Change places that open-code NLA_POLICY_MIN_LEN() to
use the macro instead, giving us flexibility in how we
handle the details of the macro.
Signed-off-by: Johannes Berg <johannes.berg@intel.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
Change places that open-code NLA_POLICY_EXACT_LEN() to
use the macro instead, giving us flexibility in how we
handle the details of the macro.
Signed-off-by: Johannes Berg <johannes.berg@intel.com>
Acked-by: Matthieu Baerts <matthieu.baerts@tessares.net>
Signed-off-by: David S. Miller <davem@davemloft.net>
Before, we took a reference to the creating netns if the new netns was
different. This caused issues with circular references, with two
wireguard interfaces swapping namespaces. The solution is to rather not
take any extra references at all, but instead simply invalidate the
creating netns pointer when that netns is deleted.
In order to prevent this from happening again, this commit improves the
rough object leak tracking by allowing it to account for created and
destroyed interfaces, aside from just peers and keys. That then makes it
possible to check for the object leak when having two interfaces take a
reference to each others' namespaces.
Fixes: e7096c131e ("net: WireGuard secure network tunnel")
Signed-off-by: Jason A. Donenfeld <Jason@zx2c4.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
We precompute the static-static ECDH during configuration time, in order
to save an expensive computation later when receiving network packets.
However, not all ECDH computations yield a contributory result. Prior,
we were just not letting those peers be added to the interface. However,
this creates a strange inconsistency, since it was still possible to add
other weird points, like a valid public key plus a low-order point, and,
like points that result in zeros, a handshake would not complete. In
order to make the behavior more uniform and less surprising, simply
allow all peers to be added. Then, we'll error out later when doing the
crypto if there's an issue. This also adds more separation between the
crypto layer and the configuration layer.
Discussed-with: Mathias Hall-Andersen <mathias@hall-andersen.dk>
Signed-off-by: Jason A. Donenfeld <Jason@zx2c4.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
Our static-static calculation returns a failure if the public key is of
low order. We check for this when peers are added, and don't allow them
to be added if they're low order, except in the case where we haven't
yet been given a private key. In that case, we would defer the removal
of the peer until we're given a private key, since at that point we're
doing new static-static calculations which incur failures we can act on.
This meant, however, that we wound up removing peers rather late in the
configuration flow.
Syzkaller points out that peer_remove calls flush_workqueue, which in
turn might then wait for sending a handshake initiation to complete.
Since handshake initiation needs the static identity lock, holding the
static identity lock while calling peer_remove can result in a rare
deadlock. We have precisely this case in this situation of late-stage
peer removal based on an invalid public key. We can't drop the lock when
removing, because then incoming handshakes might interact with a bogus
static-static calculation.
While the band-aid patch for this would involve breaking up the peer
removal into two steps like wg_peer_remove_all does, in order to solve
the locking issue, there's actually a much more elegant way of fixing
this:
If the static-static calculation succeeds with one private key, it
*must* succeed with all others, because all 32-byte strings map to valid
private keys, thanks to clamping. That means we can get rid of this
silly dance and locking headaches of removing peers late in the
configuration flow, and instead just reject them early on, regardless of
whether the device has yet been assigned a private key. For the case
where the device doesn't yet have a private key, we safely use zeros
just for the purposes of checking for low order points by way of
checking the output of the calculation.
The following PoC will trigger the deadlock:
ip link add wg0 type wireguard
ip addr add 10.0.0.1/24 dev wg0
ip link set wg0 up
ping -f 10.0.0.2 &
while true; do
wg set wg0 private-key /dev/null peer AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA= allowed-ips 10.0.0.0/24 endpoint 10.0.0.3:1234
wg set wg0 private-key <(echo AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA=)
done
[ 0.949105] ======================================================
[ 0.949550] WARNING: possible circular locking dependency detected
[ 0.950143] 5.5.0-debug+ #18 Not tainted
[ 0.950431] ------------------------------------------------------
[ 0.950959] wg/89 is trying to acquire lock:
[ 0.951252] ffff8880333e2128 ((wq_completion)wg-kex-wg0){+.+.}, at: flush_workqueue+0xe3/0x12f0
[ 0.951865]
[ 0.951865] but task is already holding lock:
[ 0.952280] ffff888032819bc0 (&wg->static_identity.lock){++++}, at: wg_set_device+0x95d/0xcc0
[ 0.953011]
[ 0.953011] which lock already depends on the new lock.
