# Bash Streams Handbook > Learn Bash streams, pipes and redirects, from beginner to advanced. [![License](http://img.shields.io/badge/license-MIT-blue.svg)](https://raw.githubusercontent.com/miguelmota/bash-pipe-handbook/master/LICENSE) [![PRs Welcome](https://img.shields.io/badge/PRs-welcome-brightgreen.svg)](#contributing) ![status-wip](https://img.shields.io/badge/status-work_in_progress-lightgrey.svg) ## Contents - [Standard streams](#standard-streams) - [Standard input](#standard-input) - [Standard output](#standard-output) - [Standard error](#standard-error) - [Redirection](#redirection) - [Pipelines](#pipelines) - [Named pipes](#named-pipes) - [Command grouping](#command-grouping) - [Process Substitution](#process-substitution) - [Subshells](#subshells) - [Examples](#examples) - [Contributing](#contributing) - [License](#license) ## Standard streams A data stream in the context of Bash is a communication channel between a program and the environment where the command was launched from. There are three data [standard streams](https://en.wikipedia.org/wiki/Standard_streams) that are created when a command is launched. The three streams are: - **stdin** - standard input - **stdout** - standard output - **stderr** - standard error Further more: - The standard input stream accepts text as it's input. - The text output from the command is sent to the shell though the standard output stream. - Error messages from the command is sent to the shell through the standard error stream. These data streams are treated as files meaning you read from them and write to them as if they are regular files. Files are identified by a unique number called a **file descriptor**, which the process uses to perform read/write operations. When a command is launched, the first three file descriptors are allocated for the standard streams in the TTY. A [_TTY_](https://en.wikipedia.org/wiki/Computer_terminal#Text_terminals) is the input/output environment, which is the terminal. This is different than a _shell_, which refers to the command-line interpreter. Standard stream file descriptors: - **0**: stdin - **1**: stdout - **2**: stderr File descriptor `0` is dedicated for standard input, `1` for standard output, and `2` for standard error. File descriptors are maintained under `/proc/$pid/fd` where `$pid` is the process id. The current process can be referenced by `/proc/self/fd`. The locations of these file descriptors are in `/proc/self/fd/0`, `/proc/self/fd/1`, and `/proc/self/fd/2` respectively. ```bash $ ls -la /proc/self/fd total 0 dr-x------ 2 mota mota 0 Sep 29 16:13 ./ dr-xr-xr-x 9 mota mota 0 Sep 29 16:13 ../ lrwx------ 1 mota mota 64 Sep 29 16:13 0 -> /dev/pts/9 lrwx------ 1 mota mota 64 Sep 29 16:13 1 -> /dev/pts/9 lrwx------ 1 mota mota 64 Sep 29 16:13 2 -> /dev/pts/9 lr-x------ 1 mota mota 64 Sep 29 16:13 3 -> /proc/815170/fd/ lrwx------ 1 mota mota 64 Sep 29 16:13 6 -> /dev/pts/9 ```
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Bash forks a child process when launching a command and inherits the file descriptors from the parent process. We can use `$$` to get the parent process ID: ```bash $ echo $$ 2317356 $ ps -p $$ PID TTY TIME CMD 2317356 pts/9 00:00:00 bash ```
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Listing `/proc/$$/fd` will print the same information as before when using `self` because the `$$` is expanded to the same process ID: ```bash $ ls -la /proc/$$/fd total 0 dr-x------ 2 mota mota 0 Sep 27 19:33 ./ dr-xr-xr-x 9 mota mota 0 Sep 27 19:33 ../ lrwx------ 1 mota mota 64 Sep 27 19:33 0 -> /dev/pts/9 lrwx------ 1 mota mota 64 Sep 27 19:33 1 -> /dev/pts/9 lrwx------ 1 mota mota 64 Sep 27 19:33 2 -> /dev/pts/9 lrwx------ 1 mota mota 64 Sep 28 12:20 255 -> /dev/pts/9 lrwx------ 1 mota mota 64 Sep 27 19:33 6 -> /dev/pts/9 ```
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In the above examples, `/dev/pts/9` is referencing the pseudo terminal device. A _pts_ is a pseudo terminal device emulated by another program, such as `xterm`, `tmux`, `ssh`, etc. Type the `tty` command to see the pts device path. ```bash $ tty /dev/pts/9 ``` You'll see a different number if you open up a new terminal window because it's a new terminal device: ```bash $ tty /dev/pts/11 ```
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If we we're on a native terminal device (non-pseudo) meaning the backend is hardware or kernel emulated (e.g. the console before launching the desktop environment), then the tty path will look something like `/dev/tty1`. The file descriptor table looks like this, where the standard streams are reading/writing from the TTY. - `0` -> `/dev/pts/9` - `1` -> `/dev/pts/9` - `2` -> `/dev/pts/9` We can write data to the stdout file descriptor and you'll see it be printed back at you: ```bash $ echo "hello world" > /proc/self/fd/1 hello world ```
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Same thing will occur if writing to the stderr file descriptor: ```bash $ echo "hello world" > /proc/self/fd/2 hello world ```
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We can read from from the stdin file descriptor and echo the input: ```bash $ echo $( example gif

