/*
This file is part of GNUnet.
Copyright (C) 2011-2013 GNUnet e.V.
GNUnet is free software: you can redistribute it and/or modify it
under the terms of the GNU Affero General Public License as published
by the Free Software Foundation, either version 3 of the License,
or (at your option) any later version.
GNUnet is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Affero General Public License for more details.
You should have received a copy of the GNU Affero General Public License
along with this program. If not, see .
SPDX-License-Identifier: AGPL3.0-or-later
*/
/**
* @file gns/gnunet-service-gns_resolver.c
* @brief GNU Name System resolver logic
* @author Martin Schanzenbach
* @author Christian Grothoff
*/
#include "platform.h"
#if HAVE_LIBIDN2
#if HAVE_IDN2_H
#include
#elif HAVE_IDN2_IDN2_H
#include
#endif
#elif HAVE_LIBIDN
#if HAVE_IDNA_H
#include
#elif HAVE_IDN_IDNA_H
#include
#endif
#endif
#include "gnunet_util_lib.h"
#include "gnunet_dnsstub_lib.h"
#include "gnunet_dht_service.h"
#include "gnunet_gnsrecord_lib.h"
#include "gnunet_namecache_service.h"
#include "gnunet_dns_service.h"
#include "gnunet_resolver_service.h"
#include "gnunet_revocation_service.h"
#include "gnunet_dnsparser_lib.h"
#include "gnunet_tun_lib.h"
#include "gnunet_gns_service.h"
#include "gns.h"
#include "gnunet-service-gns.h"
#include "gnunet-service-gns_resolver.h"
/**
* Default DHT timeout for lookups.
*/
#define DHT_LOOKUP_TIMEOUT GNUNET_TIME_relative_multiply ( \
GNUNET_TIME_UNIT_SECONDS, 60)
/**
* Default timeout for DNS lookups.
*/
#define DNS_LOOKUP_TIMEOUT GNUNET_TIME_relative_multiply ( \
GNUNET_TIME_UNIT_SECONDS, 15)
/**
* DHT replication level
*/
#define DHT_GNS_REPLICATION_LEVEL 10
/**
* DLL to hold the authority chain we had to pass in the resolution
* process.
*/
struct AuthorityChain;
/**
* Element of a resolution process for looking up the
* responsible DNS server hostname in a GNS2DNS recursive
* resolution.
*/
struct Gns2DnsPending
{
/**
* Kept in a DLL.
*/
struct Gns2DnsPending *next;
/**
* Kept in a DLL.
*/
struct Gns2DnsPending *prev;
/**
* Context this activity belongs with.
*/
struct AuthorityChain *ac;
/**
* Handle for the resolution of the IP part of the
* GNS2DNS record. Will return to us the addresses
* of the DNS resolver to use.
*/
struct GNS_ResolverHandle *rh;
/**
* Handle for DNS resolution of the DNS nameserver.
*/
struct GNUNET_RESOLVER_RequestHandle *dns_rh;
/**
* How many results did we get?
*/
unsigned int num_results;
};
/**
* Handle to a currently pending resolution. On result (positive or
* negative) the #GNS_ResultProcessor is called.
*/
struct GNS_ResolverHandle;
/**
* DLL to hold the authority chain we had to pass in the resolution
* process.
*/
struct AuthorityChain
{
/**
* This is a DLL.
*/
struct AuthorityChain *prev;
/**
* This is a DLL.
*/
struct AuthorityChain *next;
/**
* Resolver handle this entry in the chain belongs to.
*/
struct GNS_ResolverHandle *rh;
/**
* label/name corresponding to the authority
*/
char *label;
/**
* #GNUNET_YES if the authority was a GNS authority,
* #GNUNET_NO if the authority was a DNS authority.
*/
int gns_authority;
/**
* Information about the resolver authority for this label.
*/
union
{
/**
* The zone of the GNS authority
*/
struct GNUNET_IDENTITY_PublicKey gns_authority;
struct
{
/**
* Domain of the DNS resolver that is the authority.
* (appended to construct the DNS name to resolve;
* this is NOT the DNS name of the DNS server!).
*/
char name[GNUNET_DNSPARSER_MAX_NAME_LENGTH + 1];
/**
* List of resolutions of the 'ip' of the name server that
* are still pending.
*/
struct Gns2DnsPending *gp_head;
/**
* Tail of list of resolutions of the 'ip' of the name server that
* are still pending.
*/
struct Gns2DnsPending *gp_tail;
/**
* Handle to perform DNS lookups with this authority (in GNS2DNS handling).
*/
struct GNUNET_DNSSTUB_Context *dns_handle;
/**
* Did we succeed in getting an IP address for *any* of the DNS servers listed?
* Once we do, we can start with DNS queries.
*/
int found;
/**
* Did we start the recursive resolution via DNS?
*/
int launched;
} dns_authority;
} authority_info;
};
/**
* A result we got from DNS.
*/
struct DnsResult
{
/**
* Kept in DLL.
*/
struct DnsResult *next;
/**
* Kept in DLL.
*/
struct DnsResult *prev;
/**
* Binary value stored in the DNS record (appended to this struct)
*/
const void *data;
/**
* Expiration time for the DNS record, 0 if we didn't
* get anything useful (i.e. 'gethostbyname()' was used).
*/
uint64_t expiration_time;
/**
* Number of bytes in @e data.
*/
size_t data_size;
/**
* Type of the GNS/DNS record.
*/
uint32_t record_type;
};
/**
* Handle to a currently pending resolution. On result (positive or
* negative) the #GNS_ResultProcessor is called.
*/
struct GNS_ResolverHandle
{
/**
* DLL
*/
struct GNS_ResolverHandle *next;
/**
* DLL
*/
struct GNS_ResolverHandle *prev;
/**
* The top-level GNS authoritative zone to query
*/
struct GNUNET_IDENTITY_PublicKey authority_zone;
/**
* called when resolution phase finishes
*/
GNS_ResultProcessor proc;
/**
* closure passed to @e proc
*/
void *proc_cls;
/**
* Handle for DHT lookups. should be NULL if no lookups are in progress
*/
struct GNUNET_DHT_GetHandle *get_handle;
/**
* Socket for a DNS request, NULL if none is active.
*/
struct GNUNET_DNSSTUB_RequestSocket *dns_request;
/**
* Handle for standard DNS resolution, NULL if none is active.
*/
struct GNUNET_RESOLVER_RequestHandle *std_resolve;
/**
* Pending Namecache lookup task
*/
struct GNUNET_NAMECACHE_QueueEntry *namecache_qe;
/**
* Pending revocation check.
*/
struct GNUNET_REVOCATION_Query *rev_check;
/**
* Heap node associated with this lookup. Used to limit number of
* concurrent requests.
*/
struct GNUNET_CONTAINER_HeapNode *dht_heap_node;
/**
* DLL to store the authority chain
*/
struct AuthorityChain *ac_head;
/**
* DLL to store the authority chain
*/
struct AuthorityChain *ac_tail;
/**
* ID of a task associated with the resolution process.
*/
struct GNUNET_SCHEDULER_Task *task_id;
/**
* The name to resolve
*/
char *name;
/**
* Legacy Hostname to use if we encountered GNS2DNS record
* and thus can deduct the LEHO from that transition.
*/
char *leho;
/**
* DLL of results we got from DNS.
*/
struct DnsResult *dns_result_head;
/**
* DLL of results we got from DNS.
*/
struct DnsResult *dns_result_tail;
/**
* Current offset in @e name where we are resolving.
*/
size_t name_resolution_pos;
/**
* Use only cache
*/
enum GNUNET_GNS_LocalOptions options;
/**
* For SRV and TLSA records, the number of the
* protocol specified in the name. 0 if no protocol was given.
*/
int protocol;
/**
* For SRV and TLSA records, the number of the
* service specified in the name. 0 if no service was given.
*/
int service;
/**
* Desired type for the resolution.
*/
int record_type;
/**
* We increment the loop limiter for each step in a recursive
* resolution. If it passes our @e loop_threshold (e.g. due to
* self-recursion in the resolution, i.e CNAME fun), we stop.
*/
unsigned int loop_limiter;
/**
* Maximum value of @e loop_limiter allowed by client.
*/
unsigned int loop_threshold;
/**
* 16 bit random ID we used in the @e dns_request.
*/
uint16_t original_dns_id;
};
/**
* Active namestore caching operations.
*/
struct CacheOps
{
/**
* Organized in a DLL.
*/
struct CacheOps *next;
/**
* Organized in a DLL.
*/
struct CacheOps *prev;
/**
* Pending Namestore caching task.
*/
struct GNUNET_NAMECACHE_QueueEntry *namecache_qe_cache;
};
/**
* Our handle to the namecache service
*/
static struct GNUNET_NAMECACHE_Handle *namecache_handle;
/**
* Resolver handle to the dht
*/
static struct GNUNET_DHT_Handle *dht_handle;
/**
* Heap for limiting parallel DHT lookups
*/
static struct GNUNET_CONTAINER_Heap *dht_lookup_heap;
/**
* Maximum amount of parallel queries to the DHT
*/
static unsigned long long max_allowed_background_queries;
/**
* Head of resolver lookup list
*/
static struct GNS_ResolverHandle *rlh_head;
/**
* Tail of resolver lookup list
*/
static struct GNS_ResolverHandle *rlh_tail;
/**
* Organized in a DLL.
*/
static struct CacheOps *co_head;
/**
* Organized in a DLL.
*/
static struct CacheOps *co_tail;
/**
* Use namecache
*/
static int disable_cache;
/**
* Global configuration.
*/
static const struct GNUNET_CONFIGURATION_Handle *cfg;
/**
* Determine if this name is canonical (is a legal name in a zone, without delegation);
* note that we do not test that the name does not contain illegal characters, we only
* test for delegation. Note that service records (like _foo._srv) are canonical names
* even though they consist of multiple labels.