[ 0.953011]
[ 0.953651]
[ 0.953651] the existing dependency chain (in reverse order) is:
[ 0.954292]
[ 0.954292] -> #2 (&wg->static_identity.lock){++++}:
[ 0.954804] lock_acquire+0x127/0x350
[ 0.955133] down_read+0x83/0x410
[ 0.955428] wg_noise_handshake_create_initiation+0x97/0x700
[ 0.955885] wg_packet_send_handshake_initiation+0x13a/0x280
[ 0.956401] wg_packet_handshake_send_worker+0x10/0x20
[ 0.956841] process_one_work+0x806/0x1500
[ 0.957167] worker_thread+0x8c/0xcb0
[ 0.957549] kthread+0x2ee/0x3b0
[ 0.957792] ret_from_fork+0x24/0x30
[ 0.958234]
[ 0.958234] -> #1 ((work_completion)(&peer->transmit_handshake_work)){+.+.}:
[ 0.958808] lock_acquire+0x127/0x350
[ 0.959075] process_one_work+0x7ab/0x1500
[ 0.959369] worker_thread+0x8c/0xcb0
[ 0.959639] kthread+0x2ee/0x3b0
[ 0.959896] ret_from_fork+0x24/0x30
[ 0.960346]
[ 0.960346] -> #0 ((wq_completion)wg-kex-wg0){+.+.}:
[ 0.960945] check_prev_add+0x167/0x1e20
[ 0.961351] __lock_acquire+0x2012/0x3170
[ 0.961725] lock_acquire+0x127/0x350
[ 0.961990] flush_workqueue+0x106/0x12f0
[ 0.962280] peer_remove_after_dead+0x160/0x220
[ 0.962600] wg_set_device+0xa24/0xcc0
[ 0.962994] genl_rcv_msg+0x52f/0xe90
[ 0.963298] netlink_rcv_skb+0x111/0x320
[ 0.963618] genl_rcv+0x1f/0x30
[ 0.963853] netlink_unicast+0x3f6/0x610
[ 0.964245] netlink_sendmsg+0x700/0xb80
[ 0.964586] __sys_sendto+0x1dd/0x2c0
[ 0.964854] __x64_sys_sendto+0xd8/0x1b0
[ 0.965141] do_syscall_64+0x90/0xd9a
[ 0.965408] entry_SYSCALL_64_after_hwframe+0x49/0xbe
[ 0.965769]
[ 0.965769] other info that might help us debug this:
[ 0.965769]
[ 0.966337] Chain exists of:
[ 0.966337] (wq_completion)wg-kex-wg0 --> (work_completion)(&peer->transmit_handshake_work) --> &wg->static_identity.lock
[ 0.966337]
[ 0.967417] Possible unsafe locking scenario:
[ 0.967417]
[ 0.967836] CPU0 CPU1
[ 0.968155] ---- ----
[ 0.968497] lock(&wg->static_identity.lock);
[ 0.968779] lock((work_completion)(&peer->transmit_handshake_work));
[ 0.969345] lock(&wg->static_identity.lock);
[ 0.969809] lock((wq_completion)wg-kex-wg0);
[ 0.970146]
[ 0.970146] *** DEADLOCK ***
[ 0.970146]
[ 0.970531] 5 locks held by wg/89:
[ 0.970908] #0: ffffffff827433c8 (cb_lock){++++}, at: genl_rcv+0x10/0x30
[ 0.971400] #1: ffffffff82743480 (genl_mutex){+.+.}, at: genl_rcv_msg+0x642/0xe90
[ 0.971924] #2: ffffffff827160c0 (rtnl_mutex){+.+.}, at: wg_set_device+0x9f/0xcc0
[ 0.972488] #3: ffff888032819de0 (&wg->device_update_lock){+.+.}, at: wg_set_device+0xb0/0xcc0
[ 0.973095] #4: ffff888032819bc0 (&wg->static_identity.lock){++++}, at: wg_set_device+0x95d/0xcc0
[ 0.973653]
[ 0.973653] stack backtrace:
[ 0.973932] CPU: 1 PID: 89 Comm: wg Not tainted 5.5.0-debug+ #18
[ 0.974476] Call Trace:
[ 0.974638] dump_stack+0x97/0xe0
[ 0.974869] check_noncircular+0x312/0x3e0
[ 0.975132] ? print_circular_bug+0x1f0/0x1f0
