/** \mainpage Documentation \htmlonly[block]

Documentation

\endhtmlonly \section introduction Introduction This is the documentation for `fish`, the friendly interactive shell. `fish` is a user friendly commandline shell intended mostly for interactive use. A shell is a program used to execute other programs. For the latest information on `fish`, please visit the `fish` homepage. \section syntax Syntax overview Shells like fish are used by giving them commands. Every `fish` command follows the same simple syntax. A command is executed by writing the name of the command followed by any arguments. Example: \fish echo hello world \endfish This calls the `echo` command. `echo` is a command which will write its arguments to the screen. In the example above, the output will be 'hello world'. Everything in fish is done with commands. There are commands for performing a set of commands multiple times, commands for assigning variables, commands for treating a group of commands as a single command, etc.. And every single command follows the same simple syntax. If you want to find out more about the echo command used above, read the manual page for the echo command by writing: `man echo` `man` is a command for displaying a manual page on a given topic. The man command takes the name of the manual page to display as an argument. There are manual pages for almost every command on most computers. There are also manual pages for many other things, such as system libraries and important files. Every program on your computer can be used as a command in `fish`. If the program file is located in one of the directories in the `PATH`, it is sufficient to type the name of the program to use it. Otherwise the whole filename, including the directory (like `/home/me/code/checkers/checkers` or `../checkers`) has to be used. Here is a list of some useful commands: - `cd`, change the current directory - `ls`, list files and directories - `man`, display a manual page on the screen - `mv`, move (rename) files - `cp`, copy files - `open`, open files with the default application associated with each filetype - `less`, list the contents of files Commands and parameters are separated by the space character ' '. Every command ends with either a newline (i.e. by pressing the return key) or a semicolon '`;`'. More than one command can be written on the same line by separating them with semicolons. A switch is a very common special type of argument. Switches almost always start with one or more hyphens '`-`' and alter the way a command operates. For example, the '`ls`' command usually lists all the files and directories in the current working directory, but by using the '`-l`' switch, the behavior of '`ls`' is changed to not only display the filename, but also the size, permissions, owner and modification time of each file. Switches differ between commands and are documented in the manual page for each command. Some switches are common to most command though, for example '`--help`' will usually display a help text, '`-i`' will often turn on interactive prompting before taking action, while '`-f`' will turn it off. \subsection quotes Quotes Sometimes features such as parameter expansion and character escapes get in the way. When that happens, the user can write a parameter within quotes, either `'` (single quote) or `"` (double quote). There is one important difference between single quoted and double quoted strings: When using double quoted string, variable expansion still takes place. Other than that, no other kind of expansion (including brace expansion and parameter expansion) will take place, the parameter may contain spaces, and escape sequences are ignored. The only backslash escape accepted within single quotes is `\'`, which escapes a single quote and `\\`, which escapes the backslash symbol. The only backslash escapes accepted within double quotes are `\"`, which escapes a double quote, `\$`, which escapes a dollar character, `\` followed by a newline, which deletes the backslash and the newline, and lastly `\\`, which escapes the backslash symbol. Single quotes have no special meaning within double quotes and vice versa. Example: \fish rm "cumbersome filename.txt" \endfish Will remove the file 'cumbersome filename.txt', while \fish rm cumbersome filename.txt \endfish would remove the two files 'cumbersome' and 'filename.txt'. \subsection escapes Escaping characters Some characters can not be written directly on the command line. For these characters, so called escape sequences are provided. These are: - '\\a' represents the alert character - '\\b' represents the backspace character - '\\e' represents the escape character - '\\f' represents the form feed character - '\\n' represents a newline character - '\\r' represents the carriage return character - '\\t' represents the tab character - '\\v' represents the vertical tab character - '\\ ' escapes the space character - '\\$' escapes the dollar character - '\\\\' escapes the backslash character - '\\*' escapes the star character - '\\?' escapes the question mark character - '\\~' escapes the tilde character - '\\%' escapes the percent character - '\\#' escapes the hash character - '\\(' escapes the left parenthesis character - '\\)' escapes the right parenthesis character - '\\{' escapes the left curly bracket character - '\\}' escapes the right curly bracket character - '\\[' escapes the left bracket character - '\\]' escapes the right bracket character - '\\\<' escapes the less than character - '\\\>' escapes the more than character - '\\^' escapes the circumflex character - '\\&' escapes the ampersand character - '\\;' escapes the semicolon character - '\\"' escapes the quote character - '\\'' escapes the apostrophe character - '\\xxx', where xx is a hexadecimal number, represents the ascii character with the specified value. For example, `\x9` is the tab character. - '\\Xxx', where xx is a hexadecimal number, represents a byte of data with the specified value. If you are using a multibyte encoding, this can be used to enter invalid strings. Only use this if you know what you are doing. - '\\ooo', where ooo is an octal number, represents the ascii character with the specified value. For example, `\011` is the tab character. - '\\uxxxx', where xxxx is a hexadecimal number, represents the 16-bit Unicode character with the specified value. For example, `\u9` is the tab character. - '\\Uxxxxxxxx', where xxxxxxxx is a hexadecimal number, represents the 32-bit Unicode character with the specified value. For example, `\U9` is the tab character. - '\\cx', where x is a letter of the alphabet, represents the control sequence generated by pressing the control key and the specified letter. For example, `\ci` is the tab character \subsection redirects Input/Output (IO) redirection Most programs use three input/output (IO) streams, each represented by a number called a file descriptor (FD). These are: - Standard input, FD 0, for reading, defaults to reading from the keyboard. - Standard output, FD 1, for writing, defaults to writing to the screen. - Standard error, FD 2, for writing errors and warnings, defaults to writing to the screen. The reason for providing for two output file descriptors is to allow separation of errors and warnings from regular program output. Any file descriptor can be directed to a different output than its default through a simple mechanism called a redirection. An example of a file redirection is `echo hello > output.txt`, which directs the output of the echo command to the file output.txt. - To read standard input from a file, write `DESTINATION` - To write standard error to a file, write `^DESTINATION` - To append standard output to a file, write `>>DESTINATION_FILE` - To append standard error to a file, write `^^DESTINATION_FILE` `DESTINATION` can be one of the following: - A filename. The output will be written to the specified file. - An ampersand (`&`) followed by the number of another file descriptor. The output will be written to that file descriptor instead. - An ampersand followed by a minus sign (`&-`). The file descriptor will be closed. Example: To redirect both standard output and standard error to the file 'all_output.txt', you can write `echo Hello > all_output.txt ^&1`. Any file descriptor can be redirected in an arbitrary way by prefixing the redirection with the file descriptor. - To redirect input of FD N, write `NDESTINATION` - To append the output of FD N to a file, write `N>>DESTINATION_FILE` Example: `echo Hello 2>output.stderr` and `echo Hello ^output.stderr` are equivalent, and write the standard error (file descriptor 2) of the target program to `output.stderr`. \subsection