The use-package
macro allows you to isolate package configuration in your
.emacs
file in a way that is both performance-oriented and, well, tidy. I
created it because I have over 80 packages that I use in Emacs, and things
were getting difficult to manage. Yet with this utility my total load time is
around 2 seconds, with no loss of functionality!
NOTE: use-package
is not a package manager! Although use-package
does have the useful capability to interface with package managers (see
below), its primary purpose is for the configuration
and loading of packages.
- Installing use-package
- Getting started
- Key-binding
- Modes and interpreters
- Magic handlers
- Hooks
- Package customization
- Notes about lazy loading
- Information about package loads
- Conditional loading
- Byte compiling your .emacs
- Extending the load-path
- Catching errors during use-package expansion
- Diminishing and delighting minor modes
- Package installation
- Gathering Statistics
- Keyword Extensions
- Some timing results
Either clone from this GitHub repository or install from GNU ELPA (recommended).
Here is the simplest use-package
declaration:
;; This is only needed once, near the top of the file
(eval-when-compile
;; Following line is not needed if use-package.el is in ~/.emacs.d
(add-to-list 'load-path "<path where use-package is installed>")
(require 'use-package))
(use-package foo)
This loads in the package foo
, but only if foo
is available on your
system. If not, a warning is logged to the *Messages*
buffer.
Use the :init
keyword to execute code before a package is loaded. It
accepts one or more forms, up to the next keyword:
(use-package foo
:init
(setq foo-variable t))
Similarly, :config
can be used to execute code after a package is loaded.
In cases where loading is done lazily (see more about autoloading below), this
execution is deferred until after the autoload occurs:
(use-package foo
:init
(setq foo-variable t)
:config
(foo-mode 1))
As you might expect, you can use :init
and :config
together:
(use-package color-moccur
:commands (isearch-moccur isearch-all)
:bind (("M-s O" . moccur)
:map isearch-mode-map
("M-o" . isearch-moccur)
("M-O" . isearch-moccur-all))
:init
(setq isearch-lazy-highlight t)
:config
(use-package moccur-edit))
In this case, I want to autoload the commands isearch-moccur
and
isearch-all
from color-moccur.el
, and bind keys both at the global level
and within the isearch-mode-map
(see next section). When the package is
actually loaded (by using one of these commands), moccur-edit
is also
loaded, to allow editing of the moccur
buffer.
If you autoload non-interactive function, please use :autoload
.
(use-package org-crypt
:autoload org-crypt-use-before-save-magic)
Another common thing to do when loading a module is to bind a key to primary commands within that module:
(use-package ace-jump-mode
:bind ("C-." . ace-jump-mode))
This does two things: first, it creates an autoload for the ace-jump-mode
command and defers loading of ace-jump-mode
until you actually use it.
Second, it binds the key C-.
to that command. After loading, you can use
M-x describe-personal-keybindings
to see all such keybindings you've set
throughout your .emacs
file.
A more literal way to do the exact same thing is:
(use-package ace-jump-mode
:commands ace-jump-mode
:init
(bind-key "C-." 'ace-jump-mode))
When you use the :commands
keyword, it creates autoloads for those commands
and defers loading of the module until they are used. Since the :init
form
is always run -- even if ace-jump-mode
might not be on your system --
remember to restrict :init
code to only what would succeed either way.
The :bind
keyword takes either a cons or a list of conses:
(use-package hi-lock
:bind (("M-o l" . highlight-lines-matching-regexp)
("M-o r" . highlight-regexp)
("M-o w" . highlight-phrase)))
Alternatively, the command name may be replaced with a cons (desc . command)
,
where desc
is a string describing command
, which is the name of a command
to bind to:
(use-package avy
:bind ("C-:" ("Jump to char" . avy-goto-char)
"M-g f" ("Jump to line" . avy-goto-line)))
These descriptions can be used by other code that deals with key bindings. For example, the GNU ELPA package which-key displays them when showing key bindings, instead of the plain command names.
The :commands
keyword takes either a symbol or a list of symbols.
NOTE: inside strings, special keys like tab
or F1
-Fn
have to be written inside angle brackets, e.g. "C-<up>"
.