*
* Examples:
* a.b.gnu = not canonical
* a = canonical
* _foo._srv = canonical
* _f.bar = not canonical
*
* @param name the name to test
* @return #GNUNET_YES if canonical
*/
/* dead, but keep for now */ int
is_canonical (const char *name)
{
const char *pos;
const char *dot;
if (NULL == strchr (name,
(unsigned char) '.'))
return GNUNET_YES;
if ('_' != name[0])
return GNUNET_NO;
pos = &name[1];
while (NULL != (dot = strchr (pos,
(unsigned char) '.')))
if ('_' != dot[1])
return GNUNET_NO;
else
pos = dot + 1;
return GNUNET_YES;
}
/* ************************** Resolution **************************** */
/**
* Expands a name ending in .+ with the zone of origin.
*
* @param rh resolution context
* @param name name to modify (to be free'd or returned)
* @return updated name
*/
static char *
translate_dot_plus (struct GNS_ResolverHandle *rh,
char *name)
{
char *ret;
size_t s_len = strlen (name);
if (0 != strcmp (&name[s_len - 2],
".+"))
return name; /* did not end in ".+" */
GNUNET_assert (GNUNET_YES == rh->ac_tail->gns_authority);
GNUNET_asprintf (&ret,
"%.*s.%s",
(int) (s_len - 2),
name,
GNUNET_GNSRECORD_pkey_to_zkey (
&rh->ac_tail->authority_info.gns_authority));
GNUNET_free (name);
return ret;
}
/**
* Wrapper around #GNS_resolver_lookup_cancel() as a task.
* Used for delayed cleanup so we can unwind the stack first.
*
* @param cls the `struct GNS_ResolverHandle`
*/
static void
GNS_resolver_lookup_cancel_ (void *cls)
{
struct GNS_ResolverHandle *rh = cls;
rh->task_id = NULL;
GNS_resolver_lookup_cancel (rh);
}
/**
* Function called to asynchronously fail a resolution.
*
* @param rh the resolution to fail
*/
static void
fail_resolution (struct GNS_ResolverHandle *rh)
{
rh->proc (rh->proc_cls,
0,
NULL);
GNUNET_assert (NULL == rh->task_id);
rh->task_id = GNUNET_SCHEDULER_add_now (&GNS_resolver_lookup_cancel_,
rh);
}
/**
* Function called when a resolution times out.
*
* @param cls the `struct GNS_ResolverHandle`
*/
static void
timeout_resolution (void *cls)
{
struct GNS_ResolverHandle *rh = cls;
rh->task_id = NULL;
fail_resolution (rh);
}
/**
* Get the next, rightmost label from the name that we are trying to resolve,
* and update the resolution position accordingly. Labels usually consist
* of up to 63 characters without a period ("."); however, we use a special
* convention to support SRV and TLSA records where the domain name
* includes an encoding for a service and protocol in the name. The
* syntax (see RFC 2782) here is "_Service._Proto.Name" and in this
* special case we include the "_Service._Proto" in the rightmost label.
* Thus, for "_443._tcp.foo.bar" we first return the label "bar" and then
* the label "_443._tcp.foo". The special case is detected by the
* presence of labels beginning with an underscore. Whenever a label
* begins with an underscore, it is combined with the label to its right
* (and the "." is preserved).
*
* @param rh handle to the resolution operation to get the next label from
* @return NULL if there are no more labels
*/
static char *
resolver_lookup_get_next_label (struct GNS_ResolverHandle *rh)
{
const char *rp;
const char *dot;
size_t len;
char *ret;
char *srv_name;
char *proto_name;
struct protoent *pe;
struct servent *se;
if (0 == rh->name_resolution_pos)
return NULL;
dot = memrchr (rh->name,
(int) '.',
rh->name_resolution_pos);
if (NULL == dot)
{
/* done, this was the last one */
len = rh->name_resolution_pos;
rp = rh->name;
rh->name_resolution_pos = 0;
}
else
{
/* advance by one label */
len = rh->name_resolution_pos - (dot - rh->name) - 1;
rp = dot + 1;
rh->name_resolution_pos = dot - rh->name;
}
rh->protocol = 0;
rh->service = 0;
ret = GNUNET_strndup (rp, len);
/* If we have labels starting with underscore with label on
* the right (SRV/DANE/BOX case), determine port/protocol;
* The format of `rh->name` must be "_PORT._PROTOCOL".
*/
if (('_' == rh->name[0]) &&
(NULL != (dot = memrchr (rh->name,
(int) '.',
rh->name_resolution_pos))) &&
('_' == dot[1]) &&
(NULL == memrchr (rh->name,
(int) '.',
dot - rh->name)))
{
srv_name = GNUNET_strndup (&rh->name[1],
(dot - rh->name) - 1);
proto_name = GNUNET_strndup (&dot[2],
rh->name_resolution_pos - (dot - rh->name)
- 2);
rh->name_resolution_pos = 0;
pe = getprotobyname (proto_name);
if (NULL == pe)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("Protocol `%s' unknown, skipping labels.\n"),
proto_name);
GNUNET_free (proto_name);
GNUNET_free (srv_name);
return ret;
}
se = getservbyname (srv_name,
proto_name);
if (NULL == se)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ (
"Service `%s' unknown for protocol `%s', trying as number.\n"),
srv_name,
proto_name);
if (1 != sscanf (srv_name, "%u", &rh->service))
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("Service `%s' not a port, skipping service labels.\n"),
srv_name);
GNUNET_free (proto_name);
GNUNET_free (srv_name);
return ret;
}
}
else
{
rh->service = se->s_port;
}
rh->protocol = pe->p_proto;
GNUNET_free (proto_name);
GNUNET_free (srv_name);
}
return ret;
}
/**
* Gives the cumulative result obtained to the callback and clean up the request.
*
* @param rh resolution process that has culminated in a result
*/
static void
transmit_lookup_dns_result (struct GNS_ResolverHandle *rh)
{
struct DnsResult *pos;
unsigned int n;
unsigned int i;
n = 0;
for (pos = rh->dns_result_head; NULL != pos; pos = pos->next)
n++;
{
struct GNUNET_GNSRECORD_Data rd[n];
i = 0;
for (pos = rh->dns_result_head; NULL != pos; pos = pos->next)
{
rd[i].data = pos->data;
rd[i].data_size = pos->data_size;
rd[i].record_type = pos->record_type;
rd[i].flags = GNUNET_GNSRECORD_RF_NONE;
/**
* If this is a LEHO, we added this before. It must be a supplemental
* record #LSD0001
*/
if (GNUNET_GNSRECORD_TYPE_LEHO == rd[i].record_type)
rd[i].flags |= GNUNET_GNSRECORD_RF_SUPPLEMENTAL;
if (0 == pos->expiration_time)
{
rd[i].flags |= GNUNET_GNSRECORD_RF_RELATIVE_EXPIRATION;
rd[i].expiration_time = 0;
}
else
{
rd[i].expiration_time = pos->expiration_time;
}
i++;
}
GNUNET_assert (i == n);
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Transmitting standard DNS result with %u records\n",
n);
rh->proc (rh->proc_cls,
n,
rd);
}
GNS_resolver_lookup_cancel (rh);
}
/**
* Add a result from DNS to the records to be returned to the application.
*
* @param rh resolution request to extend with a result
* @param expiration_time expiration time for the answer
* @param record_type DNS record type of the answer
* @param data_size number of bytes in @a data
* @param data binary data to return in DNS record
*/
static void
add_dns_result (struct GNS_ResolverHandle *rh,
uint64_t expiration_time,
uint32_t record_type,
size_t data_size,
const void *data)
{
struct DnsResult *res;
res = GNUNET_malloc (sizeof(struct DnsResult) + data_size);
res->expiration_time = expiration_time;
res->data_size = data_size;
res->record_type = record_type;
res->data = &res[1];
GNUNET_memcpy (&res[1],
data,
data_size);
GNUNET_CONTAINER_DLL_insert (rh->dns_result_head,
rh->dns_result_tail,
res);
}
/**
* We had to do a DNS lookup. Convert the result (if any) and return
* it.
*
* @param cls closure with the `struct GNS_ResolverHandle`
* @param addr one of the addresses of the host, NULL for the last address
* @param addrlen length of the address
*/
static void
handle_dns_result (void *cls,
const struct sockaddr *addr,
socklen_t addrlen)
{
struct GNS_ResolverHandle *rh = cls;
const struct sockaddr_in *sa4;
const struct sockaddr_in6 *sa6;
if (NULL == addr)
{
rh->std_resolve = NULL;
transmit_lookup_dns_result (rh);
return;
}
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Received %u bytes of DNS IP data\n",
addrlen);
switch (addr->sa_family)
{
case AF_INET:
sa4 = (const struct sockaddr_in *) addr;
add_dns_result (rh,
0 /* expiration time is unknown */,
GNUNET_DNSPARSER_TYPE_A,
sizeof(struct in_addr),
&sa4->sin_addr);
break;
case AF_INET6:
sa6 = (const struct sockaddr_in6 *) addr;
add_dns_result (rh,
0 /* expiration time is unknown */,
GNUNET_DNSPARSER_TYPE_AAAA,
sizeof(struct in6_addr),
&sa6->sin6_addr);
break;
default:
GNUNET_break (0);
break;
}
}
/**
* Task scheduled to continue with the resolution process.
*
* @param cls the 'struct GNS_ResolverHandle' of the resolution
* @param tc task context
*/
static void
recursive_resolution (void *cls);
/**
* Begin the resolution process from 'name', starting with
* the identification of the zone specified by 'name'.
*
* @param cls closure with `struct GNS_ResolverHandle *rh`
*/
static void
start_resolver_lookup (void *cls);
/**
* Function called with the result of a DNS resolution.
