Re: [PATCH] kernel panic, pty.c: remove direct call to tty_wakupin pty_write

From: Dean Jenkins
Date: Tue Jul 02 2013 - 11:31:22 EST

On 02/07/13 12:02, Andre Naujoks wrote:
On 02.07.2013 11:39, schrieb Dean Jenkins:
On 01/07/13 15:49, Andre Naujoks wrote:
Hello.

This patch removes the direct call to tty_wakeup in pty_write. I have
not noticed any drawbacks with this but I am not familiar with the pty
driver at all. I think what happens is a recursive loop,
write_wakeup->write->write_wakeup ...
Indeed there is a recursive loop that I have witnessed whilst using SLIP
over USB HID.

In the failure case for SLIP, xleft remains positive and recursion
causes a stack overflow as xleft is not updated during the recursion:
sl_encaps()-->pty_write()-->tty_wakeup()-->slip_write_wakeup()-->pty_write()-->tty_wakeup()-->slip_write_wakeup()
etc.
The funny thing about the SLIP driver is, that I could not reproduce
this particular issue with it. The SLIP driver would just hang after a
second of high load but never crash the kernel for me. It may be,
because I used a network connection with socat, which is fast enough for
the data to go through after a few recursions.
In my case, failure occurred because the xleft variable remained positive at the end of the call to sl_encaps(). Normally, xleft is zero upon leaving sl_encaps() because only a single write per SLIP frame to PTY/TTY is necessary to write the whole frame to the TTY layer. In other words, xleft is NOT initialised to zero on the transmission of the next SLIP frame; xleft is normally zero because the previous SLIP was sent OK. Therefore, the kernel crashes on the transmission of the next SLIP frame after a failure to send a complete SLIP frame.

You can trigger the recursion crash by hard-coding xleft to a positive value before exiting sl_encaps(). This simulates a failure to send the complete SLIP frame perhaps due a kmalloc failure in the TTY buffer allocation and therefore is a rare event.

Note some TTY layers such as Bluetooth's RFCOMM TTY consumes all the SLIP frame characters in a single write from sl_encaps() or RFCOMM TTY returns an error code (not handled by SLIP so is another defect in SLIP). In other words, some TTY layers do not use the segmentation mechanism of multiple calls to pty_write() via the TTY wakeup mechanism.
The underlying issue being pty_write() calling tty_wakeup() within the
initial write thread. Note that the TTY wakeup event uses tty_wakeup()
as a callback to request more data.
The documentation for the tty interface forbids this direct call:

(from Documentation/serial/tty.txt)
write_wakeup() - May be called at any point between open and close.
The TTY_DO_WRITE_WAKEUP flag indicates if a call
is needed but always races versus calls. Thus the
ldisc must be careful about setting order and to
handle unexpected calls. Must not sleep.

The driver is forbidden from calling this directly
from the ->write call from the ldisc as the ldisc
is permitted to call the driver write method from
this function. In such a situation defer it.
I also saw that documentation and the code seems to be breaking that
description.

It is possible to mitigate against
pty-write-->tty_wakeup()-->slip_write_wakeup() by clearing and setting
TTY_DO_WRITE_WAKEUP at the "correct" time in the layers bound to
PTY/TTY. Indeed, I modified SLIP to do that and sent patches to the
linux-netdev mailing list although I am not aware of any progress in
having those patches accepted.
See below, why I don't think, that that is a good idea.

Perhaps this mitigation could be applied to your scenario ?

Eventually, your patch could be used when all protocols have mitigration
in place.


The direct call caused a reproducable kernel panic (see bottom of this
mail) for me with the following setup:

- using can-utils from git://gitorious.org/linux-can/can-utils.git
slcan_attach and cangen are used

- create a network link between two serial CAN interfaces with:
$ socat PTY,link=/tmp/slcan0,raw TCP4-LISTEN:50000 &
$ socat TCP4:localhost:50000 PTY,link=/tmp/slcan1,raw &
$ slcan_attach /tmp/slcan0
$ slcan_attach /tmp/slcan1
$ ip link set slcan0 up
$ ip link set slcan1 up

- produce a kernel panic by overloading the CAN interfaces:
$ cangen slcan0 -g0


Please keep me in CC. I am not subscribed to the list.
If I can provide any more information, I will be glad to do so.

