short and sweet LISP editing
Table of Contents
This package reimagines Paredit - a popular method to navigate and edit LISP code in Emacs.
The killer-feature are the short bindings:
Most of more than 100 interactive commands that
lispy provides are
bound to a-z and A-Z in
lispy-mode. You can see the full command reference with many
The price for these short bindings is that they are only active when:
The advantage of short bindings is that you are more likely to use them. As you use them more, you learn how to combine them, increasing your editing efficiency.
To further facilitate building complex commands from smaller commands,
digit-argument to 0-9. For
example, you can mark the third element of the list with
3m. You can then mark third through fifth element (three
total) with 2> or >>. You can then move the
selection to the last three elements of the list with 99j.
If you are currently using Paredit, note that
paredit-mode can actually coexist with very few conflicts, although
there would be some redundancy.
The key binding method is influenced by vi, although this isn't modal editing per se.
Here's a quote from Wikipedia on how vi works, in case you don't know:
vi is a modal editor: it operates in either insert mode (where typed text becomes part of the document) or normal mode (where keystrokes are interpreted as commands that control the edit session). For example, typing i while in normal mode switches the editor to insert mode, but typing i again at this point places an "i" character in the document. From insert mode, pressing ESC switches the editor back to normal mode.
Here's an illustration of Emacs, vi and lispy bindings for inserting a char and calling a command:
|vi in insert mode||j||impossible|
|vi in normal mode||impossible||j|
Of course it's not magic, lispy needs to have normal/insert mode to perform both functions with j. The difference from vi is that the mode is explicit instead of implicit - it's determined by the point position or the region state:
So people who generally like Emacs bindings (like me) can have the cake and eat it too (no dedicated insert mode + shorter key bindings). While people who like vi can still get an experience that's reasonably close to vi for LISP editing (since vi's line-based approach isn't very appropriate for LISP anyway).
But if you ask:
What if I want to insert when the point is before/after paren or the region is active?
The answer is that because of the LISP syntax you don't want to write this:
j(progn (forward-char 1))k
Also, Emacs does nothing special by default when the region is active and you press a normal key, so new commands can be called in that situation.
Basic navigation by-list and by-region:
Paredit transformations, callable by plain letters:
IDE-like features for Elisp, Clojure, Scheme, Common Lisp, Hy, Python and Julia:
edebug, while storing current function's arguments
Some pictures here.
condexpression to equivalent
ifexpressions to an equivalent
Most functions are cataloged and described at http://abo-abo.github.io/lispy/.
It's easiest/recommended to install from MELPA.
Here's a minimal MELPA configuration for your
(package-initialize) (add-to-list 'package-archives '("melpa" . "http://melpa.org/packages/"))
Afterwards, M-x package-install RET lispy RET (you might want to M-x package-refresh-contents RET beforehand if you haven't done so recently).
el-get also features a lispy recipe. Use M-x el-get-install RET lispy RET to install.
Enable lispy automatically for certain modes
After installing, you can call M-x lispy-mode for any
buffer with a LISP dialect source. To have
automatically, use something like this:
(add-hook 'emacs-lisp-mode-hook (lambda () (lispy-mode 1)))
Enable lispy for
Although I prefer to eval things in
eval-expression is handy. Here's how to use lispy
in the minibuffer during
(defun conditionally-enable-lispy () (when (eq this-command 'eval-expression) (lispy-mode 1))) (add-hook 'minibuffer-setup-hook 'conditionally-enable-lispy)
If you want to replace some of the
lispy-mode's bindings you can do
it like this:
(eval-after-load "lispy" `(progn ;; replace a global binding with own function (define-key lispy-mode-map (kbd "C-e") 'my-custom-eol) ;; replace a global binding with major-mode's default (define-key lispy-mode-map (kbd "C-j") nil) ;; replace a local binding (lispy-define-key lispy-mode-map "s" 'lispy-down)))
lispy-compat variable to enable compatibility with modes that could otherwise conflict. These currently include:
The default setting only enables compatibility with
The plain keys will call commands when:
When one of the first two conditions is true, I say that the point is
special. When the point is special, it's very clear to which sexp the
list-manipulating command will be applied to, what the result be and
where the point should end up afterwards. You can enhance this effect
show-paren-mode or similar.
Here's an illustration to this effect, with
represents the point):
You can use plain Emacs navigation commands to get into special, or you can use some of the dedicated commands:
These are the few lispy commands that don't care whether the point is special or not. Other such bindings are DEL, C-d, C-k.
