tor-parallel-relay-conn/src/or/hs_common.c

/* Copyright (c) 2016-2017, The Tor Project, Inc. */
/* See LICENSE for licensing information */

/**
 * \file hs_common.c
 * \brief Contains code shared between different HS protocol version as well
 *        as useful data structures and accessors used by other subsystems.
 *        The rendcommon.c should only contains code relating to the v2
 *        protocol.
 **/

#define HS_COMMON_PRIVATE

#include "or.h"

#include "config.h"
#include "networkstatus.h"
#include "nodelist.h"
#include "hs_cache.h"
#include "hs_common.h"
#include "hs_service.h"
#include "rendcommon.h"
#include "rendservice.h"
#include "router.h"
#include "shared_random.h"
#include "shared_random_state.h"

/* Ed25519 Basepoint value. Taken from section 5 of
 * https://tools.ietf.org/html/draft-josefsson-eddsa-ed25519-03 */
static const char *str_ed25519_basepoint =
  "(15112221349535400772501151409588531511"
  "454012693041857206046113283949847762202, "
  "463168356949264781694283940034751631413"
  "07993866256225615783033603165251855960)";

#ifdef HAVE_SYS_UN_H

/** Given <b>ports</b>, a smarlist containing rend_service_port_config_t,
 * add the given <b>p</b>, a AF_UNIX port to the list. Return 0 on success
 * else return -ENOSYS if AF_UNIX is not supported (see function in the
 * #else statement below). */
static int
add_unix_port(smartlist_t *ports, rend_service_port_config_t *p)
{
  tor_assert(ports);
  tor_assert(p);
  tor_assert(p->is_unix_addr);

  smartlist_add(ports, p);
  return 0;
}

/** Given <b>conn</b> set it to use the given port <b>p</b> values. Return 0
 * on success else return -ENOSYS if AF_UNIX is not supported (see function
 * in the #else statement below). */
static int
set_unix_port(edge_connection_t *conn, rend_service_port_config_t *p)
{
  tor_assert(conn);
  tor_assert(p);
  tor_assert(p->is_unix_addr);

  conn->base_.socket_family = AF_UNIX;
  tor_addr_make_unspec(&conn->base_.addr);
  conn->base_.port = 1;
  conn->base_.address = tor_strdup(p->unix_addr);
  return 0;
}

#else /* defined(HAVE_SYS_UN_H) */

static int
set_unix_port(edge_connection_t *conn, rend_service_port_config_t *p)
{
  (void) conn;
  (void) p;
  return -ENOSYS;
}

static int
add_unix_port(smartlist_t *ports, rend_service_port_config_t *p)
{
  (void) ports;
  (void) p;
  return -ENOSYS;
}

#endif /* HAVE_SYS_UN_H */

/* Helper function: The key is a digest that we compare to a node_t object
 * current hsdir_index. */
static int
compare_digest_to_current_hsdir_index(const void *_key, const void **_member)
{
  const char *key = _key;
  const node_t *node = *_member;
  return tor_memcmp(key, node->hsdir_index->current, DIGEST256_LEN);
}

/* Helper function: The key is a digest that we compare to a node_t object
 * next hsdir_index. */
static int
compare_digest_to_next_hsdir_index(const void *_key, const void **_member)
{
  const char *key = _key;
  const node_t *node = *_member;
  return tor_memcmp(key, node->hsdir_index->next, DIGEST256_LEN);
}

/* Helper function: Compare two node_t objects current hsdir_index. */
static int
compare_node_current_hsdir_index(const void **a, const void **b)
{
  const node_t *node1= *a;
  const node_t *node2 = *b;
  return tor_memcmp(node1->hsdir_index->current,
                    node2->hsdir_index->current,
                    DIGEST256_LEN);
}

/* Helper function: Compare two node_t objects next hsdir_index. */
static int
compare_node_next_hsdir_index(const void **a, const void **b)
{
  const node_t *node1= *a;
  const node_t *node2 = *b;
  return tor_memcmp(node1->hsdir_index->next,
                    node2->hsdir_index->next,
                    DIGEST256_LEN);
}

/* Allocate and return a string containing the path to filename in directory.
 * This function will never return NULL. The caller must free this path. */
char *
hs_path_from_filename(const char *directory, const char *filename)
{
  char *file_path = NULL;

  tor_assert(directory);
  tor_assert(filename);

  tor_asprintf(&file_path, "%s%s%s", directory, PATH_SEPARATOR, filename);
  return file_path;
}

/* Make sure that the directory for <b>service</b> is private, using the config
 * <b>username</b>.
 * If <b>create</b> is true:
 *  - if the directory exists, change permissions if needed,
 *  - if the directory does not exist, create it with the correct permissions.
 * If <b>create</b> is false:
 *  - if the directory exists, check permissions,
 *  - if the directory does not exist, check if we think we can create it.
 * Return 0 on success, -1 on failure. */
int
hs_check_service_private_dir(const char *username, const char *path,
                             unsigned int dir_group_readable,
                             unsigned int create)
{
  cpd_check_t check_opts = CPD_NONE;

  tor_assert(path);

  if (create) {
    check_opts |= CPD_CREATE;
  } else {
    check_opts |= CPD_CHECK_MODE_ONLY;
    check_opts |= CPD_CHECK;
  }
  if (dir_group_readable) {
    check_opts |= CPD_GROUP_READ;
  }
  /* Check/create directory */
  if (check_private_dir(path, check_opts, username) < 0) {
    return -1;
  }
  return 0;
}

/** Get the default HS time period length in minutes from the consensus. */
STATIC uint64_t
get_time_period_length(void)
{
  /* If we are on a test network, make the time period smaller than normal so
     that we actually see it rotate. Specifically, make it the same length as
     an SRV protocol run. */
  if (get_options()->TestingTorNetwork) {
    unsigned run_duration = sr_state_get_protocol_run_duration();
    /* An SRV run should take more than a minute (it's 24 rounds) */
    tor_assert_nonfatal(run_duration > 60);
    /* Turn it from seconds to minutes before returning: */
    return sr_state_get_protocol_run_duration() / 60;
  }

  int32_t time_period_length = networkstatus_get_param(NULL, "hsdir-interval",
                                             HS_TIME_PERIOD_LENGTH_DEFAULT,
                                             HS_TIME_PERIOD_LENGTH_MIN,
                                             HS_TIME_PERIOD_LENGTH_MAX);
  /* Make sure it's a positive value. */
  tor_assert(time_period_length >= 0);
  /* uint64_t will always be able to contain a int32_t */
  return (uint64_t) time_period_length;
}

