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/*
* Copyright (C) 2016 American Civil Liberties Union (ACLU)
* 2016-2018 CZ.NIC, z.s.p.o
*
* Initial Author: Daniel Kahn Gillmor <dkg@fifthhorseman.net>
* Ondřej Surý <ondrej@sury.org>
*
* SPDX-License-Identifier: GPL-3.0-or-later
*/
#include <gnutls/abstract.h>
#include <gnutls/crypto.h>
#include <gnutls/gnutls.h>
#include <gnutls/x509.h>
#include <uv.h>
#include <assert.h>
#include <errno.h>
#include <stdlib.h>
#include "contrib/ucw/lib.h"
#include "contrib/base64.h"
#include "daemon/io.h"
#include "daemon/tls.h"
#include "daemon/worker.h"
#include "daemon/session.h"
#define EPHEMERAL_CERT_EXPIRATION_SECONDS_RENEW_BEFORE (60*60*24*7)
#define GNUTLS_PIN_MIN_VERSION 0x030400
/** @internal Debugging facility. */
#ifdef DEBUG
#define DEBUG_MSG(...) kr_log_verbose("[tls] " __VA_ARGS__)
#else
#define DEBUG_MSG(...)
#endif
struct async_write_ctx {
uv_write_t write_req;
struct tls_common_ctx *t;
char buf[];
};
static char const server_logstring[] = "tls";
static char const client_logstring[] = "tls_client";
static int client_verify_certificate(gnutls_session_t tls_session);
/**
* Set mandatory security settings from
* https://tools.ietf.org/html/draft-ietf-dprive-dtls-and-tls-profiles-11#section-9
* Performance optimizations are not implemented at the moment.
*/
static int kres_gnutls_set_priority(gnutls_session_t session) {
static const char * const priorities =
"NORMAL:" /* GnuTLS defaults */
"-VERS-TLS1.0:-VERS-TLS1.1:" /* TLS 1.2 and higher */
/* Some distros by default allow features that are considered
* too insecure nowadays, so let's disable them explicitly. */
"-VERS-SSL3.0:-ARCFOUR-128:-COMP-ALL:+COMP-NULL";
const char *errpos = NULL;
int err = gnutls_priority_set_direct(session, priorities, &errpos);
if (err != GNUTLS_E_SUCCESS) {
kr_log_error("[tls] setting priority '%s' failed at character %zd (...'%s') with %s (%d)\n",
priorities, errpos - priorities, errpos, gnutls_strerror_name(err), err);
}
return err;
}
static ssize_t kres_gnutls_pull(gnutls_transport_ptr_t h, void *buf, size_t len)
{
struct tls_common_ctx *t = (struct tls_common_ctx *)h;
assert(t != NULL);
ssize_t avail = t->nread - t->consumed;
DEBUG_MSG("[%s] pull wanted: %zu available: %zu\n",
t->client_side ? "tls_client" : "tls", len, avail);
if (t->nread <= t->consumed) {
errno = EAGAIN;
return -1;
}
ssize_t transfer = MIN(avail, len);
memcpy(buf, t->buf + t->consumed, transfer);
t->consumed += transfer;
return transfer;
}
static void on_write_complete(uv_write_t *req, int status)
{
assert(req->data != NULL);
struct async_write_ctx *async_ctx = (struct async_write_ctx *)req->data;
struct tls_common_ctx *t = async_ctx->t;
assert(t->write_queue_size);
t->write_queue_size -= 1;
free(req->data);
}
static bool stream_queue_is_empty(struct tls_common_ctx *t)
{
return (t->write_queue_size == 0);
}
static ssize_t kres_gnutls_vec_push(gnutls_transport_ptr_t h, const giovec_t * iov, int iovcnt)
{
struct tls_common_ctx *t = (struct tls_common_ctx *)h;
if (t == NULL) {
errno = EFAULT;
return -1;
}
if (iovcnt == 0) {
return 0;
}
assert(t->session);
uv_stream_t *handle = (uv_stream_t *)session_get_handle(t->session);
assert(handle && handle->type == UV_TCP);
/*
* This is a little bit complicated. There are two different writes:
* 1. Immediate, these don't need to own the buffered data and return immediately
* 2. Asynchronous, these need to own the buffers until the write completes
* In order to avoid copying the buffer, an immediate write is tried first if possible.
* If it isn't possible to write the data without queueing, an asynchronous write
* is created (with copied buffered data).
*/
size_t total_len = 0;
uv_buf_t uv_buf[iovcnt];
for (int i = 0; i < iovcnt; ++i) {
uv_buf[i].base = iov[i].iov_base;
uv_buf[i].len = iov[i].iov_len;
total_len += iov[i].iov_len;
}
/* Try to perform the immediate write first to avoid copy */
int ret = 0;
if (stream_queue_is_empty(t)) {
ret = uv_try_write(handle, uv_buf, iovcnt);
DEBUG_MSG("[%s] push %zu <%p> = %d\n",
t->client_side ? "tls_client" : "tls", total_len, h, ret);
/* from libuv documentation -
uv_try_write will return either:
> 0: number of bytes written (can be less than the supplied buffer size).
< 0: negative error code (UV_EAGAIN is returned if no data can be sent immediately).
*/
if (ret == total_len) {
/* All the data were buffered by libuv.
* Return. */
return ret;
}
if (ret < 0 && ret != UV_EAGAIN) {
/* uv_try_write() has returned error code other then UV_EAGAIN.
