For code examples, see
EXAMPLES.md
and
share/doc/modernish/examples
- Sick of quoting hell and split/glob pitfalls?
- Tired of brittle shell scripts going haywire and causing damage?
- Mystified by line noise commands like
[
,[[
,((
? - Is scripting basic things just too hard?
- Ever wish that
find
were a built-in shell loop? - Do you want your script to work on nearly any shell on any Unix-like OS?
Modernish is a library for shell script programming which provides features like safer variable and command expansion, new language constructs for loop iteration, and much more. Modernish programs are shell programs; the new constructs are mixed with shell syntax so that the programmer can take advantage of the best of both.
There is no compiled code to install, as modernish is written entirely in the shell language. It can be deployed in embedded or multi-user systems in which new binary executables may not be introduced for security reasons, and is portable among numerous shell implementations. The installer can also bundle a reduced copy of the library with your scripts, so they can run portably with a known version of modernish without requiring prior installation.
Join us and help breathe some new life into the shell! We are looking for testers, early adopters, and developers to join us. Download the latest release or check out the very latest development code from the master branch. Read through the documentation below. Play with the example scripts and write your own. Try to break the library and send reports of breakage.
- Getting started
- Two basic forms of a modernish program
- Interactive use
- Non-interactive command line use
- Shell capability detection
- Names and identifiers
- Reliable emergency halt
- Low-level shell utilities
- Testing numbers, strings and files
- The stack
- Modules
use safe
use var/loop
use var/local
use var/arith
use var/assign
use var/readf
use var/shellquote
use var/stack
use var/string
use var/unexport
use var/genoptparser
use sys/base
use sys/cmd
use sys/dir
use sys/term
- Appendix A: List of shell cap IDs
- Appendix B: Regression test suite
- Appendix C: Supported locales
- Appendix D: Supported shells
- Appendix E: zsh: integration with native scripts
- Appendix F: Bundling modernish with your script
Run install.sh
and follow instructions, choosing your preferred shell
and install location. After successful installation you can run modernish
shell scripts and write your own. Run uninstall.sh
to remove modernish.
Both the install and uninstall scripts are interactive by default, but support fully automated (non-interactive) operation as well. Command line options are as follows:
install.sh
[ -n
] [ -s
shell ] [ -f
] [ -P
pathspec ]
[ -d
installroot ] [ -D
prefix ] [ -B
scriptfile ... ]
-n
: non-interactive operation-s
: specify default shell to execute modernish-f
: force unconditional installation on specified shell-P
: specify an alternativeDEFPATH
for the installation (be careful; usually not recommended)-d
: specify root directory for installation-D
: extra destination directory prefix (for packagers)-B:
bundle modernish with your scripts (-D
required,-n
implied), see Appendix F
uninstall.sh
[ -n
] [ -f
] [ -d
installroot ]
-n
: non-interactive operation-f
: delete*/modernish
directories even if files left-d
: specify root directory of modernish installation to uninstall
In the simple form, modernish is added to a script written for a specific shell. In the portable form, your script is shell-agnostic and may run on any shell that can run modernish.
The simplest way to write a modernish program is to source modernish as a dot script. For example, if you write for bash:
#! /bin/bash
. modernish
use safe
use sys/base
...your program starts here...
The modernish use
command load modules with optional functionality. The
safe
module initialises the safe mode.
The sys/base
module contains modernish versions of certain basic but
non-standardised utilities (e.g. readlink
, mktemp
, which
), guaranteeing
that modernish programs all have a known version at their disposal. There are
many other modules as well. See Modules for more
information.
The above method makes the program dependent on one particular shell (in this case, bash). So it is okay to mix and match functionality specific to that particular shell with modernish functionality.
(On zsh, there is a way to integrate modernish with native zsh scripts. See Appendix E.)
The most portable way to write a modernish program is to use the special generic hashbang path for modernish programs. For example:
#! /usr/bin/env modernish
#! use safe
#! use sys/base
...your program begins here...
For portability, it is important there is no space after env modernish
;
NetBSD and OpenBSD consider trailing spaces part of the name, so env
will
fail to find modernish.
A program in this form is executed by whatever shell the user who installed modernish on the local system chose as the default shell. Since you as the programmer can't know what shell this is (other than the fact that it passed some rigorous POSIX compliance testing executed by modernish), a program in this form must be strictly POSIX compliant – except, of course, that it should also make full use of the rich functionality offered by modernish.
Note that modules are loaded in a different way: the use
commands are part of
hashbang comment (starting with #!
like the initial hashbang path). Only such
lines that immediately follow the initial hashbang path are evaluated; even
an empty line in between causes the rest to be ignored.
This special way of pre-loading modules is needed to make any aliases they
define work reliably on all shells.
Modernish is primarily designed to enhance shell programs/scripts, but also
offers features for use in interactive shells. For instance, the new repeat
loop construct from the var/loop
module can be quite practical to repeat
an action x times, and the safe
module on interactive shells provides
convenience functions for manipulating, saving and restoring the state of
field splitting and globbing.
To use modernish on your favourite interactive shell, you have to add it to
your .profile
, .bashrc
or similar init file.
Important: Upon initialising, modernish adapts itself to
other settings, such as the locale. It also removes certain aliases that
may keep modernish from initialising properly. So you have to organise your
.profile
or similar file in the following order:
- first, define general system settings (
PATH
, locale, etc.); - then,
. modernish
anduse
any modules you want; - then define anything that may depend on modernish, and set your aliases.
After installation, the modernish
command can be invoked as if it were a
shell, with the standard command line options from other shells (such as
-c
to specify a command or script directly on the command line), plus some
enhancements. The effect is that the shell chosen at installation time will
be run enhanced with modernish functionality. It is not possible to use
modernish as an interactive shell in this way.
Usage:
modernish
[--use=
module | shelloption ... ] [ scriptfile ] [ arguments ]modernish
[--use=
module | shelloption ... ]-c
[ script [ me-name [ arguments ] ] ]modernish --test
[ testoption ... ]modernish
[--version
|--help
]
In the first form, the script in the file scriptfile is loaded and executed with any arguments assigned to the positional parameters.
In the second form, -c
executes the specified modernish
script, optionally with the me-name assigned to $ME
and the
arguments assigned to the positional parameters.
The --use
option pre-loads any given modernish modules
before executing the script.
The module argument to each specified --use
option is split using
standard shell field splitting. The first field is the module name and any
further fields become arguments to that module's initialisation routine.
Any given short-form or long-form shelloptions are
set or unset before executing the script. Both POSIX
shell options
and shell-specific options are supported, depending on
the shell executing modernish.
Using the shell option -e
or -o errexit
is an error, because modernish
does not support it and
would break.
The --test
option runs the regression test suite and exits. This verifies
that the modernish installation is functioning correctly. See
Appendix B
for more information.
The --version
and --help
options output the relative information and exit.
- Count to 10 using a basic loop:
modernish --use=var/loop -c 'LOOP for i=1 to 10; DO putln "$i"; DONE'
- Run a portable-form
modernish program using zsh and enhanced-prompt xtrace:
zsh /usr/local/bin/modernish -o xtrace /path/to/program.sh
Modernish includes a battery of shell feature, quirk and bug detection tests, each of which is given a special capability ID. See Appendix A for a list of shell capabilities that modernish currently detects, as well as further general information on the capability detection framework.
thisshellhas
is the central function of the capability detection
framework. It not only tests for the presence of shell features/quirks/bugs,
but can also detect specific shell built-in commands, shell reserved words,
shell options (short or long form), and signals.
Modernish itself extensively uses capability detection to adapt itself to the shell it's running on. This is how it works around shell bugs and takes advantage of efficient features not all shells have. But any script using the library can do this in the same way, with the help of this function.
Test results are cached in memory, so repeated checks using thisshellhas
are efficient and there is no need to avoid calling it to optimise
performance.
Usage:
thisshellhas
item ...
- If item contains only ASCII capital letters A-Z, digits 0-9 or
_
, return the result status of the associated modernish capability detection test. - If item is any other ASCII word, check if it is a shell reserved word or built-in command on the current shell.
- If item is
--
(end-of-options delimiter), disable the recognition of operators starting with-
for subsequent items. - If item starts with
--rw=
or--kw=
, check if the identifier immediately following these characters is a shell reserved word (a.k.a. shell keyword). - If item starts with
--bi=
, similarly check for a shell built-in command. - If item starts with
--sig=
, check if the shell knows about a signal (usable bykill
,trap
, etc.) by the name or number following the=
. If a number > 128 is given, the remainder of its division by 128 is checked. If the signal is found, its canonicalised signal name is left in theREPLY
variable, otherwiseREPLY
is unset. (If multiple--sig=
items are given and all are found,REPLY
contains only the last one.) - If item is
-o
followed by a separate word, check if this shell has a long-form shell option by that name. - If item is any other letter or digit preceded by a single
-
, check if this shell has a short-form shell option by that character. - item can also be one of the following two operators.
--cache
runs all external modernish shell capability tests that have not yet been run, causing the cache to be complete.--show
performs a--cache
and then outputs all the IDs of positive results, one per line.
thisshellhas
continues to process items until one of them produces a
negative result or is found invalid, at which point any further items are
ignored. So the function only returns successfully if all the items
specified were found on the current shell. (To check if either one item or
another is present, use separate thisshellhas
invocations separated by the
||
shell operator.)
Exit status: 0 if this shell has all the items in question; 1 if not; 2 if an item was encountered that is not recognised as a valid identifier.
Note: The tests for the presence of reserved words, built-in commands, shell options, and signals are different from capability detection tests in an important way: they only check if an item by that name exists on this shell, and don't verify that it does the same thing as on another shell.
All modernish functions require portable variable and shell function names,
that is, ones consisting of ASCII uppercase and lowercase letters, digits,
and the underscore character _
, and that don't begin with digit. For shell
option names, the constraints are the same except a dash -
is also
accepted. An invalid identifier is generally treated as a fatal error.
Function-local variables are not supported by the standard POSIX shell; only
global variables are provided for. Modernish needs a way to store its
internal state without interfering with the program using it. So most of the
modernish functionality uses an internal namespace _Msh_*
for variables,
functions and aliases. All these names may change at any time without
notice. Any names starting with _Msh_
should be considered sacrosanct and
untouchable; modernish programs should never directly use them in any way.
Of course this is not enforceable, but names starting with _Msh_
should be
uncommon enough that no unintentional conflict is likely to occur.
Modernish provides certain constants (read-only variables) to make life easier. These include:
$MSH_VERSION
: The version of modernish.$MSH_PREFIX
: Installation prefix for this modernish installation (e.g. /usr/local).$MSH_MDL
: Main modules directory.$MSH_AUX
: Main helper scripts directory.$MSH_CONFIG
: Path to modernish user configuration directory.$ME
: Path to the current program. Replacement for$0
. This is necessary if the hashbang path#!/usr/bin/env modernish
is used, or if the program is launched likesh /path/to/bin/modernish /path/to/script.sh
, as these set$0
to the path to bin/modernish and not your program's path.$MSH_SHELL
: Path to the default shell for this modernish installation, chosen at install time (e.g. /bin/sh). This is a shell that is known to have passed all the modernish tests for fatal bugs. Cross-platform scripts should use it instead of hard-coding /bin/sh, because on some operating systems (NetBSD, OpenBSD, Solaris) /bin/sh is not POSIX compliant.$SIGPIPESTATUS
: The exit status of a command killed bySIGPIPE
(a broken pipe). For instance, if you usegrep something somefile.txt | more
and you quitmore
beforegrep
is finished,grep
is killed bySIGPIPE
and exits with that particular status. Hardened commands or functions may need to handle such aSIGPIPE
exit specially to avoid unduly killing the program. The exact value of this exit status is shell-specific, so modernish runs a quick test to determine it at initialisation time.
IfSIGPIPE
was set to ignore by the process that invoked the current shell,$SIGPIPESTATUS
can't be detected and is set to the special value 99999. See also the description of theWRN_NOSIGPIPE
ID forthisshellhas
.$DEFPATH
: The default system path guaranteed to find compliant POSIX utilities, as given bygetconf PATH
.$ERROR
: A guaranteed unset variable that can be used to trigger an error that exits the (sub)shell, for instance:: "${4+${ERROR:?excess arguments}}"
(error on 4 or more arguments)
POSIX does not provide for the quoted C-style escape codes commonly used in
bash, ksh and zsh (such as $'\n'
to represent a newline character),
leaving the standard shell without a convenient way to refer to control
characters. Modernish provides control character constants (read-only
variables) with hexadecimal suffixes $CC01
.. $CC1F
and $CC7F
, as well as $CCe
,
$CCa
, $CCb
, $CCf
, $CCn
, $CCr
, $CCt
, $CCv
(corresponding with
printf
backslash escape codes). This makes it easy to insert control
characters in double-quoted strings.
More convenience constants, handy for use in bracket glob patterns for use
with case
or modernish match
:
$CONTROLCHARS
: All ASCII control characters.$WHITESPACE
: All ASCII whitespace characters.$ASCIIUPPER
: The ASCII uppercase letters A to Z.$ASCIILOWER
: The ASCII lowercase letters a to z.$ASCIIALNUM
: The ASCII alphanumeric characters 0-9, A-Z and a-z.$SHELLSAFECHARS
: Safe-list for shell-quoting.$ASCIICHARS
: The complete set of ASCII characters (minus NUL).
Usage examples:
# Use a glob pattern to check against control characters in a string:
if str match "$var" "*[$CONTROLCHARS]*"; then
putln "\$var contains at least one control character"
fi
# Use '!' (not '^') to check for characters *not* part of a particular set:
if str match "$var" "*[!$ASCIICHARS]*"; then
putln "\$var contains at least one non-ASCII character" ;;
fi
# Safely split fields at any whitespace, comma or slash (requires safe mode):
use safe
LOOP for --split=$WHITESPACE,/ field in $my_items; DO
putln "Item: $field"
DONE
The die
function reliably halts program execution, even from within
subshells, optionally
printing an error message. Note that die
is meant for an emergency program
halt only, i.e. in situations were continuing would mean the program is in an
inconsistent or undefined state. Shell scripts running in an inconsistent or
undefined state may wreak all sorts of havoc. They are also notoriously
difficult to terminate correctly, especially if the fatal error occurs within
a subshell: exit
won't work then. That's why die
is optimised for
killing all the program's processes (including subshells and external
commands launched by it) as quickly as possible. It should never be used for
exiting the program normally.
On interactive shells, die
behaves differently. It does not kill or exit your
shell; instead, it issues SIGINT
to the shell to abort the execution of your
running command(s), which is equivalent to pressing Ctrl+C.
In addition, if die
is invoked from a subshell such as a background job, it
kills all processes belonging to that job, but leaves other running jobs alone.
Usage: die
[ message ]
If the trap stack module
is active, a special
DIE
pseudosignal
can be trapped (using plain old trap
or
pushtrap
)
to perform emergency cleanup commands upon invoking die
.
If the MSH_HAVE_MERCY
variable is set in a script and die
is invoked
from a subshell, then die
will only terminate the current subshell and its
subprocesses and will not execute DIE
traps, allowing the script to resume
execution in the parent process. This is for use in special cases, such as
regression tests, and is strongly discouraged for general use. Modernish
unsets the variable on init so it cannot be inherited from the environment.
The POSIX shell lacks a simple, straightforward and portable way to output arbitrary strings of text, so modernish adds two commands for this.
put
prints each argument separated by a space, without a trailing newline.putln
prints each argument, terminating each with a newline character.
There is no processing of options or escape codes. (Modernish constants
$CCn
, etc.
can be used to insert control characters in double-quoted strings. To process escape codes, use
printf
instead.)
The echo
command is notoriously unportable and kind of broken, so is
deprecated in favour of put
and putln
. Modernish does provide its own
version of echo
, but it is only activated for
portable-form)
scripts. Otherwise, the shell-specific version of echo
is left intact.
The modernish version of echo
does not interpret any escape codes
and supports only one option, -n
, which, like BSD echo
, suppresses the
final newline. However, unlike BSD echo
, if -n
is the only argument, it is
not interpreted as an option and the string -n
is printed instead. This makes
it safe to output arbitrary data using this version of echo
as long as it is
given as a single argument (using quoting if needed).
Modernish sets three aliases that can help to make the shell language look slightly friendlier. Their use is optional.
not
is a new synonym for !
. They can be used interchangeably.
so
is a command that tests if the previous command exited with a status
of zero, so you can test the preceding command's success with if so
or
if not so
.
forever
is a new synonym for while :;
. This allows simple infinite loops
of the form: forever do
stuff; done
.
The exit
command can be used as normal, but has gained capabilities.
Extended usage: exit
[ -u
] [ status [ message ] ]
- As per standard, if status is not specified, it defaults to the exit
status of the command executed immediately prior to
exit
. Otherwise, it is evaluated as a shell arithmetic expression. If it is invalid as such, the shell exits immediately with an arithmetic error. - Any remaining arguments after status are combined, separated by spaces,
and taken as a message to print on exit. The message shown is preceded by
the name of the current program (
$ME
minus directories). Note that it is not possible to skip status while specifying a message. - If the
-u
option is given, and the shell functionshowusage
is defined, that function is run in a subshell before exiting. It is intended to print a message showing how the command should be invoked. The-u
option has no effect if the script has not defined ashowusage
function. - If status is non-zero, the message and the output of the
showusage
function are redirected to standard error.
chdir
is a robust cd
replacement for use in scripts.
The standard cd
command
is designed for interactive shells and appropriate to use there.
However, for scripts, its features create serious pitfalls:
- The
$CDPATH
variable is searched. A script may inherit a user's exported$CDPATH
, socd
may change to an unintended directory. cd
cannot be used with arbitrary directory names (such as untrusted user input), as some operands have special meanings, even after--
. POSIX specifies that-
changes directory to$OLDPWD
. On zsh (even in sh mode on zsh <= 5.7.1), numeric operands such as+12
or-345
represent directory stack entries. All such paths need escaping by prefixing./
.- Symbolic links in directory path components are not resolved by default, leaving a potential symlink attack vector.
Thus, robust and portable use of cd
in scripts is unreasonably difficult.
The modernish chdir
function calls cd
in a way that takes care of all
these issues automatically: it disables $CDPATH
and special operand
meanings, and resolves symbolic links by default.
Usage: chdir
[ -f
] [ -L
] [ -P
] [ --
] directorypath
Normally, failure to change the present working directory to directorypath
is a fatal error that ends the program. To tolerate failure, add the -f
option; in that case, exit status 0 signifies success and exit status 1
signifies failure, and scripts should always check and handle exceptions.
The options -L
(logical: don't resolve symlinks) and -P
(physical:
resolve symlinks) are the same as in cd
, except that -P
is the default.
Note that on a shell with BUG_CDNOLOGIC
(NetBSD sh),
the -L
option to chdir
does nothing.
To use arbitrary directory names (e.g. directory names input by the user or
other untrusted input) always use the --
separator that signals the end of
options, or paths starting with -
may be misinterpreted as options.
The insubshell
function checks if you're currently running in a
subshell environment
(usually called simply subshell).
A subshell is a copy of the parent shell that starts out as an exact
duplicate (including non-exported variables, functions, etc.), except for
traps. A new subshell is invoked by constructs like (
parentheses)
,
$(
command substitutions)
, pipe|
lines, and &
(to launch a background
subshell). Upon exiting a subshell, all changes to its state are lost.
This is not to be confused with a newly initialised shell that is merely a child process of the current shell, which is sometimes (confusingly and wrongly) called a "subshell" as well. This documentation avoids such a misleading use of the term.
Usage: insubshell
[ -p
| -u
]
This function returns success (0) if it was called from within a subshell and non-success (1) if not. One of two options can be given:
-p
: Store the process ID (PID) of the current subshell or main shell inREPLY
.-u
: Store an identifier inREPLY
that is useful for determining if you've entered a subshell relative to a previously stored identifier. The content and format are unspecified and shell-dependent.
isset
checks if a variable, shell function or option is set, or has
certain attributes. Usage:
isset
varname: Check if a variable is set.isset -v
varname: Id.isset -x
varname: Check if variable is exported.isset -r
varname: Check if variable is read-only.isset -f
funcname: Check if a shell function is set.isset -
optionletter (e.g.isset -C
): Check if shell option is set.isset -o
optionname: Check if shell option is set by long name.