example gif If you're not familar with the `$(...)` syntax, it allows you to use the result of the command as the the string argument since `$()` evaluates the expression. The `<` is the standard input redirect operator which we'll go over in the redirection section. ### symlinks For convenience, the file descriptor path is symlinked to `/dev/fd`. ```bash $ ls -l /dev/fd lrwxrwxrwx 1 root root 13 Aug 26 23:14 /dev/fd -> /proc/self/fd ```

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For convenience, the standard streams are symlinked to `/dev/stdin`, `/dev/stdout`, and `/dev/stderr` respectively. ```bash $ ls -l /dev/std* lrwxrwxrwx 1 root root 15 Aug 26 23:14 /dev/stderr -> /proc/self/fd/2 lrwxrwxrwx 1 root root 15 Aug 26 23:14 /dev/stdin -> /proc/self/fd/0 lrwxrwxrwx 1 root root 15 Aug 26 23:14 /dev/stdout -> /proc/self/fd/1 ```
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These are the same: - `/dev/stdin` -> `/proc/self/fd/0` - `/dev/stdout` -> `/proc/self/fd/1` - `/dev/stderr` -> `/proc/self/fd/2` The symlinks are considered [POSIX extensions](https://pubs.opengroup.org/onlinepubs/9699919799/basedefs/V1_chap02.html), so they might not be available in all [POSIX](https://en.wikipedia.org/wiki/POSIX) compliant systems. ## Redirection Redirection operators allow control of where input and output streams should go. When you see `>` it means redirection. The following are some of the redirect operators in Bash: - `>` - redirect output, overwriting target if exists - `>>` - redirect output, appending instead of overwriting if target exists - `&#>` - redirect file descriptor _#_, where _#_ is the identifier - `<` - redirect input Standard streams are can be referenced by their file descriptor identifiers. An ampersand `&` followed by the identifier number, ie `&1`, references a file descriptor when redirecting. For example: - `command 1> out.log` - outputs file descriptor 1 (stdout) to file. - `command 2> out.log` - outputs file descriptor 2 (stderr) to file. - `command 3> out.log` - outputs file descriptor 3 (a custom file descriptor) to file. Common redirects: - `1>` - redirects stdout only. This is also the same as simply doing `>` - `2>` - redirects stderr only - `2>&1` - redirects stderr to stdout. The `2>` is redirecting the standard error output into file descriptor `1` which is standard out. The final output will contain both stdout and stderr output, if any. - '&>' - redirect stdout and stderr. THis is also the same as the above `2>&1` For example: - `command 2>&1 > out.log` - says "point output of FD #2 to FD #1, and ouput FD #1 to out file". The reason an ampersand is required is because `command 2>1` would be ambiguous; it wouldn't be clear if it was redirecting to file descriptor `1` or to a filename named `1`, so the `&` is required to explicitly reference it as the file descriptor. Do note that `&1` (file descriptor `1`) is different than a single `&` (run in background) and double `&&` (AND operator). The ampersand has different meaning depending on the way it's used. Other redirect operators (this will be explained in later sections): - `<<` - "[Here documents](http://tldp.org/LDP/abs/html/here-docs.html)", a special-purpose code block - `<<<` - "[Here strings](http://www.tldp.org/LDP/abs/html/x17837.html)", a striped-down form of a here document. **Example:** demonstration of the different redirect operators: Write stdout output of `ls` list format to `list.txt` file: ```bash $ ls archive.zip book.pdf notes.txt $ ls -l > list.txt $ cat list.txt total 0 -rw-r--r-- 1 mota mota 0 Sep 30 14:17 archive.zip -rw-r--r-- 1 mota mota 0 Sep 30 14:17 book.pdf -rw-r--r-- 1 mota mota 0 Sep 30 14:19 list.txt -rw-r--r-- 1 mota mota 0 Sep 30 14:17 notes.txt ```
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Append new stdout output of `ls` showing hidden files to same `list.txt` file: ```bash $ ls -a . .. archive.zip book.pdf .cache .config notes.txt $ ls -a >> list.txt $ cat list.txt total 0 -rw-r--r-- 1 mota mota 0 Sep 30 14:17 archive.zip -rw-r--r-- 1 mota mota 0 Sep 30 14:17 book.pdf -rw-r--r-- 1 mota mota 0 Sep 30 14:19 list.txt -rw-r--r-- 1 mota mota 0 Sep 30 14:17 notes.txt . .. archive.zip book.pdf .cache .config list.txt notes.txt ```
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Search for particular filenames and write errors from stderr to `errors.txt` file: ```bash $ ls *.json ls: cannot access '*.json': No such file or directory $ ls *.json 2> errors.txt $ cat errors.txt ls: cannot access '*.json': No such file or directory ```
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Read `errors.txt` file as input to the `less` command: ```bash $ less < errors.txt ls: cannot access '*.json': No such file or directory errors.txt (END) ```
