From 399644e47874bff147afb19c89228901ac39340e Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Mon, 15 Apr 2024 21:40:15 +0200 Subject: Adding upstream version 6.05.01. Signed-off-by: Daniel Baumann --- man2/seccomp_unotify.2 | 2011 ++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2011 insertions(+) create mode 100644 man2/seccomp_unotify.2 (limited to 'man2/seccomp_unotify.2') diff --git a/man2/seccomp_unotify.2 b/man2/seccomp_unotify.2 new file mode 100644 index 0000000..156fbce --- /dev/null +++ b/man2/seccomp_unotify.2 @@ -0,0 +1,2011 @@ +.\" Copyright (C) 2020 Michael Kerrisk +.\" +.\" SPDX-License-Identifier: Linux-man-pages-copyleft +.\" +.TH seccomp_unotify 2 2023-05-03 "Linux man-pages 6.05.01" +.SH NAME +seccomp_unotify \- Seccomp user-space notification mechanism +.SH LIBRARY +Standard C library +.RI ( libc ", " \-lc ) +.SH SYNOPSIS +.nf +.B #include +.B #include +.B #include +.PP +.BI "int seccomp(unsigned int " operation ", unsigned int " flags \ +", void *" args ); +.PP +.B #include +.PP +.BI "int ioctl(int " fd ", SECCOMP_IOCTL_NOTIF_RECV," +.BI " struct seccomp_notif *" req ); +.BI "int ioctl(int " fd ", SECCOMP_IOCTL_NOTIF_SEND," +.BI " struct seccomp_notif_resp *" resp ); +.BI "int ioctl(int " fd ", SECCOMP_IOCTL_NOTIF_ID_VALID, __u64 *" id ); +.BI "int ioctl(int " fd ", SECCOMP_IOCTL_NOTIF_ADDFD," +.BI " struct seccomp_notif_addfd *" addfd ); +.fi +.SH DESCRIPTION +This page describes the user-space notification mechanism provided by the +Secure Computing (seccomp) facility. +As well as the use of the +.B SECCOMP_FILTER_FLAG_NEW_LISTENER +flag, the +.B SECCOMP_RET_USER_NOTIF +action value, and the +.B SECCOMP_GET_NOTIF_SIZES +operation described in +.BR seccomp (2), +this mechanism involves the use of a number of related +.BR ioctl (2) +operations (described below). +.\" +.SS Overview +In conventional usage of a seccomp filter, +the decision about how to treat a system call is made by the filter itself. +By contrast, the user-space notification mechanism allows +the seccomp filter to delegate +the handling of the system call to another user-space process. +Note that this mechanism is explicitly +.B not +intended as a method implementing security policy; see NOTES. +.PP +In the discussion that follows, +the thread(s) on which the seccomp filter is installed is (are) +referred to as the +.IR target , +and the process that is notified by the user-space notification +mechanism is referred to as the +.IR supervisor . +.PP +A suitably privileged supervisor can use the user-space notification +mechanism to perform actions on behalf of the target. +The advantage of the user-space notification mechanism is that +the supervisor will +usually be able to retrieve information about the target and the +performed system call that the seccomp filter itself cannot. +(A seccomp filter is limited in the information it can obtain and +the actions that it can perform because it +is running on a virtual machine inside the kernel.) +.PP +An overview of the steps performed by the target and the supervisor +is as follows: +.\"------------------------------------- +.IP (1) 5 +The target establishes a seccomp filter in the usual manner, +but with two differences: +.RS +.IP \[bu] 3 +The +.BR seccomp (2) +.I flags +argument includes the flag +.BR SECCOMP_FILTER_FLAG_NEW_LISTENER . +Consequently, the return value of the (successful) +.BR seccomp (2) +call is a new "listening" +file descriptor that can be used to receive notifications. +Only one "listening" seccomp filter can be installed for a thread. +.\" FIXME +.\" Is the last sentence above correct? +.\" +.\" Kees Cook (25 Oct 2020) notes: +.\" +.\" I like this limitation, but I expect that it'll need to change in the +.\" future. Even with LSMs, we see the need for arbitrary stacking, and the +.\" idea of there being only 1 supervisor will eventually break down. Right +.\" now there is only 1 because only container managers are using this +.\" feature. But if some daemon starts using it to isolate some thread, +.\" suddenly it might break if a container manager is trying to listen to it +.\" too, etc. I expect it won't be needed soon, but I do think it'll change. +.\" +.IP \[bu] +In cases where it is appropriate, the seccomp filter returns the action value +.BR SECCOMP_RET_USER_NOTIF . +This return value will trigger a notification event. +.RE +.\"------------------------------------- +.IP (2) +In order that the supervisor can obtain notifications +using the listening file descriptor, +(a duplicate of) that file descriptor must be passed from +the target to the supervisor. +One way in which this could be done is by passing the file descriptor +over a UNIX domain socket connection between the target and the supervisor +(using the +.B SCM_RIGHTS +ancillary message type described in +.BR unix (7)). +Another way to do this is through the use of +.BR pidfd_getfd (2). +.\" Jann Horn: +.\" Instead of using unix domain sockets to send the fd to the +.\" parent, I think you could also use clone3() with +.\" flags==CLONE_FILES|SIGCHLD, dup2() the seccomp fd to an fd +.\" that was reserved in the parent, call unshare(CLONE_FILES) +.\" in the child after setting up the seccomp fd, and wake +.\" up the parent with something like pthread_cond_signal()? +.\" I'm not sure whether that'd look better or worse in the +.\" end though, so maybe just ignore this comment. +.\"------------------------------------- +.IP (3) +The supervisor will receive notification events +on the listening file descriptor. +These events are returned as structures of type +.IR seccomp_notif . +Because this structure and its size may evolve over kernel versions, +the supervisor must first determine the size of this structure +using the +.BR seccomp (2) +.B SECCOMP_GET_NOTIF_SIZES +operation, which returns a structure of type +.IR seccomp_notif_sizes . +The supervisor allocates a buffer of size +.I seccomp_notif_sizes.seccomp_notif +bytes to receive notification events. +In addition,the supervisor allocates another buffer of size +.I seccomp_notif_sizes.seccomp_notif_resp +bytes for the response (a +.I struct seccomp_notif_resp +structure) +that it will provide to the kernel (and thus the target). +.\"------------------------------------- +.IP (4) +The target then performs its workload, +which includes system calls that will be controlled by the seccomp filter. +Whenever one of these system calls causes the filter to return the +.B SECCOMP_RET_USER_NOTIF +action value, the kernel does +.I not +(yet) execute the system call; +instead, execution of the target is temporarily blocked inside +the kernel (in a sleep state that is interruptible by signals) +and a notification event is generated on the listening file descriptor. +.\"------------------------------------- +.IP (5) +The supervisor can now repeatedly monitor the +listening file descriptor for +.BR SECCOMP_RET_USER_NOTIF -triggered +events. +To do this, the supervisor uses the +.B SECCOMP_IOCTL_NOTIF_RECV +.BR ioctl (2) +operation to read information about a notification event; +this operation blocks until an event is available. +The operation returns a +.I seccomp_notif +structure containing information about the system call +that is being attempted by the target. +(As described in NOTES, +the file descriptor can also be monitored with +.BR select (2), +.BR poll (2), +or +.BR epoll (7).) +.\" FIXME +.\" Christian Brauner: +.\" +.\" Do we support O_NONBLOCK with SECCOMP_IOCTL_NOTIF_RECV and if +.\" not should we? +.\" +.\" Michael Kerrisk: +.\" +.\" A quick test suggests that O_NONBLOCK has no effect on the blocking +.\" behavior of SECCOMP_IOCTL_NOTIF_RECV. +. +.