Exit status: 0 if the item is set; 1 if not; 2 if the argument is not
recognised as a valid identifier.
Unlike most other modernish commands, isset
does not treat an invalid
identifier as a fatal error.
When checking a shell option, a nonexistent shell option is not an error,
but returns the same result as an unset shell option. (To check if a shell
option exists, use thisshellhas
.
Note: just isset -f
checks if shell option -f
(a.k.a. -o noglob
) is
set, but with an extra argument, it checks if a shell function is set.
Similarly, isset -x
checks if shell option -x
(a.k.a -o xtrace
)
is set, but isset -x
varname checks if a variable is exported. If you
use unquoted variable expansions here, make sure they're not empty, or
the shell's empty removal mechanism will cause the wrong thing to be checked
(even in the safe mode).
setstatus
manually sets the exit status $?
to the desired value. The
function exits with the status indicated. This is useful in conditional
constructs if you want to prepare a particular exit status for a subsequent
exit
or return
command to inherit under certain circumstances.
The status argument is a parsed as a shell arithmetic expression. A negative
value is treated as a fatal error. The behaviour of values greater than 255
is not standardised and depends on your particular shell.
The test
/[
command is the bane of casual shell scripters. Even advanced
shell programmers are frequently caught unaware by one of the many pitfalls
of its arcane, hackish syntax. It attempts to look like shell grammar without
being shell grammar, causing myriad problems
(1,
2).
Its -a
, -o
, (
and )
operators are inherently and fatally broken as
there is no way to reliably distinguish operators from operands, so POSIX
deprecates their use;
however, most manual pages do not include this essential information, and
even the few that do will not tell you what to do instead.
Ksh, zsh and bash offer a [[
alternative that fixes many of these problems,
as it is integrated into the shell grammar. Nevertheless, it increases
confusion, as entirely different grammar and quoting rules apply
within [[
...]]
than outside it, yet many scripts end up using them
interchangeably. It is also not available on all POSIX shells. (To make
matters worse, Busybox ash has a false-friend [[
that is just an alias
of [
, with none of the shell grammar integration!)
Finally, the POSIX test
/[
command is incompatible with the modernish
"safe mode" which aims to eliminate most of the need to quote variables.
See use safe
for more information.
Modernish deprecates test
/[
and [[
completely. Instead, it offers a
comprehensive alternative command design that works with the usual shell
grammar in a safer way while offering various feature enhancements. The
following replacements are available:
To test if a string is a valid number in shell syntax, str isint
is
available. See String tests.
An implementation of let
as in ksh, bash and zsh is now available to all
POSIX shells. This makes C-style signed integer arithmetic evaluation
available to every
supported shell,
with the exception of the unary ++
and --
operators
(which are a nonstandard shell capability detected by modernish under the ID of
ARITHPP
).
This means let
should be used for operations and tests, e.g. both
let "x=5"
and if let "x==5"; then
... are supported (note: single =
for
assignment, double ==
for comparison). See POSIX
2.6.4 Arithmetic Expansion
for more information on the supported operators.
Multiple expressions are supported, one per argument. The exit status of let
is zero (the shell's idea of success/true) if the last expression argument
evaluates to non-zero (the arithmetic idea of true), and 1 otherwise.
It is recommended to adopt the habit to quote each let
expression with
"
double quotes"
, as this consistently makes everything work as expected:
double quotes protect operators that would otherwise be misinterpreted as
shell grammar, while shell expansions starting with $
continue to work.
Various handy functions that make common arithmetic operations
and comparisons easier to program are available from the
var/arith
module.
The following notes apply to all commands described in the subsections of this section:
- "True" is understood to mean exit status 0, and "false" is understood to mean a non-zero exit status – specifically 1.
- Passing more than the number of arguments specified for each command is a fatal error. (If the safe mode is not used, excessive arguments may be generated accidentally if you forget to quote a variable. The test result would have been wrong anyway, so modernish kills the program immediately, which makes the problem much easier to trace.)
- Passing fewer than the number of arguments specified to the command is
assumed to be the result of removal of an empty unquoted expansion.
Where possible, this is not treated as an error, and an exit status
corresponding to the omitted argument(s) being empty is returned instead.
(This helps make the safe mode possible; unlike
with
test
/[
, paranoid quoting to avoid empty removal is not needed.)
The str
function offers various operators for tests on strings. For
example, str in $foo "bar"
tests if the variable foo
contains "bar".
The str
function takes unary (one-argument) operators that check a property
of a single word, binary (two-argument) operators that check a word against a
pattern, as well as an option that makes binary operators check multiple words
against a pattern.
Usage: str
operator [ word ]
The word is checked for the property indicated by operator; if the result
is true, str
returns status 0, otherwise it returns status 1.
The available unary string test operators are:
empty
: The word is empty.isint
: The word is a decimal, octal or hexadecimal integer number in valid POSIX shell syntax, safe to use withlet
,$((
...))
and other arithmetic contexts on all POSIX-derived shells. This operator ignores leading (but not trailing) spaces and tabs.isvarname
: The word is a valid portable shell variable or function name.
If word is omitted, it is treated as empty, on the assumption that it is an unquoted empty variable. Passing more than one argument after the operator is a fatal error.
Usage: str
operator [ [ word ] pattern ]
The word is compared to the pattern according to the operator; if it
matches, str
returns status 0, otherwise it returns status 1.
The available binary matching operators are:
eq
: word is equal to pattern.ne
: word is not equal to pattern.in
: word includes pattern.begin
: word begins with pattern.end
: word ends with pattern.match
: word matches pattern as a shell glob pattern (as in the shell's nativecase
construct). A pattern that ends in an unescaped backslash is considered invalid and causesstr
to return status 2.ematch
: word matches pattern as a POSIX extended regular expression. An empty pattern is a fatal error. (In UTF-8 locales, check ifthisshellhas WRN_EREMBYTE
before matching multi-byte characters.)lt
: word lexically sorts before (is 'less than') pattern.le
: word is lexically 'less than or equal to' pattern.gt
: word lexically sorts after (is 'greater than') pattern.ge
: word is lexically 'greater than or equal to' pattern.
If word is omitted, it is treated as empty on the assumption that it is an unquoted empty variable, and the single remaining argument is assumed to be the pattern. Similarly, if both word and pattern are omitted, an empty word is matched against an empty pattern. Passing more than two arguments after the operator is a fatal error.
Usage: str -M
operator [ [ word ... ] pattern ]
The -M
option causes str
to compare any number of words to the
pattern. The available operators are the same as the binary string
matching operators listed above.
All matching words are stored in the REPLY
variable, separated
by newline characters ($CCn
) if there is more than one match.
If no words match, REPLY
is unset.
The exit status returned by str -M
is as follows:
- If no words match, the exit status is 1.
- If one word matches, the exit status is 0.
- If between two and 254 words match, the exit status is the number of matches.
- If 255 or more words match, the exit status is 255.
Usage example: the following matches a given GNU-style long-form command
line option $1
against a series of available options. To make it possible
for the options to be abbreviated, we check if any of the options begin with
the given argument $1
.
if str -M begin --fee --fi --fo --fum --foo --bar --baz --quux "$1"; then
putln "OK. The given option $1 matched $REPLY"
else
case $? in
( 1 ) putln "No such option: $1" >&2 ;;
( * ) putln "Ambiguous option: $1" "Did you mean:" "$REPLY" >&2 ;;
esac
fi
These avoid the snags with symlinks you get with [
and [[
.
By default, symlinks are not followed. Add -L
to operate on files
pointed to by symlinks instead of symlinks themselves (the -L
makes
no difference if the operands are not symlinks).
These commands all take one argument. If the argument is absent, they return false. More than one argument is a fatal error. See notes 1-3 in the parent section.
is present
file: Returns true if the file is present in the file
system (even if it is a broken symlink).
is -L present
file: Returns true if the file is present in the file
system and is not a broken symlink.
is sym
file: Returns true if the file is a symbolic link (symlink).
is -L sym
file: Returns true if the file is a non-broken symlink, i.e.
a symlink that points (either directly or indirectly via other symlinks)
to a non-symlink file that is present in the file system.
is reg
file: Returns true if file is a regular data file.
is -L reg
file: Returns true if file is either a regular data file
or a symlink pointing (either directly or indirectly via other symlinks)
to a regular data file.
Other commands are available that work exactly like is reg
and is -L reg
but test for other file types. To test for them, replace reg
with one of:
dir
for a directoryfifo
for a named pipe (FIFO)socket
for a socketblockspecial
for a block special filecharspecial
for a character special file
The following notes apply to these commands:
- Symlinks are not resolved/followed by default. To operate on files pointed
to by symlinks, add
-L
before the operator argument, e.g.is -L newer
. - Omitting any argument is a fatal error, because no empty argument (removed or otherwise) would make sense for these commands.
is newer
file1 file2: Compares file timestamps, returning true if file1
is newer than file2. Also returns true if file1 exists, but file2 does
not; this is consistent for all shells (unlike test file1 -nt file2
).
is older
file1 file2: Compares file timestamps, returning true if file1
is older than file2. Also returns true if file1 does not exist, but file2
does; this is consistent for all shells (unlike test file1 -ot file2
).
is samefile
file1 file2: Returns true if file1 and file2 are the same
file (hardlinks).
is onsamefs
file1 file2: Returns true if file1 and file2 are on the
same file system. If any non-regular, non-directory files are specified, their
parent directory is tested instead of the file itself.
These always follow symlinks.
is nonempty
file: Returns true if the file exists, is not a broken
symlink, and is not empty. Unlike [ -s file ]
, this also works
for directories, as long as you have read permission in them.
is setuid
file: Returns true if the file has its set-user-ID flag set.
is setgid
file: Returns true if the file has its set-group-ID flag set.
is onterminal
FD: Returns true if file descriptor FD is associated
with a terminal. The FD may be a non-negative integer number or one of the
special identifiers stdin
, stdout
and stderr
which are equivalent to
0, 1, and 2. For instance, is onterminal stdout
returns true if commands
that write to standard output (FD 1), such as putln
, would write to the
terminal, and false if the output is redirected to a file or pipeline.
Any symlinks given are resolved, as these tests would be meaningless for a symlink itself.
can read
file: True if the file's permission bits indicate that you can read
the file - i.e., if an r
bit is set and applies to your user.
can write
file: True if the file's permission bits indicate that you can
write to the file: for non-directories, if a w
bit is set and applies to your
user; for directories, both w
and x
.
can exec
file: True if the file's type and permission bits indicate that
you can execute the file: for regular files, if an x
bit is set and applies
to your user; for other file types, never.
can traverse
file: True if the file is a directory and its permission bits
indicate that a path can traverse through it to reach its subdirectories: for
directories, if an x
bit is set and applies to your user; for other file
types, never.
In modernish, every variable and shell option gets its own stack. Arbitrary values/states can be pushed onto the stack and popped off it in reverse order. For variables, both the value and the set/unset state is (re)stored.
Usage:
push
[--key=
value ] item [ item ... ]pop
[--keepstatus
] [--key=
value ] item [ item ... ]
where item is a valid portable variable name, a short-form shell option
(dash plus letter), or a long-form shell option (-o
followed by an option
name, as two arguments).
Before pushing or popping anything, both functions check if all the given
arguments are valid and pop
checks all items have a non-empty stack. This
allows pushing and popping groups of items with a check for the integrity of
the entire group. pop
exits with status 0 if all items were popped
successfully, and with status 1 if one or more of the given items could not
be popped (and no action was taken at all).
The --key=
option is an advanced feature that can help different modules
or functions to use the same variable stack safely. If a key is given to
push
, then for each item, the given key value is stored along with the
variable's value for that position in the stack. Subsequently, restoring
that value with pop
will only succeed if the key option with the same key
value is given to the pop
invocation. Similarly, popping a keyless value
only succeeds if no key is given to pop
. If there is any key mismatch, no
changes are made and pop
returns status 2. Note that this is
a robustness/convenience feature, not a security feature; the keys are not
hidden in any way.
If the --keepstatus
option is given, pop
will exit with the
exit status of the command executed immediately prior to calling pop
. This
can avoid the need for awkward workarounds when restoring variables or shell
options at the end of a function. However, note that this makes failure to pop
(stack empty or key mismatch) a fatal error that kills the program, as pop
no longer has a way to communicate this through its exit status.
push
and pop
allow saving and restoring the state of any shell option
available to the set
builtin. The precise shell options supported
(other than the ones guaranteed by POSIX) depend on
the shell modernish is running on.
To facilitate portability, nonexistent shell options are treated as unset.
Long-form shell options are matched to their equivalent short-form shell
options, if they exist. For instance, on all POSIX shells, -f
is
equivalent to -o noglob
, and push -o noglob
followed by pop -f
works
correctly. This also works for shell-specific short & long option
equivalents.
On shells with a dynamic no
option name prefix, that is on ksh, zsh and
yash (where, for example, noglob
is the opposite of glob
), the no
prefix is ignored, so something like push -o glob
followed by pop -o noglob
does the right thing. But this depends on the shell and should never
be used in portable scripts.
Modernish can also make traps stack-based, so that each
program component or library module can set its own trap commands
without interfering with others. This functionality is provided
by the var/stack/trap
module.
As modularity is one of modernish's
design principles,
much of its essential functionality is provided in the form of loadable
modules, so the core library is kept lean. Modules are organised
hierarchically, with names such as safe
, var/loop
and sys/cmd/harden
. The
use
command loads and initialises a module or a combined directory of modules.
Internally, modules exist in files with the name extension .mm
in
subdirectories of lib/modernish/mdl
– for example, the module
var/stack/trap
corresponds to the file lib/modernish/mdl/var/stack/trap.mm
.
Usage:
use
modulename [ argument ... ]use
[-q
|-e
] modulenameuse -l
The first form loads and initialises a module. All arguments, including the module name, are passed on to the dot script unmodified, so modules know their own name and can implement option parsing to influence their initialisation. See also Two basic forms of a modernish program for information on how to use modules in portable-form scripts.
In the second form, the -q
option queries if a module is loaded, and the -e
option queries if a module exists. use
returns status 0 for yes, 1 for no,
and 2 if the module name is invalid.
The -l
option lists all currently loaded modules in the order in which
they were originally loaded. Just add | sort
for alphabetical order.
If a directory of modules, such as sys/cmd
or even just sys
, is given as the
modulename, then all the modules in that directory and any subdirectories are
loaded recursively. In this case, passing extra arguments is a fatal error.
If a module file X.mm
exists along with a directory X
, resolving to the
same modulename, then use
will load the X.mm
module file without
automatically loading any modules in the X
directory, because it is expected
that X.mm
handles the submodules in X
manually. (This is currently the case
for var/loop
which auto-loads submodules containing loop types on first use).
The complete lib/modernish/mdl
directory path, which depends on where
modernish is installed, is stored in the system constant $MSH_MDL
.
The following subchapters document the modules that come with modernish.
The safe
module sets the 'safe mode' for the shell. It removes most of the
need to quote variables, parameter expansions, command substitutions, or glob
patterns. It uses shell settings and modernish library functionality to secure
and demystify split and glob mechanisms. This creates a new and safer way of
shell script programming, essentially building a new shell language dialect
while still running on all POSIX-compliant shells.
One of the most common headaches with shell scripting is caused by a
fundamental flaw in the shell as a scripting language: constantly
active field splitting (a.k.a. word splitting) and pathname expansion
(a.k.a. globbing). To cope with this situation, it is hammered into
programmers of shell scripts to be absolutely paranoid about properly
quoting nearly everything, including
variable and parameter expansions, command substitutions, and patterns passed
to commands like find
.
These mechanisms were designed for interactive command line usage, where they do come in very handy. But when the shell language is used as a programming language, splitting and globbing often ends up being applied unexpectedly to unquoted expansions and command substitutions, helping cause thousands of buggy, brittle, or outright dangerous shell scripts.
One could blame the programmer for forgetting to quote an expansion properly, or one could blame a pitfall-ridden scripting language design where hammering punctilious and counterintuitive habits into casual shell script programmers is necessary. Modernish does the latter, then fixes it.
Every POSIX shell comes with a little-used ability to disable global field
splitting and pathname expansion: IFS=''; set -f
. An empty IFS
variable
disables split; the -f
(or -o noglob
) shell option disables pathname
expansion. The safe mode sets these, and two others (see below).
The reason these safer settings are hardly ever used is that they are not
practical to use with the standard shell language. For instance, for textfile in *.txt
, or for item in $(some command)
which both (!)
field-splits and pathname-expands the output of a command, all break.
However, that is where modernish comes in. It introduces several powerful new loop constructs, as well as arbitrary code blocks with local settings, each of which has straightforward, intuitive operators for safely applying field splitting or pathname expansion – to specific command arguments only. By default, they are not both applied to the arguments, which is much safer. And your script code as a whole is kept safe from them at all times.
With global field splitting and pathname expansion removed, a third issue
still affects the safe mode: the shell's empty removal mechanism. If the
value of an unquoted expansion like $var
is empty, it will not expand to
an empty argument, but will be removed altogether, as if it were never
there. This behaviour cannot be disabled.
Thankfully, the vast majority of shell and Un*x commands order their arguments
in a way that is actually designed with empty removal in mind, making it a
good thing. For instance, when doing ls $option some_dir
, if $option
is
-l
the listing will be long-format and if is empty it will be removed, which
is the desired behaviour. (An empty argument there would cause an error.)
However, one command that is used in almost all shell scripts, test
/[
,
is completely unable to cope with empty removal due to its idiosyncratic
and counterintuitive syntax. Potentially empty operands come before options,
so operands removed as empty expansions cause errors or, worse, false
positives. Thus, the safe mode does not remove the need for paranoid
quoting of expansions used with test
/[
commands. Modernish fixes
this issue by deprecating test
/[
completely and offering
a safe command design
to use instead, which correctly deals with empty removal.
With the 'safe mode' shell settings, plus the safe, explicit and readable
split and glob operators and test
/[
replacements, the only quoting
requirements left are:
- a very occasional need to stop empty removal from happening;
- to quote
"$@"
and"$*"
until shell bugs are fixed (see notes below).
In addition to the above, the safe mode also sets these shell options:
set -C
(set -o noclobber
) to prevent accidentally overwriting files using output redirection. To force overwrite, use>|
instead of>
.set -u
(set -o nounset
) to make it an error to use unset (that is, uninitialised) variables by default. You'll notice this will catch many typos before they cause you hard-to-trace problems. To bypass the check for a specific variable, use${var-}
instead of$var
(be careful).
- The safe mode is not compatible with existing conventional shell scripts,
written in what we could now call the 'legacy mode'. Essentially, the safe
mode is a new way of shell script programming. That is why it is not enabled
by default, but activated by loading the
safe
module. It is highly recommended that new modernish scripts start out withuse safe
. - The shell applies entirely different quoting rules to string matching glob
patterns within
case
constructs. The safe mode changes nothing here. - Due to shell bugs ID'ed as
BUG_PP_*
, the positional parameters expansions$@
and$*
should still always be quoted. As of late 2018, these bugs have been fixed in the latest or upcoming release versions of all supported shells. But, until buggy versions fall out of use and modernish no longer supports anyBUG_PP_*
shell bugs, quoting"$@"
and"$*"
remains mandatory even in safe mode (unless you know with certainty that your script will be used on a shell with none of these bugs). - The behaviour of
"$*"
changes in safe mode. It uses the first character of$IFS
as the separator for combining all positional parameters into one string. SinceIFS
is emptied in safe mode, there is no separator, so it will string them together unseparated. You can use something likepush IFS; IFS=' '; var="$*"; pop IFS
orLOCAL IFS=' '; BEGIN var="$*"; END
to use the space character as a separator. (If you're outputting the positional parameters, note that theput
command always separates its arguments by spaces, so you can safely pass it multiple arguments with"$@"
instead.)
