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[elpa] externals/dash 2b69c14 411/426: Add dash.info and dash.texi to re
From: |
Phillip Lord |
Subject: |
[elpa] externals/dash 2b69c14 411/426: Add dash.info and dash.texi to repo |
Date: |
Tue, 04 Aug 2015 19:39:17 +0000 |
branch: externals/dash
commit 2b69c146e419bebd495cd1ed9b1392f753ffb924
Author: Magnar Sveen <address@hidden>
Commit: Magnar Sveen <address@hidden>
Add dash.info and dash.texi to repo
---
dash.info | 2675 +++++++++++++++++++++++++++++++++++++++++++++
dash.texi | 3592 +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
2 files changed, 6267 insertions(+), 0 deletions(-)
diff --git a/dash.info b/dash.info
new file mode 100644
index 0000000..900f0d0
--- /dev/null
+++ b/dash.info
@@ -0,0 +1,2675 @@
+This is dash.info, produced by makeinfo version 4.8 from dash.texi.
+
+INFO-DIR-SECTION Emacs
+START-INFO-DIR-ENTRY
+* Dash: (dash.info). A modern list library for GNU Emacs
+END-INFO-DIR-ENTRY
+
+ This manual is for `dash.el' version 2.10.0.
+
+ Copyright © 2012-2015 Magnar Sveen
+
+ This program is free software; you can redistribute it and/or
+ modify it under the terms of the GNU General Public License as
+ published by the Free Software Foundation, either version 3 of
+ the License, or (at your option) any later version.
+
+ This program is distributed in the hope that it will be useful,
+ but WITHOUT ANY WARRANTY; without even the implied warranty of
+ MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
+ GNU General Public License for more details.
+
+ You should have received a copy of the GNU General Public License
+ along with this program. If not, see
+ `http://www.gnu.org/licenses/'.
+
+
+File: dash.info, Node: Top, Next: Installation, Up: (dir)
+
+dash
+****
+
+This manual is for `dash.el' version 2.10.0.
+
+ Copyright © 2012-2015 Magnar Sveen
+
+ This program is free software; you can redistribute it and/or
+ modify it under the terms of the GNU General Public License as
+ published by the Free Software Foundation, either version 3 of
+ the License, or (at your option) any later version.
+
+ This program is distributed in the hope that it will be useful,
+ but WITHOUT ANY WARRANTY; without even the implied warranty of
+ MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
+ GNU General Public License for more details.
+
+ You should have received a copy of the GNU General Public License
+ along with this program. If not, see
+ `http://www.gnu.org/licenses/'.
+
+* Menu:
+
+* Installation::
+* Functions::
+* Development::
+* Index::
+
+--- The Detailed Node Listing ---
+
+Installation
+
+* Using in a package::
+* Syntax highlighting of dash functions::
+
+Functions
+
+* Maps::
+* Sublist selection::
+* List to list::
+* Reductions::
+* Unfolding::
+* Predicates::
+* Partitioning::
+* Indexing::
+* Set operations::
+* Other list operations::
+* Tree operations::
+* Threading macros::
+* Binding::
+* Side-effects::
+* Destructive operations::
+* Function combinators::
+
+Development
+
+* Contribute:: How to contribute
+* Changes:: List of significant changes by version
+* Contributors:: List of contributors
+
+
+File: dash.info, Node: Installation, Next: Functions, Prev: Top, Up: Top
+
+1 Installation
+**************
+
+It's available on marmalade (http://marmalade-repo.org/) and Melpa
+(http://melpa.milkbox.net/); use `M-x package-install':
+
+`M-x package-install <RET> dash'
+ Install the dash library.
+
+`M-x package-install <RET> dash-functional'
+ Optional, if you want the function combinators.
+
+ Alternatively, you can just dump dash.el or dash-functional.el in
+your load path somewhere.
+
+* Menu:
+
+* Using in a package::
+* Syntax highlighting of dash functions::
+
+
+File: dash.info, Node: Using in a package, Next: Syntax highlighting of dash
functions, Up: Installation
+
+1.1 Using in a package
+======================
+
+Add this to the big comment block at the top:
+
+ ;; Package-Requires: ((dash "2.10.0"))
+
+To get function combinators:
+
+ ;; Package-Requires: ((dash "2.10.0") (dash-functional "1.2.0") (emacs
"24"))
+
+
+File: dash.info, Node: Syntax highlighting of dash functions, Prev: Using in
a package, Up: Installation
+
+1.2 Syntax highlighting of dash functions
+=========================================
+
+Font lock of dash functions in emacs lisp buffers is now optional.
+Include this in your emacs settings to get syntax highlighting:
+
+ (eval-after-load "dash" '(dash-enable-font-lock))
+
+
+File: dash.info, Node: Functions, Next: Development, Prev: Installation,
Up: Top
+
+2 Functions
+***********
+
+This chapter contains reference documentation for the dash
+application programming interface (API). All functions and
+constructs in the library are prefixed with a dash (-).
+
+ There are also anaphoric versions of functions where that makes
+sense, prefixed with two dashes instead of one.
+
+ For instance, while `-map' takes a function to map over the list,
+one can also use the anaphoric form with double dashes - which will
+then be executed with `it' exposed as the list item. Here's an
+example:
+
+ (-map (lambda (n) (* n n)) '(1 2 3 4)) ;; normal version
+
+ (--map (* it it) '(1 2 3 4)) ;; anaphoric version
+
+Of course, the original can also be written like
+
+ (defun square (n) (* n n))
+
+ (-map 'square '(1 2 3 4))
+
+which demonstrates the usefulness of both versions.
+
+* Menu:
+
+* Maps::
+* Sublist selection::
+* List to list::
+* Reductions::
+* Unfolding::
+* Predicates::
+* Partitioning::
+* Indexing::
+* Set operations::
+* Other list operations::
+* Tree operations::
+* Threading macros::
+* Binding::
+* Side-effects::
+* Destructive operations::
+* Function combinators::
+
+
+File: dash.info, Node: Maps, Next: Sublist selection, Up: Functions
+
+2.1 Maps
+========
+
+Functions in this category take a transforming function, which is
+then applied sequentially to each or selected elements of the input
+list. The results are collected in order and returned as new list.
+
+ -- Function: -map (fn list)
+ Return a new list consisting of the result of applying FN to the
+ items in LIST.
+
+ (-map (lambda (num) (* num num)) '(1 2 3 4))
+ => '(1 4 9 16)
+ (-map 'square '(1 2 3 4))
+ => '(1 4 9 16)
+ (--map (* it it) '(1 2 3 4))
+ => '(1 4 9 16)
+
+ -- Function: -map-when (pred rep list)
+ Return a new list where the elements in LIST that does not match
+ the PRED function are unchanged, and where the elements in LIST
+ that do match the PRED function are mapped through the REP
+ function.
+
+ Alias: `-replace-where'
+
+ See also: `-update-at' (*note -update-at::)
+
+ (-map-when 'even? 'square '(1 2 3 4))
+ => '(1 4 3 16)
+ (--map-when (> it 2) (* it it) '(1 2 3 4))
+ => '(1 2 9 16)
+ (--map-when (= it 2) 17 '(1 2 3 4))
+ => '(1 17 3 4)
+
+ -- Function: -map-indexed (fn list)
+ Return a new list consisting of the result of (FN index item)
+ for each item in LIST.
+
+ In the anaphoric form `--map-indexed', the index is exposed as
+ `it-index`.
+
+ (-map-indexed (lambda (index item) (- item index)) '(1 2 3 4))
+ => '(1 1 1 1)
+ (--map-indexed (- it it-index) '(1 2 3 4))
+ => '(1 1 1 1)
+
+ -- Function: -annotate (fn list)
+ Return a list of cons cells where each cell is FN applied to each
+ element of LIST paired with the unmodified element of LIST.
+
+ (-annotate '1+ '(1 2 3))
+ => '((2 . 1) (3 . 2) (4 . 3))
+ (-annotate 'length '(("h" "e" "l" "l" "o") ("hello" "world")))
+ => '((5 "h" "e" "l" "l" "o") (2 "hello" "world"))
+ (--annotate (< 1 it) '(0 1 2 3))
+ => '((nil . 0) (nil . 1) (t . 2) (t . 3))
+
+ -- Function: -splice (pred fun list)
+ Splice lists generated by FUN in place of elements matching PRED
+ in LIST.
+
+ FUN takes the element matching PRED as input.
+
+ This function can be used as replacement for `,@' in case you
+ need to splice several lists at marked positions (for example
+ with keywords).
+
+ See also: `-splice-list' (*note -splice-list::), `-insert-at'
+ (*note -insert-at::)
+
+ (-splice 'even? (lambda (x) (list x x)) '(1 2 3 4))
+ => '(1 2 2 3 4 4)
+ (--splice 't (list it it) '(1 2 3 4))
+ => '(1 1 2 2 3 3 4 4)
+ (--splice (equal it :magic) '((list of) (magical) (code)) '((foo)
(bar) :magic (baz)))
+ => '((foo) (bar) (list of) (magical) (code) (baz))
+
+ -- Function: -splice-list (pred new-list list)
+ Splice NEW-LIST in place of elements matching PRED in LIST.
+
+ See also: `-splice' (*note -splice::), `-insert-at' (*note
+ -insert-at::)
+
+ (-splice-list 'keywordp '(a b c) '(1 :foo 2))
+ => '(1 a b c 2)
+ (-splice-list 'keywordp nil '(1 :foo 2))
+ => '(1 2)
+
+ -- Function: -mapcat (fn list)
+ Return the concatenation of the result of mapping FN over LIST.
+ Thus function FN should return a list.
+
+ (-mapcat 'list '(1 2 3))
+ => '(1 2 3)
+ (-mapcat (lambda (item) (list 0 item)) '(1 2 3))
+ => '(0 1 0 2 0 3)
+ (--mapcat (list 0 it) '(1 2 3))
+ => '(0 1 0 2 0 3)
+
+ -- Function: -copy (arg)
+ Create a shallow copy of LIST.
+
+ (-copy '(1 2 3))
+ => '(1 2 3)
+ (let ((a '(1 2 3))) (eq a (-copy a)))
+ => nil
+
+
+File: dash.info, Node: Sublist selection, Next: List to list, Prev: Maps,
Up: Functions
+
+2.2 Sublist selection
+=====================
+
+Functions returning a sublist of the original list.
+
+ -- Function: -filter (pred list)
+ Return a new list of the items in LIST for which PRED returns a
+ non-nil value.
+
+ Alias: `-select'
+
+ (-filter (lambda (num) (= 0 (% num 2))) '(1 2 3 4))
+ => '(2 4)
+ (-filter 'even? '(1 2 3 4))
+ => '(2 4)
+ (--filter (= 0 (% it 2)) '(1 2 3 4))
+ => '(2 4)
+
+ -- Function: -remove (pred list)
+ Return a new list of the items in LIST for which PRED returns
+ nil.
+
+ Alias: `-reject'
+
+ (-remove (lambda (num) (= 0 (% num 2))) '(1 2 3 4))
+ => '(1 3)
+ (-remove 'even? '(1 2 3 4))
+ => '(1 3)
+ (--remove (= 0 (% it 2)) '(1 2 3 4))
+ => '(1 3)
+
+ -- Function: -non-nil (list)
+ Return all non-nil elements of LIST.
+
+ (-non-nil '(1 nil 2 nil nil 3 4 nil 5 nil))
+ => '(1 2 3 4 5)
+
+ -- Function: -slice (list from &optional to step)
+ Return copy of LIST, starting from index FROM to index TO.
+
+ FROM or TO may be negative. These values are then interpreted
+ modulo the length of the list.
+
+ If STEP is a number, only each STEPth item in the resulting
+ section is returned. Defaults to 1.
+
+ (-slice '(1 2 3 4 5) 1)
+ => '(2 3 4 5)
+ (-slice '(1 2 3 4 5) 0 3)
+ => '(1 2 3)
+ (-slice '(1 2 3 4 5 6 7 8 9) 1 -1 2)
+ => '(2 4 6 8)
+
+ -- Function: -take (n list)
+ Return a new list of the first N items in LIST, or all items if
+ there are fewer than N.
+
+ (-take 3 '(1 2 3 4 5))
+ => '(1 2 3)
+ (-take 17 '(1 2 3 4 5))
+ => '(1 2 3 4 5)
+
+ -- Function: -drop (n list)
+ Return the tail of LIST without the first N items.
+
+ (-drop 3 '(1 2 3 4 5))
+ => '(4 5)
+ (-drop 17 '(1 2 3 4 5))
+ => '()
+
+ -- Function: -take-while (pred list)
+ Return a new list of successive items from LIST while (PRED
+ item) returns a non-nil value.
+
+ (-take-while 'even? '(1 2 3 4))
+ => '()
+ (-take-while 'even? '(2 4 5 6))
+ => '(2 4)
+ (--take-while (< it 4) '(1 2 3 4 3 2 1))
+ => '(1 2 3)
+
+ -- Function: -drop-while (pred list)
+ Return the tail of LIST starting from the first item for which
+ (PRED item) returns nil.
+
+ (-drop-while 'even? '(1 2 3 4))
+ => '(1 2 3 4)
+ (-drop-while 'even? '(2 4 5 6))
+ => '(5 6)
+ (--drop-while (< it 4) '(1 2 3 4 3 2 1))
+ => '(4 3 2 1)
+
+ -- Function: -select-by-indices (indices list)
+ Return a list whose elements are elements from LIST selected as
+ `(nth i list)` for all i from INDICES.
+
+ (-select-by-indices '(4 10 2 3 6) '("v" "e" "l" "o" "c" "i" "r" "a"
"p" "t" "o" "r"))
+ => '("c" "o" "l" "o" "r")
+ (-select-by-indices '(2 1 0) '("a" "b" "c"))
+ => '("c" "b" "a")
+ (-select-by-indices '(0 1 2 0 1 3 3 1) '("f" "a" "r" "l"))
+ => '("f" "a" "r" "f" "a" "l" "l" "a")
+
+
+File: dash.info, Node: List to list, Next: Reductions, Prev: Sublist
selection, Up: Functions
+
+2.3 List to list
+================
+
+Bag of various functions which modify input list.
+
+ -- Function: -keep (fn list)
+ Return a new list of the non-nil results of applying FN to the
+ items in LIST.
+
+ (-keep 'cdr '((1 2 3) (4 5) (6)))
+ => '((2 3) (5))
+ (-keep (lambda (num) (when (> num 3) (* 10 num))) '(1 2 3 4 5 6))
+ => '(40 50 60)
+ (--keep (when (> it 3) (* 10 it)) '(1 2 3 4 5 6))
+ => '(40 50 60)
+
+ -- Function: -concat (&rest lists)
+ Return a new list with the concatenation of the elements in the
+ supplied LISTS.
+
+ (-concat '(1))
+ => '(1)
+ (-concat '(1) '(2))
+ => '(1 2)
+ (-concat '(1) '(2 3) '(4))
+ => '(1 2 3 4)
+
+ -- Function: -flatten (l)
+ Take a nested list L and return its contents as a single, flat
+ list.
+
+ See also: `-flatten-n' (*note -flatten-n::)
+
+ (-flatten '((1)))
+ => '(1)
+ (-flatten '((1 (2 3) (((4 (5)))))))
+ => '(1 2 3 4 5)
+ (-flatten '(1 2 (3 . 4)))
+ => '(1 2 (3 . 4))
+
+ -- Function: -flatten-n (num list)
+ Flatten NUM levels of a nested LIST.
+
+ See also: `-flatten' (*note -flatten::)
+
+ (-flatten-n 1 '((1 2) ((3 4) ((5 6)))))
+ => '(1 2 (3 4) ((5 6)))
+ (-flatten-n 2 '((1 2) ((3 4) ((5 6)))))
+ => '(1 2 3 4 (5 6))
+ (-flatten-n 3 '((1 2) ((3 4) ((5 6)))))
+ => '(1 2 3 4 5 6)
+
+ -- Function: -replace (old new list)
+ Replace all OLD items in LIST with NEW.
+
+ Elements are compared using `equal'.
+
+ See also: `-replace-at' (*note -replace-at::)
+
+ (-replace 1 "1" '(1 2 3 4 3 2 1))
+ => '("1" 2 3 4 3 2 "1")
+ (-replace "foo" "bar" '("a" "nice" "foo" "sentence" "about" "foo"))
+ => '("a" "nice" "bar" "sentence" "about" "bar")
+ (-replace 1 2 nil)
+ => nil
+
+ -- Function: -insert-at (n x list)
+ Return a list with X inserted into LIST at position N.
+
+ See also: `-splice' (*note -splice::), `-splice-list' (*note
+ -splice-list::)
+
+ (-insert-at 1 'x '(a b c))
+ => '(a x b c)
+ (-insert-at 12 'x '(a b c))
+ => '(a b c x)
+
+ -- Function: -replace-at (n x list)
+ Return a list with element at Nth position in LIST replaced with
+ X.
+
+ See also: `-replace' (*note -replace::)
+
+ (-replace-at 0 9 '(0 1 2 3 4 5))
+ => '(9 1 2 3 4 5)
+ (-replace-at 1 9 '(0 1 2 3 4 5))
+ => '(0 9 2 3 4 5)
+ (-replace-at 4 9 '(0 1 2 3 4 5))
+ => '(0 1 2 3 9 5)
+
+ -- Function: -update-at (n func list)
+ Return a list with element at Nth position in LIST replaced with
+ `(func (nth n list))`.
+
+ See also: `-map-when' (*note -map-when::)
+
+ (-update-at 0 (lambda (x) (+ x 9)) '(0 1 2 3 4 5))
+ => '(9 1 2 3 4 5)
+ (-update-at 1 (lambda (x) (+ x 8)) '(0 1 2 3 4 5))
+ => '(0 9 2 3 4 5)
+ (--update-at 2 (length it) '("foo" "bar" "baz" "quux"))
+ => '("foo" "bar" 3 "quux")
+
+ -- Function: -remove-at (n list)
+ Return a list with element at Nth position in LIST removed.
+
+ See also: `-remove-at-indices' (*note -remove-at-indices::),
+ `-remove' (*note -remove::)
+
+ (-remove-at 0 '("0" "1" "2" "3" "4" "5"))
+ => '("1" "2" "3" "4" "5")
+ (-remove-at 1 '("0" "1" "2" "3" "4" "5"))
+ => '("0" "2" "3" "4" "5")
+ (-remove-at 2 '("0" "1" "2" "3" "4" "5"))
+ => '("0" "1" "3" "4" "5")
+
+ -- Function: -remove-at-indices (indices list)
+ Return a list whose elements are elements from LIST without
+ elements selected as `(nth i list)` for all i from INDICES.
+
+ See also: `-remove-at' (*note -remove-at::), `-remove' (*note
+ -remove::)
+
+ (-remove-at-indices '(0) '("0" "1" "2" "3" "4" "5"))
+ => '("1" "2" "3" "4" "5")
+ (-remove-at-indices '(0 2 4) '("0" "1" "2" "3" "4" "5"))
+ => '("1" "3" "5")
+ (-remove-at-indices '(0 5) '("0" "1" "2" "3" "4" "5"))
+ => '("1" "2" "3" "4")
+
+
+File: dash.info, Node: Reductions, Next: Unfolding, Prev: List to list,
Up: Functions
+
+2.4 Reductions
+==============
+
+Functions reducing lists into single value.
+
+ -- Function: -reduce-from (fn initial-value list)
+ Return the result of applying FN to INITIAL-VALUE and the first
+ item in LIST, then applying FN to that result and the 2nd item,
+ etc. If LIST contains no items, return INITIAL-VALUE and FN is
+ not called.
+
+ In the anaphoric form `--reduce-from', the accumulated value is
+ exposed as `acc`.
+
+ (-reduce-from '- 10 '(1 2 3))
+ => 4
+ (-reduce-from (lambda (memo item) (concat "(" memo " - "
(int-to-string item) ")")) "10" '(1 2 3))
+ => "(((10 - 1) - 2) - 3)"
+ (--reduce-from (concat acc " " it) "START" '("a" "b" "c"))
+ => "START a b c"
+
+ -- Function: -reduce-r-from (fn initial-value list)
+ Replace conses with FN, nil with INITIAL-VALUE and evaluate the
+ resulting expression. If LIST is empty, INITIAL-VALUE is
+ returned and FN is not called.
+
+ Note: this function works the same as `-reduce-from' (*note
+ -reduce-from::) but the operation associates from right instead
+ of from left.
+
+ (-reduce-r-from '- 10 '(1 2 3))
+ => -8
+ (-reduce-r-from (lambda (item memo) (concat "(" (int-to-string item)
" - " memo ")")) "10" '(1 2 3))
+ => "(1 - (2 - (3 - 10)))"
+ (--reduce-r-from (concat it " " acc) "END" '("a" "b" "c"))
+ => "a b c END"
+
+ -- Function: -reduce (fn list)
+ Return the result of applying FN to the first 2 items in LIST,
+ then applying FN to that result and the 3rd item, etc. If LIST
+ contains no items, FN must accept no arguments as well, and
+ reduce return the result of calling FN with no arguments. If
+ LIST has only 1 item, it is returned and FN is not called.
+
+ In the anaphoric form `--reduce', the accumulated value is
+ exposed as `acc`.
+
+ (-reduce '- '(1 2 3 4))
+ => -8
+ (-reduce (lambda (memo item) (format "%s-%s" memo item)) '(1 2 3))
+ => "1-2-3"
+ (--reduce (format "%s-%s" acc it) '(1 2 3))
+ => "1-2-3"
+
+ -- Function: -reduce-r (fn list)
+ Replace conses with FN and evaluate the resulting expression.