*
* @param cls the request handle of the resolution that
* we were attempting to make
* @param dns dns response, never NULL
* @param dns_len number of bytes in @a dns
*/
static void
dns_result_parser (void *cls,
const struct GNUNET_TUN_DnsHeader *dns,
size_t dns_len)
{
struct GNS_ResolverHandle *rh = cls;
struct GNUNET_DNSPARSER_Packet *p;
const struct GNUNET_DNSPARSER_Record *rec;
unsigned int rd_count;
if (NULL == dns)
{
rh->dns_request = NULL;
GNUNET_SCHEDULER_cancel (rh->task_id);
rh->task_id = NULL;
fail_resolution (rh);
return;
}
if (rh->original_dns_id != dns->id)
{
/* DNS answer, but for another query */
return;
}
p = GNUNET_DNSPARSER_parse ((const char *) dns,
dns_len);
if (NULL == p)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("Failed to parse DNS response\n"));
return;
}
/* We got a result from DNS */
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Received DNS response for `%s' with %u answers\n",
rh->ac_tail->label,
(unsigned int) p->num_answers);
if ((p->num_answers > 0) &&
(GNUNET_DNSPARSER_TYPE_CNAME == p->answers[0].type) &&
(GNUNET_DNSPARSER_TYPE_CNAME != rh->record_type))
{
int af;
GNUNET_log (GNUNET_ERROR_TYPE_INFO,
"Got CNAME `%s' from DNS for `%s'\n",
p->answers[0].data.hostname,
rh->name);
if (NULL != rh->std_resolve)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Multiple CNAME results from DNS resolving `%s'! Not really allowed...\n",
rh->name);
GNUNET_RESOLVER_request_cancel (rh->std_resolve);
}
GNUNET_free (rh->name);
rh->name = GNUNET_strdup (p->answers[0].data.hostname);
rh->name_resolution_pos = strlen (rh->name);
switch (rh->record_type)
{
case GNUNET_DNSPARSER_TYPE_A:
af = AF_INET;
break;
case GNUNET_DNSPARSER_TYPE_AAAA:
af = AF_INET6;
break;
default:
af = AF_UNSPEC;
break;
}
if (NULL != rh->leho)
add_dns_result (rh,
GNUNET_TIME_UNIT_HOURS.rel_value_us,
GNUNET_GNSRECORD_TYPE_LEHO,
strlen (rh->leho),
rh->leho);
rh->std_resolve = GNUNET_RESOLVER_ip_get (rh->name,
af,
DNS_LOOKUP_TIMEOUT,
&handle_dns_result,
rh);
GNUNET_DNSPARSER_free_packet (p);
GNUNET_DNSSTUB_resolve_cancel (rh->dns_request);
rh->dns_request = NULL;
return;
}
/* convert from (parsed) DNS to (binary) GNS format! */
rd_count = p->num_answers + p->num_authority_records
+ p->num_additional_records;
{
struct GNUNET_GNSRECORD_Data rd[rd_count + 1]; /* +1 for LEHO */
int skip;
char buf[UINT16_MAX];
size_t buf_off;
size_t buf_start;
buf_off = 0;
skip = 0;
memset (rd,
0,
sizeof(rd));
for (unsigned int i = 0; i < rd_count; i++)
{
if (i < p->num_answers)
rec = &p->answers[i];
else if (i < p->num_answers + p->num_authority_records)
rec = &p->authority_records[i - p->num_answers];
else
rec = &p->additional_records[i - p->num_answers
- p->num_authority_records];
/* As we copied the full DNS name to 'rh->ac_tail->label', this
should be the correct check to see if this record is actually
a record for our label... */
if (0 != strcmp (rec->name,
rh->ac_tail->label))
{
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Dropping record `%s', does not match desired name `%s'\n",
rec->name,
rh->ac_tail->label);
skip++;
continue;
}
rd[i - skip].record_type = rec->type;
rd[i - skip].expiration_time = rec->expiration_time.abs_value_us;
switch (rec->type)
{
case GNUNET_DNSPARSER_TYPE_A:
if (rec->data.raw.data_len != sizeof(struct in_addr))
{
GNUNET_break_op (0);
skip++;
continue;
}
rd[i - skip].data_size = rec->data.raw.data_len;
rd[i - skip].data = rec->data.raw.data;
break;
case GNUNET_DNSPARSER_TYPE_AAAA:
if (rec->data.raw.data_len != sizeof(struct in6_addr))
{
GNUNET_break_op (0);
skip++;
continue;
}
rd[i - skip].data_size = rec->data.raw.data_len;
rd[i - skip].data = rec->data.raw.data;
break;
case GNUNET_DNSPARSER_TYPE_CNAME:
case GNUNET_DNSPARSER_TYPE_PTR:
case GNUNET_DNSPARSER_TYPE_NS:
buf_start = buf_off;
if (GNUNET_OK !=
GNUNET_DNSPARSER_builder_add_name (buf,
sizeof(buf),
&buf_off,
rec->data.hostname))
{
GNUNET_break (0);
skip++;
continue;
}
rd[i - skip].data_size = buf_off - buf_start;
rd[i - skip].data = &buf[buf_start];
break;
case GNUNET_DNSPARSER_TYPE_SOA:
buf_start = buf_off;
if (GNUNET_OK !=
GNUNET_DNSPARSER_builder_add_soa (buf,
sizeof(buf),
&buf_off,
rec->data.soa))
{
GNUNET_break (0);
skip++;
continue;
}
rd[i - skip].data_size = buf_off - buf_start;
rd[i - skip].data = &buf[buf_start];
break;
case GNUNET_DNSPARSER_TYPE_MX:
buf_start = buf_off;
if (GNUNET_OK !=
GNUNET_DNSPARSER_builder_add_mx (buf,
sizeof(buf),
&buf_off,
rec->data.mx))
{
GNUNET_break (0);
skip++;
continue;
}
rd[i - skip].data_size = buf_off - buf_start;
rd[i - skip].data = &buf[buf_start];
break;
case GNUNET_DNSPARSER_TYPE_SRV:
buf_start = buf_off;
if (GNUNET_OK !=
GNUNET_DNSPARSER_builder_add_srv (buf,
sizeof(buf),
&buf_off,
rec->data.srv))
{
GNUNET_break (0);
skip++;
continue;
}
rd[i - skip].data_size = buf_off - buf_start;
rd[i - skip].data = &buf[buf_start];
break;
default:
GNUNET_log (GNUNET_ERROR_TYPE_INFO,
_ ("Skipping record of unsupported type %d\n"),
rec->type);
skip++;
continue;
}
} /* end of for all records in answer */
if (NULL != rh->leho)
{
rd[rd_count - skip].record_type = GNUNET_GNSRECORD_TYPE_LEHO;
rd[rd_count - skip].flags = GNUNET_GNSRECORD_RF_RELATIVE_EXPIRATION;
rd[rd_count - skip].flags |= GNUNET_GNSRECORD_RF_SUPPLEMENTAL;
rd[rd_count - skip].expiration_time = GNUNET_TIME_UNIT_HOURS.rel_value_us;
rd[rd_count - skip].data = rh->leho;
rd[rd_count - skip].data_size = strlen (rh->leho);
skip--; /* skip one LESS */
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Adding LEHO %s\n",
rh->leho);
}
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Returning DNS response for `%s' with %u answers\n",
rh->ac_tail->label,
(unsigned int) (rd_count - skip));
rh->proc (rh->proc_cls,
rd_count - skip,
rd);
GNUNET_DNSSTUB_resolve_cancel (rh->dns_request);
rh->dns_request = NULL;
}
GNUNET_DNSPARSER_free_packet (p);
if (NULL != rh->task_id)
GNUNET_SCHEDULER_cancel (rh->task_id); /* should be timeout task */
rh->task_id = GNUNET_SCHEDULER_add_now (&GNS_resolver_lookup_cancel_,
rh);
}
/**
* Perform recursive DNS resolution. Asks the given DNS resolver to
* resolve "rh->dns_name", possibly recursively proceeding following
* NS delegations, CNAMES, etc., until 'rh->loop_limiter' bounds us or
* we find the answer.
*
* @param rh resolution information
*/
static void
recursive_dns_resolution (struct GNS_ResolverHandle *rh)
{
struct AuthorityChain *ac;
struct GNUNET_DNSPARSER_Query *query;
struct GNUNET_DNSPARSER_Packet *p;
char *dns_request;
size_t dns_request_length;
int ret;
ac = rh->ac_tail;
GNUNET_assert (NULL != ac);
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Starting DNS lookup for `%s'\n",
ac->label);
GNUNET_assert (GNUNET_NO == ac->gns_authority);
query = GNUNET_new (struct GNUNET_DNSPARSER_Query);
query->name = GNUNET_strdup (ac->label);
query->type = rh->record_type;
query->dns_traffic_class = GNUNET_TUN_DNS_CLASS_INTERNET;
p = GNUNET_new (struct GNUNET_DNSPARSER_Packet);
p->queries = query;
p->num_queries = 1;
p->id = (uint16_t) GNUNET_CRYPTO_random_u32 (GNUNET_CRYPTO_QUALITY_NONCE,
UINT16_MAX);
p->flags.opcode = GNUNET_TUN_DNS_OPCODE_QUERY;
p->flags.recursion_desired = 1;
ret = GNUNET_DNSPARSER_pack (p,
1024,
&dns_request,
&dns_request_length);
if (GNUNET_OK != ret)
{
GNUNET_break (0);
rh->proc (rh->proc_cls,
0,
NULL);
GNUNET_assert (NULL == rh->task_id);
rh->task_id = GNUNET_SCHEDULER_add_now (&GNS_resolver_lookup_cancel_,
rh);
}
else
{
rh->original_dns_id = p->id;
GNUNET_assert (NULL != ac->authority_info.dns_authority.dns_handle);
GNUNET_assert (NULL == rh->dns_request);
rh->leho = GNUNET_strdup (ac->label);
rh->dns_request = GNUNET_DNSSTUB_resolve (
ac->authority_info.dns_authority.dns_handle,
dns_request,
dns_request_length,
&dns_result_parser,
rh);
rh->task_id = GNUNET_SCHEDULER_add_delayed (DNS_LOOKUP_TIMEOUT,
&timeout_resolution,
rh);
}
if (GNUNET_SYSERR != ret)
GNUNET_free (dns_request);
GNUNET_DNSPARSER_free_packet (p);
}
/**
* We encountered a REDIRECT record during our resolution.
* Merge it into our chain.