Usage: use safe
[ -k
| -K
] [ -i
]
The -k
and -K
module options install an extra handler that
reliably kills the program
if it tries to execute a command that is not found, on shells that have the
ability to catch and handle 'command not found' errors (currently bash, yash,
and zsh). This helps catch typos, forgetting to load a module, etc., and stops
your program from continuing in an inconsistent state and potentially causing
damage. The MSH_NOT_FOUND_OK
variable may be set to temporarily disable this
check. The uppercase -K
module option aborts the program on shells that
cannot handle 'command not found' errors (so should not be used for portable
scripts), whereas the lowercase -k
variant is ignored on such shells.
If the -i
option is given, or the shell is interactive, two extra one-letter
functions are loaded, s
and g
. These are pre-command modifiers for use when
split and glob are globally disabled; they allow running a single command with
local split and glob applied to that command's arguments only. They also have
some options designed to manipulate, examine, save, restore, and generally
experiment with the global split and glob state on interactive shells. Type
s --help
and g --help
for more information. In general, the safe mode is
designed for scripts and is not recommended for interactive shells.
The var/loop
module provides an innovative, robust and extensible
shell loop construct. Several powerful loop types are provided, while
advanced shell programmers may find it easy and fun to
create their own.
This construct is also ideal for the
safe mode:
the for
, select
and find
loop types allow you to selectively
apply field splitting and/or pathname expansion to specific arguments
without subjecting a single line of your code to them.
The basic form is a bit different from native shell loops. Note the caps:
LOOP
looptype arguments; DO
your commands here
DONE
The familiar do
...done
block syntax cannot be used because the shell
will not allow modernish to add its own functionality to it. The
DO
...DONE
block does behave in the same way as do
...done
: you can
append redirections at the end, pipe commands into a loop, etc. as usual.
The break
and continue
shell builtin commands also work as normal.
Remember: using lowercase do
...done
with modernish LOOP
will
cause the shell to throw a misleading syntax error. So will using uppercase
DO
...DONE
with the shell's native loops. To help you remember to use the
uppercase variants for modernish loops, the LOOP
keyword itself is also in
capitals.
Loops exist in submodules of var/loop
named after the loop type; for
instance, the find
loop lives in the var/loop/find
module. However, the
core var/loop
module will automatically load a loop type's module when
that loop is first used, so use
-ing individual loop submodules at your
script's startup time is optional.
The LOOP
block internally uses file descriptor 8 to do
its thing.
If your script happens to use FD 8 for other purposes, you should
know that FD 8 is made local to each loop block, and always appears
initially closed within DO
...DONE
.
This simply iterates the loop the number of times indicated. Before the first
iteration, the argument is evaluated as a shell integer arithmetic expression
as in let
and its value used as the number of iterations.
LOOP repeat 3; DO
putln "This line is repeated 3 times."
DONE
This is a slightly enhanced version of the
FOR
loop in BASIC.
It is more versatile than the repeat
loop but still very easy to use.
LOOP for
varname=
initial to limit [ step
increment ]; DO
some commands
DONE
To count from 1 to 20 in steps of 2:
LOOP for i=1 to 20 step 2; DO
putln "$i"
DONE
Note the varname=
initial needs to be one argument as in a shell
assignment (so no spaces around the =
).
If "step
increment" is omitted, increment defaults to 1 if limit is
equal to or greater than initial, or to -1 if limit is less than
initial (so counting backwards 'just works').
Technically precise description: On entry, the initial, limit and
increment values are evaluated once as shell arithmetic expressions as in
let
,
the value of initial is assigned to varname, and the loop iterates.
Before every subsequent iteration, the value of increment (as determined
on the first iteration) is added to the value of varname, then the limit
expression is re-evaluated; as long as the current value of varname is
less (if increment is non-negative) or greater (if increment is
negative) than or equal to the current value of limit, the loop reiterates.
A C-style for loop akin to for (( ))
in ksh93, bash and zsh is now
available on all POSIX-compliant shells, with a slightly different syntax.
The one loop argument contains three arithmetic expressions (as in
let
),
separated by semicolons within that argument. The first is only evaluated
before the first iteration, so is typically used to assign an initial value.
The second is evaluated before each iteration to check whether to continue
the loop, so it typically contains some comparison operator. The third is
evaluated before the second and further iterations, and typically increases
or decreases a value. For example, to count from 1 to 10:
LOOP for "i=1; i<=10; i+=1"; DO
putln "$i"
DONE
However, using complex expressions allows doing much more powerful things.
Any or all of the three expressions may also be left empty (with their
separating ;
character remaining). If the second expression is empty, it
defaults to 1, creating an infinite loop.
(Note that ++i
and i++
can only be used on shells with
ARITHPP
,
but i+=1
or i=i+1
can be used on all POSIX-compliant shells.)
The enumarative for
and select
loop types mirror those already present in
native shell implementations. However, the modernish versions provide safe
field splitting and globbing (pathname expansion) functionality that can be
used without globally enabling split or glob for any of your code – ideal
for the safe mode. They also add a unique operator
for processing text in fixed-size slices. The select
loop type brings
select
functionality to all POSIX shells and not just ksh, zsh and bash.
Usage:
LOOP
[ for
| select
] [ operators ] varname in
argument ... ;
DO
commands ;
DONE
Simple usage example:
LOOP select --glob textfile in *.txt; DO
putln "You chose text file $textfile."
DONE
If the loop type is for
, the loop iterates once for each argument, storing
it in the variable named varname.
If the loop type is select
, the loop presents before each iteration a
numbered menu that allows the user to select one of the arguments. The prompt
from the PS3
variable is displayed and a reply read from standard input. The
literal reply is stored in the REPLY
variable. If the reply was a number
corresponding to an argument in the menu, that argument is stored in the
variable named varname. Then the loop iterates. If the user enters ^D (end of
file), REPLY
is cleared and the loop breaks with an exit status of 1. (To
break the menu loop under other conditions, use the break
command.)
The following operators are supported. Note that the split and glob operators are only for use in the safe mode.
- One of
--split
or--split=
characters. This operator safely applies the shell's field splitting mechanism to the arguments given. The simple--split
operator applies the shell's default field splitting by space, tab, and newline. If you supply one or more of your own characters to split by, each of these characters will be taken as a field separator if it is whitespace, or field terminator if it is non-whitespace. (Note that shells withQRK_IFSFINAL
treat both whitespace and non-whitespace characters as separators.) - One of
--glob
or--fglob
. These operators safely apply shell pathname expansion (globbing) to the arguments given. Each argument is taken as a pattern, whether or not it contains any wildcard characters. For any resulting pathname that starts with-
or+
or is identical to!
or(
,./
is prefixed to keep various commands from misparsing it as an option or operand. Non-matching patterns are treated as follows:--glob
: Any non-matching patterns are quietly removed. If none match, the loop will not iterate but break with exit status 103.--fglob
: All patterns must match. Any nonexistent path terminates the program. Use this if your program would not work after a non-match.
--base=
string. This operator prefixes the given string to each of the arguments, after first applying field splitting and/or pathname expansion if specified. If--glob
or--fglob
are given, then the string is used as a base directory path for pathname expansion, without expanding any wildcard characters in that base directory path itself. If such base directory can't be entered, then if--glob
was given, the loop breaks with status 98, or if--fglob
was given, the program terminates.- One of
--slice
or--slice=
number. This operator divides the arguments in slices of up to number characters. The default slice size is 1 character, allowing for easy character-by-character processing. (Note that shells withWRN_MULTIBYTE
will not slice multi-byte characters correctly.)
If multiple operators are given, their mechanisms are applied in the following order: split, glob, base, slice.
This powerful loop type turns your local POSIX-compliant
find
utility
into a shell loop, safely integrating both find
and xargs
functionality into the POSIX shell. The infamous
pitfalls and limitations
of using find
and xargs
as external commands are gone, as all
the results from find
are readily available to your main shell
script. Any "dangerous" characters in file names (including
whitespace and even newlines) "just work", especially if the
safe mode
is also active. This gives you the flexibility to use either the find
expression syntax, or shell commands (including your own shell functions), or
some combination of both, to decide whether and how to handle each file found.
Usage:
LOOP find
[ options ] varname [ in
path ... ]
[ find-expression ] ;
DO
commands ;
DONE
LOOP find
[ options ] --xargs
[=
arrayname] [ in
path ... ]
[ find-expression ] ;
DO
commands ;
DONE
The loop recursively walks down the directory tree for each path given.
For each file encountered, it uses the find-expression to decide
whether to iterate the loop with the path to the file stored in the
variable referenced by varname. The find-expression is a standard
find
utility expression except as described below.
Any number of paths to search may be specified after the in
keyword.
By default, a nonexistent path is a fatal error.
The entire in
clause may be omitted, in which case it defaults to in .
so the current working directory will be searched. Any argument that starts
with a -
, or is identical to !
or (
, indicates the end of the paths
and the beginning of the find-expression; if you need to explicitly
specify a path with such a name, prefix ./
to it.
Except for syntax errors, any errors or warnings issued by find
are
considered non-fatal and will cause the exit status of the loop to be
non-zero, so your script has the opportunity to handle the exception.
- Any single-letter options supported by your local
find
utility. Note that POSIX specifies-H
and-L
only, so portable scripts should only use these. Options that require arguments (-f
on BSDfind
) are not supported. --xargs
. This operator is specified instead of the varname; it is a syntax error to have both. Instead of one iteration per found item, as many items as possible per iteration are stored into the positional parameters (PPs), so your program can access them in the usual way (using"$@"
and friends). Note that--xargs
therefore overwrites the current PPs (however, a shell function orLOCAL
block will give you local PPs). Modernish clears the PPs upon completion of the loop, but if the loop is exited prematurely (such as bybreak
), the last chunk survives.- On shells with the
KSHARRAY
capability, an extra variant is available:--xargs=
arrayname which uses the named array instead of the PPs. It otherwise works identically.
- On shells with the
--try
. If this option is specified, then if one of the primaries used in the find-expression is not supported by either thefind
utility used by the loop or by modernish itself,LOOP find
will not throw a fatal error but will instead quietly abort the loop without iterating it, set the loop's exit status to 128, and leave the invalid primary in theREPLY
variable. (Expression errors other than 'unknown primary' remain fatal errors.)- One of
--split
or--split=
characters. This operator, which is only accepted in the safe mode, safely applies the shell's field splitting mechanism to the path name(s) given (but not to any patterns in the find-expression, which are passed on to thefind
utility as given). The simple--split
operator applies the shell's default field splitting by space, tab, and newline. Alternatively, you can supply one or more characters to split by. If any pathname resulting from the split starts with-
or+
or is identical to!
or(
,./
is prefixed. - One of
--glob
or--fglob
. These operators are only accepted in the safe mode. They safely apply shell pathname expansion (globbing) to the path name(s) given (but not to any patterns in the find-expression, which are passed on to thefind
utility as given). All path names are taken as patterns, whether or not they contain any wildcard characters. If any pathname resulting from the expansion start with-
or+
or is identical to!
or(
,./
is prefixed. Non-matching patterns are treated as follows:--glob
: Any pattern not matching an existing path will output a warning to standard error and set the loop's exit status to 103 upon normal completion, even if other existing paths are processed successfully. If none match, the loop will not iterate.--fglob
: Any pattern not matching an existing path is a fatal error.
--base=
basedirectory. This operator prefixes the given basedirectory to each of the path names (and thus to each path found byfind
), after first applying field splitting and/or pathname expansion if specified. If--glob
or--fglob
are given, then wildcard characters are only expanded in the path names and not in the prefixed basedirectory. If the basedirectory can't be entered, then either the loop breaks with status 98, or if--fglob
was given, the program terminates.
LOOP find
can use all expression operands supported by your local find
utility; see its manual page. However, portable scripts should use only
operands specified by POSIX
along with the modernish additions described below.
The modernish -iterate
expression primary evaluates as true and causes the
loop to iterate, executing your commands for each matching file. It may be
used any number of times in the find-expression to start a corresponding
series of loop iterations. If it is not given, the loop acts as if the entire
find-expression is enclosed in parentheses with -iterate
appended. If the
entire find-expression is omitted, it defaults to -iterate
.
The modernish -ask
primary asks confirmation of the user. The text of the
prompt may be specified in one optional argument (which cannot start with -
or be equal to !
or (
). Any occurrences of the characters {}
within the
prompt text are replaced with the current pathname. If not specified, the
default prompt is: "{}"?
If the answer is affirmative (y
or Y
in the
POSIX locale), -ask
yields true, otherwise false. This can be used to make
any part of the expression conditional upon user input, and (unlike commands in
the shell loop body) is capable of influencing directory traversal mid-run.
The standard -exec
and -ok
primaries are integrated into the main shell
environment. When used with LOOP find
, they can call a shell builtin command
or your own shell function directly in the main shell (no subshell). Its exit
status is used in the find
expression as a true/false value capable of
influencing directory traversal (for example, when combined with -prune
),
just as if it were an external command -exec'ed with the standard utility.
Some familiar, easy-to-use but non-standard find
operands from GNU and/or
BSD may be used with LOOP find
on all systems. Before invoking the find
utility, modernish translates them internally to portable equivalents.
The following expression operands are made portable:
- The
-or
,-and
and-not
operators: same as-o
,-a
,!
. - The
-true
and-false
primaries, which always yield true/false. - The BSD-style
-depth
n primary, e.g.-depth +4
yields true on depth greater than 4 (minimum 5),-depth -4
yields true on depth less than 4 (maximum 3), and-depth 4
yields true on a depth of exactly 4. - The GNU-style
-mindepth
and-maxdepth
global options. Unlike BSD-depth
, these GNU-isms are pseudo-primaries that always yield true and affect the entireLOOP find
operation.
Expression primaries that write output (-print
and friends) may be used for
debugging or logging the loop. Their output is redirected to standard error.
Upon initialisation, the var/loop/find
module searches for a POSIX-compliant
find
utility under various names in $DEFPATH
and then in $PATH
. To see a
trace of the full command lines of utility invocations when the loop runs, set
the _loop_DEBUG
variable to any value.
For debugging or system-specific usage, it is possible to use a certain find
utility in preference to any others on the system. To do this, add an argument
to a use var/loop/find
command before the first use of the loop. For example:
use var/loop/find bsdfind
(prefer utility by this name)use var/loop/find /opt/local/bin
(look for a utility here first)use var/loop/find /opt/local/bin/gfind
(try this one first)
Some systems come with obsolete or broken find
utilities that don't fully
support -exec ... {} +
aggregating functionality as specified by POSIX.
Normally, this is a fatal error, but passing the -b
/-B
option to the
use
command, e.g. use var/loop/find -b
, enables a compatibility mode
that tolerates this defect. If no compliant find
is found, then an obsolete
or broken find
is used as a last resort, a warning is printed to standard
error, and the variable _loop_find_broken
is set. The -B
option is
equivalent to -b
but does not print a warning. Loop performance may suffer as
modernish adapts to using older exec ... {} \;
which is very inefficient.
Scripts using this compatibility mode should handle their logic using shell
code in the loop body as much as possible (after DO
) and use only simple
find
expressions (before DO
), as obsolete utilities are often buggy and
breakage is likely if complex expressions or advanced features are used.
Simple example script: without the safe mode, the *.txt
pattern
must be quoted to prevent it from being expanded by the shell.
. modernish
use var/loop
LOOP find TextFile in ~/Documents -name '*.txt'
DO
putln "Found my text file: $TextFile"
DONE
Example script with safe mode: the --glob
option
expands the patterns of the in
clause, but not the expression – so it
is not necessary to quote any pattern.
. modernish
use safe
use var/loop
LOOP find --glob lsProg in /*bin /*/*bin -type f -name ls*
DO
putln "This command may list something: $lsProg"
DONE
Example use of the modernish -ask
primary: ask the user if they want to
descend into each directory found. The shell loop body could skip unwanted
results, but cannot physically influence directory traversal, so skipping large
directories would take long. A find
expression can prevent directory
traversal using the standard -prune
primary, which can be combined with
-ask
, so that unwanted directories never iterate the loop in the first place.
. modernish
use safe
use var/loop
LOOP find file in ~/Documents \
-type d \( -ask 'Descend into "{}" directory?' -or -prune \) \
-or -iterate
DO
put "File found: "
ls -li $file
DONE
The modernish loop construct is extensible. To define a new loop type, you
only need to define a shell function called _loopgen_
type where type
is the loop type. This function, called the loop iteration generator, is
expected to output lines of text to file descriptor 8, containing properly
shell-quoted
iteration commands for the shell to run, one line per iteration.
The internal commands expanded from LOOP
, DO
and DONE
(which are
defined as aliases) launch that loop iteration generator function in the
background with safe mode enabled, while causing
the main shell to read lines from that background process through a pipe,
eval
ing each line as a command before iterating the loop. As long as that
iteration command finishes with an exit status of zero, the loop keeps
iterating. If it has a nonzero exit status or if there are no more commands
to read, iteration terminates and execution continues beyond the loop.
Instead of the normal internal namespace
which is considered off-limits for modernish scripts, var/loop
and its
submodules use a _loop_*
internal namespace for variables, which is also
for use by user-implemented loop iteration generator functions.
The above is just the general principle. For the details, study the comments
and the code in lib/modernish/mdl/var/loop.mm
and the loop generators in
lib/modernish/mdl/var/loop/*.mm
.
This module defines a new LOCAL
...BEGIN
...END
shell code block
construct with local variables, local positional parameters and local shell
options. The local positional parameters can be filled using safe field
splitting and pathname expansion operators similar to those in the LOOP
construct described above.
Usage: LOCAL
[ localitem | operator ... ] [ --
[ word ... ] ] ;
BEGIN
commands ;
END
The commands are executed once, with the specified localitems applied. Each localitem can be:
- A variable name with or without a
=
immediately followed by a value. This renders that variable local to the block, initially either unsetting it or assigning the value, which may be empty. - A shell option letter immediately preceded by a
-
or+
sign. This locally turns that shell option on or off, respectively. This follows the counterintuitive syntax ofset
. Long-form shell options like-o
optionname and+o
optionname are also supported. It depends on the shell what options are supported. Specifying a nonexistent option is a fatal error. Usethisshellhas
to check for a non-POSIX option's existence on the current shell before using it.
Modernish implements LOCAL
blocks as one-time shell functions that use
the stack
to save and restore variables and settings. So the return
command exits the
block, causing the global variables and settings to be restored and resuming
execution at the point immediately following END
. Like any shell function, a
LOCAL
block exits with the exit status of the last command executed within
it, or with the status passed on by or given as an argument to return
.
The positional parameters ($@
, $1
, etc.) are always local to the block, but
a copy is inherited from outside the block by default. Any changes to the
positional parameters made within the block will be discarded upon exiting it.
However, if a double-dash --
argument is given in the LOCAL
command line,
the positional parameters outside the block are ignored and the set of words
after --
(which may be empty) becomes the positional parameters instead.
These words can be modified prior to entering the LOCAL
block using the
following operators. The safe glob and split operators are only accepted in
the safe mode. The operators are:
- One of
--split
or--split=
characters. This operator safely applies the shell's field splitting mechanism to the words given. The simple--split
operator applies the shell's default field splitting by space, tab, and newline. If you supply one or more of your own characters to split by, each of these characters will be taken as a field separator if it is whitespace, or field terminator if it is non-whitespace. (Note that shells withQRK_IFSFINAL
treat both whitespace and non-whitespace characters as separators.) - One of
--glob
or--fglob
. These operators safely apply shell pathname expansion (globbing) to the words given. Each word is taken as a pattern, whether or not it contains any wildcard characters. For any resulting pathname that starts with-
or+
or is identical to!
or(
,./
is prefixed to keep various commands from misparsing it as an option or operand. Non-matching patterns are treated as follows:--glob
: Any non-matching patterns are quietly removed.--fglob
: All patterns must match. Any nonexistent path terminates the program. Use this if your program would not work after a non-match.