* Return. */
kr_log_verbose("[%s] uv_try_write error: %s\n",
t->client_side ? "tls_client" : "tls", uv_strerror(ret));
ret = -1;
errno = EIO;
return ret;
}
/* Since we are here expression below is true
* (ret != total_len) && (ret >= 0 || ret == UV_EAGAIN)
* or the same
* (ret != total_len && ret >= 0) || (ret != total_len && ret == UV_EAGAIN)
* i.e. either occurs partial write or UV_EAGAIN.
* Proceed and copy data amount to owned memory and perform async write.
*/
if (ret == UV_EAGAIN) {
/* No data were buffered, so we must buffer all the data. */
ret = 0;
}
}
/* Fallback when the queue is full, and it's not possible to do an immediate write */
char *p = malloc(sizeof(struct async_write_ctx) + total_len - ret);
if (p != NULL) {
struct async_write_ctx *async_ctx = (struct async_write_ctx *)p;
/* Save pointer to session tls context */
async_ctx->t = t;
char *buf = async_ctx->buf;
/* Skip data written in the partial write */
size_t to_skip = ret;
/* Copy the buffer into owned memory */
size_t off = 0;
for (int i = 0; i < iovcnt; ++i) {
if (to_skip > 0) {
/* Ignore current buffer if it's all skipped */
if (to_skip >= uv_buf[i].len) {
to_skip -= uv_buf[i].len;
continue;
}
/* Skip only part of the buffer */
uv_buf[i].base += to_skip;
uv_buf[i].len -= to_skip;
to_skip = 0;
}
memcpy(buf + off, uv_buf[i].base, uv_buf[i].len);
off += uv_buf[i].len;
}
uv_buf[0].base = buf;
uv_buf[0].len = off;
/* Create an asynchronous write request */
uv_write_t *write_req = &async_ctx->write_req;
memset(write_req, 0, sizeof(uv_write_t));
write_req->data = p;
/* Perform an asynchronous write with a callback */
if (uv_write(write_req, handle, uv_buf, 1, on_write_complete) == 0) {
ret = total_len;
t->write_queue_size += 1;
} else {
free(p);
kr_log_verbose("[%s] uv_write error: %s\n",
t->client_side ? "tls_client" : "tls", uv_strerror(ret));
errno = EIO;
ret = -1;
}
} else {
errno = ENOMEM;
ret = -1;
}
DEBUG_MSG("[%s] queued %zu <%p> = %d\n",
t->client_side ? "tls_client" : "tls", total_len, h, ret);
return ret;
}
/** Perform TLS handshake and handle error codes according to the documentation.
* See See https://gnutls.org/manual/html_node/TLS-handshake.html#TLS-handshake
* The function returns kr_ok() or success or non fatal error, kr_error(EAGAIN) on blocking, or kr_error(EIO) on fatal error.
*/
static int tls_handshake(struct tls_common_ctx *ctx, tls_handshake_cb handshake_cb) {
struct session *session = ctx->session;
const char *logstring = ctx->client_side ? client_logstring : server_logstring;
int err = gnutls_handshake(ctx->tls_session);
if (err == GNUTLS_E_SUCCESS) {
/* Handshake finished, return success */
ctx->handshake_state = TLS_HS_DONE;
struct sockaddr *peer = session_get_peer(session);
kr_log_verbose("[%s] TLS handshake with %s has completed\n",
logstring, kr_straddr(peer));
if (handshake_cb) {
if (handshake_cb(session, 0) != kr_ok()) {
return kr_error(EIO);
}
}
} else if (err == GNUTLS_E_AGAIN) {
return kr_error(EAGAIN);
} else if (gnutls_error_is_fatal(err)) {
/* Fatal errors, return error as it's not recoverable */
kr_log_verbose("[%s] gnutls_handshake failed: %s (%d)\n",
logstring,
gnutls_strerror_name(err), err);
/* Notify the peer about handshake failure via an alert. */
gnutls_alert_send_appropriate(ctx->tls_session, err);
if (handshake_cb) {
handshake_cb(session, -1);
}
return kr_error(EIO);
} else if (err == GNUTLS_E_WARNING_ALERT_RECEIVED) {
/* Handle warning when in verbose mode */
const char *alert_name = gnutls_alert_get_name(gnutls_alert_get(ctx->tls_session));
if (alert_name != NULL) {
struct sockaddr *peer = session_get_peer(session);
kr_log_verbose("[%s] TLS alert from %s received: %s\n",
logstring, kr_straddr(peer), alert_name);
}
}
return kr_ok();
}
struct tls_ctx *tls_new(struct worker_ctx *worker)
{
assert(worker != NULL);
assert(worker->engine != NULL);
struct network *net = &worker->engine->net;
if (!net->tls_credentials) {
net->tls_credentials = tls_get_ephemeral_credentials(worker->engine);
if (!net->tls_credentials) {
kr_log_error("[tls] X.509 credentials are missing, and ephemeral credentials failed; no TLS\n");
return NULL;
}
kr_log_info("[tls] Using ephemeral TLS credentials\n");
tls_credentials_log_pins(net->tls_credentials);
}
time_t now = time(NULL);
if (net->tls_credentials->valid_until != GNUTLS_X509_NO_WELL_DEFINED_EXPIRATION) {
if (net->tls_credentials->ephemeral_servicename) {
/* ephemeral cert: refresh if due to expire within a week */
if (now >= net->tls_credentials->valid_until - EPHEMERAL_CERT_EXPIRATION_SECONDS_RENEW_BEFORE) {
