# Terminals and Standard IO # *Note that the default configuration of `runc` (foreground, new terminal) is generally the best option for most users. This document exists to help explain what the purpose of the different modes is, and to try to steer users away from common mistakes and misunderstandings.* In general, most processes on Unix (and Unix-like) operating systems have 3 standard file descriptors provided at the start, collectively referred to as "standard IO" (`stdio`): * `0`: standard-in (`stdin`), the input stream into the process * `1`: standard-out (`stdout`), the output stream from the process * `2`: standard-error (`stderr`), the error stream from the process When creating and running a container via `runc`, it is important to take care to structure the `stdio` the new container's process receives. In some ways containers are just regular processes, while in other ways they're an isolated sub-partition of your machine (in a similar sense to a VM). This means that the structure of IO is not as simple as with ordinary programs (which generally just use the file descriptors you give them). ## Other File Descriptors ## Before we continue, it is important to note that processes can have more file descriptors than just `stdio`. By default in `runc` no other file descriptors will be passed to the spawned container process. If you wish to explicitly pass file descriptors to the container you have to use the `--preserve-fds` option. These ancillary file descriptors don't have any of the strange semantics discussed further in this document (those only apply to `stdio`) -- they are passed untouched by `runc`. It should be noted that `--preserve-fds` does not take individual file descriptors to preserve. Instead, it takes how many file descriptors (not including `stdio` or `LISTEN_FDS`) should be passed to the container. In the following example: ``` % runc run --preserve-fds 5 ``` `runc` will pass the first `5` file descriptors (`3`, `4`, `5`, `6`, and `7` -- assuming that `LISTEN_FDS` has not been configured) to the container. In addition to `--preserve-fds`, `LISTEN_FDS` file descriptors are passed automatically to allow for `systemd`-style socket activation. To extend the above example: ``` % LISTEN_PID=$pid_of_runc LISTEN_FDS=3 runc run --preserve-fds 5 ``` `runc` will now pass the first `8` file descriptors (and it will also pass `LISTEN_FDS=3` and `LISTEN_PID=1` to the container). The first `3` (`3`, `4`, and `5`) were passed due to `LISTEN_FDS` and the other `5` (`6`, `7`, `8`, `9`, and `10`) were passed due to `--preserve-fds`. You should keep this in mind if you use `runc` directly in something like a `systemd` unit file. To disable this `LISTEN_FDS`-style passing just unset `LISTEN_FDS`. **Be very careful when passing file descriptors to a container process.** Due to some Linux kernel (mis)features, a container with access to certain types of file descriptors (such as `O_PATH` descriptors) outside of the container's root file system can use these to break out of the container's pivoted mount namespace. [This has resulted in CVEs in the past.][CVE-2016-9962] [CVE-2016-9962]: https://nvd.nist.gov/vuln/detail/CVE-2016-9962 ## Terminal Modes ## `runc` supports two distinct methods for passing `stdio` to the container's primary process: * [new terminal](#new-terminal) (`terminal: true`) * [pass-through](#pass-through) (`terminal: false`) When first using `runc` these two modes will look incredibly similar, but this can be quite deceptive as these different modes have quite different characteristics. By default, `runc spec` will create a configuration that will create a new terminal (`terminal: true`). However, if the `terminal: ...` line is not present in `config.json` then pass-through is the default. *In general we recommend using new terminal, because it means that tools like `sudo` will work inside your container. But pass-through can be useful if you know what you're doing, or if you're using `runc` as part of a non-interactive pipeline.* ### New Terminal ### In new terminal mode, `runc` will create a brand-new "console" (or more precisely, a new pseudo-terminal using the container's namespaced `/dev/pts/ptmx`) for your contained process to use as its `stdio`. When you start a process in new terminal mode, `runc` will do the following: 1. Create a new pseudo-terminal. 2. Pass the slave end to the container's primary process as its `stdio`. 