\"------------------------------------- +.IP (6) +The +.I seccomp_notif +structure returned by the +.B SECCOMP_IOCTL_NOTIF_RECV +operation includes the same information (a +.I seccomp_data +structure) that was passed to the seccomp filter. +This information allows the supervisor to discover the system call number and +the arguments for the target's system call. +In addition, the notification event contains the ID of the thread +that triggered the notification and a unique cookie value that +is used in subsequent +.B SECCOMP_IOCTL_NOTIF_ID_VALID +and +.B SECCOMP_IOCTL_NOTIF_SEND +operations. +.IP +The information in the notification can be used to discover the +values of pointer arguments for the target's system call. +(This is something that can't be done from within a seccomp filter.) +One way in which the supervisor can do this is to open the corresponding +.IR /proc/ tid /mem +file (see +.BR proc (5)) +and read bytes from the location that corresponds to one of +the pointer arguments whose value is supplied in the notification event. +.\" Tycho Andersen mentioned that there are alternatives to /proc/PID/mem, +.\" such as ptrace() and /proc/PID/map_files +(The supervisor must be careful to avoid +a race condition that can occur when doing this; +see the description of the +.B SECCOMP_IOCTL_NOTIF_ID_VALID +.BR ioctl (2) +operation below.) +In addition, +the supervisor can access other system information that is visible +in user space but which is not accessible from a seccomp filter. +.\"------------------------------------- +.IP (7) +Having obtained information as per the previous step, +the supervisor may then choose to perform an action in response +to the target's system call +(which, as noted above, is not executed when the seccomp filter returns the +.B SECCOMP_RET_USER_NOTIF +action value). +.IP +One example use case here relates to containers. +The target may be located inside a container where +it does not have sufficient capabilities to mount a filesystem +in the container's mount namespace. +However, the supervisor may be a more privileged process that +does have sufficient capabilities to perform the mount operation. +.\"------------------------------------- +.IP (8) +The supervisor then sends a response to the notification. +The information in this response is used by the kernel to construct +a return value for the target's system call and provide +a value that will be assigned to the +.I errno +variable of the target. +.IP +The response is sent using the +.B SECCOMP_IOCTL_NOTIF_SEND +.BR ioctl (2) +operation, which is used to transmit a +.I seccomp_notif_resp +structure to the kernel. +This structure includes a cookie value that the supervisor obtained in the +.I seccomp_notif +structure returned by the +.B SECCOMP_IOCTL_NOTIF_RECV +operation. +This cookie value allows the kernel to associate the response with the +target. +This structure must include the cookie value that the supervisor +obtained in the +.I seccomp_notif +structure returned by the +.B SECCOMP_IOCTL_NOTIF_RECV +operation; +the cookie allows the kernel to associate the response with the target. +.\"------------------------------------- +.IP (9) +Once the notification has been sent, +the system call in the target thread unblocks, +returning the information that was provided by the supervisor +in the notification response. +.\"------------------------------------- +.PP +As a variation on the last two steps, +the supervisor can send a response that tells the kernel that it +should execute the target thread's system call; see the discussion of +.BR SECCOMP_USER_NOTIF_FLAG_CONTINUE , +below. +.\" +.SH IOCTL OPERATIONS +The following +.BR ioctl (2) +operations are supported by the seccomp user-space +notification file descriptor. +For each of these operations, the first (file descriptor) argument of +.BR ioctl (2) +is the listening file descriptor returned by a call to +.BR seccomp (2) +with the +.B SECCOMP_FILTER_FLAG_NEW_LISTENER +flag. +.\" +.SS SECCOMP_IOCTL_NOTIF_RECV +The +.B SECCOMP_IOCTL_NOTIF_RECV +operation (available since Linux 5.0) is used to obtain a user-space +notification event. +If no such event is currently pending, +the operation blocks until an event occurs. +The third +.BR ioctl (2) +argument is a pointer to a structure of the following form +which contains information about the event. +This structure must be zeroed out before the call. +.PP +.in +4n +.EX +struct seccomp_notif { + __u64 id; /* Cookie */ + __u32 pid; /* TID of target thread */ + __u32 flags; /* Currently unused (0) */ + struct seccomp_data data; /* See seccomp(2) */ +}; +.EE +.in +.PP +The fields in this structure are as follows: +.TP +.I id +This is a cookie for the notification. +Each such cookie is guaranteed to be unique for the corresponding +seccomp filter. +.RS +.IP \[bu] 3 +The cookie can be used with the +.B SECCOMP_IOCTL_NOTIF_ID_VALID +.BR ioctl (2) +operation described below. +.IP \[bu] +When returning a notification response to the kernel, +the supervisor must include the cookie value in the +.I seccomp_notif_resp +structure that is specified as the argument of the +.B SECCOMP_IOCTL_NOTIF_SEND +operation. +.RE +.TP +.I pid +This is the thread ID of the target thread that triggered +the notification event. +.TP +.I flags +This is a bit mask of flags providing further information on the event. +In the current implementation, this field is always zero. +.TP +.I data +This is a +.I seccomp_data +structure containing information about the system call that +triggered the notification. +This is the same structure that is passed to the seccomp filter. +See +.BR seccomp (2) +for details of this structure. +.PP +On success, this operation returns 0; on failure, \-1 is returned, and +.I errno +is set to indicate the cause of the error. +This operation can fail with the following errors: +.TP +.BR EINVAL " (since Linux 5.5)" +.\" commit 2882d53c9c6f3b8311d225062522f03772cf0179 +The +.I seccomp_notif +structure that was passed to the call contained nonzero fields. +.TP +.B ENOENT +The target thread was killed by a signal as the notification information +was being generated, +or the target's (blocked) system call was interrupted by a signal handler. +.\" FIXME +.\" From my experiments, +.\" it appears that if a SECCOMP_IOCTL_NOTIF_RECV is done after +.\" the target thread terminates, then the ioctl() simply +.\" blocks (rather than returning an error to indicate that the +.\" target no longer exists). +.\" +.\" I found that surprising, and it required some contortions in +.\" the example program. It was not possible to code my SIGCHLD +.\" handler (which reaps the zombie when the worker/target +.\" terminates) to simply set a flag checked in the main +.\" handleNotifications() loop, since this created an +.\" unavoidable race where the child might terminate just after +.\" I had checked the flag, but before I blocked (forever!) in the +.\" SECCOMP_IOCTL_NOTIF_RECV operation. Instead, I had to code +.\" the signal handler to simply call _exit(2) in order to +.\" terminate the parent process (the supervisor). +.\" +.\" Is this expected behavior? It seems to me rather +.\" desirable that SECCOMP_IOCTL_NOTIF_RECV should give an error +.\" if the target has terminated. +.\" +.\" Jann posted a patch to rectify this, but there was no response +.\" (Lore link: https://bit.ly/3jvUBxk) to his question about fixing +.\" this issue. (I've tried building with the patch, but encountered +.\" an issue with the target process entering D state after a signal.) +.\" +.\" For now, this behavior is documented in BUGS. +.\" +.\" Kees Cook commented: Let's change [this] ASAP! +.