struct tls_credentials *newcreds = tls_get_ephemeral_credentials(worker->engine);
if (newcreds) {
tls_credentials_release(net->tls_credentials);
net->tls_credentials = newcreds;
kr_log_info("[tls] Renewed expiring ephemeral X.509 cert\n");
} else {
kr_log_error("[tls] Failed to renew expiring ephemeral X.509 cert, using existing one\n");
}
}
} else {
/* non-ephemeral cert: warn once when certificate expires */
if (now >= net->tls_credentials->valid_until) {
kr_log_error("[tls] X.509 certificate has expired!\n");
net->tls_credentials->valid_until = GNUTLS_X509_NO_WELL_DEFINED_EXPIRATION;
}
}
}
struct tls_ctx *tls = calloc(1, sizeof(struct tls_ctx));
if (tls == NULL) {
kr_log_error("[tls] failed to allocate TLS context\n");
return NULL;
}
int err = gnutls_init(&tls->c.tls_session, GNUTLS_SERVER | GNUTLS_NONBLOCK);
if (err != GNUTLS_E_SUCCESS) {
kr_log_error("[tls] gnutls_init(): %s (%d)\n", gnutls_strerror_name(err), err);
tls_free(tls);
return NULL;
}
tls->credentials = tls_credentials_reserve(net->tls_credentials);
err = gnutls_credentials_set(tls->c.tls_session, GNUTLS_CRD_CERTIFICATE,
tls->credentials->credentials);
if (err != GNUTLS_E_SUCCESS) {
kr_log_error("[tls] gnutls_credentials_set(): %s (%d)\n", gnutls_strerror_name(err), err);
tls_free(tls);
return NULL;
}
if (kres_gnutls_set_priority(tls->c.tls_session) != GNUTLS_E_SUCCESS) {
tls_free(tls);
return NULL;
}
tls->c.worker = worker;
tls->c.client_side = false;
gnutls_transport_set_pull_function(tls->c.tls_session, kres_gnutls_pull);
gnutls_transport_set_vec_push_function(tls->c.tls_session, kres_gnutls_vec_push);
gnutls_transport_set_ptr(tls->c.tls_session, tls);
if (net->tls_session_ticket_ctx) {
tls_session_ticket_enable(net->tls_session_ticket_ctx,
tls->c.tls_session);
}
return tls;
}
void tls_close(struct tls_common_ctx *ctx)
{
if (ctx == NULL || ctx->tls_session == NULL) {
return;
}
assert(ctx->session);
if (ctx->handshake_state == TLS_HS_DONE) {
const struct sockaddr *peer = session_get_peer(ctx->session);
kr_log_verbose("[%s] closing tls connection to `%s`\n",
ctx->client_side ? "tls_client" : "tls",
kr_straddr(peer));
ctx->handshake_state = TLS_HS_CLOSING;
gnutls_bye(ctx->tls_session, GNUTLS_SHUT_RDWR);
}
}
void tls_free(struct tls_ctx *tls)
{
if (!tls) {
return;
}
if (tls->c.tls_session) {
/* Don't terminate TLS connection, just tear it down */
gnutls_deinit(tls->c.tls_session);
tls->c.tls_session = NULL;
}
tls_credentials_release(tls->credentials);
free(tls);
}
int tls_write(uv_write_t *req, uv_handle_t *handle, knot_pkt_t *pkt, uv_write_cb cb)
{
if (!pkt || !handle || !handle->data) {
return kr_error(EINVAL);
}
struct session *s = handle->data;
struct tls_common_ctx *tls_ctx = session_tls_get_common_ctx(s);
assert (tls_ctx);
assert (session_flags(s)->outgoing == tls_ctx->client_side);
const uint16_t pkt_size = htons(pkt->size);
const char *logstring = tls_ctx->client_side ? client_logstring : server_logstring;
gnutls_session_t tls_session = tls_ctx->tls_session;
gnutls_record_cork(tls_session);
ssize_t count = 0;
if ((count = gnutls_record_send(tls_session, &pkt_size, sizeof(pkt_size)) < 0) ||
(count = gnutls_record_send(tls_session, pkt->wire, pkt->size) < 0)) {
kr_log_verbose("[%s] gnutls_record_send failed: %s (%zd)\n",
logstring, gnutls_strerror_name(count), count);
return kr_error(EIO);
}
const ssize_t submitted = sizeof(pkt_size) + pkt->size;
int ret = gnutls_record_uncork(tls_session, GNUTLS_RECORD_WAIT);
if (ret < 0) {
if (!gnutls_error_is_fatal(ret)) {
return kr_error(EAGAIN);
} else {
kr_log_verbose("[%s] gnutls_record_uncork failed: %s (%d)\n",
logstring, gnutls_strerror_name(ret), ret);
return kr_error(EIO);
}
}
if (ret != submitted) {
kr_log_error("[%s] gnutls_record_uncork didn't send all data (%d of %zd)\n",
logstring, ret, submitted);
return kr_error(EIO);
}
/* The data is now accepted in gnutls internal buffers, the message can be treated as sent */
req->handle = (uv_stream_t *)handle;
cb(req, 0);
return kr_ok();
}
ssize_t tls_process_input_data(struct session *s, const uint8_t *buf, ssize_t nread)
{
struct tls_common_ctx *tls_p = session_tls_get_common_ctx(s);
if (!tls_p) {
return kr_error(ENOSYS);
}
assert(tls_p->session == s);
const bool ok = tls_p->recv_buf == buf && nread <= sizeof(tls_p->recv_buf);
if (!ok) {
assert(false);
/* don't risk overflowing the buffer if we have a mistake somewhere */
return kr_error(EINVAL);
}
const char *logstring = tls_p->client_side ? client_logstring : server_logstring;
tls_p->buf = buf;
tls_p->nread = nread >= 0 ? nread : 0;
tls_p->consumed = 0;
/* Ensure TLS handshake is performed before receiving data.