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### Standard input stdin (standard input) is an input stream where input data is sent to. The program reads the stream data as input for the program. stdin is a file descriptor we can write to. In most cases the standard input is input from the keyboard. The stdin file descriptor is located at `/proc/self/fd/0` but we can use the symlink `/dev/stdin` as well. Data to be sent to program as input is redirected with `<`: ```bash command < input.txt ``` **Example:** Read stdin as input for bash script: `program.sh`: ```bash while read line do echo "hello $line" done < /dev/stdin ``` Create file with names: ```bash $ printf "alice\nbob\n" > file.txt ``` Run program: ```bash $ chmod +x program.sh $ ./program.sh < file.txt hello alice hello bob ```
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**Example:** For stdin demonstration purposes, you can send file data as input to the echo command by reading the file into a subshell and using the result as the echo arguments: ```bash $ echo "hello world" > file.txt $ echo $(< file.txt) hello world ```
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### Standard output stdout (standard output) is an output stream where data is sent to and then outputted by the terminal. stdout is a file descriptor we can write to. The stdout file descriptor is located at `/proc/self/fd/1` but we can use the symlink `/dev/stdout` as well. The standard output of a program is redirect with `1>` or simply just `>`: ```bash command > stdout.log ``` The above is the same as `command 1> stdout.log` **Example:** Redirect stdout to a file: ```bash $ echo "hello world" > stdout.log $ cat stdout.log hello world ```
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Trying to write to a file that can't be opened for writing will make the command fail: ```bash $ touch stdout.log $ chmod -w stdout.log $ echo "hello world" > stdout.log bash: stdout.log: Permission denied ```
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Sometimes when we aren't interested in the program stdout output, we can redirected to `/dev/null` to silence the output. This device file acts like a black hole for data streams. ```bash command > /dev/null ``` ### Standard error stderr (standard error) is an output stream where error data is sent to and then outputted by the terminal. stderr is a file descriptor we can write to. The stderr file descriptor is located at `/proc/self/fd/2` but we can use the symlink `/dev/stderr` as well. The standard error of a program is redirect with `2>`: ```bash command 2> stdout.log ``` **Example:** Redirect stdout to the stderr file descriptor. stderr messages are outputted to the terminal: ```bash $ echo "hello world" > /dev/stderr hello world ```
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**Example:** Redirect the standard error messages to a file. Redirecting with only `>` captures stdout and not stderr: ```bash $ ls /foo > out.log ls: cannot access '/foo': No such file or directory $ cat out.log ```
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We use `2>` to redirect stderr only: ```bash $ ls /foo 2> out.log $ cat out.log ls: cannot access '/foo': No such file or directory ```
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Of course now the following won't write anything to the file because there is no error: ```bash $ ls /home 2> out.log mota/ $ cat out.log ```
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We can use `2>&1` to redirect stderr to stdout, and then redirect stdout to the file with `>` (or `>>` to append): ```bash $ ls /home > out.log 2>&1 $ cat out.log mota/ $ ls /foo >> out.log 2>&1 $ cat out.log mota/ ls: cannot access '/foo': No such file or directory ```
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Alternatively, we can redirect stdout to stderr with `1>&2` (or simply `>&2`), and then redirect stderr to the file with `2>` (or `2>>` to append): ```bash $ ls /home 2> out.log 1>&2 $ cat out.log mota/ $ ls /foo 2>> out.log 1>&2 $ cat out.log mota/ ls: cannot access '/foo': No such file or directory ```
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Since `>` is shorthand for `1>`, we can replace `1>&2` with `>&2` and it'll work the same. **Order is important!** The following is what probably seems more intuitive but it won't work as you'd expect: ```bash $ ls /foo 2>&1 > out.log ls: cannot access '/foo': No such file or directory $ cat out.log ```
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It didn't write to the file, and the reason is because stderr was made a copy of stdout before stdout was redirected to the file. It's assigning the right operand to the left operand by copy and not by reference. Basically the above example is redirecting stderr to whatever stdout currently is (the TTY screen in this case) and then redirects stdout to the file. Moving the stderr redirect operator `2>&1` to after the stdout `>` part correctly copies the error stream to the output stream which is redirecting to the file. #### Shorthand We already learned about the `>` shorthand for `1>`. There's another shorthand for redirecting stderr to stdout to a file or file descriptor. The redirection `> file 2>&1` can be shorthanded to `&>` ```bash $ ls /home &> out.log $ cat out.log mota/ $ ls /foo &>> out.log $ cat out.log mota/ ls: cannot access '/foo': No such file or directory ```