--base=
string. This operator prefixes the given string to each of the words, after first applying field splitting and/or pathname expansion if specified. If--glob
or--fglob
are given, then the string is used as a base directory path for pathname expansion, without expanding any wildcard characters in that base directory path itself. If such base directory can't be entered, then if--glob
was given, all words are removed, or if--fglob
was given, the program terminates.- One of
--slice
or--slice=
number. This operator divides the words in slices of up to number characters. The default slice size is 1 character, allowing for easy character-by-character processing. (Note that shells withWRN_MULTIBYTE
will not slice multi-byte characters correctly.)
If multiple operators are given, their mechanisms are applied in the following order: split, glob, base, slice.
- Due to the limitations of aliases and shell reserved words,
LOCAL
has to use its ownBEGIN
...END
block instead of the shell'sdo
...done
. Using the latter results in a misleading shell syntax error. LOCAL
blocks do not mix well with use of the shell capabilityLOCALVARS
(shell-native functionality for local variables), especially not on shells withQRK_LOCALUNS
orQRK_LOCALUNS2
. Using both with the same variables causes unpredictable behaviour, depending on the shell.- Warning! Never use
break
orcontinue
within aLOCAL
block to resume or break from enclosing loops outside the block! Shells withQRK_BCDANGER
allow this, preventingEND
from restoring the global settings and corrupting the stack; shells without this quirk will throw an error if you try this. A proper way to do what you want is to exit the block with a nonzero status using something likereturn 1
, then append something like|| break
or|| continue
toEND
. Note that this caveat only applies when crossingBEGIN
...END
boundaries. Usingcontinue
andbreak
to continue or break loops entirely within the block is fine.
These shortcut functions are alternatives for using
let
.
inc
, dec
, mult
, div
, mod
: simple integer arithmetic shortcuts. The first
argument is a variable name. The optional second argument is an
arithmetic expression, but a sane default value is assumed (1 for inc
and dec, 2 for mult and div, 256 for mod). For instance, inc X
is
equivalent to X=$((X+1))
and mult X Y-2
is equivalent to X=$((X*(Y-2)))
.
ndiv
is like div
but with correct rounding down for negative numbers.
Standard shell integer division simply chops off any digits after the
decimal point, which has the effect of rounding down for positive numbers
and rounding up for negative numbers. ndiv
consistently rounds down.
These have the same name as their test
/[
option equivalents. Unlike
with test
, the arguments are shell integer arith expressions, which can be
anything from simple numbers to complex expressions. As with $(( ))
,
variable names are expanded to their values even without the $
.
Function: Returns successfully if:
eq <expr> <expr> the two expressions evaluate to the same number
ne <expr> <expr> the two expressions evaluate to different numbers
lt <expr> <expr> the 1st expr evaluates to a smaller number than the 2nd
le <expr> <expr> the 1st expr eval's to smaller than or equal to the 2nd
gt <expr> <expr> the 1st expr evaluates to a greater number than the 2nd
ge <expr> <expr> the 1st expr eval's to greater than or equal to the 2nd
This module is provided to solve a common POSIX shell language annoyance: in a
normal shell variable assignment, only literal variable names are accepted, so
it is impossible to use a variable whose name is stored in another variable.
The only way around this is to use eval
which is too difficult to use safely.
Instead, you can now use the assign
command.
Usage: assign
[ [ +r
] variable=
value ... ] | [ -r
variable=
variable2 ... ] ...
assign
safely processes assignment-arguments in the same form as customarily
given to the readonly
and export
commands, but it only assigns values to
variables without setting any attributes. Each argument is grammatically an
ordinary shell word, so any part or all of it may result from an expansion. The
absence of a =
character in any argument is a fatal error. The text preceding
the first =
is taken as the variable name in which to store the value; an
invalid variable name is a fatal error. No whitespace is accepted before the
=
and any whitespace after the =
is part of the value to be assigned.
The -r
(reference) option causes the part to the right of the =
to be
taken as a second variable name variable2, and its value is assigned to
variable instead. +r
turns this option back off.
Examples: Each of the lines below assigns the value 'hello world' to the
variable greeting
.
var=greeting; assign $var='hello world'
var=greeting; assign "$var=hello world"
tag='greeting=hello world'; assign "$tag"
var=greeting; gvar=myinput; myinput='hello world'; assign -r $var=$gvar
readf
reads arbitrary data from standard input into a variable until end
of file, converting it into a format suitable for passing to the
printf
utility. For example, readf var <foo; printf "$var" >bar
will copy foo to
bar. Thus, readf
allows storing both text and binary files into shell
variables in a textual format suitable for manipulation with standard shell
facilities.
All non-printable, non-ASCII characters are converted to printf
octal or
one-letter escape codes, except newlines. Not encoding newline characters
allows for better processing by line-based utilities such as grep
, sed
,
awk
, etc. However, if the file ends in a newline, that final newline is
encoded to \n
to protect it from being stripped by command substitutions.
Usage: readf
[ -h
] varname
The -h
option disables conversion of high-byte characters (accented letters,
non-Latin scripts). Do not use for binary files; this is only guaranteed to
work for text files in an encoding compatible with the current locale.
Caveats:
- Best for small-ish files. The encoded file is stored in memory (a shell
variable). For a binary file, encoding in
printf
format typically about doubles the size, though it could be up to four times as large. - If the shell executing your program does not have
printf
as a builtin command, the externalprintf
command will fail if the encoded file size exceeds the maximum length of arguments to external commands (getconf ARG_MAX
will obtain this limit for your system). Shell builtin commands do not have this limit. Check for aprintf
builtin usingthisshellhas
if you need to be sure, and alwaysharden
printf
!
This module provides an efficient, fast, safe and portable shell-quoting
algorithm for quoting arbitrary data in such a way that the quoted values are
safe to pass to the shell for parsing as string literals. This is essential
for any context where the shell must grammatically parse untrusted input,
such as when supplying arbitrary values to trap
or eval
.
The shell-quoting algorithm is optimised to minimise exponential growth when quoting repeatedly. By default, it also ensures that quoted strings are always one single printable line, making them safe for terminal output and processing by line-oriented utilities.
Usage: shellquote
[ -f
|+f
|-P
|+P
] varname[=
value] ...
The values of the variables specified by name are shell-quoted and stored
back into those variables.
Repeating a variable name will add another level of shell-quoting.
If a =
plus a value (which may be empty) is appended to the varname,
that value is shell-quoted and assigned to the variable.
Options modify the algorithm for variable names following them, as follows:
-
By default, newlines and any control characters are converted into
${CC*}
expansions and quoted with double quotes, ensuring that the quoted string consists of a single line of printable text. The-P
option forces pure POSIX quoted strings that may span multiple lines;+P
turns this back off. -
By default, a value is only quoted if it contains characters not present in
$SHELLSAFECHARS
. The-f
option forces unconditional quoting, disabling optimisations that may leave shell-safe characters unquoted;+f
turns this back off.
shellquote
will die if you
attempt to quote an unset variable (because there is no value to quote).
The shellquoteparams
command shell-quotes the current positional
parameters in place using the default quoting method of shellquote
. No
options are supported and any attempt to add arguments results in a syntax
error.
Modules that extend the stack.
This module contains stack query and maintenance functions.
If you only need one or two of these functions, they can also be loaded as
individual submodules of var/stack/extra
.
For the four functions below, item can be:
- a valid portable variable name
- a short-form shell option: dash plus letter
- a long-form shell option:
-o
followed by an option name (two arguments) --trap=
SIGNAME to refer to the trap stack for the indicated signal (as set bypushtrap
fromvar/stack/trap
)
stackempty
[ --key=
value ] [ --force
] item: Tests if the stack
for an item is empty. Returns status 0 if it is, 1 if it is not. The key
feature works as in pop
: by default, a key
mismatch is considered equivalent to an empty stack. If --force
is given,
this function ignores keys altogether.
clearstack
[ --key=
value ] [ --force
] item [ item ... ]:
Clears one or more stacks, discarding all items on it.
If (part of) the stack is keyed or a --key
is given, only clears until a
key mismatch is encountered. The --force
option overrides this and always
clears the entire stack (be careful, e.g. don't use within
LOCAL
... BEGIN
... END
).
Returns status 0 on success, 1 if that stack was already empty, 2 if
there was nothing to clear due to a key mismatch.
stacksize
[ --silent
| --quiet
] item: Leaves the size of a stack in
the REPLY
variable and, if option --silent
or --quiet
is not given,
writes it to standard output.
The size of the complete stack is returned, even if some values are keyed.
printstack
[ --quote
] item: Outputs a stack's content.
Option --quote
shell-quotes each stack value before printing it, allowing
for parsing multi-line or otherwise complicated values.
Column 1 to 7 of the output contain the number of the item (down to 0).
If the item is set, column 8 and 9 contain a colon and a space, and
if the value is non-empty or quoted, column 10 and up contain the value.
Sets of values that were pushed with a key are started with a special
line containing --- key:
value. A subsequent set pushed with no key is
started with a line containing --- (key off)
.
Returns status 0 on success, 1 if that stack is empty.
This module provides pushtrap
and poptrap
. These functions integrate
with the main modernish stack
to make traps stack-based, so that each
program component or library module can set its own trap commands without
interfering with others.
This module also provides a new
DIE
pseudosignal
that allows pushing traps to execute when
die
is called.
Note an important difference between the trap stack and stacks for variables
and shell options: pushing traps does not save them for restoring later, but
adds them alongside other traps on the same signal. All pushed traps are
active at the same time and are executed from last-pushed to first-pushed
when the respective signal is triggered. Traps cannot be pushed and popped
using push
and pop
but use dedicated commands as follows.
Usage:
pushtrap
[--key=
value ] [--nosubshell
] [--
] command sigspec [ sigspec ... ]poptrap
[--key=
value ] [-R
] [--
] sigspec [ sigspec ... ]
pushtrap
works like regular trap
, with the following exceptions:
- Adds traps for a signal without overwriting previous ones.
- An invalid signal is a fatal error. When using non-standard signals, check if
thisshellhas --sig=
yoursignal before using it. - Unlike regular traps, a stack-based trap does not cause a signal to be
ignored. Setting one will cause it to be executed upon the shell receiving
that signal, but after the stack traps complete execution, modernish re-sends
the signal to the main shell, causing it to behave as if no trap were set
(unless a regular POSIX trap is also active).
Thus,
pushtrap
does not accept an empty command as it would be pointless. - Each stack trap is executed in a new
subshell
to keep it from interfering
with others. This means a stack trap cannot change variables except within
its own environment, and
exit
will only exit the trap and not the program. The--nosubshell
option overrides this behaviour, causing that particular trap to be executed in the main shell environment instead. This is not recommended if not absolutely needed, as you have to be extra careful to avoid exiting the shell or otherwise interfere with other stack traps. This option cannot be used withDIE
traps. - Each stack trap is executed with
$?
initially set to the exit status that was active at the time the signal was triggered. - Stack traps do not have access to the positional parameters.
pushtrap
stores current$IFS
(field splitting) and$-
(shell options) along with the pushed trap. Within the subshell executing each stack trap, modernish restoresIFS
and the shell optionsf
(noglob
),u
(nounset
) andC
(noclobber
) to the values in effect during the correspondingpushtrap
. This is to avoid unexpected effects in case a trap is triggered while temporary settings are in effect. The--nosubshell
option disables this functionality for the trap pushed.- The
--key
option applies the keying functionality inherited from plainpush
to the trap stack. It works the same way, so the description is not repeated here.
poptrap
takes just signal names or numbers as arguments. It takes the
last-pushed trap for each signal off the stack. By default, it discards
the trap commands. If the -R
option is given, it stores commands to
restore those traps into the REPLY
variable, in a format suitable for
re-entry into the shell. Again, the --key
option works as in
plain pop
.
With the sole exception of
DIE
traps,
all stack-based traps, like native shell traps, are reset upon entering a
subshell.
However, commands for printing traps will print the traps for
the parent shell, until another trap
, pushtrap
or poptrap
command is
invoked, at which point all memory of the parent shell's traps is erased.
Modernish tries hard to avoid incompatibilities with existing trap practice.
To that end, it intercepts the regular POSIX trap
command using an alias,
reimplementing and interfacing it with the shell's builtin trap facility
so that plain old regular traps play nicely with the trap stack. You should
not notice any changes in the POSIX trap
command's behaviour, except for
the following:
- The regular
trap
command does not overwrite stack traps (but still overwrites existing regular traps). - Unlike zsh's native trap command, signal names are case insensitive.
- Unlike dash's native trap command, signal names may have the
SIG
prefix; that prefix is quietly accepted and discarded. - Setting an empty trap action to ignore a signal only works fully (passing the ignoring on to child processes) if there are no stack traps associated with the signal; otherwise, an empty trap action merely suppresses the signal's default action for the current process – e.g., after executing the stack traps, it keeps the shell from exiting.
- The
trap
command with no arguments, which prints the traps that are set in a format suitable for re-entry into the shell, now also prints the stack traps aspushtrap
commands. (bash
users might notice theSIG
prefix is not included in the signal names written.) - The bash/yash-style
-p
option, including its yash-style--print
equivalent, is now supported on all shells. If further arguments are given after that option, they are taken as signal specifications and only the commands to recreate the traps for those signals are printed. - Saving the traps to a variable using command substitution (as in:
var=$(trap)
) now works on every shell supported by modernish, including (d)ash, mksh and zsh which don't support this natively. - To reset (unset) a trap, the modernish
trap
command accepts both valid POSIX syntax and legacy bash/(d)ash/zsh syntax, liketrap INT
to unset aSIGINT
trap (which only works if thetrap
command is given exactly one argument). Note that this is for compatibility with existing scripts only. - Bypassing the
trap
alias to set a trap using the shell builtin command will cause an inconsistent state. This may be repaired with a simpletrap
command; as modernish prints the traps, it will quietly detect ones it doesn't yet know about and make them work nicely with the trap stack.
POSIX traps for each signal are always executed after that signal's stack-based traps; this means they should not rely on modernish modules that use the trap stack to clean up after themselves on exit, as those cleanups would already have been done.
The var/stack/trap
module adds new DIE
pseudosignal whose traps are
executed upon invoking die
.
This allows for emergency cleanup operations upon fatal program failure,
as EXIT
traps cannot be executed after die
is invoked.
- On non-interactive shells (as well as
subshells
of interactive shells),
DIE
is its own pseudosignal with its own trap stack and POSIX trap. In order to kill the malfunctioning program as quickly as possible (hopefully before it has a chance to delete all your data),die
doesn't wait for those traps to complete before killing the program. Instead, it executes eachDIE
trap simultaneously as a background job, then gathers the process IDs of the main shell and all its subprocesses, sendingSIGKILL
to all of them except anyDIE
trap processes. Unlike other traps,DIE
traps are inherited by and survive in subshell processes, andpushtrap
may add to them within the subshell. Whatever shell process invokesdie
will fork allDIE
trap actions before beingSIGKILL
ed itself. (Note that anyDIE
traps pushed or set within a subshell will still be forgotten upon exiting the subshell.) - On an interactive shell (not including its
subshells),
DIE
is simply an alias forINT
, andINT
traps (both POSIX and stack) are cleared out after executing them once. This is becausedie
usesSIGINT
for command interruption on interactive shells, and it would not make sense to execute emergency cleanup commands repeatedly. As a side effect of this special handling,INT
traps on interactive shells do not have access to the positional parameters and cannot return from functions.
String comparison and manipulation functions.
toupper
and tolower
: convert case in variables.
Usage:
toupper
varname [ varname ... ]tolower
varname [ varname ... ]
Arguments are taken as variable names (note: they should be given without
the $
) and case is converted in the contents of the specified variables,
without reading input or writing output.
toupper
and tolower
try hard to use the fastest available method on the
particular shell your program is running on. They use built-in shell
functionality where available and working correctly, otherwise they fall back
on running an external utility.
Which external utility is chosen depends on whether the current locale uses
the Unicode UTF-8 character set or not. For non-UTF-8 locales, modernish
assumes the POSIX/C locale and tr
is always used. For UTF-8 locales,
modernish tries hard to find a way to correctly convert case even for
non-Latin alphabets. A few shells have this functionality built in with
typeset
. The rest need an external utility. Modernish initialisation
tries tr
, awk
, GNU awk
and GNU sed
before giving up and setting
the variable MSH_2UP2LOW_NOUTF8
. If isset MSH_2UP2LOW_NOUTF8
, it
means modernish is in a UTF-8 locale but has not found a way to convert
case for non-ASCII characters, so toupper
and tolower
will convert
only ASCII characters and leave any other characters in the string alone.
trim
: strip whitespace from the beginning and end of a variable's value.
Whitespace is defined by the [:space:]
character class. In the POSIX
locale, this is tab, newline, vertical tab, form feed, carriage return, and
space, but in other locales it may be different.
(On shells with BUG_NOCHCLASS
,
$WHITESPACE
is used to define whitespace instead.) Optionally, a string of literal
characters can be provided in the second argument. Any characters appearing
in that string will then be trimmed instead of whitespace.
Usage: trim
varname [ characters ]
replacein
: Replace leading, -t
railing or -a
ll occurrences of a string by
another string in a variable.
Usage: replacein
[ -t
| -a
] varname oldstring newstring
append
and prepend
: Append or prepend zero or more strings to a
variable, separated by a string of zero or more characters, avoiding the
hairy problem of dangling separators.
Usage: append
|prepend
[ --sep=
separator ] [ -Q
] varname [ string ... ]
If the separator is not specified, it defaults to a space character.
If the -Q
option is given, each string is
shell-quoted
before appending or prepending.
The unexport
function clears the "export" bit of a variable, conserving
its value, and/or assigns values to variables without setting the export
bit. This works even if set -a
(allexport) is active, allowing an "export
all variables, except these" way of working.
Usage is like export
, with the caveat that variable assignment arguments
containing non-shell-safe characters or expansions must be quoted as
appropriate, unlike in some specific shell implementations of export
.
(To get rid of that headache, use safe
.)
Unlike export
, unexport
does not work for read-only variables.
As the getopts
builtin is not portable when used in functions, this module
provides a command that generates modernish code to parse options for your
shell function in a standards-compliant manner. The generated parser
supports short-form (one-character) options which can be stacked/combined.
Usage:
generateoptionparser
[ -o
] [ -f
func ] [ -v
varprefix ]
[ -n
options ] [ -a options ] [ varname ]
-o
: Write parser to standard output.-f
: Function name to prefix to error messages. Default: none.-v
: Variable name prefix for options. Default:opt_
.-n
: String of options that do not take arguments.-a
: String of options that require arguments.- varname: Store parser in specified variable. Default:
REPLY
.
At least one of -n
and -a
is required. All other arguments are optional.
Option characters must be valid components of portable variable names, so
they must be ASCII upper- or lowercase letters, digits, or the underscore.
generateoptionparser
stores the generated parser code in a variable: either
REPLY
or the varname specified as the first non-option argument. This makes
it possible to generate and use the parser on the fly with a command like
eval "$REPLY"
immediately following the generateoptionparser
invocation.
For better efficiency and readability, it will often be preferable to insert
the option parser code directly into your shell function instead. The -o
option writes the parser code to standard output, so it can be redirected to
a file, inserted into your editor, etc.
Parsed options are shifted out of the positional parameters while setting or
unsetting corresponding variables, until a non-option argument, a --
end-of-options delimiter argument, or the end of arguments is encountered.
Unlike with getopts
, no additional shift
command is required.
Each specified option gets a corresponding variable with a name consisting
of the varprefix (default: opt_
) plus the option character. If an option
is not passed to your function, the parser unsets its variable; otherwise it
sets it to either the empty value or its option-argument if it requires one.
Thus, your function can check if any option x
was given using
isset
,
for example, if isset opt_x; then
...
Some very common and essential utilities are not specified by POSIX, differ
widely among systems, and are not always available. For instance, the
which
and readlink
commands have incompatible options on various GNU and
BSD variants and may be absent on other Unix-like systems. The sys/base
module provides a complete re-implementation of such non-standard but basic
utilities, written as modernish shell functions. Using the modernish version
of these utilities can help a script to be fully portable. These versions
also have various enhancements over the GNU and BSD originals, some of which
are made possible by their integration into the modernish shell environment.