piping Piping The user can string together multiple commands into a so called pipeline. This means that the standard output of one command will be read in as standard input into the next command. This is done by separating the commands by the pipe character '`|`'. For example \fish cat foo.txt | head \endfish will call the `cat` program with the parameter 'foo.txt', which will print the contents of the file 'foo.txt'. The contents of foo.txt will then be filtered through the program 'head', which will pass on the first ten lines of the file to the screen. For more information on how to combine commands through pipes, read the manual pages of the commands you want to use using the `man` command. If you want to find out more about the `cat` program, type `man cat`. Pipes usually connect file descriptor 1 (standard output) of the first process to file descriptor 0 (standard input) of the second process. It is possible use a different output file descriptor by prepending the desired FD number and then output redirect symbol to the pipe. For example: \fish make fish 2>| less \endfish will attempt to build the fish program, and any errors will be shown using the less pager. \subsection syntax-background Background jobs When you start a job in `fish`, `fish` itself will pause, and give control of the terminal to the program just started. Sometimes, you want to continue using the commandline, and have the job run in the background. To create a background job, append an \& (ampersand) to your command. This will tell fish to run the job in the background. Background jobs are very useful when running programs that have a graphical user interface. Example: \fish emacs & \endfish will start the emacs text editor in the background. \subsection syntax-job-control Job control Most programs allow you to suspend the program's execution and return control to `fish` by pressing @key{Control,Z} (also referred to as `^Z`). Once back at the `fish` commandline, you can start other programs and do anything you want. If you then want you can go back to the suspended command by using the `fg` (foreground) command. If you instead want to put a suspended job into the background, use the `bg` command. To get a listing of all currently started jobs, use the `jobs` command. \subsection syntax-function Functions Functions are programs written in the fish syntax. They group together one or more commands and their arguments using a single name. It can also be used to start a specific command with additional arguments. For example, the following is a function definition that calls the command `ls` with the argument '`-l`' to print a detailed listing of the contents of the current directory: \fish function ll ls -l $argv end \endfish The first line tells fish that a function by the name of `ll` is to be defined. To use it, simply write `ll` on the commandline. The second line tells fish that the command `ls -l $argv` should be called when `ll` is invoked. '`$argv`' is an array variable, which always contains all arguments sent to the function. In the example above, these are simply passed on to the `ls` command. For more information on functions, see the documentation for the function builtin. \subsubsection syntax-function-wrappers Defining aliases One of the most common uses for functions is to slightly alter the behavior of an already existing command. For example, one might want to redefine the `ls` command to display colors. The switch for turning on colors on GNU systems is '`--color=auto`'. An alias, or wrapper, around `ls` might look like this: \fish function ls command ls --color=auto $argv end \endfish There are a few important things that need to be noted about aliases: - Always take care to add the `$argv` variable to the list of parameters to the wrapped command. This makes sure that if the user specifies any additional parameters to the function, they are passed on to the underlying command. - If the alias has the same name as the aliased command, it is necessary to prefix the call to the program with `command` in order to tell fish that the function should not call itself, but rather a command with the same name. Failing to do so will cause infinite recursion bugs. To easily create a function of this form, you can use the alias command. \subsubsection syntax-function-autoloading Autoloading functions Functions can be defined on the commandline or in a configuration file, but they can also be automatically loaded. This method of defining functions has several advantages. An autoloaded function becomes available automatically to all running shells. If the function definition is changed, all running shells will automatically reload the altered version. Startup time and memory usage is improved, etc. Fish automatically searches through any directories in the array variable `$fish_function_path`, and any functions defined are automatically loaded when needed. A function definition file must have a filename consisting of the name of the function plus the suffix '`.fish`'. By default, Fish searches the following for functions, using the first available file that it finds: - A directory for end-users to keep their own functions, usually `~/.config/fish/functions` (controlled by the `XDG_CONFIG_HOME` environment variable). - A directory for systems administrators to install functions for all users on the system, usually `/etc/fish/functions`. - A directory for third-party software vendors to ship their own functions for their software, usually `/usr/share/fish/vendor_functions.d`. - The functions shipped with fish, usually installed in `/usr/share/fish/functions`. These paths are controlled by parameters set at build, install, or run time, and may vary from the defaults listed above. This wide search may be confusing. If you are unsure, your functions probably belong in `~/.config/fish/functions`. It is very important that function definition files only contain the definition for the specified function and nothing else. Otherwise, it is possible that autoloading a function files requires that the function already be loaded, which creates a circular dependency. Autoloading also won't work for event handlers, since fish cannot know that a function is supposed to be executed when an event occurs when it hasn't yet loaded the function. See the event handlers section for more information. If you are developing another program, you may wish to install functions which are available for all users of the fish shell on a system. They can be installed to the "vendor" functions directory. As this path may vary from system to system, the `pkgconfig` framework should be used to discover this path with the output of `pkg-config --variable functionsdir fish`. \subsubsection syntax-conditional Conditional execution of code and flow control There are four fish builtins that let you execute commands only if a specific criterion is met. These builtins are `if`, `switch`, `and` and `or`. The `switch` command is used to execute one of possibly many blocks of commands depending on the value of a string. See the documentation for switch for more information. The other conditionals use the exit status of a command to decide if a command or a block of commands should be executed. See the documentation for `if`, `and` and `or` for more information. \subsection syntax-words Some common words This is a short explanation of some of the commonly used words in fish. - argument a parameter given to a command - builtin a command that is implemented in the shell. Builtins are commands that are so closely tied to the shell that it is impossible to implement them as external commands. - command a program that the shell can run. - function a block of commands that can be called as if they were a single command. By using functions, it is possible to string together multiple smaller commands into one more advanced command. - job a running pipeline or command - pipeline a set of commands stringed together so that the output of one command is the input of the next command - redirection an operation that changes one of the input/output streams associated with a job - switch a special flag sent as an argument to a command that will alter the behavior of the command. A switch almost always begins with one or two hyphens. \section docs Help `fish` has an extensive help system. Use the `help` command to obtain help on a specific subject or command. For instance, writing `help syntax` displays the syntax section of this documentation. `fish` also has man pages for its commands. For example, `man set` will show the documentation for `set` as a man page. Help on a specific builtin can also be