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## Pipelines Using the `|` pipe operator allows you to send the output of one program as input to another program. ```bash command 1 | command2 ``` A basic example is filtering output of a program. For example, to only display files that end in `.txt` ```bash $ ls archive.zip book.pdf data.txt My_Notes.txt $ ls | grep "\.txt$" data.txt My_Notes.txt ```
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You can chain multiple commands creating a pipeline: ```bash command 1 | command 2 | command3 ``` **Example:** Add additional lowercase command: ```bash $ ls | grep "\.txt$" | tr '[A-Z]' '[a-z]' data.txt my_notes.txt ```
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It's important to note that the commands in pipelines, ie `cmd1 | cmd2 | cmd3`, are all launched in parallel and not ran sequentially. The inputs and outputs are configured appropriately for each program For running a series of commands in sequential order then use the following operators: - `&&` - run command if the last one did not fail (zero exit status code) - `||` - run command if the last one failed (non-zero exit status code) - `;` - run command regardless of the last exit code ### `&&` The AND operator `&&` (double ampersand) is used for separating commands and only running the command if the previous on succeeds: ```bash command1 && command2 ``` **Example:** Continue if condition is true. The `test` command returns exit code `0` if the condition is true. ```bash $ test 2 -lt 5 && echo "yes" yes ```
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If the `test` condition is false then the circuit breaks because the exit code is non-zero and the execution order doesn't reach the echo command: ```bash $ test 7 -lt 5 && echo "yes" ```
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You can chain as many commands as you need: ```bash command1 && command2 && command3 ``` It's important to not confuse the `&&` double ampersand with a single `&` ampersand since they do very different things. The single ampersand is used for launching the command list in the background. See ["&" section](#&). ### `||` The OR operator `||` (double pipe) is used for separating commands and only running the command if the previous one failed: ```bash command1 || command2 ``` **Example:** Continue if condition is false. The `test` command returns a non-zero exit code if the condition is false. ```bash $ test 7 -lt 5 || echo "yes" yes ```
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If the `test` condition is true and exit code is 0 then the execution will stop at the OR statement: ```bash $ test 2 -lt 5 || echo "yes" ```
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### `;` Commands separated by a ; are executed sequentially: one after another. The shell waits for the finish of each command. # command2 will be executed after command1 command1 ; command2 ### `&` The single ampersand is used for launching a command or command list in a new subshell in the background. The operator `&` must be at the end of the command: ```bash command & ``` **Example:** Run program in background. This command is will be immediately launched in the background and after 5 seconds it will display a desktop notification: ```bash $ sleep 5 && notify-send "hello world" & [1] 2481042 ```
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After running a command with `&` you'll see the job ID and process ID returned. Run `jobs` to see the list of running processes launched in the background. ```bash $ jobs [1]+ Running sleep 5 && notify-send "hello world" & ```
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After the command has completed and exited, the status will change to done: ```bash $ jobs [1]+ Done sleep 5 && notify-send "hello world" ``` Use the `-l` flag to list the process ID as well: ```bash $ jobs -l [1]+ 2481042 Done sleep 5 && notify-send "hello world" ``` If the command hasn't completed yet, you can bring to the foreground with the `fg` command: ```bash $ fg 1 sleep 5 && notify-send "hello world" ```
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Notice how there's no `&` at the end because the process is no longer running in the background. **Example:** Launch bash scripts or executible files in the background: ```bash $ cat > program.sh sleep 5 && notify-send "hello world" ^D $ chmod +x program.sh $ ./program.sh & ```