/** Get the HS time period number at time <b>now</b> */
uint64_t
hs_get_time_period_num(time_t now)
{
  uint64_t time_period_num;

  /* Start by calculating minutes since the epoch */
  uint64_t time_period_length = get_time_period_length();
  uint64_t minutes_since_epoch = now / 60;

  /* Apply the rotation offset as specified by prop224 (section
   * [TIME-PERIODS]), so that new time periods synchronize nicely with SRV
   * publication */
  unsigned int time_period_rotation_offset = sr_state_get_phase_duration();
  time_period_rotation_offset /= 60; /* go from seconds to minutes */
  tor_assert(minutes_since_epoch > time_period_rotation_offset);
  minutes_since_epoch -= time_period_rotation_offset;

  /* Calculate the time period */
  time_period_num = minutes_since_epoch / time_period_length;
  return time_period_num;
}

/** Get the number of the _upcoming_ HS time period, given that the current
 *  time is <b>now</b>. */
uint64_t
hs_get_next_time_period_num(time_t now)
{
  return hs_get_time_period_num(now) + 1;
}

/* Return the start time of the upcoming time period based on <b>now</b>. */
time_t
hs_get_start_time_of_next_time_period(time_t now)
{
  uint64_t time_period_length = get_time_period_length();

  /* Get start time of next time period */
  uint64_t next_time_period_num = hs_get_next_time_period_num(now);
  uint64_t start_of_next_tp_in_mins = next_time_period_num *time_period_length;

  /* Apply rotation offset as specified by prop224 section [TIME-PERIODS] */
  unsigned int time_period_rotation_offset = sr_state_get_phase_duration();
  return (time_t)(start_of_next_tp_in_mins * 60 + time_period_rotation_offset);
}

/* Create a new rend_data_t for a specific given <b>version</b>.
 * Return a pointer to the newly allocated data structure. */
static rend_data_t *
rend_data_alloc(uint32_t version)
{
  rend_data_t *rend_data = NULL;

  switch (version) {
  case HS_VERSION_TWO:
  {
    rend_data_v2_t *v2 = tor_malloc_zero(sizeof(*v2));
    v2->base_.version = HS_VERSION_TWO;
    v2->base_.hsdirs_fp = smartlist_new();
    rend_data = &v2->base_;
    break;
  }
  default:
    tor_assert(0);
    break;
  }

  return rend_data;
}

/** Free all storage associated with <b>data</b> */
void
rend_data_free(rend_data_t *data)
{
  if (!data) {
    return;
  }
  /* By using our allocation function, this should always be set. */
  tor_assert(data->hsdirs_fp);
  /* Cleanup the HSDir identity digest. */
  SMARTLIST_FOREACH(data->hsdirs_fp, char *, d, tor_free(d));
  smartlist_free(data->hsdirs_fp);
  /* Depending on the version, cleanup. */
  switch (data->version) {
  case HS_VERSION_TWO:
  {
    rend_data_v2_t *v2_data = TO_REND_DATA_V2(data);
    tor_free(v2_data);
    break;
  }
  default:
    tor_assert(0);
  }
}

/* Allocate and return a deep copy of <b>data</b>. */
rend_data_t *
rend_data_dup(const rend_data_t *data)
{
  rend_data_t *data_dup = NULL;
  smartlist_t *hsdirs_fp = smartlist_new();

  tor_assert(data);
  tor_assert(data->hsdirs_fp);

  SMARTLIST_FOREACH(data->hsdirs_fp, char *, fp,
                    smartlist_add(hsdirs_fp, tor_memdup(fp, DIGEST_LEN)));

  switch (data->version) {
  case HS_VERSION_TWO:
  {
    rend_data_v2_t *v2_data = tor_memdup(TO_REND_DATA_V2(data),
                                         sizeof(*v2_data));
    data_dup = &v2_data->base_;
    data_dup->hsdirs_fp = hsdirs_fp;
    break;
  }
  default:
    tor_assert(0);
    break;
  }

  return data_dup;
}

/* Compute the descriptor ID for each HS descriptor replica and save them. A
 * valid onion address must be present in the <b>rend_data</b>.
 *
 * Return 0 on success else -1. */
static int
compute_desc_id(rend_data_t *rend_data)
{
  int ret = 0;
  unsigned replica;
  time_t now = time(NULL);

  tor_assert(rend_data);

  switch (rend_data->version) {
  case HS_VERSION_TWO:
  {
    rend_data_v2_t *v2_data = TO_REND_DATA_V2(rend_data);
    /* Compute descriptor ID for each replicas. */
    for (replica = 0; replica < ARRAY_LENGTH(v2_data->descriptor_id);
         replica++) {
      ret = rend_compute_v2_desc_id(v2_data->descriptor_id[replica],
                                    v2_data->onion_address,
                                    v2_data->descriptor_cookie,
                                    now, replica);
      if (ret < 0) {
        goto end;
      }
    }
    break;
  }
  default:
    tor_assert(0);
  }

 end:
  return ret;
}

/* Allocate and initialize a rend_data_t object for a service using the
 * provided arguments. All arguments are optional (can be NULL), except from
 * <b>onion_address</b> which MUST be set. The <b>pk_digest</b> is the hash of
 * the service private key. The <b>cookie</b> is the rendezvous cookie and
 * <b>auth_type</b> is which authentiation this service is configured with.
 *
 * Return a valid rend_data_t pointer. This only returns a version 2 object of
 * rend_data_t. */
rend_data_t *
rend_data_service_create(const char *onion_address, const char *pk_digest,
                         const uint8_t *cookie, rend_auth_type_t auth_type)
{
  /* Create a rend_data_t object for version 2. */
  rend_data_t *rend_data = rend_data_alloc(HS_VERSION_TWO);
  rend_data_v2_t *v2= TO_REND_DATA_V2(rend_data);