* See https://www.gnutls.org/manual/html_node/TLS-handshake.html */
while (tls_p->handshake_state <= TLS_HS_IN_PROGRESS) {
int err = tls_handshake(tls_p, tls_p->handshake_cb);
if (err == kr_error(EAGAIN)) {
return 0; /* Wait for more data */
} else if (err != kr_ok()) {
return err;
}
}
/* See https://gnutls.org/manual/html_node/Data-transfer-and-termination.html#Data-transfer-and-termination */
ssize_t submitted = 0;
uint8_t *wire_buf = session_wirebuf_get_free_start(s);
size_t wire_buf_size = session_wirebuf_get_free_size(s);
while (true) {
ssize_t count = gnutls_record_recv(tls_p->tls_session, wire_buf, wire_buf_size);
if (count == GNUTLS_E_AGAIN) {
if (tls_p->consumed == tls_p->nread) {
/* See https://www.gnutls.org/manual/html_node/Asynchronous-operation.html */
break; /* No more data available in this libuv buffer */
}
continue;
} else if (count == GNUTLS_E_INTERRUPTED) {
continue;
} else if (count == GNUTLS_E_REHANDSHAKE) {
/* See https://www.gnutls.org/manual/html_node/Re_002dauthentication.html */
struct sockaddr *peer = session_get_peer(s);
kr_log_verbose("[%s] TLS rehandshake with %s has started\n",
logstring, kr_straddr(peer));
tls_set_hs_state(tls_p, TLS_HS_IN_PROGRESS);
int err = kr_ok();
while (tls_p->handshake_state <= TLS_HS_IN_PROGRESS) {
err = tls_handshake(tls_p, tls_p->handshake_cb);
if (err == kr_error(EAGAIN)) {
break;
} else if (err != kr_ok()) {
return err;
}
}
if (err == kr_error(EAGAIN)) {
/* pull function is out of data */
break;
}
/* There are can be data available, check it. */
continue;
} else if (count < 0) {
kr_log_verbose("[%s] gnutls_record_recv failed: %s (%zd)\n",
logstring, gnutls_strerror_name(count), count);
return kr_error(EIO);
} else if (count == 0) {
break;
}
DEBUG_MSG("[%s] received %zd data\n", logstring, count);
wire_buf += count;
wire_buf_size -= count;
submitted += count;
if (wire_buf_size == 0 && tls_p->consumed != tls_p->nread) {
/* session buffer is full
* whereas not all the data were consumed */
return kr_error(ENOSPC);
}
}
/* Here all data must be consumed. */
if (tls_p->consumed != tls_p->nread) {
/* Something went wrong, better return error.
* This is most probably due to gnutls_record_recv() did not
* consume all available network data by calling kres_gnutls_pull().
* TODO assess the need for buffering of data amount.
*/
return kr_error(ENOSPC);
}
return submitted;
}
#if TLS_CAN_USE_PINS
/*
DNS-over-TLS Out of band key-pinned authentication profile uses the
same form of pins as HPKP:
e.g. pin-sha256="FHkyLhvI0n70E47cJlRTamTrnYVcsYdjUGbr79CfAVI="
DNS-over-TLS OOB key-pins: https://tools.ietf.org/html/rfc7858#appendix-A
HPKP pin reference: https://tools.ietf.org/html/rfc7469#appendix-A
*/
#define PINLEN ((((32) * 8 + 4)/6) + 3 + 1)
/* Compute pin_sha256 for the certificate.
* It may be in raw format - just TLS_SHA256_RAW_LEN bytes without termination,
* or it may be a base64 0-terminated string requiring up to
* TLS_SHA256_BASE64_BUFLEN bytes.