Standalone special keys (and some combinations) can be written in square brackets, e.g. [tab]
instead of "<tab>"
. The syntax for the keybindings is similar to
the "kbd" syntax: see https://www.gnu.org/software/emacs/manual/html_node/emacs/Init-Rebinding.html
for more information.
Examples:
(use-package helm
:bind (("M-x" . helm-M-x)
("M-<f5>" . helm-find-files)
([f10] . helm-buffers-list)
([S-f10] . helm-recentf)))
Furthermore, remapping commands
with :bind
and bind-key
works as expected, because when the
binding is a vector, it is passed straight to define-key
. So the
following example will rebind M-q
(originally fill-paragraph
) to
unfill-toggle
:
(use-package unfill
:bind ([remap fill-paragraph] . unfill-toggle))
Normally :bind
expects that commands are functions that will be autoloaded
from the given package. However, this does not work if one of those commands
is actually a keymap, since keymaps are not functions, and cannot be
autoloaded using Emacs' autoload
mechanism.
To handle this case, use-package
offers a special, limited variant of
:bind
called :bind-keymap
. The only difference is that the "commands"
bound to by :bind-keymap
must be keymaps defined in the package, rather than
command functions. This is handled behind the scenes by generating custom code
that loads the package containing the keymap, and then re-executes your
keypress after the first load, to reinterpret that keypress as a prefix key.
For example:
(use-package projectile
:bind-keymap
("C-c p" . projectile-command-map))
Slightly different from binding a key to a keymap, is binding a key within a
local keymap that only exists after the package is loaded. use-package
supports this with a :map
modifier, taking the local keymap to bind to:
(use-package helm
:bind (:map helm-command-map
("C-c h" . helm-execute-persistent-action)))
The effect of this statement is to wait until helm
has loaded, and then to
bind the key C-c h
to helm-execute-persistent-action
within Helm's local
keymap, helm-command-map
.
Multiple uses of :map
may be specified. Any binding occurring before the
first use of :map
are applied to the global keymap:
(use-package term
:bind (("C-c t" . term)
:map term-mode-map
("M-p" . term-send-up)
("M-n" . term-send-down)
:map term-raw-map
("M-o" . other-window)
("M-p" . term-send-up)
("M-n" . term-send-down)))
A special case of binding within a local keymap is when that keymap is
used by repeat-mode
. These keymaps are usually defined specifically
for this. Using the :repeat-map
keyword, and passing it a name for
the map it defines, will bind all following keys inside that map, and
(by default) set the repeat-map
property of each bound command to
that map.
This creates a keymap called git-gutter+-repeat-map
, makes four
bindings in it as above, then sets the repeat-map
property of each
bound command (git-gutter+-next-hunk
git-gutter+-previous-hunk
,
git-gutter+-stage-hunks
and git-gutter+-revert-hunk
) to that
keymap.
(use-package git-gutter+
:bind
(:repeat-map git-gutter+-repeat-map
("n" . git-gutter+-next-hunk)
("p" . git-gutter+-previous-hunk)
("s" . git-gutter+-stage-hunks)
("r" . git-gutter+-revert-hunk)))
Specifying :exit
inside the scope of :repeat-map
will prevent the
repeat-map
property being set, so that the command can be used from
within the repeat map, but after it using it the repeat map will no
longer be available. This is useful for commands often used at the end
of a series of repeated commands:
(use-package git-gutter+
:bind
(:repeat-map my/git-gutter+-repeat-map
("n" . git-gutter+-next-hunk)
("p" . git-gutter+-previous-hunk)
("s" . git-gutter+-stage-hunks)
("r" . git-gutter+-revert-hunk)
:exit
("c" . magit-commit-create)
("C" . magit-commit)
("b" . magit-blame)))
Specifying :continue
forces setting the repeat-map
property
(just like not specifying :exit
), so these two snippets are
equivalent:
(use-package git-gutter+
:bind
(:repeat-map my/git-gutter+-repeat-map
("n" . git-gutter+-next-hunk)
("p" . git-gutter+-previous-hunk)
("s" . git-gutter+-stage-hunks)
("r" . git-gutter+-revert-hunk)