obtained with the `-h` parameter. For instance, to obtain help on the `fg` builtin, either type `fg -h` or `help fg`. \section autosuggestions Autosuggestions fish suggests commands as you type, based on command history, completions, and valid file paths. As you type commands, you will see a suggestion offered after the cursor, in a muted gray color (which can be changed with the `fish_color_autosuggestion` variable). To accept the autosuggestion (replacing the command line contents), press right arrow or @key{Control,F}. To accept the first suggested word, press @key{Alt,→,Right} or @key{Alt,F}. If the autosuggestion is not what you want, just ignore it: it won't execute unless you accept it. Autosuggestions are a powerful way to quickly summon frequently entered commands, by typing the first few characters. They are also an efficient technique for navigating through directory hierarchies. \section completion Tab completion Tab completion is one of the most time saving features of any modern shell. By tapping the tab key, the user asks `fish` to guess the rest of the command or parameter that the user is currently typing. If `fish` can only find one possible completion, `fish` will write it out. If there is more than one completion, `fish` will write out the longest prefix that all completions have in common. If the completions differ on the first character, a list of all possible completions is printed. The list features descriptions of the completions and if the list doesn't fit the screen, it is scrollable by using the arrow keys, the page up/page down keys, the tab key or the space bar. Once the list has been entered, pressing any other key will start a search. If the list has not been entered, pressing any other key will exit the list and insert the pressed key into the command line. These are the general purpose tab completions that `fish` provides: - Completion of commands (builtins, functions and regular programs). - Completion of shell variable names. - Completion of usernames for tilde expansion. - Completion of filenames, even on strings with wildcards such as '`*`', '`**`' and '`?`'. - Completion of job ID, job name and process names for process expansion. `fish` provides a large number of program specific completions. Most of these completions are simple options like the `-l` option for `ls`, but some are more advanced. The latter include: - The programs `man` and `whatis` show all installed manual pages as completions. - The `make` program uses all targets in the Makefile in the current directory as completions. - The `mount` command uses all mount points specified in fstab as completions. - The `ssh` command uses all hosts that are stored in the known_hosts file as completions. (See the ssh documentation for more information) - The `su` command uses all users on the system as completions. - The `apt-get`, `rpm` and `yum` commands use all installed packages as completions. \subsection completion-own Writing your own completions Specifying your own completions is not difficult. To specify a completion, use the `complete` command. `complete` takes as a parameter the name of the command to specify a completion for. For example, to add a completion for the program `myprog`, one would start the completion command with `complete -c myprog ...` To provide a list of possible completions for myprog, use the `-a` switch. If `myprog` accepts the arguments start and stop, this can be specified as `complete -c myprog -a 'start stop'`. The argument to the `-a` switch is always a single string. At completion time, it will be tokenized on spaces and tabs, and variable expansion, command substitution and other forms of parameter expansion will take place. `fish` has a special syntax to support specifying switches accepted by a command. The switches `-s`, `-l` and `-o` are used to specify a short switch (single character, such as `-l`), a gnu style long switch (such as '`--color`') and an old-style long switch (like '`-shuffle`'), respectively. If the command 'myprog' has an option '-o' which can also be written as '`--output`', and which can take an additional value of either 'yes' or 'no', this can be specified by writing: \fish complete -c myprog -s o -l output -a "yes no" \endfish There are also special switches for specifying that a switch requires an argument, to disable filename completion, to create completions that are only available in some combinations, etc.. For a complete description of the various switches accepted by the `complete` command, see the documentation for the complete builtin, or write `complete --help` inside the `fish` shell. For examples of how to write your own complex completions, study the completions in `/usr/share/fish/completions`. (The exact path depends on your chosen installation prefix and may be slightly different) \subsection completion-func Useful functions for writing completions `fish` ships with several functions that are very useful when writing command specific completions. Most of these functions name begins with the string '`__fish_`'. Such functions are internal to `fish` and their name and interface may change in future fish versions. Still, some of them may be very useful when writing completions. A few of these functions are described here. Be aware that they may be removed or changed in future versions of fish. Functions beginning with the string `__fish_print_` print a newline separated list of strings. For example, `__fish_print_filesystems` prints a list of all known file systems. Functions beginning with `__fish_complete_` print out a newline separated list of completions with descriptions. The description is separated from the completion by a tab character. - `__fish_complete_directories STRING DESCRIPTION` performs path completion on STRING, allowing only directories, and giving them the description DESCRIPTION. - `__fish_complete_path STRING DESCRIPTION` performs path completion on STRING, giving them the description DESCRIPTION. - `__fish_complete_groups` prints a list of all user groups with the groups members as description. - `__fish_complete_pids` prints a list of all processes IDs with the command name as description. - `__fish_complete_suffix SUFFIX` performs file completion allowing only files ending in SUFFIX, with an optional description. - `__fish_complete_users` prints a list of all users with their full name as description. - `__fish_print_filesystems` prints a list of all known file systems. Currently, this is a static list, and not dependent on what file systems the host operating system actually understands. - `__fish_print_hostnames` prints a list of all known hostnames. This functions searches the fstab for nfs servers, ssh for known hosts and checks the `/etc/hosts` file. - `__fish_print_interfaces` prints a list of all known network interfaces. - `__fish_print_packages` prints a list of all installed packages. This function currently handles Debian, rpm and Gentoo packages. \subsection completion-path Where to put completions Completions can be defined on the commandline or in a configuration file, but they can also be automatically loaded. Fish automatically searches through any directories in the array variable `$fish_complete_path`, and any completions defined are automatically loaded when needed. A completion file must have a filename consisting of the name of the command to complete and the suffix '`.fish`'. By default, Fish searches the following for completions, using the first available file that it finds: - A directory for end-users to keep their own completions, usually `~/.config/fish/completions` (controlled by the `XDG_CONFIG_HOME` environment variable); - A directory for systems administrators to install completions for all users on the system, usually `/etc/fish/completions`; - A directory for third-party software vendors to ship their own completions for their software, usually `/usr/share/fish/vendor_completions.d`; - The completions shipped with fish, usually installed in `/usr/share/fish/completions`; and - Completions automatically generated from the operating system's manual, usually stored in `~/.local/share/generated_completions`. These paths are controlled by parameters set at build, install, or run time, and may vary from the defaults listed above. This wide search may be confusing. If you are unsure, your completions probably belong in `~/.config/fish/completions`. If you have written new completions for a common Unix command, please consider sharing your work by submitting it via the instructions in Further help and development. If you are developing another program and would like to ship completions with your program, install them to the "vendor" completions directory. As this path may vary from system to system, the `pkgconfig` framework should be used to discover this path with the output of `pkg-config --variable completionsdir fish`. \section expand Parameter expansion (Globbing) When an argument for a program is given on the commandline, it undergoes the process of parameter expansion before it is sent on to the command. Parameter expansion is a powerful mechanism that allows you to expand the parameter in various ways, including performing wildcard matching on files, inserting the value of a shell variable into the parameter or even using the output of another command as a parameter list. \subsection expand-wildcard Wildcards If a star (`*`) or a question mark (`?