This is the patch. It applies to the current linux master branch:


From 9f67139bebb938026406a66c1411e0b50628a238 Mon Sep 17 00:00:00 2001
From: Andre Naujoks <nautsch2@xxxxxxxxxxxxxx>
Date: Mon, 1 Jul 2013 15:45:13 +0200
Subject: [PATCH 1/2] remove direct call to tty_wakeup in pty_write.

Signed-off-by: Andre Naujoks <nautsch2@xxxxxxxxxxxxxx>
---
drivers/tty/pty.c | 1 -
1 file changed, 1 deletion(-)

diff --git a/drivers/tty/pty.c b/drivers/tty/pty.c
index abfd990..5dcb782 100644
--- a/drivers/tty/pty.c
+++ b/drivers/tty/pty.c
@@ -127,7 +127,6 @@ static int pty_write(struct tty_struct *tty, const
unsigned char *buf, int c)
/* And shovel */
if (c) {
tty_flip_buffer_push(to->port);
- tty_wakeup(tty);
}
}
return c;
I agree that this looks to be a simple remedy to the issue. However,
this code has existed in this state for many years so there is a risk
that some applications rely on this "feature" in order to work. For
example, SLIP uses this "feature" although I am not certain that the
existing SLIP code would break if your patch were applied. The TTY
wakeup event should take care of completing the transmission (in theory).
The SLIP driver doesn't break. It is actually more stable and does not
hang for me any more with high loads.

For example this hangs for me after a second or two over a
slip-pty-socat connection without the fix:

machineA$ netcat -l -p 60000
machineB$ cat /dev/zero | netcat <machineA-ip> 60000

With the fix, it does not hang any more.


I am currently using this patch and it "just works". I agree, that this
should probably be tested by some more people which are likely to be
affected by this.
My patches work in a similar way be manipulating TTY_DO_WRITE_WAKEUP to prevent pty_write() calling the wakeup function pointer within sl_encaps().

I'd really like a comment from Greg Kroah-Hartman or Jiri Slaby on this,
because they are the maintainers for the pty driver and probably know
about any implications of this.

I think a lower risk approach would be to modify the upper layers in the
protocol write function to clear the TTY_DO_WRITE_WAKEUP flag before
pty_write is called and set TTY_DO_WRITE_WAKEUP afterwards to allow the
TTY wakeup event to complete the transmission. I did this in the SLIP
Does this cause a race? What if the callback is defered and we have not
re-set the flag yet, when it should be called?
I do not think there is a race with my solution. I will forward my patches to the linux-kernel mailing list so you can see.

The race is worse at the moment because both sl_encaps() and the TTY wakeup event can call the tty_wakeup() function and therefore potentially calls the function pointer to execute slip_write_wakeup() at the same time on 2 CPUs. In the current code there is a risk that slip_write_wakeup() runs concurrently with itself.

The wakup function is called even with the direct call removed,
otherwise the slcan and the slip drivers would no longer work, it is
just defered as required by the documentation.

I think there is no way around fixing the pty driver. All workarounds I
could think of (including disabling the callback for the duration of the
write inside the callback) are somehow broken.

sl_encaps() and slip_write_wakeup() functions. Note that the SLIP
segmentation mechanism is also broken as it is possible to send
truncated SLIP frames upon a failure to send all characters of the
Is that really a problem? The SLIP driver (and the slcan driver) stops
the netif queue before entering sl_encaps and wakes it up again, when
all data is transmitted (from the wakup call), doesn't it? So there
should be not further calls to sl_xmit while the queue is stopped. But I
might misunderstand the semantics of netif_stop_queue and
netif_wake_queue here.
The problem is that xleft remembers the state from the previous SLIP frame rather than set to zero for the new SLIP frame. Yes, the netif queue mechanism provides locking but the lock will be prematurely cleared in slip_write_wakeup() when the SLIP frame fails to be fully sent because slip_write_wakeup() first uses the xleft value from the previous SLIP frame eg. zero.


Regards
Andre

frame. This leads to the recursive loop on the transmission of next SLIP
frame because xleft remains positive (uninitialised) and this causes the
kernel to crash catastrophically. The scheduler crashes due to the stack
overflow overwriting the task data structures.

If anyone is interested, I could upload my SLIP patches to the
linux-kernel mailing list.
Regards,
Dean Jenkins
Mentor Graphics
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