A cross-platform shell implementation of mktemp
that aims to be just as
safe as native mktemp
(1) implementations, while avoiding the problem of
having various mutually incompatible versions and adding several unique
features of its own.
Creates one or more unique temporary files, directories or named pipes,
atomically (i.e. avoiding race conditions) and with safe permissions.
The path name(s) are stored in REPLY
and optionally written to stdout.
Usage: mktemp
[ -dFsQCt
] [ template ... ]
-d
: Create a directory instead of a regular file.-F
: Create a FIFO (named pipe) instead of a regular file.-s
: Silent. Store output in$REPLY
, don't write any output or message.-Q
: Shell-quote each unit of output. Separate by spaces, not newlines.-C
: Automated cleanup. Pushes a trap to remove the files on exit. On an interactive shell, that's all this option does. On a non-interactive shell, the following applies: Clean up on receivingSIGPIPE
andSIGTERM
as well. On receivingSIGINT
, clean up if the option was given at least twice, otherwise notify the user of files left. On the invocation ofdie
, clean up if the option was given at least three times, otherwise notify the user of files left.-t
: Prefix one temporary files directory to all the templates:$XDG_RUNTIME_DIR
or$TMPDIR
if set, or/tmp
. The templates may not contain any slashes. If the template has neither any trailingX
es nor a trailing dot, a dot is added before the random suffix.
The template defaults to “/tmp/temp.
”. An suffix of random shell-safe ASCII
characters is added to the template to create the file. For compatibility with
other mktemp
implementations, any optional trailing X
characters in the
template are removed. The length of the suffix will be equal to the amount of
X
es removed, or 10, whichever is more. The longer the random suffix, the
higher the security of using mktemp
in a shared directory such as tmp
.
Since /tmp
is a world-writable directory shared by other users, for best
security it is recommended to create a private subdirectory using mktemp -d
and work within that.
Option -C
cannot be used without option -s
when in a
subshell.
Modernish will detect this and treat it as a
fatal error. The reason is that a typical command substitution like
tmpfile=$(mktemp -C)
is incompatible with auto-cleanup, as the cleanup EXIT trap would be
triggered not upon exiting the program but upon exiting the command
substitution subshell that just ran mktemp
, thereby immediately undoing
the creation of the file. Instead, do something like:
mktemp -sC; tmpfile=$REPLY
This module depends on the trap stack to do auto-cleanup (the -C
option),
so it will automatically use var/stack/trap
on initialisation.
readlink
reads the target of a symbolic link, robustly handling strange
filenames such as those containing newline characters. It stores the result
in the REPLY
variable and optionally writes it on standard output.
Usage: readlink
[ -nsefmQ
] path [ path ... ]
-n
: If writing output, don't add a trailing newline. This does not remove the separating newlines if multiple paths are given.-s
: Silent operation: don't write output, only store it inREPLY
.-e
,-f
,-m
: Canonicalise. Convert each path found into a canonical and absolute path that can be used starting from any working directory. Relative paths are resolved starting from the present working directory. Double slashes are removed. Any special pathname components.
and..
are resolved. All symlinks encountered are followed, but a path does not need to contain any symlinks. UNC network paths (as on Cygwin) are supported. These options differ as follows:-e
: All pathname components must exist to produce a result.-f
: All but the last pathname component must exist to produce a result.-m
: No pathname component needs to exist; this always produces a result. Nonexistent pathname components are simulated as regular directories.
-Q
: Shell-quote each unit of output. Separate by spaces instead of newlines. This generates a list of arguments in shell syntax, guaranteed to be suitable for safe parsing by the shell, even if the resulting pathnames should contain strange characters such as spaces or newlines and other control characters.
The exit status of readlink
is 0 on success and 1 if the path either is
not a symlink, or could not be canonicalised according to the option given.
rev
copies the specified files to the standard output, reversing the order
of characters in every line. If no files are specified, the standard input
is read.
Usage: like rev
on Linux and BSD, which is like cat
except that -
is
a filename and does not denote standard input. No options are supported.
A cross-platform implementation of seq
that is more powerful and versatile
than native GNU and BSD seq
(1) implementations. The core is written in
bc
, the POSIX arbitrary-precision calculator language. That means this
seq
inherits the capacity to handle numbers with a precision and size only
limited by computer memory, as well as the ability to handle input numbers
in any base from 1 to 16 and produce output in any base 1 and up.
Usage: seq
[ -w
] [ -L
] [ -f
format ] [ -s
string ] [ -S
scale ]
[ -B
base ] [ -b
base ] [ first [ incr ] ] last
seq
prints a sequence of arbitrary-precision floating point numbers, one
per line, from first (default 1), to as near last as possible, in increments of
incr (default 1). If first is larger than last, the default incr is -1.
An incr of zero is treated as a fatal error.
-w
: Equalise width by padding with leading zeros. The longest of the first, incr or last arguments is taken as the length that each output number should be padded to.-L
: Use the current locale's radix point in the output instead of the full stop (.
).-f
:printf
-style floating-point format. The format string is passed on (with an added\n
) toawk
's builtinprintf
function. Because of that, the-f
option can only be used if the output base is 10. Note thatawk
's floating point precision is limited, so very large or long numbers will be rounded.-s
: Instead of writing one number per line, write all numbers on one line separated by string and terminated by a newline character.-S
: Explicitly set the scale (number of digits after the radix point). Defaults to the largest number of digits after the radix point among the first, incr or last arguments.-B
: Set input and output base from 1 to 16. Defaults to 10.-b
: Set arbitrary output base from 1. Defaults to input base. See thebc
(1) manual for more information on the output format for bases greater than 16.
The -S
, -B
and -b
options take shell integer numbers as operands. This
means a leading 0X
or 0x
denotes a hexadecimal number and a leading 0
denotes an octal number.
For portability reasons, modernish seq
uses a full stop (.
) for the
radix point, regardless of the
system locale. This applies both to command arguments and to output.
The -L
option causes seq
to use the current locale's radix point
character for output only.
The -S
, -B
and -b
options are modernish innovations.
The -w
, -f
and -s
options are inspired by GNU and BSD seq
.
The following differences apply:
- Like GNU and unlike BSD, the separator specified by the
-s
option is not appended to the final number and there is no-t
option to add a terminator character. - Like GNU and unlike BSD, the
-s
option-argument is taken as literal characters and is not parsed for backslash escape codes like\n
. - Unlike GNU and like BSD, the output radix point defaults to a full stop, regardless of the current locale.
- Unlike GNU and like BSD, if incr is not specified,
it defaults to -1 if first > last, 1 otherwise.
For example,
seq 5 1
counts backwards from 5 to 1, and specifyingseq 5 -1 1
as with GNU is not needed. - Unlike GNU and like BSD, an incr of zero is not accepted.
To output the same number or string infinite times, use
yes
instead. - Unlike both GNU and BSD, the
-f
option accepts any format specifiers accepted byawk
'sprintf()
function.
The sys/base/seq
module depends on, and automatically loads,
var/string/touplow
.
Shuffle lines of text. A portable reimplementation of a commonly used GNU utility.
Usage:
shuf
[-n
max ] [-r
rfile ] fileshuf
[-n
max ] [-r
rfile ]-i
low-
highshuf
[-n
max ] [-r
rfile ]-e
argument ...
By default, shuf
reads lines of text from standard input, or from file
(the file -
signifies standard input).
It writes the input lines to standard output in random order.
-i
: Use sequence of non-negative integers low through high as input.-e
: Instead of reading input, use the arguments as lines of input.-n
: Output a maximum of max lines.-r
: Use rfile as the source of random bytes. Defaults to/dev/urandom
.
Differences with GNU shuf
:
- Long option names are not supported.
- The
-o
/--output-file
option is not supported; use output redirection. Safely shuffling files in-place is not supported; use a temporary file. --random-source=
file is changed to-r
file.- The
-z
/--zero-terminated
option is not supported.
tac
(the reverse of cat
) is a cross-platform reimplementation of the GNU
tac
utility, with some extra features.
Usage: tac
[ -rbBP
] [ -S
separator ] file [ file ... ]
tac
outputs the files in reverse order of lines/records.
If file is -
or is not given, tac
reads from standard input.
-s
: Specify the record (line) separator. Default: linefeed.-r
: Interpret the record separator as an extended regular expression. This allows using separators that may vary. Each separator is preserved in the output as it is in the input.-b
: Assume the separator comes before each record in the input, and also output the separator before each record. Cannot be combined with-B
.-B
: Assume the separator comes after each record in the input, but output the separator before each record. Cannot be combined with-b
.-P
: Paragraph mode: output text last paragraph first. Input paragraphs are separated from each other by at least two linefeeds. Cannot be combined with any other option.
Differences between GNU tac
and modernish tac
:
- The
-B
and-P
options were added. - The
-r
option interprets the record separator as an extended regular expression. This is an incompatibility with GNUtac
unless expressions are used that are valid as both basic and extended regular expressions. - In UTF-8 locales, multi-byte characters are recognised and reversed correctly.
The modernish which
utility finds external programs and reports their
absolute paths, offering several unique options for reporting, formatting
and robust processing. The default operation is similar to GNU which
.
Usage: which
[ -apqsnQ1f
] [ -P
number ] program [ program ... ]
By default, which
finds the first available path to each given program.
If program is itself a path name (contains a slash), only that path's base
directory is searched; if it is a simple command name, the current $PATH
is searched. Any relative paths found are converted to absolute paths.
Symbolic links are not followed. The first path found for each program is
written to standard output (one per line), and a warning is written to
standard error for every program not found. The exit status is 0 (success)
if all programs were found, 1 otherwise.
which
also leaves its output in the REPLY
variable. This may be useful
if you run which
in the main shell environment. The REPLY
value will
not survive a command substitution
subshell
as in ls_path=$(which ls)
.
The following options modify the default behaviour described above:
-a
: List all programs that can be found in the directories searched, instead of just the first one. This is useful for finding duplicate commands that the shell would not normally find when searching its$PATH
.-p
: Search in$DEFPATH
(the default standard utilityPATH
provided by the operating system) instead of in the user's$PATH
, which is vulnerable to manipulation.-q
: Be quiet: suppress all warnings.-s
: Silent operation: don't write output, only store it in theREPLY
variable. Suppress warnings except, if you runwhich -s
in a subshell, a warning that theREPLY
variable will not survive the subshell.-n
: When writing to standard output, do not write a final newline.-Q
: Shell-quote each unit of output. Separate by spaces instead of newlines. This generates a one-line list of arguments in shell syntax, guaranteed to be suitable for safe parsing by the shell, even if the resulting pathnames should contain strange characters such as spaces or newlines and other control characters.-1
(one): Output the results for at most one of the arguments in descending order of preference: once a search succeeds, ignore the rest. Suppress warnings except a subshell warning for-s
. This is useful for finding a command that can exist under several names, for example:which -f -1 gnutar gtar tar
This option modifies which's exit status behaviour:which -1
returns successfully if at least one command was found.-f
: Throw a fatal error in cases wherewhich
would otherwise return status 1 (non-success).-P
: Strip the indicated number of pathname elements from the output, starting from the right.-P1
: strip/program
;-P2
: strip/*/program
, etc. This is useful for determining the installation root directory for an installed package.--help
: Show brief usage information.
yes
very quickly outputs infinite lines of text, each consisting of its
space-separated arguments, until terminated by a signal or by a failure to
write output. If no argument is given, the default line is y
. No options
are supported.
This infinite-output command is useful for piping into commands that need an indefinite input data stream, or to automate a command requiring interactive confirmation.
Modernish yes
is like GNU yes
in that it outputs all its arguments,
whereas BSD yes
only outputs the first. It can output multiple gigabytes
per second on modern systems.
Modules in this category contain functions for enhancing the invocation of commands.
extern
is like command
but always runs an external command, without
having to know or determine its location. This provides an easy way to
bypass a builtin, alias or function. It does the same $PATH
search
the shell normally does when running an external command. For instance, to
guarantee running external printf
just do: extern printf ...
Usage: extern
[ -p
] [ -v
] [ -u
varname ... ]
[ varname=
value ... ] command [ argument ... ]
-p
: The command, as well as any commands it further invokes, are searched in$DEFPATH
(the default standard utilityPATH
provided by the operating system) instead of in the user's$PATH
, which is vulnerable to manipulation.extern -p
is much more reliable than the shell's builtincommand -p
because: (a) many existing shell installations use a wrong search path forcommand -p
; (b)command -p
does not export the defaultPATH
, so something likecommand -p sudo cp foo /bin/bar
searches onlysudo
in the secure default path and notcp
.
-v
: don't execute command but show the full path name of the command that would have been executed. Any extra arguments are taken as more command paths to show, one per line.extern
exits with status 0 if all the commands were found, 1 otherwise. This option can be combined with-p
.-u
: Temporary export override. Unset the given variable in the environment of the command executed, even if it is currently exported. Can be specified multiple times.- varname
=
value assignment-arguments: These variables/values are temporarily exported to the environment during the execution of the command.- This is provided because assignments preceding
extern
cause unwanted, shell-dependent side effects, asextern
is a shell function. Be sure to provide assignment-arguments followingextern
instead. - Assignment-arguments after a
--
end-of-options delimiter are not parsed; this allows commands containing a=
sign to be executed.
- This is provided because assignments preceding
The harden
function allows implementing emergency halt on error
for any external commands and shell builtin utilities. It is
modernish's replacement for set -e
a.k.a. set -o errexit
(which is
fundamentally
flawed,
not supported and will break the library).
It depends on, and auto-loads, the sys/cmd/extern
module.
harden
sets a shell function with the same name as the command hardened,
so it can be used transparently. This function hardens the given command by
checking its exit status against values indicating error or system failure.
Exactly what exit statuses signify an error or failure depends on the
command in question; this should be looked up in the
POSIX specification
(under "Utilities") or in the command's man
page or other documentation.
If the command fails, the function installed by harden
calls die
, so it
will reliably halt program execution, even if the failure occurred within a
subshell.
Usage:
harden
[ -f
funcname ] [ -[cSpXtPE]
] [ -e
testexpr ]
[ var=
value ... ] [ -u
var ... ] command_name_or_path
[ command_argument ... ]
The -f
option hardens the command as the shell function funcname instead
of defaulting to command_name_or_path as the function name. (If the latter
is a path, that's always an invalid function name, so the use of -f
is
mandatory.) If command_name_or_path is itself a shell function, that
function is bypassed and the builtin or external command by that name is
hardened instead. If no such command is found, harden
dies with the message
that hardening shell functions is not supported. (Instead, you should invoke
die
directly from your shell function upon detecting a fatal error.)
The -c
option causes command_name_or_path to be hardened and run
immediately instead of setting a shell function for later use. This option
is meant for commands that run once; it is not efficient for repeated use.
It cannot be used together with the -f
option.
The -S
option allows specifying several possible names/paths for a
command. It causes the command_name_or_path to be split by comma and
interpreted as multiple names or paths to search. The first name or path
found is used. Requires -f
.
The -e
option, which defaults to >0
, indicates the exit statuses
corresponding to a fatal error. It depends on the command what these are;
consult the POSIX spec and the manual pages.
The status test expression testexpr, argument
to the -e
option, is like a shell arithmetic
expression, with the binary operators ==
!=
<=
>=
<
>
turned
into unary operators referring to the exit status of the command in
question. Assignment operators are disallowed. Everything else is the same,
including &&
(logical and) and ||
(logical or) and parentheses.
Note that the expression needs to be quoted as the characters used in it
clash with shell grammar tokens.
The -X
option causes harden
to always search for and harden an external
command, even if a built-in command by that name exists.
The -E
option causes the hardening function to consider it a fatal error
if the hardened command writes anything to the standard error stream. This
option allows hardening commands (such as
bc
)
where you can't rely on the exit status to detect an error. The text written
to standard error is passed on as part of the error message printed by
die
. Note that:
- Intercepting standard error necessitates that the command be executed from a
subshell.
This means any builtins or shell functions hardened with
-E
cannot influence the calling shell (e.g.harden -E cd
renderscd
ineffective). -E
does not disable exit status checks; by default, any exit status greater than zero is still considered a fatal error as well. If your command does not even reliably return a 0 status upon success, then you may want to add-e '>125'
, limiting the exit status check to reserved values indicating errors launching the command and signals caught.
The -p
option causes harden
to search for commands using the
system default path (as obtained with getconf PATH
) as opposed to the
current $PATH
. This ensures that you're using a known-good external
command that came with your operating system. By default, the system-default
PATH search only applies to the command itself, and not to any commands that
the command may search for in turn. But if the -p
option is specified at
least twice, the command is run in a subshell with PATH
exported as the
default path, which is equivalent to adding a PATH=$DEFPATH
assignment
argument (see below).
Examples:
harden make # simple check for status > 0
harden -f tar '/usr/local/bin/gnutar' # id.; be sure to use this 'tar' version
harden -e '> 1' grep # for grep, status > 1 means error
harden -e '==1 || >2' gzip # 1 and >2 are errors, but 2 isn't (see manual)
As far as the shell is concerned, hardened commands are shell functions and not external or builtin commands. This essentially changes one behaviour of the shell: variable assignments preceding the command will not be local to the command as usual, but will persist after the command completes. (POSIX technically makes that behaviour optional but all current shells behave the same in POSIX mode.)
For example, this means that something like
harden -e '>1' grep
# [...]
LC_ALL=C grep regex some_ascii_file.txt
should never be done, because the meant-to-be-temporary LC_ALL
locale
assignment will persist and is likely to cause problems further on.
To solve this problem, harden
supports adding these assignments as
part of the hardening command, so instead of the above you do:
harden -e '>1' LC_ALL=C grep
# [...]
grep regex some_ascii_file.txt
With the -u
option, harden
also supports unsetting variables for the
duration of a command, e.g.:
harden -e '>1' -u LC_ALL grep
The -u
option may be specified multiple times.
It causes the hardened command to be invoked from a
subshell
with the specified variables unset.
If you're piping a command's output into another command that may close
the pipe before the first command is finished, you can use the -P
option
to allow for this:
harden -e '==1 || >2' -P gzip # also tolerate gzip being killed by SIGPIPE
gzip -dc file.txt.gz | head -n 10 # show first 10 lines of decompressed file
head
will close the pipe of gzip
input after ten lines; the operating
system kernel then kills gzip
with the PIPE signal before it's finished,
causing a particular exit status that is greater than 128. This exit status
would normally make harden
kill your entire program, which in the example
above is clearly not the desired behaviour. If the exit status caused by a
broken pipe were known, you could specifically allow for that exit status in
the status expression. The trouble is that this exit status varies depending
on the shell and the operating system. The -p
option was made to solve
this problem: it automatically detects and whitelists the correct exit
status corresponding to SIGPIPE
termination on the current system.
Tolerating SIGPIPE
is an option and not the default, because in many
contexts it may be entirely unexpected and a symptom of a severe error if a
command is killed by a broken pipe. It is up to the programmer to decide
which commands should expect SIGPIPE
and which shouldn't.
Tip: It could happen that the same command should expect SIGPIPE
in one
context but not another. You can create two hardened versions of the same
command, one that tolerates SIGPIPE
and one that doesn't. For example:
harden -f hardGrep -e '>1' grep # hardGrep does not tolerate being aborted
harden -f pipeGrep -e '>1' -P grep # pipeGrep for use in pipes that may break
Note: If SIGPIPE
was set to ignore by the process invoking the current
shell, the -p
option has no effect, because no process or subprocess of
the current shell can ever be killed by SIGPIPE
. However, this may cause
various other problems and you may want to refuse to let your program run
under that condition.
thisshellhas WRN_NOSIGPIPE
can help
you easily detect that condition so your program can make a decision. See
the WRN_NOSIGPIPE
description for more information.