*
* @param rh resolution we are performing
* @param rname value of the redirect record we got for the current
* authority chain tail
*/
static void
handle_gns_redirect_result (struct GNS_ResolverHandle *rh,
const char *rname)
{
size_t nlen;
char *res;
const char *tld;
struct AuthorityChain *ac;
int af;
struct GNUNET_IDENTITY_PublicKey zone;
nlen = strlen (rname);
tld = GNS_get_tld (rname);
if (0 == strcmp ("+", tld))
{
/* REDIRECT resolution continues relative to current domain */
if (0 == rh->name_resolution_pos)
{
res = GNUNET_strndup (rname, nlen - 2);
rh->name_resolution_pos = nlen - 2;
}
else
{
GNUNET_asprintf (&res,
"%.*s.%.*s",
(int) rh->name_resolution_pos,
rh->name,
(int) (nlen - 2),
rname);
rh->name_resolution_pos = strlen (res);
}
GNUNET_free (rh->name);
rh->name = res;
ac = GNUNET_new (struct AuthorityChain);
ac->rh = rh;
ac->gns_authority = GNUNET_YES;
ac->authority_info.gns_authority =
rh->ac_tail->authority_info.gns_authority;
ac->label = resolver_lookup_get_next_label (rh);
/* add AC to tail */
GNUNET_CONTAINER_DLL_insert_tail (rh->ac_head,
rh->ac_tail,
ac);
rh->task_id = GNUNET_SCHEDULER_add_now (&recursive_resolution,
rh);
return;
}
if (GNUNET_OK == GNUNET_GNSRECORD_zkey_to_pkey (tld, &zone))
{
/* REDIRECT resolution continues relative to current domain */
if (0 == rh->name_resolution_pos)
{
GNUNET_asprintf (&res,
"%.*s",
(int) (strlen (rname) - (strlen (tld) + 1)),
rname);
}
else
{
GNUNET_asprintf (&res,
"%.*s.%.*s",
(int) rh->name_resolution_pos,
rh->name,
(int) (strlen (rname) - (strlen (tld) + 1)),
rname);
}
rh->name_resolution_pos = strlen (res);
GNUNET_free (rh->name);
rh->name = res;
ac = GNUNET_new (struct AuthorityChain);
ac->rh = rh;
ac->gns_authority = GNUNET_YES;
ac->authority_info.gns_authority = zone;
ac->label = resolver_lookup_get_next_label (rh);
/* add AC to tail */
GNUNET_CONTAINER_DLL_insert_tail (rh->ac_head,
rh->ac_tail,
ac);
rh->task_id = GNUNET_SCHEDULER_add_now (&recursive_resolution,
rh);
return;
}
GNUNET_log (GNUNET_ERROR_TYPE_INFO,
"Got REDIRECT `%s' from GNS for `%s'\n",
rname,
rh->name);
if (NULL != rh->std_resolve)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Multiple REDIRECT results from GNS resolving `%s'! Not really allowed...\n",
rh->name);
GNUNET_RESOLVER_request_cancel (rh->std_resolve);
}
/* name is absolute, go to DNS */
GNUNET_free (rh->name);
rh->name = GNUNET_strdup (rname);
rh->name_resolution_pos = strlen (rh->name);
switch (rh->record_type)
{
case GNUNET_DNSPARSER_TYPE_A:
af = AF_INET;
break;
case GNUNET_DNSPARSER_TYPE_AAAA:
af = AF_INET6;
break;
default:
af = AF_UNSPEC;
break;
}
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Doing standard DNS lookup for `%s'\n",
rh->name);
rh->std_resolve = GNUNET_RESOLVER_ip_get (rh->name,
af,
DNS_LOOKUP_TIMEOUT,
&handle_dns_result,
rh);
}
/**
* We encountered a CNAME record during our resolution.
* Merge it into our chain.
*
* @param rh resolution we are performing
* @param cname value of the cname record we got for the current
* authority chain tail
*/
static void
handle_gns_cname_result (struct GNS_ResolverHandle *rh,
const char *cname)
{
struct AuthorityChain *ac;
int af;
struct GNUNET_IDENTITY_PublicKey zone;
GNUNET_free (rh->name);
rh->name = GNUNET_strdup (cname);
rh->name_resolution_pos = strlen (rh->name);
switch (rh->record_type)
{
case GNUNET_DNSPARSER_TYPE_A:
af = AF_INET;
break;
case GNUNET_DNSPARSER_TYPE_AAAA:
af = AF_INET6;
break;
default:
af = AF_UNSPEC;
break;
}
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Doing standard DNS lookup for `%s'\n",
rh->name);
rh->std_resolve = GNUNET_RESOLVER_ip_get (rh->name,
af,
DNS_LOOKUP_TIMEOUT,
&handle_dns_result,
rh);
}
/**
* Process a records that were decrypted from a block.
*
* @param cls closure with the 'struct GNS_ResolverHandle'
* @param rd_count number of entries in @a rd array
* @param rd array of records with data to store
*/
static void
handle_gns_resolution_result (void *cls,
unsigned int rd_count,
const struct GNUNET_GNSRECORD_Data *rd);
/**
* We have resolved one or more of the nameservers for a
* GNS2DNS lookup. Once we have some of them, begin using
* the DNSSTUB resolver.
*
* @param ac context for GNS2DNS resolution
*/
static void
continue_with_gns2dns (struct AuthorityChain *ac)
{
struct GNS_ResolverHandle *rh = ac->rh;
if ((NULL != ac->authority_info.dns_authority.gp_head) &&
(GNUNET_NO == ac->authority_info.dns_authority.found))
return; /* more pending and none found yet */
if (GNUNET_NO == ac->authority_info.dns_authority.found)
{
GNUNET_log (GNUNET_ERROR_TYPE_INFO,
"Failed to resolve DNS server for `%s' in GNS2DNS resolution\n",
ac->authority_info.dns_authority.name);
fail_resolution (rh);
return;
}
if (GNUNET_NO != ac->authority_info.dns_authority.launched)
return; /* already running, do not launch again! */
/* recurse */
ac->authority_info.dns_authority.launched = GNUNET_YES;
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Will continue resolution using DNS to resolve `%s'\n",
ac->label);
GNUNET_assert (NULL == rh->task_id);
rh->task_id = GNUNET_SCHEDULER_add_now (&recursive_resolution,
rh);
}
/**
* We've resolved the IP address for the DNS resolver to use
* after encountering a GNS2DNS record.
*
* @param cls the `struct Gns2DnsPending` used for this request
* @param rd_count number of records in @a rd
* @param rd addresses for the DNS resolver (presumably)
*/
static void
handle_gns2dns_result (void *cls,
unsigned int rd_count,
const struct GNUNET_GNSRECORD_Data *rd)
{
struct Gns2DnsPending *gp = cls;
struct AuthorityChain *ac = gp->ac;
GNUNET_CONTAINER_DLL_remove (ac->authority_info.dns_authority.gp_head,
ac->authority_info.dns_authority.gp_tail,
gp);
/* enable cleanup of 'rh' handle that automatically comes after we return,
and which expects 'rh' to be in the #rlh_head DLL. */
if (NULL != gp->rh)
{
GNUNET_CONTAINER_DLL_insert (rlh_head,
rlh_tail,
gp->rh);
gp->rh = NULL;
}
GNUNET_free (gp);
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Received %u results for IP address of DNS server for GNS2DNS transition\n",
rd_count);
/* find suitable A/AAAA record */
for (unsigned int j = 0; j < rd_count; j++)
{
switch (rd[j].record_type)
{
case GNUNET_DNSPARSER_TYPE_A:
{
struct sockaddr_in v4;
if (sizeof(struct in_addr) != rd[j].data_size)
{
GNUNET_break_op (0);
continue;
}
memset (&v4,
0,
sizeof(v4));
v4.sin_family = AF_INET;
v4.sin_port = htons (53);
#if HAVE_SOCKADDR_IN_SIN_LEN
v4.sin_len = (u_char) sizeof(v4);
#endif
GNUNET_memcpy (&v4.sin_addr,
rd[j].data,
sizeof(struct in_addr));
if (GNUNET_OK ==
GNUNET_DNSSTUB_add_dns_sa (
ac->authority_info.dns_authority.dns_handle,
(const struct sockaddr *) &v4))
ac->authority_info.dns_authority.found = GNUNET_YES;
break;
}
case GNUNET_DNSPARSER_TYPE_AAAA:
{
struct sockaddr_in6 v6;
if (sizeof(struct in6_addr) != rd[j].data_size)
{
GNUNET_break_op (0);
continue;
}
/* FIXME: might want to check if we support IPv6 here,
and otherwise skip this one and hope we find another */
memset (&v6,
0,
sizeof(v6));
v6.sin6_family = AF_INET6;
v6.sin6_port = htons (53);
#if HAVE_SOCKADDR_IN_SIN_LEN
v6.sin6_len = (u_char) sizeof(v6);
#endif
GNUNET_memcpy (&v6.sin6_addr,
rd[j].data,
sizeof(struct in6_addr));
if (GNUNET_OK ==
GNUNET_DNSSTUB_add_dns_sa (
ac->authority_info.dns_authority.dns_handle,
(const struct sockaddr *) &v6))
ac->authority_info.dns_authority.found = GNUNET_YES;
break;
}
default:
break;
}
}
continue_with_gns2dns (ac);
}
/**
* Function called by the resolver for each address obtained from DNS.
*
* @param cls closure, a `struct Gns2DnsPending *`
* @param addr one of the addresses of the host, NULL for the last address
* @param addrlen length of @a addr
*/
static void
handle_gns2dns_ip (void *cls,
const struct sockaddr *addr,
socklen_t addrlen)
{
struct Gns2DnsPending *gp = cls;
struct AuthorityChain *ac = gp->ac;
struct sockaddr_storage ss;
struct sockaddr_in *v4;
struct sockaddr_in6 *v6;
if (NULL == addr)
{
/* DNS resolution finished */
if (0 == gp->num_results)
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Failed to use DNS to resolve name of DNS resolver\n");
GNUNET_CONTAINER_DLL_remove (ac->authority_info.dns_authority.gp_head,
ac->authority_info.dns_authority.gp_tail,
gp);
GNUNET_free (gp);
continue_with_gns2dns (ac);
return;
}
GNUNET_memcpy (&ss,
addr,
addrlen);
switch (ss.ss_family)
{
case AF_INET:
v4 = (struct sockaddr_in *) &ss;
v4->sin_port = htons (53);
gp->num_results++;
break;
case AF_INET6:
v6 = (struct sockaddr_in6 *) &ss;
v6->sin6_port = htons (53);
gp->num_results++;
break;
default:
GNUNET_log (GNUNET_ERROR_TYPE_ERROR,
"Unsupported AF %d\n",
ss.ss_family);
return;
}
if (GNUNET_OK ==
GNUNET_DNSSTUB_add_dns_sa (ac->authority_info.dns_authority.dns_handle,
(struct sockaddr *) &ss))
ac->authority_info.dns_authority.found = GNUNET_YES;
}
/**
* We found a REDIRECT record, perform recursive resolution on it.