\" +.SS SECCOMP_IOCTL_NOTIF_ID_VALID +The +.B SECCOMP_IOCTL_NOTIF_ID_VALID +operation (available since Linux 5.0) is used to check that a notification ID +returned by an earlier +.B SECCOMP_IOCTL_NOTIF_RECV +operation is still valid +(i.e., that the target still exists and its system call +is still blocked waiting for a response). +.PP +The third +.BR ioctl (2) +argument is a pointer to the cookie +.RI ( id ) +returned by the +.B SECCOMP_IOCTL_NOTIF_RECV +operation. +.PP +This operation is necessary to avoid race conditions that can occur when the +.I pid +returned by the +.B SECCOMP_IOCTL_NOTIF_RECV +operation terminates, and that process ID is reused by another process. +An example of this kind of race is the following +.IP (1) 5 +A notification is generated on the listening file descriptor. +The returned +.I seccomp_notif +contains the TID of the target thread (in the +.I pid +field of the structure). +.IP (2) +The target terminates. +.IP (3) +Another thread or process is created on the system that by chance reuses the +TID that was freed when the target terminated. +.IP (4) +The supervisor +.BR open (2)s +the +.IR /proc/ tid /mem +file for the TID obtained in step 1, with the intention of (say) +inspecting the memory location(s) that containing the argument(s) of +the system call that triggered the notification in step 1. +.PP +In the above scenario, the risk is that the supervisor may try +to access the memory of a process other than the target. +This race can be avoided by following the call to +.BR open (2) +with a +.B SECCOMP_IOCTL_NOTIF_ID_VALID +operation to verify that the process that generated the notification +is still alive. +(Note that if the target terminates after the latter step, +a subsequent +.BR read (2) +from the file descriptor may return 0, indicating end of file.) +.\" Jann Horn: +.\" the PID can be reused, but the /proc/$pid directory is +.\" internally not associated with the numeric PID, but, +.\" conceptually speaking, with a specific incarnation of the +.\" PID, or something like that. (Actually, it is associated +.\" with the "struct pid", which is not reused, instead of the +.\" numeric PID. +.PP +See NOTES for a discussion of other cases where +.B SECCOMP_IOCTL_NOTIF_ID_VALID +checks must be performed. +.PP +On success (i.e., the notification ID is still valid), +this operation returns 0. +On failure (i.e., the notification ID is no longer valid), +\-1 is returned, and +.I errno +is set to +.BR ENOENT . +.\" +.SS SECCOMP_IOCTL_NOTIF_SEND +The +.B SECCOMP_IOCTL_NOTIF_SEND +operation (available since Linux 5.0) +is used to send a notification response back to the kernel. +The third +.BR ioctl (2) +argument of this structure is a pointer to a structure of the following form: +.PP +.in +4n +.EX +struct seccomp_notif_resp { + __u64 id; /* Cookie value */ + __s64 val; /* Success return value */ + __s32 error; /* 0 (success) or negative error number */ + __u32 flags; /* See below */ +}; +.EE +.in +.PP +The fields of this structure are as follows: +.TP +.I id +This is the cookie value that was obtained using the +.B SECCOMP_IOCTL_NOTIF_RECV +operation. +This cookie value allows the kernel to correctly associate this response +with the system call that triggered the user-space notification. +.TP +.I val +This is the value that will be used for a spoofed +success return for the target's system call; see below. +.TP +.I error +This is the value that will be used as the error number +.RI ( errno ) +for a spoofed error return for the target's system call; see below. +.TP +.I flags +This is a bit mask that includes zero or more of the following flags: +.RS +.TP +.BR SECCOMP_USER_NOTIF_FLAG_CONTINUE " (since Linux 5.5)" +Tell the kernel to execute the target's system call. +.\" commit fb3c5386b382d4097476ce9647260fc89b34afdb +.RE +.PP +Two kinds of response are possible: +.IP \[bu] 3 +A response to the kernel telling it to execute the +target's system call. +In this case, the +.I flags +field includes +.B SECCOMP_USER_NOTIF_FLAG_CONTINUE +and the +.I error +and +.I val +fields must be zero. +.IP +This kind of response can be useful in cases where the supervisor needs +to do deeper analysis of the target's system call than is possible +from a seccomp filter (e.g., examining the values of pointer arguments), +and, having decided that the system call does not require emulation +by the supervisor, the supervisor wants the system call to +be executed normally in the target. +.IP +The +.B SECCOMP_USER_NOTIF_FLAG_CONTINUE +flag should be used with caution; see NOTES. +.IP \[bu] +A spoofed return value for the target's system call. +In this case, the kernel does not execute the target's system call, +instead causing the system call to return a spoofed value as specified by +fields of the +.I seccomp_notif_resp +structure. +The supervisor should set the fields of this structure as follows: +.RS +.IP + 3 +.I flags +does not contain +.BR SECCOMP_USER_NOTIF_FLAG_CONTINUE . +.IP + +.I error +is set either to 0 for a spoofed "success" return or to a negative +error number for a spoofed "failure" return. +In the former case, the kernel causes the target's system call +to return the value specified in the +.I val +field. +In the latter case, the kernel causes the target's system call +to return \-1, and +.I errno +is assigned the negated +.I error +value. +.IP + +.I val +is set to a value that will be used as the return value for a spoofed +"success" return for the target's system call. +The value in this field is ignored if the +.I error +field contains a nonzero value. +.\" FIXME +.\" Kees Cook suggested: +.\" +.\" Strictly speaking, this is architecture specific, but +.\" all architectures do it this way. Should seccomp enforce +.\" val == 0 when err != 0 ? +.\" +.\" Christian Brauner +.\" +.\" Feels like it should, at least for the SEND ioctl where we already +.\" verify that val and err are both 0 when CONTINUE is specified (as you +.\" pointed out correctly above). +.RE +.PP +On success, this operation returns 0; on failure, \-1 is returned, and +.I errno +is set to indicate the cause of the error. +This operation can fail with the following errors: +.TP +.B EINPROGRESS +A response to this notification has already been sent. +.TP +.B EINVAL +An invalid value was specified in the +.I flags field. +.TP +.B +.B EINVAL +The +.I flags +field contained +.BR SECCOMP_USER_NOTIF_FLAG_CONTINUE , +and the +.I error +or +.I val +field was not zero. +.TP +.B ENOENT +The blocked system call in the target +has been interrupted by a signal handler +or the target has terminated. +.\" Jann Horn notes: +.\" you could also get this [ENOENT] if a response has already +.\" been sent, instead of EINPROGRESS - the only difference is +.\" whether the target thread has picked up the response yet +.\" +.SS SECCOMP_IOCTL_NOTIF_ADDFD +The +.B SECCOMP_IOCTL_NOTIF_ADDFD +operation (available since Linux 5.9) +allows the supervisor to install a file descriptor +into the target's file descriptor table. +Much like the use of +.B SCM_RIGHTS +messages described in +.BR unix (7), +this operation is semantically equivalent to duplicating +a file descriptor from the supervisor's file descriptor table +into the target's file descriptor table. +.PP +The +.B SECCOMP_IOCTL_NOTIF_ADDFD +operation permits the supervisor to emulate a target system call (such as +.BR socket (2) +or +.BR openat (2)) +that generates a file descriptor. +The supervisor can perform the system call that generates +the file descriptor (and associated open file description) +and then use this operation to allocate +a file descriptor that refers to the same open file description in the target. +(For an explanation of open file descriptions, see +.BR open (2).) +.PP +Once this operation has been performed, +the supervisor can close its copy of the file descriptor. +.PP +In the target, +the received file descriptor is subject to the same +Linux Security Module (LSM) checks as are applied to a file descriptor +that is received in an +.B SCM_RIGHTS +ancillary message. +If the file descriptor refers to a socket, +it inherits the cgroup version 1 network controller settings +.RI ( classid +and +.IR netprioidx ) +of the target. +.PP +The third +.BR ioctl (2) +argument is a pointer to a structure of the following form: +.PP +.in +4n +.EX +struct seccomp_notif_addfd { + __u64 id; /* Cookie value */ + __u32 flags; /* Flags */ + __u32 srcfd; /* Local file descriptor number */ + __u32 newfd; /* 0 or desired file descriptor + number in target */ + __u32 newfd_flags; /* Flags to set on target file + descriptor */ +}; +.EE +.in +.PP +The fields in this structure are as follows: +.TP +.I id +This field should be set to the notification ID +(cookie value) that was obtained via +.BR SECCOMP_IOCTL_NOTIF_RECV . +.TP +.I flags +This field is a bit mask of flags that modify the behavior of the operation. +Currently, only one flag is supported: +.RS +.TP +.B SECCOMP_ADDFD_FLAG_SETFD +When allocating the file descriptor in the target, +use the file descriptor number specified in the +.I newfd +field. +.TP +.BR SECCOMP_ADDFD_FLAG_SEND " (since Linux 5.14)" +.