;
const char canon_delim = '.';
unsigned int vlen, i;
int pos[49 * 2], tlen;
if (!reversed && ndelim == 0 && delim == canon_delim) {
/* Trivial case */
memcpy(dest, macro_value, macro_len);
return macro_len;
}
vlen = rspamd_spf_split_elt(macro_value, macro_len,
pos, G_N_ELEMENTS(pos), delim);
if (vlen > 0) {
if (reversed) {
for (i = vlen - 1;; i--) {
tlen = pos[i * 2 + 1] - pos[i * 2];
if (i != 0) {
memcpy(d, ¯o_value[pos[i * 2]], tlen);
d += tlen;
*d++ = canon_delim;
}
else {
memcpy(d, ¯o_value[pos[i * 2]], tlen);
d += tlen;
break;
}
}
}
else {
for (i = 0; i < vlen; i++) {
tlen = pos[i * 2 + 1] - pos[i * 2];
if (i != vlen - 1) {
memcpy(d, ¯o_value[pos[i * 2]], tlen);
d += tlen;
*d++ = canon_delim;
}
else {
memcpy(d, ¯o_value[pos[i * 2]], tlen);
d += tlen;
}
}
}
}
else {
/* Trivial case */
memcpy(dest, macro_value, macro_len);
return macro_len;
}
return (d - dest);
}
static const char *
expand_spf_macro(struct spf_record *rec, struct spf_resolved_element *resolved,
const char *begin)
{
const char *p, *macro_value = NULL;
char *c, *new, *tmp, delim = '.';
gsize len = 0, macro_len = 0;
int state = 0, ndelim = 0;
char ip_buf[64 + 1]; /* cannot use INET6_ADDRSTRLEN as we use ptr lookup */
gboolean need_expand = FALSE, reversed;
struct rspamd_task *task;
g_assert(rec != NULL);
g_assert(begin != NULL);
task = rec->task;
p = begin;
/* Calculate length */
while (*p) {
switch (state) {
case 0:
/* Skip any character and wait for % in input */
if (*p == '%') {
state = 1;
}
else {
len++;
}
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_notice_spf(
"spf error for domain %s: unknown spf element",
rec->sender_domain);
return begin;
}
p++;
break;
case 2:
/* Read macro name */
switch (g_ascii_tolower(*p)) {
case 'i':
len += sizeof(ip_buf) - 1;
break;
case 's':
if (rec->sender) {
len += strlen(rec->sender);
}
else {
len += sizeof("unknown") - 1;
}
break;
case 'l':
if (rec->local_part) {
len += strlen(rec->local_part);
}
else {
len += sizeof("unknown") - 1;
}
break;
case 'o':
if (rec->sender_domain) {
len += strlen(rec->sender_domain);
}
else {
len += sizeof("unknown") - 1;
}
break;
case 'd':
if (resolved->cur_domain) {
len += strlen(resolved->cur_domain);
}
else {
len += sizeof("unknown") - 1;
}
break;
case 'v':
len += sizeof("in-addr") - 1;
break;
case 'h':
if (task->helo) {
len += strlen(task->helo);
}
else {
len += sizeof("unknown") - 1;
}
break;
default:
msg_notice_spf(
"spf error for domain %s: unknown or "
"unsupported spf macro %c in %s",
rec->sender_domain,
*p,
begin);
return begin;
}
p++;
state = 3;
break;
case 3:
/* Read modifier */
if (*p == '}') {
state = 0;
need_expand = TRUE;
}
p++;
break;
default:
g_assert_not_reached();
}
}
if (!need_expand) {
/* No expansion needed */
return begin;
}
new = rspamd_mempool_alloc(task->task_pool, len + 1);
/* Reduce TTL to avoid caching of records with macros */
if (rec->ttl != 0) {
rec->ttl = 0;
msg_debug_spf("disable SPF caching as there is macro expansion");
}
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_spf(
"spf error for domain %s: unknown spf element",
rec->sender_domain);
return begin;
}
p++;
break;
case 2:
/* Read macro name */
switch (g_ascii_tolower(*p)) {
case 'i':
if (task->from_addr) {
if (rspamd_inet_address_get_af(task->from_addr) == AF_INET) {
macro_len = rspamd_strlcpy(ip_buf,
rspamd_inet_address_to_string(task->from_addr),
sizeof(ip_buf));
macro_value = ip_buf;
}
else if (rspamd_inet_address_get_af(task->from_addr) == AF_INET6) {
/* See #3625 for details */
socklen_t slen;
struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *)
rspamd_inet_address_get_sa(task->from_addr, &slen);
/* Expand IPv6 address */
#define IPV6_OCTET(x) bytes[(x)] >> 4, bytes[(x)] & 0xF
unsigned char *bytes = (unsigned char *) &sin6->sin6_addr;
macro_len = rspamd_snprintf(ip_buf, sizeof(ip_buf),
"%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd."