*
* @param rh resolution handle
* @param rd record with CNAME to resolve recursively
*/
static void
recursive_redirect_resolution (struct GNS_ResolverHandle *rh,
const struct GNUNET_GNSRECORD_Data *rd)
{
handle_gns_redirect_result (rh,
rd->data);
}
/**
* We found a CNAME record, perform recursive resolution on it.
*
* @param rh resolution handle
* @param rd record with CNAME to resolve recursively
*/
static void
recursive_cname_resolution (struct GNS_ResolverHandle *rh,
const struct GNUNET_GNSRECORD_Data *rd)
{
char *cname;
size_t off;
off = 0;
cname = GNUNET_DNSPARSER_parse_name (rd->data,
rd->data_size,
&off);
if ((NULL == cname) ||
(off != rd->data_size))
{
GNUNET_break_op (0); /* record not well-formed */
GNUNET_free (cname);
fail_resolution (rh);
return;
}
handle_gns_cname_result (rh,
cname);
GNUNET_free (cname);
}
/**
* We found a PKEY record, perform recursive resolution on it.
*
* @param rh resolution handle
* @param rd record with PKEY to resolve recursively
*/
static void
recursive_pkey_resolution (struct GNS_ResolverHandle *rh,
const struct GNUNET_GNSRECORD_Data *rd)
{
struct AuthorityChain *ac;
struct GNUNET_IDENTITY_PublicKey auth;
/* delegation to another zone */
if (GNUNET_OK != GNUNET_GNSRECORD_identity_from_data (rd->data,
rd->data_size,
rd->record_type,
&auth))
{
GNUNET_break_op (0);
fail_resolution (rh);
return;
}
/* expand authority chain */
ac = GNUNET_new (struct AuthorityChain);
ac->rh = rh;
ac->gns_authority = GNUNET_YES;
ac->authority_info.gns_authority = auth;
ac->label = resolver_lookup_get_next_label (rh);
/* add AC to tail */
GNUNET_CONTAINER_DLL_insert_tail (rh->ac_head,
rh->ac_tail,
ac);
/* recurse */
rh->task_id = GNUNET_SCHEDULER_add_now (&recursive_resolution,
rh);
}
/**
* We found one or more GNS2DNS records, perform recursive resolution on it.
* (to be precise, one or more records in @a rd is GNS2DNS, there may be others,
* so this function still needs to check which ones are GNS2DNS).
*
* @param rh resolution handle
* @param rd_count length of the @a rd array
* @param rd record with PKEY to resolve recursively
* @return #GNUNET_OK if this worked, #GNUNET_SYSERR if no GNS2DNS records were in @a rd
*/
static int
recursive_gns2dns_resolution (struct GNS_ResolverHandle *rh,
unsigned int rd_count,
const struct GNUNET_GNSRECORD_Data *rd)
{
struct AuthorityChain *ac;
const char *tld;
char *ns;
ns = NULL;
/* expand authority chain */
ac = GNUNET_new (struct AuthorityChain);
ac->rh = rh;
ac->authority_info.dns_authority.dns_handle = GNUNET_DNSSTUB_start (4);
for (unsigned int i = 0; i < rd_count; i++)
{
char *ip;
char *n;
size_t off;
struct Gns2DnsPending *gp;
struct GNUNET_IDENTITY_PublicKey zone;
struct sockaddr_in v4;
struct sockaddr_in6 v6;
if (GNUNET_GNSRECORD_TYPE_GNS2DNS != rd[i].record_type)
{
/**
* Records other than GNS2DNS not allowed
*/
GNUNET_free (ns);
GNUNET_free (ac);
return GNUNET_SYSERR;
}
off = 0;
n = GNUNET_DNSPARSER_parse_name (rd[i].data,
rd[i].data_size,
&off);
ip = GNUNET_strdup (&((const char *) rd[i].data)[off]);
if ((NULL == n) ||
(NULL == ip))
{
GNUNET_break_op (0);
GNUNET_free (n);
GNUNET_free (ip);
continue;
}
off += strlen (ip) + 1;
if (off != rd[i].data_size)
{
GNUNET_break_op (0);
GNUNET_free (n);
GNUNET_free (ip);
continue;
}
/* resolve 'ip' to determine the IP(s) of the DNS
resolver to use for lookup of 'ns' */
if (NULL != ns)
{
if (0 != strcasecmp (ns,
n))
{
/* NS values must all be the same for all GNS2DNS records,
anything else leads to insanity */
GNUNET_break_op (0);
GNUNET_free (n);
GNUNET_free (ip);
continue;
}
GNUNET_free (n);
}
else
{
ns = n;
}
/* check if 'ip' is already an IPv4/IPv6 address */
if ((1 == inet_pton (AF_INET,
ip,
&v4)) ||
(1 == inet_pton (AF_INET6,
ip,
&v6)))
{
GNUNET_break (GNUNET_OK ==
GNUNET_DNSSTUB_add_dns_ip (
ac->authority_info.dns_authority.dns_handle,
ip));
ac->authority_info.dns_authority.found = GNUNET_YES;
GNUNET_free (ip);
continue;
}
tld = GNS_get_tld (ip);
if ((0 != strcmp (tld, "+")) &&
(GNUNET_OK != GNUNET_GNSRECORD_zkey_to_pkey (tld, &zone)))
{
/* 'ip' is a DNS name */
gp = GNUNET_new (struct Gns2DnsPending);
gp->ac = ac;
GNUNET_CONTAINER_DLL_insert (ac->authority_info.dns_authority.gp_head,
ac->authority_info.dns_authority.gp_tail,
gp);
gp->dns_rh = GNUNET_RESOLVER_ip_get (ip,
AF_UNSPEC,
GNUNET_TIME_UNIT_FOREVER_REL,
&handle_gns2dns_ip,
gp);
GNUNET_free (ip);
continue;
}
/* 'ip' should be a GNS name */
gp = GNUNET_new (struct Gns2DnsPending);
gp->ac = ac;
GNUNET_CONTAINER_DLL_insert (ac->authority_info.dns_authority.gp_head,
ac->authority_info.dns_authority.gp_tail,
gp);
gp->rh = GNUNET_new (struct GNS_ResolverHandle);
if (0 == strcmp (tld, "+"))
{
ip = translate_dot_plus (rh,
ip);
tld = GNS_get_tld (ip);
if (GNUNET_OK !=
GNUNET_GNSRECORD_zkey_to_pkey (tld,
&zone))
{
GNUNET_break_op (0);
GNUNET_free (ip);
continue;
}
}
gp->rh->authority_zone = zone;
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Resolving `%s' to determine IP address of DNS server for GNS2DNS transition for `%s'\n",
ip,
ns);
gp->rh->name = ip;
gp->rh->name_resolution_pos = strlen (ip) - strlen (tld) - 1;
gp->rh->proc = &handle_gns2dns_result;
gp->rh->proc_cls = gp;
gp->rh->record_type = GNUNET_GNSRECORD_TYPE_ANY;
gp->rh->options = GNUNET_GNS_LO_DEFAULT;
gp->rh->loop_limiter = rh->loop_limiter + 1;
gp->rh->loop_threshold = rh->loop_threshold;
gp->rh->task_id
= GNUNET_SCHEDULER_add_now (&start_resolver_lookup,
gp->rh);
} /* end 'for all records' */
if (NULL == ns)
{
/* not a single GNS2DNS record found */
GNUNET_free (ac);
return GNUNET_SYSERR;
}
GNUNET_assert (strlen (ns) <= GNUNET_DNSPARSER_MAX_NAME_LENGTH);
strcpy (ac->authority_info.dns_authority.name,
ns);
/* for DNS recursion, the label is the full DNS name,
created from the remainder of the GNS name and the
name in the NS record */
GNUNET_asprintf (&ac->label,
"%.*s%s%s",
(int) rh->name_resolution_pos,
rh->name,
(0 != rh->name_resolution_pos) ? "." : "",
ns);
GNUNET_free (ns);
{
/* the GNS name is UTF-8 and may include multibyte chars.
* We have to convert the combined name to a DNS-compatible IDNA.
*/
char *tmp = ac->label;
if (IDNA_SUCCESS != idna_to_ascii_8z (tmp,
&ac->label,
IDNA_ALLOW_UNASSIGNED))
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("Name `%s' cannot be converted to IDNA."),
tmp);
GNUNET_free (tmp);
GNUNET_free (ac);
return GNUNET_SYSERR;
}
GNUNET_free (tmp);
}
GNUNET_CONTAINER_DLL_insert_tail (rh->ac_head,
rh->ac_tail,
ac);
if (strlen (ac->label) > GNUNET_DNSPARSER_MAX_NAME_LENGTH)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("GNS lookup resulted in DNS name that is too long (`%s')\n"),
ac->label);
GNUNET_free (ac->label);
GNUNET_free (ac);
return GNUNET_SYSERR;
}
continue_with_gns2dns (ac);
return GNUNET_OK;
}
/**
* Process a records that were decrypted from a block.