:exit
("c" . magit-commit-create)
("C" . magit-commit)
("b" . magit-blame)))
(use-package git-gutter+
:bind
(:repeat-map my/git-gutter+-repeat-map
:exit
("c" . magit-commit-create)
("C" . magit-commit)
("b" . magit-blame)
:continue
("n" . git-gutter+-next-hunk)
("p" . git-gutter+-previous-hunk)
("s" . git-gutter+-stage-hunks)
("r" . git-gutter+-revert-hunk)))
Similar to :bind
, you can use :mode
and :interpreter
to establish a
deferred binding within the auto-mode-alist
and interpreter-mode-alist
variables. The specifier to either keyword can be a cons cell, a list of cons
cells, or a string or regexp:
(use-package ruby-mode
:mode "\\.rb\\'"
:interpreter "ruby")
;; The package is "python" but the mode is "python-mode":
(use-package python
:mode ("\\.py\\'" . python-mode)
:interpreter ("python" . python-mode))
If you aren't using :commands
, :bind
, :bind*
, :bind-keymap
,
:bind-keymap*
, :mode
, :interpreter
, or :hook
(all of which imply :defer
; see
the docstring for use-package
for a brief description of each), you can
still defer loading with the :defer
keyword:
(use-package ace-jump-mode
:defer t
:init
(autoload 'ace-jump-mode "ace-jump-mode" nil t)
(bind-key "C-." 'ace-jump-mode))
This does exactly the same thing as the following:
(use-package ace-jump-mode
:bind ("C-." . ace-jump-mode))
Similar to :mode
and :interpreter
, you can also use :magic
and
:magic-fallback
to cause certain function to be run if the beginning of a
file matches a given regular expression. The difference between the two is
that :magic-fallback
has a lower priority than :mode
. For example:
(use-package pdf-tools
:load-path "site-lisp/pdf-tools/lisp"
:magic ("%PDF" . pdf-view-mode)
:config
(pdf-tools-install :no-query))
This registers an autoloaded command for pdf-view-mode
, defers loading of
pdf-tools
, and runs pdf-view-mode
if the beginning of a buffer matches the
string "%PDF"
.
The :hook
keyword allows adding functions onto package hooks. Thus,
all of the following are equivalent:
(use-package company
:hook prog-mode)
(use-package company
:hook (prog-mode . company-mode))
(use-package company
:commands company-mode
:init
(add-hook 'prog-mode-hook #'company-mode))
And likewise, when multiple hooks should be applied, the following are also equivalent:
(use-package company
:hook (prog-mode text-mode))
(use-package company
:hook ((prog-mode text-mode) . company-mode))
(use-package company
:hook ((prog-mode . company-mode)
(text-mode . company-mode)))
(use-package company
:commands company-mode
:init
(add-hook 'prog-mode-hook #'company-mode)
(add-hook 'text-mode-hook #'company-mode))
When using :hook
omit the "-hook" suffix if you specify the hook
explicitly, as this is appended by default. For example the following
code will not work as it attempts to add to the prog-mode-hook-hook
which does not exist:
;; DOES NOT WORK
(use-package ace-jump-mode
:hook (prog-mode-hook . ace-jump-mode))
If you do not like this behaviour, set use-package-hook-name-suffix
to nil. By default the value of this variable is "-hook".
The use of :hook
, as with :bind
, :mode
, :interpreter
, etc., causes the
functions being hooked to implicitly be read as :commands
(meaning they will
establish interactive autoload
definitions for that module, if not already
defined as functions), and so :defer t
is also implied by :hook
.
The :custom
keyword allows customization of package custom variables.
(use-package comint
:custom
(comint-buffer-maximum-size 20000 "Increase comint buffer size.")
(comint-prompt-read-only t "Make the prompt read only."))
The documentation string is not mandatory.
NOTE: these are only for people who wish to keep customizations with their
accompanying use-package declarations. Functionally, the only benefit over
using setq
in a :config
block is that customizations might execute code
when values are assigned.
NOTE: The customized values are not saved in the Emacs custom-file
.
Thus you should either use the :custom
option or you should use M-x customize-option
which will save customized values in the Emacs custom-file
.