[ 0.975410] ? __kernel_text_address+0x9/0x30
[ 0.975727] ? unwind_get_return_address+0x51/0x90
[ 0.976024] check_prev_add+0x167/0x1e20
[ 0.976367] ? graph_lock+0x70/0x160
[ 0.976682] __lock_acquire+0x2012/0x3170
[ 0.976998] ? register_lock_class+0x1140/0x1140
[ 0.977323] lock_acquire+0x127/0x350
[ 0.977627] ? flush_workqueue+0xe3/0x12f0
[ 0.977890] flush_workqueue+0x106/0x12f0
[ 0.978147] ? flush_workqueue+0xe3/0x12f0
[ 0.978410] ? find_held_lock+0x2c/0x110
[ 0.978662] ? lock_downgrade+0x6e0/0x6e0
[ 0.978919] ? queue_rcu_work+0x60/0x60
[ 0.979166] ? netif_napi_del+0x151/0x3b0
[ 0.979501] ? peer_remove_after_dead+0x160/0x220
[ 0.979871] peer_remove_after_dead+0x160/0x220
[ 0.980232] wg_set_device+0xa24/0xcc0
[ 0.980516] ? deref_stack_reg+0x8e/0xc0
[ 0.980801] ? set_peer+0xe10/0xe10
[ 0.981040] ? __ww_mutex_check_waiters+0x150/0x150
[ 0.981430] ? __nla_validate_parse+0x163/0x270
[ 0.981719] ? genl_family_rcv_msg_attrs_parse+0x13f/0x310
[ 0.982078] genl_rcv_msg+0x52f/0xe90
[ 0.982348] ? genl_family_rcv_msg_attrs_parse+0x310/0x310
[ 0.982690] ? register_lock_class+0x1140/0x1140
[ 0.983049] netlink_rcv_skb+0x111/0x320
[ 0.983298] ? genl_family_rcv_msg_attrs_parse+0x310/0x310
[ 0.983645] ? netlink_ack+0x880/0x880
[ 0.983888] genl_rcv+0x1f/0x30
[ 0.984168] netlink_unicast+0x3f6/0x610
[ 0.984443] ? netlink_detachskb+0x60/0x60
[ 0.984729] ? find_held_lock+0x2c/0x110
[ 0.984976] netlink_sendmsg+0x700/0xb80
[ 0.985220] ? netlink_broadcast_filtered+0xa60/0xa60
[ 0.985533] __sys_sendto+0x1dd/0x2c0
[ 0.985763] ? __x64_sys_getpeername+0xb0/0xb0
[ 0.986039] ? sockfd_lookup_light+0x17/0x160
[ 0.986397] ? __sys_recvmsg+0x8c/0xf0
[ 0.986711] ? __sys_recvmsg_sock+0xd0/0xd0
[ 0.987018] __x64_sys_sendto+0xd8/0x1b0
[ 0.987283] ? lockdep_hardirqs_on+0x39b/0x5a0
[ 0.987666] do_syscall_64+0x90/0xd9a
[ 0.987903] entry_SYSCALL_64_after_hwframe+0x49/0xbe
[ 0.988223] RIP: 0033:0x7fe77c12003e
[ 0.988508] Code: c3 8b 07 85 c0 75 24 49 89 fb 48 89 f0 48 89 d7 48 89 ce 4c 89 c2 4d 89 ca 4c 8b 44 24 08 4c 8b 4c 24 10 4c 4
[ 0.989666] RSP: 002b:00007fffada2ed58 EFLAGS: 00000246 ORIG_RAX: 000000000000002c
[ 0.990137] RAX: ffffffffffffffda RBX: 00007fe77c159d48 RCX: 00007fe77c12003e
[ 0.990583] RDX: 0000000000000040 RSI: 000055fd1d38e020 RDI: 0000000000000004
[ 0.991091] RBP: 000055fd1d38e020 R08: 000055fd1cb63358 R09: 000000000000000c
[ 0.991568] R10: 0000000000000000 R11: 0000000000000246 R12: 000000000000002c
[ 0.992014] R13: 0000000000000004 R14: 000055fd1d38e020 R15: 0000000000000001
Signed-off-by: Jason A. Donenfeld <Jason@zx2c4.com>
Reported-by: syzbot <syzkaller@googlegroups.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
WireGuard is a layer 3 secure networking tunnel made specifically for
the kernel, that aims to be much simpler and easier to audit than IPsec.
