/* Copyright (c) 2016-2017, The Tor Project, Inc. */
/* See LICENSE for licensing information */
/**
* \file hs_service.c
* \brief Implement next generation hidden service functionality
**/
#include "or.h"
#include "relay.h"
#include "rendservice.h"
#include "circuitlist.h"
#include "circpathbias.h"
#include "hs_intropoint.h"
#include "hs_service.h"
#include "hs_common.h"
#include "hs/cell_establish_intro.h"
#include "hs/cell_common.h"
/* Set the default values for a service configuration object c. */
static void
set_service_default_config(hs_service_config_t *c,
const or_options_t *options)
{
tor_assert(c);
c->ports = smartlist_new();
c->directory_path = NULL;
c->descriptor_post_period = options->RendPostPeriod;
c->max_streams_per_rdv_circuit = 0;
c->max_streams_close_circuit = 0;
c->num_intro_points = NUM_INTRO_POINTS_DEFAULT;
c->allow_unknown_ports = 0;
c->is_single_onion = 0;
c->dir_group_readable = 0;
c->is_ephemeral = 0;
}
/* Allocate and initilize a service object. The service configuration will
* contain the default values. Return the newly allocated object pointer. This
* function can't fail. */
hs_service_t *
hs_service_new(const or_options_t *options)
{
hs_service_t *service = tor_malloc_zero(sizeof(hs_service_t));
/* Set default configuration value. */
set_service_default_config(&service->config, options);
/* Set the default service version. */
service->version = HS_SERVICE_DEFAULT_VERSION;
return service;
}
/* Free the given service object and all its content. This function
* also takes care of wiping service keys from memory. It is safe to pass a
* NULL pointer. */
void
hs_service_free(hs_service_t *service)
{
if (service == NULL) {
return;
}
/* Free descriptors. */
if (service->desc_current) {
hs_descriptor_free(service->desc_current->desc);
/* Wipe keys. */
memwipe(&service->desc_current->signing_kp, 0,
sizeof(service->desc_current->signing_kp));
memwipe(&service->desc_current->blinded_kp, 0,
sizeof(service->desc_current->blinded_kp));
/* XXX: Free intro points. */
tor_free(service->desc_current);
}
if (service->desc_next) {
hs_descriptor_free(service->desc_next->desc);
/* Wipe keys. */
memwipe(&service->desc_next->signing_kp, 0,
sizeof(service->desc_next->signing_kp));
memwipe(&service->desc_next->blinded_kp, 0,
sizeof(service->desc_next->blinded_kp));
/* XXX: Free intro points. */
tor_free(service->desc_next);
}
/* Free service configuration. */
tor_free(service->config.directory_path);
if (service->config.ports) {
SMARTLIST_FOREACH(service->config.ports, rend_service_port_config_t *, p,
rend_service_port_config_free(p););
smartlist_free(service->config.ports);
}
/* Wipe service keys. */
memwipe(&service->keys.identity_sk, 0, sizeof(service->keys.identity_sk));
tor_free(service);
}
/* Initialize the service HS subsystem. */
void
hs_service_init(void)
{
return;
}
/* Release all global the storage of hidden service subsystem. */
void
hs_service_free_all(void)
{
rend_service_free_all();
}
/* XXX We don't currently use these functions, apart from generating unittest
data. When we start implementing the service-side support for prop224 we
should revisit these functions and use them. */
/** Given an ESTABLISH_INTRO cell, encode it and place its payload in
* buf_out which has size buf_out_len. Return the number of
* bytes written, or a negative integer if there was an error. */
ssize_t
get_establish_intro_payload(uint8_t *buf_out, size_t buf_out_len,
const trn_cell_establish_intro_t *cell)
{
ssize_t bytes_used = 0;
if (buf_out_len < RELAY_PAYLOAD_SIZE) {
return -1;
}
bytes_used = trn_cell_establish_intro_encode(buf_out, buf_out_len,
cell);
return bytes_used;
}
/* Set the cell extensions of cell. */
static void
set_trn_cell_extensions(trn_cell_establish_intro_t *cell)
{