`) is present in the parameter, `fish` attempts to match the given parameter to any files in such a way that: - `?` can match any single character except '/'. - `*` can match any string of characters not containing '/'. This includes matching an empty string. - `**` matches any string of characters. This includes matching an empty string. The matched string may include the `/` character; that is, it recurses into subdirectories. Note that augmenting this wildcard with other strings will not match files in the current working directory (`$PWD`) if you separate the strings with a slash ("/"). This is unlike other shells such as zsh. For example, `**\/*.fish` in zsh will match `.fish` files in the PWD but in fish will only match such files in a subdirectory. In fish you should type `***.fish` to match files in the PWD as well as subdirectories. Other shells, such as zsh, provide a rich glob syntax for restricting the files matched by globs. For example, `**(.)`, to only match regular files. Fish prefers to defer such features to programs, such as `find`, rather than reinventing the wheel. Thus, if you want to limit the wildcard expansion to just regular files the fish approach is to define and use a function. For example, \fish{cli-dark} function ff --description 'Like ** but only returns plain files.' # This also ignores .git directories. find . \( -name .git -type d -prune \) -o -type f | \ sed -n -e '/^\.\/\.git$/n' -e 's/^\.\///p' end \endfish You would then use it in place of `**` like this, `my_prog (ff)`, to pass only regular files in or below $PWD to `my_prog`. Wildcard matches are sorted case insensitively. When sorting matches containing numbers, consecutive digits are considered to be one element, so that the strings '1' '5' and '12' would be sorted in the order given. File names beginning with a dot are not considered when wildcarding unless a dot is specifically given as the first character of the file name. Examples: - `a*` matches any files beginning with an 'a' in the current directory. - `???` matches any file in the current directory whose name is exactly three characters long. - `**` matches any files and directories in the current directory and all of its subdirectories. Note that for most commands, if any wildcard fails to expand, the command is not executed, `$status` is set to nonzero, and a warning is printed. This behavior is consistent with setting `shopt -s failglob` in bash. There are exactly 3 exceptions, namely `set`, `count` and `for`. Their globs are permitted to expand to zero arguments, as with `shopt -s nullglob` in bash. Examples: \fish ls *.foo # Lists the .foo files, or warns if there aren't any. set foos *.foo if count $foos >/dev/null ls $foos end # Lists the .foo files, if any. \endfish \subsection expand-command-substitution Command substitution The output of a series of commands can be used as the parameters to another command. If a parameter contains a set of parenthesis, the text enclosed by the parenthesis will be interpreted as a list of commands. On expansion, this list is executed, and substituted by the output. If the output is more than one line long, each line will be expanded to a new parameter. Setting `IFS` to the empty string will disable line splitting. The exit status of the last run command substitution is available in the status variable. Only part of the output can be used, see index range expansion for details. Examples: \fish echo (basename image.jpg .jpg).png # Outputs 'image.png'. for i in *.jpg; convert $i (basename $i .jpg).png; end # Convert all JPEG files in the current directory to the # PNG format using the 'convert' program. begin; set -l IFS; set data (cat data.txt); end # Set the `data` variable to the contents of 'data.txt' # without splitting it into an array. \endfish \subsection expand-brace Brace expansion A comma separated list of characters enclosed in curly braces will be expanded so each element of the list becomes a new parameter. Examples: \fish echo input.{c,h,txt} # Outputs 'input.c input.h input.txt' mv *.{c,h} src/ # Moves all files with the suffix '.c' or '.h' to the subdirectory src. \endfish \subsection expand-variable Variable expansion A dollar sign followed by a string of characters is expanded into the value of the shell variable with the same name. For an introduction to the concept of shell variables, read the Shell variables section. Undefined and empty variables expand to nothing. To separate a variable name from text it should immediately be followed by, encase the variable within quotes. Examples: \fish echo $HOME # Prints the home directory of the current user. echo $nonexistentvariable # Prints no output. echo The plural of $WORD is "$WORD"s # Prints "The plural of cat is cats" when $WORD is set to cat. echo The plural of $WORD is {$WORD}s # ditto \endfish Note that without the quotes or braces, fish will try to expand a variable called `$WORDs`, which may not exist. The latter syntax `{$WORD}` works by exploiting brace expansion; care should be taken with array variables and undefined variables, as these behave very differently to POSIX shells. Variable expansion is the only type of expansion performed on double quoted strings. There is, however, an important difference in how variables are expanded when quoted and when unquoted. An unquoted variable expansion will result in a variable number of arguments. For example, if the variable `$foo` has zero elements or is undefined, the argument `$foo` will expand to zero elements. If the variable $foo is an array of five elements, the argument `$foo` will expand to five elements. When quoted, like `"$foo"`, a variable expansion will always result in exactly one argument. Undefined variables will expand to the empty string, and array variables will be concatenated using the space character. There is one further notable feature of fish variable expansion. Consider the following code snippet: \fish set foo a b c set a 10; set b 20; set c 30 for i in (seq (count $$foo)) echo $$foo[$i] end # Output is: # 10 # 20 # 30 \endfish The above code demonstrates how to use multiple '`$`' symbols to expand the value of a variable as a variable name. One can think of the `$` symbol as a variable dereference operator. When using this feature together with array brackets, the brackets will always match the innermost `$` dereference. Thus, `$$foo[5]` will always mean the fifth element of the `foo` variable should be dereferenced, not the fifth element of the doubly dereferenced variable `foo`. The latter can instead be expressed as `$$foo[1][5]`. \subsection cartesian-product Cartesian Products Lists adjacent to other lists or strings are expanded as cartesian products: Examples: \fish{cli-dark} >_ echo {good,bad}" apples" good apples bad apples >_ set -l a x y z >_ set -l b 1 2 3 >_ echo $a$b x1 y1 z1 x2 y2 z2 x3 y3 z3 >_ echo $a"-"$b x-1 y-1 z-1 x-2 y-2 z-2 x-3 y-3 z-3 >_ echo {x,y,z}$b x1 y1 z1 x2 y2 z2 x3 y3 z3 >_ echo {$b}word 1word 2word 3word \endfish Be careful when you try to use braces to separate variable names from text. The dangers noted in the last example above can be avoided by wrapping the variable in double quotes instead of braces (`echo "$b"word`). \subsection expand-index-range Index range expansion Both command substitution and shell variable expansion support accessing only specific items by providing a set of indices in square brackets. It's often needed to access a sequence of elements. To do this, use the range operator '`..