  /* We need at least one else the call is wrong. */
  tor_assert(onion_address != NULL);

  if (pk_digest) {
    memcpy(v2->rend_pk_digest, pk_digest, sizeof(v2->rend_pk_digest));
  }
  if (cookie) {
    memcpy(rend_data->rend_cookie, cookie, sizeof(rend_data->rend_cookie));
  }

  strlcpy(v2->onion_address, onion_address, sizeof(v2->onion_address));
  v2->auth_type = auth_type;

  return rend_data;
}

/* Allocate and initialize a rend_data_t object for a client request using the
 * given arguments. Either an onion address or a descriptor ID is needed. Both
 * can be given but in this case only the onion address will be used to make
 * the descriptor fetch. The <b>cookie</b> is the rendezvous cookie and
 * <b>auth_type</b> is which authentiation the service is configured with.
 *
 * Return a valid rend_data_t pointer or NULL on error meaning the
 * descriptor IDs couldn't be computed from the given data. */
rend_data_t *
rend_data_client_create(const char *onion_address, const char *desc_id,
                        const char *cookie, rend_auth_type_t auth_type)
{
  /* Create a rend_data_t object for version 2. */
  rend_data_t *rend_data = rend_data_alloc(HS_VERSION_TWO);
  rend_data_v2_t *v2= TO_REND_DATA_V2(rend_data);

  /* We need at least one else the call is wrong. */
  tor_assert(onion_address != NULL || desc_id != NULL);

  if (cookie) {
    memcpy(v2->descriptor_cookie, cookie, sizeof(v2->descriptor_cookie));
  }
  if (desc_id) {
    memcpy(v2->desc_id_fetch, desc_id, sizeof(v2->desc_id_fetch));
  }
  if (onion_address) {
    strlcpy(v2->onion_address, onion_address, sizeof(v2->onion_address));
    if (compute_desc_id(rend_data) < 0) {
      goto error;
    }
  }

  v2->auth_type = auth_type;

  return rend_data;

 error:
  rend_data_free(rend_data);
  return NULL;
}

/* Return the onion address from the rend data. Depending on the version,
 * the size of the address can vary but it's always NUL terminated. */
const char *
rend_data_get_address(const rend_data_t *rend_data)
{
  tor_assert(rend_data);

  switch (rend_data->version) {
  case HS_VERSION_TWO:
    return TO_REND_DATA_V2(rend_data)->onion_address;
  default:
    /* We should always have a supported version. */
    tor_assert(0);
  }
}

/* Return the descriptor ID for a specific replica number from the rend
 * data. The returned data is a binary digest and depending on the version its
 * size can vary. The size of the descriptor ID is put in <b>len_out</b> if
 * non NULL. */
const char *
rend_data_get_desc_id(const rend_data_t *rend_data, uint8_t replica,
                      size_t *len_out)
{
  tor_assert(rend_data);

  switch (rend_data->version) {
  case HS_VERSION_TWO:
    tor_assert(replica < REND_NUMBER_OF_NON_CONSECUTIVE_REPLICAS);
    if (len_out) {
      *len_out = DIGEST_LEN;
    }
    return TO_REND_DATA_V2(rend_data)->descriptor_id[replica];
  default:
    /* We should always have a supported version. */
    tor_assert(0);
  }
}

/* Return the public key digest using the given <b>rend_data</b>. The size of
 * the digest is put in <b>len_out</b> (if set) which can differ depending on
 * the version. */
const uint8_t *
rend_data_get_pk_digest(const rend_data_t *rend_data, size_t *len_out)
{
  tor_assert(rend_data);

  switch (rend_data->version) {
  case HS_VERSION_TWO:
  {
    const rend_data_v2_t *v2_data = TO_REND_DATA_V2(rend_data);
    if (len_out) {
      *len_out = sizeof(v2_data->rend_pk_digest);
    }
    return (const uint8_t *) v2_data->rend_pk_digest;
  }
  default:
    /* We should always have a supported version. */
    tor_assert(0);
  }
}

/* Using the given time period number, compute the disaster shared random
 * value and put it in srv_out. It MUST be at least DIGEST256_LEN bytes. */
static void
compute_disaster_srv(uint64_t time_period_num, uint8_t *srv_out)
{
  crypto_digest_t *digest;

  tor_assert(srv_out);

  digest = crypto_digest256_new(DIGEST_SHA3_256);

  /* Start setting up payload:
   *  H("shared-random-disaster" | INT_8(period_length) | INT_8(period_num)) */
  crypto_digest_add_bytes(digest, HS_SRV_DISASTER_PREFIX,
                          HS_SRV_DISASTER_PREFIX_LEN);

  /* Setup INT_8(period_length) | INT_8(period_num) */
  {
    uint64_t time_period_length = get_time_period_length();
    char period_stuff[sizeof(uint64_t)*2];
    size_t offset = 0;
    set_uint64(period_stuff, tor_htonll(time_period_length));
    offset += sizeof(uint64_t);
    set_uint64(period_stuff+offset, tor_htonll(time_period_num));
    offset += sizeof(uint64_t);
    tor_assert(offset == sizeof(period_stuff));

    crypto_digest_add_bytes(digest, period_stuff,  sizeof(period_stuff));
  }

  crypto_digest_get_digest(digest, (char *) srv_out, DIGEST256_LEN);
  crypto_digest_free(digest);
}

/** Due to the high cost of computing the disaster SRV and that potentially we
 *  would have to do it thousands of times in a row, we always cache the
 *  computer disaster SRV (and its corresponding time period num) in case we
 *  want to reuse it soon after. We need to cache two SRVs, one for each active
 *  time period (in case of overlap mode).
 */
static uint8_t cached_disaster_srv[2][DIGEST256_LEN];
static uint64_t cached_time_period_nums[2] = {0};

/** Compute the disaster SRV value for this <b>time_period_num</b> and put it
 *  in <b>srv_out</b> (of size at least DIGEST256_LEN). First check our caches
 *  to see if we have already computed it. */
STATIC void
get_disaster_srv(uint64_t time_period_num, uint8_t *srv_out)
{
  if (time_period_num == cached_time_period_nums[0]) {
    memcpy(srv_out, cached_disaster_srv[0], DIGEST256_LEN);
    return;
  } else if (time_period_num == cached_time_period_nums[1]) {
    memcpy(srv_out, cached_disaster_srv[1], DIGEST256_LEN);
    return;
  } else {
    int replace_idx;
    // Replace the lower period number.
    if (cached_time_period_nums[0] <= cached_time_period_nums[1]) {
      replace_idx = 0;
    } else {
      replace_idx = 1;
    }
    cached_time_period_nums[replace_idx] = time_period_num;
    compute_disaster_srv(time_period_num, cached_disaster_srv[replace_idx]);
    memcpy(srv_out, cached_disaster_srv[replace_idx], DIGEST256_LEN);
    return;
  }
}

