How can I send the stdout of one process to multiple processes using (preferably unnamed) pipes in Unix (or Windows)? How can I send the stdout of one process to multiple processes using (preferably unnamed) pipes in Unix (or Windows)? windows windows

How can I send the stdout of one process to multiple processes using (preferably unnamed) pipes in Unix (or Windows)?


Editor's note:
- >(…) is a process substitution that is a nonstandard shell feature of some POSIX-compatible shells: bash, ksh, zsh.
- This answer accidentally sends the output process substitution's output through the pipeline too: echo 123 | tee >(tr 1 a) | tr 1 b.
- Output from the process substitutions will be unpredictably interleaved, and, except in zsh, the pipeline may terminate before the commands inside >(…) do.

In unix (or on a mac), use the tee command:

$ echo 123 | tee >(tr 1 a) >(tr 1 b) >/dev/nullb23a23

Usually you would use tee to redirect output to multiple files, but using >(...) you canredirect to another process. So, in general,

$ proc1 | tee >(proc2) ... >(procN-1) >(procN) >/dev/null

will do what you want.

Under windows, I don't think the built-in shell has an equivalent. Microsoft's Windows PowerShell has a tee command though.


Like dF said, bash allows to use the >(…) construct running a command in place of a filename. (There is also the <(…) construct to substitute the output of another command in place of a filename, but that is irrelevant now, I mention it just for completeness).

If you don't have bash, or running on a system with an older version of bash, you can do manually what bash does, by making use of FIFO files.

The generic way to achieve what you want, is:

  • decide how many processes should receive the output of your command, and create as many FIFOs, preferably on a global temporary folder:
    subprocesses="a b c d"    mypid=$$    for i in $subprocesses # this way we are compatible with all sh-derived shells      do        mkfifo /tmp/pipe.$mypid.$i    done
  • start all your subprocesses waiting input from the FIFOs:
    for i in $subprocesses    do        tr 1 $i </tmp/pipe.$mypid.$i & # background!    done
  • execute your command teeing to the FIFOs:
    proc1 | tee $(for i in $subprocesses; do echo /tmp/pipe.$mypid.$i; done)
  • finally, remove the FIFOs:
    for i in $subprocesses; do rm /tmp/pipe.$mypid.$i; done

NOTE: for compatibility reasons, I would do the $(…) with backquotes, but I couldn't do it writing this answer (the backquote is used in SO). Normally, the $(…) is old enough to work even in old versions of ksh, but if it doesn't, enclose the part in backquotes.


Unix (bash, ksh, zsh)

dF.'s answer contains the seed of an answer based on tee and output process substitutions
(>(...)) that may or may not work, depending on your requirements:

Note that process substitutions are a nonstandard feature that (mostly) POSIX-features-only shells such as dash (which acts as /bin/sh on Ubuntu, for instance), do not support. Shell scripts targeting /bin/sh should not rely on them.

echo 123 | tee >(tr 1 a) >(tr 1 b) >/dev/null

The pitfalls of this approach are:

  • unpredictable, asynchronous output behavior: the output streams from the commands inside the output process substitutions >(...) interleave in unpredictable ways.

  • In bash and ksh (as opposed to zsh - but see exception below):

    • output may arrive after the command has finished.
    • subsequent commands may start executing before the commands in the process substitutions have finished - bash and ksh do not wait for the output process substitution-spawned processes to finish, at least by default.
    • jmb puts it well in a comment on dF.'s answer:

be aware that the commands started inside >(...) are dissociated from the original shell, and you can't easily determine when they finish; the tee will finish after writing everything, but the substituted processes will still be consuming the data from various buffers in the kernel and file I/O, plus whatever time is taken by their internal handling of data. You can encounter race conditions if your outer shell then goes on to rely on anything produced by the sub-processes.

  • zsh is the only shell that does by default wait for the processes run in the output process substitutions to finish, except if it is stderr that is redirected to one (2> >(...)).

  • ksh (at least as of version 93u+) allows use of argument-less wait to wait for the output process substitution-spawned processes to finish.
    Note that in an interactive session that could result in waiting for any pending background jobs too, however.

  • bash v4.4+ can wait for the most recently launched output process substitution with wait $!, but argument-less wait does not work, making this unsuitable for a command with multiple output process substitutions.

  • However, bash and ksh can be forced to wait by piping the command to | cat, but note that this makes the command run in a subshell. Caveats:

    • ksh (as of ksh 93u+) doesn't support sending stderr to an output process substitution (2> >(...)); such an attempt is silently ignored.