*
* @param cls closure with the `struct GNS_ResolverHandle`
* @param rd_count number of entries in @a rd array
* @param rd array of records with data to store
*/
static void
handle_gns_resolution_result (void *cls,
unsigned int rd_count,
const struct GNUNET_GNSRECORD_Data *rd)
{
struct GNS_ResolverHandle *rh = cls;
char *cname;
int af;
char scratch[UINT16_MAX];
size_t scratch_off;
size_t scratch_start;
size_t off;
struct GNUNET_GNSRECORD_Data rd_new[rd_count];
unsigned int rd_off;
GNUNET_log (GNUNET_ERROR_TYPE_INFO,
"Resolution succeeded for `%s' in zone %s, got %u records\n",
rh->ac_tail->label,
GNUNET_GNSRECORD_z2s (&rh->ac_tail->authority_info.gns_authority),
rd_count);
if (0 == rd_count)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("GNS lookup failed (zero records found for `%s')\n"),
rh->name);
fail_resolution (rh);
return;
}
if (0 == rh->name_resolution_pos)
{
/* top-level match, are we done yet? */
if ((rd_count > 0) &&
(GNUNET_DNSPARSER_TYPE_CNAME == rd[0].record_type) &&
(GNUNET_DNSPARSER_TYPE_CNAME != rh->record_type))
{
off = 0;
cname = GNUNET_DNSPARSER_parse_name (rd[0].data,
rd[0].data_size,
&off);
if ((NULL == cname) ||
(off != rd[0].data_size))
{
GNUNET_break_op (0);
GNUNET_free (cname);
fail_resolution (rh);
return;
}
handle_gns_cname_result (rh,
cname);
GNUNET_free (cname);
return;
}
if ((rd_count > 0) &&
(GNUNET_GNSRECORD_TYPE_REDIRECT == rd[0].record_type) &&
(GNUNET_GNSRECORD_TYPE_REDIRECT != rh->record_type))
{
handle_gns_cname_result (rh,
rd[0].data);
return;
}
/* If A/AAAA was requested,
* but we got a GNS2DNS record */
if ((GNUNET_DNSPARSER_TYPE_A == rh->record_type) ||
(GNUNET_DNSPARSER_TYPE_AAAA == rh->record_type))
{
for (unsigned int i = 0; i < rd_count; i++)
{
switch (rd[i].record_type)
{
case GNUNET_GNSRECORD_TYPE_GNS2DNS:
{
/* delegation to DNS */
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Found GNS2DNS record, delegating to DNS!\n");
if (GNUNET_OK ==
recursive_gns2dns_resolution (rh,
rd_count,
rd))
return;
else
goto fail;
}
default:
break;
} /* end: switch */
} /* end: for rd */
} /* end: name_resolution_pos */
/* convert relative names in record values to absolute names,
using 'scratch' array for memory allocations */
scratch_off = 0;
rd_off = 0;
for (unsigned int i = 0; i < rd_count; i++)
{
GNUNET_assert (rd_off <= i);
if ((0 != rh->protocol) &&
(0 != rh->service) &&
(GNUNET_GNSRECORD_TYPE_BOX != rd[i].record_type))
continue; /* we _only_ care about boxed records */
GNUNET_assert (rd_off < rd_count);
rd_new[rd_off] = rd[i];
/* Check if the embedded name(s) end in "+", and if so,
replace the "+" with the zone at "ac_tail", changing the name
to a ".ZONEKEY". The name is allocated on the 'scratch' array,
so we can free it afterwards. */
switch (rd[i].record_type)
{
case GNUNET_GNSRECORD_TYPE_REDIRECT:
{
char *rname;
rname = GNUNET_strndup (rd[i].data, rd[i].data_size);
rname = translate_dot_plus (rh, rname);
GNUNET_break (NULL != rname);
scratch_start = scratch_off;
memcpy (&scratch[scratch_start], rname, strlen (rname) + 1);
scratch_off += strlen (rname) + 1;
GNUNET_assert (rd_off < rd_count);
rd_new[rd_off].data = &scratch[scratch_start];
rd_new[rd_off].data_size = scratch_off - scratch_start;
rd_off++;
GNUNET_free (rname);
}
break;
case GNUNET_DNSPARSER_TYPE_CNAME:
{
char *cname;
off = 0;
cname = GNUNET_DNSPARSER_parse_name (rd[i].data,
rd[i].data_size,
&off);
if ((NULL == cname) ||
(off != rd[i].data_size))
{
GNUNET_break_op (0); /* record not well-formed */
}
else
{
cname = translate_dot_plus (rh, cname);
GNUNET_break (NULL != cname);
scratch_start = scratch_off;
if (GNUNET_OK !=
GNUNET_DNSPARSER_builder_add_name (scratch,
sizeof(scratch),
&scratch_off,
cname))
{
GNUNET_break (0);
}
else
{
GNUNET_assert (rd_off < rd_count);
rd_new[rd_off].data = &scratch[scratch_start];
rd_new[rd_off].data_size = scratch_off - scratch_start;
rd_off++;
}
}
GNUNET_free (cname);
}
break;
case GNUNET_DNSPARSER_TYPE_SOA:
{
struct GNUNET_DNSPARSER_SoaRecord *soa;
off = 0;
soa = GNUNET_DNSPARSER_parse_soa (rd[i].data,
rd[i].data_size,
&off);
if ((NULL == soa) ||
(off != rd[i].data_size))
{
GNUNET_break_op (0); /* record not well-formed */
}
else
{
soa->mname = translate_dot_plus (rh, soa->mname);
soa->rname = translate_dot_plus (rh, soa->rname);
scratch_start = scratch_off;
if (GNUNET_OK !=
GNUNET_DNSPARSER_builder_add_soa (scratch,
sizeof(scratch),
&scratch_off,
soa))
{
GNUNET_break (0);
}
else
{
GNUNET_assert (rd_off < rd_count);
rd_new[rd_off].data = &scratch[scratch_start];
rd_new[rd_off].data_size = scratch_off - scratch_start;
rd_off++;
}
}
if (NULL != soa)
GNUNET_DNSPARSER_free_soa (soa);
}
break;
case GNUNET_DNSPARSER_TYPE_MX:
{
struct GNUNET_DNSPARSER_MxRecord *mx;
off = 0;
mx = GNUNET_DNSPARSER_parse_mx (rd[i].data,
rd[i].data_size,
&off);
if ((NULL == mx) ||
(off != rd[i].data_size))
{
GNUNET_break_op (0); /* record not well-formed */
}
else
{
mx->mxhost = translate_dot_plus (rh, mx->mxhost);
scratch_start = scratch_off;
if (GNUNET_OK !=
GNUNET_DNSPARSER_builder_add_mx (scratch,
sizeof(scratch),
&scratch_off,
mx))
{
GNUNET_break (0);
}
else
{
GNUNET_assert (rd_off < rd_count);
rd_new[rd_off].data = &scratch[scratch_start];
rd_new[rd_off].data_size = scratch_off - scratch_start;
rd_off++;
}
}
if (NULL != mx)
GNUNET_DNSPARSER_free_mx (mx);
}
break;
case GNUNET_DNSPARSER_TYPE_SRV:
{
struct GNUNET_DNSPARSER_SrvRecord *srv;
off = 0;
srv = GNUNET_DNSPARSER_parse_srv (rd[i].data,
rd[i].data_size,
&off);
if ((NULL == srv) ||
(off != rd[i].data_size))
{
GNUNET_break_op (0); /* record not well-formed */
}
else
{
srv->target = translate_dot_plus (rh, srv->target);
scratch_start = scratch_off;
if (GNUNET_OK !=
GNUNET_DNSPARSER_builder_add_srv (scratch,
sizeof(scratch),
&scratch_off,
srv))
{
GNUNET_break (0);
}
else
{
GNUNET_assert (rd_off < rd_count);
rd_new[rd_off].data = &scratch[scratch_start];
rd_new[rd_off].data_size = scratch_off - scratch_start;
rd_off++;
}
}
if (NULL != srv)
GNUNET_DNSPARSER_free_srv (srv);
}
break;
case GNUNET_GNSRECORD_TYPE_PKEY:
case GNUNET_GNSRECORD_TYPE_EDKEY:
{
struct GNUNET_IDENTITY_PublicKey pubkey;
if (rd[i].data_size < sizeof(uint32_t))
{
GNUNET_break_op (0);
break;
}
if (GNUNET_OK !=
GNUNET_GNSRECORD_identity_from_data (rd[i].data,
rd[i].data_size,
rd[i].record_type,
&pubkey))
{
GNUNET_break_op (0);
break;
}
rd_off++;
if (rd[i].record_type != rh->record_type)
{
/* try to resolve "@" */
struct AuthorityChain *ac;
ac = GNUNET_new (struct AuthorityChain);
ac->rh = rh;
ac->gns_authority = GNUNET_YES;
ac->authority_info.gns_authority = pubkey;
ac->label = GNUNET_strdup (GNUNET_GNS_EMPTY_LABEL_AT);
GNUNET_CONTAINER_DLL_insert_tail (rh->ac_head,
rh->ac_tail,
ac);
rh->task_id = GNUNET_SCHEDULER_add_now (&recursive_resolution,
rh);
return;
}
}
break;
case GNUNET_GNSRECORD_TYPE_GNS2DNS:
{
/* delegation to DNS */
if (GNUNET_GNSRECORD_TYPE_GNS2DNS == rh->record_type)
{
rd_off++;
break; /* do not follow to DNS, we wanted the GNS2DNS record! */
}
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Found GNS2DNS record, delegating to DNS!\n");
if (GNUNET_OK ==
recursive_gns2dns_resolution (rh,
rd_count,
rd))
return;
else
goto fail;
}
case GNUNET_GNSRECORD_TYPE_BOX:
{
/* unbox SRV/TLSA records if a specific one was requested */
if ((0 != rh->protocol) &&
(0 != rh->service) &&
(rd[i].data_size >= sizeof(struct GNUNET_GNSRECORD_BoxRecord)))
{
const struct GNUNET_GNSRECORD_BoxRecord *box;
box = rd[i].data;
if ((ntohs (box->protocol) == rh->protocol) &&
(ntohs (box->service) == rh->service))
{
/* Box matches, unbox! */
GNUNET_assert (rd_off < rd_count);
rd_new[rd_off].record_type = ntohl (box->record_type);
rd_new[rd_off].data_size -= sizeof(struct
GNUNET_GNSRECORD_BoxRecord);
rd_new[rd_off].data = &box[1];
rd_off++;
}
}
else
{
/* no specific protocol/service specified, preserve all BOX
records (for modern, GNS-enabled applications) */
rd_off++;
}
break;
}
default:
rd_off++;
break;
} /* end: switch */
} /* end: for rd_count */
/* yes, we are done, return result */
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Returning GNS response for `%s' with %u answers\n",
rh->ac_tail->label,
rd_off);
rh->proc (rh->proc_cls,
rd_off,
rd_new);
rh->task_id = GNUNET_SCHEDULER_add_now (&GNS_resolver_lookup_cancel_,
rh);
return;
}
switch (rd[0].record_type)
{
case GNUNET_GNSRECORD_TYPE_REDIRECT:
GNUNET_break_op (1 == rd_count); /* REDIRECT should be unique */
recursive_redirect_resolution (rh,
&rd[0]);
return;
case GNUNET_DNSPARSER_TYPE_CNAME:
GNUNET_break_op (1 == rd_count); /* CNAME should be unique */
recursive_cname_resolution (rh,
&rd[0]);
return;
case GNUNET_GNSRECORD_TYPE_PKEY:
case GNUNET_GNSRECORD_TYPE_EDKEY:
GNUNET_break_op (1 == rd_count); /* PKEY should be unique */
recursive_pkey_resolution (rh,
&rd[0]);
return;
case GNUNET_GNSRECORD_TYPE_GNS2DNS:
if (GNUNET_OK ==
recursive_gns2dns_resolution (rh,
rd_count,
rd))
return;
default:
if (GNUNET_YES != GNUNET_GNSRECORD_is_critical (rd[0].record_type))
return;
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("Unable to process critical delegation record\n"));
break;
}
fail:
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("GNS lookup recursion failed (no delegation record found)\n"));
fail_resolution (rh);
}
/**
* Function called once the namestore has completed the request for
* caching a block.