+ The final nil is ignored. If LIST contains no items, FN must
+ accept no arguments as well, and reduce return the result of
+ calling FN with no arguments. If LIST has only 1 item, it is
+ returned and FN is not called.
+
+ The first argument of FN is the new item, the second is the
+ accumulated value.
+
+ Note: this function works the same as `-reduce' (*note
+ -reduce::) but the operation associates from right instead of
+ from left.
+
+ (-reduce-r '- '(1 2 3 4))
+ => -2
+ (-reduce-r (lambda (item memo) (format "%s-%s" memo item)) '(1 2 3))
+ => "3-2-1"
+ (--reduce-r (format "%s-%s" acc it) '(1 2 3))
+ => "3-2-1"
+
+ -- Function: -count (pred list)
+ Counts the number of items in LIST where (PRED item) is non-nil.
+
+ (-count 'even? '(1 2 3 4 5))
+ => 2
+ (--count (< it 4) '(1 2 3 4))
+ => 3
+
+ -- Function: -sum (list)
+ Return the sum of LIST.
+
+ (-sum '())
+ => 0
+ (-sum '(1))
+ => 1
+ (-sum '(1 2 3 4))
+ => 10
+
+ -- Function: -product (list)
+ Return the product of LIST.
+
+ (-product '())
+ => 1
+ (-product '(1))
+ => 1
+ (-product '(1 2 3 4))
+ => 24
+
+ -- Function: -min (list)
+ Return the smallest value from LIST of numbers or markers.
+
+ (-min '(0))
+ => 0
+ (-min '(3 2 1))
+ => 1
+ (-min '(1 2 3))
+ => 1
+
+ -- Function: -min-by (comparator list)
+ Take a comparison function COMPARATOR and a LIST and return the
+ least element of the list by the comparison function.
+
+ See also combinator `-on' (*note -on::) which can transform the
+ values before comparing them.
+
+ (-min-by '> '(4 3 6 1))
+ => 1
+ (--min-by (> (car it) (car other)) '((1 2 3) (2) (3 2)))
+ => '(1 2 3)
+ (--min-by (> (length it) (length other)) '((1 2 3) (2) (3 2)))
+ => '(2)
+
+ -- Function: -max (list)
+ Return the largest value from LIST of numbers or markers.
+
+ (-max '(0))
+ => 0
+ (-max '(3 2 1))
+ => 3
+ (-max '(1 2 3))
+ => 3
+
+ -- Function: -max-by (comparator list)
+ Take a comparison function COMPARATOR and a LIST and return the
+ greatest element of the list by the comparison function.
+
+ See also combinator `-on' (*note -on::) which can transform the
+ values before comparing them.
+
+ (-max-by '> '(4 3 6 1))
+ => 6
+ (--max-by (> (car it) (car other)) '((1 2 3) (2) (3 2)))
+ => '(3 2)
+ (--max-by (> (length it) (length other)) '((1 2 3) (2) (3 2)))
+ => '(1 2 3)
+
+
+File: dash.info, Node: Unfolding, Next: Predicates, Prev: Reductions, Up:
Functions
+
+2.5 Unfolding
+=============
+
+Operations dual to reductions, building lists from seed value rather
+than consuming a list to produce a single value.
+
+ -- Function: -iterate (fun init n)
+ Return a list of iterated applications of FUN to INIT.
+
+ This means a list of form:
+
+ (init (fun init) (fun (fun init)) ...)
+
+ N is the length of the returned list.
+
+ (-iterate '1+ 1 10)
+ => '(1 2 3 4 5 6 7 8 9 10)
+ (-iterate (lambda (x) (+ x x)) 2 5)
+ => '(2 4 8 16 32)
+ (--iterate (* it it) 2 5)
+ => '(2 4 16 256 65536)
+
+ -- Function: -unfold (fun seed)
+ Build a list from SEED using FUN.
+
+ This is "dual" operation to `-reduce-r' (*note -reduce-r::):
+ while -reduce-r consumes a list to produce a single value,
+ `-unfold' (*note -unfold::) takes a seed value and builds a
+ (potentially infinite!) list.
+
+ FUN should return `nil' to stop the generating process, or a
+ cons (A . B), where A will be prepended to the result and B is
+ the new seed.
+
+ (-unfold (lambda (x) (unless (= x 0) (cons x (1- x)))) 10)
+ => '(10 9 8 7 6 5 4 3 2 1)
+ (--unfold (when it (cons it (cdr it))) '(1 2 3 4))
+ => '((1 2 3 4) (2 3 4) (3 4) (4))
+ (--unfold (when it (cons it (butlast it))) '(1 2 3 4))
+ => '((1 2 3 4) (1 2 3) (1 2) (1))
+
+
+File: dash.info, Node: Predicates, Next: Partitioning, Prev: Unfolding,
Up: Functions
+
+2.6 Predicates
+==============
+
+ -- Function: -any? (pred list)
+ Return t if (PRED x) is non-nil for any x in LIST, else nil.
+
+ Alias: `-any-p', `-some?', `-some-p'
+
+ (-any? 'even? '(1 2 3))
+ => t
+ (-any? 'even? '(1 3 5))
+ => nil
+ (--any? (= 0 (% it 2)) '(1 2 3))
+ => t
+
+ -- Function: -all? (pred list)
+ Return t if (PRED x) is non-nil for all x in LIST, else nil.
+
+ Alias: `-all-p', `-every?', `-every-p'
+
+ (-all? 'even? '(1 2 3))
+ => nil
+ (-all? 'even? '(2 4 6))
+ => t
+ (--all? (= 0 (% it 2)) '(2 4 6))
+ => t
+
+ -- Function: -none? (pred list)
+ Return t if (PRED x) is nil for all x in LIST, else nil.
+
+ Alias: `-none-p'
+
+ (-none? 'even? '(1 2 3))
+ => nil
+ (-none? 'even? '(1 3 5))
+ => t
+ (--none? (= 0 (% it 2)) '(1 2 3))
+ => nil
+
+ -- Function: -only-some? (pred list)
+ Return `t` if at least one item of LIST matches PRED and at
+ least one item of LIST does not match PRED. Return `nil` both
+ if all items match the predicate or if none of the items match
+ the predicate.
+
+ Alias: `-only-some-p'
+
+ (-only-some? 'even? '(1 2 3))
+ => t
+ (-only-some? 'even? '(1 3 5))
+ => nil
+ (-only-some? 'even? '(2 4 6))
+ => nil
+
+ -- Function: -contains? (list element)
+ Return non-nil if LIST contains ELEMENT.
+
+ The test for equality is done with `equal', or with `-compare-fn'
+ if that's non-nil.
+
+ Alias: `-contains-p'
+
+ (-contains? '(1 2 3) 1)
+ => t
+ (-contains? '(1 2 3) 2)
+ => t
+ (-contains? '(1 2 3) 4)
+ => nil
+
+ -- Function: -same-items? (list list2)
+ Return true if LIST and LIST2 has the same items.
+
+ The order of the elements in the lists does not matter.
+
+ Alias: `-same-items-p'
+
+ (-same-items? '(1 2 3) '(1 2 3))
+ => t
+ (-same-items? '(1 2 3) '(3 2 1))
+ => t
+ (-same-items? '(1 2 3) '(1 2 3 4))
+ => nil
+
+ -- Function: -is-prefix? (prefix list)
+ Return non-nil if PREFIX is prefix of LIST.
+
+ Alias: `-is-prefix-p'
+
+ (-is-prefix? '(1 2 3) '(1 2 3 4 5))
+ => t
+ (-is-prefix? '(1 2 3 4 5) '(1 2 3))
+ => nil
+ (-is-prefix? '(1 3) '(1 2 3 4 5))
+ => nil
+
+ -- Function: -is-suffix? (suffix list)
+ Return non-nil if SUFFIX is suffix of LIST.
+
+ Alias: `-is-suffix-p'
+
+ (-is-suffix? '(3 4 5) '(1 2 3 4 5))
+ => t
+ (-is-suffix? '(1 2 3 4 5) '(3 4 5))
+ => nil
+ (-is-suffix? '(3 5) '(1 2 3 4 5))
+ => nil
+
+ -- Function: -is-infix? (infix list)
+ Return non-nil if INFIX is infix of LIST.
+
+ This operation runs in O(n^2) time
+
+ Alias: `-is-infix-p'
+
+ (-is-infix? '(1 2 3) '(1 2 3 4 5))
+ => t
+ (-is-infix? '(2 3 4) '(1 2 3 4 5))
+ => t
+ (-is-infix? '(3 4 5) '(1 2 3 4 5))
+ => t
+
+
+File: dash.info, Node: Partitioning, Next: Indexing, Prev: Predicates, Up:
Functions
+
+2.7 Partitioning
+================
+
+Functions partitioning the input list into a list of lists.
+
+ -- Function: -split-at (n list)
+ Return a list of ((-take N LIST) (-drop N LIST)), in no more
+ than one pass through the list.
+
+ (-split-at 3 '(1 2 3 4 5))
+ => '((1 2 3) (4 5))
+ (-split-at 17 '(1 2 3 4 5))
+ => '((1 2 3 4 5) nil)
+
+ -- Function: -split-with (pred list)
+ Return a list of ((-take-while PRED LIST) (-drop-while PRED
+ LIST)), in no more than one pass through the list.
+
+ (-split-with 'even? '(1 2 3 4))
+ => '(nil (1 2 3 4))
+ (-split-with 'even? '(2 4 5 6))
+ => '((2 4) (5 6))
+ (--split-with (< it 4) '(1 2 3 4 3 2 1))
+ => '((1 2 3) (4 3 2 1))
+
+ -- Function: -split-on (item list)
+ Split the LIST each time ITEM is found.
+
+ Unlike `-partition-by' (*note -partition-by::), the ITEM is
+ discarded from the results. Empty lists are also removed from
+ the result.
+
+ Comparison is done by `equal'.
+
+ See also `-split-when' (*note -split-when::)
+
+ (-split-on '| '(Nil | Leaf a | Node [Tree a]))
+ => '((Nil) (Leaf a) (Node [Tree a]))
+ (-split-on ':endgroup '("a" "b" :endgroup "c" :endgroup "d" "e"))
+ => '(("a" "b") ("c") ("d" "e"))
+ (-split-on ':endgroup '("a" "b" :endgroup :endgroup "d" "e"))
+ => '(("a" "b") ("d" "e"))
+
+ -- Function: -split-when (fn list)
+ Split the LIST on each element where FN returns non-nil.
+
+ Unlike `-partition-by' (*note -partition-by::), the "matched"
+ element is discarded from the results. Empty lists are also
+ removed from the result.
+
+ This function can be thought of as a generalization of
+ `split-string'.
+
+ (-split-when 'even? '(1 2 3 4 5 6))
+ => '((1) (3) (5))
+ (-split-when 'even? '(1 2 3 4 6 8 9))
+ => '((1) (3) (9))
+ (--split-when (memq it '(&optional &rest)) '(a b &optional c d &rest
args))
+ => '((a b) (c d) (args))
+
+ -- Function: -separate (pred list)
+ Return a list of ((-filter PRED LIST) (-remove PRED LIST)), in
+ one pass through the list.
+
+ (-separate (lambda (num) (= 0 (% num 2))) '(1 2 3 4 5 6 7))
+ => '((2 4 6) (1 3 5 7))
+ (--separate (< it 5) '(3 7 5 9 3 2 1 4 6))
+ => '((3 3 2 1 4) (7 5 9 6))
+ (-separate 'cdr '((1 2) (1) (1 2 3) (4)))
+ => '(((1 2) (1 2 3)) ((1) (4)))
+
+ -- Function: -partition (n list)
+ Return a new list with the items in LIST grouped into N-sized
+ sublists. If there are not enough items to make the last group
+ N-sized, those items are discarded.
+
+ (-partition 2 '(1 2 3 4 5 6))
+ => '((1 2) (3 4) (5 6))
+ (-partition 2 '(1 2 3 4 5 6 7))
+ => '((1 2) (3 4) (5 6))
+ (-partition 3 '(1 2 3 4 5 6 7))
+ => '((1 2 3) (4 5 6))
+
+ -- Function: -partition-all (n list)
+ Return a new list with the items in LIST grouped into N-sized
+ sublists. The last group may contain less than N items.
+
+ (-partition-all 2 '(1 2 3 4 5 6))
+ => '((1 2) (3 4) (5 6))
+ (-partition-all 2 '(1 2 3 4 5 6 7))
+ => '((1 2) (3 4) (5 6) (7))
+ (-partition-all 3 '(1 2 3 4 5 6 7))
+ => '((1 2 3) (4 5 6) (7))
+
+ -- Function: -partition-in-steps (n step list)
+ Return a new list with the items in LIST grouped into N-sized
+ sublists at offsets STEP apart. If there are not enough items
+ to make the last group N-sized, those items are discarded.
+
+ (-partition-in-steps 2 1 '(1 2 3 4))
+ => '((1 2) (2 3) (3 4))
+ (-partition-in-steps 3 2 '(1 2 3 4))
+ => '((1 2 3))
+ (-partition-in-steps 3 2 '(1 2 3 4 5))
+ => '((1 2 3) (3 4 5))
+
+ -- Function: -partition-all-in-steps (n step list)
+ Return a new list with the items in LIST grouped into N-sized
+ sublists at offsets STEP apart. The last groups may contain
+ less than N items.
+
+ (-partition-all-in-steps 2 1 '(1 2 3 4))
+ => '((1 2) (2 3) (3 4) (4))
+ (-partition-all-in-steps 3 2 '(1 2 3 4))
+ => '((1 2 3) (3 4))
+ (-partition-all-in-steps 3 2 '(1 2 3 4 5))
+ => '((1 2 3) (3 4 5) (5))
+
+ -- Function: -partition-by (fn list)
+ Apply FN to each item in LIST, splitting it each time FN returns
+ a new value.
+
+ (-partition-by 'even? '())
+ => '()
+ (-partition-by 'even? '(1 1 2 2 2 3 4 6 8))
+ => '((1 1) (2 2 2) (3) (4 6 8))
+ (--partition-by (< it 3) '(1 2 3 4 3 2 1))
+ => '((1 2) (3 4 3) (2 1))
+
+ -- Function: -partition-by-header (fn list)
+ Apply FN to the first item in LIST. That is the header value.
+ Apply FN to each item in LIST, splitting it each time FN returns
+ the header value, but only after seeing at least one other value
+ (the body).
+
+ (--partition-by-header (= it 1) '(1 2 3 1 2 1 2 3 4))
+ => '((1 2 3) (1 2) (1 2 3 4))
+ (--partition-by-header (> it 0) '(1 2 0 1 0 1 2 3 0))
+ => '((1 2 0) (1 0) (1 2 3 0))
+ (-partition-by-header 'even? '(2 1 1 1 4 1 3 5 6 6 1))
+ => '((2 1 1 1) (4 1 3 5) (6 6 1))
+
+ -- Function: -group-by (fn list)
+ Separate LIST into an alist whose keys are FN applied to the
+ elements of LIST. Keys are compared by `equal'.
+
+ (-group-by 'even? '())
+ => '()
+ (-group-by 'even? '(1 1 2 2 2 3 4 6 8))
+ => '((nil 1 1 3) (t 2 2 2 4 6 8))
+ (--group-by (car (split-string it "/")) '("a/b" "c/d" "a/e"))
+ => '(("a" "a/b" "a/e") ("c" "c/d"))
+
+
+File: dash.info, Node: Indexing, Next: Set operations, Prev: Partitioning,
Up: Functions
+
+2.8 Indexing
+============
+
+Return indices of elements based on predicates, sort elements by
+indices etc.
+
+ -- Function: -elem-index (elem list)
+ Return the index of the first element in the given LIST which is
+ equal to the query element ELEM, or nil if there is no such
+ element.
+
+ (-elem-index 2 '(6 7 8 2 3 4))
+ => 3
+ (-elem-index "bar" '("foo" "bar" "baz"))
+ => 1
+ (-elem-index '(1 2) '((3) (5 6) (1 2) nil))
+ => 2
+
+ -- Function: -elem-indices (elem list)
+ Return the indices of all elements in LIST equal to the query
+ element ELEM, in ascending order.
+
+ (-elem-indices 2 '(6 7 8 2 3 4 2 1))
+ => '(3 6)
+ (-elem-indices "bar" '("foo" "bar" "baz"))
+ => '(1)
+ (-elem-indices '(1 2) '((3) (1 2) (5 6) (1 2) nil))
+ => '(1 3)
+
+ -- Function: -find-index (pred list)
+ Take a predicate PRED and a LIST and return the index of the
+ first element in the list satisfying the predicate, or nil if
+ there is no such element.
+
+ (-find-index 'even? '(2 4 1 6 3 3 5 8))
+ => 0
+ (--find-index (< 5 it) '(2 4 1 6 3 3 5 8))
+ => 3
+ (-find-index (-partial 'string-lessp "baz") '("bar" "foo" "baz"))
+ => 1
+
+ -- Function: -find-last-index (pred list)
+ Take a predicate PRED and a LIST and return the index of the
+ last element in the list satisfying the predicate, or nil if
+ there is no such element.
+
+ (-find-last-index 'even? '(2 4 1 6 3 3 5 8))
+ => 7
+ (--find-last-index (< 5 it) '(2 7 1 6 3 8 5 2))
+ => 5
+ (-find-last-index (-partial 'string-lessp "baz") '("q" "foo" "baz"))
+ => 1
+
+ -- Function: -find-indices (pred list)
+ Return the indices of all elements in LIST satisfying the
+ predicate PRED, in ascending order.
+
+ (-find-indices 'even? '(2 4 1 6 3 3 5 8))
+ => '(0 1 3 7)
+ (--find-indices (< 5 it) '(2 4 1 6 3 3 5 8))
+ => '(3 7)
+ (-find-indices (-partial 'string-lessp "baz") '("bar" "foo" "baz"))
+ => '(1)
+
+ -- Function: -grade-up (comparator list)
+ Grade elements of LIST using COMPARATOR relation, yielding a
+ permutation vector such that applying this permutation to LIST
+ sorts it in ascending order.
+
+ (-grade-up '< '(3 1 4 2 1 3 3))
+ => '(1 4 3 0 5 6 2)
+ (let ((l '(3 1 4 2 1 3 3))) (-select-by-indices (-grade-up '< l) l))
+ => '(1 1 2 3 3 3 4)
+
+ -- Function: -grade-down (comparator list)
+ Grade elements of LIST using COMPARATOR relation, yielding a
+ permutation vector such that applying this permutation to LIST
+ sorts it in descending order.
+
+ (-grade-down '< '(3 1 4 2 1 3 3))
+ => '(2 0 5 6 3 1 4)
+ (let ((l '(3 1 4 2 1 3 3))) (-select-by-indices (-grade-down '< l)
l))
+ => '(4 3 3 3 2 1 1)
+
+
+File: dash.info, Node: Set operations, Next: Other list operations, Prev:
Indexing, Up: Functions
+
+2.9 Set operations
+==================
+
+Operations pretending lists are sets.
+
+ -- Function: -union (list list2)
+ Return a new list containing the elements of LIST1 and elements
+ of LIST2 that are not in LIST1. The test for equality is done
+ with `equal', or with `-compare-fn' if that's non-nil.
+
+ (-union '(1 2 3) '(3 4 5))
+ => '(1 2 3 4 5)
+ (-union '(1 2 3 4) '())
+ => '(1 2 3 4)
+ (-union '(1 1 2 2) '(3 2 1))
+ => '(1 1 2 2 3)
+
+ -- Function: -difference (list list2)
+ Return a new list with only the members of LIST that are not in
+ LIST2. The test for equality is done with `equal', or with
+ `-compare-fn' if that's non-nil.
+
+ (-difference '() '())
+ => '()
+ (-difference '(1 2 3) '(4 5 6))
+ => '(1 2 3)
+ (-difference '(1 2 3 4) '(3 4 5 6))
+ => '(1 2)
+
+ -- Function: -intersection (list list2)
+ Return a new list containing only the elements that are members
+ of both LIST and LIST2. The test for equality is done with
+ `equal', or with `-compare-fn' if that's non-nil.
+
+ (-intersection '() '())
+ => '()
+ (-intersection '(1 2 3) '(4 5 6))
+ => '()
+ (-intersection '(1 2 3 4) '(3 4 5 6))
+ => '(3 4)
+
+ -- Function: -distinct (list)
+ Return a new list with all duplicates removed. The test for
+ equality is done with `equal', or with `-compare-fn' if that's
+ non-nil.
+
+ Alias: `-uniq'
+
+ (-distinct '())
+ => '()
+ (-distinct '(1 2 2 4))
+ => '(1 2 4)
+
+
+File: dash.info, Node: Other list operations, Next: Tree operations, Prev:
Set operations, Up: Functions
+
+2.10 Other list operations
+==========================
+
+Other list functions not fit to be classified elsewhere.
+
+ -- Function: -rotate (n list)
+ Rotate LIST N places to the right. With N negative, rotate to
+ the left. The time complexity is O(n).
+
+ (-rotate 3 '(1 2 3 4 5 6 7))
+ => '(5 6 7 1 2 3 4)
+ (-rotate -3 '(1 2 3 4 5 6 7))
+ => '(4 5 6 7 1 2 3)
+
+ -- Function: -repeat (n x)
+ Return a list with X repeated N times. Return nil if N is less
+ than 1.
+
+ (-repeat 3 :a)
+ => '(:a :a :a)
+ (-repeat 1 :a)
+ => '(:a)
+ (-repeat 0 :a)
+ => nil
+
+ -- Function: -cons* (&rest args)
+ Make a new list from the elements of ARGS.