* \return error code */
static int get_oob_key_pin(gnutls_x509_crt_t crt, char *outchar, ssize_t outchar_len, bool raw)
{
if (raw && outchar_len < TLS_SHA256_RAW_LEN) {
assert(false);
return kr_error(ENOSPC);
/* With !raw we have check inside kr_base64_encode. */
}
gnutls_pubkey_t key;
int err = gnutls_pubkey_init(&key);
if (err != GNUTLS_E_SUCCESS) return err;
gnutls_datum_t datum = { .data = NULL, .size = 0 };
err = gnutls_pubkey_import_x509(key, crt, 0);
if (err != GNUTLS_E_SUCCESS) goto leave;
err = gnutls_pubkey_export2(key, GNUTLS_X509_FMT_DER, &datum);
if (err != GNUTLS_E_SUCCESS) goto leave;
char raw_pin[TLS_SHA256_RAW_LEN]; /* TMP buffer if raw == false */
err = gnutls_hash_fast(GNUTLS_DIG_SHA256, datum.data, datum.size,
(raw ? outchar : raw_pin));
if (err != GNUTLS_E_SUCCESS || raw/*success*/)
goto leave;
/* Convert to non-raw. */
err = kr_base64_encode((uint8_t *)raw_pin, sizeof(raw_pin),
(uint8_t *)outchar, outchar_len);
if (err >= 0 && err < outchar_len) {
err = GNUTLS_E_SUCCESS;
outchar[err] = '\0'; /* kr_base64_encode() doesn't do it */
} else if (err >= 0) {
assert(false);
err = kr_error(ENOSPC); /* base64 fits but '\0' doesn't */
outchar[outchar_len - 1] = '\0';
}
leave:
gnutls_free(datum.data);
gnutls_pubkey_deinit(key);
return err;
}
void tls_credentials_log_pins(struct tls_credentials *tls_credentials)
{
for (int index = 0;; index++) {
gnutls_x509_crt_t *certs = NULL;
unsigned int cert_count = 0;
int err = gnutls_certificate_get_x509_crt(tls_credentials->credentials,
index, &certs, &cert_count);
if (err != GNUTLS_E_SUCCESS) {
if (err != GNUTLS_E_REQUESTED_DATA_NOT_AVAILABLE) {
kr_log_error("[tls] could not get X.509 certificates (%d) %s\n",
err, gnutls_strerror_name(err));
}
return;
}
for (int i = 0; i < cert_count; i++) {
char pin[TLS_SHA256_BASE64_BUFLEN] = { 0 };
err = get_oob_key_pin(certs[i], pin, sizeof(pin), false);
if (err != GNUTLS_E_SUCCESS) {
kr_log_error("[tls] could not calculate RFC 7858 OOB key-pin from cert %d (%d) %s\n",
i, err, gnutls_strerror_name(err));
} else {
kr_log_info("[tls] RFC 7858 OOB key-pin (%d): pin-sha256=\"%s\"\n",
i, pin);
}
gnutls_x509_crt_deinit(certs[i]);
}
gnutls_free(certs);
}
}
#else
void tls_credentials_log_pins(struct tls_credentials *tls_credentials)
{
kr_log_verbose("[tls] could not calculate RFC 7858 OOB key-pin; GnuTLS 3.4.0+ required\n");
}
#endif
static int str_replace(char **where_ptr, const char *with)
{
char *copy = with ? strdup(with) : NULL;
if (with && !copy) {
return kr_error(ENOMEM);
}
free(*where_ptr);
*where_ptr = copy;
return kr_ok();
}
static time_t _get_end_entity_expiration(gnutls_certificate_credentials_t creds)
{
gnutls_datum_t data;
gnutls_x509_crt_t cert = NULL;
int err;
time_t ret = GNUTLS_X509_NO_WELL_DEFINED_EXPIRATION;
if ((err = gnutls_certificate_get_crt_raw(creds, 0, 0, &data)) != GNUTLS_E_SUCCESS) {
kr_log_error("[tls] failed to get cert to check expiration: (%d) %s\n",
err, gnutls_strerror_name(err));
goto done;
}
if ((err = gnutls_x509_crt_init(&cert)) != GNUTLS_E_SUCCESS) {
kr_log_error("[tls] failed to initialize cert: (%d) %s\n",
err, gnutls_strerror_name(err));
goto done;
}
if ((err = gnutls_x509_crt_import(cert, &data, GNUTLS_X509_FMT_DER)) != GNUTLS_E_SUCCESS) {
kr_log_error("[tls] failed to construct cert while checking expiration: (%d) %s\n",
err, gnutls_strerror_name(err));
goto done;
}
ret = gnutls_x509_crt_get_expiration_time (cert);
done:
/* do not free data; g_c_get_crt_raw() says to treat it as
* constant. */
gnutls_x509_crt_deinit(cert);
return ret;
}
int tls_certificate_set(struct network *net, const char *tls_cert, const char *tls_key)
{
if (!net) {
return kr_error(EINVAL);
}
struct tls_credentials *tls_credentials = calloc(1, sizeof(*tls_credentials));
if (tls_credentials == NULL) {
return kr_error(ENOMEM);
}
int err = 0;
if ((err = gnutls_certificate_allocate_credentials(&tls_credentials->credentials)) != GNUTLS_E_SUCCESS) {
kr_log_error("[tls] gnutls_certificate_allocate_credentials() failed: (%d) %s\n",
err, gnutls_strerror_name(err));
tls_credentials_free(tls_credentials);
return kr_error(ENOMEM);
}
if ((err = gnutls_certificate_set_x509_system_trust(tls_credentials->credentials)) < 0) {
if (err != GNUTLS_E_UNIMPLEMENTED_FEATURE) {
kr_log_error("[tls] warning: gnutls_certificate_set_x509_system_trust() failed: (%d) %s\n",
err, gnutls_strerror_name(err));
tls_credentials_free(tls_credentials);
return err;
}
}
if ((str_replace(&tls_credentials->tls_cert, tls_cert) != 0) ||
(str_replace(&tls_credentials->tls_key, tls_key) != 0)) {
tls_credentials_free(tls_credentials);
return kr_error(ENOMEM);
}
if ((err = gnutls_certificate_set_x509_key_file(tls_credentials->credentials,
tls_cert, tls_key, GNUTLS_X509_FMT_PEM)) != GNUTLS_E_SUCCESS) {
tls_credentials_free(tls_credentials);
kr_log_error("[tls] gnutls_certificate_set_x509_key_file(%s,%s) failed: %d (%s)\n",
tls_cert, tls_key, err, gnutls_strerror_name(err));
return kr_error(EINVAL);