"%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd.%xd",
IPV6_OCTET(0), IPV6_OCTET(1),
IPV6_OCTET(2), IPV6_OCTET(3),
IPV6_OCTET(4), IPV6_OCTET(5),
IPV6_OCTET(6), IPV6_OCTET(7),
IPV6_OCTET(8), IPV6_OCTET(9),
IPV6_OCTET(10), IPV6_OCTET(11),
IPV6_OCTET(12), IPV6_OCTET(13),
IPV6_OCTET(14), IPV6_OCTET(15));
macro_value = ip_buf;
#undef IPV6_OCTET
}
else {
macro_len = rspamd_snprintf(ip_buf, sizeof(ip_buf),
"127.0.0.1");
macro_value = ip_buf;
}
}
else {
macro_len = rspamd_snprintf(ip_buf, sizeof(ip_buf),
"127.0.0.1");
macro_value = ip_buf;
}
break;
case 's':
if (rec->sender) {
macro_len = strlen(rec->sender);
macro_value = rec->sender;
}
else {
macro_len = sizeof("unknown") - 1;
macro_value = "unknown";
}
break;
case 'l':
if (rec->local_part) {
macro_len = strlen(rec->local_part);
macro_value = rec->local_part;
}
else {
macro_len = sizeof("unknown") - 1;
macro_value = "unknown";
}
break;
case 'o':
if (rec->sender_domain) {
macro_len = strlen(rec->sender_domain);
macro_value = rec->sender_domain;
}
else {
macro_len = sizeof("unknown") - 1;
macro_value = "unknown";
}
break;
case 'd':
if (resolved && resolved->cur_domain) {
macro_len = strlen(resolved->cur_domain);
macro_value = resolved->cur_domain;
}
else {
macro_len = sizeof("unknown") - 1;
macro_value = "unknown";
}
break;
case 'v':
if (task->from_addr) {
if (rspamd_inet_address_get_af(task->from_addr) == AF_INET) {
macro_len = sizeof("in-addr") - 1;
macro_value = "in-addr";
}
else {
macro_len = sizeof("ip6") - 1;
macro_value = "ip6";
}
}
else {
macro_len = sizeof("in-addr") - 1;
macro_value = "in-addr";
}
break;
case 'h':
if (task->helo) {
tmp = strchr(task->helo, '@');
if (tmp) {
macro_len = strlen(tmp + 1);
macro_value = tmp + 1;
}
else {
macro_len = strlen(task->helo);
macro_value = task->helo;
}
}
else {
macro_len = sizeof("unknown") - 1;
macro_value = "unknown";
}
break;
default:
msg_info_spf(
"spf error for domain %s: unknown or "
"unsupported spf macro %c in %s",
rec->sender_domain,
*p,
begin);
return begin;
}
p++;
state = 3;
ndelim = 0;
delim = '.';
reversed = FALSE;
break;
case 3:
/* Read modifier */
if (*p == '}') {
state = 0;
len = rspamd_spf_process_substitution(macro_value,
macro_len, ndelim, delim, reversed, c);
c += len;
}
else if (*p == 'r' && len != 0) {
reversed = TRUE;
}
else if (g_ascii_isdigit(*p)) {
ndelim = strtoul(p, &tmp, 10);
if (tmp == NULL || tmp == p) {
p++;
}
else {
p = tmp;
continue;
}
}
else if (*p == '+' || *p == '-' ||
*p == '.' || *p == ',' || *p == '/' || *p == '_' ||
*p == '=') {
delim = *p;
}
else {
msg_info_spf("spf error for domain %s: unknown or "
"unsupported spf macro %c in %s",
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
spf_process_element(struct spf_record *rec,
struct spf_resolved_element *resolved,
const char *elt,
const char **elts)
{
struct spf_addr *addr = NULL;
gboolean res = FALSE;
const char *begin;
char t;
g_assert(elt != NULL);
g_assert(rec != NULL);
if (*elt == '\0' || resolved->redirected) {
return TRUE;
}
begin = expand_spf_macro(rec, resolved, 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, resolved, addr);
}
else {
msg_notice_spf("spf error for domain %s: bad spf command %s",
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 if (g_ascii_strncasecmp(begin, SPF_IP4_ALT, sizeof(SPF_IP4_ALT) - 1) == 0) {