Do not use both.
The :custom-face
keyword allows customization of package custom faces.
(use-package eruby-mode
:custom-face
(eruby-standard-face ((t (:slant italic)))))
(use-package example
:custom-face
(example-1-face ((t (:foreground "LightPink"))))
(example-2-face ((t (:foreground "LightGreen"))) face-defspec-spec))
(use-package zenburn-theme
:preface
(setq my/zenburn-colors-alist
'((fg . "#DCDCCC") (bg . "#1C1C1C") (cyan . "#93E0E3")))
:custom-face
(region ((t (:background ,(alist-get my/zenburn-colors-alist 'cyan)))))
:config
(load-theme 'zenburn t))
The keywords :commands
, et al, provide "triggers" that cause a package to be
loaded when certain events occur. However, if use-package
cannot determine
that any trigger has been declared, it will load the package immediately (when
Emacs is starting up) unless :defer t
is given. The presence of triggers can
be overridden using :demand t
to force immediately loading anyway. For
example, :hook
represents a trigger that fires when the specified hook is
run.
In almost all cases you don't need to manually specify :defer t
, because
this is implied whenever :bind
or :mode
or :interpreter
are used.
Typically, you only need to specify :defer
if you know for a fact that some
other package will do something to cause your package to load at the
appropriate time, and thus you would like to defer loading even though
use-package
has not created any autoloads for you.
You can override package deferral with the :demand
keyword. Thus, even if
you use :bind
, adding :demand
will force loading to occur immediately and
not establish an autoload for the bound key.
When a package is loaded, and if you have use-package-verbose
set to t
, or
if the package takes longer than 0.1s to load, you will see a message to
indicate this loading activity in the *Messages*
buffer. The same will
happen for configuration, or :config
blocks that take longer than 0.1s to
execute. In general, you should keep :init
forms as simple and quick as
possible, and put as much as you can get away with into the :config
block.
This way, deferred loading can help your Emacs to start as quickly as
possible.
Additionally, if an error occurs while initializing or configuring a package,
this will not stop your Emacs from loading. Rather, the error will be
captured by use-package
, and reported to a special *Warnings*
popup
buffer, so that you can debug the situation in an otherwise functional Emacs.
You can use the :if
keyword to predicate the loading and initialization of
modules.
For example, I only want edit-server
running for my main,
graphical Emacs, not for other Emacsen I may start at the command line:
(use-package edit-server
:if window-system
:init
(add-hook 'after-init-hook 'server-start t)
(add-hook 'after-init-hook 'edit-server-start t))
In another example, we can load things conditional on the operating system:
(use-package exec-path-from-shell
:if (memq window-system '(mac ns))
:ensure t
:config
(exec-path-from-shell-initialize))
The :disabled
keyword can turn off a module you're having difficulties with,
or stop loading something you're not using at the present time:
(use-package ess-site
:disabled
:commands R)
When byte-compiling your .emacs
file, disabled declarations are omitted
from the output entirely, to accelerate startup times.
NOTE: :when
is provided as an alias for :if
, and :unless foo
means
the same thing as :if (not foo)
.
If you need to conditionalize a use-package form so that the condition occurs
before even the :preface
is executed, simply use when
around the
use-package form itself. For example, the following will also stop
:ensure
from happening on Mac systems:
(when (memq window-system '(mac ns))
(use-package exec-path-from-shell
:ensure t
:config
(exec-path-from-shell-initialize)))
Sometimes it only makes sense to configure a package after another has been
loaded, because certain variables or functions are not in scope until that
time. This can achieved using an :after
keyword that allows a fairly rich
description of the exact conditions when loading should occur. Here is an
example:
(use-package hydra
:load-path "site-lisp/hydra")
(use-package ivy
:load-path "site-lisp/swiper")
(use-package ivy-hydra
:after (ivy hydra))
In this case, because all of these packages are demand-loaded in the order
they occur, the use of :after
is not strictly necessary. By using it,
however, the above code becomes order-independent, without an implicit
depedence on the nature of your init file.