+
+ The last 2 members of ARGS are used as the final cons of the
+ result so if the final member of ARGS is not a list the result is
+ a dotted list.
+
+ (-cons* 1 2)
+ => '(1 . 2)
+ (-cons* 1 2 3)
+ => '(1 2 . 3)
+ (-cons* 1)
+ => 1
+
+ -- Function: -snoc (list elem &rest elements)
+ Append ELEM to the end of the list.
+
+ This is like `cons', but operates on the end of list.
+
+ If ELEMENTS is non nil, append these to the list as well.
+
+ (-snoc '(1 2 3) 4)
+ => '(1 2 3 4)
+ (-snoc '(1 2 3) 4 5 6)
+ => '(1 2 3 4 5 6)
+ (-snoc '(1 2 3) '(4 5 6))
+ => '(1 2 3 (4 5 6))
+
+ -- Function: -interpose (sep list)
+ Return a new list of all elements in LIST separated by SEP.
+
+ (-interpose "-" '())
+ => '()
+ (-interpose "-" '("a"))
+ => '("a")
+ (-interpose "-" '("a" "b" "c"))
+ => '("a" "-" "b" "-" "c")
+
+ -- Function: -interleave (&rest lists)
+ Return a new list of the first item in each list, then the
+ second etc.
+
+ (-interleave '(1 2) '("a" "b"))
+ => '(1 "a" 2 "b")
+ (-interleave '(1 2) '("a" "b") '("A" "B"))
+ => '(1 "a" "A" 2 "b" "B")
+ (-interleave '(1 2 3) '("a" "b"))
+ => '(1 "a" 2 "b")
+
+ -- Function: -zip-with (fn list1 list2)
+ Zip the two lists LIST1 and LIST2 using a function FN. This
+ function is applied pairwise taking as first argument element of
+ LIST1 and as second argument element of LIST2 at corresponding
+ position.
+
+ The anaphoric form `--zip-with' binds the elements from LIST1 as
+ `it`, and the elements from LIST2 as `other`.
+
+ (-zip-with '+ '(1 2 3) '(4 5 6))
+ => '(5 7 9)
+ (-zip-with 'cons '(1 2 3) '(4 5 6))
+ => '((1 . 4) (2 . 5) (3 . 6))
+ (--zip-with (concat it " and " other) '("Batman" "Jekyll") '("Robin"
"Hyde"))
+ => '("Batman and Robin" "Jekyll and Hyde")
+
+ -- Function: -zip (&rest lists)
+ Zip LISTS together. Group the head of each list, followed by the
+ second elements of each list, and so on. The lengths of the
+ returned groupings are equal to the length of the shortest input
+ list.
+
+ If two lists are provided as arguments, return the groupings as
+ a list of cons cells. Otherwise, return the groupings as a list
+ of lists.
+
+ (-zip '(1 2 3) '(4 5 6))
+ => '((1 . 4) (2 . 5) (3 . 6))
+ (-zip '(1 2 3) '(4 5 6 7))
+ => '((1 . 4) (2 . 5) (3 . 6))
+ (-zip '(1 2 3 4) '(4 5 6))
+ => '((1 . 4) (2 . 5) (3 . 6))
+
+ -- Function: -zip-fill (fill-value &rest lists)
+ Zip LISTS, with FILL-VALUE padded onto the shorter lists. The
+ lengths of the returned groupings are equal to the length of the
+ longest input list.
+
+ (-zip-fill 0 '(1 2 3 4 5) '(6 7 8 9))
+ => '((1 . 6) (2 . 7) (3 . 8) (4 . 9) (5 . 0))
+
+ -- Function: -cycle (list)
+ Return an infinite copy of LIST that will cycle through the
+ elements and repeat from the beginning.
+
+ (-take 5 (-cycle '(1 2 3)))
+ => '(1 2 3 1 2)
+ (-take 7 (-cycle '(1 "and" 3)))
+ => '(1 "and" 3 1 "and" 3 1)
+ (-zip (-cycle '(1 2 3)) '(1 2))
+ => '((1 . 1) (2 . 2))
+
+ -- Function: -pad (fill-value &rest lists)
+ Appends FILL-VALUE to the end of each list in LISTS such that
+ they will all have the same length.
+
+ (-pad 0 '())
+ => '(nil)
+ (-pad 0 '(1))
+ => '((1))
+ (-pad 0 '(1 2 3) '(4 5))
+ => '((1 2 3) (4 5 0))
+
+ -- Function: -table (fn &rest lists)
+ Compute outer product of LISTS using function FN.
+
+ The function FN should have the same arity as the number of
+ supplied lists.
+
+ The outer product is computed by applying fn to all possible
+ combinations created by taking one element from each list in
+ order. The dimension of the result is (length lists).
+
+ See also: `-table-flat' (*note -table-flat::)
+
+ (-table '* '(1 2 3) '(1 2 3))
+ => '((1 2 3) (2 4 6) (3 6 9))
+ (-table (lambda (a b) (-sum (-zip-with '* a b))) '((1 2) (3 4)) '((1
3) (2 4)))
+ => '((7 15) (10 22))
+ (apply '-table 'list (-repeat 3 '(1 2)))
+ => '((((1 1 1) (2 1 1)) ((1 2 1) (2 2 1))) (((1 1 2) (2 1 2))
((1 2 2) (2 2 2))))
+
+ -- Function: -table-flat (fn &rest lists)
+ Compute flat outer product of LISTS using function FN.
+
+ The function FN should have the same arity as the number of
+ supplied lists.
+
+ The outer product is computed by applying fn to all possible
+ combinations created by taking one element from each list in
+ order. The results are flattened, ignoring the tensor structure
+ of the result. This is equivalent to calling:
+
+ (-flatten-n (1- (length lists)) (-table fn lists))
+
+ but the implementation here is much more efficient.
+
+ See also: `-flatten-n' (*note -flatten-n::), `-table' (*note
+ -table::)
+
+ (-table-flat 'list '(1 2 3) '(a b c))
+ => '((1 a) (2 a) (3 a) (1 b) (2 b) (3 b) (1 c) (2 c) (3 c))
+ (-table-flat '* '(1 2 3) '(1 2 3))
+ => '(1 2 3 2 4 6 3 6 9)
+ (apply '-table-flat 'list (-repeat 3 '(1 2)))
+ => '((1 1 1) (2 1 1) (1 2 1) (2 2 1) (1 1 2) (2 1 2) (1 2 2) (2
2 2))
+
+ -- Function: -first (pred list)
+ Return the first x in LIST where (PRED x) is non-nil, else nil.
+
+ To get the first item in the list no questions asked, use `car'.
+
+ Alias: `-find'
+
+ (-first 'even? '(1 2 3))
+ => 2
+ (-first 'even? '(1 3 5))
+ => nil
+ (--first (> it 2) '(1 2 3))
+ => 3
+
+ -- Function: -some (pred list)
+ Return (PRED x) for the first LIST item where (PRED x) is
+ non-nil, else nil.
+
+ Alias: `-any'
+
+ (-some 'even? '(1 2 3))
+ => t
+ (--some (member 'foo it) '((foo bar) (baz)))
+ => '(foo bar)
+ (--some (plist-get it :bar) '((:foo 1 :bar 2) (:baz 3)))
+ => 2
+
+ -- Function: -last (pred list)
+ Return the last x in LIST where (PRED x) is non-nil, else nil.
+
+ (-last 'even? '(1 2 3 4 5 6 3 3 3))
+ => 6
+ (-last 'even? '(1 3 7 5 9))
+ => nil
+ (--last (> (length it) 3) '("a" "looong" "word" "and" "short" "one"))
+ => "short"
+
+ -- Function: -first-item (list)
+ Return the first item of LIST, or nil on an empty list.
+
+ (-first-item '(1 2 3))
+ => 1
+ (-first-item nil)
+ => nil
+
+ -- Function: -last-item (list)
+ Return the last item of LIST, or nil on an empty list.
+
+ (-last-item '(1 2 3))
+ => 3
+ (-last-item nil)
+ => nil
+
+ -- Function: -butlast (list)
+ Return a list of all items in list except for the last.
+
+ (-butlast '(1 2 3))
+ => '(1 2)
+ (-butlast '(1 2))
+ => '(1)
+ (-butlast '(1))
+ => nil
+
+ -- Function: -sort (comparator list)
+ Sort LIST, stably, comparing elements using COMPARATOR. Return
+ the sorted list. LIST is NOT modified by side effects.
+ COMPARATOR is called with two elements of LIST, and should
+ return non-nil if the first element should sort before the
+ second.
+
+ (-sort '< '(3 1 2))
+ => '(1 2 3)
+ (-sort '> '(3 1 2))
+ => '(3 2 1)
+ (--sort (< it other) '(3 1 2))
+ => '(1 2 3)
+
+ -- Function: -list (&rest args)
+ Return a list with ARGS.
+
+ If first item of ARGS is already a list, simply return ARGS. If
+ not, return a list with ARGS as elements.
+
+ (-list 1)
+ => '(1)
+ (-list 1 2 3)
+ => '(1 2 3)
+ (-list '(1 2 3))
+ => '(1 2 3)
+
+ -- Function: -fix (fn list)
+ Compute the (least) fixpoint of FN with initial input LIST.
+
+ FN is called at least once, results are compared with `equal'.
+
+ (-fix (lambda (l) (-non-nil (--mapcat (-split-at (/ (length it) 2)
it) l))) '((1 2 3 4 5 6)))
+ => '((1) (2) (3) (4) (5) (6))
+ (let ((data '(("starwars" "scifi") ("jedi" "starwars" "warrior"))))
(--fix (-uniq (--mapcat (cons it (cdr (assoc it data))) it)) '("jedi" "book")))
+ => '("jedi" "starwars" "warrior" "scifi" "book")
+
+
+File: dash.info, Node: Tree operations, Next: Threading macros, Prev: Other
list operations, Up: Functions
+
+2.11 Tree operations
+====================
+
+Functions pretending lists are trees.
+
+ -- Function: -tree-seq (branch children tree)
+ Return a sequence of the nodes in TREE, in depth-first search
+ order.
+
+ BRANCH is a predicate of one argument that returns non-nil if the
+ passed argument is a branch, that is, a node that can have
+ children.
+
+ CHILDREN is a function of one argument that returns the children
+ of the passed branch node.
+
+ Non-branch nodes are simply copied.
+
+ (-tree-seq 'listp 'identity '(1 (2 3) 4 (5 (6 7))))
+ => '((1 (2 3) 4 (5 (6 7))) 1 (2 3) 2 3 4 (5 (6 7)) 5 (6 7) 6 7)
+ (-tree-seq 'listp 'reverse '(1 (2 3) 4 (5 (6 7))))
+ => '((1 (2 3) 4 (5 (6 7))) (5 (6 7)) (6 7) 7 6 5 4 (2 3) 3 2 1)
+ (--tree-seq (vectorp it) (append it nil) [1 [2 3] 4 [5 [6 7]]])
+ => '([1 [2 3] 4 [5 [6 7]]] 1 [2 3] 2 3 4 [5 [6 7]] 5 [6 7] 6 7)
+
+ -- Function: -tree-map (fn tree)
+ Apply FN to each element of TREE while preserving the tree
+ structure.
+
+ (-tree-map '1+ '(1 (2 3) (4 (5 6) 7)))
+ => '(2 (3 4) (5 (6 7) 8))
+ (-tree-map '(lambda (x) (cons x (expt 2 x))) '(1 (2 3) 4))
+ => '((1 . 2) ((2 . 4) (3 . 8)) (4 . 16))
+ (--tree-map (length it) '("<body>" ("<p>" "text" "</p>") "</body>"))
+ => '(6 (3 4 4) 7)
+
+ -- Function: -tree-map-nodes (pred fun tree)
+ Call FUN on each node of TREE that satisfies PRED.
+
+ If PRED returns nil, continue descending down this node. If PRED
+ returns non-nil, apply FUN to this node and do not descend
+ further.
+
+ (-tree-map-nodes 'vectorp (lambda (x) (-sum (append x nil))) '(1 [2
3] 4 (5 [6 7] 8)))
+ => '(1 5 4 (5 13 8))
+ (-tree-map-nodes 'keywordp (lambda (x) (symbol-name x)) '(1 :foo 4
((5 6 :bar) :baz 8)))
+ => '(1 ":foo" 4 ((5 6 ":bar") ":baz" 8))
+ (--tree-map-nodes (eq (car-safe it) 'add-mode) (-concat it (list
:mode 'emacs-lisp-mode)) '(with-mode emacs-lisp-mode (foo bar) (add-mode a b)
(baz (add-mode c d))))
+ => '(with-mode emacs-lisp-mode (foo bar) (add-mode a b :mode
emacs-lisp-mode) (baz (add-mode c d :mode emacs-lisp-mode)))
+
+ -- Function: -tree-reduce (fn tree)
+ Use FN to reduce elements of list TREE. If elements of TREE are
+ lists themselves, apply the reduction recursively.
+
+ FN is first applied to first element of the list and second
+ element, then on this result and third element from the list etc.
+
+ See `-reduce-r' (*note -reduce-r::) for how exactly are lists of
+ zero or one element handled.
+
+ (-tree-reduce '+ '(1 (2 3) (4 5)))
+ => 15
+ (-tree-reduce 'concat '("strings" (" on" " various") ((" levels"))))
+ => "strings on various levels"
+ (--tree-reduce (cond ((stringp it) (concat it " " acc)) (t (let ((sn
(symbol-name it))) (concat "<" sn ">" acc "</" sn ">")))) '(body (p "some
words") (div "more" (b "bold") "words")))
+ => "<body><p>some words</p> <div>more <b>bold</b>
words</div></body>"
+
+ -- Function: -tree-reduce-from (fn init-value tree)
+ Use FN to reduce elements of list TREE. If elements of TREE are
+ lists themselves, apply the reduction recursively.
+
+ FN is first applied to INIT-VALUE and first element of the list,
+ then on this result and second element from the list etc.
+
+ The initial value is ignored on cons pairs as they always contain
+ two elements.
+
+ (-tree-reduce-from '+ 1 '(1 (1 1) ((1))))
+ => 8
+ (--tree-reduce-from (-concat acc (list it)) nil '(1 (2 3 (4 5)) (6
7)))
+ => '((7 6) ((5 4) 3 2) 1)
+
+ -- Function: -tree-mapreduce (fn folder tree)
+ Apply FN to each element of TREE, and make a list of the results.
+ If elements of TREE are lists themselves, apply FN recursively to
+ elements of these nested lists.
+
+ Then reduce the resulting lists using FOLDER and initial value
+ INIT-VALUE. See `-reduce-r-from' (*note -reduce-r-from::).
+
+ This is the same as calling `-tree-reduce' (*note
+ -tree-reduce::) after `-tree-map' (*note -tree-map::) but is
+ twice as fast as it only traverse the structure once.
+
+ (-tree-mapreduce 'list 'append '(1 (2 (3 4) (5 6)) (7 (8 9))))
+ => '(1 2 3 4 5 6 7 8 9)
+ (--tree-mapreduce 1 (+ it acc) '(1 (2 (4 9) (2 1)) (7 (4 3))))
+ => 9
+ (--tree-mapreduce 0 (max acc (1+ it)) '(1 (2 (4 9) (2 1)) (7 (4 3))))
+ => 3
+
+ -- Function: -tree-mapreduce-from (fn folder init-value tree)
+ Apply FN to each element of TREE, and make a list of the results.
+ If elements of TREE are lists themselves, apply FN recursively to
+ elements of these nested lists.
+
+ Then reduce the resulting lists using FOLDER and initial value
+ INIT-VALUE. See `-reduce-r-from' (*note -reduce-r-from::).
+
+ This is the same as calling `-tree-reduce-from' (*note
+ -tree-reduce-from::) after `-tree-map' (*note -tree-map::) but
+ is twice as fast as it only traverse the structure once.
+
+ (-tree-mapreduce-from 'identity '* 1 '(1 (2 (3 4) (5 6)) (7 (8 9))))
+ => 362880
+ (--tree-mapreduce-from (+ it it) (cons it acc) nil '(1 (2 (4 9) (2
1)) (7 (4 3))))
+ => '(2 (4 (8 18) (4 2)) (14 (8 6)))
+ (concat "{" (--tree-mapreduce-from (cond ((-cons-pair? it) (concat
(symbol-name (car it)) " -> " (symbol-name (cdr it)))) (t (concat (symbol-name
it) " : {"))) (concat it (unless (or (equal acc "}") (equal (substring it (1-
(length it))) "{")) ", ") acc) "}" '((elips-mode (foo (bar . booze)) (baz .
qux)) (c-mode (foo . bla) (bum . bam)))))
+ => "{elips-mode : {foo : {bar -> booze{, baz -> qux{, c-mode :
{foo -> bla, bum -> bam}}"
+
+ -- Function: -clone (list)
+ Create a deep copy of LIST. The new list has the same elements
+ and structure but all cons are replaced with new ones. This is
+ useful when you need to clone a structure such as plist or alist.
+
+ (let* ((a '(1 2 3)) (b (-clone a))) (nreverse a) b)
+ => '(1 2 3)
+
+
+File: dash.info, Node: Threading macros, Next: Binding, Prev: Tree
operations, Up: Functions
+
+2.12 Threading macros
+=====================
+
+ -- Function: -> (x &optional form &rest more)
+ Thread the expr through the forms. Insert X as the second item
+ in the first form, making a list of it if it is not a list
+ already. If there are more forms, insert the first form as the
+ second item in second form, etc.
+
+ (-> '(2 3 5))
+ => '(2 3 5)
+ (-> '(2 3 5) (append '(8 13)))
+ => '(2 3 5 8 13)
+ (-> '(2 3 5) (append '(8 13)) (-slice 1 -1))
+ => '(3 5 8)
+
+ -- Function: ->> (x form &rest more)
+ Thread the expr through the forms. Insert X as the last item in
+ the first form, making a list of it if it is not a list already.
+ If there are more forms, insert the first form as the last item
+ in second form, etc.
+
+ (->> '(1 2 3) (-map 'square))
+ => '(1 4 9)
+ (->> '(1 2 3) (-map 'square) (-remove 'even?))
+ => '(1 9)
+ (->> '(1 2 3) (-map 'square) (-reduce '+))
+ => 14
+
+ -- Function: -> (x form &rest more)
+ Thread the expr through the forms. Insert X at the position
+ signified by the token `it' in the first form. If there are more
+ forms, insert the first form at the position signified by `it' in
+ in second form, etc.
+
+ (--> "def" (concat "abc" it "ghi"))
+ => "abcdefghi"
+ (--> "def" (concat "abc" it "ghi") (upcase it))
+ => "ABCDEFGHI"
+ (--> "def" (concat "abc" it "ghi") upcase)
+ => "ABCDEFGHI"
+
+
+File: dash.info, Node: Binding, Next: Side-effects, Prev: Threading macros,
Up: Functions
+
+2.13 Binding
+============
+
+Convenient versions of `let` and `let*` constructs combined with flow
+control.
+
+ -- Function: -when-let (var-val &rest body)
+ If VAL evaluates to non-nil, bind it to VAR and execute body.
+ VAR-VAL should be a (VAR VAL) pair.
+
+ Note: binding is done according to `-let' (*note -let::).
+
+ (-when-let (match-index (string-match "d" "abcd")) (+ match-index 2))
+ => 5
+ (-when-let ((&plist :foo foo) (list :foo "foo")) foo)
+ => "foo"
+ (-when-let ((&plist :foo foo) (list :bar "bar")) foo)
+ => nil
+
+ -- Function: -when-let* (vars-vals &rest body)
+ If all VALS evaluate to true, bind them to their corresponding
+ VARS and execute body. VARS-VALS should be a list of (VAR VAL)
+ pairs.
+
+ Note: binding is done according to `-let*' (*note -let*::).
+
+ (-when-let* ((x 5) (y 3) (z (+ y 4))) (+ x y z))
+ => 15
+ (-when-let* ((x 5) (y nil) (z 7)) (+ x y z))
+ => nil
+
+ -- Function: -if-let (var-val then &rest else)
+ If VAL evaluates to non-nil, bind it to VAR and do THEN,
+ otherwise do ELSE. VAR-VAL should be a (VAR VAL) pair.
+
+ Note: binding is done according to `-let' (*note -let::).
+
+ (-if-let (match-index (string-match "d" "abc")) (+ match-index 3) 7)
+ => 7
+ (--if-let (even? 4) it nil)
+ => t
+
+ -- Function: -if-let* (vars-vals then &rest else)
+ If all VALS evaluate to true, bind them to their corresponding
+ VARS and do THEN, otherwise do ELSE. VARS-VALS should be a list
+ of (VAR VAL) pairs.
+
+ Note: binding is done according to `-let*' (*note -let*::).
+
+ (-if-let* ((x 5) (y 3) (z 7)) (+ x y z) "foo")
+ => 15
+ (-if-let* ((x 5) (y nil) (z 7)) (+ x y z) "foo")
+ => "foo"
+ (-if-let* (((_ _ x) '(nil nil 7))) x)
+ => 7
+
+ -- Function: -let (varlist &rest body)
+ Bind variables according to VARLIST then eval BODY.
+
+ VARLIST is a list of lists of the form (PATTERN SOURCE). Each
+ PATTERN is matched against the SOURCE "structurally". SOURCE is
+ only evaluated once for each PATTERN. Each PATTERN is matched
+ recursively, and can therefore contain sub-patterns which are
+ matched against corresponding sub-expressions of SOURCE.
+
+ All the SOURCEs are evalled before any symbols are bound (i.e.
+ "in parallel").