*
* @param cls closure with the `struct CacheOps`
* @param success #GNUNET_OK on success
* @param emsg error message
*/
static void
namecache_cache_continuation (void *cls,
int32_t success,
const char *emsg)
{
struct CacheOps *co = cls;
co->namecache_qe_cache = NULL;
if (GNUNET_OK != success)
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("Failed to cache GNS resolution: %s\n"),
emsg);
GNUNET_CONTAINER_DLL_remove (co_head,
co_tail,
co);
GNUNET_free (co);
}
/**
* Iterator called on each result obtained for a DHT
* operation that expects a reply
*
* @param cls closure with the `struct GNS_ResolverHandle`
* @param exp when will this value expire
* @param key key of the result
* @param get_path peers on reply path (or NULL if not recorded)
* [0] = datastore's first neighbor, [length - 1] = local peer
* @param get_path_length number of entries in @a get_path
* @param put_path peers on the PUT path (or NULL if not recorded)
* [0] = origin, [length - 1] = datastore
* @param put_path_length number of entries in @a put_path
* @param type type of the result
* @param size number of bytes in data
* @param data pointer to the result data
*/
static void
handle_dht_response (void *cls,
struct GNUNET_TIME_Absolute exp,
const struct GNUNET_HashCode *key,
const struct GNUNET_DHT_PathElement *get_path,
unsigned int get_path_length,
const struct GNUNET_DHT_PathElement *put_path,
unsigned int put_path_length,
enum GNUNET_BLOCK_Type type,
size_t size,
const void *data)
{
struct GNS_ResolverHandle *rh = cls;
struct AuthorityChain *ac = rh->ac_tail;
const struct GNUNET_GNSRECORD_Block *block;
struct CacheOps *co;
(void) exp;
(void) key;
(void) get_path;
(void) get_path_length;
(void) put_path;
(void) put_path_length;
(void) type;
GNUNET_DHT_get_stop (rh->get_handle);
rh->get_handle = NULL;
GNUNET_CONTAINER_heap_remove_node (rh->dht_heap_node);
rh->dht_heap_node = NULL;
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Handling response from the DHT\n");
if (size < sizeof(struct GNUNET_GNSRECORD_Block))
{
/* how did this pass DHT block validation!? */
GNUNET_break (0);
fail_resolution (rh);
return;
}
block = data;
if (size != GNUNET_GNSRECORD_block_get_size (block))
{
/* how did this pass DHT block validation!? */
GNUNET_break (0);
fail_resolution (rh);
return;
}
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Decrypting DHT block of size %lu for `%s', expires %s\n",
GNUNET_GNSRECORD_block_get_size (block),
rh->name,
GNUNET_STRINGS_absolute_time_to_string (exp));
if (GNUNET_OK !=
GNUNET_GNSRECORD_block_decrypt (block,
&ac->authority_info.gns_authority,
ac->label,
&handle_gns_resolution_result,
rh))
{
GNUNET_break_op (0); /* block was ill-formed */
fail_resolution (rh);
return;
}
if (0 == GNUNET_TIME_absolute_get_remaining (
GNUNET_GNSRECORD_block_get_expiration (block)).
rel_value_us)
{
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Received expired block from the DHT, will not cache it.\n");
return;
}
if (GNUNET_YES == disable_cache)
return;
/* Cache well-formed blocks */
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Caching response from the DHT in namecache\n");
co = GNUNET_new (struct CacheOps);
co->namecache_qe_cache = GNUNET_NAMECACHE_block_cache (namecache_handle,
block,
&
namecache_cache_continuation,
co);
GNUNET_CONTAINER_DLL_insert (co_head,
co_tail,
co);
}
/**
* Initiate a DHT query for a set of GNS records.
*
* @param rh resolution handle
* @param query key to use in the DHT lookup
*/
static void
start_dht_request (struct GNS_ResolverHandle *rh,
const struct GNUNET_HashCode *query)
{
struct GNS_ResolverHandle *rx;
GNUNET_assert (NULL == rh->get_handle);
rh->get_handle = GNUNET_DHT_get_start (dht_handle,
GNUNET_BLOCK_TYPE_GNS_NAMERECORD,
query,
DHT_GNS_REPLICATION_LEVEL,
GNUNET_DHT_RO_DEMULTIPLEX_EVERYWHERE,
NULL, 0,
&handle_dht_response, rh);
rh->dht_heap_node = GNUNET_CONTAINER_heap_insert (dht_lookup_heap,
rh,
GNUNET_TIME_absolute_get ().
abs_value_us);
if (GNUNET_CONTAINER_heap_get_size (dht_lookup_heap) >
max_allowed_background_queries)
{
/* fail longest-standing DHT request */
rx = GNUNET_CONTAINER_heap_remove_root (dht_lookup_heap);
rx->dht_heap_node = NULL;
GNUNET_assert (NULL != rx);
fail_resolution (rx);
}
}
/**
* Process a records that were decrypted from a block that we got from
* the namecache. Simply calls #handle_gns_resolution_result().
*
* @param cls closure with the `struct GNS_ResolverHandle`
* @param rd_count number of entries in @a rd array
* @param rd array of records with data to store
*/
static void
handle_gns_namecache_resolution_result (void *cls,
unsigned int rd_count,
const struct GNUNET_GNSRECORD_Data *rd)
{
struct GNS_ResolverHandle *rh = cls;
if (0 == rd_count)
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("GNS namecache returned empty result for `%s'\n"),
rh->name);
handle_gns_resolution_result (rh,
rd_count,
rd);
}
/**
* Process a record that was stored in the namecache.
*
* @param cls closure with the `struct GNS_ResolverHandle`
* @param block block that was stored in the namecache
*/
static void
handle_namecache_block_response (void *cls,
const struct GNUNET_GNSRECORD_Block *block)
{
struct GNS_ResolverHandle *rh = cls;
struct AuthorityChain *ac = rh->ac_tail;
const char *label = ac->label;
const struct GNUNET_IDENTITY_PublicKey *auth =
&ac->authority_info.gns_authority;
struct GNUNET_HashCode query;
GNUNET_assert (NULL != rh->namecache_qe);
rh->namecache_qe = NULL;
if (((GNUNET_GNS_LO_DEFAULT == rh->options) ||
((GNUNET_GNS_LO_LOCAL_MASTER == rh->options) &&
(ac != rh->ac_head))) &&
((NULL == block) ||
(0 == GNUNET_TIME_absolute_get_remaining (
GNUNET_GNSRECORD_block_get_expiration (block)).
rel_value_us)))
{
/* namecache knows nothing; try DHT lookup */
GNUNET_GNSRECORD_query_from_public_key (auth,
label,
&query);
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Starting DHT lookup for `%s' in zone `%s' under key `%s'\n",
ac->label,
GNUNET_GNSRECORD_z2s (&ac->authority_info.gns_authority),
GNUNET_h2s (&query));
start_dht_request (rh, &query);
return;
}
if ((NULL == block) ||
(0 == GNUNET_TIME_absolute_get_remaining (
GNUNET_GNSRECORD_block_get_expiration (block)).
rel_value_us))
{
/* DHT not permitted and no local result, fail */
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Resolution failed for `%s' in zone %s (DHT lookup not permitted by configuration)\n",
ac->label,
GNUNET_GNSRECORD_z2s (&ac->authority_info.gns_authority));
fail_resolution (rh);
return;
}
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Received result from namecache for label `%s'\n",
ac->label);
if (GNUNET_OK !=
GNUNET_GNSRECORD_block_decrypt (block,
auth,
label,
&handle_gns_namecache_resolution_result,
rh))
{
GNUNET_break_op (0); /* block was ill-formed */
/* try DHT instead */
GNUNET_GNSRECORD_query_from_public_key (auth,
label,
&query);
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Starting DHT lookup for `%s' in zone `%s' under key `%s'\n",
ac->label,
GNUNET_GNSRECORD_z2s (&ac->authority_info.gns_authority),
GNUNET_h2s (&query));
start_dht_request (rh, &query);
return;
}
}
/**
* Lookup tail of our authority chain in the namecache.
*
* @param rh query we are processing
*/
static void
recursive_gns_resolution_namecache (struct GNS_ResolverHandle *rh)
{
struct AuthorityChain *ac = rh->ac_tail;
struct GNUNET_HashCode query;
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Starting GNS resolution for `%s' in zone %s\n",
ac->label,
GNUNET_GNSRECORD_z2s (&ac->authority_info.gns_authority));
GNUNET_GNSRECORD_query_from_public_key (&ac->authority_info.gns_authority,
ac->label,
&query);
if (GNUNET_YES != disable_cache)
{
rh->namecache_qe
= GNUNET_NAMECACHE_lookup_block (namecache_handle,
&query,
&handle_namecache_block_response,
rh);
GNUNET_assert (NULL != rh->namecache_qe);
}
else
{
start_dht_request (rh,
&query);
}
}
/**
* Function called with the result from a revocation check.