By default, :after (foo bar)
is the same as :after (:all foo bar)
, meaning
that loading of the given package will not happen until both foo
and bar
have been loaded. Here are some of the other possibilities:
:after (foo bar)
:after (:all foo bar)
:after (:any foo bar)
:after (:all (:any foo bar) (:any baz quux))
:after (:any (:all foo bar) (:all baz quux))
When you nest selectors, such as (:any (:all foo bar) (:all baz quux))
, it
means that the package will be loaded when either both foo
and bar
have
been loaded, or both baz
and quux
have been loaded.
NOTE: pay attention if you set use-package-always-defer
to t, and also use
the :after
keyword, as you will need to specify how the declared package is
to be loaded: e.g., by some :bind
. If you're not using one of the mechanisms
that registers autoloads, such as :bind
or :hook
, and your package manager
does not provide autoloads, it's possible that without adding :demand t
to
those declarations, your package will never be loaded.
While the :after
keyword delays loading until the dependencies are loaded,
the somewhat simpler :requires
keyword simply never loads the package if the
dependencies are not available at the time the use-package
declaration is
encountered. By "available" in this context it means that foo
is available
if (featurep 'foo)
evaluates to a non-nil value. For example:
(use-package abbrev
:requires foo)
This is the same as:
(use-package abbrev
:if (featurep 'foo))
As a convenience, a list of such packages may be specified:
(use-package abbrev
:requires (foo bar baz))
For more complex logic, such as that supported by :after
, simply use :if
and the appropriate Lisp expression.
Another feature of use-package
is that it always loads every file that it
can when .emacs
is being byte-compiled. This helps to silence spurious
warnings about unknown variables and functions.
However, there are times when this is just not enough. For those times, use
the :defines
and :functions
keywords to introduce dummy variable and
function declarations solely for the sake of the byte-compiler:
(use-package texinfo
:defines texinfo-section-list
:commands texinfo-mode
:init
(add-to-list 'auto-mode-alist '("\\.texi$" . texinfo-mode)))
If you need to silence a missing function warning, you can use :functions
:
(use-package ruby-mode
:mode "\\.rb\\'"
:interpreter "ruby"
:functions inf-ruby-keys
:config
(defun my-ruby-mode-hook ()
(require 'inf-ruby)
(inf-ruby-keys))
(add-hook 'ruby-mode-hook 'my-ruby-mode-hook))
Normally, use-package
will load each package at compile time before
compiling the configuration, to ensure that any necessary symbols are in scope
to satisfy the byte-compiler. At times this can cause problems, since a
package may have special loading requirements, and all that you want to use
use-package
for is to add a configuration to the eval-after-load
hook. In
such cases, use the :no-require
keyword:
(use-package foo
:no-require t
:config
(message "This is evaluated when `foo' is loaded"))
If your package needs a directory added to the load-path
in order to load,
use :load-path
. This takes a symbol, a function, a string or a list of
strings. If the path is relative, it is expanded within
user-emacs-directory
:
(use-package ess-site
:load-path "site-lisp/ess/lisp/"
:commands R)
NOTE: when using a symbol or a function to provide a dynamically generated
list of paths, you must inform the byte-compiler of this definition so the
value is available at byte-compilation time. This is done by using the
special form eval-and-compile
(as opposed to eval-when-compile
). Further,
this value is fixed at whatever was determined during compilation, to avoid
looking up the same information again on each startup:
(eval-and-compile
(defun ess-site-load-path ()
(shell-command "find ~ -path ess/lisp")))
(use-package ess-site
:load-path (lambda () (list (ess-site-load-path)))
:commands R)
By default, if use-package-expand-minimally
is nil (the default),
use-package will attempts to catch and report errors that occur during
expansion of use-package declarations in your init file. Setting
use-package-expand-minimally
to t completely disables this checking.
This behavior may be overridden locally using the :catch
keyword. If t
or
nil
, it enables or disables catching errors at load time. It can also be a
function taking two arguments: the keyword being processed at the time the
error was encountered, and the error object (as generated by
condition-case
). For example:
(use-package example
;; Note that errors are never trapped in the preface, since doing so would
;; hide definitions from the byte-compiler.