}
/* record the expiration date: */
tls_credentials->valid_until = _get_end_entity_expiration(tls_credentials->credentials);
/* Exchange the x509 credentials */
struct tls_credentials *old_credentials = net->tls_credentials;
/* Start using the new x509_credentials */
net->tls_credentials = tls_credentials;
tls_credentials_log_pins(net->tls_credentials);
if (old_credentials) {
err = tls_credentials_release(old_credentials);
if (err != kr_error(EBUSY)) {
return err;
}
}
return kr_ok();
}
struct tls_credentials *tls_credentials_reserve(struct tls_credentials *tls_credentials) {
if (!tls_credentials) {
return NULL;
}
tls_credentials->count++;
return tls_credentials;
}
int tls_credentials_release(struct tls_credentials *tls_credentials) {
if (!tls_credentials) {
return kr_error(EINVAL);
}
if (--tls_credentials->count < 0) {
tls_credentials_free(tls_credentials);
} else {
return kr_error(EBUSY);
}
return kr_ok();
}
void tls_credentials_free(struct tls_credentials *tls_credentials) {
if (!tls_credentials) {
return;
}
if (tls_credentials->credentials) {
gnutls_certificate_free_credentials(tls_credentials->credentials);
}
if (tls_credentials->tls_cert) {
free(tls_credentials->tls_cert);
}
if (tls_credentials->tls_key) {
free(tls_credentials->tls_key);
}
if (tls_credentials->ephemeral_servicename) {
free(tls_credentials->ephemeral_servicename);
}
free(tls_credentials);
}
void tls_client_param_unref(tls_client_param_t *entry)
{
if (!entry) return;
assert(entry->refs); /* Well, we'd only leak memory. */
--(entry->refs);
if (entry->refs) return;
DEBUG_MSG("freeing TLS parameters %p\n", (void *)entry);
for (int i = 0; i < entry->ca_files.len; ++i) {
free_const(entry->ca_files.at[i]);
}
array_clear(entry->ca_files);
free_const(entry->hostname);
for (int i = 0; i < entry->pins.len; ++i) {
free_const(entry->pins.at[i]);
}
array_clear(entry->pins);
if (entry->credentials) {
gnutls_certificate_free_credentials(entry->credentials);
}
if (entry->session_data.data) {
gnutls_free(entry->session_data.data);
}
free(entry);
}
static int param_free(void **param, void *null)
{
assert(param && *param);
tls_client_param_unref(*param);
return 0;
}
void tls_client_params_free(tls_client_params_t *params)
{
if (!params) return;
trie_apply(params, param_free, NULL);
trie_free(params);
}
tls_client_param_t * tls_client_param_new()
{
tls_client_param_t *e = calloc(1, sizeof(*e));
if (!e) {
assert(!ENOMEM);
return NULL;
}
/* Note: those array_t don't need further initialization. */
e->refs = 1;
int ret = gnutls_certificate_allocate_credentials(&e->credentials);
if (ret != GNUTLS_E_SUCCESS) {
kr_log_error("[tls_client] error: gnutls_certificate_allocate_credentials() fails (%s)\n",
gnutls_strerror_name(ret));
free(e);
return NULL;
}
gnutls_certificate_set_verify_function(e->credentials, client_verify_certificate);
return e;
}
/**
* Convert an IP address and port number to binary key.
*
* \precond buffer \param key must have sufficient size
* \param addr[in]
* \param len[out] output length
* \param key[out] output buffer
*/
static bool construct_key(const union inaddr *addr, uint32_t *len, char *key)
{
switch (addr->ip.sa_family) {
case AF_INET:
memcpy(key, &addr->ip4.sin_port, sizeof(addr->ip4.sin_port));
memcpy(key + sizeof(addr->ip4.sin_port), &addr->ip4.sin_addr,
sizeof(addr->ip4.sin_addr));
*len = sizeof(addr->ip4.sin_port) + sizeof(addr->ip4.sin_addr);
return true;
case AF_INET6:
memcpy(key, &addr->ip6.sin6_port, sizeof(addr->ip6.sin6_port));
memcpy(key + sizeof(addr->ip6.sin6_port), &addr->ip6.sin6_addr,
sizeof(addr->ip6.sin6_addr));
*len = sizeof(addr->ip6.sin6_port) + sizeof(addr->ip6.sin6_addr);
return true;
default:
assert(!EINVAL);
return false;
}
}
tls_client_param_t ** tls_client_param_getptr(tls_client_params_t **params,
const struct sockaddr *addr, bool do_insert)
{
assert(params && addr);
/* We accept NULL for empty map; ensure the map exists if needed. */
if (!*params) {
if (!do_insert) return NULL;
*params = trie_create(NULL);
if (!*params) {
assert(!ENOMEM);
return NULL;
}
}
/* Construct the key. */
const union inaddr *ia = (const union inaddr *)addr;
char key[sizeof(ia->ip6.sin6_port) + sizeof(ia->ip6.sin6_addr)];
uint32_t len;
if (!construct_key(ia, &len, key))
return NULL;
/* Get the entry. */
return (tls_client_param_t **)
(do_insert ? trie_get_ins : trie_get_try)(*params, key, len);
}
int tls_client_param_remove(tls_client_params_t *params, const struct sockaddr *addr)
{
const union inaddr *ia = (const union inaddr *)addr;
char key[sizeof(ia->ip6.sin6_port) + sizeof(ia->ip6.sin6_addr)];
uint32_t len;
if (!construct_key(ia, &len, key))
return kr_error(EINVAL);
trie_val_t param_ptr;
int ret = trie_del(params, key, len, ¶m_ptr);
if (ret)
return kr_error(ret);
tls_client_param_unref(param_ptr);
return kr_ok();
}
/**
* Verify that at least one certificate in the certificate chain matches
* at least one certificate pin in the non-empty params->pins array.