+
+ If VARLIST only contains one (PATTERN SOURCE) element, you can
+ optionally specify it using a vector and discarding the
+ outer-most parens. Thus
+
+ (-let ((PATTERN SOURCE)) ..)
+
+ becomes
+
+ (-let [PATTERN SOURCE] ..).
+
+ `-let' (*note -let::) uses a convention of not binding places
+ (symbols) starting with _ whenever it's possible. You can use
+ this to skip over entries you don't care about. However, this
+ is not *always* possible (as a result of implementation) and
+ these symbols might get bound to undefined values.
+
+ Following is the overview of supported patterns. Remember that
+ patterns can be matched recursively, so every a, b, aK in the
+ following can be a matching construct and not necessarily a
+ symbol/variable.
+
+ Symbol:
+
+ a - bind the SOURCE to A. This is just like regular `let'.
+
+ Conses and lists:
+
+ (a) - bind `car' of cons/list to A
+
+ (a . b) - bind car of cons to A and `cdr' to B
+
+ (a b) - bind car of list to A and `cadr' to B
+
+ (a1 a2 a3 ...) - bind 0th car of list to A1, 1st to A2, 2nd to
+ A3 ...
+
+ (a1 a2 a3 ... aN . rest) - as above, but bind the Nth cdr to
+ REST.
+
+ Vectors:
+
+ [a] - bind 0th element of a non-list sequence to A (works with
+ vectors, strings, bit arrays...)
+
+ [a1 a2 a3 ...] - bind 0th element of non-list sequence to A0,
+ 1st to A1, 2nd to A2, ...
+ If the PATTERN is shorter than SOURCE, the values at
+ places not in PATTERN are ignored.
+ If the PATTERN is longer than SOURCE, an `error' is
+ thrown.
+
+ [a1 a2 a3 ... &rest rest] ) - as above, but bind the rest of
+ the sequence to REST. This is
+ conceptually the same as improper
+ list matching (a1 a2 ... aN .
+ rest)
+
+ Key/value stores:
+
+ (&plist key0 a0 ... keyN aN) - bind value mapped by keyK in the
+ SOURCE plist to aK. If the
+ value is not found, aK is nil.
+
+ (&alist key0 a0 ... keyN aN) - bind value mapped by keyK in the
+ SOURCE alist to aK. If the
+ value is not found, aK is nil.
+
+ (&hash key0 a0 ... keyN aN) - bind value mapped by keyK in the
+ SOURCE hash table to aK. If the
+ value is not found, aK is nil.
+
+ Further, special keyword &keys supports "inline" matching of
+ plist-like key-value pairs, similarly to &keys keyword of
+ `cl-defun'.
+
+ (a1 a2 ... aN &keys key1 b1 ... keyN bK)
+
+ This binds N values from the list to a1 ... aN, then interprets
+ the cdr as a plist (see key/value matching above).
+
+ (-let (([a (b c) d] [1 (2 3) 4])) (list a b c d))
+ => '(1 2 3 4)
+ (-let [(a b c . d) (list 1 2 3 4 5 6)] (list a b c d))
+ => '(1 2 3 (4 5 6))
+ (-let [(&plist :foo foo :bar bar) (list :baz 3 :foo 1 :qux 4 :bar
2)] (list foo bar))
+ => '(1 2)
+
+ -- Function: -let* (varlist &rest body)
+ Bind variables according to VARLIST then eval BODY.
+
+ VARLIST is a list of lists of the form (PATTERN SOURCE). Each
+ PATTERN is matched against the SOURCE structurally. SOURCE is
+ only evaluated once for each PATTERN.
+
+ Each SOURCE can refer to the symbols already bound by this
+ VARLIST. This is useful if you want to destructure SOURCE
+ recursively but also want to name the intermediate structures.
+
+ See `-let' (*note -let::) for the list of all possible patterns.
+
+ (-let* (((a . b) (cons 1 2)) ((c . d) (cons 3 4))) (list a b c d))
+ => '(1 2 3 4)
+ (-let* (((a . b) (cons 1 (cons 2 3))) ((c . d) b)) (list a b c d))
+ => '(1 (2 . 3) 2 3)
+ (-let* (((&alist "foo" foo "bar" bar) (list (cons "foo" 1) (cons
"bar" (list 'a 'b 'c)))) ((a b c) bar)) (list foo a b c bar))
+ => '(1 a b c (a b c))
+
+ -- Function: -lambda (match-form &rest body)
+ Return a lambda which destructures its input as MATCH-FORM and
+ executes BODY.
+
+ Note that you have to enclose the MATCH-FORM in a pair of parens,
+ such that:
+
+ (-lambda (x) body) (-lambda (x y ...) body)
+
+ has the usual semantics of `lambda'. Furthermore, these get
+ translated into normal lambda, so there is no performance
+ penalty.
+
+ See `-let' (*note -let::) for the description of destructuring
+ mechanism.
+
+ (-map (-lambda ((x y)) (+ x y)) '((1 2) (3 4) (5 6)))
+ => '(3 7 11)
+ (-map (-lambda ([x y]) (+ x y)) '([1 2] [3 4] [5 6]))
+ => '(3 7 11)
+ (funcall (-lambda ((_ . a) (_ . b)) (-concat a b)) '(1 2 3) '(4 5 6))
+ => '(2 3 5 6)
+
+
+File: dash.info, Node: Side-effects, Next: Destructive operations, Prev:
Binding, Up: Functions
+
+2.14 Side-effects
+=================
+
+Functions iterating over lists for side-effect only.
+
+ -- Function: -each (list fn)
+ Call FN with every item in LIST. Return nil, used for
+ side-effects only.
+
+ (let (s) (-each '(1 2 3) (lambda (item) (setq s (cons item s)))))
+ => nil
+ (let (s) (-each '(1 2 3) (lambda (item) (setq s (cons item s)))) s)
+ => '(3 2 1)
+ (let (s) (--each '(1 2 3) (setq s (cons it s))) s)
+ => '(3 2 1)
+
+ -- Function: -each-while (list pred fn)
+ Call FN with every item in LIST while (PRED item) is non-nil.
+ Return nil, used for side-effects only.
+
+ (let (s) (-each-while '(2 4 5 6) 'even? (lambda (item) (!cons item
s))) s)
+ => '(4 2)
+ (let (s) (--each-while '(1 2 3 4) (< it 3) (!cons it s)) s)
+ => '(2 1)
+
+ -- Function: -dotimes (num fn)
+ Repeatedly calls FN (presumably for side-effects) passing in
+ integers from 0 through NUM-1.
+
+ (let (s) (-dotimes 3 (lambda (n) (!cons n s))) s)
+ => '(2 1 0)
+ (let (s) (--dotimes 5 (!cons it s)) s)
+ => '(4 3 2 1 0)
+
+
+File: dash.info, Node: Destructive operations, Next: Function combinators,
Prev: Side-effects, Up: Functions
+
+2.15 Destructive operations
+===========================
+
+ -- Function: !cons (car cdr)
+ Destructive: Set CDR to the cons of CAR and CDR.
+
+ (let (l) (!cons 5 l) l)
+ => '(5)
+ (let ((l '(3))) (!cons 5 l) l)
+ => '(5 3)
+
+ -- Function: !cdr (list)
+ Destructive: Set LIST to the cdr of LIST.
+
+ (let ((l '(3))) (!cdr l) l)
+ => '()
+ (let ((l '(3 5))) (!cdr l) l)
+ => '(5)
+
+
+File: dash.info, Node: Function combinators, Prev: Destructive operations,
Up: Functions
+
+2.16 Function combinators
+=========================
+
+These combinators require Emacs 24 for its lexical scope. So they are
+offered in a separate package: `dash-functional`.
+
+ -- Function: -partial (fn &rest args)
+ Takes a function FN and fewer than the normal arguments to FN,
+ and returns a fn that takes a variable number of additional ARGS.
+ When called, the returned function calls FN with ARGS first and
+ then additional args.
+
+ (funcall (-partial '- 5) 3)
+ => 2
+ (funcall (-partial '+ 5 2) 3)
+ => 10
+
+ -- Function: -rpartial (fn &rest args)
+ Takes a function FN and fewer than the normal arguments to FN,
+ and returns a fn that takes a variable number of additional ARGS.
+ When called, the returned function calls FN with the additional
+ args first and then ARGS.
+
+ (funcall (-rpartial '- 5) 8)
+ => 3
+ (funcall (-rpartial '- 5 2) 10)
+ => 3
+
+ -- Function: -juxt (&rest fns)
+ Takes a list of functions and returns a fn that is the
+ juxtaposition of those fns. The returned fn takes a variable
+ number of args, and returns a list containing the result of
+ applying each fn to the args (left-to-right).
+
+ (funcall (-juxt '+ '-) 3 5)
+ => '(8 -2)
+ (-map (-juxt 'identity 'square) '(1 2 3))
+ => '((1 1) (2 4) (3 9))
+
+ -- Function: -compose (&rest fns)
+ Takes a list of functions and returns a fn that is the
+ composition of those fns. The returned fn takes a variable
+ number of arguments, and returns the result of applying each fn
+ to the result of applying the previous fn to the arguments
+ (right-to-left).
+
+ (funcall (-compose 'square '+) 2 3)
+ => (square (+ 2 3))
+ (funcall (-compose 'identity 'square) 3)
+ => (square 3)
+ (funcall (-compose 'square 'identity) 3)
+ => (square 3)
+
+ -- Function: -applify (fn)
+ Changes an n-arity function FN to a 1-arity function that
+ expects a list with n items as arguments
+
+ (-map (-applify '+) '((1 1 1) (1 2 3) (5 5 5)))
+ => '(3 6 15)
+ (-map (-applify (lambda (a b c) (\` ((\, a) ((\, b) ((\, c)))))))
'((1 1 1) (1 2 3) (5 5 5)))
+ => '((1 (1 (1))) (1 (2 (3))) (5 (5 (5))))
+ (funcall (-applify '<) '(3 6))
+ => t
+
+ -- Function: -on (operator transformer)
+ Return a function of two arguments that first applies
+ TRANSFORMER to each of them and then applies OPERATOR on the
+ results (in the same order).
+
+ In types: (b -> b -> c) -> (a -> b) -> a -> a -> c
+
+ (-sort (-on '< 'length) '((1 2 3) (1) (1 2)))
+ => '((1) (1 2) (1 2 3))
+ (-min-by (-on '> 'length) '((1 2 3) (4) (1 2)))
+ => '(4)
+ (-min-by (-on 'string-lessp 'int-to-string) '(2 100 22))
+ => 22
+
+ -- Function: -flip (func)
+ Swap the order of arguments for binary function FUNC.
+
+ In types: (a -> b -> c) -> b -> a -> c
+
+ (funcall (-flip '<) 2 1)
+ => t
+ (funcall (-flip '-) 3 8)
+ => 5
+ (-sort (-flip '<) '(4 3 6 1))
+ => '(6 4 3 1)
+
+ -- Function: -const (c)
+ Return a function that returns C ignoring any additional
+ arguments.
+
+ In types: a -> b -> a
+
+ (funcall (-const 2) 1 3 "foo")
+ => 2
+ (-map (-const 1) '("a" "b" "c" "d"))
+ => '(1 1 1 1)
+ (-sum (-map (-const 1) '("a" "b" "c" "d")))
+ => 4
+
+ -- Function: -cut (&rest params)
+ Take n-ary function and n arguments and specialize some of them.
+ Arguments denoted by <> will be left unspecialized.
+
+ See SRFI-26 for detailed description.
+
+ (funcall (-cut list 1 <> 3 <> 5) 2 4)
+ => '(1 2 3 4 5)
+ (-map (-cut funcall <> 5) '(1+ 1- (lambda (x) (/ 1.0 x))))
+ => '(6 4 0.2)
+ (-filter (-cut < <> 5) '(1 3 5 7 9))
+ => '(1 3)
+
+ -- Function: -not (pred)
+ Take an unary predicates PRED and return an unary predicate that
+ returns t if PRED returns nil and nil if PRED returns non-nil.
+
+ (funcall (-not 'even?) 5)
+ => t
+ (-filter (-not (-partial '< 4)) '(1 2 3 4 5 6 7 8))
+ => '(1 2 3 4)
+
+ -- Function: -orfn (&rest preds)
+ Take list of unary predicates PREDS and return an unary
+ predicate with argument x that returns non-nil if at least one of
+ the PREDS returns non-nil on x.
+
+ In types: [a -> Bool] -> a -> Bool
+
+ (-filter (-orfn 'even? (-partial (-flip '<) 5)) '(1 2 3 4 5 6 7 8 9
10))
+ => '(1 2 3 4 6 8 10)
+ (funcall (-orfn 'stringp 'even?) "foo")
+ => t
+
+ -- Function: -andfn (&rest preds)
+ Take list of unary predicates PREDS and return an unary
+ predicate with argument x that returns non-nil if all of the
+ PREDS returns non-nil on x.
+
+ In types: [a -> Bool] -> a -> Bool
+
+ (funcall (-andfn (-cut < <> 10) 'even?) 6)
+ => t
+ (funcall (-andfn (-cut < <> 10) 'even?) 12)
+ => nil
+ (-filter (-andfn (-not 'even?) (-cut >= 5 <>)) '(1 2 3 4 5 6 7 8 9
10))
+ => '(1 3 5)
+
+ -- Function: -iteratefn (fn n)
+ Return a function FN composed N times with itself.
+
+ FN is a unary function. If you need to use a function of higher
+ arity, use `-applify' (*note -applify::) first to turn it into
+ an unary function.
+
+ With n = 0, this acts as identity function.
+
+ In types: (a -> a) -> Int -> a -> a.
+
+ This function satisfies the following law:
+
+ (funcall (-iteratefn fn n) init) = (-last-item (-iterate fn init
+ (1+ n))).
+
+ (funcall (-iteratefn (lambda (x) (* x x)) 3) 2)
+ => 256
+ (funcall (-iteratefn '1+ 3) 1)
+ => 4
+ (funcall (-iteratefn 'cdr 3) '(1 2 3 4 5))
+ => '(4 5)
+
+ -- Function: -fixfn (fn &optional equal-test halt-test)
+ Return a function that computes the (least) fixpoint of FN.
+
+ FN must be a unary function. The returned lambda takes a single
+ argument, X, the initial value for the fixpoint iteration. The
+ iteration halts when either of the following conditions is
+ satisified:
+
+ 1. Iteration converges to the fixpoint, with equality being
+ tested using EQUAL-TEST. If EQUAL-TEST is not specified,
+ `equal' is used. For functions over the floating point
+ numbers, it may be necessary to provide an appropriate
+ appoximate comparsion test.
+
+ 2. HALT-TEST returns a non-nil value. HALT-TEST defaults to a
+ simple counter that returns t after `-fixfn-max-iterations',
+ to guard against infinite iteration. Otherwise, HALT-TEST
+ must be a function that accepts a single argument, the
+ current value of X, and returns non-nil as long as iteration
+ should continue. In this way, a more sophisticated
+ convergence test may be supplied by the caller.
+
+ The return value of the lambda is either the fixpoint or, if
+ iteration halted before converging, a cons with car `halted' and
+ cdr the final output from HALT-TEST.
+
+ In types: (a -> a) -> a -> a.
+
+ (funcall (-fixfn 'cos 'approx-equal) 0.7)
+ => 0.7390851332151607
+ (funcall (-fixfn (lambda (x) (expt (+ x 10) 0.25))) 2.0)
+ => 1.8555845286409378
+ (funcall (-fixfn 'sin 'approx-equal) 0.1)
+ => '(halted . t)
+
+ -- Function: -prodfn (&rest fns)
+ Take a list of n functions and return a function that takes a
+ list of length n, applying i-th function to i-th element of the
+ input list. Returns a list of length n.
+
+ In types (for n=2): ((a -> b), (c -> d)) -> (a, c) -> (b, d)
+
+ This function satisfies the following laws:
+
+ (-compose (-prodfn f g ...) (-prodfn f' g' ...)) = (-prodfn
+ (-compose f f') (-compose g g') ...) (-prodfn f g ...) =
+ (-juxt (-compose f (-partial 'nth 0)) (-compose g (-partial 'nth
+ 1)) ...) (-compose (-prodfn f g ...) (-juxt f' g' ...)) =
+ (-juxt (-compose f f') (-compose g g') ...) (-compose
+ (-partial 'nth n) (-prod f1 f2 ...)) = (-compose fn (-partial
+ 'nth n))
+
+ (funcall (-prodfn '1+ '1- 'int-to-string) '(1 2 3))
+ => '(2 1 "3")
+ (-map (-prodfn '1+ '1-) '((1 2) (3 4) (5 6) (7 8)))
+ => '((2 1) (4 3) (6 5) (8 7))
+ (apply '+ (funcall (-prodfn 'length 'string-to-int) '((1 2 3) "15")))
+ => 18
+
+
+File: dash.info, Node: Development, Next: Index, Prev: Functions, Up: Top
+
+3 Development
+*************
+
+The dash repository is hosted on GitHub:
+`https://github.com/magnars/dash.el'
+
+* Menu:
+
+* Contribute:: How to contribute
+* Changes:: List of significant changes by version
+* Contributors:: List of contributors
+
+
+File: dash.info, Node: Contribute, Next: Changes, Up: Development
+
+3.1 Contribute
+==============
+
+Yes, please do. Pure functions in the list manipulation realm only,
+please. There's a suite of tests in dev/examples.el, so remember to
+add tests for your function, or it might get broken later.
+
+ Run the tests with `./run-tests.sh'. Create the docs with
+`./create-docs.sh'. I highly recommend that you install these as a
+pre-commit hook, so that the tests are always running and the docs are
+always in sync:
+
+
+cp pre-commit.sh .git/hooks/pre-commit
+
+ Oh, and don't edit `README.md' directly, it is auto-generated.
+Change `readme-template.md' or `examples-to-docs.el' instead. The
+same goes for the info manual.
+
+
+File: dash.info, Node: Changes, Next: Contributors, Prev: Contribute, Up:
Development
+
+3.2 Changes
+===========
+
+Changes in 2.10:
+
+ * Add `-let' destructuring to `-if-let' and `-when-let' (Fredrik
+ Bergroth)
+
+Changes in 2.9:
+
+ * Add `-let', `-let*' and `-lambda' with destructuring
+
+ * Add `-tree-seq' and `-tree-map-nodes'
+
+ * Add `-non-nil'
+
+ * Add `-fix'
+
+ * Add `-fixfn' (dash-functional 1.2)
+
+ * Add `-copy' (Wilfred Hughes)
+
+Changes in 2.8:
+
+ * Add `-butlast'
+
+Changes in 2.7:
+
+ * `-zip' now supports more than two lists (Steve Lamb)
+
+ * Add `-cycle', `-pad', `-annotate', `-zip-fill' (Steve Lamb)
+
+ * Add `-table', `-table-flat' (finite cartesian product)
+
+ * Add `-flatten-n'
+
+ * `-slice' now supports "step" argument
+
+ * Add functional combinators `-iteratefn', `-prodfn'
+
+ * Add `-replace', `-splice', `-splice-list' which generalize
+ `-replace-at' and `-insert-at'
+
+ * Add `-compose', `-iteratefn' and `-prodfn' (dash-functional 1.1)
+
+Changes in 2.6:
+
+ * Add `-is-prefix-p', `-is-suffix-p', `-is-infix-p' (Matus Goljer)
+
+ * Add `-iterate', `-unfold' (Matus Goljer)
+
+ * Add `-split-on', `-split-when' (Matus Goljer)
+
+ * Add `-find-last-index' (Matus Goljer)
+
+ * Add `-list' (Johan Andersson)
+
+Changes in 2.5:
+
+ * Add `-same-items?' (Johan Andersson)
+
+ * A few bugfixes
+
+Changes in 2.4:
+
+ * Add `-snoc' (Matus Goljer)
+
+ * Add `-replace-at', `-update-at', `-remove-at', and
+ `-remove-at-indices' (Matus Goljer)
+
+Changes in 2.3:
+
+ * Add tree operations (Matus Goljer)
+
+ * Make font-lock optional
+
+Changes in 2.2:
+
+ * Add `-compose' (Christina Whyte)
+
+Changes in 2.1:
+
+ * Add indexing operations (Matus Goljer)
+
+Changes in 2.0:
+
+ * Split out `dash-functional.el' (Matus Goljer)
+
+ * Add `-andfn', `-orfn', `-not', `-cut', `-const', `-flip' and
+ `-on'. (Matus Goljer)
+
+ * Fix `-min', `-max', `-min-by' and `-max-by' (Matus Goljer)
+
+Changes in 1.8:
+
+ * Add `-first-item' and `-last-item' (Wilfred Hughes)
+
+Changes in 1.7:
+
+ * Add `-rotate' (Matus Goljer)
+
+Changes in 1.6:
+
+ * Add `-min', `-max', `-min-by' and `-max-by' (Johan Andersson)
+
+Changes in 1.5:
+
+ * Add `-sum' and `-product' (Johan Andersson)
+
+Changes in 1.4:
+
+ * Add `-sort'
+
+ * Add `-reduce-r' (Matus Goljer)
+
+ * Add `-reduce-r-from' (Matus Goljer)
+
+Changes in 1.3:
+
+ * Add `-partition-in-steps'
+
+ * Add `-partition-all-in-steps'
+
+Changes in 1.2:
+
+ * Add `-last' (Matus Goljer)
+
+ * Add `-insert-at' (Emanuel Evans)
+
+ * Add `-when-let' and `-if-let' (Emanuel Evans)
+
+ * Add `-when-let*' and `-if-let*' (Emanuel Evans)
+
+ * Some bugfixes
+
+
+File: dash.info, Node: Contributors, Prev: Changes, Up: Development
+
+3.3 Contributors
+================
+
+ * Matus Goljer (https://github.com/Fuco1) contributed lots of
+ features and functions.