#ifdef TOR_UNIT_TESTS

/** Get the first cached disaster SRV. Only used by unittests. */
STATIC uint8_t *
get_first_cached_disaster_srv(void)
{
  return cached_disaster_srv[0];
}

/** Get the second cached disaster SRV. Only used by unittests. */
STATIC uint8_t *
get_second_cached_disaster_srv(void)
{
  return cached_disaster_srv[1];
}

#endif

/* When creating a blinded key, we need a parameter which construction is as
 * follow: H(pubkey | [secret] | ed25519-basepoint | nonce).
 *
 * The nonce has a pre-defined format which uses the time period number
 * period_num and the start of the period in second start_time_period.
 *
 * The secret of size secret_len is optional meaning that it can be NULL and
 * thus will be ignored for the param construction.
 *
 * The result is put in param_out. */
static void
build_blinded_key_param(const ed25519_public_key_t *pubkey,
                        const uint8_t *secret, size_t secret_len,
                        uint64_t period_num, uint64_t period_length,
                        uint8_t *param_out)
{
  size_t offset = 0;
  const char blind_str[] = "Derive temporary signing key";
  uint8_t nonce[HS_KEYBLIND_NONCE_LEN];
  crypto_digest_t *digest;

  tor_assert(pubkey);
  tor_assert(param_out);

  /* Create the nonce N. The construction is as follow:
   *    N = "key-blind" || INT_8(period_num) || INT_8(period_length) */
  memcpy(nonce, HS_KEYBLIND_NONCE_PREFIX, HS_KEYBLIND_NONCE_PREFIX_LEN);
  offset += HS_KEYBLIND_NONCE_PREFIX_LEN;
  set_uint64(nonce + offset, tor_htonll(period_num));
  offset += sizeof(uint64_t);
  set_uint64(nonce + offset, tor_htonll(period_length));
  offset += sizeof(uint64_t);
  tor_assert(offset == HS_KEYBLIND_NONCE_LEN);

  /* Generate the parameter h and the construction is as follow:
   *    h = H(BLIND_STRING | pubkey | [secret] | ed25519-basepoint | N) */
  digest = crypto_digest256_new(DIGEST_SHA3_256);
  crypto_digest_add_bytes(digest, blind_str, sizeof(blind_str));
  crypto_digest_add_bytes(digest, (char *) pubkey, ED25519_PUBKEY_LEN);
  /* Optional secret. */
  if (secret) {
    crypto_digest_add_bytes(digest, (char *) secret, secret_len);
  }
  crypto_digest_add_bytes(digest, str_ed25519_basepoint,
                          strlen(str_ed25519_basepoint));
  crypto_digest_add_bytes(digest, (char *) nonce, sizeof(nonce));

  /* Extract digest and put it in the param. */
  crypto_digest_get_digest(digest, (char *) param_out, DIGEST256_LEN);
  crypto_digest_free(digest);

  memwipe(nonce, 0, sizeof(nonce));
}

/* Using an ed25519 public key and version to build the checksum of an
 * address. Put in checksum_out. Format is:
 *    SHA3-256(".onion checksum" || PUBKEY || VERSION)
 *
 * checksum_out must be large enough to receive 32 bytes (DIGEST256_LEN). */
static void
build_hs_checksum(const ed25519_public_key_t *key, uint8_t version,
                  uint8_t *checksum_out)
{
  size_t offset = 0;
  char data[HS_SERVICE_ADDR_CHECKSUM_INPUT_LEN];

  /* Build checksum data. */
  memcpy(data, HS_SERVICE_ADDR_CHECKSUM_PREFIX,
         HS_SERVICE_ADDR_CHECKSUM_PREFIX_LEN);
  offset += HS_SERVICE_ADDR_CHECKSUM_PREFIX_LEN;
  memcpy(data + offset, key->pubkey, ED25519_PUBKEY_LEN);
  offset += ED25519_PUBKEY_LEN;
  set_uint8(data + offset, version);
  offset += sizeof(version);
  tor_assert(offset == HS_SERVICE_ADDR_CHECKSUM_INPUT_LEN);

  /* Hash the data payload to create the checksum. */
  crypto_digest256((char *) checksum_out, data, sizeof(data),
                   DIGEST_SHA3_256);
}

/* Using an ed25519 public key, checksum and version to build the binary
 * representation of a service address. Put in addr_out. Format is:
 *    addr_out = PUBKEY || CHECKSUM || VERSION
 *
 * addr_out must be large enough to receive HS_SERVICE_ADDR_LEN bytes. */
static void
build_hs_address(const ed25519_public_key_t *key, const uint8_t *checksum,
                 uint8_t version, char *addr_out)
{
  size_t offset = 0;

  tor_assert(key);
  tor_assert(checksum);

  memcpy(addr_out, key->pubkey, ED25519_PUBKEY_LEN);
  offset += ED25519_PUBKEY_LEN;
  memcpy(addr_out + offset, checksum, HS_SERVICE_ADDR_CHECKSUM_LEN_USED);
  offset += HS_SERVICE_ADDR_CHECKSUM_LEN_USED;
  set_uint8(addr_out + offset, version);
  offset += sizeof(uint8_t);
  tor_assert(offset == HS_SERVICE_ADDR_LEN);
}

/* Helper for hs_parse_address(): Using a binary representation of a service
 * address, parse its content into the key_out, checksum_out and version_out.
 * Any out variable can be NULL in case the caller would want only one field.
 * checksum_out MUST at least be 2 bytes long. address must be at least
 * HS_SERVICE_ADDR_LEN bytes but doesn't need to be NUL terminated. */
static void
hs_parse_address_impl(const char *address, ed25519_public_key_t *key_out,
                      uint8_t *checksum_out, uint8_t *version_out)
{
  size_t offset = 0;

  tor_assert(address);

  if (key_out) {
    /* First is the key. */
    memcpy(key_out->pubkey, address, ED25519_PUBKEY_LEN);
  }
  offset += ED25519_PUBKEY_LEN;
  if (checksum_out) {
    /* Followed by a 2 bytes checksum. */
    memcpy(checksum_out, address + offset, HS_SERVICE_ADDR_CHECKSUM_LEN_USED);
  }
  offset += HS_SERVICE_ADDR_CHECKSUM_LEN_USED;
  if (version_out) {
    /* Finally, version value is 1 byte. */
    *version_out = get_uint8(address + offset);
  }
  offset += sizeof(uint8_t);
  /* Extra safety. */
  tor_assert(offset == HS_SERVICE_ADDR_LEN);
}