`' for this. A range '`a..b`', where range limits 'a' and 'b' are integer numbers, is expanded into a sequence of indices '`a a+1 a+2 ... b`' or '`a a-1 a-2 ... b`' depending on which of 'a' or 'b' is higher. The negative range limits are calculated from the end of the array or command substitution. Some examples: \fish # Limit the command substitution output echo (seq 10)[2..5] # Uses elements from 2 to 5 # Output is: 2 3 4 5 # Use overlapping ranges: echo (seq 10)[2..5 1..3] # Takes elements from 2 to 5 and then elements from 1 to 3 # Output is: 2 3 4 5 1 2 3 # Reverse output echo (seq 10)[-1..1] # Uses elements from the last output line to # the first one in reverse direction # Output is: 10 9 8 7 6 5 4 3 2 1 \endfish The same works when setting or expanding variables: \fish # Reverse path variable set PATH $PATH[-1..1] # or set PATH[-1..1] $PATH # Use only n last items of the PATH set n -3 echo $PATH[$n..-1] \endfish Note that variables can be used as indices for expansion of variables, but not command substitution. \subsection expand-home Home directory expansion The `~` (tilde) character at the beginning of a parameter, followed by a username, is expanded into the home directory of the specified user. A lone `~`, or a `~` followed by a slash, is expanded into the home directory of the process owner. \subsection expand-process Process expansion The `%` (percent) character at the beginning of a parameter followed by a string is expanded into a process ID (PID). The following expansions are performed: - If the string is the entire word `self`, the shell's PID is the result. - Otherwise, if the string is the entire word `last`, the last job's PID is the result. - Otherwise, if the string is the ID of a job, the result is the process group ID of the job. - Otherwise, if any child processes match the specified string, their PIDs are the result of the expansion. - Otherwise, if any processes owned by the user match the specified string, their PIDs are the result of the expansion. - If none of these matches apply, an error is produced. This form of expansion is useful for commands like kill and fg, which take process IDs as arguments. Example: `fg %ema` will search for a process whose command line begins with the letters 'ema', such as emacs, and if found, put it in the foreground. `kill -s SIGINT %3` will send the SIGINT signal to the job with job ID 3. \subsection combine Combining different expansions All of the above expansions can be combined. If several expansions result in more than one parameter, all possible combinations are created. When combining multiple parameter expansions, expansions are performed in the following order: - Command substitutions - Variable expansions - Bracket expansion - Pid expansion - Wildcard expansion Expansions are performed from right to left, nested bracket expansions are performed from the inside and out. Example: If the current directory contains the files 'foo' and 'bar', the command `echo a(ls){1,2,3} ` will output 'abar1 abar2 abar3 afoo1 afoo2 afoo3'. \section variables Shell variables Shell variables are named pieces of data, which can be created, deleted and their values changed and used by the user. Variables may optionally be "exported", so that a copy of the variable is available to any subprocesses the shell creates. An exported variable is referred to as an "environment variable". To set a variable value, use the `set` command. Example: To set the variable `smurf_color` to the value `blue`, use the command `set smurf_color blue`. After a variable has been set, you can use the value of a variable in the shell through variable expansion. Example: To use the value of the variable `smurf`, write `$` (dollar symbol) followed by the name of the variable, like `echo Smurfs are usually $smurf_color`, which would print the result 'Smurfs are usually blue'. \subsection variables-scope Variable scope There are three kinds of variables in fish: universal, global and local variables. Universal variables are shared between all fish sessions a user is running on one computer. Global variables are specific to the current fish session, but are not associated with any specific block scope, and will never be erased unless the user explicitly requests it using `set -e`. Local variables are specific to the current fish session, and associated with a specific block of commands, and is automatically erased when a specific block goes out of scope. A block of commands is a series of commands that begins with one of the commands `for`, `while` , `if`, `function`, `begin` or `switch`, and ends with the command `end`. The user can specify that a variable should have either global or local scope using the `-g/--global` or `-l/--local` switches. Variables can be explicitly set to be universal with the `-U` or `--universal` switch, global with the `-g` or `--global` switch, or local with the `-l` or `--local` switch. The scoping rules when creating or updating a variable are: -# If a variable is explicitly set to either universal, global or local, that setting will be honored. If a variable of the same name exists in a different scope, that variable will not be changed. -# If a variable is not explicitly set to be either universal, global or local, but has been previously defined, the variable scope is not changed. -# If a variable is not explicitly set to be either universal, global or local and has never before been defined, the variable will be local to the currently executing function. Note that this is different from using the `-l` or `--local` flag. If one of those flags is used, the variable will be local to the most inner currently executing block, while without these the variable will be local to the function. If no function is executing, the variable will be global. There may be many variables with the same name, but different scopes. When using a variable, the variable scope will be searched from the inside out, i.e. a local variable will be used rather than a global variable with the same name, a global variable will be used rather than a universal variable with the same name. Example: The following code will not output anything: \fish begin # This is a nice local scope where all variables will die set -l pirate 'There be treasure in them thar hills' end echo $pirate # This will not output anything, since the pirate was local \endfish \subsection variables-universal More on universal variables Universal variables are variables that are shared between all the users' fish sessions on the computer. Fish stores many of its configuration options as universal variables. This means that in order to change fish settings, all you have to do is change the variable value once, and it will be automatically updated for all sessions, and preserved across computer reboots and login/logout. To see universal variables in action, start two fish sessions side by side, and issue the following command in one of them `set fish_color_cwd blue`. Since `fish_color_cwd` is a universal variable, the color of the current working directory listing in the prompt will instantly change to blue on both terminals. Universal variables are stored in the file `.config/fish/fishd.MACHINE_ID`, where MACHINE_ID is typically your MAC address. Do not edit this file directly, as your edits may be overwritten. Edit them through fish scripts or by using fish interactively instead. Do not append to universal variables in config.fish, because these variables will then get longer with each new shell instance. Instead, simply set them once at the command line. \subsection variables-functions Variable scope for functions When calling a function, all current local variables temporarily disappear. This shadowing of the local scope is needed since the variable namespace would become cluttered, making it very easy to accidentally overwrite variables from another function. For example: \fish function shiver set phrase 'Shiver me timbers' end function avast set phrase 'Avast, mateys' # Calling the shiver function here can not # change any variables in the local scope shiver echo $phrase end avast # Outputs "Avast, mateys" \endfish \subsection variables-export Exporting variables Variables in fish can be exported. This means the variable will be inherited by any commands started by fish. It is convention that exported variables are in uppercase and unexported variables are in lowercase. Variables can be explicitly set to be exported with the `-x` or `--export` switch, or not exported with the `-u` or `--unexport` switch. The exporting rules when creating or updating a variable are identical to the scoping rules for variables: -# If a variable is explicitly set to either be exported or not exported, that setting will be honored. -# If a variable is not explicitly set to be exported or not exported, but has been previously defined, the previous exporting rule for the variable is kept. -# If a variable is not explicitly set to be either exported or not exported and has never before been defined, the variable will not be exported. \subsection variables-arrays Arrays `fish` can store a list of multiple strings inside of a variable. To access one element of an array, use the index of the element inside of square brackets, like this: `echo $PATH[3]` Note that array indices start at 1 in `fish`, not 0, as is more common in other languages. This is because many common Unix tools like `seq` are more suited to such use. If you do not use any brackets, all the elements of the array will be written as separate items. This means you can easily iterate over an array using this syntax: \fish for i in $PATH; echo $i is in the path; end \endfish To create a variable `smurf`, containing the items `blue` and `small`, simply write: \fish set smurf blue small \endfish It is also possible to set or erase individual elements of an array: \fish # Set smurf to be an array with the elements 'blue' and 'small' set smurf blue small # Change the second element of smurf to 'evil' set smurf[2] evil # Erase the first element set -e smurf[1] # Output 'evil' echo $smurf \endfish If you specify a negative index when expanding or assigning to an array variable, the index will be calculated from the end of the array. For example, the index -1 means the last index of an array. A range of indices can be specified, see index range expansion for details. All arrays are one-dimensional and cannot contain other arrays, although it is possible to fake nested arrays using the dereferencing rules of variable expansion. `fish` automatically creates arrays from the variables `PATH`, `CDPATH` and `MANPATH` when it is started. (Previous versions created arrays from *all* colon-delimited environment variables.) \subsection variables-special Special variables The user can change the settings of `fish` by changing the values of certain variables. - A large number of variable starting with the prefixes `fish_color` and `fish_pager_color.` See Variables for changing highlighting colors for more information. - `fish_greeting`, the greeting message printed on startup. - `fish_escape_delay_ms` overrides the default timeout of 300ms (default key bindings) or 10ms (vi key bindings) after seeing an escape character before giving up on matching a key binding. See the documentation for the bind builtin command. This delay facilitates using escape as a meta key. - `BROWSER`, the user's preferred web browser. If this variable is set, fish will use the specified browser instead of the system default browser to display the fish documentation. - `CDPATH`, an array of directories in which to search for the new directory for the `cd` builtin. By default, the fish configuration defines `CDPATH` to be a universal variable with the values `.` and `~`. - `LANG`, `LC_ALL`, `LC_COLLATE`, `LC_CTYPE`, `LC_MESSAGES`, `LC_MONETARY`, `LC_NUMERIC` and `LC_TIME` set the language option for the shell and subprograms. See the section Locale variables for more information. - `fish_user_paths`, an array of directories that are prepended to `PATH`. This can be a universal variable. - `PATH`, an array of directories in which to search for commands - `umask`, the current file creation mask. The preferred way to change the umask variable is through the umask function. An attempt to set umask to an invalid value will always fail. `fish` also sends additional information to the user through the values of certain environment variables. The user cannot change the values of most of these variables. - `_`, the name of the currently running command. - `argv`, an array of arguments to the shell or function. `argv` is only defined when inside a function call, or if fish was invoked with a list of arguments, like `fish myscript.fish foo bar`. This variable can be changed by the user. - `history`, an array containing the last commands that were entered. - `HOME`, the user's home directory. This variable can be changed by the user. - `IFS`, the internal field separator that is used for word splitting with the read builtin. Setting this to the empty string will also disable line splitting in command substitution. This variable can be changed by the user. - `PWD`, the current working directory. - `status`, the exit status of the last foreground job to exit. If the job was terminated through a signal, the exit status will be 128 plus the signal number. - `USER`, the current username. This variable can be changed by the user. - `CMD_DURATION`, the runtime of the last command in milliseconds. The names of these variables are mostly derived from the csh family of shells and differ from the ones used by Bourne style shells such as bash. Variables whose name are in uppercase are exported to the commands started by fish, while those in lowercase are not exported. This rule is not enforced by fish, but it is good coding practice to use casing to distinguish between exported and unexported variables. `fish` also uses several variables internally. Such variables are prefixed with the string `__FISH` or `__fish.` These should never be used by the user. Changing their value may break fish. \subsection variables-status The status variable Whenever a process exits, an exit status is returned to the program that started it (usually the shell). This exit status is an integer number, which tells the calling application how the execution of the command went. In general, a zero exit status means that the command executed without problem, but a non-zero exit status means there was some form of problem. Fish stores the exit status of the last process in the last job to exit in the `status` variable. If `fish` encounters a problem while executing a command, the status variable may also be set to a specific value: - 1 is the generally the exit status from fish builtin commands if they were supplied with invalid arguments - 124 means that the command was not executed because none of the wildcards in the command produced any matches - 125 means that while an executable with the specified name was located, the operating system could not actually execute the command - 126 means that while a file with the specified name was located, it was not executable - 127 means that no function, builtin or command with the given name could be located If a process exits through a signal, the exit status will be 128 plus the number of the signal. \subsection variables-color Variables for changing highlighting colors The colors used by fish for syntax highlighting can be configured by changing the values of a various variables. The value of these variables can be one of the colors accepted by the set_color command. The `--bold` or `-b` switches accepted by `set_color` are also accepted. The following variables are available to change the highlighting colors in fish: - `fish_color_normal`, the default color - `fish_color_command`, the color for commands - `fish_color_quote`, the color for quoted blocks of text - `fish_color_redirection`, the color for IO redirections - `fish_color_end`, the color for process separators like ';' and '&' - `fish_color_error`, the color used to highlight potential errors - `fish_color_param`, the color for regular command parameters - `fish_color_comment`, the color used for code comments - `fish_color_match`, the color used to highlight matching parenthesis - `fish_color_search_match`, the color used to highlight history search matches - `fish_color_operator`, the color for parameter expansion operators like '*' and '~' - `fish_color_escape`, the color used to highlight character escapes like '\\n' and '\\x70' - `fish_color_cwd`, the color used for the current working directory in the default prompt - `fish_color_autosuggestion`, the color used for autosuggestions Additionally, the following variables are available to change the highlighting in the completion pager: - `fish_pager_color_prefix`, the color of the prefix string, i.e. the string that is to be completed - `fish_pager_color_completion`, the color of the completion itself - `fish_pager_color_description`, the color of the completion description - `fish_pager_color_progress`, the color of the progress bar at the bottom left corner - `fish_pager_color_secondary`, the background color of the every second completion Example: To make errors highlighted and red, use: \fish set fish_color_error red --bold \endfish \subsection variables-locale Locale variables The most common way to set the locale to use a command like 'set -x LANG en_GB.utf8', which sets the current locale to be the English language, as used in Great Britain, using the UTF-8 character set. For a list of available locales, use 'locale -a'. `LANG`, `LC_ALL`, `LC_COLLATE`, `LC_CTYPE`, `LC_MESSAGES`, `LC_MONETARY`, `LC_NUMERIC` and `LC_TIME` set the language option for the shell and