+
+ * Takafumi Arakaki (https://github.com/tkf) contributed
+ `-group-by'.
+
+ * tali713 (https://github.com/tali713) is the author of `-applify'.
+
+ * Víctor M. Valenzuela (https://github.com/vemv) contributed
+ `-repeat'.
+
+ * Nic Ferrier (https://github.com/nicferrier) contributed `-cons*'.
+
+ * Wilfred Hughes (https://github.com/Wilfred) contributed
+ `-slice', `-first-item' and `-last-item'.
+
+ * Emanuel Evans (https://github.com/shosti) contributed `-if-let',
+ `-when-let' and `-insert-at'.
+
+ * Johan Andersson (https://github.com/rejeep) contributed `-sum',
+ `-product' and `-same-items?'
+
+ * Christina Whyte (https://github.com/kurisuwhyte) contributed
+ `-compose'
+
+ * Steve Lamb (https://github.com/steventlamb) contributed
+ `-cycle', `-pad', `-annotate', `-zip-fill' and an n-ary version
+ of `-zip'.
+
+ * Fredrik Bergroth (https://github.com/fbergroth) made the
+ `-if-let' family use `-let' destructuring and improved script
+ for generating documentation.
+
+ * Mark Oteiza (https://github.com/holomorph) contributed the
+ script to create an info manual.
+
+ Thanks!
+
+
+File: dash.info, Node: Index, Prev: Development, Up: Top
+
+Index
+*****
+
+ [index ]
+* Menu:
+
+* !cdr: Destructive operations.
+ (line 15)
+* !cons: Destructive operations.
+ (line 7)
+* -->: Threading macros. (line 33)
+* ->: Threading macros. (line 7)
+* ->>: Threading macros. (line 20)
+* -all?: Predicates. (line 19)
+* -andfn: Function combinators.
+ (line 141)
+* -annotate: Maps. (line 51)
+* -any?: Predicates. (line 7)
+* -applify: Function combinators.
+ (line 57)
+* -butlast: Other list operations.
+ (line 238)
+* -clone: Tree operations. (line 124)
+* -compose: Function combinators.
+ (line 43)
+* -concat: List to list. (line 20)
+* -cons*: Other list operations.
+ (line 29)
+* -const: Function combinators.
+ (line 94)
+* -contains?: Predicates. (line 58)
+* -copy: Maps. (line 104)
+* -count: Reductions. (line 79)
+* -cut: Function combinators.
+ (line 107)
+* -cycle: Other list operations.
+ (line 119)
+* -difference: Set operations. (line 21)
+* -distinct: Set operations. (line 45)
+* -dotimes: Side-effects. (line 29)
+* -drop: Sublist selection. (line 66)
+* -drop-while: Sublist selection. (line 85)
+* -each: Side-effects. (line 9)
+* -each-while: Side-effects. (line 20)
+* -elem-index: Indexing. (line 10)
+* -elem-indices: Indexing. (line 22)
+* -filter: Sublist selection. (line 9)
+* -find-index: Indexing. (line 33)
+* -find-indices: Indexing. (line 57)
+* -find-last-index: Indexing. (line 45)
+* -first: Other list operations.
+ (line 185)
+* -first-item: Other list operations.
+ (line 222)
+* -fix: Other list operations.
+ (line 275)
+* -fixfn: Function combinators.
+ (line 178)
+* -flatten: List to list. (line 31)
+* -flatten-n: List to list. (line 44)
+* -flip: Function combinators.
+ (line 82)
+* -grade-down: Indexing. (line 78)
+* -grade-up: Indexing. (line 68)
+* -group-by: Partitioning. (line 146)
+* -if-let: Binding. (line 35)
+* -if-let*: Binding. (line 46)
+* -insert-at: List to list. (line 70)
+* -interleave: Other list operations.
+ (line 67)
+* -interpose: Other list operations.
+ (line 57)
+* -intersection: Set operations. (line 33)
+* -is-infix?: Predicates. (line 111)
+* -is-prefix?: Predicates. (line 87)
+* -is-suffix?: Predicates. (line 99)
+* -iterate: Unfolding. (line 10)
+* -iteratefn: Function combinators.
+ (line 155)
+* -juxt: Function combinators.
+ (line 32)
+* -keep: List to list. (line 9)
+* -lambda: Binding. (line 179)
+* -last: Other list operations.
+ (line 212)
+* -last-item: Other list operations.
+ (line 230)
+* -let: Binding. (line 60)
+* -let*: Binding. (line 159)
+* -list: Other list operations.
+ (line 262)
+* -map: Maps. (line 11)
+* -map-indexed: Maps. (line 39)
+* -map-when: Maps. (line 22)
+* -mapcat: Maps. (line 93)
+* -max: Reductions. (line 131)
+* -max-by: Reductions. (line 141)
+* -min: Reductions. (line 107)
+* -min-by: Reductions. (line 117)
+* -non-nil: Sublist selection. (line 35)
+* -none?: Predicates. (line 31)
+* -not: Function combinators.
+ (line 120)
+* -on: Function combinators.
+ (line 68)
+* -only-some?: Predicates. (line 43)
+* -orfn: Function combinators.
+ (line 129)
+* -pad: Other list operations.
+ (line 130)
+* -partial: Function combinators.
+ (line 10)
+* -partition: Partitioning. (line 75)
+* -partition-all: Partitioning. (line 87)
+* -partition-all-in-steps: Partitioning. (line 110)
+* -partition-by: Partitioning. (line 122)
+* -partition-by-header: Partitioning. (line 133)
+* -partition-in-steps: Partitioning. (line 98)
+* -prodfn: Function combinators.
+ (line 213)
+* -product: Reductions. (line 97)
+* -reduce: Reductions. (line 41)
+* -reduce-from: Reductions. (line 9)
+* -reduce-r: Reductions. (line 58)
+* -reduce-r-from: Reductions. (line 25)
+* -remove: Sublist selection. (line 22)
+* -remove-at: List to list. (line 107)
+* -remove-at-indices: List to list. (line 120)
+* -repeat: Other list operations.
+ (line 18)
+* -replace: List to list. (line 56)
+* -replace-at: List to list. (line 81)
+* -rotate: Other list operations.
+ (line 9)
+* -rpartial: Function combinators.
+ (line 21)
+* -same-items?: Predicates. (line 73)
+* -select-by-indices: Sublist selection. (line 96)
+* -separate: Partitioning. (line 64)
+* -slice: Sublist selection. (line 41)
+* -snoc: Other list operations.
+ (line 43)
+* -some: Other list operations.
+ (line 199)
+* -sort: Other list operations.
+ (line 248)
+* -splice: Maps. (line 62)
+* -splice-list: Maps. (line 82)
+* -split-at: Partitioning. (line 9)
+* -split-on: Partitioning. (line 29)
+* -split-when: Partitioning. (line 47)
+* -split-with: Partitioning. (line 18)
+* -sum: Reductions. (line 87)
+* -table: Other list operations.
+ (line 141)
+* -table-flat: Other list operations.
+ (line 160)
+* -take: Sublist selection. (line 57)
+* -take-while: Sublist selection. (line 74)
+* -tree-map: Tree operations. (line 29)
+* -tree-map-nodes: Tree operations. (line 40)
+* -tree-mapreduce: Tree operations. (line 86)
+* -tree-mapreduce-from: Tree operations. (line 105)
+* -tree-reduce: Tree operations. (line 54)
+* -tree-reduce-from: Tree operations. (line 71)
+* -tree-seq: Tree operations. (line 9)
+* -unfold: Unfolding. (line 26)
+* -union: Set operations. (line 9)
+* -update-at: List to list. (line 94)
+* -when-let: Binding. (line 10)
+* -when-let*: Binding. (line 23)
+* -zip: Other list operations.
+ (line 94)
+* -zip-fill: Other list operations.
+ (line 111)
+* -zip-with: Other list operations.
+ (line 78)
+
+
+
+Tag Table:
+Node: Top947
+Node: Installation2423
+Node: Using in a package2992
+Node: Syntax highlighting of dash functions3356
+Node: Functions3740
+Node: Maps4941
+Ref: -map5237
+Ref: -map-when5575
+Ref: -map-indexed6149
+Ref: -annotate6551
+Ref: -splice7038
+Ref: -splice-list7804
+Ref: -mapcat8164
+Ref: -copy8537
+Node: Sublist selection8723
+Ref: -filter8916
+Ref: -remove9283
+Ref: -non-nil9638
+Ref: -slice9796
+Ref: -take10325
+Ref: -drop10577
+Ref: -take-while10776
+Ref: -drop-while11123
+Ref: -select-by-indices11476
+Node: List to list11983
+Ref: -keep12170
+Ref: -concat12558
+Ref: -flatten12852
+Ref: -flatten-n13204
+Ref: -replace13584
+Ref: -insert-at14036
+Ref: -replace-at14353
+Ref: -update-at14741
+Ref: -remove-at15221
+Ref: -remove-at-indices15698
+Node: Reductions16265
+Ref: -reduce-from16434
+Ref: -reduce-r-from17111
+Ref: -reduce17798
+Ref: -reduce-r18486
+Ref: -count19298
+Ref: -sum19520
+Ref: -product19706
+Ref: -min19912
+Ref: -min-by20135
+Ref: -max20651
+Ref: -max-by20873
+Node: Unfolding21394
+Ref: -iterate21633
+Ref: -unfold22075
+Node: Predicates22866
+Ref: -any?22990
+Ref: -all?23303
+Ref: -none?23618
+Ref: -only-some?23913
+Ref: -contains?24383
+Ref: -same-items?24755
+Ref: -is-prefix?25133
+Ref: -is-suffix?25449
+Ref: -is-infix?25765
+Node: Partitioning26112
+Ref: -split-at26300
+Ref: -split-with26583
+Ref: -split-on26983
+Ref: -split-when27647
+Ref: -separate28276
+Ref: -partition28715
+Ref: -partition-all29164
+Ref: -partition-in-steps29589
+Ref: -partition-all-in-steps30083
+Ref: -partition-by30565
+Ref: -partition-by-header30944
+Ref: -group-by31544
+Node: Indexing31974
+Ref: -elem-index32176
+Ref: -elem-indices32568
+Ref: -find-index32948
+Ref: -find-last-index33388
+Ref: -find-indices33845
+Ref: -grade-up34250
+Ref: -grade-down34651
+Node: Set operations35059
+Ref: -union35242
+Ref: -difference35673
+Ref: -intersection36077
+Ref: -distinct36501
+Node: Other list operations36809
+Ref: -rotate37034
+Ref: -repeat37327
+Ref: -cons*37587
+Ref: -snoc37971
+Ref: -interpose38377
+Ref: -interleave38672
+Ref: -zip-with39038
+Ref: -zip39726
+Ref: -zip-fill40373
+Ref: -cycle40694
+Ref: -pad41064
+Ref: -table41384
+Ref: -table-flat42167
+Ref: -first43156
+Ref: -some43519
+Ref: -last43882
+Ref: -first-item44213
+Ref: -last-item44410
+Ref: -butlast44603
+Ref: -sort44847
+Ref: -list45337
+Ref: -fix45665
+Node: Tree operations46199
+Ref: -tree-seq46395
+Ref: -tree-map47250
+Ref: -tree-map-nodes47690
+Ref: -tree-reduce48542
+Ref: -tree-reduce-from49417
+Ref: -tree-mapreduce50016
+Ref: -tree-mapreduce-from50860
+Ref: -clone52130
+Node: Threading macros52457
+Ref: ->52602
+Ref: ->>53092
+Ref: -->53586
+Node: Binding54101
+Ref: -when-let54305
+Ref: -when-let*54795
+Ref: -if-let55214
+Ref: -if-let*55605
+Ref: -let56112
+Ref: -let*59832
+Ref: -lambda60769
+Node: Side-effects61566
+Ref: -each61760
+Ref: -each-while62163
+Ref: -dotimes62521
+Node: Destructive operations62822
+Ref: !cons62995
+Ref: !cdr63202
+Node: Function combinators63398
+Ref: -partial63667
+Ref: -rpartial64060
+Ref: -juxt64460
+Ref: -compose64889
+Ref: -applify65443
+Ref: -on65887
+Ref: -flip66407
+Ref: -const66716
+Ref: -cut67057
+Ref: -not67510
+Ref: -orfn67821
+Ref: -andfn68254
+Ref: -iteratefn68747
+Ref: -fixfn69444
+Ref: -prodfn70999
+Node: Development72046
+Node: Contribute72395
+Node: Changes73116
+Node: Contributors75730
+Node: Index77068
+
+End Tag Table
diff --git a/dash.texi b/dash.texi
new file mode 100644
index 0000000..656acaf
--- /dev/null
+++ b/dash.texi
@@ -0,0 +1,3592 @@
+\input texinfo @c -*- texinfo -*-
address@hidden %**start of header
address@hidden dash.info
address@hidden dash
address@hidden UTF-8
address@hidden en
address@hidden fn cp
address@hidden Emacs
address@hidden
+* Dash: (dash.info). A modern list library for GNU Emacs
address@hidden direntry
address@hidden %**end of header
+
address@hidden
+
+This manual is for @code{dash.el} version 2.10.0.
+
+Copyright © 2012-2015 Magnar Sveen
+
address@hidden
+This program is free software; you can redistribute it and/or modify
+it under the terms of the GNU General Public License as published by
+the Free Software Foundation, either version 3 of the License, or
+(at your option) any later version.
+
+This program is distributed in the hope that it will be useful,
+but WITHOUT ANY WARRANTY; without even the implied warranty of
+MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
+GNU General Public License for more details.
+
+You should have received a copy of the GNU General Public License
+along with this program. If not, see @uref{http://www.gnu.org/licenses/}.
address@hidden quotation
address@hidden copying
+
address@hidden
address@hidden
address@hidden Dash
address@hidden Magnar Sveen
address@hidden
address@hidden 0pt plus 1filll
address@hidden
address@hidden titlepage
+
address@hidden
+
address@hidden
address@hidden Top
address@hidden dash
address@hidden
address@hidden ifnottex
+
address@hidden
+* Installation::
+* Functions::
+* Development::
+* Index::
+
address@hidden
+--- The Detailed Node Listing ---
+
+Installation
+
+* Using in a package::
+* Syntax highlighting of dash functions::
+
+Functions
+
+* Maps::
+* Sublist selection::
+* List to list::
+* Reductions::
+* Unfolding::
+* Predicates::
+* Partitioning::
+* Indexing::
+* Set operations::
+* Other list operations::
+* Tree operations::
+* Threading macros::
+* Binding::
+* Side-effects::
+* Destructive operations::
+* Function combinators::
+
+Development
+
+* Contribute:: How to contribute
+* Changes:: List of significant changes by version
+* Contributors:: List of contributors
address@hidden detailmenu
address@hidden menu
+
+
+
address@hidden Installation
address@hidden Installation
+
+It's available on @uref{http://marmalade-repo.org/,marmalade} and
address@hidden://melpa.milkbox.net/,Melpa}; use @code{M-x
+package-install}:
+
address@hidden @kbd
address@hidden M-x package-install @key{RET} dash
+Install the dash library.
address@hidden table
+
address@hidden @kbd
address@hidden M-x package-install @key{RET} dash-functional
+Optional, if you want the function combinators.
address@hidden table
+
+Alternatively, you can just dump @verb{~dash.el~} or
address@hidden in your load path somewhere.
+
address@hidden
+* Using in a package::
+* Syntax highlighting of dash functions::
address@hidden menu
+
address@hidden Using in a package
address@hidden Using in a package
+
+Add this to the big comment block at the top:
+
address@hidden
+;; Package-Requires: ((dash "2.10.0"))
address@hidden lisp
+
address@hidden To get function combinators:
+
address@hidden
+;; Package-Requires: ((dash "2.10.0") (dash-functional "1.2.0") (emacs "24"))
address@hidden lisp
+
address@hidden Syntax highlighting of dash functions
address@hidden Syntax highlighting of dash functions
+
+Font lock of dash functions in emacs lisp buffers is now optional.
+Include this in your emacs settings to get syntax highlighting:
+
address@hidden
+(eval-after-load "dash" '(dash-enable-font-lock))
address@hidden lisp
+
address@hidden Functions
address@hidden Functions
+
+This chapter contains reference documentation for the dash
address@hidden programming interface,API}. All functions and
+constructs in the library are prefixed with a dash (-).
+
+There are also anaphoric versions of functions where that makes sense,
+prefixed with two dashes instead of one.
+
+For instance, while @code{-map} takes a function to map over the list,
+one can also use the anaphoric form with double dashes - which will
+then be executed with @code{it} exposed as the list item. Here's an
+example:
+
address@hidden
+(-map (lambda (n) (* n n)) '(1 2 3 4)) ;; normal version
+
+(--map (* it it) '(1 2 3 4)) ;; anaphoric version
address@hidden lisp
+
address@hidden Of course, the original can also be written like
+
address@hidden
+(defun square (n) (* n n))
+
+(-map 'square '(1 2 3 4))
address@hidden lisp
+
address@hidden which demonstrates the usefulness of both versions.
+
address@hidden
+* Maps::
+* Sublist selection::
+* List to list::
+* Reductions::
+* Unfolding::
+* Predicates::
+* Partitioning::
+* Indexing::
+* Set operations::
+* Other list operations::
+* Tree operations::
+* Threading macros::
+* Binding::
+* Side-effects::
+* Destructive operations::
+* Function combinators::
address@hidden menu
+
+
address@hidden Maps
address@hidden Maps
+
+
+Functions in this category take a transforming function, which
+is then applied sequentially to each or selected elements of the
+input list. The results are collected in order and returned as
+new list.
+
+
address@hidden
address@hidden -map (fn list)
+Return a new list consisting of the result of applying @var{fn} to the items
in @var{list}.
+
address@hidden
address@hidden
+(-map (lambda (num) (* num num)) '(1 2 3 4))
+ @result{} '(1 4 9 16)
address@hidden group
address@hidden
+(-map 'square '(1 2 3 4))
+ @result{} '(1 4 9 16)
address@hidden group
address@hidden
+(--map (* it it) '(1 2 3 4))
+ @result{} '(1 4 9 16)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -map-when (pred rep list)
+Return a new list where the elements in @var{list} that does not match the
@var{pred} function
+are unchanged, and where the elements in @var{list} that do match the
@var{pred} function are mapped
+through the @var{rep} function.
+
+Alias: @code{-replace-where}
+
+See also: @code{-update-at} (@pxref{-update-at})
+
address@hidden
address@hidden
+(-map-when 'even? 'square '(1 2 3 4))
+ @result{} '(1 4 3 16)
address@hidden group
address@hidden
+(--map-when (> it 2) (* it it) '(1 2 3 4))
+ @result{} '(1 2 9 16)
address@hidden group
address@hidden
+(--map-when (= it 2) 17 '(1 2 3 4))
+ @result{} '(1 17 3 4)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -map-indexed (fn list)
+Return a new list consisting of the result of (@var{fn} index item) for each
item in @var{list}.
+
+In the anaphoric form @code{--map-indexed}, the index is exposed as `it-index`.
+
address@hidden
address@hidden
+(-map-indexed (lambda (index item) (- item index)) '(1 2 3 4))
+ @result{} '(1 1 1 1)
address@hidden group
address@hidden
+(--map-indexed (- it it-index) '(1 2 3 4))
+ @result{} '(1 1 1 1)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -annotate (fn list)
+Return a list of cons cells where each cell is @var{fn} applied to each
+element of @var{list} paired with the unmodified element of @var{list}.
+
address@hidden
address@hidden
+(-annotate '1+ '(1 2 3))
+ @result{} '((2 . 1) (3 . 2) (4 . 3))
address@hidden group
address@hidden
+(-annotate 'length '(("h" "e" "l" "l" "o") ("hello" "world")))
+ @result{} '((5 "h" "e" "l" "l" "o") (2 "hello" "world"))
address@hidden group
address@hidden
+(--annotate (< 1 it) '(0 1 2 3))
+ @result{} '((nil . 0) (nil . 1) (t . 2) (t . 3))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -splice (pred fun list)
+Splice lists generated by @var{fun} in place of elements matching @var{pred}
in @var{list}.
+
address@hidden takes the element matching @var{pred} as input.
+
+This function can be used as replacement for @code{,@@} in case you
+need to splice several lists at marked positions (for example
+with keywords).
+
+See also: @code{-splice-list} (@pxref{-splice-list}), @code{-insert-at}
(@pxref{-insert-at})
+
address@hidden
address@hidden
+(-splice 'even? (lambda (x) (list x x)) '(1 2 3 4))
+ @result{} '(1 2 2 3 4 4)
address@hidden group
address@hidden
+(--splice 't (list it it) '(1 2 3 4))
+ @result{} '(1 1 2 2 3 3 4 4)
address@hidden group
address@hidden
+(--splice (equal it :magic) '((list of) (magical) (code)) '((foo) (bar) :magic
(baz)))
+ @result{} '((foo) (bar) (list of) (magical) (code) (baz))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -splice-list (pred new-list list)
+Splice @var{new-list} in place of elements matching @var{pred} in @var{list}.
+
+See also: @code{-splice} (@pxref{-splice}), @code{-insert-at}
(@pxref{-insert-at})
+
address@hidden
address@hidden
+(-splice-list 'keywordp '(a b c) '(1 :foo 2))
+ @result{} '(1 a b c 2)
address@hidden group
address@hidden
+(-splice-list 'keywordp nil '(1 :foo 2))
+ @result{} '(1 2)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -mapcat (fn list)
+Return the concatenation of the result of mapping @var{fn} over @var{list}.