\" commit 0ae71c7720e3ae3aabd2e8a072d27f7bd173d25c +Perform the equivalent of +.B SECCOMP_IOCTL_NOTIF_ADDFD +plus +.B SECCOMP_IOCTL_NOTIF_SEND +as an atomic operation. +On successful invocation, the target process's +.I errno +will be 0 +and the return value will be the file descriptor number +that was allocated in the target. +If allocating the file descriptor in the target fails, +the target's system call continues to be blocked +until a successful response is sent. +.RE +.TP +.I srcfd +This field should be set to the number of the file descriptor +in the supervisor that is to be duplicated. +.TP +.I newfd +This field determines which file descriptor number is allocated in the target. +If the +.B SECCOMP_ADDFD_FLAG_SETFD +flag is set, +then this field specifies which file descriptor number should be allocated. +If this file descriptor number is already open in the target, +it is atomically closed and reused. +If the descriptor duplication fails due to an LSM check, or if +.I srcfd +is not a valid file descriptor, +the file descriptor +.I newfd +will not be closed in the target process. +.IP +If the +.B SECCOMP_ADDFD_FLAG_SETFD +flag it not set, then this field must be 0, +and the kernel allocates the lowest unused file descriptor number +in the target. +.TP +.I newfd_flags +This field is a bit mask specifying flags that should be set on +the file descriptor that is received in the target process. +Currently, only the following flag is implemented: +.RS +.TP +.B O_CLOEXEC +Set the close-on-exec flag on the received file descriptor. +.RE +.PP +On success, this +.BR ioctl (2) +call returns the number of the file descriptor that was allocated +in the target. +Assuming that the emulated system call is one that returns +a file descriptor as its function result (e.g., +.BR socket (2)), +this value can be used as the return value +.RI ( resp.val ) +that is supplied in the response that is subsequently sent with the +.B SECCOMP_IOCTL_NOTIF_SEND +operation. +.PP +On error, \-1 is returned and +.I errno +is set to indicate the cause of the error. +.PP +This operation can fail with the following errors: +.TP +.B EBADF +Allocating the file descriptor in the target would cause the target's +.B RLIMIT_NOFILE +limit to be exceeded (see +.BR getrlimit (2)). +.TP +.B EBUSY +If the flag +.B SECCOMP_IOCTL_NOTIF_SEND +is used, this means the operation can't proceed until other +.B SECCOMP_IOCTL_NOTIF_ADDFD +requests are processed. +.TP +.B EINPROGRESS +The user-space notification specified in the +.I id +field exists but has not yet been fetched (by a +.BR SECCOMP_IOCTL_NOTIF_RECV ) +or has already been responded to (by a +.BR SECCOMP_IOCTL_NOTIF_SEND ). +.TP +.B EINVAL +An invalid flag was specified in the +.I flags +or +.I newfd_flags +field, or the +.I newfd +field is nonzero and the +.B SECCOMP_ADDFD_FLAG_SETFD +flag was not specified in the +.I flags +field. +.TP +.B EMFILE +The file descriptor number specified in +.I newfd +exceeds the limit specified in +.IR /proc/sys/fs/nr_open . +.TP +.B ENOENT +The blocked system call in the target +has been interrupted by a signal handler +or the target has terminated. +.PP +Here is some sample code (with error handling omitted) that uses the +.B SECCOMP_ADDFD_FLAG_SETFD +operation (here, to emulate a call to +.BR openat (2)): +.PP +.EX +.in +4n +int fd, removeFd; +\& +fd = openat(req\->data.args[0], path, req\->data.args[2], + req\->data.args[3]); +\& +struct seccomp_notif_addfd addfd; +addfd.id = req\->id; /* Cookie from SECCOMP_IOCTL_NOTIF_RECV */ +addfd.srcfd = fd; +addfd.newfd = 0; +addfd.flags = 0; +addfd.newfd_flags = O_CLOEXEC; +\& +targetFd = ioctl(notifyFd, SECCOMP_IOCTL_NOTIF_ADDFD, &addfd); +\& +close(fd); /* No longer needed in supervisor */ +\& +struct seccomp_notif_resp *resp; + /* Code to allocate 'resp' omitted */ +resp\->id = req\->id; +resp\->error = 0; /* "Success" */ +resp\->val = targetFd; +resp\->flags = 0; +ioctl(notifyFd, SECCOMP_IOCTL_NOTIF_SEND, resp); +.in +.EE +.SH NOTES +One example use case for the user-space notification +mechanism is to allow a container manager +(a process which is typically running with more privilege than +the processes inside the container) +to mount block devices or create device nodes for the container. +The mount use case provides an example of where the +.B SECCOMP_USER_NOTIF_FLAG_CONTINUE +.BR ioctl (2) +operation is useful. +Upon receiving a notification for the +.BR mount (2) +system call, the container manager (the "supervisor") can distinguish +a request to mount a block filesystem +(which would not be possible for a "target" process inside the container) +and mount that file system. +If, on the other hand, the container manager detects that the operation +could be performed by the process inside the container +(e.g., a mount of a +.BR tmpfs (5) +filesystem), it can notify the kernel that the target process's +.BR mount (2) +system call can continue. +.\" +.SS select()/poll()/epoll semantics +The file descriptor returned when +.BR seccomp (2) +is employed with the +.B SECCOMP_FILTER_FLAG_NEW_LISTENER +flag can be monitored using +.BR poll (2), +.BR epoll (7), +and +.BR select (2). +These interfaces indicate that the file descriptor is ready as follows: +.IP \[bu] 3 +When a notification is pending, +these interfaces indicate that the file descriptor is readable. +Following such an indication, a subsequent +.B SECCOMP_IOCTL_NOTIF_RECV +.BR ioctl (2) +will not block, returning either information about a notification +or else failing with the error +.B EINTR +if the target has been killed by a signal or its system call +has been interrupted by a signal handler. +.IP \[bu] +After the notification has been received (i.e., by the +.B SECCOMP_IOCTL_NOTIF_RECV +.BR ioctl (2) +operation), these interfaces indicate that the file descriptor is writable, +meaning that a notification response can be sent using the +.B SECCOMP_IOCTL_NOTIF_SEND +.BR ioctl (2) +operation. +.IP \[bu] +After the last thread using the filter has terminated and been reaped using +.BR waitpid (2) +(or similar), +the file descriptor indicates an end-of-file condition (readable in +.BR select (2); +.BR POLLHUP / EPOLLHUP +in +.BR poll (2)/ +.BR epoll_wait (2)). +.SS Design goals; use of SECCOMP_USER_NOTIF_FLAG_CONTINUE +The intent of the user-space notification feature is +to allow system calls to be performed on behalf of the target. +The target's system call should either be handled by the supervisor or +allowed to continue normally in the kernel (where standard security +policies will be applied). +.PP +.BR "Note well" : +this mechanism must not be used to make security policy decisions +about the system call, +which would be inherently race-prone for reasons described next. +.PP +The +.B SECCOMP_USER_NOTIF_FLAG_CONTINUE +flag must be used with caution. +If set by the supervisor, the target's system call will continue. +However, there is a time-of-check, time-of-use race here, +since an attacker could exploit the interval of time where the target is +blocked waiting on the "continue" response to do things such as +rewriting the system call arguments. +.PP +Note furthermore that a user-space notifier can be bypassed if +the existing filters allow the use of +.BR seccomp (2) +or +.BR prctl (2) +to install a filter that returns an action value with a higher precedence than +.B SECCOMP_RET_USER_NOTIF +(see +.BR seccomp (2)). +.PP +It should thus be absolutely clear that the +seccomp user-space notification mechanism +.B can not +be used to implement a security policy! +It should only ever be used in scenarios where a more privileged process +supervises the system calls of a lesser privileged target to +get around kernel-enforced security restrictions when +the supervisor deems this safe. +In other words, +in order to continue a system call, the supervisor should be sure that +another security mechanism or the kernel itself will sufficiently block +the system call if its arguments are rewritten to something unsafe. +.