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## Named pipes The `mkfifo` allows us to create a special type of file, a FIFO file, which can be opened for writing and reading and behave similar to a pipe. These files are referred to as named pipes. The difference between a FIFO file and a regular file is that the FIFO file must be opened on both ends at the same time to let the program continue with input or output operations. The data is passed internally through the kernel without writing it to the file system (the file size is always 0 bytes). This means reading from the FIFO file will be blocked until it's opened for writing, and writing to it will be blocked will until it's opened for reading. **Example:** create a named piped for writing and reading First we create the named pipe with `mkfifo`: ```bash $ mkfifo mypipe ``` Listing the file information shows us that it's a pipe because the file type letter in the attributes is `p` ```bash $ ls -l mypipe prw-r--r-- 1 mota mota 0 Oct 25 02:14 mypipe ``` In one terminal, we redirect some standard output to the named pipe: ```bash $ echo "hello world" > mypipe ``` Notice how it appears to hang after running the command. The pipe is blocked until another process reads from the pipe. In another terminal, redirect standard input of the pipe into `cat` to read and print the contents that were sent to the pipe in the first terminal. This also unblocks the pipe since both ends are simultaneously opened. ```bash $ cat < mypipe hello world ```
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The FIFO device file is on disk so we have to manually delete it if we're done using it: ```bash $ rm mypipe ``` Another option is to create FIFO files in `/tmp` which will get automatically wiped after a restart. ## Command grouping Commands can be grouped using curly braces `{...}` ```bash $ { command; command; command; } ``` **Important!** there must be a space separating the command and the curly brace and the last command needs to be terminated by a semicolon for the group to be executed correctly. Another way to group commands is by using a subshell `(...)`. ```bash $ (command; command; command) ``` Grouping with subshells does not require the space separation and last command semicolon as like grouping with curly braces. There are differences in grouping using a subshell and subshells are explained further in the [subshells section](#subshells) Grouping commands is useful for managing redirection. For example, we can redirect the output of multiple programs to a single location without adding redudant redirects. For context: ```bash $ ls data.json list.txt $ cat list.txt archive.zip book.pdf ```
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We can take file write redirects like these: ```bash $ date > out.log $ ls >> out.log $ cat list.txt >> out.log $ cat out.log Sat Oct 10 09:35:06 PM PDT 2020 data.json list.txt out.log archive.zip book.pdf ```
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Group them to simplify things: ```bash $ { date; ls; cat list.txt; } > out.log $ cat out.log Sat Oct 10 09:35:06 PM PDT 2020 data.json list.txt out.log archive.zip book.pdf ```
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A command group can be piped to another command as if it were a single standard input: ```bash $ { date; ls; cat list.txt; } | tail -n+2 | sort archive.zip book.pdf data.json list.txt ```
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Similarly, grouping can be done with a subshell: ```bash $ (date; ls; cat list.txt) | tail -n+2 | sort archive.zip book.pdf data.json list.txt ```
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### pipefail By default, a bash pipeline's exit status code will be whichever exit code the last command returned, meaning a non-zero exit code is not preserved throughout the pipeline. **Example:** here we have a program that has a failing pipeline however the exit code is `0`. The last exit code can be read from the variable `$?`. ```bash $ cat > program.sh ls /foo | tee out.log; echo $? echo "done" ^D $ chmod +x program.sh $ ./program.sh ls: cannot access '/foo': No such file or directory 0 done ```
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The bash `set` builtin command allows us to configure shell options. One important option is the `set -o pipefail` option which causes the pipeline's exit code to be preserved if a command fails in the pipeline: ```bash $ cat > program.sh set -o pipefail ls /foo | tee out.log; echo $? echo "done" ^D $ chmod +x program.sh $ ./program.sh ls: cannot access '/foo': No such file or directory 2 done ```
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The `ls` man page mentions the following reasons for exit status codes: - `0` - if OK - `1` - if minor problems - `2` - if serious trouble Notice how the last echo command still got executed after the pipeline failed. We can combine the `pipefail` option with the `set -e` (`errexit`) option to immediately exit the script if any command fails: ```bash $ cat > program.sh set -eo pipefail ls /foo | tee out.log; echo $? echo "done" ^D $ chmod +x program.sh $ ./program.sh ls: cannot access '/foo': No such file or directory ```
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The program exited immediately after the failing `ls` command and didn't print any commands after it. ## Process Substitution Process substitution allows us to run a program and write to another program as if it were a file. The syntax for process substitution is `>(command)` for writing to the program as an output file or `<(command)` for using the program as an input file. - `<(command)` - for programs that produce standard output - `>(command)` - for programs that intake standard input The operator `<()` or `>()` creates a temporary file descriptor that manages reading and writing the substituted program. It's important that theres no space between the `<` or `>` and the parentheses `(` otherwise it would result in an error. Although it looks similar, process substitution is different than command grouping or subshells. **Example:** Print the file descriptor created by process substitution: We can use the echo command to view the result of the expansion: ```bash $ echo <(date) /dev/fd/63 ```