:preface (message "I'm here at byte-compile and load time.")
:init (message "I'm always here at startup")
:config
(message "I'm always here after the package is loaded")
(error "oops")
;; Don't try to (require 'example), this is just an example!
:no-require t
:catch (lambda (keyword err)
(message (error-message-string err))))
Evaluating the above form will print these messages:
I’m here at byte-compile and load time.
I’m always here at startup
Configuring package example...
I’m always here after the package is loaded
oops
use-package
also provides built-in support for the diminish and
delight utilities -- if you have them installed. Their purpose is to
remove or change minor mode strings in your mode-line.
diminish is invoked with
the :diminish
keyword, which is passed either a minor mode symbol, a
cons of the symbol and its replacement string, or just a replacement
string, in which case the minor mode symbol is guessed to be the
package name with "-mode" appended at the end:
(use-package abbrev
:diminish abbrev-mode
:config
(if (file-exists-p abbrev-file-name)
(quietly-read-abbrev-file)))
delight is invoked with
the :delight
keyword, which is passed a minor mode symbol, a
replacement string or
quoted
mode-line data (in
which case the minor mode symbol is guessed to be the package name
with "-mode" appended at the end), both of these, or several lists of
both. If no arguments are provided, the default mode name is hidden
completely.
;; Don't show anything for rainbow-mode.
(use-package rainbow-mode
:delight)
;; Don't show anything for auto-revert-mode, which doesn't match
;; its package name.
(use-package autorevert
:delight auto-revert-mode)
;; Remove the mode name for projectile-mode, but show the project name.
(use-package projectile
:delight '(:eval (concat " " (projectile-project-name))))
;; Completely hide visual-line-mode and change auto-fill-mode to " AF".
(use-package emacs
:delight
(auto-fill-function " AF")
(visual-line-mode))
You can use use-package
to load packages from ELPA with package.el
. This
is particularly useful if you share your .emacs
among several machines; the
relevant packages are downloaded automatically once declared in your .emacs
.
The :ensure
keyword causes the package(s) to be installed automatically if
not already present on your system:
(use-package magit
:ensure t)
If you need to install a different package from the one named by
use-package
, you can specify it like this:
(use-package tex
:ensure auctex)
Enable use-package-always-ensure
if you wish this behavior to be global
for all packages:
(require 'use-package-ensure)
(setq use-package-always-ensure t)
NOTE: :ensure
will install a package if it is not already installed, but
it does not keep it up-to-date. If you want to keep your packages updated
automatically, one option is to use
auto-package-update,
like
(use-package auto-package-update
:config
(setq auto-package-update-delete-old-versions t)
(setq auto-package-update-hide-results t)
(auto-package-update-maybe))
Lastly, when running on Emacs 24.4 or later, use-package can pin a package to
a specific archive, allowing you to mix and match packages from different
archives. The primary use-case for this is preferring packages from the
gnu
and melpa-stable
archives, but using specific packages from melpa
when you need to track newer versions than what is available in the stable
archives is also a valid use-case.
By default package.el
prefers melpa
over melpa-stable
due to the
versioning (> evil-20141208.623 evil-1.0.9)
, so even if you are tracking
only a single package from melpa
, you will need to tag all the non-melpa
packages with the appropriate archive. If this really annoys you, then you can
set use-package-always-pin
to set a default.
If you want to manually keep a package updated and ignore upstream updates,
you can pin it to manual
, which as long as there is no repository by that
name, will Just Work(tm).
use-package
throws an error if you try to pin a package to an archive that
has not been configured using package-archives
(apart from the magic
manual
archive mentioned above):
Archive 'foo' requested for package 'bar' is not available.
Example:
(use-package company
:ensure t
:pin gnu)
(use-package evil
:ensure t)
;; no :pin needed, as package.el will choose the version in melpa
(use-package adaptive-wrap
:ensure t
;; as this package is available only in the gnu archive, this is
;; technically not needed, but it helps to highlight where it
;; comes from
:pin gnu)
(use-package org
:ensure t
;; ignore org-mode from upstream and use a manually installed version
:pin manual)
NOTE: the :pin
argument has no effect on emacs versions < 24.4.