+Thus function @var{fn} should return a list.
+
address@hidden
address@hidden
+(-mapcat 'list '(1 2 3))
+ @result{} '(1 2 3)
address@hidden group
address@hidden
+(-mapcat (lambda (item) (list 0 item)) '(1 2 3))
+ @result{} '(0 1 0 2 0 3)
address@hidden group
address@hidden
+(--mapcat (list 0 it) '(1 2 3))
+ @result{} '(0 1 0 2 0 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -copy (arg)
+Create a shallow copy of @var{list}.
+
address@hidden
address@hidden
+(-copy '(1 2 3))
+ @result{} '(1 2 3)
address@hidden group
address@hidden
+(let ((a '(1 2 3))) (eq a (-copy a)))
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Sublist selection
address@hidden Sublist selection
+
+
+Functions returning a sublist of the original list.
+
+
address@hidden
address@hidden -filter (pred list)
+Return a new list of the items in @var{list} for which @var{pred} returns a
non-nil value.
+
+Alias: @code{-select}
+
address@hidden
address@hidden
+(-filter (lambda (num) (= 0 (% num 2))) '(1 2 3 4))
+ @result{} '(2 4)
address@hidden group
address@hidden
+(-filter 'even? '(1 2 3 4))
+ @result{} '(2 4)
address@hidden group
address@hidden
+(--filter (= 0 (% it 2)) '(1 2 3 4))
+ @result{} '(2 4)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -remove (pred list)
+Return a new list of the items in @var{list} for which @var{pred} returns nil.
+
+Alias: @code{-reject}
+
address@hidden
address@hidden
+(-remove (lambda (num) (= 0 (% num 2))) '(1 2 3 4))
+ @result{} '(1 3)
address@hidden group
address@hidden
+(-remove 'even? '(1 2 3 4))
+ @result{} '(1 3)
address@hidden group
address@hidden
+(--remove (= 0 (% it 2)) '(1 2 3 4))
+ @result{} '(1 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -non-nil (list)
+Return all non-nil elements of @var{list}.
+
address@hidden
address@hidden
+(-non-nil '(1 nil 2 nil nil 3 4 nil 5 nil))
+ @result{} '(1 2 3 4 5)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -slice (list from &optional to step)
+Return copy of @var{list}, starting from index @var{from} to index @var{to}.
+
address@hidden or @var{to} may be negative. These values are then interpreted
+modulo the length of the list.
+
+If @var{step} is a number, only each STEPth item in the resulting
+section is returned. Defaults to 1.
+
address@hidden
address@hidden
+(-slice '(1 2 3 4 5) 1)
+ @result{} '(2 3 4 5)
address@hidden group
address@hidden
+(-slice '(1 2 3 4 5) 0 3)
+ @result{} '(1 2 3)
address@hidden group
address@hidden
+(-slice '(1 2 3 4 5 6 7 8 9) 1 -1 2)
+ @result{} '(2 4 6 8)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -take (n list)
+Return a new list of the first @var{n} items in @var{list}, or all items if
there are fewer than @var{n}.
+
address@hidden
address@hidden
+(-take 3 '(1 2 3 4 5))
+ @result{} '(1 2 3)
address@hidden group
address@hidden
+(-take 17 '(1 2 3 4 5))
+ @result{} '(1 2 3 4 5)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -drop (n list)
+Return the tail of @var{list} without the first @var{n} items.
+
address@hidden
address@hidden
+(-drop 3 '(1 2 3 4 5))
+ @result{} '(4 5)
address@hidden group
address@hidden
+(-drop 17 '(1 2 3 4 5))
+ @result{} '()
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -take-while (pred list)
+Return a new list of successive items from @var{list} while (@var{pred} item)
returns a non-nil value.
+
address@hidden
address@hidden
+(-take-while 'even? '(1 2 3 4))
+ @result{} '()
address@hidden group
address@hidden
+(-take-while 'even? '(2 4 5 6))
+ @result{} '(2 4)
address@hidden group
address@hidden
+(--take-while (< it 4) '(1 2 3 4 3 2 1))
+ @result{} '(1 2 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -drop-while (pred list)
+Return the tail of @var{list} starting from the first item for which
(@var{pred} item) returns nil.
+
address@hidden
address@hidden
+(-drop-while 'even? '(1 2 3 4))
+ @result{} '(1 2 3 4)
address@hidden group
address@hidden
+(-drop-while 'even? '(2 4 5 6))
+ @result{} '(5 6)
address@hidden group
address@hidden
+(--drop-while (< it 4) '(1 2 3 4 3 2 1))
+ @result{} '(4 3 2 1)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -select-by-indices (indices list)
+Return a list whose elements are elements from @var{list} selected
+as `(nth i list)` for all i from @var{indices}.
+
address@hidden
address@hidden
+(-select-by-indices '(4 10 2 3 6) '("v" "e" "l" "o" "c" "i" "r" "a" "p" "t"
"o" "r"))
+ @result{} '("c" "o" "l" "o" "r")
address@hidden group
address@hidden
+(-select-by-indices '(2 1 0) '("a" "b" "c"))
+ @result{} '("c" "b" "a")
address@hidden group
address@hidden
+(-select-by-indices '(0 1 2 0 1 3 3 1) '("f" "a" "r" "l"))
+ @result{} '("f" "a" "r" "f" "a" "l" "l" "a")
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden List to list
address@hidden List to list
+
+
+Bag of various functions which modify input list.
+
+
address@hidden
address@hidden -keep (fn list)
+Return a new list of the non-nil results of applying @var{fn} to the items in
@var{list}.
+
address@hidden
address@hidden
+(-keep 'cdr '((1 2 3) (4 5) (6)))
+ @result{} '((2 3) (5))
address@hidden group
address@hidden
+(-keep (lambda (num) (when (> num 3) (* 10 num))) '(1 2 3 4 5 6))
+ @result{} '(40 50 60)
address@hidden group
address@hidden
+(--keep (when (> it 3) (* 10 it)) '(1 2 3 4 5 6))
+ @result{} '(40 50 60)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -concat (&rest lists)
+Return a new list with the concatenation of the elements in the supplied
@var{lists}.
+
address@hidden
address@hidden
+(-concat '(1))
+ @result{} '(1)
address@hidden group
address@hidden
+(-concat '(1) '(2))
+ @result{} '(1 2)
address@hidden group
address@hidden
+(-concat '(1) '(2 3) '(4))
+ @result{} '(1 2 3 4)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -flatten (l)
+Take a nested list @var{l} and return its contents as a single, flat list.
+
+See also: @code{-flatten-n} (@pxref{-flatten-n})
+
address@hidden
address@hidden
+(-flatten '((1)))
+ @result{} '(1)
address@hidden group
address@hidden
+(-flatten '((1 (2 3) (((4 (5)))))))
+ @result{} '(1 2 3 4 5)
address@hidden group
address@hidden
+(-flatten '(1 2 (3 . 4)))
+ @result{} '(1 2 (3 . 4))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -flatten-n (num list)
+Flatten @var{num} levels of a nested @var{list}.
+
+See also: @code{-flatten} (@pxref{-flatten})
+
address@hidden
address@hidden
+(-flatten-n 1 '((1 2) ((3 4) ((5 6)))))
+ @result{} '(1 2 (3 4) ((5 6)))
address@hidden group
address@hidden
+(-flatten-n 2 '((1 2) ((3 4) ((5 6)))))
+ @result{} '(1 2 3 4 (5 6))
address@hidden group
address@hidden
+(-flatten-n 3 '((1 2) ((3 4) ((5 6)))))
+ @result{} '(1 2 3 4 5 6)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -replace (old new list)
+Replace all @var{old} items in @var{list} with @var{new}.
+
+Elements are compared using @code{equal}.
+
+See also: @code{-replace-at} (@pxref{-replace-at})
+
address@hidden
address@hidden
+(-replace 1 "1" '(1 2 3 4 3 2 1))
+ @result{} '("1" 2 3 4 3 2 "1")
address@hidden group
address@hidden
+(-replace "foo" "bar" '("a" "nice" "foo" "sentence" "about" "foo"))
+ @result{} '("a" "nice" "bar" "sentence" "about" "bar")
address@hidden group
address@hidden
+(-replace 1 2 nil)
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -insert-at (n x list)
+Return a list with @var{x} inserted into @var{list} at position @var{n}.
+
+See also: @code{-splice} (@pxref{-splice}), @code{-splice-list}
(@pxref{-splice-list})
+
address@hidden
address@hidden
+(-insert-at 1 'x '(a b c))
+ @result{} '(a x b c)
address@hidden group
address@hidden
+(-insert-at 12 'x '(a b c))
+ @result{} '(a b c x)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -replace-at (n x list)
+Return a list with element at Nth position in @var{list} replaced with @var{x}.
+
+See also: @code{-replace} (@pxref{-replace})
+
address@hidden
address@hidden
+(-replace-at 0 9 '(0 1 2 3 4 5))
+ @result{} '(9 1 2 3 4 5)
address@hidden group
address@hidden
+(-replace-at 1 9 '(0 1 2 3 4 5))
+ @result{} '(0 9 2 3 4 5)
address@hidden group
address@hidden
+(-replace-at 4 9 '(0 1 2 3 4 5))
+ @result{} '(0 1 2 3 9 5)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -update-at (n func list)
+Return a list with element at Nth position in @var{list} replaced with `(func
(nth n list))`.
+
+See also: @code{-map-when} (@pxref{-map-when})
+
address@hidden
address@hidden
+(-update-at 0 (lambda (x) (+ x 9)) '(0 1 2 3 4 5))
+ @result{} '(9 1 2 3 4 5)
address@hidden group
address@hidden
+(-update-at 1 (lambda (x) (+ x 8)) '(0 1 2 3 4 5))
+ @result{} '(0 9 2 3 4 5)
address@hidden group
address@hidden
+(--update-at 2 (length it) '("foo" "bar" "baz" "quux"))
+ @result{} '("foo" "bar" 3 "quux")
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -remove-at (n list)
+Return a list with element at Nth position in @var{list} removed.
+
+See also: @code{-remove-at-indices} (@pxref{-remove-at-indices}),
@code{-remove} (@pxref{-remove})
+
address@hidden
address@hidden
+(-remove-at 0 '("0" "1" "2" "3" "4" "5"))
+ @result{} '("1" "2" "3" "4" "5")
address@hidden group
address@hidden
+(-remove-at 1 '("0" "1" "2" "3" "4" "5"))
+ @result{} '("0" "2" "3" "4" "5")
address@hidden group
address@hidden
+(-remove-at 2 '("0" "1" "2" "3" "4" "5"))
+ @result{} '("0" "1" "3" "4" "5")
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -remove-at-indices (indices list)
+Return a list whose elements are elements from @var{list} without
+elements selected as `(nth i list)` for all i
+from @var{indices}.
+
+See also: @code{-remove-at} (@pxref{-remove-at}), @code{-remove}
(@pxref{-remove})
+
address@hidden
address@hidden
+(-remove-at-indices '(0) '("0" "1" "2" "3" "4" "5"))
+ @result{} '("1" "2" "3" "4" "5")
address@hidden group
address@hidden
+(-remove-at-indices '(0 2 4) '("0" "1" "2" "3" "4" "5"))
+ @result{} '("1" "3" "5")
address@hidden group
address@hidden
+(-remove-at-indices '(0 5) '("0" "1" "2" "3" "4" "5"))
+ @result{} '("1" "2" "3" "4")
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Reductions
address@hidden Reductions
+
+
+Functions reducing lists into single value.
+
+
address@hidden
address@hidden -reduce-from (fn initial-value list)
+Return the result of applying @var{fn} to @var{initial-value} and the
+first item in @var{list}, then applying @var{fn} to that result and the 2nd
+item, etc. If @var{list} contains no items, return @var{initial-value} and
address@hidden is not called.
+
+In the anaphoric form @code{--reduce-from}, the accumulated value is
+exposed as `acc`.
+
address@hidden
address@hidden
+(-reduce-from '- 10 '(1 2 3))
+ @result{} 4
address@hidden group
address@hidden
+(-reduce-from (lambda (memo item) (concat "(" memo " - " (int-to-string item)
")")) "10" '(1 2 3))
+ @result{} "(((10 - 1) - 2) - 3)"
address@hidden group
address@hidden
+(--reduce-from (concat acc " " it) "START" '("a" "b" "c"))
+ @result{} "START a b c"
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -reduce-r-from (fn initial-value list)
+Replace conses with @var{fn}, nil with @var{initial-value} and evaluate
+the resulting expression. If @var{list} is empty, @var{initial-value} is
+returned and @var{fn} is not called.
+
+Note: this function works the same as @code{-reduce-from}
(@pxref{-reduce-from}) but the
+operation associates from right instead of from left.
+
address@hidden
address@hidden
+(-reduce-r-from '- 10 '(1 2 3))
+ @result{} -8
address@hidden group
address@hidden
+(-reduce-r-from (lambda (item memo) (concat "(" (int-to-string item) " - "
memo ")")) "10" '(1 2 3))
+ @result{} "(1 - (2 - (3 - 10)))"
address@hidden group
address@hidden
+(--reduce-r-from (concat it " " acc) "END" '("a" "b" "c"))
+ @result{} "a b c END"
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -reduce (fn list)
+Return the result of applying @var{fn} to the first 2 items in @var{list},
+then applying @var{fn} to that result and the 3rd item, etc. If @var{list}
+contains no items, @var{fn} must accept no arguments as well, and
+reduce return the result of calling @var{fn} with no arguments. If
address@hidden has only 1 item, it is returned and @var{fn} is not called.
+
+In the anaphoric form @code{--reduce}, the accumulated value is
+exposed as `acc`.
+
address@hidden
address@hidden
+(-reduce '- '(1 2 3 4))
+ @result{} -8
address@hidden group
address@hidden
+(-reduce (lambda (memo item) (format "%s-%s" memo item)) '(1 2 3))
+ @result{} "1-2-3"
address@hidden group
address@hidden
+(--reduce (format "%s-%s" acc it) '(1 2 3))
+ @result{} "1-2-3"
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -reduce-r (fn list)
+Replace conses with @var{fn} and evaluate the resulting expression.
+The final nil is ignored. If @var{list} contains no items, @var{fn} must
+accept no arguments as well, and reduce return the result of
+calling @var{fn} with no arguments. If @var{list} has only 1 item, it is
+returned and @var{fn} is not called.
+
+The first argument of @var{fn} is the new item, the second is the
+accumulated value.
+
+Note: this function works the same as @code{-reduce} (@pxref{-reduce}) but the
operation
+associates from right instead of from left.
+
address@hidden
address@hidden
+(-reduce-r '- '(1 2 3 4))
+ @result{} -2
address@hidden group
address@hidden
+(-reduce-r (lambda (item memo) (format "%s-%s" memo item)) '(1 2 3))
+ @result{} "3-2-1"
address@hidden group
address@hidden
+(--reduce-r (format "%s-%s" acc it) '(1 2 3))
+ @result{} "3-2-1"
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -count (pred list)
+Counts the number of items in @var{list} where (@var{pred} item) is non-nil.
+
address@hidden
address@hidden
+(-count 'even? '(1 2 3 4 5))
+ @result{} 2
address@hidden group
address@hidden
+(--count (< it 4) '(1 2 3 4))
+ @result{} 3
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -sum (list)
+Return the sum of @var{list}.
+
address@hidden
address@hidden
+(-sum '())
+ @result{} 0
address@hidden group
address@hidden
+(-sum '(1))
+ @result{} 1
address@hidden group
address@hidden
+(-sum '(1 2 3 4))
+ @result{} 10
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -product (list)
+Return the product of @var{list}.
+
address@hidden
address@hidden
+(-product '())
+ @result{} 1
address@hidden group
address@hidden
+(-product '(1))
+ @result{} 1
address@hidden group
address@hidden
+(-product '(1 2 3 4))
+ @result{} 24
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -min (list)
+Return the smallest value from @var{list} of numbers or markers.
+
address@hidden
address@hidden
+(-min '(0))
+ @result{} 0
address@hidden group
address@hidden
+(-min '(3 2 1))
+ @result{} 1
address@hidden group
address@hidden
+(-min '(1 2 3))
+ @result{} 1
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -min-by (comparator list)
+Take a comparison function @var{comparator} and a @var{list} and return
+the least element of the list by the comparison function.
+
+See also combinator @code{-on} (@pxref{-on}) which can transform the values
before
+comparing them.
+
address@hidden
address@hidden
+(-min-by '> '(4 3 6 1))
+ @result{} 1
address@hidden group
address@hidden
+(--min-by (> (car it) (car other)) '((1 2 3) (2) (3 2)))
+ @result{} '(1 2 3)
address@hidden group
address@hidden
+(--min-by (> (length it) (length other)) '((1 2 3) (2) (3 2)))
+ @result{} '(2)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -max (list)
+Return the largest value from @var{list} of numbers or markers.
+
address@hidden
address@hidden
+(-max '(0))
+ @result{} 0
address@hidden group
address@hidden
+(-max '(3 2 1))
+ @result{} 3
address@hidden group
address@hidden
+(-max '(1 2 3))
+ @result{} 3
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -max-by (comparator list)
+Take a comparison function @var{comparator} and a @var{list} and return
+the greatest element of the list by the comparison function.
+
+See also combinator @code{-on} (@pxref{-on}) which can transform the values
before
+comparing them.
+
address@hidden
address@hidden
+(-max-by '> '(4 3 6 1))
+ @result{} 6
address@hidden group
address@hidden
+(--max-by (> (car it) (car other)) '((1 2 3) (2) (3 2)))
+ @result{} '(3 2)
address@hidden group
address@hidden
+(--max-by (> (length it) (length other)) '((1 2 3) (2) (3 2)))
+ @result{} '(1 2 3)
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Unfolding
address@hidden Unfolding
+
+
+Operations dual to reductions, building lists from seed value rather than
consuming a list to produce a single value.
+
+
address@hidden
address@hidden -iterate (fun init n)
+Return a list of iterated applications of @var{fun} to @var{init}.
+
+This means a list of form:
+
+ (init (fun init) (fun (fun init)) ...)
+
address@hidden is the length of the returned list.
+
address@hidden
address@hidden
+(-iterate '1+ 1 10)
+ @result{} '(1 2 3 4 5 6 7 8 9 10)
address@hidden group
address@hidden
+(-iterate (lambda (x) (+ x x)) 2 5)
+ @result{} '(2 4 8 16 32)
address@hidden group
address@hidden
+(--iterate (* it it) 2 5)
+ @result{} '(2 4 16 256 65536)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -unfold (fun seed)
+Build a list from @var{seed} using @var{fun}.
+
+This is "dual" operation to @code{-reduce-r} (@pxref{-reduce-r}): while
-reduce-r
+consumes a list to produce a single value, @code{-unfold} (@pxref{-unfold})
takes a
+seed value and builds a (potentially infinite!) list.
+
address@hidden should return @code{nil} to stop the generating process, or a
+cons (@var{a} . @var{b}), where @var{a} will be prepended to the result and
@var{b} is
+the new seed.
+
address@hidden
address@hidden
+(-unfold (lambda (x) (unless (= x 0) (cons x (1- x)))) 10)
+ @result{} '(10 9 8 7 6 5 4 3 2 1)
address@hidden group
address@hidden
+(--unfold (when it (cons it (cdr it))) '(1 2 3 4))
+ @result{} '((1 2 3 4) (2 3 4) (3 4) (4))
address@hidden group
address@hidden
+(--unfold (when it (cons it (butlast it))) '(1 2 3 4))
+ @result{} '((1 2 3 4) (1 2 3) (1 2) (1))
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Predicates
address@hidden Predicates
+
address@hidden
address@hidden -any? (pred list)
+Return t if (@var{pred} x) is non-nil for any x in @var{list}, else nil.
+
+Alias: @code{-any-p}, @code{-some?}, @code{-some-p}
+
address@hidden
address@hidden
+(-any? 'even? '(1 2 3))
+ @result{} t
address@hidden group
address@hidden
+(-any? 'even? '(1 3 5))
+ @result{} nil
address@hidden group
address@hidden
+(--any? (= 0 (% it 2)) '(1 2 3))
+ @result{} t
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -all? (pred list)
+Return t if (@var{pred} x) is non-nil for all x in @var{list}, else nil.
+
+Alias: @code{-all-p}, @code{-every?}, @code{-every-p}
+
address@hidden
address@hidden
+(-all? 'even? '(1 2 3))
+ @result{} nil
address@hidden group
address@hidden
+(-all? 'even? '(2 4 6))
+ @result{} t
address@hidden group
address@hidden
+(--all? (= 0 (% it 2)) '(2 4 6))
+ @result{} t
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -none? (pred list)
+Return t if (@var{pred} x) is nil for all x in @var{list}, else nil.
+
+Alias: @code{-none-p}
+
address@hidden
address@hidden
+(-none? 'even? '(1 2 3))
+ @result{} nil
address@hidden group
address@hidden
+(-none? 'even? '(1 3 5))
+ @result{} t
address@hidden group
address@hidden
+(--none? (= 0 (% it 2)) '(1 2 3))
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -only-some? (pred list)
+Return `t` if at least one item of @var{list} matches @var{pred} and at least
one item of @var{list} does not match @var{pred}.
+Return `nil` both if all items match the predicate or if none of the items
match the predicate.
+
+Alias: @code{-only-some-p}
+
address@hidden
address@hidden
+(-only-some? 'even? '(1 2 3))
+ @result{} t
address@hidden group
address@hidden
+(-only-some? 'even? '(1 3 5))
+ @result{} nil
address@hidden group
address@hidden
+(-only-some? 'even? '(2 4 6))
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -contains? (list element)
+Return non-nil if @var{list} contains @var{element}.