3. Send the master end to a process to interact with the `stdio` for the container's primary process ([details below](#runc-modes)). It should be noted that since a new pseudo-terminal is being used for communication with the container, some strange properties of pseudo-terminals might surprise you. For instance, by default, all new pseudo-terminals translate the byte `'\n'` to the sequence `'\r\n'` on both `stdout` and `stderr`. In addition there are [a whole range of `ioctls(2)` that can only interact with pseudo-terminal `stdio`][tty_ioctl(4)]. > **NOTE**: In new terminal mode, all three `stdio` file descriptors are the > same underlying file. The reason for this is to match how a shell's `stdio` > looks to a process (as well as remove race condition issues with having to > deal with multiple master pseudo-terminal file descriptors). However this > means that it is not really possible to uniquely distinguish between `stdout` > and `stderr` from the caller's perspective. [tty_ioctl(4)]: https://linux.die.net/man/4/tty_ioctl ### Pass-Through ### If you have already set up some file handles that you wish your contained process to use as its `stdio`, then you can ask `runc` to pass them through to the contained process (this is not necessarily the same as `--preserve-fds`'s passing of file descriptors -- [details below](#runc-modes)). As an example (assuming that `terminal: false` is set in `config.json`): ``` % echo input | runc run some_container > /tmp/log.out 2>& /tmp/log.err ``` Here the container's various `stdio` file descriptors will be substituted with the following: * `stdin` will be sourced from the `echo input` pipeline. * `stdout` will be output into `/tmp/log.out` on the host. * `stderr` will be output into `/tmp/log.err` on the host. It should be noted that the actual file handles seen inside the container may be different [based on the mode `runc` is being used in](#runc-modes) (for instance, the file referenced by `1` could be `/tmp/log.out` directly or a pipe which `runc` is using to buffer output, based on the mode). However the net result will be the same in either case. In principle you could use the [new terminal mode](#new-terminal) in a pipeline, but the difference will become more clear when you are introduced to [`runc`'s detached mode](#runc-modes). ## `runc` Modes ## `runc` itself runs in two modes: * [foreground](#foreground) * [detached](#detached) You can use either [terminal mode](#terminal-modes) with either `runc` mode. However, there are considerations that may indicate preference for one mode over another. It should be noted that while two types of modes (terminal and `runc`) are conceptually independent from each other, you should be aware of the intricacies of which combination you are using. *In general we recommend using foreground because it's the most straight-forward to use, with the only downside being that you will have a long-running `runc` process. Detached mode is difficult to get right and generally requires having your own `stdio` management.* ### Foreground ### The default (and most straight-forward) mode of `runc`. In this mode, your `runc` command remains in the foreground with the container process as a child. All `stdio` is buffered through the foreground `runc` process (irrespective of which terminal mode you are using). This is conceptually quite similar to running a normal process interactively in a shell (and if you are using `runc` in a shell interactively, this is what you should use). Because the `stdio` will be buffered in this mode, some very important peculiarities of this mode should be kept in mind: * With [new terminal mode](#new-terminal), the container will see a pseudo-terminal as its `stdio` (as you might expect). However, the `stdio` of the foreground `runc` process will remain the `stdio` that the process was started with -- and `runc` will copy all `stdio` between its `stdio` and the container's `stdio`. This means that while a new pseudo-terminal has been created, the foreground `runc` process manages it over the lifetime of the container. * With [pass-through mode](#pass-through), the foreground `runc`'s `stdio` is **not** passed to the container. Instead, the container's `stdio` is a set of pipes which are used to copy data between `runc`'s `stdio` and the container's `stdio`. This means that the container never has direct access to host file descriptors (aside from the pipes created by the container runtime, but that shouldn't be an issue). The main drawback of the foreground mode of operation is that it requires a long-running foreground `runc` process. If you kill the foreground `runc` process then you will no longer have access to the `stdio` of the container (and in most cases this will result in the container dying abnormally due to `SIGPIPE` or some other error). By extension this means that any bug in the long-running foreground `runc` process (such as a memory leak) or a stray OOM-kill sweep could result in your container being killed **through no fault of the user**. In addition, there is no way in foreground mode of passing a file descriptor directly to the container process as its `stdio` (like `--preserve-fds` does). These shortcomings are obviously sub-optimal and are the reason that `runc` has an additional mode called "detached mode". ### Detached ### In contrast to foreground mode, in detached mode there is no long-running foreground `runc` process once the container has started. In fact, there is no long-running `runc` process at all. However, this means that it is up to the caller to handle the `stdio` after `runc` has set it up for you. In a shell this means that the `runc` command will exit and control will return to the shell, after the container has been set up. You can run `runc` in detached mode in one of the following ways: * `runc run -d ...