Special is useful for manipulating/navigating lists. If you want to manipulate symbols, use region selection instead.
When special, the digit keys call
digit-argument which is very
useful since most lispy commands accept a numeric argument.
For instance, 3c is equivalent to ccc (clone sexp 3 times), and
4j is equivalent to jjjj (move point 4 sexps down).
Some useful applications are 9l and 9h - they exit list forwards
and backwards respectively at most 9 times which makes them
effectively equivalent to
you can move to the last sexp of the file with 999j.
To get out of the special position, you can use any of the good-old navigational commands such as C-f or C-n. Additionally SPC will break out of special to get around the situation when you have the point between the open parens like this
and want to start inserting; SPC will change the code to this:
Here's a list of commands for inserting pairs:
A lot of Lispy commands come in pairs - one reverses the other:
||C-d or DEL|
These commands handle whitespace in addition to inserting the expected thing.
Most special commands will leave the point special after they're
done. This allows to chain them as well as apply them
continuously by holding the key. Some useful hold-able keys are
Not so useful, but fun is /: start it from
|( position and hold
until all your Lisp code is turned into Python :).
lispy-ace-paren jumps to a "(" character within current
top-level form (e.g.
defun). It's much faster than typing in the
avy binding + selecting "(", and there's less candidates,
since they're limited to the current top-level form.
lispy-ace-symbol will let you select which symbol to
mark within current form. This can be followed up with e.g. eval,
describe, follow, raise etc. Or you can simply m to
deactivate the mark and edit from there.
lispy-ace-subword is a niche command for a neat combo. Start with:
Type c, -, b and C-d to get:
(buffer-substring-no-properties (region-beginning) (region-|))
end to finish the statement.
Sometimes the expression that you want to operate on isn't bounded by parens. In that case you can mark it with a region and operate on that.
While in special:
While not in special:
The arrow keys j/k will move the region up/down within the current list. The actual code will not be changed.
Use d -
lispy-different to switch between different sides
of the region. The side is important since the grow/shrink operations
apply to current side of the region.
Use a combination of:
lispy-slurp- extend by one sexp from the current side. Use digit argument to extend by several sexps.
lispy-barf- shrink by one sexp from the current side. Use digit argument to shrink by several sexps.
The other two arrow keys will mark the parent list of the current region:
lispy-left- mark the parent list with the point on the left
lispy-right- mark the parent list with the point on the right
To do the reverse of the previous operation, i.e. to mark the first
child of marked list, use i -
lispy-mark-list- deactivate region
lispy-clone- clone region and keep it active
lispy-move-down- move region one sexp down
lispy-move-up- move region one sexp up
lispy-undo- deactivate region and undo
lispy-teleport- move region inside the sexp you select with
lispy-convolute- exchange the order of application of two sexps that contain region
lispy-new-copy- copy region as kill without deactivating the mark
lispy-paste- replace region with current kill
These features are specific to the Lisp dialect used. Currently Elisp
and Clojure (via
cider) are supported. There's also basic
evaluation support for:
Bound to C-1. Show the doc for the current function inline.
C-h f is fine, but the extra buffer, and having to navigate to a symbol is tiresome. C-1 toggles on/off the inline doc for current function. No extra buffer necessary:
Here's how it looks for Clojure:
Bound to C-2. Show arguments for current function inline.
eldoc-mode is cool, but it shows you arguments over there and
you're writing over here!. No problem, C-2 fixes that:
As you see, normal, &optional and &rest arguments have each a different face. Here's how it looks for Clojure:
Bound to g.
Use completion to select a symbol to jump to from all top-level symbols in the in current directory.
Works out of the box for Elisp, Scheme and Common Lisp. clojure-semantic is required for Clojure.
There's a feature similar to
ipython-notebook. Evaluating an Emacs
outline will evaluate all of the outline's code and echo the result of
the last expression. When an outline ends with a colon (
result will instead be inserted into the buffer. If the evaluation
result changes for whatever reason, it will be replaced after each
Python, Clojure, and Julia currently have a slightly better notebook
support, pressing e on the parent outline will evaluate all
the children outlines sequentially. This allows to arrange scripts
hierarchically, with relatively few top-level outlines and relatively
many total outlines. Each outline's output can be examined by adding a
: to the title of the outline.
The following example shows a buffer before and after pressing e.
There is one top-level outline, with one level-2 child, which in turn
has a four level-3 children. Three of these children end in
their output will be updated after the eval.