/* Using the given identity public key and a blinded public key, compute the
 * subcredential and put it in subcred_out (must be of size DIGEST256_LEN).
 * This can't fail. */
void
hs_get_subcredential(const ed25519_public_key_t *identity_pk,
                     const ed25519_public_key_t *blinded_pk,
                     uint8_t *subcred_out)
{
  uint8_t credential[DIGEST256_LEN];
  crypto_digest_t *digest;

  tor_assert(identity_pk);
  tor_assert(blinded_pk);
  tor_assert(subcred_out);

  /* First, build the credential. Construction is as follow:
   *  credential = H("credential" | public-identity-key) */
  digest = crypto_digest256_new(DIGEST_SHA3_256);
  crypto_digest_add_bytes(digest, HS_CREDENTIAL_PREFIX,
                          HS_CREDENTIAL_PREFIX_LEN);
  crypto_digest_add_bytes(digest, (const char *) identity_pk->pubkey,
                          ED25519_PUBKEY_LEN);
  crypto_digest_get_digest(digest, (char *) credential, DIGEST256_LEN);
  crypto_digest_free(digest);

  /* Now, compute the subcredential. Construction is as follow:
   *  subcredential = H("subcredential" | credential | blinded-public-key). */
  digest = crypto_digest256_new(DIGEST_SHA3_256);
  crypto_digest_add_bytes(digest, HS_SUBCREDENTIAL_PREFIX,
                          HS_SUBCREDENTIAL_PREFIX_LEN);
  crypto_digest_add_bytes(digest, (const char *) credential,
                          sizeof(credential));
  crypto_digest_add_bytes(digest, (const char *) blinded_pk->pubkey,
                          ED25519_PUBKEY_LEN);
  crypto_digest_get_digest(digest, (char *) subcred_out, DIGEST256_LEN);
  crypto_digest_free(digest);

  memwipe(credential, 0, sizeof(credential));
}

/* From the given list of hidden service ports, find the ones that much the
 * given edge connection conn, pick one at random and use it to set the
 * connection address. Return 0 on success or -1 if none. */
int
hs_set_conn_addr_port(const smartlist_t *ports, edge_connection_t *conn)
{
  rend_service_port_config_t *chosen_port;
  unsigned int warn_once = 0;
  smartlist_t *matching_ports;

  tor_assert(ports);
  tor_assert(conn);

  matching_ports = smartlist_new();
  SMARTLIST_FOREACH_BEGIN(ports, rend_service_port_config_t *, p) {
    if (TO_CONN(conn)->port != p->virtual_port) {
      continue;
    }
    if (!(p->is_unix_addr)) {
      smartlist_add(matching_ports, p);
    } else {
      if (add_unix_port(matching_ports, p)) {
        if (!warn_once) {
          /* Unix port not supported so warn only once. */
          log_warn(LD_REND, "Saw AF_UNIX virtual port mapping for port %d "
                            "which is unsupported on this platform. "
                            "Ignoring it.",
                   TO_CONN(conn)->port);
        }
        warn_once++;
      }
    }
  } SMARTLIST_FOREACH_END(p);

  chosen_port = smartlist_choose(matching_ports);
  smartlist_free(matching_ports);
  if (chosen_port) {
    if (!(chosen_port->is_unix_addr)) {
      /* Get a non-AF_UNIX connection ready for connection_exit_connect() */
      tor_addr_copy(&TO_CONN(conn)->addr, &chosen_port->real_addr);
      TO_CONN(conn)->port = chosen_port->real_port;
    } else {
      if (set_unix_port(conn, chosen_port)) {
        /* Simply impossible to end up here else we were able to add a Unix
         * port without AF_UNIX support... ? */
        tor_assert(0);
      }
    }
  }
  return (chosen_port) ? 0 : -1;
}

/* Using a base32 representation of a service address, parse its content into
 * the key_out, checksum_out and version_out. Any out variable can be NULL in
 * case the caller would want only one field. checksum_out MUST at least be 2
 * bytes long.
 *
 * Return 0 if parsing went well; return -1 in case of error. */
int
hs_parse_address(const char *address, ed25519_public_key_t *key_out,
                 uint8_t *checksum_out, uint8_t *version_out)
{
  char decoded[HS_SERVICE_ADDR_LEN];

  tor_assert(address);

  /* Obvious length check. */
  if (strlen(address) != HS_SERVICE_ADDR_LEN_BASE32) {
    log_warn(LD_REND, "Service address %s has an invalid length. "
                      "Expected %lu but got %lu.",
             escaped_safe_str(address),
             (unsigned long) HS_SERVICE_ADDR_LEN_BASE32,
             (unsigned long) strlen(address));
    goto invalid;
  }

  /* Decode address so we can extract needed fields. */
  if (base32_decode(decoded, sizeof(decoded), address, strlen(address)) < 0) {
    log_warn(LD_REND, "Service address %s can't be decoded.",
             escaped_safe_str(address));
    goto invalid;
  }

  /* Parse the decoded address into the fields we need. */
  hs_parse_address_impl(decoded, key_out, checksum_out, version_out);

  return 0;
 invalid:
  return -1;
}

/* Validate a given onion address. The length, the base32 decoding and
 * checksum are validated. Return 1 if valid else 0. */
int
hs_address_is_valid(const char *address)
{
  uint8_t version;
  uint8_t checksum[HS_SERVICE_ADDR_CHECKSUM_LEN_USED];
  uint8_t target_checksum[DIGEST256_LEN];
  ed25519_public_key_t key;

  /* Parse the decoded address into the fields we need. */
  if (hs_parse_address(address, &key, checksum, &version) < 0) {
    goto invalid;
  }