    • While zsh is (commendably) synchronous by default with the (far more common) stdout output process substitutions, even the | cat technique cannot make them synchronous with stderr output process substitutions (2> >(...)).

  • However, even if you ensure synchronous execution, the problem of unpredictably interleaved output remains.

The following command, when run in bash or ksh, illustrates the problematic behaviors (you may have to run it several times to see both symptoms): The AFTER will typically print before output from the output substitutions, and the output from the latter can be interleaved unpredictably.

printf 'line %s\n' {1..30} | tee >(cat -n) >(cat -n) >/dev/null; echo AFTER

In short:

  • Guaranteeing a particular per-command output sequence:

    • Neither bash nor ksh nor zsh support that.
  • Synchronous execution:

    • Doable, except with stderr-sourced output process substitutions:
      • In zsh, they're invariably asynchronous.
      • In ksh, they don't work at all.

If you can live with these limitations, using output process substitutions is a viable option (e.g., if all of them write to separate output files).


Note that tzot's much more cumbersome, but potentially POSIX-compliant solution also exhibits unpredictable output behavior; however, by using wait you can ensure that subsequent commands do not start executing until all background processes have finished.
See bottom for a more robust, synchronous, serialized-output implementation.


The only straightforward bash solution with predictable output behavior is the following, which, however, is prohibitively slow with large input sets, because shell loops are inherently slow.
Also note that this alternates the output lines from the target commands.

while IFS= read -r line; do   tr 1 a <<<"$line"  tr 1 b <<<"$line"done < <(echo '123')

Unix (using GNU Parallel)

Installing GNU parallel enables a robust solution with serialized (per-command) output that additionally allows parallel execution:

$ echo '123' | parallel --pipe --tee {} ::: 'tr 1 a' 'tr 1 b'a23b23

parallel by default ensures that output from the different commands doesn't interleave (this behavior can be modified - see man parallel).

Note: Some Linux distros come with a different parallel utility, which won't work with the command above; use parallel --version to determine which one, if any, you have.


Windows

Jay Bazuzi's helpful answer shows how to do it in PowerShell. That said: his answer is the analog of the looping bash answer above, it will be prohibitively slow with large input sets and also alternates the output lines from the target commands.



bash-based, but otherwise portable Unix solution with synchronous execution and output serialization

The following is a simple, but reasonably robust implementation of the approach presented in tzot's answer that additionally provides:

  • synchronous execution
  • serialized (grouped) output

While not strictly POSIX compliant, because it is a bash script, it should be portable to any Unix platform that has bash.

Note: You can find a more full-fledged implementation released under the MIT license in this Gist.

If you save the code below as script fanout, make it executable and put int your PATH, the command from the question would work as follows:

$ echo 123 | fanout 'tr 1 a' 'tr 1 b'# tr 1 aa23# tr 1 bb23

fanout script source code:

#!/usr/bin/env bash# The commands to pipe to, passed as a single string each.aCmds=( "$@" )# Create a temp. directory to hold all FIFOs and captured output.tmpDir="${TMPDIR:-/tmp}/$kTHIS_NAME-$$-$(date +%s)-$RANDOM"mkdir "$tmpDir" || exit# Set up a trap that automatically removes the temp dir. when this script# exits.trap 'rm -rf "$tmpDir"' EXIT # Determine the number padding for the sequential FIFO / output-capture names, # so that *alphabetic* sorting, as done by *globbing* is equivalent to# *numerical* sorting.maxNdx=$(( $# - 1 ))fmtString="%0${#maxNdx}d"# Create the FIFO and output-capture filename arraysaFifos=() aOutFiles=()for (( i = 0; i <= maxNdx; ++i )); do  printf -v suffix "$fmtString" $i  aFifos[i]="$tmpDir/fifo-$suffix"  aOutFiles[i]="$tmpDir/out-$suffix"done# Create the FIFOs.mkfifo "${aFifos[@]}" || exit# Start all commands in the background, each reading from a dedicated FIFO.for (( i = 0; i <= maxNdx; ++i )); do  fifo=${aFifos[i]}  outFile=${aOutFiles[i]}  cmd=${aCmds[i]}  printf '# %s\n' "$cmd" > "$outFile"  eval "$cmd" < "$fifo" >> "$outFile" &done# Now tee stdin to all FIFOs.tee "${aFifos[@]}" >/dev/null || exit# Wait for all background processes to finish.wait# Print all captured stdout output, grouped by target command, in sequences.cat "${aOutFiles[@]}"