By overriding use-package-ensure-function
and/or
use-package-pre-ensure-function
, other package managers can override
:ensure
to use them instead of package.el
. At the present time,
the only package manager that does this
is straight.el
.
If you'd like to see how many packages you've loaded, what stage of
initialization they've reached, and how much aggregate time they've
spent (roughly), you can enable use-package-compute-statistics
after
loading use-package
but before any use-package
forms, and then run
the command M-x use-package-report
to see the results. The buffer
displayed is a tabulated list. You can use S
in a column to sort the
rows based on it.
Starting with version 2.0, use-package
is based on an extensible
framework that makes it easy for package authors to add new keywords,
or modify the behavior of existing keywords.
Some keyword extensions are now included in the use-package
distribution and can be optionally installed.
The :ensure-system-package
keyword allows you to ensure system
binaries exist alongside your package declarations.
First, you will want to make sure exec-path
is cognisant of all
binary package names that you would like to ensure are
installed. exec-path-from-shell
is often a good way to do this.
To enable the extension after you've loaded use-package
:
(use-package use-package-ensure-system-package
:ensure t)
Here’s an example of usage:
(use-package rg
:ensure-system-package rg)
This will expect a global binary package to exist called rg
. If it
does not, it will use your system package manager (using the package
system-packages
) to
attempt an install of a binary by the same name asynchronously. For
example, for most macOS
users this would call: brew install rg
.
If the package is named differently than the binary, you can use a
cons in the form of (binary . package-name)
, i.e.:
(use-package rg
:ensure-system-package
(rg . ripgrep))
In the previous macOS
example, this would call: brew install ripgrep
if rg
was not found.
What if you want to customize the install command further?
(use-package tern
:ensure-system-package (tern . "npm i -g tern"))
:ensure-system-package
can also take a cons where its cdr
is a
string that will get called by (async-shell-command)
to install if
it isn’t found.
You may also pass in a list of cons-es:
(use-package ruby-mode
:ensure-system-package
((rubocop . "gem install rubocop")
(ruby-lint . "gem install ruby-lint")
(ripper-tags . "gem install ripper-tags")
(pry . "gem install pry")))
Finally, in case the package dependency does not provide a global executable, you can ensure packages exist by checking the presence of a file path by providing a string like so:
(use-package dash-at-point
:if (eq system-type 'darwin)
:ensure-system-package
("/Applications/Dash.app" . "brew cask install dash"))
:ensure-system-package
will use system-packages-install
to install
system packages, except where a custom command has been specified, in
which case it will be executed verbatim by async-shell-command
.
Configuration variables system-packages-package-manager
and
system-packages-use-sudo
will be honoured, but not for custom
commands. Custom commands should include the call to sudo in the
command if needed.
The :chords
keyword allows you to define
key-chord
bindings
for use-package
declarations in the same manner as the :bind
keyword.
To enable the extension:
(use-package use-package-chords
:ensure t
:config (key-chord-mode 1))
Then you can define your chord bindings in the same manner as :bind
using a cons or a list of conses:
(use-package ace-jump-mode
:chords (("jj" . ace-jump-char-mode)
("jk" . ace-jump-word-mode)
("jl" . ace-jump-line-mode)))
The first step is to add your keyword at the right place in
use-package-keywords
. This list determines the order in which things will
happen in the expanded code. You should never change this order, but it gives
you a framework within which to decide when your keyword should fire.
Define a normalizer for your keyword by defining a function named after the keyword, for example:
(defun use-package-normalize/:pin (name-symbol keyword args)
(use-package-only-one (symbol-name keyword) args
(lambda (label arg)
(cond
((stringp arg) arg)
((symbolp arg) (symbol-name arg))
(t
(use-package-error
":pin wants an archive name (a string)"))))))
The job of the normalizer is take a list of arguments (possibly nil), and turn
it into the single argument (which could still be a list) that should appear
in the final property list used by use-package
.
Once you have a normalizer, you must create a handler for the keyword:
(defun use-package-handler/:pin (name-symbol keyword archive-name rest state)
(let ((body (use-package-process-keywords name-symbol rest state)))
;; This happens at macro expansion time, not when the expanded code is
;; compiled or evaluated.