  /* Get the checksum it's suppose to be and compare it with what we have
   * encoded in the address. */
  build_hs_checksum(&key, version, target_checksum);
  if (tor_memcmp(checksum, target_checksum, sizeof(checksum))) {
    log_warn(LD_REND, "Service address %s invalid checksum.",
             escaped_safe_str(address));
    goto invalid;
  }

  /* Valid address. */
  return 1;
 invalid:
  return 0;
}

/* Build a service address using an ed25519 public key and a given version.
 * The returned address is base32 encoded and put in addr_out. The caller MUST
 * make sure the addr_out is at least HS_SERVICE_ADDR_LEN_BASE32 + 1 long.
 *
 * Format is as follow:
 *     base32(PUBKEY || CHECKSUM || VERSION)
 *     CHECKSUM = H(".onion checksum" || PUBKEY || VERSION)
 * */
void
hs_build_address(const ed25519_public_key_t *key, uint8_t version,
                 char *addr_out)
{
  uint8_t checksum[DIGEST256_LEN];
  char address[HS_SERVICE_ADDR_LEN];

  tor_assert(key);
  tor_assert(addr_out);

  /* Get the checksum of the address. */
  build_hs_checksum(key, version, checksum);
  /* Get the binary address representation. */
  build_hs_address(key, checksum, version, address);

  /* Encode the address. addr_out will be NUL terminated after this. */
  base32_encode(addr_out, HS_SERVICE_ADDR_LEN_BASE32 + 1, address,
                sizeof(address));
  /* Validate what we just built. */
  tor_assert(hs_address_is_valid(addr_out));
}

/* Return a newly allocated copy of lspec. */
link_specifier_t *
hs_link_specifier_dup(const link_specifier_t *lspec)
{
  link_specifier_t *dup = link_specifier_new();
  memcpy(dup, lspec, sizeof(*dup));
  /* The unrecognized field is a dynamic array so make sure to copy its
   * content and not the pointer. */
  link_specifier_setlen_un_unrecognized(
                        dup, link_specifier_getlen_un_unrecognized(lspec));
  if (link_specifier_getlen_un_unrecognized(dup)) {
    memcpy(link_specifier_getarray_un_unrecognized(dup),
           link_specifier_getconstarray_un_unrecognized(lspec),
           link_specifier_getlen_un_unrecognized(dup));
  }
  return dup;
}

/* From a given ed25519 public key pk and an optional secret, compute a
 * blinded public key and put it in blinded_pk_out. This is only useful to
 * the client side because the client only has access to the identity public
 * key of the service. */
void
hs_build_blinded_pubkey(const ed25519_public_key_t *pk,
                        const uint8_t *secret, size_t secret_len,
                        uint64_t time_period_num,
                        ed25519_public_key_t *blinded_pk_out)
{
  /* Our blinding key API requires a 32 bytes parameter. */
  uint8_t param[DIGEST256_LEN];

  tor_assert(pk);
  tor_assert(blinded_pk_out);
  tor_assert(!tor_mem_is_zero((char *) pk, ED25519_PUBKEY_LEN));

  build_blinded_key_param(pk, secret, secret_len,
                          time_period_num, get_time_period_length(), param);
  ed25519_public_blind(blinded_pk_out, pk, param);

  memwipe(param, 0, sizeof(param));
}

/* From a given ed25519 keypair kp and an optional secret, compute a blinded
 * keypair for the current time period and put it in blinded_kp_out. This is
 * only useful by the service side because the client doesn't have access to
 * the identity secret key. */
void
hs_build_blinded_keypair(const ed25519_keypair_t *kp,
                         const uint8_t *secret, size_t secret_len,
                         uint64_t time_period_num,
                         ed25519_keypair_t *blinded_kp_out)
{
  /* Our blinding key API requires a 32 bytes parameter. */
  uint8_t param[DIGEST256_LEN];

  tor_assert(kp);
  tor_assert(blinded_kp_out);
  /* Extra safety. A zeroed key is bad. */
  tor_assert(!tor_mem_is_zero((char *) &kp->pubkey, ED25519_PUBKEY_LEN));
  tor_assert(!tor_mem_is_zero((char *) &kp->seckey, ED25519_SECKEY_LEN));

  build_blinded_key_param(&kp->pubkey, secret, secret_len,
                          time_period_num, get_time_period_length(), param);
  ed25519_keypair_blind(blinded_kp_out, kp, param);

  memwipe(param, 0, sizeof(param));
}

/* Return true if overlap mode is active given the date in consensus. If
 * consensus is NULL, then we use the latest live consensus we can find. */
MOCK_IMPL(int,
hs_overlap_mode_is_active, (const networkstatus_t *consensus, time_t now))
{
  time_t valid_after;
  time_t srv_start_time, tp_start_time;

  if (!consensus) {
    consensus = networkstatus_get_live_consensus(now);
    if (!consensus) {
      return 0;
    }
  }

  /* We consider to be in overlap mode when we are in the period of time
   * between a fresh SRV and the beginning of the new time period (in the
   * normal network this is between 00:00 (inclusive) and 12:00 UTC
   * (exclusive)) */
  valid_after = consensus->valid_after;
  srv_start_time =sr_state_get_start_time_of_current_protocol_run(valid_after);
  tp_start_time = hs_get_start_time_of_next_time_period(srv_start_time);

  if (valid_after >= srv_start_time && valid_after < tp_start_time) {
    return 1;
  }

  return 0;
}

/* Return 1 if any virtual port in ports needs a circuit with good uptime.
 * Else return 0. */
int
hs_service_requires_uptime_circ(const smartlist_t *ports)
{
  tor_assert(ports);

  SMARTLIST_FOREACH_BEGIN(ports, rend_service_port_config_t *, p) {
    if (smartlist_contains_int_as_string(get_options()->LongLivedPorts,
                                         p->virtual_port)) {
      return 1;
    }
  } SMARTLIST_FOREACH_END(p);
  return 0;
}

/* Build hs_index which is used to find the responsible hsdirs. This index
 * value is used to select the responsible HSDir where their hsdir_index is
 * closest to this value.
 *    SHA3-256("store-at-idx" | blinded_public_key |
 *             INT_8(replicanum) | INT_8(period_length) | INT_8(period_num) )
 *
 * hs_index_out must be large enough to receive DIGEST256_LEN bytes. */
void
hs_build_hs_index(uint64_t replica, const ed25519_public_key_t *blinded_pk,
                  uint64_t period_num, uint8_t *hs_index_out)
{
  crypto_digest_t *digest;

  tor_assert(blinded_pk);
  tor_assert(hs_index_out);