trn_cell_extension_t *trn_cell_extensions = trn_cell_extension_new();
/* For now, we don't use extensions at all. */
trn_cell_extensions->num = 0; /* It's already zeroed, but be explicit. */
trn_cell_establish_intro_set_extensions(cell, trn_cell_extensions);
}
/** Given the circuit handshake info in circuit_key_material, create and
* return an ESTABLISH_INTRO cell. Return NULL if something went wrong. The
* returned cell is allocated on the heap and it's the responsibility of the
* caller to free it. */
trn_cell_establish_intro_t *
generate_establish_intro_cell(const uint8_t *circuit_key_material,
size_t circuit_key_material_len)
{
trn_cell_establish_intro_t *cell = NULL;
ssize_t encoded_len;
log_warn(LD_GENERAL,
"Generating ESTABLISH_INTRO cell (key_material_len: %u)",
(unsigned) circuit_key_material_len);
/* Generate short-term keypair for use in ESTABLISH_INTRO */
ed25519_keypair_t key_struct;
if (ed25519_keypair_generate(&key_struct, 0) < 0) {
goto err;
}
cell = trn_cell_establish_intro_new();
/* Set AUTH_KEY_TYPE: 2 means ed25519 */
trn_cell_establish_intro_set_auth_key_type(cell,
HS_INTRO_AUTH_KEY_TYPE_ED25519);
/* Set AUTH_KEY_LEN field */
/* Must also set byte-length of AUTH_KEY to match */
int auth_key_len = ED25519_PUBKEY_LEN;
trn_cell_establish_intro_set_auth_key_len(cell, auth_key_len);
trn_cell_establish_intro_setlen_auth_key(cell, auth_key_len);
/* Set AUTH_KEY field */
uint8_t *auth_key_ptr = trn_cell_establish_intro_getarray_auth_key(cell);
memcpy(auth_key_ptr, key_struct.pubkey.pubkey, auth_key_len);
/* No cell extensions needed */
set_trn_cell_extensions(cell);
/* Set signature size.
We need to do this up here, because _encode() needs it and we need to call
_encode() to calculate the MAC and signature.
*/
int sig_len = ED25519_SIG_LEN;
trn_cell_establish_intro_set_sig_len(cell, sig_len);
trn_cell_establish_intro_setlen_sig(cell, sig_len);
/* XXX How to make this process easier and nicer? */
/* Calculate the cell MAC (aka HANDSHAKE_AUTH). */
{
/* To calculate HANDSHAKE_AUTH, we dump the cell in bytes, and then derive
the MAC from it. */
uint8_t cell_bytes_tmp[RELAY_PAYLOAD_SIZE] = {0};
uint8_t mac[TRUNNEL_SHA3_256_LEN];
encoded_len = trn_cell_establish_intro_encode(cell_bytes_tmp,
sizeof(cell_bytes_tmp),
cell);
if (encoded_len < 0) {
log_warn(LD_OR, "Unable to pre-encode ESTABLISH_INTRO cell.");
goto err;
}
/* sanity check */
tor_assert(encoded_len > ED25519_SIG_LEN + 2 + TRUNNEL_SHA3_256_LEN);
/* Calculate MAC of all fields before HANDSHAKE_AUTH */
crypto_mac_sha3_256(mac, sizeof(mac),
circuit_key_material, circuit_key_material_len,
cell_bytes_tmp,
encoded_len -
(ED25519_SIG_LEN + 2 + TRUNNEL_SHA3_256_LEN));
/* Write the MAC to the cell */
uint8_t *handshake_ptr =
trn_cell_establish_intro_getarray_handshake_mac(cell);
memcpy(handshake_ptr, mac, sizeof(mac));
}
/* Calculate the cell signature */
{
/* To calculate the sig we follow the same procedure as above. We first
dump the cell up to the sig, and then calculate the sig */
uint8_t cell_bytes_tmp[RELAY_PAYLOAD_SIZE] = {0};
ed25519_signature_t sig;
encoded_len = trn_cell_establish_intro_encode(cell_bytes_tmp,
sizeof(cell_bytes_tmp),
cell);
if (encoded_len < 0) {
log_warn(LD_OR, "Unable to pre-encode ESTABLISH_INTRO cell (2).");
goto err;
}
tor_assert(encoded_len > ED25519_SIG_LEN);
if (ed25519_sign_prefixed(&sig,
cell_bytes_tmp,
encoded_len -
(ED25519_SIG_LEN + sizeof(cell->sig_len)),
ESTABLISH_INTRO_SIG_PREFIX,
&key_struct)) {
log_warn(LD_BUG, "Unable to gen signature for ESTABLISH_INTRO cell.");
goto err;
}
/* And write the signature to the cell */
uint8_t *sig_ptr = trn_cell_establish_intro_getarray_sig(cell);
memcpy(sig_ptr, sig.sig, sig_len);
}
/* We are done! Return the cell! */
return cell;
err:
trn_cell_establish_intro_free(cell);
return NULL;
}