*
* @param cls the `struct GNS_ResovlerHandle`
* @param is_valid #GNUNET_YES if the zone was not yet revoked
*/
static void
handle_revocation_result (void *cls,
int is_valid)
{
struct GNS_ResolverHandle *rh = cls;
struct AuthorityChain *ac = rh->ac_tail;
rh->rev_check = NULL;
if (GNUNET_YES != is_valid)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
_ ("Zone %s was revoked, resolution fails\n"),
GNUNET_GNSRECORD_z2s (&ac->authority_info.gns_authority));
fail_resolution (rh);
return;
}
recursive_gns_resolution_namecache (rh);
}
/**
* Perform revocation check on tail of our authority chain.
*
* @param rh query we are processing
*/
static void
recursive_gns_resolution_revocation (struct GNS_ResolverHandle *rh)
{
struct AuthorityChain *ac = rh->ac_tail;
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Starting revocation check for zone %s\n",
GNUNET_GNSRECORD_z2s (&ac->authority_info.gns_authority));
rh->rev_check = GNUNET_REVOCATION_query (cfg,
&ac->authority_info.gns_authority,
&handle_revocation_result,
rh);
GNUNET_assert (NULL != rh->rev_check);
}
/**
* Task scheduled to continue with the resolution process.
*
* @param cls the `struct GNS_ResolverHandle` of the resolution
*/
static void
recursive_resolution (void *cls)
{
struct GNS_ResolverHandle *rh = cls;
rh->task_id = NULL;
if (rh->loop_threshold < rh->loop_limiter++)
{
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Encountered unbounded recursion resolving `%s'\n",
rh->name);
fail_resolution (rh);
return;
}
if (GNUNET_YES == rh->ac_tail->gns_authority)
recursive_gns_resolution_revocation (rh);
else
recursive_dns_resolution (rh);
}
/**
* Begin the resolution process from 'name', starting with
* the identification of the zone specified by 'name'.
*
* @param cls the `struct GNS_ResolverHandle`
*/
static void
start_resolver_lookup (void *cls)
{
struct GNS_ResolverHandle *rh = cls;
struct AuthorityChain *ac;
struct in_addr v4;
struct in6_addr v6;
rh->task_id = NULL;
if (1 == inet_pton (AF_INET,
rh->name,
&v4))
{
/* name is IPv4 address, pretend it's an A record */
struct GNUNET_GNSRECORD_Data rd;
rd.data = &v4;
rd.data_size = sizeof(v4);
rd.expiration_time = UINT64_MAX;
rd.record_type = GNUNET_DNSPARSER_TYPE_A;
rd.flags = 0;
rh->proc (rh->proc_cls,
1,
&rd);
GNUNET_assert (NULL == rh->task_id);
rh->task_id = GNUNET_SCHEDULER_add_now (&GNS_resolver_lookup_cancel_,
rh);
return;
}
if (1 == inet_pton (AF_INET6,
rh->name,
&v6))
{
/* name is IPv6 address, pretend it's an AAAA record */
struct GNUNET_GNSRECORD_Data rd;
rd.data = &v6;
rd.data_size = sizeof(v6);
rd.expiration_time = UINT64_MAX;
rd.record_type = GNUNET_DNSPARSER_TYPE_AAAA;
rd.flags = 0;
rh->proc (rh->proc_cls,
1,
&rd);
GNUNET_assert (NULL == rh->task_id);
rh->task_id = GNUNET_SCHEDULER_add_now (&GNS_resolver_lookup_cancel_,
rh);
return;
}
ac = GNUNET_new (struct AuthorityChain);
ac->rh = rh;
ac->label = resolver_lookup_get_next_label (rh);
if (NULL == ac->label)
/* name was just the "TLD", so we default to label
#GNUNET_GNS_EMPTY_LABEL_AT */
ac->label = GNUNET_strdup (GNUNET_GNS_EMPTY_LABEL_AT);
ac->gns_authority = GNUNET_YES;
ac->authority_info.gns_authority = rh->authority_zone;
GNUNET_CONTAINER_DLL_insert_tail (rh->ac_head,
rh->ac_tail,
ac);
rh->task_id = GNUNET_SCHEDULER_add_now (&recursive_resolution,
rh);
}
/**
* Lookup of a record in a specific zone calls lookup result processor
* on result.
*
* @param zone the zone to perform the lookup in
* @param record_type the record type to look up
* @param name the name to look up
* @param options local options to control local lookup
* @param recursion_depth_limit how many zones to traverse
* at most
* @param proc the processor to call on result
* @param proc_cls the closure to pass to @a proc
* @return handle to cancel operation
*/
struct GNS_ResolverHandle *
GNS_resolver_lookup (const struct GNUNET_IDENTITY_PublicKey *zone,
uint32_t record_type,
const char *name,
enum GNUNET_GNS_LocalOptions options,
uint16_t recursion_depth_limit,
GNS_ResultProcessor proc,
void *proc_cls)
{
struct GNS_ResolverHandle *rh;
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Starting lookup for `%s'\n",
name);
rh = GNUNET_new (struct GNS_ResolverHandle);
GNUNET_CONTAINER_DLL_insert (rlh_head,
rlh_tail,
rh);
rh->authority_zone = *zone;
rh->proc = proc;
rh->proc_cls = proc_cls;
rh->options = options;
rh->record_type = record_type;
rh->name = GNUNET_strdup (name);
rh->name_resolution_pos = strlen (name);
rh->loop_threshold = recursion_depth_limit;
rh->task_id = GNUNET_SCHEDULER_add_now (&start_resolver_lookup,
rh);
return rh;
}
/**
* Cancel active resolution (i.e. client disconnected).
*
* @param rh resolution to abort
*/
void
GNS_resolver_lookup_cancel (struct GNS_ResolverHandle *rh)
{
struct DnsResult *dr;
struct AuthorityChain *ac;
GNUNET_CONTAINER_DLL_remove (rlh_head,
rlh_tail,
rh);
if (NULL != rh->dns_request)
{
GNUNET_DNSSTUB_resolve_cancel (rh->dns_request);
rh->dns_request = NULL;
}
while (NULL != (ac = rh->ac_head))
{
GNUNET_CONTAINER_DLL_remove (rh->ac_head,
rh->ac_tail,
ac);
if (GNUNET_NO == ac->gns_authority)
{
struct Gns2DnsPending *gp;
while (NULL != (gp = ac->authority_info.dns_authority.gp_head))
{
GNUNET_CONTAINER_DLL_remove (ac->authority_info.dns_authority.gp_head,
ac->authority_info.dns_authority.gp_tail,
gp);
if (NULL != gp->rh)
{
/* rh->g2dc->rh is NOT in the DLL yet, so to enable us
using GNS_resolver_lookup_cancel here, we need to
add it first... */
GNUNET_CONTAINER_DLL_insert (rlh_head,
rlh_tail,
gp->rh);
GNUNET_assert (NULL == gp->rh->task_id);
gp->rh->task_id = GNUNET_SCHEDULER_add_now (
&GNS_resolver_lookup_cancel_,
gp->rh);
gp->rh = NULL;
}
if (NULL != gp->dns_rh)
{
GNUNET_RESOLVER_request_cancel (gp->dns_rh);
gp->dns_rh = NULL;
}
GNUNET_free (gp);
}
GNUNET_DNSSTUB_stop (ac->authority_info.dns_authority.dns_handle);
}
GNUNET_free (ac->label);
GNUNET_free (ac);
}
if (NULL != rh->task_id)
{
GNUNET_SCHEDULER_cancel (rh->task_id);
rh->task_id = NULL;
}
if (NULL != rh->get_handle)
{
GNUNET_DHT_get_stop (rh->get_handle);
rh->get_handle = NULL;
}
if (NULL != rh->dht_heap_node)
{
GNUNET_CONTAINER_heap_remove_node (rh->dht_heap_node);
rh->dht_heap_node = NULL;
}
if (NULL != rh->namecache_qe)
{
GNUNET_NAMECACHE_cancel (rh->namecache_qe);
rh->namecache_qe = NULL;
}
if (NULL != rh->rev_check)
{
GNUNET_REVOCATION_query_cancel (rh->rev_check);
rh->rev_check = NULL;
}
if (NULL != rh->std_resolve)
{
GNUNET_log (GNUNET_ERROR_TYPE_DEBUG,
"Canceling standard DNS resolution\n");
GNUNET_RESOLVER_request_cancel (rh->std_resolve);
rh->std_resolve = NULL;
}
while (NULL != (dr = rh->dns_result_head))
{
GNUNET_CONTAINER_DLL_remove (rh->dns_result_head,
rh->dns_result_tail,
dr);
GNUNET_free (dr);
}
GNUNET_free (rh->leho);
GNUNET_free (rh->name);
GNUNET_free (rh);
}
/* ***************** Resolver initialization ********************* */
/**
* Initialize the resolver
*
* @param nc the namecache handle
* @param dht the dht handle
* @param c configuration handle
* @param max_bg_queries maximum number of parallel background queries in dht
*/
void
GNS_resolver_init (struct GNUNET_NAMECACHE_Handle *nc,
struct GNUNET_DHT_Handle *dht,
const struct GNUNET_CONFIGURATION_Handle *c,
unsigned long long max_bg_queries)
{
cfg = c;
namecache_handle = nc;
dht_handle = dht;
dht_lookup_heap =
GNUNET_CONTAINER_heap_create (GNUNET_CONTAINER_HEAP_ORDER_MIN);
max_allowed_background_queries = max_bg_queries;
disable_cache = GNUNET_CONFIGURATION_get_value_yesno (cfg,
"namecache",
"DISABLE");
if (GNUNET_YES == disable_cache)
GNUNET_log (GNUNET_ERROR_TYPE_WARNING,
"Namecache disabled\n");
}
/**
* Shutdown resolver
*/
void
GNS_resolver_done ()
{
struct GNS_ResolverHandle *rh;
struct CacheOps *co;
/* abort active resolutions */
while (NULL != (rh = rlh_head))
{
rh->proc (rh->proc_cls,
0,
NULL);
GNS_resolver_lookup_cancel (rh);
}
while (NULL != (co = co_head))
{
GNUNET_CONTAINER_DLL_remove (co_head,
co_tail,
co);
GNUNET_NAMECACHE_cancel (co->namecache_qe_cache);
GNUNET_free (co);
}
GNUNET_CONTAINER_heap_destroy (dht_lookup_heap);
dht_lookup_heap = NULL;
dht_handle = NULL;
namecache_handle = NULL;
}
/* end of gnunet-service-gns_resolver.c */