(if (null archive-name)
body
(use-package-pin-package name-symbol archive-name)
(use-package-concat
body
`((push '(,name-symbol . ,archive-name)
package-pinned-packages))))))
Handlers can affect the handling of keywords in two ways. First, it can
modify the state
plist before recursively processing the remaining keywords,
to influence keywords that pay attention to the state (one example is the
state keyword :deferred
, not to be confused with the use-package
keyword
:defer
). Then, once the remaining keywords have been handled and their
resulting forms returned, the handler may manipulate, extend, or just ignore
those forms.
The task of each handler is to return a list of forms representing code to
be inserted. It does not need to be a progn
list, as this is handled
automatically in other places. Thus it is very common to see the idiom of
using use-package-concat
to add new functionality before or after a code
body, so that only the minimum code necessary is emitted as the result of a
use-package
expansion.
After the keyword has been inserted into use-package-keywords
, and a
normalizer and a handler defined, you can now test it by seeing how usages of
the keyword will expand. For this, use M-x pp-macroexpand-last-sexp
with
the cursor set immediately after the (use-package ...)
expression.
On my Retina iMac, the "Mac port" variant of Emacs 24.4 loads in 0.57s, with around 218 packages configured (nearly all of them lazy-loaded). However, I experience no loss of functionality, just a bit of latency when I'm first starting to use Emacs (due to the autoloading). Since I also use idle-loading for many packages, perceived latency is typically reduced overall.
On Linux, the same configuration loads in 0.32s.
If I don't use Emacs graphically, I can test the absolute minimum times. This is done by running:
time emacs -l init.elc -batch --eval '(message "Hello, world!")'
On the Mac I see an average of 0.36s for the same configuration, and on Linux 0.26s.
The meaning of :init
has been changed: It now always happens before
package load, whether :config
has been deferred or not. This means that
some uses of :init
in your configuration may need to be changed to :config
(in the non-deferred case). For the deferred case, the behavior is unchanged
from before.
Also, because :init
and :config
now mean "before" and "after", the :pre-
and :post-
keywords are gone, as they should no longer be necessary.
Lastly, an effort has been made to make your Emacs start even in the presence
of use-package configuration failures. So after this change, be sure to check
your *Messages*
buffer. Most likely, you will have several instances where
you are using :init
, but should be using :config
(this was the case for me
in a number of places).
I am removing this feature for now because it can result in a nasty inconsistency. Consider the following definition:
(use-package vkill
:commands vkill
:idle (some-important-configuration-here)
:bind ("C-x L" . vkill-and-helm-occur)
:init
(defun vkill-and-helm-occur ()
(interactive)
(vkill)
(call-interactively #'helm-occur))
:config
(setq vkill-show-all-processes t))
If I load my Emacs and wait until the idle timer fires, then this is the sequence of events:
:init :idle <load> :config
But if I load Emacs and immediately type C-x L without waiting for the idle timer to fire, this is the sequence of events:
:init <load> :config :idle
It's possible that the user could use featurep
in their idle to test for
this case, but that's a subtlety I'd rather avoid.
:defer [N]
causes the package to be loaded -- if it has not already been --
after N
seconds of idle time.
(use-package back-button
:commands (back-button-mode)
:defer 2
:init
(setq back-button-show-toolbar-buttons nil)
:config
(back-button-mode 1))
:preface
can be used to establish function and variable definitions that
will 1) make the byte-compiler happy (it won't complain about functions whose
definitions are unknown because you have them within a guard block), and 2)
allow you to define code that can be used in an :if
test.
NOTE: whatever is specified within :preface
is evaluated both at load
time and at byte-compilation time, in order to ensure that definitions are
seen by both the Lisp evaluator and the byte-compiler, so you should avoid
having any side-effects in your preface, and restrict it merely to symbol
declarations and definitions.
What :defines
does for variables, :functions
does for functions.
This means you should put the following at the top of your Emacs, to further reduce load time:
(eval-when-compile
(require 'use-package))
(require 'diminish) ;; if you use :diminish
(require 'bind-key) ;; if you use any :bind variant