* \returns GNUTLS_E_SUCCESS if pin matches, any other value is an error
*/
static int client_verify_pin(const unsigned int cert_list_size,
const gnutls_datum_t *cert_list,
tls_client_param_t *params)
{
assert(params->pins.len > 0);
#if TLS_CAN_USE_PINS
for (int i = 0; i < cert_list_size; i++) {
gnutls_x509_crt_t cert;
int ret = gnutls_x509_crt_init(&cert);
if (ret != GNUTLS_E_SUCCESS) {
return ret;
}
ret = gnutls_x509_crt_import(cert, &cert_list[i], GNUTLS_X509_FMT_DER);
if (ret != GNUTLS_E_SUCCESS) {
gnutls_x509_crt_deinit(cert);
return ret;
}
#ifdef DEBUG
if (VERBOSE_STATUS) {
char pin_base64[TLS_SHA256_BASE64_BUFLEN];
/* DEBUG: additionally compute and print the base64 pin.
* Not very efficient, but that's OK for DEBUG. */
ret = get_oob_key_pin(cert, pin_base64, sizeof(pin_base64), false);
if (ret == GNUTLS_E_SUCCESS) {
DEBUG_MSG("[tls_client] received pin: %s\n", pin_base64);
} else {
DEBUG_MSG("[tls_client] failed to convert received pin\n");
/* Now we hope that `ret` below can't differ. */
}
}
#endif
char cert_pin[TLS_SHA256_RAW_LEN];
/* Get raw pin and compare. */
ret = get_oob_key_pin(cert, cert_pin, sizeof(cert_pin), true);
gnutls_x509_crt_deinit(cert);
if (ret != GNUTLS_E_SUCCESS) {
return ret;
}
for (size_t j = 0; j < params->pins.len; ++j) {
const uint8_t *pin = params->pins.at[j];
if (memcmp(cert_pin, pin, TLS_SHA256_RAW_LEN) != 0)
continue; /* mismatch */
DEBUG_MSG("[tls_client] matched a configured pin no. %zd\n", j);
return GNUTLS_E_SUCCESS;
}
DEBUG_MSG("[tls_client] none of %zd configured pin(s) matched\n",
params->pins.len);
}
kr_log_error("[tls_client] no pin matched: %zu pins * %d certificates\n",
params->pins.len, cert_list_size);
return GNUTLS_E_CERTIFICATE_ERROR;
#else /* TLS_CAN_USE_PINS */
kr_log_error("[tls_client] internal inconsistency: TLS_CAN_USE_PINS\n");
assert(false);
return GNUTLS_E_CERTIFICATE_ERROR;
#endif
}
/**
* Verify that \param tls_session contains a valid X.509 certificate chain
* with given hostname.
*
* \returns GNUTLS_E_SUCCESS if certificate chain is valid, any other value is an error
*/
static int client_verify_certchain(gnutls_session_t tls_session, const char *hostname)
{
if (!hostname) {
kr_log_error("[tls_client] internal config inconsistency: no hostname set\n");
assert(false);
return GNUTLS_E_CERTIFICATE_ERROR;
}
unsigned int status;
int ret = gnutls_certificate_verify_peers3(tls_session, hostname, &status);
if ((ret == GNUTLS_E_SUCCESS) && (status == 0)) {
return GNUTLS_E_SUCCESS;
}
if (ret == GNUTLS_E_SUCCESS) {
gnutls_datum_t msg;
ret = gnutls_certificate_verification_status_print(
status, gnutls_certificate_type_get(tls_session), &msg, 0);
if (ret == GNUTLS_E_SUCCESS) {
kr_log_error("[tls_client] failed to verify peer certificate: "
"%s\n", msg.data);
gnutls_free(msg.data);
} else {
kr_log_error("[tls_client] failed to verify peer certificate: "
"unable to print reason: %s (%s)\n",
gnutls_strerror(ret), gnutls_strerror_name(ret));
} /* gnutls_certificate_verification_status_print end */
} else {
kr_log_error("[tls_client] failed to verify peer certificate: "
"gnutls_certificate_verify_peers3 error: %s (%s)\n",
gnutls_strerror(ret), gnutls_strerror_name(ret));
} /* gnutls_certificate_verify_peers3 end */
return GNUTLS_E_CERTIFICATE_ERROR;
}
/**
* Verify that actual TLS security parameters of \param tls_session
* match requirements provided by user in tls_session->params.