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**Example:** Print the contents of the file created by process substitution: ```bash $ cat <(date) Sat Oct 10 12:56:18 PM PDT 2020 ```
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**Example:** command tee stdout to cat The tee command accepts only files to write to but using process substitution we can write the output to cat. This results in the date command being printed and the cat command printing the date as well. ```bash $ date | tee >(cat) Sat Oct 10 01:27:15 PM PDT 2020 Sat Oct 10 01:27:15 PM PDT 2020 ```
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**Example:** send command stderr to substituted file while also logging stdout and stderr: ```bash command 2> tee >(cat >&2) ``` The `>()` operator substitute the tee command as a file and within that process substitution the cat command is substituted as a file so tee can write to it. The `2>` operator sends only stderr to outer substituted file. The operator `>&2` copies stdout to stderr. If there is no stderr from the command then nothing is sent to the tee substituted file: ```bash $ ls /home 2> >(tee >(cat >&2)) mota/ ```
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If there is stderr from the command then the tee process substitution will process it and log it: ```bash $ ls /foo 2> >(tee >(cat >&2)) ls: cannot access '/foo': No such file or directory ls: cannot access '/foo': No such file or directory ```
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## Subshells A subshell executes commands in a child copy of the current shell. The environment is copied to the new instance of the shell when running subshelled commands. The copy of the environment is deleted once the subshell exits so changes, such as environment variables assignments, in the subhsell are lost when it exits. Command grouping is preferred to subshells in most cases because it's faster and uses less memory. Wrap the command(s) in parentheses `(...)` to launch them in a subshell: ```bash $ (command) ``` **Example:** running a command in a subshell: Notice how the second environment variable echo is not printed because the variable was set in the subshell environment: ```bash $ (FOO=bar; echo $FOO); echo $FOO bar ```
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**Example:** using process substitution to get around subshell caveats: As an example, the `read` command can be used for caching input. The read input is copied to the `$REPLY` environment variable. ```bash $ read hello world $ echo $REPLY hello world ```
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However if we pipe a string to the read command, it will not print the string as expected after reading it: ```bash $ echo "hello world" | read $ echo $REPLY ```
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This is because read command is launched in a subshell when it's in a pipeline and the `REPLY` variable copy is lost after it exits. Commands in pipelines are executed in subshell and any variable assignments will not be available after the subshell terminates. We can use process substitution to get around this problem so a subshell doesn't to be initialized: ```bash $ read < <(echo "hello world") $ echo $REPLY hello world ```
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## Examples The following are various examples utilizing bash pipelines and redirections: ### Pipe only on stderr ```bash # will echo message only if command is not found $ command -v mycommand &>/dev/null || echo "command not found" ``` ### Echo to stderr Copy stderr file descriptor #1 to stdout file descriptor #2: ```bash echo "this will go to stderr" 1>&2 ```
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You can omit the `1` since `>` is the same as `1>`: ```bash echo "this will go to stderr" >&2 ```
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To make it more readable, the redirect can be moved to the front: ```bash >&2 echo "this will go to stderr" ```
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### Diff two commands Diff the output of two commands using process substitution: ```bash diff <(command) <(command) ``` **Example 1:** ```bash $ diff <(xxd file1.bin) <(xxd file2.bin) ``` **Example 2:** ```bash $ diff <(printf "foo\nbar/nqux\n") <(printf "foo\nbaz\nqux\n") ```
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### Record SSH session Use `tee` to record an SSH session: ```bash ssh user@server | tee /path/to/file ``` **Example:** ```bash $ ssh root@example.com | tee session.log # after exiting server $ cat session.log ```