subprograms. These variables work as follows: `LC_ALL` forces all the aspects of the locale to the specified value. If `LC_ALL` is set, all other locale variables will be ignored. The other `LC_` variables set the specified aspect of the locale information. `LANG` is a fallback value, it will be used if none of the `LC_` variables are specified. \section builtin-overview Builtin commands Many other shells have a large library of builtin commands. Most of these commands are also available as standalone commands, but have been implemented in the shell anyway. To avoid code duplication, and to avoid the confusion of subtly differing versions of the same command, `fish` generally only implements builtins for actions which cannot be performed by a regular command. For a list of all builtins, functions and commands shipped with fish, see the table of contents. The documentation is also available by using the `--help` switch of the command. \section editor Command line editor The `fish` editor features copy and paste, a searchable history and many editor functions that can be bound to special keyboard shortcuts. Similar to bash, fish has Emacs and Vi editing modes. The default editing mode is Emacs. You can switch to Vi mode with `fish_vi_key_bindings` and switch back with `fish_default_key_bindings`. \subsection emacs-mode Emacs mode commands - @key{Tab} completes the current token. @key{Shift, Tab} completes the current token and starts the pager's search mode. - @key{Home} or @key{Control,A} moves the cursor to the beginning of the line. - @key{End} or @key{Control,E} moves to the end of line. If the cursor is already at the end of the line, and an autosuggestion is available, @key{End} or @key{Control,E} accepts the autosuggestion. - @cursor_key{←,Left} (or @key{Control,B}) and @cursor_key{→,Right} (or @key{Control,F}) move the cursor left or right by one character. If the cursor is already at the end of the line, and an autosuggestion is available, the @cursor_key{→,Right} key and the @key{Control,F} combination accept the suggestion. - @key{Alt,←,Left} and @key{Alt,→,Right} move the cursor one word left or right, or moves forward/backward in the directory history if the command line is empty. If the cursor is already at the end of the line, and an autosuggestion is available, @key{Alt,→,Right} (or @key{Alt,F}) accepts the first word in the suggestion. - @cursor_key{↑,Up} and @cursor_key{↓,Down} search the command history for the previous/next command containing the string that was specified on the commandline before the search was started. If the commandline was empty when the search started, all commands match. See the history section for more information on history searching. - @key{Alt,↑,Up} and @key{Alt,↓,Down} search the command history for the previous/next token containing the token under the cursor before the search was started. If the commandline was not on a token when the search started, all tokens match. See the history section for more information on history searching. - @key{Delete} and @key{Backspace} removes one character forwards or backwards respectively. - @key{Control,C} deletes the entire line. - @key{Control,D} delete one character to the right of the cursor. If the command line is empty, @key{Control,D} will exit fish. - @key{Control,K} moves contents from the cursor to the end of line to the killring. - @key{Control,U} moves contents from the beginning of line to the cursor to the killring. - @key{Control,L} clears and repaints the screen. - @key{Control,W} moves the previous path component (everything up to the previous "/") to the killring. - @key{Alt,D} moves the next word to the killring. - @key{Alt,W} prints a short description of the command under the cursor. - @key{Alt,L} lists the contents of the current directory, unless the cursor is over a directory argument, in which case the contents of that directory will be listed. - @key{Alt,P} adds the string '`| less;`' to the end of the job under the cursor. The result is that the output of the command will be paged. - @key{Alt,C} capitalizes the current word. - @key{Alt,U} makes the current word uppercase. - @key{Alt,H} (or @key{F1}) shows the manual page for the current command, if one exists. - @key{Control, t} transposes the last two characters - @key{Alt,t} transposes the last two words You can change these key bindings using the bind builtin command. \subsection vi-mode Vi mode commands Vi mode allows for the use of Vi-like commands at the prompt. Initially, insert mode is active. @key{Escape} enters command mode. The commands available in command, insert and visual mode are described below. Vi mode builds on top of Emacs mode, so all keybindings mentioned there that do not contradict the ones mentioned here also work. \subsubsection vi-mode-command Command mode Command mode is also known as normal mode. - @key{h} moves the cursor left. - @key{l} moves the cursor right. - @key{i} enters insert mode at the current cursor position. - @key{v} enters visual mode at the current cursor position. - @key{a} enters insert mode after the current cursor position. - @key{Shift,A} enters insert mode at the end of the line. - @key{0} (zero) moves the cursor to beginning of line (remaining in command mode). - @key{d}@key{d} deletes the current line and moves it to the killring. - @key{Shift,D} deletes text after the current cursor position and moves it to the killring. - @key{p} pastes text from the killring. - @key{u} undoes the most recent action. - @key{[} and @key{]} search the command history for the previous/next token containing the token under the cursor before the search was started. See the history section for more information on history searching. - @key{Control,C} deletes the entire line. \subsubsection vi-mode-insert Insert mode - @key{Tab} completes the current token. - @key{Escape} or @key{Control,C} enters command mode. - @cursor_key{↑,Up} and @cursor_key{↓,Down} search the command history. See the history section for more information on history searching. - @key{Control,W} moves the previous word to the killring. - @key{Control,U} moves contents from the beginning of line to the cursor to the killring. - @key{Control,x} moves the cursor to the end of the line. If an autosuggestion is available, it will be accepted completely. \subsubsection vi-mode-visual Visual mode - @cursor_key{←,Left} and @cursor_key{→,Right} extend the selection backward/forward by one character. - @key{b} and @key{w} extend the selection backward/forward by one word. - @key{d} and @key{x} move the selection to the killring and enter command mode. - @key{Escape} and @key{Control,C} enter command mode. \subsection killring Copy and paste (Kill Ring) `fish` uses an Emacs style kill ring for copy and paste functionality. Use @key{Control,K} to cut from the current cursor position to the end of the line. The string that is cut (a.k.a. killed) is inserted into a linked list of kills, called the kill ring. To paste the latest value from the kill ring use @key{Control,Y}. After pasting, use @key{Alt,Y} to rotate to the previous kill. If the environment variable `DISPLAY` is set and the `xsel` program is installed, `fish` will try to connect to the X Windows server specified by this variable, and use the clipboard on the X server for copying and pasting. \subsection history-search Searchable history After a command has been entered, it is inserted at the end of a history list. Any duplicate history items are automatically removed. By pressing the up and down keys, the user can search forwards and backwards in the history. If the current command line is not empty when starting a history search, only the commands containing the string entered into the command line are shown. By pressing @key{Alt,↑,Up} and @key{Alt,↓,Down}, a history search is also performed, but instead of searching for a complete commandline, each commandline is broken into separate elements just like it would be before execution, and the history is searched for an element matching that under the cursor. History searches can be aborted by pressing the escape key. Prefixing the commandline with a space will prevent the entire line from being stored in the history. The history is stored in the file `~/.config/fish/fish_history`. Examples: To search for previous entries containing the word 'make', type `make` in the console and press the up key. If the commandline reads `cd m`, place the cursor over the `m` character and press @key{Alt,↑,Up} to search for previously typed words containing 'm'. \subsection multiline Multiline editing The fish commandline editor can be used to work on commands that are several lines long. There