\" +.SS Caveats regarding the use of \fI/proc/\fPtid\fI/mem\fP +The discussion above noted the need to use the +.B SECCOMP_IOCTL_NOTIF_ID_VALID +.BR ioctl (2) +when opening the +.IR /proc/ tid /mem +file of the target +to avoid the possibility of accessing the memory of the wrong process +in the event that the target terminates and its ID +is recycled by another (unrelated) thread. +However, the use of this +.BR ioctl (2) +operation is also necessary in other situations, +as explained in the following paragraphs. +.PP +Consider the following scenario, where the supervisor +tries to read the pathname argument of a target's blocked +.BR mount (2) +system call: +.IP (1) 5 +From one of its functions +.RI ( func() ), +the target calls +.BR mount (2), +which triggers a user-space notification and causes the target to block. +.IP (2) +The supervisor receives the notification, opens +.IR /proc/ tid /mem , +and (successfully) performs the +.B SECCOMP_IOCTL_NOTIF_ID_VALID +check. +.IP (3) +The target receives a signal, which causes the +.BR mount (2) +to abort. +.IP (4) +The signal handler executes in the target, and returns. +.IP (5) +Upon return from the handler, the execution of +.I func() +resumes, and it returns (and perhaps other functions are called, +overwriting the memory that had been used for the stack frame of +.IR func() ). +.IP (6) +Using the address provided in the notification information, +the supervisor reads from the target's memory location that used to +contain the pathname. +.IP (7) +The supervisor now calls +.BR mount (2) +with some arbitrary bytes obtained in the previous step. +.PP +The conclusion from the above scenario is this: +since the target's blocked system call may be interrupted by a signal handler, +the supervisor must be written to expect that the +target may abandon its system call at +.B any +time; +in such an event, any information that the supervisor obtained from +the target's memory must be considered invalid. +.PP +To prevent such scenarios, +every read from the target's memory must be separated from use of +the bytes so obtained by a +.B SECCOMP_IOCTL_NOTIF_ID_VALID +check. +In the above example, the check would be placed between the two final steps. +An example of such a check is shown in EXAMPLES. +.PP +Following on from the above, it should be clear that +a write by the supervisor into the target's memory can +.B never +be considered safe. +.\" +.SS Caveats regarding blocking system calls +Suppose that the target performs a blocking system call (e.g., +.BR accept (2)) +that the supervisor should handle. +The supervisor might then in turn execute the same blocking system call. +.PP +In this scenario, +it is important to note that if the target's system call is now +interrupted by a signal, the supervisor is +.I not +informed of this. +If the supervisor does not take suitable steps to +actively discover that the target's system call has been canceled, +various difficulties can occur. +Taking the example of +.BR accept (2), +the supervisor might remain blocked in its +.BR accept (2) +holding a port number that the target +(which, after the interruption by the signal handler, +perhaps closed its listening socket) might expect to be able to reuse in a +.BR bind (2) +call. +.PP +Therefore, when the supervisor wishes to emulate a blocking system call, +it must do so in such a way that it gets informed if the target's +system call is interrupted by a signal handler. +For example, if the supervisor itself executes the same +blocking system call, then it could employ a separate thread +that uses the +.B SECCOMP_IOCTL_NOTIF_ID_VALID +operation to check if the target is still blocked in its system call. +Alternatively, in the +.BR accept (2) +example, the supervisor might use +.BR poll (2) +to monitor both the notification file descriptor +(so as to discover when the target's +.BR accept (2) +call has been interrupted) and the listening file descriptor +(so as to know when a connection is available). +.PP +If the target's system call is interrupted, +the supervisor must take care to release resources (e.g., file descriptors) +that it acquired on behalf of the target. +.\" +.SS Interaction with SA_RESTART signal handlers +Consider the following scenario: +.IP (1) 5 +The target process has used +.BR sigaction (2) +to install a signal handler with the +.B SA_RESTART +flag. +.IP (2) +The target has made a system call that triggered a seccomp +user-space notification and the target is currently blocked +until the supervisor sends a notification response. +.IP (3) +A signal is delivered to the target and the signal handler is executed. +.IP (4) +When (if) the supervisor attempts to send a notification response, the +.B SECCOMP_IOCTL_NOTIF_SEND +.BR ioctl (2)) +operation will fail with the +.B ENOENT +error. +.PP +In this scenario, the kernel will restart the target's system call. +Consequently, the supervisor will receive another user-space notification. +Thus, depending on how many times the blocked system call +is interrupted by a signal handler, +the supervisor may receive multiple notifications for +the same instance of a system call in the target. +.PP +One oddity is that system call restarting as described in this scenario +will occur even for the blocking system calls listed in +.BR signal (7) +that would +.B never +normally be restarted by the +.B SA_RESTART +flag. +.\" FIXME +.\" About the above, Kees Cook commented: +.\" +.\" Does this need fixing? I imagine the correct behavior for this case +.\" would be a response to _SEND of EINPROGRESS and the target would see +.\" EINTR normally? +.\" +.\" I mean, it's not like seccomp doesn't already expose weirdness with +.\" syscall restarts. Not even arm64 compat agrees[3] with arm32 in this +.\" regard. :( +. +.\" FIXME +.\" Michael Kerrisk: +.\" I wonder about the effect of this oddity for system calls that +.\" are normally nonrestartable because they have timeouts. My +.\" understanding is that the kernel doesn't restart those system +.\" calls because it's impossible for the kernel to restart the call +.\" with the right timeout value. I wonder what happens when those +.\" system calls are restarted in the scenario we're discussing.) +.PP +Furthermore, if the supervisor response is a file descriptor +added with +.BR SECCOMP_IOCTL_NOTIF_ADDFD , +then the flag +.B SECCOMP_ADDFD_FLAG_SEND +can be used to atomically add the file descriptor and return that value, +making sure no file descriptors are inadvertently leaked into the target. +.SH BUGS +If a +.B SECCOMP_IOCTL_NOTIF_RECV +.BR ioctl (2) +operation +.\" or a poll/epoll/select +is performed after the target terminates, then the +.BR ioctl (2) +call simply blocks (rather than returning an error to indicate that the +target no longer exists). +.\" FIXME +.\" Comment from Kees Cook: +.\" +.\" I want this fixed. It caused me no end of pain when building the +.\" selftests, and ended up spawning my implementing a global test timeout +.\" in kselftest. :P Before the usage counter refactor, there was no sane +.\" way to deal with this, but now I think we're close. +.