The -t
option will trace command output. Each execution of a command
hardened with -t
causes the command line to be output to standard
error, in the following format:
[functionname]> commandline
where functionname
is the name of the shell function used to harden the
command and commandline
is the actual command executed. The
commandline
is properly shell-quoted in a format suitable for re-entry
into the shell; however, command lines longer than 512 bytes will be
truncated and the unquoted string (TRUNCATED)
will be appended to the
trace. If standard error is on a terminal that supports ANSI colours,
the tracing output will be colourised.
The -t
option was added to harden
because the commands that you harden
are often the same ones you would be particularly interested in tracing. The
advantage of using harden -t
over the shell's builtin tracing facility
(set -x
or set -o xtrace
) is that the output is a lot less noisy,
especially when using a shell library such as modernish.
Note: Internally, -t
uses the shell file descriptor 9, redirecting it to
standard error (using exec 9>&2
). This allows tracing to continue to work
normally even for commands that redirect standard error to a file (which is
another enhancement over set -x
on most shells). However, this does mean
harden -t
conflicts with any other use of the file descriptor 9 in your
shell program.
If file descriptor 9 is already open before harden
is called, harden
does not attempt to override this. This means tracing may be redirected
elsewhere by doing something like exec 9>trace.out
before calling
harden
. (Note that redirecting FD 9 on the harden
command itself will
not work as it won't survive the run of the command.)
Sometimes you just want to trace the execution of some specific commands as
in harden -t
(see above) without actually hardening them against command
errors; you might prefer to do your own error handling. trace
makes this
easy. It is modernish's replacement or complement for set -x
a.k.a. set -o xtrace
.
Unlike harden -t
, it can also trace shell functions.
Usage 1: trace
[ -f
funcname ] [ -[cSpXE]
]
[ var=
value ... ] [ -u
var ... ] command_name_or_path
[ command_argument ... ]
For non-function commands, trace
acts as a shortcut for
harden -t -P -e '>125 && !=255'
command_name_or_path.
Any further options and arguments are passed on to harden
as given. The
result is that the indicated command is automatically traced upon execution.
A bonus is that you still get minimal hardening against fatal system errors.
Errors in the traced command itself are ignored, but your program is
immediately halted with an informative error message if the traced command:
- cannot be found (exit status 127);
- was found but cannot be executed (exit status 126);
- was killed by a signal other than
SIGPIPE
(exit status > 128, except the shell-specific exit status forSIGPIPE
, and except 255 which is used by some utilities, such asssh
andrsync
, to return an error).
Note: The caveat for command-local variable assignments for harden
also
applies to trace
. See
Important note on variable assignments
above.
Usage 2: [ #!
] trace -f
funcname
If no further arguments are given, trace -f
will trace the shell
function funcname without applying further hardening (except against
nonexistence). trace -f
can be used to trace the execution of modernish
library functions as well as your own script's functions. The trace output
for shell functions shows an extra ()
following the function name.
Internally, this involves setting an alias under the function's name, so
the limitations of the shell's alias expansion mechanism apply: only
function calls that the shell had not yet parsed before calling trace -f
will be traced. So you should use trace -f
at the beginning of your
script, before defining your own functions. To facilitate this, trace -f
does not check that the function funcname exists while setting up
tracing, but only when attempting to execute the traced function.
In portable-form
modernish scripts, trace -f
should be used as a hashbang command to be
compatible with alias expansion on all shells. Only the trace -f
form
may be used that way. For example:
#! /usr/bin/env modernish
#! use safe -k
#! use sys/cmd/harden
#! trace -f push
#! trace -f pop
...your program begins here...
mapr
(map records) is an alternative to xargs
that shares features with the
mapfile
command in bash 4.x. It is fully integrated into your script's main
shell environment, so it can call your shell functions as well as builtin and
external utilities.
It depends on, and auto-loads, the sys/cmd/procsubst
module.
Usage: mapr
[ -d
delimiter | -P
] [ -s
count ] [ -n
number ]
[ -m
length ] [ -c
quantum ] callback
mapr
reads delimited records from the standard input, invoking the specified
callback command once or repeatedly as needed, with batches of input records
as arguments. The callback may consist of multiple arguments. By default, an
input record is one line of text.
Options:
-d
delimiter: Use the single character delimiter to delimit input records, instead of the newline character. ANUL
(0) character and multi-byte characters are not supported.-P
: Paragraph mode. Input records are delimited by sequences consisting of a newline plus one or more blank lines, and leading or trailing blank lines will not result in empty records at the beginning or end of the input. Cannot be used together with-d
.-s
count: Skip and discard the first count records read.-n
number: Stop processing after passing a total of number records to invocation(s) of callback. If-n
is not supplied or number is 0, all records are passed, except those skipped using-s
.-m
length: Set the maximum argument length in bytes of each callback command call, including the callback command argument(s) and the current batch of up to quantum input records. The length of each argument is increased by 1 to account for the terminating null byte. The default maximum length depends on constraints set by the operating system for invoking external commands. If length is 0, this limit is disabled.-c
quantum: Pass at most quantum arguments at a time to each call to callback. If-c
is not supplied or if quantum is 0, the number of arguments per invocation is not limited except by-m
; whichever limit is reached first applies.
Arguments:
- callback: Call the callback command with the collected arguments each
time quantum lines are read. The callback command may be a shell function or
any other kind of command, and is executed from the same shell environment
that invoked
mapr
. If the callback command exits or returns with status 255 or is interrupted by theSIGPIPE
signal,mapr
will not process any further batches but immediately exit with the status of the callback command. If it exits with another exit status 126 or greater, a fatal error is thrown. Otherwise,mapr
exits with the status of the last-executed callback command. - argument: If there are extra arguments supplied on the mapr command line, they will be added before the collected arguments on each invocation on the callback command.
mapr
was inspired by the bash 4.x builtin command mapfile
a.k.a.
readarray
, and uses similar options, but there are important differences.
mapr
passes all the records as arguments to the callback command.mapr
does not support assigning records directly to an array. Instead, all handling is done through the callback command (which could be a shell function that assigns its arguments to an array.)- The callback command is specified directly instead of with a
-C
option, and it may consist of several arguments (as withxargs
). - The record separator itself is never included in the arguments passed
to the callback command (so there is no
-t
option to remove it). mapr
supports paragraph mode.- If the callback command exits with status 255, processing is aborted.
mapr
shares important characteristics with
xargs
while avoiding its myriad pitfalls.
- Instead of being an external utility,
mapr
is fully integrated into the shell. The callback command can be a shell function or builtin, which can directly modify the shell environment. mapr
is line-oriented by default, so it is safe to use for input arguments that contain spaces or tabs.mapr
does not parse or modify the input arguments in any way, e.g. it does not process and remove quotes from them likexargs
does.mapr
supports paragraph mode.
This module provides a portable
process substitution
construct, the advantage being that this is not limited to bash, ksh or zsh
but works on all POSIX shells capable of running modernish. It is not
possible for modernish to introduce the original ksh syntax into other
shells. Instead, this module provides a %
command for use within a
$(
command substitution)
.
The %
command takes one simple command as its arguments, executes it in
the background, and writes a file name from which to read its output. So
if %
is used within a command substitution as intended, that file name
is passed on to the invoking command as an argument.
The %
command supports one option, -o
. If that option is given, then it is
expected that, instead of reading input, the invoking command writes output to
the file name passed on to it, so that the command invoked by % -o
can read
that data from its standard input.
ksh/bash/zsh | modernish |
---|---|
diff -u <(ls) <(ls -a)
|
diff -u $(% ls) $(% ls -a)
|
IFS=' ' read -r user vsz args < <(ps -o 'user= vsz= args=' -p $$)
|
IFS=' ' read -r user vsz args < $(% ps -o 'user= vsz= args=' -p $$)
|
{ some commands; } > >(tee stdout.log) 2> >(tee stderr.log)
(both `tee` commands write terminal output to standard output) |
{ some commands; } > $(% -o tee stdout.log) 2> $(% -o tee stderr.log)
(both `tee` commands write terminal output to standard error) |
Unlike the bash/ksh/zsh version, modernish process substitution only works with simple commands. This includes shell function calls, but not aliases or anything involving shell grammar or reserved words (such as redirections, pipelines, loops, etc.). To use such complex commands, enclose them in a shell function and call that function from the process substitution.
Also note that anything that a command invoked by the % -o
writes to its
standard output is redirected to standard error. The main shell environment's
standard output is not available because the command substitution subsumes it.
The source
command sources a dot script like the .
command, but
additionally supports passing arguments to sourced scripts like you would
pass them to a function. It mostly mimics the behaviour of the source
command built in to bash and zsh.
If a filename without a directory path is given, then, unlike the .
command, source
looks for the dot script in the current directory by
default, as well as searching $PATH
.
It is a fatal error to attempt to source a directory, a file with no read permission, or a nonexistent file.
Functions for working with directories.
countfiles
: Count the files in a directory using nothing but shell
functionality, so without external commands. (It's amazing how many pitfalls
this has, so a library function is needed to do it robustly.)
Usage: countfiles
[ -s
] directory [ globpattern ... ]
Count the number of files in a directory, storing the number in REPLY
and (unless -s
is given) printing it to standard output.
If any globpatterns are given, only count the files matching them.
The mkcd
function makes one or more directories, then, upon success,
change into the last-mentioned one. mkcd
inherits mkdir
's usage, so
options depend on your system's mkdir
; only the
POSIX options
are guaranteed.
When mkcd
is run from a script, it uses cd -P
to change the working
directory, resolving any symlinks in the present working directory path.
Utilities for working with the terminal.
This module provides commands to efficiently output a string repeatedly.
Usage:
putr
[ number |-
] stringputrln
[ number |-
] string
Output the string number times. When using putrln
, add a newline at
the end.
If a -
is given instead of a number, then the total length of the output
is the line length of the terminal divided by the length of the string,
rounded down.
Note that, unlike with put
and putln
, only a single string
argument is accepted.
Example: putrln - '='
prints a full terminal line of equals signs.
readkey
: read a single character from the keyboard without echoing back to
the terminal. Buffering is done so that multiple waiting characters are read
one at a time.
Usage: readkey
[ -E
ERE ] [ -t
timeout ] [ -r
] [ varname ]
-E
: Only accept characters that match the extended regular expression
ERE (the type of RE used by grep -E
/egrep
). readkey
will silently
ignore input not matching the ERE and wait for input matching it.
-t
: Specify a timeout in seconds (one significant digit after the
decimal point). After the timeout expires, no character is read and
readkey
returns status 1.
-r
: Raw mode. Disables INTR (Ctrl+C), QUIT, and SUSP (Ctrl+Z) processing
as well as translation of carriage return (13) to linefeed (10).
The character read is stored into the variable referenced by varname,
which defaults to REPLY
if not specified.
This module depends on the trap stack to save and restore the terminal state
if the program is stopped while reading a key, so it will automatically
use var/stack/trap
on initialisation.
This appendix lists all the shell capabilities, quirks, and bugs that modernish can detect in the current shell, so that modernish scripts can easily query the results of these tests and decide what to do. Certain problematic system conditions are also detected this way and listed here.
The all-caps IDs below are all usable with the
thisshellhas
function. This makes it easy for a cross-platform modernish script to
be aware of relevant conditions and decide what to do.
Each detection test has its own little test script in the
lib/modernish/cap
directory. These tests are executed on demand, the
first time the capability or bug in question is queried using
thisshellhas
. See README.md
in that directory for further information.
The test scripts also document themselves in the comments.
Modernish currently identifies and supports the following non-standard shell capabilities:
ADDASSIGN
: Add a string to a variable using additive assignment, e.g. VAR+=
stringANONFUNC
: zsh anonymous functions (basically the native zsh equivalent of modernish's var/local module)ARITHCMD
: standalone arithmetic evaluation using a command like((
expression))
.ARITHFOR
: ksh93/C-style arithmeticfor
loops of the formfor ((
exp1;
exp2;
exp3)) do
commands; done
.ARITHPP
: support for the++
and--
unary operators in shell arithmetic.CESCQUOT
: Quoting with C-style escapes, like$'\n'
for newline.DBLBRACKET
: The ksh88-style[[
double-bracket command]]
, implemented as a reserved word, integrated into the main shell grammar, and with a different grammar applying within the double brackets. (ksh93, mksh, bash, zsh, yash >= 2.48)DBLBRACKETERE
:DBLBRACKET
plus the=~
binary operator to match a string against an extended regular expression.DBLBRACKETV
:DBLBRACKET
plus the-v
unary operator to test if a variable is set. Named variables only. (Testing positional parameters (like[[ -v 1 ]]
) does not work on bash or ksh93; check$#
instead.)DOTARG
: Dot scripts support arguments.HERESTR
: Here-strings, an abbreviated kind of here-document.KSH88FUNC
: define ksh88-style shell functions with thefunction
keyword, supporting dynamically scoped local variables with thetypeset
builtin. (mksh, bash, zsh, yash, et al)KSH93FUNC
: the same, but with static scoping for local variables. (ksh93 only) See Q28 at the ksh93 FAQ for an explanation of the difference.KSHARRAY
: ksh93-style arrays. Supported on bash, zsh (underemulate sh
), mksh, and ksh93.LEPIPEMAIN
: execute last element of a pipe in the main shell, so that things like somecommand| read
somevariable work. (zsh, AT&T ksh, bash 4.2+)LINENO
: the$LINENO
variable contains the current shell script line number.LOCALVARS
: thelocal
command creates dynamically scoped local variables within functions defined using standard POSIX syntax.NONFORKSUBSH
: as a performance optimisation, subshells are implemented without forking a new process, so they share a PID with the main shell. (AT&T ksh93; it has many bugs related to this, but there's a nice workaround:ulimit -t unlimited
forces a subshell to fork, making those bugs disappear! See alsoBUG_FNSUBSH
.)PRINTFV
: The shell'sprintf
builtin has the-v
option to print to a variable, which avoids forking a command substitution subshell.PROCREDIR
: the shell natively supports<(
process redirection)
, a special kind of redirection that connects standard input (or standard output) to a background process running your command(s). This exists on yash. Note this is not combined with a redirection like< <(
command)
. Contrast with bash/ksh/zsh'sPROCSUBST
where this<(
syntax)
substitutes a file name.PROCSUBST
: the shell natively supports<(
process substitution)
, a special kind of command substitution that substitutes a file name, connecting it to a background process running your command(s). This exists on ksh93 and zsh. (Bash has it too, but its POSIX mode turns it off, so modernish can't use it.) Note this is usually combined with a redirection, like< <(
command)
. Contrast this with yash'sPROCREDIR
where the same<(
syntax)
is itself a redirection.PSREPLACE
: Search and replace strings in variables using special parameter substitutions with a syntax vaguely resembling sed.RANDOM
: the$RANDOM
pseudorandom generator. Modernish seeds it if detected. The variable is then set it to read-only whether the generator is detected or not, in order to block it from losing its special properties by being unset or overwritten, and to stop it being used if there is no generator. This is because some of modernish depends onRANDOM
either working properly or being unset.
(The use case for non-readonlyRANDOM
is setting a known seed to get reproducible pseudorandom sequences. To get that in a modernish script, useawk
'ssrand(yourseed)
andint(rand()*32768)
.)ROFUNC
: Set functions to read-only withreadonly -f
. (bash, yash)TESTERE
: The regulartest
/[
builtin command supports the=~
binary operator to match a string against an extended regular expression.TESTO
: Thetest
/[
builtin supports the-o
unary operator to check if a shell option is set.TRAPPRSUBSH
: The ability to obtain a list of the current shell's native traps from a command substitution subshell, for example:var=$(trap)
, as long as no new traps have been set within that command substitution. Note that thevar/stack/trap
module transparently reimplements this feature on shells without this native capability.TRAPZERR
: This feature ID is detected if theERR
trap is an alias for theZERR
trap. According to the zsh manual, this is the case for zsh on most systems, i.e. those that don't have aSIGERR
signal. (The trap stack uses this feature test.)VARPREFIX
: Expansions of type${!
prefix@}
and${!
prefix*}
yield all names of set variables beginning withprefix
in the same way and with the same quoting effects as$@
and$*
, respectively. This includes the name prefix itself, unless the shell hasBUG_VARPREFIX
. (bash; AT&T ksh93)
Modernish currently identifies and supports the following shell quirks:
QRK_32BIT
: mksh: the shell only has 32-bit arithmetic. Since every modern system these days supports 64-bit long integers even on 32-bit kernels, we can now count this as a quirk.QRK_ANDORBG
: On zsh, the&
operator takes the last simple command as the background job and not an entire AND-OR list (if any). In other words,a && b || c &
is interpreted asa && b || { c & }
and not{ a && b || c; } &
.QRK_ARITHEMPT
: In yash, with POSIX mode turned off, a set but empty variable yields an empty string when used in an arithmetic expression, instead of 0. For example,foo=''; echo $((foo))
outputs an empty line.QRK_ARITHWHSP
: In yash and FreeBSD /bin/sh, trailing whitespace from variables is not trimmed in arithmetic expansion, causing the shell to exit with an 'invalid number' error. POSIX is silent on the issue. The modernishisint
function (to determine if a string is a valid integer number in shell syntax) isQRK_ARITHWHSP
compatible, tolerating only leading whitespace.QRK_BCDANGER
:break
andcontinue
can affect non-enclosing loops, even across shell function barriers (zsh, Busybox ash; older versions of bash, dash and yash). (This is especially dangerous when using var/local which internally uses a temporary shell function to try to protect against breaking out of the block without restoring global parameters and settings.)QRK_EMPTPPFLD
: Unquoted$@
and$*
do not discard empty fields. POSIX says for both unquoted$@
and unquoted$*
that empty positional parameters may be discarded from the expansion. AFAIK, just one shell (yash) doesn't.QRK_EMPTPPWRD
: POSIX says that empty"$@"
generates zero fields but empty''
or""
or"$emptyvariable"
generates one empty field. But it leaves unspecified whether something like"$@$emptyvariable"
generates zero fields or one field. Zsh, pdksh/mksh and (d)ash generate one field, as seems logical. But bash, AT&T ksh and yash generate zero fields, which we consider a quirk. (See also BUG_PP_01)QRK_EVALNOOPT
:eval
does not parse options, not even--
, which makes it incompatible with other shells: on the one hand, (d)ash does not accept
eval -- "$command"
whereas on other shells this is necessary if the command starts with a-
, or the command would be interpreted as an option toeval
. A simple workaround is to prefix arbitrary commands with a space. Both situations are POSIX compliant, but since they are incompatible without a workaround,the minority situation is labeled here as a QuiRK.QRK_EXECFNBI
: In pdksh and zsh,exec
looks up shell functions and builtins before external commands, and if it finds one it does the equivalent of running the function or builtin followed byexit
. This is probably a bug in POSIX terms;exec
is supposed to launch a program that overlays the current shell, implying the program launched byexec
is always external to the shell. However, since the POSIX language is rather vague and possibly incorrect, this is labeled as a shell quirk instead of a shell bug.QRK_FNRDREXIT
: On FreeBSD sh and NetBSD sh, an error in a redirection attached to a function call causes the shell to exit. This affects redirections of all functions, including modernish library functions as well as functions set byharden
.QRK_GLOBDOTS
: Pathname expansion of.*
matches the pseudonames.
and..