are three ways to make a command span more than a single line: - Pressing the @key{Enter} key while a block of commands is unclosed, such as when one or more block commands such as `for`, `begin` or `if` do not have a corresponding `end` command. - Pressing @key{Alt,Enter} instead of pressing the @key{Enter} key. - By inserting a backslash (`\`) character before pressing the @key{Enter} key, escaping the newline. The fish commandline editor works exactly the same in single line mode and in multiline mode. To move between lines use the left and right arrow keys and other such keyboard shortcuts. \section job-control Running multiple programs Normally when `fish` starts a program, this program will be put in the foreground, meaning it will take control of the terminal and `fish` will be stopped until the program finishes. Sometimes this is not desirable. For example, you may wish to start an application with a graphical user interface from the terminal, and then be able to continue using the shell. In such cases, there are several ways in which the user can change fish's behavior. -# By ending a command with the `&` (ampersand) symbol, the user tells `fish` to put the specified command into the background. A background process will be run simultaneous with `fish`. `fish` will retain control of the terminal, so the program will not be able to read from the keyboard. -# By pressing @key{Control,Z}, the user stops a currently running foreground program and returns control to `fish`. Some programs do not support this feature, or remap it to another key. GNU Emacs uses @key{Control,X} @key{z} to stop running. -# By using the `fg` and `bg` builtin commands, the user can send any currently running job into the foreground or background. Note that functions cannot be started in the background. Functions that are stopped and then restarted in the background using the `bg` command will not execute correctly. \section initialization Initialization files On startup, Fish evaluates a number of configuration files, which can be used to control the behavior of the shell. Configuration files are evaluated in the following order: - Configuration shipped with fish, which should not be edited, usually `/usr/share/fish/config.fish`. - System-wide configuration files, where administrators can include initialization that should be run for all users on the system - similar to `/etc/profile` for POSIX-style shells - usually `/etc/fish/config.fish`; - Configuration snippets in files ending in `.fish`, in the directories: - `~/.config/fish/conf.d/` - `/etc/fish/conf.d` - `/usr/share/fish/vendor_conf.d` If there are multiple files with the same name in these directories, only the first will be executed. - User initialization, usually in `~/.config/fish/config.fish` (controlled by the `XDG_CONFIG_HOME` environment variable). These paths are controlled by parameters set at build, install, or run time, and may vary from the defaults listed above. This wide search may be confusing. If you are unsure, use `~/.config/fish/config.fish`. These files are all executed on the startup of every shell. If you want to run a command only on starting an interactive shell, use the exit status of the command `status --is-interactive` to determine if the shell is interactive. If you want to run a command only when using a login shell, use `status --is-login` instead. This will speed up the starting of non-interactive or non-login shells. If you are developing another program, you may wish to install configuration which is run for all users of the fish shell on a system. This is discouraged; if not carefully written, they may have side-effects or slow the startup of the shell. Additionally, users of other shells will not benefit from the Fish-specific configuration. However, if they are absolutely required, you may install them to the "vendor" configuration directory. As this path may vary from system to system, the `pkgconfig` framework should be used to discover this path with the output of `pkg-config --variable confdir fish`. Examples: If you want to add the directory `~/linux/bin` to your PATH variable when using a login shell, add the following to your `~/.config/fish/config.fish` file: \fish if status --is-login set PATH $PATH ~/linux/bin end \endfish If you want to run a set of commands when `fish` exits, use an event handler that is triggered by the exit of the shell: \fish function on_exit --on-process %self echo fish is now exiting end \endfish \section other Other features \subsection color Syntax highlighting `fish` interprets the command line as it is typed and uses syntax highlighting to provide feedback to the user. The most important feedback is the detection of potential errors. By default, errors are marked red. Detected errors include: - Non existing commands. - Reading from or appending to a non existing file. - Incorrect use of output redirects - Mismatched parenthesis When the cursor is over a parenthesis or a quote, `fish` also highlights its matching quote or parenthesis. To customize the syntax highlighting, you can set the environment variables listed in the Variables for changing highlighting colors section. \subsection title Programmable title When using most virtual terminals, it is possible to set the message displayed in the titlebar of the terminal window. This can be done automatically in fish by defining the `fish_title` function. The `fish_title` function is executed before and after a new command is executed or put into the foreground and the output is used as a titlebar message. The $_ environment variable will always contain the name of the job to be put into the foreground (Or 'fish' if control is returning to the shell) when the `fish_prompt` function is called. The first argument to fish_title will contain the most recently executed foreground command as a string, starting with fish 2.2. Examples: The default `fish` title is \fish function fish_title echo $_ ' ' pwd end \endfish To show the last command in the title: \fish function fish_title echo $argv[1] end \endfish \subsection greeting Configurable greeting If a function named `fish_greeting` exists, it will be run when entering interactive mode. Otherwise, if an environment variable named `fish_greeting` exists, it will be printed. \subsection event Event handlers When defining a new function in fish, it is possible to make it into an event handler, i.e. a function that is automatically run when a specific event takes place. Events that can trigger a handler currently are: - When a signal is delivered - When a process or job exits - When the value of a variable is updated - When the prompt is about to be shown - When a command lookup fails Example: To specify a signal handler for the WINCH signal, write: \fish function --on-signal WINCH my_signal_handler echo Got WINCH signal! end \endfish Please note that event handlers only become active when a function is loaded, which means you might need to otherwise source or execute a function instead of relying on autoloading. One approach is to put it into your initialization file. For more information on how to define new event handlers, see the documentation for the function command. \subsection debugging Debugging fish scripts Fish includes a built in debugger. The debugger allows you to stop execution of a script at an arbitrary point and launch a prompt. This prompt can then be used to check or change the value of any variables or perform any shellscript command. To resume normal execution of the script, simply exit the prompt. To start the debugger, simply call the builtin command `breakpoint`. The default action of the TRAP signal is to call this builtin, so a running script can be debugged by sending it the TRAP signal. Once in the debugger, it is easy to insert new breakpoints by using the funced function to edit the definition of a function. \section issues Common issues with fish If you install fish in your home directory, fish will not work correctly for any other user than yourself. This is because fish needs its initialization files to function properly. To solve this problem, either copy the initialization files to each fish users home directory, or install them in `/etc`. \section more-help Further help and development If you have a question not answered by this documentation, there are several avenues for help: -# The official mailing list at fish-users@lists.sourceforge.net -# The Internet Relay Chat channel, \#fish on `irc.oftc.net` -# The project GitHub page If you have an improvement for fish, you can submit it via the mailing list or the GitHub page. \htmlonly[block]
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