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### Split pipe into multiple streams Split a pipe into two separate pipes using `tee` and process substitution: ```bash command | tee >(command) ``` **Example 1:** echo text and reverse the text in second stream: ```bash $ echo "split this pipe" | tee >(rev) split this pipe epip siht tilps ``` You're not limited to just one; add as many additional streams as you like: ```bash $ echo "split this pipe" | tee >(rev) >(tr ' ' '_') >(tr a-z A-Z) split this pipe SPLIT THIS PIPE split_this_pipe epip siht tilps ```
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**Example 2:** Run command and copy output to clipboard: ```bash $ echo "hello world" | tee >(copy) hello world ``` ### Send text to another terminal Echo text from one TTY to another TTY: ```bash command | /dev/pts/{id} ``` **Example:** Terminal 1 ```bash $ tty /dev/pts/39 ``` Terminal 2 ```bash $ echo "this will show up in terminal 1" > /dev/pts/39 ```
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### Pipe terminal output to another terminal Pipe stdout and stderr output of current TTY to another TTY: ```bash $ exec &> >(tee >(cat > /dev/pts/{id})) ``` **Example:** Terminal 1 ```bash $ tty /dev/pts/39 ``` Terminal 2 ```bash $ exec &> >(tee >(cat > /dev/pts/39)) ```
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Another way is to use the `script` command. The `script` command allows you to record terminal sessions. Here we specify the TTY as the output file: ```bash script -q /dev/pts/{id} command ``` **Example:** Terminal 1: ```bash $ tty /dev/pts/12 ``` Terminal 2: ```bash $ script -q /dev/pts/12 bash ```
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### Read pipe into variable ```bash $ read varname < <(command) ``` **Example:** ```bash $ read myvar < <(echo "hello world") $ echo $myvar hello world ```
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### Pipe to file descriptor ```bash command | tee /dev/fd/{id} ``` **Example:** ```bash $ echo "hello world" | tee /dev/fd/3 ``` However, the above won't work on all systems. The cross-platform compatible way is to use process substitution: ```bash $ command > >(tee >(cat >&3)) ``` ### Read stdin line by line in Bash Set stdin as input file: ```bash while read line do echo "echo: $line" done < /dev/stdin ``` **Example:** ```bash $ cat | reader.sh ```
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### Read command output as line by line in Bash ```bash while read line do echo "$line" done < <(command) ``` **Example:** ```bash while true; do date; sleep 1; done > stream.log ``` ```bash while read line do echo "$line" done < <(tail -n0 -f stream.log) ```
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Another way of reading command output line by line: ```bash command | while read line do echo "$line" done ``` **Example:** ```bash tail -n0 -f stream.log | while read line do echo "$line" done ```
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### Pipe terminal to another computer's terminal Pipe your terminal to an open TCP socket file descriptor: ```bash $ exec 3<>/dev/tcp/{hostname}/{port} && exec &> >(tee >(cat >&3)) ``` **Example:** Terminal 1 ```bash $ nc -l -p 1337 ``` Terminal 2 ```bash $ exec 3<>/dev/tcp/127.0.0.1/1337 && exec &> >(tee >(cat >&3)) ```
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Alternatively, you can use netcat to pipe your terminal: ```bash $ exec &> >(nc 127.0.0.1 1337) ```
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### Redirect the output of multiple commands ```bash { command1; command2; command3; } > stdout.log 2> stderr.log ``` **Example:** ```bash $ { date ; echo "ok"; >&2 echo "error!"; } > stdout.log 2> stderr.log $ cat stdout.log Sat 29 Aug 2020 11:16:39 AM PDT $ cat stderr.log error! ```
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### Stream audio Stream audio to terminal audio player: ```bash curl -s {http-stream-url} | mpv - ``` **Example:** Streaming mp3 audio from [somafm](https://somafm.com/) to [mpv](https://mpv.io/) player: ```bash $ curl -s http://ice1.somafm.com/defcon-128-mp3 | mpv - ```
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**Example:** Using [`afplay`](https://ss64.com/osx/afplay.html) player (preinstalled on macOS). Note `afplay` doesn't support streaming so we create a file descriptor to stream to. ```bash $ exec 3<> /tmp/file.mp3 && curl -s http://ice1.somafm.com/defcon-128-mp3 | tee >&3 | (sleep 1; afplay /tmp/file.mp3) ``` **Example:** using [`ffplay`](https://ffmpeg.org/ffplay.html) player (preinstalled on Fedora): ```bash $ curl -s http://ice1.somafm.com/defcon-128-mp3 | ffplay -nodisp - ``` **Example:** Using [`youtube-dl`](https://ytdl-org.github.io/youtube-dl/) to get the m3u8 playlist url for `mpv` to stream: ```bash $ youtube-dl -f best -g https://www.youtube.com/watch?v=dQw4w9WgXcQ | xargs -I % curl -s % | mpv --no-video - ```
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### Stream directory contents to remote server Server: ```bash nc -l -s 0.0.0.0 -p 1337 | tar xf - ``` Client: ```bash tar cf - /some/directory | nc {hostname} 1337 ``` **Example:** pipe all content from current client directory to server: Server: ```bash $ nc -l -p 1337 | tar xf - ``` Client: ```bash tar cf - . | nc 127.0.0.1 1337 ```