+
+The test for equality is done with @code{equal}, or with @code{-compare-fn}
+if that's non-nil.
+
+Alias: @code{-contains-p}
+
address@hidden
address@hidden
+(-contains? '(1 2 3) 1)
+ @result{} t
address@hidden group
address@hidden
+(-contains? '(1 2 3) 2)
+ @result{} t
address@hidden group
address@hidden
+(-contains? '(1 2 3) 4)
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -same-items? (list list2)
+Return true if @var{list} and @var{list2} has the same items.
+
+The order of the elements in the lists does not matter.
+
+Alias: @code{-same-items-p}
+
address@hidden
address@hidden
+(-same-items? '(1 2 3) '(1 2 3))
+ @result{} t
address@hidden group
address@hidden
+(-same-items? '(1 2 3) '(3 2 1))
+ @result{} t
address@hidden group
address@hidden
+(-same-items? '(1 2 3) '(1 2 3 4))
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -is-prefix? (prefix list)
+Return non-nil if @var{prefix} is prefix of @var{list}.
+
+Alias: @code{-is-prefix-p}
+
address@hidden
address@hidden
+(-is-prefix? '(1 2 3) '(1 2 3 4 5))
+ @result{} t
address@hidden group
address@hidden
+(-is-prefix? '(1 2 3 4 5) '(1 2 3))
+ @result{} nil
address@hidden group
address@hidden
+(-is-prefix? '(1 3) '(1 2 3 4 5))
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -is-suffix? (suffix list)
+Return non-nil if @var{suffix} is suffix of @var{list}.
+
+Alias: @code{-is-suffix-p}
+
address@hidden
address@hidden
+(-is-suffix? '(3 4 5) '(1 2 3 4 5))
+ @result{} t
address@hidden group
address@hidden
+(-is-suffix? '(1 2 3 4 5) '(3 4 5))
+ @result{} nil
address@hidden group
address@hidden
+(-is-suffix? '(3 5) '(1 2 3 4 5))
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -is-infix? (infix list)
+Return non-nil if @var{infix} is infix of @var{list}.
+
+This operation runs in @var{o}(n^2) time
+
+Alias: @code{-is-infix-p}
+
address@hidden
address@hidden
+(-is-infix? '(1 2 3) '(1 2 3 4 5))
+ @result{} t
address@hidden group
address@hidden
+(-is-infix? '(2 3 4) '(1 2 3 4 5))
+ @result{} t
address@hidden group
address@hidden
+(-is-infix? '(3 4 5) '(1 2 3 4 5))
+ @result{} t
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Partitioning
address@hidden Partitioning
+
+
+Functions partitioning the input list into a list of lists.
+
+
address@hidden
address@hidden -split-at (n list)
+Return a list of ((-take @var{n} @var{list}) (-drop @var{n} @var{list})), in
no more than one pass through the list.
+
address@hidden
address@hidden
+(-split-at 3 '(1 2 3 4 5))
+ @result{} '((1 2 3) (4 5))
address@hidden group
address@hidden
+(-split-at 17 '(1 2 3 4 5))
+ @result{} '((1 2 3 4 5) nil)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -split-with (pred list)
+Return a list of ((-take-while @var{pred} @var{list}) (-drop-while @var{pred}
@var{list})), in no more than one pass through the list.
+
address@hidden
address@hidden
+(-split-with 'even? '(1 2 3 4))
+ @result{} '(nil (1 2 3 4))
address@hidden group
address@hidden
+(-split-with 'even? '(2 4 5 6))
+ @result{} '((2 4) (5 6))
address@hidden group
address@hidden
+(--split-with (< it 4) '(1 2 3 4 3 2 1))
+ @result{} '((1 2 3) (4 3 2 1))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -split-on (item list)
+Split the @var{list} each time @var{item} is found.
+
+Unlike @code{-partition-by} (@pxref{-partition-by}), the @var{item} is
discarded from the results.
+Empty lists are also removed from the result.
+
+Comparison is done by @code{equal}.
+
+See also @code{-split-when} (@pxref{-split-when})
+
address@hidden
address@hidden
+(-split-on '| '(Nil | Leaf a | Node [Tree a]))
+ @result{} '((Nil) (Leaf a) (Node [Tree a]))
address@hidden group
address@hidden
+(-split-on ':endgroup '("a" "b" :endgroup "c" :endgroup "d" "e"))
+ @result{} '(("a" "b") ("c") ("d" "e"))
address@hidden group
address@hidden
+(-split-on ':endgroup '("a" "b" :endgroup :endgroup "d" "e"))
+ @result{} '(("a" "b") ("d" "e"))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -split-when (fn list)
+Split the @var{list} on each element where @var{fn} returns non-nil.
+
+Unlike @code{-partition-by} (@pxref{-partition-by}), the "matched" element is
discarded from
+the results. Empty lists are also removed from the result.
+
+This function can be thought of as a generalization of
address@hidden
+
address@hidden
address@hidden
+(-split-when 'even? '(1 2 3 4 5 6))
+ @result{} '((1) (3) (5))
address@hidden group
address@hidden
+(-split-when 'even? '(1 2 3 4 6 8 9))
+ @result{} '((1) (3) (9))
address@hidden group
address@hidden
+(--split-when (memq it '(&optional &rest)) '(a b &optional c d &rest args))
+ @result{} '((a b) (c d) (args))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -separate (pred list)
+Return a list of ((-filter @var{pred} @var{list}) (-remove @var{pred}
@var{list})), in one pass through the list.
+
address@hidden
address@hidden
+(-separate (lambda (num) (= 0 (% num 2))) '(1 2 3 4 5 6 7))
+ @result{} '((2 4 6) (1 3 5 7))
address@hidden group
address@hidden
+(--separate (< it 5) '(3 7 5 9 3 2 1 4 6))
+ @result{} '((3 3 2 1 4) (7 5 9 6))
address@hidden group
address@hidden
+(-separate 'cdr '((1 2) (1) (1 2 3) (4)))
+ @result{} '(((1 2) (1 2 3)) ((1) (4)))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -partition (n list)
+Return a new list with the items in @var{list} grouped into @var{n-}sized
sublists.
+If there are not enough items to make the last group @var{n-}sized,
+those items are discarded.
+
address@hidden
address@hidden
+(-partition 2 '(1 2 3 4 5 6))
+ @result{} '((1 2) (3 4) (5 6))
address@hidden group
address@hidden
+(-partition 2 '(1 2 3 4 5 6 7))
+ @result{} '((1 2) (3 4) (5 6))
address@hidden group
address@hidden
+(-partition 3 '(1 2 3 4 5 6 7))
+ @result{} '((1 2 3) (4 5 6))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -partition-all (n list)
+Return a new list with the items in @var{list} grouped into @var{n-}sized
sublists.
+The last group may contain less than @var{n} items.
+
address@hidden
address@hidden
+(-partition-all 2 '(1 2 3 4 5 6))
+ @result{} '((1 2) (3 4) (5 6))
address@hidden group
address@hidden
+(-partition-all 2 '(1 2 3 4 5 6 7))
+ @result{} '((1 2) (3 4) (5 6) (7))
address@hidden group
address@hidden
+(-partition-all 3 '(1 2 3 4 5 6 7))
+ @result{} '((1 2 3) (4 5 6) (7))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -partition-in-steps (n step list)
+Return a new list with the items in @var{list} grouped into @var{n-}sized
sublists at offsets @var{step} apart.
+If there are not enough items to make the last group @var{n-}sized,
+those items are discarded.
+
address@hidden
address@hidden
+(-partition-in-steps 2 1 '(1 2 3 4))
+ @result{} '((1 2) (2 3) (3 4))
address@hidden group
address@hidden
+(-partition-in-steps 3 2 '(1 2 3 4))
+ @result{} '((1 2 3))
address@hidden group
address@hidden
+(-partition-in-steps 3 2 '(1 2 3 4 5))
+ @result{} '((1 2 3) (3 4 5))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -partition-all-in-steps (n step list)
+Return a new list with the items in @var{list} grouped into @var{n-}sized
sublists at offsets @var{step} apart.
+The last groups may contain less than @var{n} items.
+
address@hidden
address@hidden
+(-partition-all-in-steps 2 1 '(1 2 3 4))
+ @result{} '((1 2) (2 3) (3 4) (4))
address@hidden group
address@hidden
+(-partition-all-in-steps 3 2 '(1 2 3 4))
+ @result{} '((1 2 3) (3 4))
address@hidden group
address@hidden
+(-partition-all-in-steps 3 2 '(1 2 3 4 5))
+ @result{} '((1 2 3) (3 4 5) (5))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -partition-by (fn list)
+Apply @var{fn} to each item in @var{list}, splitting it each time @var{fn}
returns a new value.
+
address@hidden
address@hidden
+(-partition-by 'even? '())
+ @result{} '()
address@hidden group
address@hidden
+(-partition-by 'even? '(1 1 2 2 2 3 4 6 8))
+ @result{} '((1 1) (2 2 2) (3) (4 6 8))
address@hidden group
address@hidden
+(--partition-by (< it 3) '(1 2 3 4 3 2 1))
+ @result{} '((1 2) (3 4 3) (2 1))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -partition-by-header (fn list)
+Apply @var{fn} to the first item in @var{list}. That is the header
+value. Apply @var{fn} to each item in @var{list}, splitting it each time
@var{fn}
+returns the header value, but only after seeing at least one
+other value (the body).
+
address@hidden
address@hidden
+(--partition-by-header (= it 1) '(1 2 3 1 2 1 2 3 4))
+ @result{} '((1 2 3) (1 2) (1 2 3 4))
address@hidden group
address@hidden
+(--partition-by-header (> it 0) '(1 2 0 1 0 1 2 3 0))
+ @result{} '((1 2 0) (1 0) (1 2 3 0))
address@hidden group
address@hidden
+(-partition-by-header 'even? '(2 1 1 1 4 1 3 5 6 6 1))
+ @result{} '((2 1 1 1) (4 1 3 5) (6 6 1))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -group-by (fn list)
+Separate @var{list} into an alist whose keys are @var{fn} applied to the
+elements of @var{list}. Keys are compared by @code{equal}.
+
address@hidden
address@hidden
+(-group-by 'even? '())
+ @result{} '()
address@hidden group
address@hidden
+(-group-by 'even? '(1 1 2 2 2 3 4 6 8))
+ @result{} '((nil 1 1 3) (t 2 2 2 4 6 8))
address@hidden group
address@hidden
+(--group-by (car (split-string it "/")) '("a/b" "c/d" "a/e"))
+ @result{} '(("a" "a/b" "a/e") ("c" "c/d"))
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Indexing
address@hidden Indexing
+
+
+Return indices of elements based on predicates, sort elements by indices etc.
+
+
address@hidden
address@hidden -elem-index (elem list)
+Return the index of the first element in the given @var{list} which
+is equal to the query element @var{elem}, or nil if there is no
+such element.
+
address@hidden
address@hidden
+(-elem-index 2 '(6 7 8 2 3 4))
+ @result{} 3
address@hidden group
address@hidden
+(-elem-index "bar" '("foo" "bar" "baz"))
+ @result{} 1
address@hidden group
address@hidden
+(-elem-index '(1 2) '((3) (5 6) (1 2) nil))
+ @result{} 2
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -elem-indices (elem list)
+Return the indices of all elements in @var{list} equal to the query
+element @var{elem}, in ascending order.
+
address@hidden
address@hidden
+(-elem-indices 2 '(6 7 8 2 3 4 2 1))
+ @result{} '(3 6)
address@hidden group
address@hidden
+(-elem-indices "bar" '("foo" "bar" "baz"))
+ @result{} '(1)
address@hidden group
address@hidden
+(-elem-indices '(1 2) '((3) (1 2) (5 6) (1 2) nil))
+ @result{} '(1 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -find-index (pred list)
+Take a predicate @var{pred} and a @var{list} and return the index of the
+first element in the list satisfying the predicate, or nil if
+there is no such element.
+
address@hidden
address@hidden
+(-find-index 'even? '(2 4 1 6 3 3 5 8))
+ @result{} 0
address@hidden group
address@hidden
+(--find-index (< 5 it) '(2 4 1 6 3 3 5 8))
+ @result{} 3
address@hidden group
address@hidden
+(-find-index (-partial 'string-lessp "baz") '("bar" "foo" "baz"))
+ @result{} 1
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -find-last-index (pred list)
+Take a predicate @var{pred} and a @var{list} and return the index of the
+last element in the list satisfying the predicate, or nil if
+there is no such element.
+
address@hidden
address@hidden
+(-find-last-index 'even? '(2 4 1 6 3 3 5 8))
+ @result{} 7
address@hidden group
address@hidden
+(--find-last-index (< 5 it) '(2 7 1 6 3 8 5 2))
+ @result{} 5
address@hidden group
address@hidden
+(-find-last-index (-partial 'string-lessp "baz") '("q" "foo" "baz"))
+ @result{} 1
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -find-indices (pred list)
+Return the indices of all elements in @var{list} satisfying the
+predicate @var{pred}, in ascending order.
+
address@hidden
address@hidden
+(-find-indices 'even? '(2 4 1 6 3 3 5 8))
+ @result{} '(0 1 3 7)
address@hidden group
address@hidden
+(--find-indices (< 5 it) '(2 4 1 6 3 3 5 8))
+ @result{} '(3 7)
address@hidden group
address@hidden
+(-find-indices (-partial 'string-lessp "baz") '("bar" "foo" "baz"))
+ @result{} '(1)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -grade-up (comparator list)
+Grade elements of @var{list} using @var{comparator} relation, yielding a
+permutation vector such that applying this permutation to @var{list}
+sorts it in ascending order.
+
address@hidden
address@hidden
+(-grade-up '< '(3 1 4 2 1 3 3))
+ @result{} '(1 4 3 0 5 6 2)
address@hidden group
address@hidden
+(let ((l '(3 1 4 2 1 3 3))) (-select-by-indices (-grade-up '< l) l))
+ @result{} '(1 1 2 3 3 3 4)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -grade-down (comparator list)
+Grade elements of @var{list} using @var{comparator} relation, yielding a
+permutation vector such that applying this permutation to @var{list}
+sorts it in descending order.
+
address@hidden
address@hidden
+(-grade-down '< '(3 1 4 2 1 3 3))
+ @result{} '(2 0 5 6 3 1 4)
address@hidden group
address@hidden
+(let ((l '(3 1 4 2 1 3 3))) (-select-by-indices (-grade-down '< l) l))
+ @result{} '(4 3 3 3 2 1 1)
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Set operations
address@hidden Set operations
+
+
+Operations pretending lists are sets.
+
+
address@hidden
address@hidden -union (list list2)
+Return a new list containing the elements of @var{list1} and elements of
@var{list2} that are not in @var{list1}.
+The test for equality is done with @code{equal},
+or with @code{-compare-fn} if that's non-nil.
+
address@hidden
address@hidden
+(-union '(1 2 3) '(3 4 5))
+ @result{} '(1 2 3 4 5)
address@hidden group
address@hidden
+(-union '(1 2 3 4) '())
+ @result{} '(1 2 3 4)
address@hidden group
address@hidden
+(-union '(1 1 2 2) '(3 2 1))
+ @result{} '(1 1 2 2 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -difference (list list2)
+Return a new list with only the members of @var{list} that are not in
@var{list2}.
+The test for equality is done with @code{equal},
+or with @code{-compare-fn} if that's non-nil.
+
address@hidden
address@hidden
+(-difference '() '())
+ @result{} '()
address@hidden group
address@hidden
+(-difference '(1 2 3) '(4 5 6))
+ @result{} '(1 2 3)
address@hidden group
address@hidden
+(-difference '(1 2 3 4) '(3 4 5 6))
+ @result{} '(1 2)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -intersection (list list2)
+Return a new list containing only the elements that are members of both
@var{list} and @var{list2}.
+The test for equality is done with @code{equal},
+or with @code{-compare-fn} if that's non-nil.
+
address@hidden
address@hidden
+(-intersection '() '())
+ @result{} '()
address@hidden group
address@hidden
+(-intersection '(1 2 3) '(4 5 6))
+ @result{} '()
address@hidden group
address@hidden
+(-intersection '(1 2 3 4) '(3 4 5 6))
+ @result{} '(3 4)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -distinct (list)
+Return a new list with all duplicates removed.
+The test for equality is done with @code{equal},
+or with @code{-compare-fn} if that's non-nil.
+
+Alias: @code{-uniq}
+
address@hidden
address@hidden
+(-distinct '())
+ @result{} '()
address@hidden group
address@hidden
+(-distinct '(1 2 2 4))
+ @result{} '(1 2 4)
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Other list operations
address@hidden Other list operations
+
+
+Other list functions not fit to be classified elsewhere.
+
+
address@hidden
address@hidden -rotate (n list)
+Rotate @var{list} @var{n} places to the right. With @var{n} negative, rotate
to the left.
+The time complexity is @var{o}(n).
+
address@hidden
address@hidden
+(-rotate 3 '(1 2 3 4 5 6 7))
+ @result{} '(5 6 7 1 2 3 4)
address@hidden group
address@hidden
+(-rotate -3 '(1 2 3 4 5 6 7))
+ @result{} '(4 5 6 7 1 2 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -repeat (n x)
+Return a list with @var{x} repeated @var{n} times.
+Return nil if @var{n} is less than 1.
+
address@hidden
address@hidden
+(-repeat 3 :a)
+ @result{} '(:a :a :a)
address@hidden group
address@hidden
+(-repeat 1 :a)
+ @result{} '(:a)
address@hidden group
address@hidden
+(-repeat 0 :a)
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -cons* (&rest args)
+Make a new list from the elements of @var{args}.
+
+The last 2 members of @var{args} are used as the final cons of the
+result so if the final member of @var{args} is not a list the result is
+a dotted list.
+
address@hidden
address@hidden
+(-cons* 1 2)
+ @result{} '(1 . 2)
address@hidden group
address@hidden
+(-cons* 1 2 3)
+ @result{} '(1 2 . 3)
address@hidden group
address@hidden
+(-cons* 1)
+ @result{} 1
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -snoc (list elem &rest elements)
+Append @var{elem} to the end of the list.
+
+This is like @code{cons}, but operates on the end of list.
+
+If @var{elements} is non nil, append these to the list as well.
+
address@hidden
address@hidden
+(-snoc '(1 2 3) 4)
+ @result{} '(1 2 3 4)
address@hidden group
address@hidden
+(-snoc '(1 2 3) 4 5 6)
+ @result{} '(1 2 3 4 5 6)
address@hidden group
address@hidden
+(-snoc '(1 2 3) '(4 5 6))
+ @result{} '(1 2 3 (4 5 6))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -interpose (sep list)
+Return a new list of all elements in @var{list} separated by @var{sep}.
+
address@hidden
address@hidden
+(-interpose "-" '())
+ @result{} '()
address@hidden group
address@hidden
+(-interpose "-" '("a"))
+ @result{} '("a")
address@hidden group
address@hidden
+(-interpose "-" '("a" "b" "c"))
+ @result{} '("a" "-" "b" "-" "c")
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -interleave (&rest lists)
+Return a new list of the first item in each list, then the second etc.
+
address@hidden
address@hidden
+(-interleave '(1 2) '("a" "b"))
+ @result{} '(1 "a" 2 "b")
address@hidden group
address@hidden
+(-interleave '(1 2) '("a" "b") '("A" "B"))
+ @result{} '(1 "a" "A" 2 "b" "B")
address@hidden group
address@hidden
+(-interleave '(1 2 3) '("a" "b"))
+ @result{} '(1 "a" 2 "b")
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -zip-with (fn list1 list2)
+Zip the two lists @var{list1} and @var{list2} using a function @var{fn}. This
+function is applied pairwise taking as first argument element of
address@hidden and as second argument element of @var{list2} at corresponding
+position.
+
+The anaphoric form @code{--zip-with} binds the elements from @var{list1} as
`it`,
+and the elements from @var{list2} as `other`.
+
address@hidden
address@hidden
+(-zip-with '+ '(1 2 3) '(4 5 6))
+ @result{} '(5 7 9)
address@hidden group
address@hidden
+(-zip-with 'cons '(1 2 3) '(4 5 6))
+ @result{} '((1 . 4) (2 . 5) (3 . 6))
address@hidden group
address@hidden
+(--zip-with (concat it " and " other) '("Batman" "Jekyll") '("Robin" "Hyde"))
+ @result{} '("Batman and Robin" "Jekyll and Hyde")
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -zip (&rest lists)
+Zip @var{lists} together. Group the head of each list, followed by the
+second elements of each list, and so on. The lengths of the returned
+groupings are equal to the length of the shortest input list.
+
+If two lists are provided as arguments, return the groupings as a list
+of cons cells. Otherwise, return the groupings as a list of lists.
+
address@hidden
address@hidden
+(-zip '(1 2 3) '(4 5 6))
+ @result{} '((1 . 4) (2 . 5) (3 . 6))
address@hidden group
address@hidden
+(-zip '(1 2 3) '(4 5 6 7))
+ @result{} '((1 . 4) (2 . 5) (3 . 6))
address@hidden group
address@hidden
+(-zip '(1 2 3 4) '(4 5 6))
+ @result{} '((1 . 4) (2 . 5) (3 . 6))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -zip-fill (fill-value &rest lists)
+Zip @var{lists}, with @var{fill-value} padded onto the shorter lists. The
+lengths of the returned groupings are equal to the length of the
+longest input list.