` which operates similar to `runc run` but is detached. * `runc create` followed by `runc start` which is the standard container lifecycle defined by the OCI runtime specification (`runc create` sets up the container completely, waiting for `runc start` to begin execution of user code). The main use-case of detached mode is for higher-level tools that want to be wrappers around `runc`. By running `runc` in detached mode, those tools have far more control over the container's `stdio` without `runc` getting in the way (most wrappers around `runc` like `cri-o` or `containerd` use detached mode for this reason). Unfortunately using detached mode is a bit more complicated and requires more care than the foreground mode -- mainly because it is now up to the caller to handle the `stdio` of the container. #### Detached Pass-Through #### In detached mode, pass-through actually does what it says on the tin -- the `stdio` file descriptors of the `runc` process are passed through (untouched) to the container's `stdio`. The purpose of this option is to allow a user to set up `stdio` for a container themselves and then force `runc` to just use their pre-prepared `stdio` (without any pseudo-terminal funny business). *If you don't see why this would be useful, don't use this option.* **You must be incredibly careful when using detached pass-through (especially in a shell).** The reason for this is that by using detached pass-through you are passing host file descriptors to the container. In the case of a shell, usually your `stdio` is going to be a pseudo-terminal (on your host). A malicious container could take advantage of TTY-specific `ioctls` like `TIOCSTI` to fake input into the **host** shell (remember that in detached mode, control is returned to your shell and so the terminal you've given the container is being read by a shell prompt). There are also several other issues with running non-malicious containers in a shell with detached pass-through (where you pass your shell's `stdio` to the container): * Output from the container will be interleaved with output from your shell (in a non-deterministic way), without any real way of distinguishing from where a particular piece of output came from. * Any input to `stdin` will be non-deterministically split and given to either the container or the shell (because both are blocked on a `read(2)` of the same FIFO-style file descriptor). They are all related to the fact that there is going to be a race when either your host or the container tries to read from (or write to) `stdio`. This problem is especially obvious when in a shell, where usually the terminal has been put into raw mode (where each individual key-press should cause `read(2)` to return). > **NOTE**: There is also currently a [known problem][issue-1721] where using > detached pass-through will result in the container hanging if the `stdout` or > `stderr` is a pipe (though this should be a temporary issue). [issue-1721]: https://github.com/opencontainers/runc/issues/1721 #### Detached New Terminal #### When creating a new pseudo-terminal in detached mode, and fairly obvious problem appears -- how do we use the new terminal that `runc` created? Unlike in pass-through, `runc` has created a new set of file descriptors that need to be used by *something* in order for container communication to work. The way this problem is resolved is through the use of Unix domain sockets. There is a feature of Unix sockets called `SCM_RIGHTS` which allows a file descriptor to be sent through a Unix socket to a completely separate process (which can then use that file descriptor as though they opened it). When using `runc` in detached new terminal mode, this is how a user gets access to the pseudo-terminal's master file descriptor. To this end, there is a new option (which is required if you want to use `runc` in detached new terminal mode): `--console-socket`. This option takes the path to a Unix domain socket which `runc` will connect to and send the pseudo-terminal master file descriptor down. The general process for getting the pseudo-terminal master is as follows: 1. Create a Unix domain socket at some path, `$socket_path`. 2. Call `runc run` or `runc create` with the argument `--console-socket $socket_path`. 3. Using `recvmsg(2)` retrieve the file descriptor sent using `SCM_RIGHTS` by `runc`. 4. Now the manager can interact with the `stdio` of the container, using the retrieved pseudo-terminal master. After `runc` exits, the only process with a copy of the pseudo-terminal master file descriptor is whoever read the file descriptor from the socket. > **NOTE**: Currently `runc` doesn't support abstract socket addresses (due to > it not being possible to pass an `argv` with a null-byte as the first > character). In the future this may change, but currently you must use a valid > path name. In order to help users make use of detached new terminal mode, we have provided a [Go implementation in the `go-runc` bindings][containerd/go-runc.Socket], as well as [a simple client][recvtty]. [containerd/go-runc.Socket]: https://godoc.org/github.com/containerd/go-runc#Socket [recvtty]: /contrib/cmd/recvtty