res = parse_spf_ip4(rec, addr);
}
else if (g_ascii_strncasecmp(begin, SPF_IP6_ALT, sizeof(SPF_IP6_ALT) - 1) == 0) {
res = parse_spf_ip6(rec, addr);
}
else {
msg_notice_spf("spf error for domain %s: bad spf command %s",
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, resolved, addr);
}
else {
msg_notice_spf("spf error for domain %s: bad spf command %s",
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, resolved, addr);
}
else {
msg_notice_spf("spf error for domain %s: bad spf command %s",
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_notice_spf("spf error for domain %s: bad spf command %s",
rec->sender_domain, begin);
}
break;
case 'r':
/* redirect */
if (g_ascii_strncasecmp(begin, SPF_REDIRECT,
sizeof(SPF_REDIRECT) - 1) == 0) {
/*
* According to https://tools.ietf.org/html/rfc7208#section-6.1
* There must be no ALL element anywhere in the record,
* redirect must be ignored
*/
gboolean ignore_redirect = FALSE;
for (const char **tmp = elts; *tmp != NULL; tmp++) {
if (g_ascii_strcasecmp((*tmp) + 1, "all") == 0) {
ignore_redirect = TRUE;
break;
}
}
if (!ignore_redirect) {
res = parse_spf_redirect(rec, resolved, addr);
}
else {
msg_notice_spf("ignore SPF redirect (%s) for domain %s as there is also all element",
begin, rec->sender_domain);
/* Pop the current addr as it is ignored */
g_ptr_array_remove_index_fast(resolved->elts,
resolved->elts->len - 1);
return TRUE;
}
}
else {
msg_notice_spf("spf error for domain %s: bad spf command %s",
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_notice_spf("spf error for domain %s: bad spf command %s",
rec->sender_domain, begin);
break;
}
if (res) {
addr->flags |= RSPAMD_SPF_FLAG_PARSED;
}
return res;
}
static void
parse_spf_scopes(struct spf_record *rec, char **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 standard 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,
char *begin)
{
char **elts, **cur_elt;
gsize len;
/* Skip spaces */
while (g_ascii_isspace(*begin)) {
begin++;
}
len = strlen(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_notice_spf("spf error for domain %s: sender id is invalid",
rec->sender_domain);
}
else {
begin++;
parse_spf_scopes(rec, &begin);
}
/* Now common spf record */
}
else {
msg_debug_spf(
"spf error for domain %s: bad spf record start: %*s",
rec->sender_domain,
(int) len,
begin);
return FALSE;
}
while (g_ascii_isspace(*begin) && *begin) {
begin++;
}
elts = g_strsplit_set(begin, " ", 0);
if (elts) {
cur_elt = elts;
while (*cur_elt) {
spf_process_element(rec, resolved, *cur_elt, (const char **) elts);
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 spf_resolved_element *resolved = NULL;
struct spf_addr *addr;
rec->requests_inflight--;
if (reply->flags & RDNS_TRUNCATED) {
msg_warn_spf("got a truncated record when trying to resolve TXT record for %s",
rec->sender_domain);
resolved = rspamd_spf_new_addr_list(rec, rec->sender_domain);
addr = g_malloc0(sizeof(*addr));
addr->flags |= RSPAMD_SPF_FLAG_TEMPFAIL;
g_ptr_array_insert(resolved->elts, 0, addr);
rspamd_spf_maybe_return(rec);
return;
}
else {
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;
}
}
else if ((reply->code == RDNS_RC_NOREC || reply->code == RDNS_RC_NXDOMAIN) && rec->dns_requests == 0) {