  /* Build hs_index. See construction at top of function comment. */
  digest = crypto_digest256_new(DIGEST_SHA3_256);
  crypto_digest_add_bytes(digest, HS_INDEX_PREFIX, HS_INDEX_PREFIX_LEN);
  crypto_digest_add_bytes(digest, (const char *) blinded_pk->pubkey,
                          ED25519_PUBKEY_LEN);

  /* Now setup INT_8(replicanum) | INT_8(period_length) | INT_8(period_num) */
  {
    uint64_t period_length = get_time_period_length();
    char buf[sizeof(uint64_t)*3];
    size_t offset = 0;
    set_uint64(buf, tor_htonll(replica));
    offset += sizeof(uint64_t);
    set_uint64(buf+offset, tor_htonll(period_length));
    offset += sizeof(uint64_t);
    set_uint64(buf+offset, tor_htonll(period_num));
    offset += sizeof(uint64_t);
    tor_assert(offset == sizeof(buf));

    crypto_digest_add_bytes(digest, buf, sizeof(buf));
  }

  crypto_digest_get_digest(digest, (char *) hs_index_out, DIGEST256_LEN);
  crypto_digest_free(digest);
}

/* Build hsdir_index which is used to find the responsible hsdirs. This is the
 * index value that is compare to the hs_index when selecting an HSDir.
 *    SHA3-256("node-idx" | node_identity |
 *             shared_random_value | INT_8(period_length) | INT_8(period_num) )
 *
 * hsdir_index_out must be large enough to receive DIGEST256_LEN bytes. */
void
hs_build_hsdir_index(const ed25519_public_key_t *identity_pk,
                     const uint8_t *srv_value, uint64_t period_num,
                     uint8_t *hsdir_index_out)
{
  crypto_digest_t *digest;

  tor_assert(identity_pk);
  tor_assert(srv_value);
  tor_assert(hsdir_index_out);

  /* Build hsdir_index. See construction at top of function comment. */
  digest = crypto_digest256_new(DIGEST_SHA3_256);
  crypto_digest_add_bytes(digest, HSDIR_INDEX_PREFIX, HSDIR_INDEX_PREFIX_LEN);
  crypto_digest_add_bytes(digest, (const char *) identity_pk->pubkey,
                          ED25519_PUBKEY_LEN);
  crypto_digest_add_bytes(digest, (const char *) srv_value, DIGEST256_LEN);

  {
    uint64_t time_period_length = get_time_period_length();
    char period_stuff[sizeof(uint64_t)*2];
    size_t offset = 0;
    set_uint64(period_stuff, tor_htonll(period_num));
    offset += sizeof(uint64_t);
    set_uint64(period_stuff+offset, tor_htonll(time_period_length));
    offset += sizeof(uint64_t);
    tor_assert(offset == sizeof(period_stuff));

    crypto_digest_add_bytes(digest, period_stuff,  sizeof(period_stuff));
  }

  crypto_digest_get_digest(digest, (char *) hsdir_index_out, DIGEST256_LEN);
  crypto_digest_free(digest);
}

/* Return a newly allocated buffer containing the current shared random value
 * or if not present, a disaster value is computed using the given time period
 * number. If a consensus is provided in <b>ns</b>, use it to get the SRV
 * value. This function can't fail. */
uint8_t *
hs_get_current_srv(uint64_t time_period_num, const networkstatus_t *ns)
{
  uint8_t *sr_value = tor_malloc_zero(DIGEST256_LEN);
  const sr_srv_t *current_srv = sr_get_current(ns);

  if (current_srv) {
    memcpy(sr_value, current_srv->value, sizeof(current_srv->value));
  } else {
    /* Disaster mode. */
    get_disaster_srv(time_period_num, sr_value);
  }
  return sr_value;
}

/* Return a newly allocated buffer containing the previous shared random
 * value or if not present, a disaster value is computed using the given time
 * period number. This function can't fail. */
uint8_t *
hs_get_previous_srv(uint64_t time_period_num, const networkstatus_t *ns)
{
  uint8_t *sr_value = tor_malloc_zero(DIGEST256_LEN);
  const sr_srv_t *previous_srv = sr_get_previous(ns);

  if (previous_srv) {
    memcpy(sr_value, previous_srv->value, sizeof(previous_srv->value));
  } else {
    /* Disaster mode. */
    get_disaster_srv(time_period_num, sr_value);
  }
  return sr_value;
}

/* Return the number of replicas defined by a consensus parameter or the
 * default value. */
int32_t
hs_get_hsdir_n_replicas(void)
{
  /* The [1,16] range is a specification requirement. */
  return networkstatus_get_param(NULL, "hsdir_n_replicas",
                                 HS_DEFAULT_HSDIR_N_REPLICAS, 1, 16);
}

/* Return the spread fetch value defined by a consensus parameter or the
 * default value. */
int32_t
hs_get_hsdir_spread_fetch(void)
{
  /* The [1,128] range is a specification requirement. */
  return networkstatus_get_param(NULL, "hsdir_spread_fetch",
                                 HS_DEFAULT_HSDIR_SPREAD_FETCH, 1, 128);
}

/* Return the spread store value defined by a consensus parameter or the
 * default value. */
int32_t
hs_get_hsdir_spread_store(void)
{
  /* The [1,128] range is a specification requirement. */
  return networkstatus_get_param(NULL, "hsdir_spread_store",
                                 HS_DEFAULT_HSDIR_SPREAD_STORE, 1, 128);
}

/** <b>node</b> is an HSDir so make sure that we have assigned an hsdir index.
 *  Return 0 if everything is as expected, else return -1. */
static int
node_has_hsdir_index(const node_t *node)
{
  tor_assert(node_supports_v3_hsdir(node));

  /* A node can't have an HSDir index without a descriptor since we need desc
   * to get its ed25519 key */
  if (!node_has_descriptor(node)) {
    return 0;
  }