\" +.SH EXAMPLES +The (somewhat contrived) program shown below demonstrates the use of +the interfaces described in this page. +The program creates a child process that serves as the "target" process. +The child process installs a seccomp filter that returns the +.B SECCOMP_RET_USER_NOTIF +action value if a call is made to +.BR mkdir (2). +The child process then calls +.BR mkdir (2) +once for each of the supplied command-line arguments, +and reports the result returned by the call. +After processing all arguments, the child process terminates. +.PP +The parent process acts as the supervisor, listening for the notifications +that are generated when the target process calls +.BR mkdir (2). +When such a notification occurs, +the supervisor examines the memory of the target process (using +.IR /proc/ pid /mem ) +to discover the pathname argument that was supplied to the +.BR mkdir (2) +call, and performs one of the following actions: +.IP \[bu] 3 +If the pathname begins with the prefix "/tmp/", +then the supervisor attempts to create the specified directory, +and then spoofs a return for the target process based on the return +value of the supervisor's +.BR mkdir (2) +call. +In the event that that call succeeds, +the spoofed success return value is the length of the pathname. +.IP \[bu] +If the pathname begins with "./" (i.e., it is a relative pathname), +the supervisor sends a +.B SECCOMP_USER_NOTIF_FLAG_CONTINUE +response to the kernel to say that the kernel should execute +the target process's +.BR mkdir (2) +call. +.IP \[bu] +If the pathname begins with some other prefix, +the supervisor spoofs an error return for the target process, +so that the target process's +.BR mkdir (2) +call appears to fail with the error +.B EOPNOTSUPP +("Operation not supported"). +Additionally, if the specified pathname is exactly "/bye", +then the supervisor terminates. +.PP +This program can be used to demonstrate various aspects of the +behavior of the seccomp user-space notification mechanism. +To help aid such demonstrations, +the program logs various messages to show the operation +of the target process (lines prefixed "T:") and the supervisor +(indented lines prefixed "S:"). +.PP +In the following example, the target attempts to create the directory +.IR /tmp/x . +Upon receiving the notification, the supervisor creates the directory on the +target's behalf, +and spoofs a success return to be received by the target process's +.BR mkdir (2) +call. +.PP +.in +4n +.EX +$ \fB./seccomp_unotify /tmp/x\fP +T: PID = 23168 +\& +T: about to mkdir("/tmp/x") + S: got notification (ID 0x17445c4a0f4e0e3c) for PID 23168 + S: executing: mkdir("/tmp/x", 0700) + S: success! spoofed return = 6 + S: sending response (flags = 0; val = 6; error = 0) +T: SUCCESS: mkdir(2) returned 6 +\& +T: terminating + S: target has terminated; bye +.EE +.in +.PP +In the above output, note that the spoofed return value seen by the target +process is 6 (the length of the pathname +.IR /tmp/x ), +whereas a normal +.BR mkdir (2) +call returns 0 on success. +.PP +In the next example, the target attempts to create a directory using the +relative pathname +.IR ./sub . +Since this pathname starts with "./", +the supervisor sends a +.B SECCOMP_USER_NOTIF_FLAG_CONTINUE +response to the kernel, +and the kernel then (successfully) executes the target process's +.BR mkdir (2) +call. +.PP +.in +4n +.EX +$ \fB./seccomp_unotify ./sub\fP +T: PID = 23204 +\& +T: about to mkdir("./sub") + S: got notification (ID 0xddb16abe25b4c12) for PID 23204 + S: target can execute system call + S: sending response (flags = 0x1; val = 0; error = 0) +T: SUCCESS: mkdir(2) returned 0 +\& +T: terminating + S: target has terminated; bye +.EE +.in +.PP +If the target process attempts to create a directory with +a pathname that doesn't start with "." and doesn't begin with the prefix +"/tmp/", then the supervisor spoofs an error return +.RB ( EOPNOTSUPP , +"Operation not supported") +for the target's +.BR mkdir (2) +call (which is not executed): +.PP +.in +4n +.EX +$ \fB./seccomp_unotify /xxx\fP +T: PID = 23178 +\& +T: about to mkdir("/xxx") + S: got notification (ID 0xe7dc095d1c524e80) for PID 23178 + S: spoofing error response (Operation not supported) + S: sending response (flags = 0; val = 0; error = \-95) +T: ERROR: mkdir(2): Operation not supported +\& +T: terminating + S: target has terminated; bye +.EE +.in +.PP +In the next example, +the target process attempts to create a directory with the pathname +.BR /tmp/nosuchdir/b . +Upon receiving the notification, +the supervisor attempts to create that directory, but the +.BR mkdir (2) +call fails because the directory +.B /tmp/nosuchdir +does not exist. +Consequently, the supervisor spoofs an error return that passes the error +that it received back to the target process's +.BR mkdir (2) +call. +.PP +.in +4n +.EX +$ \fB./seccomp_unotify /tmp/nosuchdir/b\fP +T: PID = 23199 +\& +T: about to mkdir("/tmp/nosuchdir/b") + S: got notification (ID 0x8744454293506046) for PID 23199 + S: executing: mkdir("/tmp/nosuchdir/b", 0700) + S: failure! (errno = 2; No such file or directory) + S: sending response (flags = 0; val = 0; error = \-2) +T: ERROR: mkdir(2): No such file or directory +\& +T: terminating + S: target has terminated; bye +.EE +.in +.PP +If the supervisor receives a notification and sees that the +argument of the target's +.BR mkdir (2) +is the string "/bye", then (as well as spoofing an +.B EOPNOTSUPP +error), the supervisor terminates. +If the target process subsequently executes another +.BR mkdir (2) +that triggers its seccomp filter to return the +.B SECCOMP_RET_USER_NOTIF +action value, then the kernel causes the target process's system call to +fail with the error +.B ENOSYS +("Function not implemented"). +This is demonstrated by the following example: +.PP +.in +4n +.EX +$ \fB./seccomp_unotify /bye /tmp/y\fP +T: PID = 23185 +\& +T: about to mkdir("/bye") + S: got notification (ID 0xa81236b1d2f7b0f4) for PID 23185 + S: spoofing error response (Operation not supported) + S: sending response (flags = 0; val = 0; error = \-95) + S: terminating ********** +T: ERROR: mkdir(2): Operation not supported +\& +T: about to mkdir("/tmp/y") +T: ERROR: mkdir(2): Function not implemented +\& +T: terminating +.EE +.in +.\" +.SS Program source +.\" SRC BEGIN (seccomp_unotify.c) +.EX +#define _GNU_SOURCE +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +\& +#define ARRAY_SIZE(arr) (sizeof(arr) / sizeof((arr)[0])) +\& +/* Send the file descriptor \[aq]fd\[aq] over the connected UNIX domain socket + \[aq]sockfd\[aq]. Returns 0 on success, or \-1 on error. */ +\& +static int +sendfd(int sockfd, int fd) +{ + int data; + struct iovec iov; + struct msghdr msgh; + struct cmsghdr *cmsgp; +\& + /* Allocate a char array of suitable size to hold the ancillary data. + However, since this buffer is in reality a \[aq]struct cmsghdr\[aq], use a + union to ensure that it is suitably aligned. */ + union { + char buf[CMSG_SPACE(sizeof(int))]; + /* Space large enough to hold an \[aq]int\[aq] */ + struct cmsghdr align; + } controlMsg; +\& + /* The \[aq]msg_name\[aq] field can be used to specify the address of the + destination socket when sending a datagram. However, we do not + need to use this field because \[aq]sockfd\[aq] is a connected socket. */ +\& + msgh.msg_name = NULL; + msgh.msg_namelen = 0; +\& + /* On Linux, we must transmit at least one byte of real data in + order to send ancillary data. We transmit an arbitrary integer + whose value is ignored by recvfd(). */ +\& + msgh.msg_iov = &iov; + msgh.msg_iovlen = 1; + iov.iov_base = &data; + iov.iov_len = sizeof(int); + data = 12345; +\& + /* Set \[aq]msghdr\[aq] fields that describe ancillary data */ +\& + msgh.msg_control = controlMsg.buf; + msgh.msg_controllen = sizeof(controlMsg.buf); +\& + /* Set up ancillary data describing file descriptor to send */ +\& + cmsgp = CMSG_FIRSTHDR(&msgh); + cmsgp\->cmsg_level = SOL_SOCKET; + cmsgp\->cmsg_type = SCM_RIGHTS; + cmsgp\->cmsg_len = CMSG_LEN(sizeof(int)); + memcpy(CMSG_DATA(cmsgp), &fd, sizeof(int)); +\& + /* Send real plus ancillary data */ +\& + if (sendmsg(sockfd, &msgh, 0) == \-1) + return \-1; +\& + return 0; +} +\& +/* Receive a file descriptor on a connected UNIX domain socket. Returns + the received file descriptor on success, or \-1 on error. */ +\& +static int +recvfd(int sockfd) +{ + int data, fd; + ssize_t nr; + struct iovec iov; + struct msghdr msgh; +\& + /* Allocate a char buffer for