resolved = rspamd_spf_new_addr_list(rec, rec->sender_domain);
addr = g_malloc0(sizeof(*addr));
addr->flags |= RSPAMD_SPF_FLAG_NA;
g_ptr_array_insert(resolved->elts, 0, addr);
}
else if (reply->code != RDNS_RC_NOREC && reply->code != RDNS_RC_NXDOMAIN && rec->dns_requests == 0) {
resolved = rspamd_spf_new_addr_list(rec, rec->sender_domain);
addr = g_malloc0(sizeof(*addr));
addr->flags |= RSPAMD_SPF_FLAG_TEMPFAIL;
g_ptr_array_insert(resolved->elts, 0, addr);
}
}
if (resolved) {
struct rdns_reply_entry *selected = NULL;
if (!spf_process_txt_record(rec, resolved, reply, &selected)) {
resolved = g_ptr_array_index(rec->resolved, 0);
if (rec->resolved->len > 1) {
addr = g_ptr_array_index(resolved->elts, 0);
if ((reply->code == RDNS_RC_NOREC || reply->code == RDNS_RC_NXDOMAIN) && (addr->flags & RSPAMD_SPF_FLAG_REDIRECT)) {
addr->flags |= RSPAMD_SPF_FLAG_PERMFAIL;
}
else {
addr->flags |= RSPAMD_SPF_FLAG_TEMPFAIL;
}
}
else {
addr = g_malloc0(sizeof(*addr));
if (reply->code == RDNS_RC_NOREC || reply->code == RDNS_RC_NXDOMAIN || reply->code == RDNS_RC_NOERROR) {
addr->flags |= RSPAMD_SPF_FLAG_NA;
}
else {
addr->flags |= RSPAMD_SPF_FLAG_TEMPFAIL;
}
g_ptr_array_insert(resolved->elts, 0, addr);
}
}
else {
rec->top_record = rspamd_mempool_strdup(rec->task->task_pool,
selected->content.txt.data);
rspamd_mempool_set_variable(rec->task->task_pool,
RSPAMD_MEMPOOL_SPF_RECORD,
(gpointer) rec->top_record, NULL);
}
}
rspamd_spf_maybe_return(rec);
}
static struct rspamd_spf_cred *
rspamd_spf_cache_domain(struct rspamd_task *task)
{
struct rspamd_email_address *addr;
struct rspamd_spf_cred *cred = NULL;
addr = rspamd_task_get_sender(task);
if (!addr || (addr->flags & RSPAMD_EMAIL_ADDR_EMPTY)) {
/* Get domain from helo */
if (task->helo) {
GString *fs = g_string_new("");
cred = rspamd_mempool_alloc(task->task_pool, sizeof(*cred));
cred->domain = task->helo;
cred->local_part = "postmaster";
rspamd_printf_gstring(fs, "postmaster@%s", cred->domain);
cred->sender = fs->str;
rspamd_mempool_add_destructor(task->task_pool,
rspamd_gstring_free_hard, fs);
}
}
else {
rspamd_ftok_t tok;
cred = rspamd_mempool_alloc(task->task_pool, sizeof(*cred));
tok.begin = addr->domain;
tok.len = addr->domain_len;
cred->domain = rspamd_mempool_ftokdup(task->task_pool, &tok);
tok.begin = addr->user;
tok.len = addr->user_len;
cred->local_part = rspamd_mempool_ftokdup(task->task_pool, &tok);
tok.begin = addr->addr;
tok.len = addr->addr_len;
cred->sender = rspamd_mempool_ftokdup(task->task_pool, &tok);
}
if (cred) {
rspamd_mempool_set_variable(task->task_pool, RSPAMD_MEMPOOL_SPF_DOMAIN,
cred, NULL);
}
return cred;
}
struct rspamd_spf_cred *
rspamd_spf_get_cred(struct rspamd_task *task)
{
struct rspamd_spf_cred *cred;
cred = rspamd_mempool_get_variable(task->task_pool,
RSPAMD_MEMPOOL_SPF_DOMAIN);
if (!cred) {
cred = rspamd_spf_cache_domain(task);
}
return cred;
}
const char *
rspamd_spf_get_domain(struct rspamd_task *task)
{
char *domain = NULL;
struct rspamd_spf_cred *cred;
cred = rspamd_spf_get_cred(task);
if (cred) {
domain = cred->domain;
}
return domain;
}
gboolean
rspamd_spf_resolve(struct rspamd_task *task, spf_cb_t callback,
gpointer cbdata, struct rspamd_spf_cred *cred)
{
struct spf_record *rec;
if (!cred || !cred->domain) {
return FALSE;
}
/* First lookup in the hash */