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A thing to note is that it'd be very easy to for someone to stream all your home directory contents (SSH keys, AWS credentials, etc) if they're able to run this command on your machine! Only run trusted software and monitor outgoing HTTP requests using something like [OpenSnitch](https://github.com/evilsocket/opensnitch). ### Take webcam picture on mouse move **Example:** trigger a webcam picture to be taken when mouse movement events is read from `/dev/input/mouse0`, and wait 10 seconds before listening for another mouse event again: ```bash while true; do sudo cat /dev/input/mouse0 | read -n1; streamer -q -o cam.jpeg -s 640x480 > /dev/null 2>&1; sleep 10; done ```
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### Group commands with OR Group commands with OR operator to try different commands until one succeeds and pipe the result to the next command: ```bash $ ( command || command || command ) | command ``` **Example:** attempt to deflate a gzipped file and pipe text to `less`: ```bash $ echo "hello world" > stream.log; gzip stream.log; FILE=stream.log.gz $ ( zcat $FILE || gzcat $FILE || bzcat2 $FILE ) | less hello world ```
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### Writing standard input to a file ```bash $ cat > file.txt hello world ^D $ cat file.txt hello world ```
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It's the same thing using the `-` argument in cat to indicate that you want to read from stdin, e.g. `cat - > file.txt` ### Concatenating files with standard input in between **Example:** With `cat` can use the `-` in place of a file name to read from stdin. Press _ctrl-d_ to exit the stdin prompt: ```bash $ echo "hello" > 1.txt $ echo "world" > 3.txt $ cat 1.txt - 3.txt > all.txt earth ^D $ cat all.txt hello earth world ```
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### Send commands to terminal through a named pipe **Example:** Set standard input of terminal to FIFO file In terminal 1, create a FIFO file and replace terminal standard input by using `exec`: ```bash $ mkfifo myfifo $ exec < myfifo ``` In terminal 2, write to the FIFO file and see the command being executed in the first terminal. However, the first terminal will close right away. This is because the writer closed the FIFO and the reading process received `EOF`. ```bash $ echo "ls -l" > myfifo ```
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We can create a file descriptor with an open connection to the FIFO pipe to prevent the terminal from closing when writing commands to it. In temrinal 1, run `exec` again to replace standard input: ```bash $ exec < myfifo ``` In terminal 2, use `exec` to create a custom file descriptor `3` and redirect the standard output to the named pipe. Now we can echo commands to this file descriptor and the first terminal will execute them and remain opened. ```bash $ exec 3> myfifo $ echo "ls -l" >&3 ```
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Use the FD close operator `{fd}>&-` with `exec` to close the file descriptor opened for writing to the FIFO: ```bash $ exec 3>&- ```
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### Filter input for reading with process substitution In this example, we'll create a program that will intake a filtered output of `ls -l` and print a formatted string. Print long form of `ls`: ```bash $ ls -l total 8 -rw-r--r-- 1 mota mota 2247 Oct 10 19:51 book.pdf -rw-r--r-- 1 mota mota 465 Oct 10 19:51 data.txt ``` Strip out first line: ```bash $ ls -l | tail -n+2 -rw-r--r-- 1 mota mota 2247 Oct 10 19:51 book.pdf -rw-r--r-- 1 mota mota 465 Oct 10 19:51 data.txt ``` Print only the size and filename columns: ```bash $ ls -l | tail -n+2 | awk '{print $5 " " $9}' 2247 book.pdf 465 data.txt ``` Now that we know what filter pipeline we'll use, let's create a program that reads line by line the output of the pipeline through process substitution as standard input and prints a formatted string for every line: `program.sh` ```bash while read size filename; do cat << EOF $filename is $size bytes EOF done < <(ls -l | tail -n+2 | awk '{print $5 " " $9}') ``` ```bash $ ./program.sh book.pdf is 2247 bytes data.txt is 465 bytes ```
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## Contributing Pull requests are welcome! For contributions please create a new branch and submit a pull request for review. ## Resources - [GNU Bash Manual - Redirections](https://www.gnu.org/software/bash/manual/html_node/Redirections.html) - [Advanced Bash-Scripting Guide: Process Substitution](https://tldp.org/LDP/abs/html/process-sub.html) - [Introduction to Linux - I/O redirection](https://linux.die.net/Intro-Linux/chap_05.html) - [The Linux Command Line](http://linuxcommand.org/tlcl.php) - [Bash One-Liners Explained: All about redirections](https://catonmat.net/bash-one-liners-explained-part-three) - [Bash Redirection Cheat Sheet](https://catonmat.net/ftp/bash-redirections-cheat-sheet.pdf) ## License [MIT](LICENSE) @ [Miguel Mota](https://github.com/miguelmota/)