so that, e.g.,cp -pr .* backup/
cannot be used to copy all your hidden files. (bash < 5.2, (d)ash, AT&T ksh != 93u+m, yash)QRK_HDPARQUOT
: Double quotes within certain parameter substitutions in here-documents aren't removed (FreeBSD sh; bosh). For instance, ifvar
is set,${var+"x"}
in a here-document yields"x"
, notx
. POSIX considers it undefined to use double quotes there, so they should be avoided for a script to be fully POSIX compatible. (Note this quirk does not apply for substitutions that remove patterns, such as${var#"$x"}
and${var%"$x"}
; those are defined by POSIX and double quotes are fine to use.) (Note 2: single quotes produce widely varying behaviour and should never be used within any form of parameter substitution in a here-document.)QRK_IFSFINAL
: in field splitting, a final non-whitespaceIFS
delimiter character is counted as an empty field (yash < 2.42, zsh, pdksh). This is a QRK (quirk), not a BUG, because POSIX is ambiguous on this.QRK_LOCALINH
: On a shell withLOCALVARS
, local variables, when declared without assigning a value, inherit the state of their global namesake, if any. (dash, FreeBSD sh)QRK_LOCALSET
: On a shell withLOCALVARS
, local variables are immediately set to the empty value upon being declared, instead of being initially without a value. (zsh)QRK_LOCALSET2
: LikeQRK_LOCALSET
, but only if the variable by the same name in the global/parent scope is unset. If the global variable is set, then the local variable starts out unset. (bash 2 and 3)QRK_LOCALUNS
: On a shell withLOCALVARS
, local variables lose their local status when unset. Since the variable name reverts to global, this means thatunset
will not necessarily unset the variable! (yash, pdksh/mksh. Note: this is actually a behaviour oftypeset
, to which modernish aliaseslocal
on these shells.)QRK_LOCALUNS2
: This is a more treacherous version ofQRK_LOCALUNS
that is unique to bash. Theunset
command works as expected when used on a local variable in the same scope that variable was declared in, however, it makes local variables global again if they are unset in a subscope of that local scope, such as a function called by the function where it is local. (Note: sinceQRK_LOCALUNS2
is a special case ofQRK_LOCALUNS
, modernish will not detect both.) On bash >= 5.0, modernish eliminates this quirk upon initialisation by settingshopt -s localvar_unset
.QRK_OPTABBR
: Long-form shell option names can be abbreviated down to a length where the abbreviation is not redundant with other long-form option names. (ksh93, yash)QRK_OPTCASE
: Long-form shell option names are case-insensitive. (yash, zsh)QRK_OPTDASH
: Long-form shell option names ignore the-
. (ksh93, yash)QRK_OPTNOPRFX
: Long-form shell option names use a dynamicno
prefix for all options (including POSIX ones). For instance,glob
is the opposite ofnoglob
, andnonotify
is the opposite ofnotify
. (ksh93, yash, zsh)QRK_OPTULINE
: Long-form shell option names ignore the_
. (yash, zsh)QRK_PPIPEMAIN
: On zsh <= 5.5.1, in all elements of a pipeline, parameter expansions are evaluated in the current environment (with any changes they make surviving the pipeline), though the commands themselves of every element but the last are executed in a subshell. For instance, given unset or emptyv
, in the pipelinecmd1 ${v:=foo} | cmd2
, the assignment tov
survives, thoughcmd1
itself is executed in a subshell.QRK_SPCBIXP
: Variable assignments directly preceding special builtin commands are exported, and persist as exported. (bash; yash)QRK_UNSETF
: If 'unset' is invoked without any option flag (-v or -f), and no variable by the given name exists but a function does, the shell unsets the function. (bash)
Modernish currently identifies and supports the following shell bugs:
BUG_ALIASCSHD
: A spurious syntax error occurs if a here-document containing a command substitution is used within two aliases that define a block. The syntax error reporting a missing}
occurs because the alias terminating the block is not correctly expanded. This bug affectsvar/local
andvar/loop
as they define blocks this way. Workaround: make a shell function that handles the here-document and call that shell function from the block/loop instead. Bug found on: dash <= 0.5.10.2; Busybox ash <= 1.31.1.BUG_ALIASPOSX
: Running any command "foo" in POSIX mode likePOSIXLY_CORRECT=y foo
will globally disable alias expansion on a non-interactive shell (killing modernish), unless POSIX mode is globally enabled. Bug found on bash 4.2 through 5.0. Note: on bash versions with this bug, modernish automatically enables POSIX mode to avoid triggering it. A side effect is that process substitution (PROCSUBST
) isn't available.BUG_ARITHINIT
: Using unset or empty variables (dash <= 0.5.9.1 on macOS) or unset variables (yash <= 2.44) in arithmetic expressions causes the shell to exit, instead of taking them as a value of zero.BUG_ARITHLNNO
: The shell supports$LINENO
, but the variable is considered unset in arithmetic contexts, like$(( LINENO > 0 ))
. This makes it error out underset -u
and default to zero otherwise. Workaround: use shell expansion like$(( $LINENO > 0 ))
. (FreeBSD sh)BUG_ARITHNAN
: The case-insensitive special floating point constantsInf
andNaN
are recognised in arithmetic evaluation, overriding any variables with the namesInf
,NaN
,INF
,nan
, etc. (AT&T ksh93; zsh 5.6 - 5.8)BUG_ARITHSPLT
: Unquoted$((
arithmetic expressions))
are not subject to field splitting as expected. (zsh, mksh<=R49)BUG_ASGNCC01
: ifIFS
contains a$CC01
(^A
) character, unquoted expansions in shell assignments discard that character (if present). Found on: bash 4.0-4.3BUG_ASGNLOCAL
: If you have a function-local variable (seeLOCALVARS
) with the same name as a global variable, and within the function you run a shell builtin command preceded by a temporary variable assignment, then the global variable is unset. (zsh <= 5.7.1)BUG_BRACQUOT
: shell quoting within bracket patterns has no effect (zsh < 5.3; ksh93) This bug means the-
retains it special meaning of 'character range', and an initial!
(and, on some shells,^
) retains the meaning of negation, even in quoted strings within bracket patterns, including quoted variables.BUG_CASEEMPT
: An emptycase
list on a single line, as incase x in esac
, is a syntax error. (AT&T ksh93)BUG_CASELIT
: If acase
pattern doesn't match as a pattern, it's tried again as a literal string, even if the pattern isn't quoted. This can result in false positives when a pattern doesn't match itself, like with bracket patterns. This contravenes POSIX and breaks use cases such as input validation. (AT&T ksh93) Note: modernishmatch
works around this.BUG_CASEPAREN
:case
patterns without an opening parenthesis (i.e. with only an unbalanced closing parenthesis) are misparsed as a syntax error within command substitutions of the form$( )
. Workaround: include the opening parenthesis. Found on: bash 3.2BUG_CASESTAT
: Thecase
conditional construct prematurely clobbers the exit status$?
. (found in zsh < 5.3, Busybox ash <= 1.25.0, dash < 0.5.9.1)BUG_CDNOLOGIC
: Thecd
built-in command lacks the POSIX-specified-L
option and does not support logical traversal; it always acts as if the-P
(physical traversal) option was passed. This also renders the-L
option to modernishchdir
ineffective. (NetBSD sh)BUG_CDPCANON
:cd -P
(and hence also modernishchdir
) does not correctly canonicalise/normalise a directory path that starts with three or more slashses; it reduces these to two initial slashes instead of one in$PWD
. (zsh <= 5.7.1)BUG_CMDEXEC
: usingcommand exec
(to open a file descriptor, usingcommand
to avoid exiting the shell on failure) within a function causes bash <= 4.0 to fail to restore the global positional parameters when leaving that function. It also renders bash <=4.0 prone to hanging.BUG_CMDEXPAN
: if thecommand
command results from an expansion, it acts likecommand -v
, showing the path of the command instead of executing it. For example:v=command; "$v" ls
orset -- command ls; "$@"
don't work. (AT&T ksh93)BUG_CMDOPTEXP
: thecommand
builtin does not recognise options if they result from expansions. For instance, you cannot conditionally store-p
in a variable likedefaultpath
and then docommand $defaultpath someCommand
. (found in zsh < 5.3)BUG_CMDPV
:command -pv
does not find builtins ({pd,m}ksh), does not accept the -p and -v options together (zsh < 5.3) or ignores the-p
option altogether (bash 3.2); in any case, it's not usable to find commands in the default system PATH.BUG_CMDSETPP
: usingcommand set --
has no effect; it does not set the positional parameters. For compat, useset
withoutcommand
. (mksh <= R57)BUG_CMDSPASGN
: preceding a special builtin withcommand
does not stop preceding invocation-local variable assignments from becoming global. (AT&T ksh93)BUG_CMDSPEXIT
: preceding a special builtin (other thaneval
,exec
,return
orexit
) withcommand
does not always stop it from exiting the shell if the builtin encounters error. (bash <= 4.0; zsh <= 5.2; mksh; ksh93)BUG_CSNHDBKSL
: Backslashes within non-expanding here-documents within command substitutions are incorrectly expanded to perform newline joining, as opposed to left intact. (bash <= 4.4)BUG_CSUBBTQUOT
: A spurious syntax erorr is thrown when using double quotes within a backtick-style command substitution that is itself within double quotes. (AT&T ksh93 < 93u+m 2022-05-20)BUG_CSUBLNCONT
: Backslash line continuation is not processed correctly within modern-form$(
command substitutions)
. (AT&T ksh93 < 93u+m 2022-05-21)BUG_CSUBRMLF
: A bug affecting the stripping of final linefeeds from command substitutions. If a command substitution does not produce any output to substitute and is concatenated in a string or here-document, then the shell removes any concurrent linefeeds occurring directly before the command substitution in that string or here-document. (dash <= 0.5.10.2, Busybox ash, FreeBSD sh)BUG_CSUBSTDO
: If standard output (file descriptor 1) is closed before entering a command substitution, and any other file descriptors are redirected within the command substitution, commands such asecho
orputln
will not work within the command substitution, acting as if standard output is still closed (AT&T ksh93 <= AJM 93u+ 2012-08-01). Workaround: seecap/BUG_CSUBSTDO.t
.BUG_DEVTTY
: the shell can't redirect output to/dev/tty
ifset -C
/set -o noclobber
(part of safe mode) is active. Workaround: use>| /dev/tty
instead of> /dev/tty
. Bug found on: bash on certain systems (at least QNX and Interix).BUG_DOLRCSUB
: parsing problem where, inside a command substitution of the form$(...)
, the sequence$$'...'
is treated as$'...'
(i.e. as a use of CESCQUOT), and$$"..."
as$"..."
(bash-specific translatable string). (Found in bash up to 4.4)BUG_DQGLOB
: globbing is not properly deactivated within double-quoted strings. Within double quotes, a*
or?
immediately following a backslash is interpreted as a globbing character. This applies to both pathname expansion and pattern matching incase
. Found in: dash. (The bug is not triggered when using modernishmatch
.)BUG_EXPORTUNS
: Setting the export flag on an otherwise unset variable causes a set and empty environment variable to be exported, though the variable continues to be considered unset within the current shell. (FreeBSD sh < 13.0)BUG_FNSUBSH
: Function definitions within subshells (including command substitutions) are ignored if a function by the same name exists in the main shell, so the wrong function is executed.unset -f
is also silently ignored. ksh93 (all current versions as of November 2018) has this bug. It only applies to non-forked subshells. SeeNONFORKSUBSH
.BUG_FORLOCAL
: afor
loop in a function makes the iteration variable local to the function, so it won't survive the execution of the function. Found on: yash. This is intentional and documented behaviour on yash in non-POSIX mode, but in POSIX terms it's a bug, so we mark it as such.BUG_GETOPTSMA
: Thegetopts
builtin leaves a:
instead of a?
in the specified option variable if a given option that requires an argument lacks an argument, and the option string does not start with a:
. (zsh)BUG_HDOCBKSL
: Line continuation using backslashes in expanding here-documents is handled incorrectly. (zsh up to 5.4.2)BUG_HDOCMASK
: Here-documents (and here-strings, seeHERESTRING
) use temporary files. This fails if the currentumask
setting disallows the user to read, so the here-document can't read from the shell's temporary file. Workaround: ensure user-readableumask
when using here-documents. (bash, mksh, zsh)BUG_IFSCC01PP
: IfIFS
contains a$CC01
(^A
) control character, the expansion"$@"
(even quoted) is gravely corrupted. Since many modernish functions use this to loop through the positional parameters, this breaks the library. (Found in bash < 4.4)BUG_IFSGLOBC
: In glob pattern matching (such as incase
and[[
), if a wildcard character is part ofIFS
, it is matched literally instead of as a matching character. This applies to glob characters*
,?
,[
and]
. Since nearly all modernish functions usecase
for argument validation and other purposes, nearly every modernish function breaks on shells with this bug ifIFS
contains any of these three characters! (Found in bash < 4.4)BUG_IFSGLOBP
: In pathname expansion (filename globbing), if a wildcard character is part ofIFS
, it is matched literally instead of as a matching character. This applies to glob characters*
,?
,[
and]
. (Bug found in bash, all versions up to at least 4.4)BUG_IFSGLOBS
: in glob pattern matching (as incase
or parameter substitution with#
and%
), ifIFS
starts with?
or*
and the"$*"
parameter expansion inserts anyIFS
separator characters, those characters are erroneously interpreted as wildcards when quoted "$*" is used as the glob pattern. (AT&T ksh93)BUG_IFSISSET
: AT&T ksh93 (2011/2012 versions):${IFS+s}
always yieldss
even ifIFS
is unset. This applies toIFS
only.BUG_ISSETLOOP
: AT&T ksh93: Expansions like${var+set}
remain static when used within afor
,while
oruntil
loop; the expansions don't change along with the state of the variable, so they cannot be used to check whether a variable is set within a loop if the state of that variable may change in the course of the loop.BUG_KBGPID
: AT&T ksh93: If a single command ending in&
(i.e. a background job) is enclosed in a{
braces; }
block with an I/O redirection, the$!
special parameter is not set to the background job's PID.BUG_KUNSETIFS
: AT&T ksh93: UnsettingIFS
fails to activate default field splitting if the following conditions are met: 1.IFS
is set and empty (i.e. split is disabled) in the main shell, and at least one expansion has been processed with that setting; 2. The code is currently executing in a non-forked subshell (seeNONFORKSUBSH
).BUG_LNNONEG
:$LINENO
becomes wildly inaccurate, even negative, when dotting/sourcing scripts. Bug found on: dash with LINENO support compiled in.BUG_LOOPRET1
: If areturn
command is given with a status argument within the set of conditional commands in awhile
oruntil
loop (i.e., betweenwhile
/until
anddo
), the status argument is ignored and the function returns with status 0 instead of the specified status. Found on: dash <= 0.5.8; zsh <= 5.2BUG_LOOPRET2
: If areturn
command is given without a status argument within the set of conditional commands in awhile
oruntil
loop (i.e., betweenwhile
/until
anddo
), the exit status passed down from the previous command is ignored and the function returns with status 0 instead. Found on: dash <= 0.5.10.2; AT&T ksh93; zsh <= 5.2BUG_LOOPRET3
: If areturn
command is given within the set of conditional commands in awhile
oruntil
loop (i.e., betweenwhile
/until
anddo
), and the return status (either the status argument toreturn
or the exit status passed down from the previous command byreturn
without a status argument) is non-zero, and the conditional command list itself yields false (forwhile
) or true (foruntil
), and the whole construct is executed in a dot script sourced from another script, then too many levels of loop are broken out of, causing program flow corruption or premature exit. Found on: zsh <= 5.7.1BUG_MULTIBIFS
: We're on a UTF-8 locale and the shell supports UTF-8 characters in general (i.e. we don't haveWRN_MULTIBYTE
) – however, using multi-byte characters asIFS
field delimiters still doesn't work. For example,"$*"
joins positional parameters on the first byte ofIFS
instead of the first character. (ksh93, mksh, FreeBSD sh, Busybox ash)BUG_NOCHCLASS
: POSIX-mandated character[:
classes:]
within bracket[
expressions]
are not supported in glob patterns. (mksh)BUG_NOEXPRO
: Cannot export read-only variables. (zsh <= 5.7.1 in sh mode)BUG_OPTNOLOG
: on dash, setting-o nolog
causes$-
to wreak havoc: trying to expand$-
silently aborts parsing of an entire argument, so e.g."one,$-,two"
yields"one,"
. (Same applies to-o debug
.)BUG_PP_01
: POSIX says that empty"$@"
generates zero fields but empty''
or""
or"$emptyvariable"
generates one empty field. This means concatenating"$@"
with one or more other, separately quoted, empty strings (like"$@""$emptyvariable"
) should still produce one empty field. But on bash 3.x, this erroneously produces zero fields. (See also QRK_EMPTPPWRD)BUG_PP_02
: LikeBUG_PP_01
, but with unquoted$@
and only with"$emptyvariable"$@
, not$@"$emptyvariable"
. (mksh <= R50f; FreeBSD sh <= 10.3)BUG_PP_03
: WhenIFS
is unset or empty (zsh 5.3.x) or empty (mksh <= R50), assigningvar=$*
only assigns the first field, failing to join and discarding the rest of the fields. Workaround:var="$*"
(POSIX leavesvar=$@
, etc. undefined, so we don't test for those.)BUG_PP_03A
: WhenIFS
is unset, assignments likevar=$*
incorrectly remove leading and trailing spaces (but not tabs or newlines) from the result. Workaround: quote the expansion. Found on: bash 4.3 and 4.4.BUG_PP_03B
: WhenIFS
is unset, assignments likevar=${var+$*}
, etc. incorrectly remove leading and trailing spaces (but not tabs or newlines) from the result. Workaround: quote the expansion. Found on: bash 4.3 and 4.4.BUG_PP_03C
: WhenIFS
is unset, assigningvar=${var-$*}
only assigns the first field, failing to join and discarding the rest of the fields. (zsh 5.3, 5.3.1) Workaround:var=${var-"$*"}
BUG_PP_04A
: Like BUG_PP_03A, but for conditional assignments within parameter substitutions, as in: ${var=$*}
or: ${var:=$*}
. Workaround: quote either$*
within the expansion or the expansion itself. (bash <= 4.4)BUG_PP_04E
: When assigning the positional parameters ($*) to a variable using a conditional assignment within a parameter substitution, e.g.: ${var:=$*}
, the fields are always joined and separated by spaces, except ifIFS
is set and empty. Workaround as in BUG_PP_04A. (bash 4.3)BUG_PP_04_S
: WhenIFS
is null (empty), the result of a substitution like${var=$*}
is incorrectly field-split on spaces. The assignment itself succeeds normally. Found on: bash 4.2, 4.3BUG_PP_05
: POSIX says that empty$@
and$*
generate zero fields, but with nullIFS
, empty unquoted$@
and$*
yield one empty field. Found on: dash 0.5.9 and 0.5.9.1; Busybox ash.BUG_PP_06A
: POSIX says that unquoted$@
and$*
initially generate as many fields as there are positional parameters, and then (because$@
or$*
is unquoted) each field is split further according toIFS
. With this bug, the latter step is not done ifIFS
is unset (i.e. default split). Found on: zsh < 5.4BUG_PP_07
: unquoted$*
and$@
(including in substitutions like${1+$@}
or${var-$*}
) do not perform default field splitting ifIFS
is unset. Found on: zsh (up to 5.3.1) in sh modeBUG_PP_07A
: WhenIFS
is unset, unquoted$*
undergoes word splitting as ifIFS=' '
, and not the expectedIFS=" ${CCt}${CCn}"
. Found on: bash 4.4BUG_PP_08
: WhenIFS
is empty, unquoted$@
and$*
do not generate one field for each positional parameter as expected, but instead join them into a single field without a separator. Found on: yash < 2.44 and dash < 0.5.9 and Busybox ash < 1.27.0BUG_PP_08B
: WhenIFS
is empty, unquoted$*
within a substitution (e.g.${1+$*}
or${var-$*}
) does not generate one field for each positional parameter as expected, but instead joins them into a single field without a separator. Found on: bash 3 and 4BUG_PP_09
: WhenIFS
is non-empty but does not contain a space, unquoted$*
within a substitution (e.g.${1+$*}
or${var-$*}
) does not generate one field for each positional parameter as expected, but instead joins them into a single field separated by spaces (even though, as said,IFS
does not contain a space). Found on: bash 4.3BUG_PP_10
: WhenIFS
is null (empty), assigningvar=$*
removes any$CC01
(^A) and$CC7F
(DEL) characters. (bash 3, 4)BUG_PP_10A
: WhenIFS
is non-empty, assigningvar=$*
prefixes each$CC01
(^A) and$CC7F
(DEL) character with a$CC01
character. (bash 4.4)BUG_PP_1ARG
: WhenIFS
is empty on bash <= 4.3 (i.e. field splitting is off),${1+"$@"}
or"${1+$@}"
is counted as a single argument instead of each positional parameter as separate arguments. This also applies to prepending text only if there are positional parameters with something like"${1+foobar $@}"
.BUG_PP_MDIGIT
: Multiple-digit positional parameters don't require expansion braces, so e.g.$10
=${10}
(dash; Busybox ash). This is classed as a bug because it causes a straight-up incompatibility with POSIX scripts. POSIX says: "The parameter name or symbol can be enclosed in braces, which are optional except for positional parameters with more than one digit [...]".BUG_PP_MDLEN
: For${#x}
expansions where x >= 10, only the first digit of the positional parameter number is considered, e.g.${#10}