if (spf_lib_ctx->spf_hash) {
struct spf_resolved *cached;
cached = rspamd_lru_hash_lookup(spf_lib_ctx->spf_hash, cred->domain,
task->task_timestamp);
if (cached) {
cached->flags |= RSPAMD_SPF_FLAG_CACHED;
if (cached->top_record) {
rspamd_mempool_set_variable(task->task_pool,
RSPAMD_MEMPOOL_SPF_RECORD,
rspamd_mempool_strdup(task->task_pool,
cached->top_record),
NULL);
}
callback(cached, task, cbdata);
return TRUE;
}
}
rec = rspamd_mempool_alloc0(task->task_pool, sizeof(struct spf_record));
rec->task = task;
rec->callback = callback;
rec->cbdata = cbdata;
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 */
rec->sender = cred->sender;
rec->local_part = cred->local_part;
rec->sender_domain = cred->domain;
if (rspamd_dns_resolver_request_task_forced(task,
spf_dns_callback,
(void *) rec, RDNS_REQUEST_TXT, rec->sender_domain)) {
rec->requests_inflight++;
return TRUE;
}
return FALSE;
}
struct spf_resolved *
_spf_record_ref(struct spf_resolved *flat, const char *loc)
{
REF_RETAIN(flat);
return flat;
}
void _spf_record_unref(struct spf_resolved *flat, const char *loc)
{
REF_RELEASE(flat);
}
char *
spf_addr_mask_to_string(struct spf_addr *addr)
{
GString *res;
char *s, ipstr[INET6_ADDRSTRLEN + 1];
if (addr->flags & RSPAMD_SPF_FLAG_ANY) {
res = g_string_new("any");
}
else if (addr->flags & RSPAMD_SPF_FLAG_IPV4) {
(void) inet_ntop(AF_INET, addr->addr4, ipstr, sizeof(ipstr));
res = g_string_sized_new(sizeof(ipstr));
rspamd_printf_gstring(res, "%s/%d", ipstr, addr->m.dual.mask_v4);
}
else if (addr->flags & RSPAMD_SPF_FLAG_IPV6) {
(void) inet_ntop(AF_INET6, addr->addr6, ipstr, sizeof(ipstr));
res = g_string_sized_new(sizeof(ipstr));
rspamd_printf_gstring(res, "%s/%d", ipstr, addr->m.dual.mask_v6);
}
else {
res = g_string_new(NULL);
rspamd_printf_gstring(res, "unknown, flags = %d", addr->flags);
}
s = res->str;
g_string_free(res, FALSE);
return s;
}
struct spf_addr *
spf_addr_match_task(struct rspamd_task *task, struct spf_resolved *rec)
{
const uint8_t *s, *d;
unsigned int af, mask, bmask, addrlen;
struct spf_addr *selected = NULL, *addr, *any_addr = NULL;
unsigned int i;
if (task->from_addr == NULL) {
return FALSE;
}
for (i = 0; i < rec->elts->len; i++) {
addr = &g_array_index(rec->elts, struct spf_addr, i);
if (addr->flags & RSPAMD_SPF_FLAG_TEMPFAIL) {
continue;
}
af = rspamd_inet_address_get_af(task->from_addr);
/* Basic comparing algorithm */
if (((addr->flags & RSPAMD_SPF_FLAG_IPV6) && af == AF_INET6) ||
((addr->flags & RSPAMD_SPF_FLAG_IPV4) && af == AF_INET)) {
d = rspamd_inet_address_get_hash_key(task->from_addr, &addrlen);
if (af == AF_INET6) {
s = (const uint8_t *) addr->addr6;
mask = addr->m.dual.mask_v6;
}
else {
s = (const uint8_t *) addr->addr4;
mask = addr->m.dual.mask_v4;
}
/* Compare the first bytes */
bmask = mask / CHAR_BIT;
if (mask > addrlen * CHAR_BIT) {
msg_info_task("bad mask length: %d", mask);
}
else if (memcmp(s, d, bmask) == 0) {
if (bmask * CHAR_BIT < mask) {
/* Compare the remaining bits */
s += bmask;
d += bmask;
mask = (0xffu << (CHAR_BIT - (mask - bmask * 8u))) & 0xffu;
if ((*s & mask) == (*d & mask)) {
selected = addr;
break;
}
}
else {
selected = addr;
break;
}
}
}
else {
if (addr->flags & RSPAMD_SPF_FLAG_ANY) {
any_addr = addr;
}
}
}
if (selected) {
return selected;
}
return any_addr;
}