Extensive documentation and description of the protocol and
considerations, along with formal proofs of the cryptography, are
available at:
* https://www.wireguard.com/
* https://www.wireguard.com/papers/wireguard.pdf
This commit implements WireGuard as a simple network device driver,
accessible in the usual RTNL way used by virtual network drivers. It
makes use of the udp_tunnel APIs, GRO, GSO, NAPI, and the usual set of
networking subsystem APIs. It has a somewhat novel multicore queueing
system designed for maximum throughput and minimal latency of encryption
operations, but it is implemented modestly using workqueues and NAPI.
Configuration is done via generic Netlink, and following a review from
the Netlink maintainer a year ago, several high profile userspace tools
have already implemented the API.
This commit also comes with several different tests, both in-kernel
tests and out-of-kernel tests based on network namespaces, taking profit
of the fact that sockets used by WireGuard intentionally stay in the
namespace the WireGuard interface was originally created, exactly like
the semantics of userspace tun devices. See wireguard.com/netns/ for
pictures and examples.
The source code is fairly short, but rather than combining everything
into a single file, WireGuard is developed as cleanly separable files,
making auditing and comprehension easier. Things are laid out as
follows:
* noise.[ch], cookie.[ch], messages.h: These implement the bulk of the
cryptographic aspects of the protocol, and are mostly data-only in
nature, taking in buffers of bytes and spitting out buffers of
bytes. They also handle reference counting for their various shared
pieces of data, like keys and key lists.
* ratelimiter.[ch]: Used as an integral part of cookie.[ch] for
ratelimiting certain types of cryptographic operations in accordance
with particular WireGuard semantics.
* allowedips.[ch], peerlookup.[ch]: The main lookup structures of
WireGuard, the former being trie-like with particular semantics, an
integral part of the design of the protocol, and the latter just
being nice helper functions around the various hashtables we use.
* device.[ch]: Implementation of functions for the netdevice and for
rtnl, responsible for maintaining the life of a given interface and
wiring it up to the rest of WireGuard.
* peer.[ch]: Each interface has a list of peers, with helper functions
available here for creation, destruction, and reference counting.
* socket.[ch]: Implementation of functions related to udp_socket and
the general set of kernel socket APIs, for sending and receiving
ciphertext UDP packets, and taking care of WireGuard-specific sticky
socket routing semantics for the automatic roaming.
* netlink.[ch]: Userspace API entry point for configuring WireGuard
peers and devices. The API has been implemented by several userspace
tools and network management utility, and the WireGuard project
distributes the basic wg(8) tool.
* queueing.[ch]: Shared function on the rx and tx path for handling
the various queues used in the multicore algorithms.
* send.c: Handles encrypting outgoing packets in parallel on
multiple cores, before sending them in order on a single core, via
workqueues and ring buffers. Also handles sending handshake and cookie
messages as part of the protocol, in parallel.
* receive.c: Handles decrypting incoming packets in parallel on
multiple cores, before passing them off in order to be ingested via
the rest of the networking subsystem with GRO via the typical NAPI
poll function. Also handles receiving handshake and cookie messages
as part of the protocol, in parallel.
* timers.[ch]: Uses the timer wheel to implement protocol particular
event timeouts, and gives a set of very simple event-driven entry
point functions for callers.
* main.c, version.h: Initialization and deinitialization of the module.
* selftest/*.h: Runtime unit tests for some of the most security
sensitive functions.
* tools/testing/selftests/wireguard/netns.sh: Aforementioned testing
script using network namespaces.
This commit aims to be as self-contained as possible, implementing
WireGuard as a standalone module not needing much special handling or
coordination from the network subsystem. I expect for future
optimizations to the network stack to positively improve WireGuard, and
vice-versa, but for the time being, this exists as intentionally
standalone.
We introduce a menu option for CONFIG_WIREGUARD, as well as providing a
verbose debug log and self-tests via CONFIG_WIREGUARD_DEBUG.
Signed-off-by: Jason A. Donenfeld <Jason@zx2c4.com>
Cc: David Miller <davem@davemloft.net>
Cc: Greg KH <gregkh@linuxfoundation.org>
Cc: Linus Torvalds <torvalds@linux-foundation.org>
Cc: Herbert Xu <herbert@gondor.apana.org.au>
Cc: linux-crypto@vger.kernel.org
Cc: linux-kernel@vger.kernel.org
Cc: netdev@vger.kernel.org
Signed-off-by: David S. Miller <davem@davemloft.net>