the ancillary data. See the comments + in sendfd() */ + union { + char buf[CMSG_SPACE(sizeof(int))]; + struct cmsghdr align; + } controlMsg; + struct cmsghdr *cmsgp; +\& + /* The \[aq]msg_name\[aq] field can be used to obtain the address of the + sending socket. However, we do not need this information. */ +\& + msgh.msg_name = NULL; + msgh.msg_namelen = 0; +\& + /* Specify buffer for receiving real data */ +\& + msgh.msg_iov = &iov; + msgh.msg_iovlen = 1; + iov.iov_base = &data; /* Real data is an \[aq]int\[aq] */ + iov.iov_len = sizeof(int); +\& + /* Set \[aq]msghdr\[aq] fields that describe ancillary data */ +\& + msgh.msg_control = controlMsg.buf; + msgh.msg_controllen = sizeof(controlMsg.buf); +\& + /* Receive real plus ancillary data; real data is ignored */ +\& + nr = recvmsg(sockfd, &msgh, 0); + if (nr == \-1) + return \-1; +\& + cmsgp = CMSG_FIRSTHDR(&msgh); +\& + /* Check the validity of the \[aq]cmsghdr\[aq] */ +\& + if (cmsgp == NULL + || cmsgp\->cmsg_len != CMSG_LEN(sizeof(int)) + || cmsgp\->cmsg_level != SOL_SOCKET + || cmsgp\->cmsg_type != SCM_RIGHTS) + { + errno = EINVAL; + return \-1; + } +\& + /* Return the received file descriptor to our caller */ +\& + memcpy(&fd, CMSG_DATA(cmsgp), sizeof(int)); + return fd; +} +\& +static void +sigchldHandler(int sig) +{ + char msg[] = "\etS: target has terminated; bye\en"; +\& + write(STDOUT_FILENO, msg, sizeof(msg) \- 1); + _exit(EXIT_SUCCESS); +} +\& +static int +seccomp(unsigned int operation, unsigned int flags, void *args) +{ + return syscall(SYS_seccomp, operation, flags, args); +} +\& +/* The following is the x86\-64\-specific BPF boilerplate code for checking + that the BPF program is running on the right architecture + ABI. At + completion of these instructions, the accumulator contains the system + call number. */ +\& +/* For the x32 ABI, all system call numbers have bit 30 set */ +\& +#define X32_SYSCALL_BIT 0x40000000 +\& +#define X86_64_CHECK_ARCH_AND_LOAD_SYSCALL_NR \e + BPF_STMT(BPF_LD | BPF_W | BPF_ABS, \e + (offsetof(struct seccomp_data, arch))), \e + BPF_JUMP(BPF_JMP | BPF_JEQ | BPF_K, AUDIT_ARCH_X86_64, 0, 2), \e + BPF_STMT(BPF_LD | BPF_W | BPF_ABS, \e + (offsetof(struct seccomp_data, nr))), \e + BPF_JUMP(BPF_JMP | BPF_JGE | BPF_K, X32_SYSCALL_BIT, 0, 1), \e + BPF_STMT(BPF_RET | BPF_K, SECCOMP_RET_KILL_PROCESS) +\& +/* installNotifyFilter() installs a seccomp filter that generates + user\-space notifications (SECCOMP_RET_USER_NOTIF) when the process + calls mkdir(2); the filter allows all other system calls. +\& + The function return value is a file descriptor from which the + user\-space notifications can be fetched. */ +\& +static int +installNotifyFilter(void) +{ + int notifyFd; +\& + struct sock_filter filter[] = { + X86_64_CHECK_ARCH_AND_LOAD_SYSCALL_NR, +\& + /* mkdir() triggers notification to user\-space supervisor */ +\& + BPF_JUMP(BPF_JMP | BPF_JEQ | BPF_K, SYS_mkdir, 0, 1), + BPF_STMT(BPF_RET + BPF_K, SECCOMP_RET_USER_NOTIF), +\& + /* Every other system call is allowed */ +\& + BPF_STMT(BPF_RET | BPF_K, SECCOMP_RET_ALLOW), + }; +\& + struct sock_fprog prog = { + .len = ARRAY_SIZE(filter), + .filter = filter, + }; +\& + /* Install the filter with the SECCOMP_FILTER_FLAG_NEW_LISTENER flag; + as a result, seccomp() returns a notification file descriptor. */ +\& + notifyFd = seccomp(SECCOMP_SET_MODE_FILTER, + SECCOMP_FILTER_FLAG_NEW_LISTENER, &prog); + if (notifyFd == \-1) + err(EXIT_FAILURE, "seccomp\-install\-notify\-filter"); +\& + return notifyFd; +} +\& +/* Close a pair of sockets created by socketpair() */ +\& +static void +closeSocketPair(int sockPair[2]) +{ + if (close(sockPair[0]) == \-1) + err(EXIT_FAILURE, "closeSocketPair\-close\-0"); + if (close(sockPair[1]) == \-1) + err(EXIT_FAILURE, "closeSocketPair\-close\-1"); +} +\& +/* Implementation of the target process; create a child process that: +\& + (1) installs a seccomp filter with the + SECCOMP_FILTER_FLAG_NEW_LISTENER flag; + (2) writes the seccomp notification file descriptor returned from + the previous step onto the UNIX domain socket, \[aq]sockPair[0]\[aq]; + (3) calls mkdir(2) for each element of \[aq]argv\[aq]. +\& + The function return value in the parent is the PID of the child + process; the child does not return from this function. */ +\& +static pid_t +targetProcess(int sockPair[2], char *argv[]) +{ + int notifyFd, s; + pid_t targetPid; +\& + targetPid = fork(); +\& + if (targetPid == \-1) + err(EXIT_FAILURE, "fork"); +\& + if (targetPid > 0) /* In parent, return PID of child */ + return targetPid; +\& + /* Child falls through to here */ +\& + printf("T: PID = %ld\en", (long) getpid()); +\& + /* Install seccomp filter(s) */ +\& + if (prctl(PR_SET_NO_NEW_PRIVS, 1, 0, 0, 0)) + err(EXIT_FAILURE, "prctl"); +\& + notifyFd = installNotifyFilter(); +\& + /* Pass the notification file descriptor to the tracing process over + a UNIX domain socket */ +\& + if (sendfd(sockPair[0], notifyFd) == \-1) + err(EXIT_FAILURE, "sendfd"); +\& + /* Notification and socket FDs are no longer needed in target */ +\& + if (close(notifyFd) == \-1) + err(EXIT_FAILURE, "close\-target\-notify\-fd"); +\& + closeSocketPair(sockPair); +\& + /* Perform a mkdir() call for each of the command\-line arguments */ +\& + for (char **ap = argv; *ap != NULL; ap++) { + printf("\enT: about to mkdir(\e"%s\e")\en", *ap); +\& + s = mkdir(*ap, 0700); + if (s == \-1) + perror("T: ERROR: mkdir(2)"); + else + printf("T: SUCCESS: mkdir(2) returned %d\en", s); + } +\& + printf("\enT: terminating\en"); + exit(EXIT_SUCCESS); +} +\& +/* Check that the notification ID provided by a SECCOMP_IOCTL_NOTIF_RECV + operation is still valid. It will no longer be valid if the target + process has terminated or is no longer blocked in the system call that + generated the notification (because it was interrupted by a signal). +\& + This operation can be used when doing such things as accessing + /proc/PID files in the target process in order to avoid TOCTOU race + conditions where the PID that is returned by SECCOMP_IOCTL_NOTIF_RECV + terminates and is reused by another process. */ +\& +static bool +cookieIsValid(int notifyFd, uint64_t id) +{ + return ioctl(notifyFd, SECCOMP_IOCTL_NOTIF_ID_VALID, &id) == 0; +} +\& +/* Access the memory of the target process in order to fetch the + pathname referred to by the system call argument \[aq]argNum\[aq] in + \[aq]req\->data.args[]\[aq]. The pathname is returned in \[aq]path\[aq], + a buffer of \[aq]len\[aq] bytes allocated by the caller. +\& + Returns true if the pathname is successfully fetched, and false + otherwise. For possible causes of failure, see the comments below. */ +\& +static bool +getTargetPathname(struct seccomp_notif *req, int notifyFd, + int argNum, char *path, size_t len) +{ + int procMemFd; + char procMemPath[PATH_MAX]; + ssize_t nread; +\& + snprintf(procMemPath, sizeof(procMemPath), "/proc/%d/mem", req\->pid); +\& + procMemFd = open(procMemPath, O_RDONLY | O_CLOEXEC); + if (procMemFd == \-1) + return false; +\& + /* Check that the process whose info we are accessing is still alive + and blocked in the system call that caused the notification. + If the SECCOMP_IOCTL_NOTIF_ID_VALID operation (performed in + cookieIsValid()) succeeded, we know that the /proc/PID/mem file + descriptor that we opened corresponded to the process for which we + received a notification. If that process subsequently terminates, + then read() on that file descriptor will return 0 (EOF). */ +\& + if (!cookieIsValid(notifyFd, req\->id)) { + close(procMemFd); + return false; + } +\& + /* Read bytes at the location containing the pathname argument */ +\& + nread = pread(procMemFd, path, len, req\->data.args[argNum]); +\& + close(procMemFd); +\& + if (nread <= 0) + return false; +\& + /* Once again check that the notification ID is still valid. The + case we are particularly concerned about here is that just + before we fetched the pathname, the target\[aq]s blocked system + call was interrupted by a signal handler, and after the handler + returned, the