I'm confused over whether bash variables are exported to subshells and when they are accessible by scripts. My experience so far led me to believe that bash variables are automatically available to subshells. E.g.:

> FOO=bar
> echo $FOO
> (echo $FOO)

The above appears to demonstrate that bash variables are accessible in subshells.

Given this script:

#! /usr/bin/bash
# c.sh

  echo before
  echo ${FOO}
  echo after


I understand that calling the script in the current shell context gives it access to the current shell's variables:

> . ./c.sh 

If I were to call the script without the "dot space" precedent...

> ./c.sh 


...isn't it the case that the script is called in a subshell? If so, and it's also true that the current shell's variables are available to subshells (as I inferred from the firstmost code-block), why is $FOO not available to c.sh when run this way?

Similarly, why is $FOO also unavailable when c.sh is run within parentheses - which I understood to mean running the expression in a subshell:

> (./c.sh)


(If this doesn't muddy this post with too many questions: if "./c.sh" and "(./c.sh)" both run the script in a subshell of the current shell, what's the difference between the two ways of calling?)

  • 3
    A subshell is forked off the parent process, so a variable doesn't need to be exported to be visible in it: Child processes always inherit 100% of their parent process's state (except for the PID itself, and file descriptors which were explicitly opened with flags instructing the OS not to copy them on fork). Aug 17, 2018 at 22:57
  • 6
    So ./foo does not run foo in a subshell: It's a completely unrelated child process, behind not just a fork() but an execve() boundary. Aug 17, 2018 at 22:58
  • 5
    ...whereas (./c.sh) forks off a subshell, and then runs a child process from inside it, so the child process is a grandchild rather than a direct child of the original shell, and you have an execv boundary between the child and the grandchild (albeit none between parent and child). Aug 17, 2018 at 23:05
  • 2
    You tagged shell so I would like to point out that not all shells handle sub-shells in the same way as bash. Korn shell, for example, avoids creating a child process for a sub-shell.
    – cdarke
    Aug 18, 2018 at 6:57
  • 1
    @cdarke, ...I'd rather say that ksh implements (...)'s "separate environment" semantics without using subshells to the extent possible (when it becomes impossible to comply with POSIX semantics without creating a subshell, a subshell gets created; it's inaccurate to imply that (...) doesn't use them at all). Reading the above as a request to edit my answer to no longer state that (...) requests a subshell (vs requesting an independent environment most readily implemented with a subshell) is fair. Aug 19, 2018 at 13:33

1 Answer 1


(...) runs ... in a separate environment, something most easily achieved (and implemented in bash, dash, and most other POSIX-y shells) using a subshell -- which is to say, a child created by fork()ing the old shell, but not calling any execv-family function. Thus, the entire in-memory state of the parent is duplicated, including non-exported shell variables. And for a subshell, this is precisely what you typically want: just a copy of the parent shell's process image, not replaced with a new executable image and thus keeping all its state in place.

Consider (. shell-library.bash; function-from-that-library "$preexisting_non_exported_variable") as an example: Because of the parens it fork()s a subshell, but it then sources the contents of shell-library.bash directly inside that shell, without replacing the shell interpreter created by that fork() with a separate executable. This means that function-from-that-library can see non-exported functions and variables from the parent shell (which it couldn't if it were execve()'d), and is a bit faster to start up (since it doesn't need to link, load, and otherwise initialize a new shell interpreter as happens during execve() operation); but also that changes it makes to in-memory state, shell configuration, and process attributes like working directory won't modify the parent interpreter that called it (as would be the case if there were no subshell and it weren't fork()'d), so the parent shell is protected from having configuration changes made by the library that could modify its later operation.

./other-script, by contrast, runs other-script as a completely separate executable; it does not retain non-exported variables after the child shell (which is not a subshell!) has been invoked. This works as follows:

  • The shell calls fork() to create a child. At this point in time, the child still has even non-exported variable state copied.
  • The child honors any redirections (if it was ./other-script >>log.out, the child would open("log.out", O_APPEND) and then fdup() the descriptor over to 1, overwriting stdout).
  • The child calls execv("./other-script", {"./other-script", NULL}), instructing the operating system to replace it with a new instance of other-script. After this call succeeds, the process running under the child's PID is an entirely new program, and only exported variables survive.
  • 3
    This is fascinating - I'd never considered fork() and exec() in the context of bash. Is my understanding correct: when I call (./c.sh), a subshell is forked, therefore $FOO is visible in the subshell. But that subshell then fork()s and exec()s ./c.sh, therefore within the context of c.sh (which is sort of a "grandchild process" of the shell where I typed "(./c.sh)"), $FOO is no longer visible ?
    – StoneThrow
    Aug 17, 2018 at 23:22
  • 1
    Second sentence should read "of the parent", no? Not completely certain, hence not just editing ;) Aug 17, 2018 at 23:27
  • 3
    Also, if you use exec ./other-script (which runs exec() without forking first), the other script inherits exported variables, but not non-exported shell variables. ./other-script is mostly equivalent to (exec ./other-script), in which the ( ) forks a subshell (keeping non-exported variables), and then the exec effectively exits the current shell (destroying non-exported variables) and runs a new shell in the same process. Aug 18, 2018 at 5:11
  • 3
    @cdarke: that's not a bashism; it's defined by Posix: "[$$] Expands to the decimal process ID of the invoked shell. In a subshell (see Shell Execution Environment ), '$' shall expand to the same value as that of the current shell."
    – rici
    Aug 18, 2018 at 7:13
  • 2
    @Harry, fork()ing creates a copy of the parent as a child, then execve() replaces that copy of the parent with the program you want to have as your child (when what you want is in fact a different program; for a subshell, what you typically want is just a copy of the parent with no replacement). Sep 12, 2021 at 18:41

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