,${#12}
,${#123}
are all parsed as if they are${#1}
. Then, string parsing is aborted so that further characters or expansions, if any, are lost. Bug found in: dash 0.5.11 - 0.5.11.4 (fixed in dash 0.5.11.5)BUG_PSUBASNCC
: in an assignment parameter substitution of the form${foo=value}
, if the characters$CC01
(^A) or$CC7F
(DEL) are in the value, all their occurrences are stripped from the expansion (although the assignment itself is done correctly). If the expansion is quoted, only$CC01
is stripped. This bug is independent of the state ofIFS
, except ifIFS
is null, the assignment in${foo=$*}
(unquoted) is buggy too: it strips$CC01
from the assigned value. (Found on bash 4.2, 4.3, 4.4)BUG_PSUBBKSL1
: A backslash-escaped}
character within a quoted parameter substitution is not unescaped. (bash 3.2, dash <= 0.5.9.1, Busybox 1.27 ash)BUG_PSUBEMIFS
: ifIFS
is empty (no split, as in safe mode), then if a parameter substitution of the forms${foo-$*}
,${foo+$*}
,${foo:-$*}
or${foo:+$*}
occurs in a command argument, the characters$CC01
(^A) or$CC7F
(DEL) are stripped from the expanded argument. (Found on: bash 4.4)BUG_PSUBEMPT
: Expansions of the form${V-}
and${V:-}
are not subject to normal shell empty removal if that parameter is unset, causing unexpected empty arguments to commands. Workaround:${V+$V}
and${V:+$V}
work as expected. (Found on FreeBSD 10.3 sh)BUG_PSUBIFSNW
: When field-splitting unquoted parameter substitutions like${var#foo}
,${var##foo}
,${var%foo}
or${var%%foo}
on non-whitespaceIFS
, if there is an initial empty field, a spurious extra initial empty field is generated. (mksh)BUG_PSUBNEWLN
: Due to a bug in the parser, parameter substitutions spread over more than one line cause a syntax error. Workaround: instead of a literal newline, use$CCn
. (found in dash <= 0.5.9.1 and Busybox ash <= 1.28.1)BUG_PSUBSQUOT
: in pattern matching parameter substitutions (${param#pattern}
,${param%pattern}
,${param##pattern}
and${param%%pattern}
), if the whole parameter substitution is quoted with double quotes, then single quotes in the pattern are not parsed. POSIX says they are to keep their special meaning, so that glob characters may be quoted. For example:x=foobar; echo "${x#'foo'}"
should yieldbar
but with this bug yieldsfoobar
. (dash <= 0.5.9.1; Busybox 1.27 ash)BUG_PSUBSQHD
: Like BUG_PSUBSQUOT, but included a here-document instead of quoted with double quotes. (dash <= 0.5.9.1; mksh)BUG_PUTIOERR
: Shell builtins that output strings (echo
,printf
, ksh/zshprint
), and thus also modernishput
andputln
, do not check for I/O errors on output. This means a script cannot check for them, and a script process in a pipe can get stuck in an infinite loop ifSIGPIPE
is ignored.BUG_READWHSP
: If there is more than one field to read,read
does not trim trailingIFS
whitespace. (dash 0.5.7, 0.5.8)BUG_REDIRIO
: the I/O redirection operator<>
(open a file descriptor for both read and write) defaults to opening standard output (i.e. is short for1<>
) instead of defaulting to opening standard input (0<>
) as POSIX specifies. (AT&T ksh93)BUG_REDIRPOS
: Buggy behaviour occurs if a redirection is positioned in between to variable assignments in the same command. On zsh 5.0.x, a parse error is thrown. On zsh 5.1 to 5.4.2, anything following the redirection (other assignments or command arguments) is silently ignored.BUG_SCLOSEDFD
: bash < 5.0 and dash fail to establish a block-local scope for a file descriptor that is added to the end of the block as a redirection that closes that file descriptor (e.g.} 8<&-
ordone 7>&-
). If that FD is already closed outside the block, the FD remains global, so you can't locallyexec
it. So with this bug, it is not straightforward to make a block-local FD appear initially closed within a block. Workaround: first open the FD, then close it – for example:done 7>/dev/null 7>&-
will establish a local scope for FD 7 for the precedingdo
...done
block while still making FD 7 appear initially closed within the block.BUG_SETOUTVAR
: Theset
builtin (with no arguments) only prints native function-local variables when called from a shell function. (yash <= 2.46)BUG_SHIFTERR0
: Theshift
builtin silently returns a successful exit status (0) when attempting to shift a number greater than the current amount of positional parameters. (Busybox ash <= 1.28.4)BUG_SPCBILOC
: Variable assignments preceding special builtins create a partially function-local variable if a variable by the same name already exists in the global scope. (bash < 5.0 in POSIX mode)BUG_TESTERR1A
:test
/[
exits with a non-errorfalse
status (1) if an invalid argument is given to an operator. (AT&T ksh93)BUG_TESTILNUM
: On dash (up to 0.5.8), giving an illegal number totest -t
or[ -t
causes some kind of corruption so the nexttest
/[
invocation fails with an "unexpected operator" error even if it's legit.BUG_TESTONEG
: Thetest
/[
builtin supports a-o
unary operator to check if a shell option is set, but it ignores theno
prefix on shell option names, so something like[ -o noclobber ]
gives a false positive. Bug found on yash up to 2.43. (TheTESTO
feature test implicitly checks against this bug and won't detect the feature if the bug is found.)BUG_TRAPEMPT
: Thetrap
builtin does not quote empty traps in its output, rendering the output unsuitable for shell re-input. For instance,trap '' INT; trap
outputs "trap -- INT
" instead of "trap -- '' INT
". (found in mksh <= R56c)BUG_TRAPEXIT
: the shell'strap
builtin does not know the EXIT trap by name, but only by number (0). Using the name throws a "bad trap" error. Found in klibc 2.0.4 dash.BUG_TRAPFNEXI
: When a function issues a signal whose trap exits the shell, the shell is not exited immediately, but only on return from the function. (zsh)BUG_TRAPRETIR
: Usingreturn
withineval
triggers infinite recursion if both a RETURN trap and thefunctrace
shell option are active. This bug in bash-only functionality triggers a crash when using modernish, so to avoid this, modernish automatically disables thefunctrace
shell option if aRETURN
trap is set or pushed and this bug is detected. (bash 4.3, 4.4)BUG_TRAPSUB0
: Subshells in traps fail to pass down a nonzero exit status of the last command they execute, under certain conditions or consistently, depending on the shell. (bash <= 4.0; dash 0.5.9 - 0.5.10.2; yash <= 2.47)BUG_TRAPUNSRE
: When a trap unsets itself and then resends its own signal, the execution of the trap action (including functions called by it) is not interrupted by the now-untrapped signal; instead, the process terminates after completing the entire trap routine. (bash <= 4.2; zsh)BUG_UNSETUNXP
: If an unset variable is given the export flag using theexport
command, a subsequentunset
command does not remove that export flag again. Workaround: assign to the variable first, then unset it to unexport it. (Found on AT&T ksh JM-93u-2011-02-08; Busybox 1.27.0 ash)BUG_VARPREFIX
: On a shell with theVARPREFIX
feature, expansions of type${!
prefix@}
and${!
prefix*}
do not find the variable name prefix itself. (AT&T ksh93)BUG_ZSHNAMES
: A series of lowerase names, normally okay for script use as per POSIX convention, is reserved for special use. Unsetting these names is impossible in most cases, and changing them may corrupt important shell or system settings. This may conflict with simple-form modernish scripts. This bug is detected on zsh when it was not initially invoked in emulation mode, and emulation mode was enabled usingemulate sh
post invocation instead (which does not disable these conflicting parameters). As of zsh 5.6, the list of variable names affected is:aliases
argv
builtins
cdpath
commands
dirstack
dis_aliases
dis_builtins
dis_functions
dis_functions_source
dis_galiases
dis_patchars
dis_reswords
dis_saliases
fignore
fpath
funcfiletrace
funcsourcetrace
funcstack
functions
functions_source
functrace
galiases
histchars
history
historywords
jobdirs
jobstates
jobtexts
keymaps
mailpath
manpath
module_path
modules
nameddirs
options
parameters
patchars
path
pipestatus
prompt
psvar
reswords
saliases
signals
status
termcap
terminfo
userdirs
usergroups
watch
widgets
zsh_eval_context
zsh_scheduled_events
BUG_ZSHNAMES2
: Two lowercase variable nameshistchars
andsignals
, normally okay for script use as per POSIX convention, are reserved for special use on zsh, even if zsh is initialised in sh mode (via ash
symlink or using the--emulate sh
option at startup). Bug found on: zsh <= 5.7.1. The bug is only detected ifBUG_ZSHNAMES
is not detected, because this bug's effects are included in that one's.
Warning IDs do not identify any characteristic of the shell, but instead warn about a potentially problematic system condition that was detected at initialisation time.
WRN_EREMBYTE
: The current system locale setting supports Unicode UTF-8 multi-byte/variable-length characters, but the utility used bystr ematch
to match extended regular expressions (EREs) does not support them and treats all characters as single bytes. This means multi-byte characters will be matched as multiple characters, and character[:
classes:]
within bracket expressions will only match ASCII characters.WRN_MULTIBYTE
: The current system locale setting supports Unicode UTF-8 multi-byte/variable-length characters, but the current shell does not support them and treats all characters as single bytes. This means counting or processing multi-byte characters with the current shell will produce incorrect results. Scripts that need compatibility with this system condition should checkif thisshellhas WRN_MULTIBYTE
and resort to a workaround that uses external utilities where necessary.WRN_NOSIGPIPE
: Modernish has detected that the process that launched the current program has setSIGPIPE
to ignore, an irreversible condition that is in turn inherited by any process started by the current shell, and their subprocesses, and so on. The system constant$SIGPIPESTATUS
is set to the special value 99999 and neither the current shell nor any process it spawns is now capable of receivingSIGPIPE
. The-P
option toharden
is also rendered ineffective. Depending on how a given commandfoo
is implemented, it is now possible that a pipeline such asfoo | head -n 10
never ends; iffoo
doesn't check for I/O errors, the only way it would ever stop trying to write lines is by receivingSIGPIPE
ashead
terminates. Programs that use commands in this fashion should checkif thisshellhas WRN_NOSIGPIPE
and either employ workarounds or refuse to run if so.
Modernish comes with a suite of regression tests to detect bugs in modernish
itself, which can be run using modernish --test
after installation. By
default, it will run all the tests verbosely but without tracing the command
execution. The install.sh
installer will run modernish --test -eqq
on the
selected shell before installation.
A few options are available to specify after --test
:
-h
: show help.-e
: disable or reduce expensive (i.e. slow or memory-hogging) tests.-q
: quieter operation; report expected fails [known shell bugs] and unexpected fails [bugs in modernish]). Add-q
again for quietest operation (report unexpected fails only).-s
: entirely silent operation.-t
: run only specific test sets or tests. Test sets are those listed in the full default output ofmodernish --test
. This option requires an option-argument in the following format:
testset1:
num1,
num2,
…/
testset2:
num1,
num2,
…/
…
The colon followed by numbers is optional; if omitted, the entire set will be run, otherwise the given numbered tests will be run in the given order. Example:modernish --test -t match:2,4,7/arith/shellquote:1
runs test 2, 4 and 7 from thematch
set, the entirearith
set, and only test 1 from theshellquote
set. A testset can also be given as the incomplete beginning of a name or as a shell glob pattern. In that case, all matching sets will be run.-x
: trace each test using the shell'sxtrace
facility. Each trace is stored in a separate file in a specially created temporary directory. By default, the trace is deleted if a test does not produce an unexpected fail. Add-x
again to keep expected fails as well, and again to keep all traces regardless of result. If any traces were saved, modernish will tell you the location of the temporary directory at the end, otherwise it will silently remove the directory again.-E
: don't run any tests, but output a command to open the tests that would have been run in your editor. The editor from theVISUAL
orEDITOR
environment variable is used, withvi
as a default. This option should be used together with-t
to specify tests. All other options are ignored.-F
: takes an argument with the name or path to afind
utility to prefer when testingLOOP find
. More info here.
These short options can be combined so, for example,
--test -qxx
is the same as --test -q -x -x
.
Note the difference between these regression tests and the cap tests listed in
Appendix A. The latter are
tests for whatever shell is executing modernish: they detect capabilities
(features, quirks, bugs) of the current shell. They are meant to be run via
thisshellhas
and are designed to
be taken advantage of in scripts. On the other hand, these tests run by
modernish --test
are regression tests for modernish itself. It does not
make sense to use these in a script.
New/unknown shell bugs can still cause modernish regression tests to fail, of course. That's why some of the regression tests also check for consistency with the results of the capability detection tests: if there is a shell bug in a widespread release version that modernish doesn't know about yet, this in turn is considered to be a bug in modernish, because one of its goals is to know about all the shell bugs in all released shell versions currently seeing significant use.
The testshells.sh
program in share/doc/modernish/examples
can be used to
run the regression test suite on all the shells installed on your system.
You could put it as testshells
in some convenient location in your
$PATH
, and then simply run:
testshells modernish --test
(adding any further options you like – for instance, you might like to add
-q
to avoid very long terminal output). On first run, testshells
will
generate a list of shells it can find on your system and it will give you a
chance to edit it before proceeding.
modernish, like most shells, fully supports two system locales: POSIX (a.k.a. C, a.k.a. ASCII) and Unicode's UTF-8. It will work in other locales, but things like converting to upper/lower case, and matching single characters in patterns, are not guaranteed.
Caveat: some shells or operating systems have bugs that prevent (or lack
features required for) full locale support. If portability is a concern,
check for thisshellhas WRN_MULTIBYTE
or thisshellhas BUG_NOCHCLASS
where needed. See Appendix A.
Scripts/programs should not change the locale (LC_*
or LANG
) after
initialising modernish. Doing this might break various functions, as
modernish sets specific versions depending on your OS, shell and locale.
(Temporarily changing the locale is fine as long as you don't use
modernish features that depend on it – for example, setting a specific
locale just for an external command. However, if you use harden
, see
the important note
in its documentation!)
Modernish builds on the POSIX 2018 Edition standard, so it should run on any sufficiently POSIX-compliant shell and operating system. It uses both bug/feature detection and regression testing to determine whether it can run on any particular shell, so it does not block or support particular shell versions as such. However, modernish has been confirmed to run correctly on the following shells:
- bash 3.2 or higher
- Busybox ash 1.20.0 or higher, excluding 1.28.x (also possibly excluding anything older than 1.27.x on UTF-8 locales, depending on your operating system)
- dash (Debian sh) 0.5.7 or higher, excluding 0.5.10, 0.5.10.1, 0.5.11-0.5.11.4
- FreeBSD sh 11.0 or higher
- gwsh
- ksh 93u+ 2012-08-01, 93u+m
- mksh version R55 or higher
- NetBSD sh 9.0 or higher
- yash 2.40 or higher (2.44+ for POSIX mode)
- zsh 5.3 or higher
Currently known not to run modernish due to excessive bugs:
This appendix is specific to zsh.
While modernish duplicates some functionality already available natively
on zsh, it still has plenty to add. However, writing a normal
simple-form modernish script turns
emulate sh
on for the entire script, so you lose important aspects
of the zsh language.
But there is another way – modernish functionality may be integrated with native zsh scripts using 'sticky emulation', as follows:
emulate -R sh -c '. modernish'
This causes modernish functions to run in sh mode while your script will still run in native zsh mode with all its advantages. The following notes apply:
- Using the safe mode is not recommended, as zsh
does not apply split/glob to variable expansions by default, and the
modernish safe mode would defeat the
${~var}
and${=var}
flags that apply these on a case by case basis. This does mean that:- The
--split
and--glob
operators to constructs such asLOOP find
are not available. Use zsh expansion flags instead. - Quoting literal glob patterns to commands like
find
remains necessary.
- The
- Using
LOCAL
is not recommended. Anonymous functions are the native zsh equivalent. - Native zsh loops should be preferred over modernish loops, except where
modernish adds functionality not available in zsh (such as
LOOP find
or user-programmed loops).
See man zshbuiltins
under emulate
, option -c
, for more information.
The modernish installer install.sh
can bundle one or more scripts with a
stripped-down version of the modernish library. This allows the bundled scripts
to run with a known version of modernish, whether or not modernish is installed
on the user's system. Like modernish itself, bundling is cross-platform and
portable (or as portable as your script is).
Bundled scripts are not modified. Instead, for each script, a wrapper script is installed under the same name in the installation root directory. This wrapper automatically looks for a suitable POSIX-compliant shell that passes the modernish battery of fatal bug tests, then sets up the environment to run the real script with modernish on that shell. Your modernish script can be run through the supplied wrapper script from any directory location on any POSIX-compliant operating system, as long as all files remain in the same location relative to each other.
Bundling is always a non-interactive installer operation, with options specified on the command line. The installer usage for bundling is as follows:
install.sh
-B
-D
rootdir [ -d
subdir ]
[ -s
shell ] scriptfile [ scriptfile ... ]
The -B
option enables bundling mode. The option does not itself take an
option-argument. Instead, any number of scriptfiles to bundle can be given
as arguments following all other options. All scripts are bundled with a
single copy of modernish. The bundling operation does not deal with any
auxiliary files the scripts may require (other than modernish modules); any
such need to be added manually after bundling is complete.
The -D
option specifies the path to the bundled installation's root
directory, where wrapper scripts are installed. This option is mandatory.
If the directory doesn't exist, it is created.
The -d
option specifies the subdirectory of the -D
root directory where the
bundled scripts and modernish are installed. It can contain slashes to install
the bundle at a deeper directory level. The default subdirectory is bndl
.
The option-argument can be empty or /
, in which case the bundle is installed
directly into the installation root directory.
The -s
option specifies a preferred shell for the bundled scripts. A shell
name or a full path to a shell can be given. Wrapper scripts try the full path
first (if any), then try to find a shell with its basename, and then try to
find a shell with that basename minus any version number (e.g. bash
instead
of bash-5.0
or ksh
instead of ksh93
). If all that doesn't produce a shell
that passes fatal bugs tests, it continues with the normal shell search.
This means the script won't fail to launch if the preferred shell can't be
found. Instead, it is up to the script itself to refuse to run if required
shell-specific conditions are not met. Script should use the
thisshellhas
function to check for any nonstandard
capabilities
required, or any
bugs
or
quirks
that the script is incompatible with (or indeed requires!).
Bundling is supported for both
portable-form
and
simple-form
modernish scripts. The installer automatically adapts the wrapper scripts to
the form used. For simple-form scripts, the directory containing the bundled
modernish core library (by default, .../bndl/bin/modernish
) is prefixed to
$PATH
so that . modernish
works. Since simple-form scripts are often more
shell-specific, you may want to specify a preferred shell with the -s
option.
To save space, the bundled copy of the modernish library is reduced such that
all comments are stripped from the code,
interactive use
is not supported,
the regression test suite
is not included,
thisshellhas
does not have the --cache
and --show
operators,
and the
cap/*.t
capability detection scripts
are "statically linked" (directly included) into bin/modernish instead of
shipped as separate files.
A README.modernish
file is added with a short explanation, the licence,
and a link for people to get the complete version of modernish. Please do
not remove this when distributing bundled scripts.
EOF