* \returns GNUTLS_E_SUCCESS if requirements were met, any other value is an error
*/
static int client_verify_certificate(gnutls_session_t tls_session)
{
struct tls_client_ctx *ctx = gnutls_session_get_ptr(tls_session);
assert(ctx->params != NULL);
if (ctx->params->insecure) {
return GNUTLS_E_SUCCESS;
}
gnutls_certificate_type_t cert_type = gnutls_certificate_type_get(tls_session);
if (cert_type != GNUTLS_CRT_X509) {
kr_log_error("[tls_client] invalid certificate type %i has been received\n",
cert_type);
return GNUTLS_E_CERTIFICATE_ERROR;
}
unsigned int cert_list_size = 0;
const gnutls_datum_t *cert_list =
gnutls_certificate_get_peers(tls_session, &cert_list_size);
if (cert_list == NULL || cert_list_size == 0) {
kr_log_error("[tls_client] empty certificate list\n");
return GNUTLS_E_CERTIFICATE_ERROR;
}
if (ctx->params->pins.len > 0)
/* check hash of the certificate but ignore everything else */
return client_verify_pin(cert_list_size, cert_list, ctx->params);
else
return client_verify_certchain(ctx->c.tls_session, ctx->params->hostname);
}
struct tls_client_ctx *tls_client_ctx_new(tls_client_param_t *entry,
struct worker_ctx *worker)
{
struct tls_client_ctx *ctx = calloc(1, sizeof (struct tls_client_ctx));
if (!ctx) {
return NULL;
}
unsigned int flags = GNUTLS_CLIENT | GNUTLS_NONBLOCK
#ifdef GNUTLS_ENABLE_FALSE_START
| GNUTLS_ENABLE_FALSE_START
#endif
;
int ret = gnutls_init(&ctx->c.tls_session, flags);
if (ret != GNUTLS_E_SUCCESS) {
tls_client_ctx_free(ctx);
return NULL;
}
ret = kres_gnutls_set_priority(ctx->c.tls_session);
if (ret != GNUTLS_E_SUCCESS) {
tls_client_ctx_free(ctx);
return NULL;
}
/* Must take a reference on parameters as the credentials are owned by it
* and must not be freed while the session is active. */
++(entry->refs);
ctx->params = entry;
ret = gnutls_credentials_set(ctx->c.tls_session, GNUTLS_CRD_CERTIFICATE,
entry->credentials);
if (ret == GNUTLS_E_SUCCESS && entry->hostname) {
ret = gnutls_server_name_set(ctx->c.tls_session, GNUTLS_NAME_DNS,
entry->hostname, strlen(entry->hostname));
kr_log_verbose("[tls_client] set hostname, ret = %d\n", ret);
} else if (!entry->hostname) {
kr_log_verbose("[tls_client] no hostname\n");
}
if (ret != GNUTLS_E_SUCCESS) {
tls_client_ctx_free(ctx);
return NULL;
}
ctx->c.worker = worker;
ctx->c.client_side = true;
gnutls_transport_set_pull_function(ctx->c.tls_session, kres_gnutls_pull);
gnutls_transport_set_vec_push_function(ctx->c.tls_session, kres_gnutls_vec_push);
gnutls_transport_set_ptr(ctx->c.tls_session, ctx);
return ctx;
}
void tls_client_ctx_free(struct tls_client_ctx *ctx)
{
if (ctx == NULL) {
return;
}
if (ctx->c.tls_session != NULL) {
gnutls_deinit(ctx->c.tls_session);
ctx->c.tls_session = NULL;
}
/* Must decrease the refcount for referenced parameters */
tls_client_param_unref(ctx->params);
free (ctx);
}
int tls_pull_timeout_func(gnutls_transport_ptr_t h, unsigned int ms)
{
struct tls_common_ctx *t = (struct tls_common_ctx *)h;
assert(t != NULL);
ssize_t avail = t->nread - t->consumed;
DEBUG_MSG("[%s] timeout check: available: %zu\n",
t->client_side ? "tls_client" : "tls", avail);
if (avail <= 0) {
errno = EAGAIN;
return -1;
}
return avail;
}
int tls_client_connect_start(struct tls_client_ctx *client_ctx,
struct session *session,
tls_handshake_cb handshake_cb)
{
if (session == NULL || client_ctx == NULL) {
return kr_error(EINVAL);
}
assert(session_flags(session)->outgoing && session_get_handle(session)->type == UV_TCP);
struct tls_common_ctx *ctx = &client_ctx->c;
gnutls_session_set_ptr(ctx->tls_session, client_ctx);
gnutls_handshake_set_timeout(ctx->tls_session, ctx->worker->engine->net.tcp.tls_handshake_timeout);
gnutls_transport_set_pull_timeout_function(ctx->tls_session, tls_pull_timeout_func);
session_tls_set_client_ctx(session, client_ctx);
ctx->handshake_cb = handshake_cb;
ctx->handshake_state = TLS_HS_IN_PROGRESS;
ctx->session = session;
tls_client_param_t *tls_params = client_ctx->params;
if (tls_params->session_data.data != NULL) {
gnutls_session_set_data(ctx->tls_session, tls_params->session_data.data,
tls_params->session_data.size);
}
/* See https://www.gnutls.org/manual/html_node/Asynchronous-operation.html */
while (ctx->handshake_state <= TLS_HS_IN_PROGRESS) {
int ret = tls_handshake(ctx, handshake_cb);
if (ret != kr_ok()) {
return ret;
}
}
return kr_ok();
}
tls_hs_state_t tls_get_hs_state(const struct tls_common_ctx *ctx)
{
return ctx->handshake_state;
}
int tls_set_hs_state(struct tls_common_ctx *ctx, tls_hs_state_t state)
{
if (state >= TLS_HS_LAST) {
return kr_error(EINVAL);
}
ctx->handshake_state = state;
return kr_ok();
}
int tls_client_ctx_set_session(struct tls_client_ctx *ctx, struct session *session)
{
if (!ctx) {
return kr_error(EINVAL);
}
ctx->c.session = session;
return kr_ok();
}
#undef DEBUG_MSG
|