  /* At this point, since the node has a desc, this node must also have an
   * hsdir index. If not, something went wrong, so BUG out. */
  if (BUG(node->hsdir_index == NULL) ||
      BUG(tor_mem_is_zero((const char*)node->hsdir_index->current,
                          DIGEST256_LEN))) {
    return 0;
  }

  return 1;
}

/* For a given blinded key and time period number, get the responsible HSDir
 * and put their routerstatus_t object in the responsible_dirs list. If
 * is_next_period is true, the next hsdir_index of the node_t is used. If
 * is_client is true, the spread fetch consensus parameter is used else the
 * spread store is used which is only for upload. This function can't fail but
 * it is possible that the responsible_dirs list contains fewer nodes than
 * expected.
 *
 * This function goes over the latest consensus routerstatus list and sorts it
 * by their node_t hsdir_index then does a binary search to find the closest
 * node. All of this makes it a bit CPU intensive so use it wisely. */
void
hs_get_responsible_hsdirs(const ed25519_public_key_t *blinded_pk,
                          uint64_t time_period_num, int is_next_period,
                          int is_client, smartlist_t *responsible_dirs)
{
  smartlist_t *sorted_nodes;
  /* The compare function used for the smartlist bsearch. We have two
   * different depending on is_next_period. */
  int (*cmp_fct)(const void *, const void **);

  tor_assert(blinded_pk);
  tor_assert(responsible_dirs);

  sorted_nodes = smartlist_new();

  /* Add every node_t that support HSDir v3 for which we do have a valid
   * hsdir_index already computed for them for this consensus. */
  {
    networkstatus_t *c = networkstatus_get_latest_consensus();
    if (!c || smartlist_len(c->routerstatus_list) == 0) {
      log_warn(LD_REND, "No valid consensus so we can't get the responsible "
                        "hidden service directories.");
      goto done;
    }
    SMARTLIST_FOREACH_BEGIN(c->routerstatus_list, const routerstatus_t *, rs) {
      /* Even though this node_t object won't be modified and should be const,
       * we can't add const object in a smartlist_t. */
      node_t *n = node_get_mutable_by_id(rs->identity_digest);
      tor_assert(n);
      if (node_supports_v3_hsdir(n) && rs->is_hs_dir) {
        if (!node_has_hsdir_index(n)) {
          log_info(LD_GENERAL, "Node %s was found without hsdir index.",
                   node_describe(n));
          continue;
        }
        smartlist_add(sorted_nodes, n);
      }
    } SMARTLIST_FOREACH_END(rs);
  }
  if (smartlist_len(sorted_nodes) == 0) {
    log_warn(LD_REND, "No nodes found to be HSDir or supporting v3.");
    goto done;
  }

  /* First thing we have to do is sort all node_t by hsdir_index. The
   * is_next_period tells us if we want the current or the next one. Set the
   * bsearch compare function also while we are at it. */
  if (is_next_period) {
    smartlist_sort(sorted_nodes, compare_node_next_hsdir_index);
    cmp_fct = compare_digest_to_next_hsdir_index;
  } else {
    smartlist_sort(sorted_nodes, compare_node_current_hsdir_index);
    cmp_fct = compare_digest_to_current_hsdir_index;
  }

  /* For all replicas, we'll select a set of HSDirs using the consensus
   * parameters and the sorted list. The replica starting at value 1 is
   * defined by the specification. */
  for (int replica = 1; replica <= hs_get_hsdir_n_replicas(); replica++) {
    int idx, start, found, n_added = 0;
    uint8_t hs_index[DIGEST256_LEN] = {0};
    /* Number of node to add to the responsible dirs list depends on if we are
     * trying to fetch or store. A client always fetches. */
    int n_to_add = (is_client) ? hs_get_hsdir_spread_fetch() :
                                 hs_get_hsdir_spread_store();

    /* Get the index that we should use to select the node. */
    hs_build_hs_index(replica, blinded_pk, time_period_num, hs_index);
    /* The compare function pointer has been set correctly earlier. */
    start = idx = smartlist_bsearch_idx(sorted_nodes, hs_index, cmp_fct,
                                        &found);
    /* Getting the length of the list if no member is greater than the key we
     * are looking for so start at the first element. */
    if (idx == smartlist_len(sorted_nodes)) {
      start = idx = 0;
    }
    while (n_added < n_to_add) {
      const node_t *node = smartlist_get(sorted_nodes, idx);
      /* If the node has already been selected which is possible between
       * replicas, the specification says to skip over. */
      if (!smartlist_contains(responsible_dirs, node->rs)) {
        smartlist_add(responsible_dirs, node->rs);
        ++n_added;
      }
      if (++idx == smartlist_len(sorted_nodes)) {
        /* Wrap if we've reached the end of the list. */
        idx = 0;
      }
      if (idx == start) {
        /* We've gone over the whole list, stop and avoid infinite loop. */
        break;
      }
    }
  }

 done:
  smartlist_free(sorted_nodes);
}

/* Initialize the entire HS subsytem. This is called in tor_init() before any
 * torrc options are loaded. Only for >= v3. */
void
hs_init(void)
{
  hs_circuitmap_init();
  hs_service_init();
  hs_cache_init();
}

/* Release and cleanup all memory of the HS subsystem (all version). This is
 * called by tor_free_all(). */
void
hs_free_all(void)
{
  hs_circuitmap_free_all();
  hs_service_free_all();
  hs_cache_free_all();
}

/* For the given origin circuit circ, decrement the number of rendezvous
 * stream counter. This handles every hidden service version. */
void
hs_dec_rdv_stream_counter(origin_circuit_t *circ)
{
  tor_assert(circ);

  if (circ->rend_data) {
    circ->rend_data->nr_streams--;
  } else if (circ->hs_ident) {
    circ->hs_ident->num_rdv_streams--;
  } else {
    /* Should not be called if this circuit is not for hidden service. */
    tor_assert_nonfatal_unreached();
  }
}

/* For the given origin circuit circ, increment the number of rendezvous
 * stream counter. This handles every hidden service version. */
void
hs_inc_rdv_stream_counter(origin_circuit_t *circ)
{
  tor_assert(circ);

  if (circ->rend_data) {
    circ->rend_data->nr_streams++;
  } else if (circ->hs_ident) {
    circ->hs_ident->num_rdv_streams++;
  } else {
    /* Should not be called if this circuit is not for hidden service. */
    tor_assert_nonfatal_unreached();
  }
}