target carried on execution (past the interrupted + system call). In that case, we have no guarantees about what we + are reading, since the target\[aq]s memory may have been arbitrarily + changed by subsequent operations. */ +\& + if (!cookieIsValid(notifyFd, req\->id)) { + perror("\etS: notification ID check failed!!!"); + return false; + } +\& + /* Even if the target\[aq]s system call was not interrupted by a signal, + we have no guarantees about what was in the memory of the target + process. (The memory may have been modified by another thread, or + even by an external attacking process.) We therefore treat the + buffer returned by pread() as untrusted input. The buffer should + contain a terminating null byte; if not, then we will trigger an + error for the target process. */ +\& + if (strnlen(path, nread) < nread) + return true; +\& + return false; +} +\& +/* Allocate buffers for the seccomp user\-space notification request and + response structures. It is the caller\[aq]s responsibility to free the + buffers returned via \[aq]req\[aq] and \[aq]resp\[aq]. */ +\& +static void +allocSeccompNotifBuffers(struct seccomp_notif **req, + struct seccomp_notif_resp **resp, + struct seccomp_notif_sizes *sizes) +{ + size_t resp_size; +\& + /* Discover the sizes of the structures that are used to receive + notifications and send notification responses, and allocate + buffers of those sizes. */ +\& + if (seccomp(SECCOMP_GET_NOTIF_SIZES, 0, sizes) == \-1) + err(EXIT_FAILURE, "seccomp\-SECCOMP_GET_NOTIF_SIZES"); +\& + *req = malloc(sizes\->seccomp_notif); + if (*req == NULL) + err(EXIT_FAILURE, "malloc\-seccomp_notif"); +\& + /* When allocating the response buffer, we must allow for the fact + that the user\-space binary may have been built with user\-space + headers where \[aq]struct seccomp_notif_resp\[aq] is bigger than the + response buffer expected by the (older) kernel. Therefore, we + allocate a buffer that is the maximum of the two sizes. This + ensures that if the supervisor places bytes into the response + structure that are past the response size that the kernel expects, + then the supervisor is not touching an invalid memory location. */ +\& + resp_size = sizes\->seccomp_notif_resp; + if (sizeof(struct seccomp_notif_resp) > resp_size) + resp_size = sizeof(struct seccomp_notif_resp); +\& + *resp = malloc(resp_size); + if (*resp == NULL) + err(EXIT_FAILURE, "malloc\-seccomp_notif_resp"); +\& +} +\& +/* Handle notifications that arrive via the SECCOMP_RET_USER_NOTIF file + descriptor, \[aq]notifyFd\[aq]. */ +\& +static void +handleNotifications(int notifyFd) +{ + bool pathOK; + char path[PATH_MAX]; + struct seccomp_notif *req; + struct seccomp_notif_resp *resp; + struct seccomp_notif_sizes sizes; +\& + allocSeccompNotifBuffers(&req, &resp, &sizes); +\& + /* Loop handling notifications */ +\& + for (;;) { +\& + /* Wait for next notification, returning info in \[aq]*req\[aq] */ +\& + memset(req, 0, sizes.seccomp_notif); + if (ioctl(notifyFd, SECCOMP_IOCTL_NOTIF_RECV, req) == \-1) { + if (errno == EINTR) + continue; + err(EXIT_FAILURE, "\etS: ioctl\-SECCOMP_IOCTL_NOTIF_RECV"); + } +\& + printf("\etS: got notification (ID %#llx) for PID %d\en", + req\->id, req\->pid); +\& + /* The only system call that can generate a notification event + is mkdir(2). Nevertheless, we check that the notified system + call is indeed mkdir() as kind of future\-proofing of this + code in case the seccomp filter is later modified to + generate notifications for other system calls. */ +\& + if (req\->data.nr != SYS_mkdir) { + printf("\etS: notification contained unexpected " + "system call number; bye!!!\en"); + exit(EXIT_FAILURE); + } +\& + pathOK = getTargetPathname(req, notifyFd, 0, path, sizeof(path)); +\& + /* Prepopulate some fields of the response */ +\& + resp\->id = req\->id; /* Response includes notification ID */ + resp\->flags = 0; + resp\->val = 0; +\& + /* If getTargetPathname() failed, trigger an EINVAL error + response (sending this response may yield an error if the + failure occurred because the notification ID was no longer + valid); if the directory is in /tmp, then create it on behalf + of the supervisor; if the pathname starts with \[aq].\[aq], tell the + kernel to let the target process execute the mkdir(); + otherwise, give an error for a directory pathname in any other + location. */ +\& + if (!pathOK) { + resp\->error = \-EINVAL; + printf("\etS: spoofing error for invalid pathname (%s)\en", + strerror(\-resp\->error)); + } else if (strncmp(path, "/tmp/", strlen("/tmp/")) == 0) { + printf("\etS: executing: mkdir(\e"%s\e", %#llo)\en", + path, req\->data.args[1]); +\& + if (mkdir(path, req\->data.args[1]) == 0) { + resp\->error = 0; /* "Success" */ + resp\->val = strlen(path); /* Used as return value of + mkdir() in target */ + printf("\etS: success! spoofed return = %lld\en", + resp\->val); + } else { +\& + /* If mkdir() failed in the supervisor, pass the error + back to the target */ +\& + resp\->error = \-errno; + printf("\etS: failure! (errno = %d; %s)\en", errno, + strerror(errno)); + } + } else if (strncmp(path, "./", strlen("./")) == 0) { + resp\->error = resp\->val = 0; + resp\->flags = SECCOMP_USER_NOTIF_FLAG_CONTINUE; + printf("\etS: target can execute system call\en"); + } else { + resp\->error = \-EOPNOTSUPP; + printf("\etS: spoofing error response (%s)\en", + strerror(\-resp\->error)); + } +\& + /* Send a response to the notification */ +\& + printf("\etS: sending response " + "(flags = %#x; val = %lld; error = %d)\en", + resp\->flags, resp\->val, resp\->error); +\& + if (ioctl(notifyFd, SECCOMP_IOCTL_NOTIF_SEND, resp) == \-1) { + if (errno == ENOENT) + printf("\etS: response failed with ENOENT; " + "perhaps target process\[aq]s syscall was " + "interrupted by a signal?\en"); + else + perror("ioctl\-SECCOMP_IOCTL_NOTIF_SEND"); + } +\& + /* If the pathname is just "/bye", then the supervisor breaks out + of the loop and terminates. This allows us to see what happens + if the target process makes further calls to mkdir(2). */ +\& + if (strcmp(path, "/bye") == 0) + break; + } +\& + free(req); + free(resp); + printf("\etS: terminating **********\en"); + exit(EXIT_FAILURE); +} +\& +/* Implementation of the supervisor process: +\& + (1) obtains the notification file descriptor from \[aq]sockPair[1]\[aq] + (2) handles notifications that arrive on that file descriptor. */ +\& +static void +supervisor(int sockPair[2]) +{ + int notifyFd; +\& + notifyFd = recvfd(sockPair[1]); +\& + if (notifyFd == \-1) + err(EXIT_FAILURE, "recvfd"); +\& + closeSocketPair(sockPair); /* We no longer need the socket pair */ +\& + handleNotifications(notifyFd); +} +\& +int +main(int argc, char *argv[]) +{ + int sockPair[2]; + struct sigaction sa; +\& + setbuf(stdout, NULL); +\& + if (argc < 2) { + fprintf(stderr, "At least one pathname argument is required\en"); + exit(EXIT_FAILURE); + } +\& + /* Create a UNIX domain socket that is used to pass the seccomp + notification file descriptor from the target process to the + supervisor process. */ +\& + if (socketpair(AF_UNIX, SOCK_STREAM, 0, sockPair) == \-1) + err(EXIT_FAILURE, "socketpair"); +\& + /* Create a child process\-\-the "target"\-\-that installs seccomp + filtering. The target process writes the seccomp notification + file descriptor onto \[aq]sockPair[0]\[aq] and then calls mkdir(2) for + each directory in the command\-line arguments. */ +\& + (void) targetProcess(sockPair, &argv[optind]); +\& + /* Catch SIGCHLD when the target terminates, so that the + supervisor can also terminate. */ +\& + sa.sa_handler = sigchldHandler; + sa.sa_flags = 0; + sigemptyset(&sa.sa_mask); + if (sigaction(SIGCHLD, &sa, NULL) == \-1) + err(EXIT_FAILURE, "sigaction"); +\& + supervisor(sockPair); +\& + exit(EXIT_SUCCESS); +} +.EE +.\" SRC END +.SH SEE ALSO +.BR ioctl (2), +.BR pidfd_getfd (2), +.BR pidfd_open (2), +.BR seccomp (2) +.PP +A further example program can be found in the kernel source file +.IR samples/seccomp/user-trap.c . -- cgit v1.2.3