+
address@hidden
address@hidden
+(-zip-fill 0 '(1 2 3 4 5) '(6 7 8 9))
+ @result{} '((1 . 6) (2 . 7) (3 . 8) (4 . 9) (5 . 0))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -cycle (list)
+Return an infinite copy of @var{list} that will cycle through the
+elements and repeat from the beginning.
+
address@hidden
address@hidden
+(-take 5 (-cycle '(1 2 3)))
+ @result{} '(1 2 3 1 2)
address@hidden group
address@hidden
+(-take 7 (-cycle '(1 "and" 3)))
+ @result{} '(1 "and" 3 1 "and" 3 1)
address@hidden group
address@hidden
+(-zip (-cycle '(1 2 3)) '(1 2))
+ @result{} '((1 . 1) (2 . 2))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -pad (fill-value &rest lists)
+Appends @var{fill-value} to the end of each list in @var{lists} such that they
+will all have the same length.
+
address@hidden
address@hidden
+(-pad 0 '())
+ @result{} '(nil)
address@hidden group
address@hidden
+(-pad 0 '(1))
+ @result{} '((1))
address@hidden group
address@hidden
+(-pad 0 '(1 2 3) '(4 5))
+ @result{} '((1 2 3) (4 5 0))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -table (fn &rest lists)
+Compute outer product of @var{lists} using function @var{fn}.
+
+The function @var{fn} should have the same arity as the number of
+supplied lists.
+
+The outer product is computed by applying fn to all possible
+combinations created by taking one element from each list in
+order. The dimension of the result is (length lists).
+
+See also: @code{-table-flat} (@pxref{-table-flat})
+
address@hidden
address@hidden
+(-table '* '(1 2 3) '(1 2 3))
+ @result{} '((1 2 3) (2 4 6) (3 6 9))
address@hidden group
address@hidden
+(-table (lambda (a b) (-sum (-zip-with '* a b))) '((1 2) (3 4)) '((1 3) (2 4)))
+ @result{} '((7 15) (10 22))
address@hidden group
address@hidden
+(apply '-table 'list (-repeat 3 '(1 2)))
+ @result{} '((((1 1 1) (2 1 1)) ((1 2 1) (2 2 1))) (((1 1 2) (2 1 2)) ((1 2
2) (2 2 2))))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -table-flat (fn &rest lists)
+Compute flat outer product of @var{lists} using function @var{fn}.
+
+The function @var{fn} should have the same arity as the number of
+supplied lists.
+
+The outer product is computed by applying fn to all possible
+combinations created by taking one element from each list in
+order. The results are flattened, ignoring the tensor structure
+of the result. This is equivalent to calling:
+
+ (-flatten-n (1- (length lists)) (-table fn lists))
+
+but the implementation here is much more efficient.
+
+See also: @code{-flatten-n} (@pxref{-flatten-n}), @code{-table}
(@pxref{-table})
+
address@hidden
address@hidden
+(-table-flat 'list '(1 2 3) '(a b c))
+ @result{} '((1 a) (2 a) (3 a) (1 b) (2 b) (3 b) (1 c) (2 c) (3 c))
address@hidden group
address@hidden
+(-table-flat '* '(1 2 3) '(1 2 3))
+ @result{} '(1 2 3 2 4 6 3 6 9)
address@hidden group
address@hidden
+(apply '-table-flat 'list (-repeat 3 '(1 2)))
+ @result{} '((1 1 1) (2 1 1) (1 2 1) (2 2 1) (1 1 2) (2 1 2) (1 2 2) (2 2
2))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -first (pred list)
+Return the first x in @var{list} where (@var{pred} x) is non-nil, else nil.
+
+To get the first item in the list no questions asked, use @code{car}.
+
+Alias: @code{-find}
+
address@hidden
address@hidden
+(-first 'even? '(1 2 3))
+ @result{} 2
address@hidden group
address@hidden
+(-first 'even? '(1 3 5))
+ @result{} nil
address@hidden group
address@hidden
+(--first (> it 2) '(1 2 3))
+ @result{} 3
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -some (pred list)
+Return (@var{pred} x) for the first @var{list} item where (@var{pred} x) is
non-nil, else nil.
+
+Alias: @code{-any}
+
address@hidden
address@hidden
+(-some 'even? '(1 2 3))
+ @result{} t
address@hidden group
address@hidden
+(--some (member 'foo it) '((foo bar) (baz)))
+ @result{} '(foo bar)
address@hidden group
address@hidden
+(--some (plist-get it :bar) '((:foo 1 :bar 2) (:baz 3)))
+ @result{} 2
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -last (pred list)
+Return the last x in @var{list} where (@var{pred} x) is non-nil, else nil.
+
address@hidden
address@hidden
+(-last 'even? '(1 2 3 4 5 6 3 3 3))
+ @result{} 6
address@hidden group
address@hidden
+(-last 'even? '(1 3 7 5 9))
+ @result{} nil
address@hidden group
address@hidden
+(--last (> (length it) 3) '("a" "looong" "word" "and" "short" "one"))
+ @result{} "short"
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -first-item (list)
+Return the first item of @var{list}, or nil on an empty list.
+
address@hidden
address@hidden
+(-first-item '(1 2 3))
+ @result{} 1
address@hidden group
address@hidden
+(-first-item nil)
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -last-item (list)
+Return the last item of @var{list}, or nil on an empty list.
+
address@hidden
address@hidden
+(-last-item '(1 2 3))
+ @result{} 3
address@hidden group
address@hidden
+(-last-item nil)
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -butlast (list)
+Return a list of all items in list except for the last.
+
address@hidden
address@hidden
+(-butlast '(1 2 3))
+ @result{} '(1 2)
address@hidden group
address@hidden
+(-butlast '(1 2))
+ @result{} '(1)
address@hidden group
address@hidden
+(-butlast '(1))
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -sort (comparator list)
+Sort @var{list}, stably, comparing elements using @var{comparator}.
+Return the sorted list. @var{list} is @var{not} modified by side effects.
address@hidden is called with two elements of @var{list}, and should return
non-nil
+if the first element should sort before the second.
+
address@hidden
address@hidden
+(-sort '< '(3 1 2))
+ @result{} '(1 2 3)
address@hidden group
address@hidden
+(-sort '> '(3 1 2))
+ @result{} '(3 2 1)
address@hidden group
address@hidden
+(--sort (< it other) '(3 1 2))
+ @result{} '(1 2 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -list (&rest args)
+Return a list with @var{args}.
+
+If first item of @var{args} is already a list, simply return @var{args}. If
+not, return a list with @var{args} as elements.
+
address@hidden
address@hidden
+(-list 1)
+ @result{} '(1)
address@hidden group
address@hidden
+(-list 1 2 3)
+ @result{} '(1 2 3)
address@hidden group
address@hidden
+(-list '(1 2 3))
+ @result{} '(1 2 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -fix (fn list)
+Compute the (least) fixpoint of @var{fn} with initial input @var{list}.
+
address@hidden is called at least once, results are compared with @code{equal}.
+
address@hidden
address@hidden
+(-fix (lambda (l) (-non-nil (--mapcat (-split-at (/ (length it) 2) it) l)))
'((1 2 3 4 5 6)))
+ @result{} '((1) (2) (3) (4) (5) (6))
address@hidden group
address@hidden
+(let ((data '(("starwars" "scifi") ("jedi" "starwars" "warrior")))) (--fix
(-uniq (--mapcat (cons it (cdr (assoc it data))) it)) '("jedi" "book")))
+ @result{} '("jedi" "starwars" "warrior" "scifi" "book")
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Tree operations
address@hidden Tree operations
+
+
+Functions pretending lists are trees.
+
+
address@hidden
address@hidden -tree-seq (branch children tree)
+Return a sequence of the nodes in @var{tree}, in depth-first search order.
+
address@hidden is a predicate of one argument that returns non-nil if the
+passed argument is a branch, that is, a node that can have children.
+
address@hidden is a function of one argument that returns the children
+of the passed branch node.
+
+Non-branch nodes are simply copied.
+
address@hidden
address@hidden
+(-tree-seq 'listp 'identity '(1 (2 3) 4 (5 (6 7))))
+ @result{} '((1 (2 3) 4 (5 (6 7))) 1 (2 3) 2 3 4 (5 (6 7)) 5 (6 7) 6 7)
address@hidden group
address@hidden
+(-tree-seq 'listp 'reverse '(1 (2 3) 4 (5 (6 7))))
+ @result{} '((1 (2 3) 4 (5 (6 7))) (5 (6 7)) (6 7) 7 6 5 4 (2 3) 3 2 1)
address@hidden group
address@hidden
+(--tree-seq (vectorp it) (append it nil) [1 [2 3] 4 [5 [6 7]]])
+ @result{} '([1 [2 3] 4 [5 [6 7]]] 1 [2 3] 2 3 4 [5 [6 7]] 5 [6 7] 6 7)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -tree-map (fn tree)
+Apply @var{fn} to each element of @var{tree} while preserving the tree
structure.
+
address@hidden
address@hidden
+(-tree-map '1+ '(1 (2 3) (4 (5 6) 7)))
+ @result{} '(2 (3 4) (5 (6 7) 8))
address@hidden group
address@hidden
+(-tree-map '(lambda (x) (cons x (expt 2 x))) '(1 (2 3) 4))
+ @result{} '((1 . 2) ((2 . 4) (3 . 8)) (4 . 16))
address@hidden group
address@hidden
+(--tree-map (length it) '("<body>" ("<p>" "text" "</p>") "</body>"))
+ @result{} '(6 (3 4 4) 7)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -tree-map-nodes (pred fun tree)
+Call @var{fun} on each node of @var{tree} that satisfies @var{pred}.
+
+If @var{pred} returns nil, continue descending down this node. If @var{pred}
+returns non-nil, apply @var{fun} to this node and do not descend
+further.
+
address@hidden
address@hidden
+(-tree-map-nodes 'vectorp (lambda (x) (-sum (append x nil))) '(1 [2 3] 4 (5 [6
7] 8)))
+ @result{} '(1 5 4 (5 13 8))
address@hidden group
address@hidden
+(-tree-map-nodes 'keywordp (lambda (x) (symbol-name x)) '(1 :foo 4 ((5 6 :bar)
:baz 8)))
+ @result{} '(1 ":foo" 4 ((5 6 ":bar") ":baz" 8))
address@hidden group
address@hidden
+(--tree-map-nodes (eq (car-safe it) 'add-mode) (-concat it (list :mode
'emacs-lisp-mode)) '(with-mode emacs-lisp-mode (foo bar) (add-mode a b) (baz
(add-mode c d))))
+ @result{} '(with-mode emacs-lisp-mode (foo bar) (add-mode a b :mode
emacs-lisp-mode) (baz (add-mode c d :mode emacs-lisp-mode)))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -tree-reduce (fn tree)
+Use @var{fn} to reduce elements of list @var{tree}.
+If elements of @var{tree} are lists themselves, apply the reduction
recursively.
+
address@hidden is first applied to first element of the list and second
+element, then on this result and third element from the list etc.
+
+See @code{-reduce-r} (@pxref{-reduce-r}) for how exactly are lists of zero or
one element handled.
+
address@hidden
address@hidden
+(-tree-reduce '+ '(1 (2 3) (4 5)))
+ @result{} 15
address@hidden group
address@hidden
+(-tree-reduce 'concat '("strings" (" on" " various") ((" levels"))))
+ @result{} "strings on various levels"
address@hidden group
address@hidden
+(--tree-reduce (cond ((stringp it) (concat it " " acc)) (t (let ((sn
(symbol-name it))) (concat "<" sn ">" acc "</" sn ">")))) '(body (p "some
words") (div "more" (b "bold") "words")))
+ @result{} "<body><p>some words</p> <div>more <b>bold</b>
words</div></body>"
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -tree-reduce-from (fn init-value tree)
+Use @var{fn} to reduce elements of list @var{tree}.
+If elements of @var{tree} are lists themselves, apply the reduction
recursively.
+
address@hidden is first applied to @var{init-value} and first element of the
list,
+then on this result and second element from the list etc.
+
+The initial value is ignored on cons pairs as they always contain
+two elements.
+
address@hidden
address@hidden
+(-tree-reduce-from '+ 1 '(1 (1 1) ((1))))
+ @result{} 8
address@hidden group
address@hidden
+(--tree-reduce-from (-concat acc (list it)) nil '(1 (2 3 (4 5)) (6 7)))
+ @result{} '((7 6) ((5 4) 3 2) 1)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -tree-mapreduce (fn folder tree)
+Apply @var{fn} to each element of @var{tree}, and make a list of the results.
+If elements of @var{tree} are lists themselves, apply @var{fn} recursively to
+elements of these nested lists.
+
+Then reduce the resulting lists using @var{folder} and initial value
address@hidden See @code{-reduce-r-from} (@pxref{-reduce-r-from}).
+
+This is the same as calling @code{-tree-reduce} (@pxref{-tree-reduce}) after
@code{-tree-map} (@pxref{-tree-map})
+but is twice as fast as it only traverse the structure once.
+
address@hidden
address@hidden
+(-tree-mapreduce 'list 'append '(1 (2 (3 4) (5 6)) (7 (8 9))))
+ @result{} '(1 2 3 4 5 6 7 8 9)
address@hidden group
address@hidden
+(--tree-mapreduce 1 (+ it acc) '(1 (2 (4 9) (2 1)) (7 (4 3))))
+ @result{} 9
address@hidden group
address@hidden
+(--tree-mapreduce 0 (max acc (1+ it)) '(1 (2 (4 9) (2 1)) (7 (4 3))))
+ @result{} 3
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -tree-mapreduce-from (fn folder init-value tree)
+Apply @var{fn} to each element of @var{tree}, and make a list of the results.
+If elements of @var{tree} are lists themselves, apply @var{fn} recursively to
+elements of these nested lists.
+
+Then reduce the resulting lists using @var{folder} and initial value
address@hidden See @code{-reduce-r-from} (@pxref{-reduce-r-from}).
+
+This is the same as calling @code{-tree-reduce-from}
(@pxref{-tree-reduce-from}) after @code{-tree-map} (@pxref{-tree-map})
+but is twice as fast as it only traverse the structure once.
+
address@hidden
address@hidden
+(-tree-mapreduce-from 'identity '* 1 '(1 (2 (3 4) (5 6)) (7 (8 9))))
+ @result{} 362880
address@hidden group
address@hidden
+(--tree-mapreduce-from (+ it it) (cons it acc) nil '(1 (2 (4 9) (2 1)) (7 (4
3))))
+ @result{} '(2 (4 (8 18) (4 2)) (14 (8 6)))
address@hidden group
address@hidden
+(concat "@{" (--tree-mapreduce-from (cond ((-cons-pair? it) (concat
(symbol-name (car it)) " -> " (symbol-name (cdr it)))) (t (concat (symbol-name
it) " : @{"))) (concat it (unless (or (equal acc "@}") (equal (substring it (1-
(length it))) "@{")) ", ") acc) "@}" '((elips-mode (foo (bar . booze)) (baz .
qux)) (c-mode (foo . bla) (bum . bam)))))
+ @result{} "@{elips-mode : @{foo : @{bar -> address@hidden, baz ->
address@hidden, c-mode : @{foo -> bla, bum -> address@hidden@}"
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -clone (list)
+Create a deep copy of @var{list}.
+The new list has the same elements and structure but all cons are
+replaced with new ones. This is useful when you need to clone a
+structure such as plist or alist.
+
address@hidden
address@hidden
+(let* ((a '(1 2 3)) (b (-clone a))) (nreverse a) b)
+ @result{} '(1 2 3)
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Threading macros
address@hidden Threading macros
+
address@hidden>}
address@hidden -> (x &optional form &rest more)
+Thread the expr through the forms. Insert @var{x} as the second item
+in the first form, making a list of it if it is not a list
+already. If there are more forms, insert the first form as the
+second item in second form, etc.
+
address@hidden
address@hidden
+(-> '(2 3 5))
+ @result{} '(2 3 5)
address@hidden group
address@hidden
+(-> '(2 3 5) (append '(8 13)))
+ @result{} '(2 3 5 8 13)
address@hidden group
address@hidden
+(-> '(2 3 5) (append '(8 13)) (-slice 1 -1))
+ @result{} '(3 5 8)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden>>}
address@hidden ->> (x form &rest more)
+Thread the expr through the forms. Insert @var{x} as the last item
+in the first form, making a list of it if it is not a list
+already. If there are more forms, insert the first form as the
+last item in second form, etc.
+
address@hidden
address@hidden
+(->> '(1 2 3) (-map 'square))
+ @result{} '(1 4 9)
address@hidden group
address@hidden
+(->> '(1 2 3) (-map 'square) (-remove 'even?))
+ @result{} '(1 9)
address@hidden group
address@hidden
+(->> '(1 2 3) (-map 'square) (-reduce '+))
+ @result{} 14
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden>}
address@hidden --> (x form &rest more)
+Thread the expr through the forms. Insert @var{x} at the position
+signified by the token @code{it} in the first form. If there are more
+forms, insert the first form at the position signified by @code{it} in
+in second form, etc.
+
address@hidden
address@hidden
+(--> "def" (concat "abc" it "ghi"))
+ @result{} "abcdefghi"
address@hidden group
address@hidden
+(--> "def" (concat "abc" it "ghi") (upcase it))
+ @result{} "ABCDEFGHI"
address@hidden group
address@hidden
+(--> "def" (concat "abc" it "ghi") upcase)
+ @result{} "ABCDEFGHI"
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Binding
address@hidden Binding
+
+
+Convenient versions of `let` and `let*` constructs combined with flow control.
+
+
address@hidden
address@hidden -when-let (var-val &rest body)
+If @var{val} evaluates to non-nil, bind it to @var{var} and execute body.
address@hidden should be a (@var{var} @var{val}) pair.
+
+Note: binding is done according to @code{-let} (@pxref{-let}).
+
address@hidden
address@hidden
+(-when-let (match-index (string-match "d" "abcd")) (+ match-index 2))
+ @result{} 5
address@hidden group
address@hidden
+(-when-let ((&plist :foo foo) (list :foo "foo")) foo)
+ @result{} "foo"
address@hidden group
address@hidden
+(-when-let ((&plist :foo foo) (list :bar "bar")) foo)
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -when-let* (vars-vals &rest body)
+If all @var{vals} evaluate to true, bind them to their corresponding
address@hidden and execute body. @var{vars-vals} should be a list of (@var{var}
@var{val})
+pairs.
+
+Note: binding is done according to @code{-let*} (@pxref{-let*}).
+
address@hidden
address@hidden
+(-when-let* ((x 5) (y 3) (z (+ y 4))) (+ x y z))
+ @result{} 15
address@hidden group
address@hidden
+(-when-let* ((x 5) (y nil) (z 7)) (+ x y z))
+ @result{} nil
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -if-let (var-val then &rest else)
+If @var{val} evaluates to non-nil, bind it to @var{var} and do @var{then},
+otherwise do @var{else}. @var{var-val} should be a (@var{var} @var{val}) pair.
+
+Note: binding is done according to @code{-let} (@pxref{-let}).
+
address@hidden
address@hidden
+(-if-let (match-index (string-match "d" "abc")) (+ match-index 3) 7)
+ @result{} 7
address@hidden group
address@hidden
+(--if-let (even? 4) it nil)
+ @result{} t
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -if-let* (vars-vals then &rest else)
+If all @var{vals} evaluate to true, bind them to their corresponding
address@hidden and do @var{then}, otherwise do @var{else}. @var{vars-vals}
should be a list
+of (@var{var} @var{val}) pairs.
+
+Note: binding is done according to @code{-let*} (@pxref{-let*}).
+
address@hidden
address@hidden
+(-if-let* ((x 5) (y 3) (z 7)) (+ x y z) "foo")
+ @result{} 15
address@hidden group
address@hidden
+(-if-let* ((x 5) (y nil) (z 7)) (+ x y z) "foo")
+ @result{} "foo"
address@hidden group
address@hidden
+(-if-let* (((_ _ x) '(nil nil 7))) x)
+ @result{} 7
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -let (varlist &rest body)
+Bind variables according to @var{varlist} then eval @var{body}.
+
address@hidden is a list of lists of the form (@var{pattern} @var{source}).
Each
address@hidden is matched against the @var{source} "structurally". @var{source}
+is only evaluated once for each @var{pattern}. Each @var{pattern} is matched
+recursively, and can therefore contain sub-patterns which are
+matched against corresponding sub-expressions of @var{source}.
+
+All the SOURCEs are evalled before any symbols are
+bound (i.e. "in parallel").
+
+If @var{varlist} only contains one (@var{pattern} @var{source}) element, you
can
+optionally specify it using a vector and discarding the
+outer-most parens. Thus
+
+ (-let ((@var{pattern} @var{source})) ..)
+
+becomes
+
+ (-let address@hidden @var{source}] ..).
+
address@hidden (@pxref{-let}) uses a convention of not binding places (symbols)
starting
+with _ whenever it's possible. You can use this to skip over
+entries you don't care about. However, this is not *always*
+possible (as a result of implementation) and these symbols might
+get bound to undefined values.
+
+Following is the overview of supported patterns. Remember that
+patterns can be matched recursively, so every a, b, aK in the
+following can be a matching construct and not necessarily a
+symbol/variable.
+
+Symbol:
+
+ a - bind the @var{source} to @var{a}. This is just like regular
@code{let}.
+
+Conses and lists:
+
+ (a) - bind @code{car} of cons/list to @var{a}
+
+ (a . b) - bind car of cons to @var{a} and @code{cdr} to @var{b}
+
+ (a b) - bind car of list to @var{a} and @code{cadr} to @var{b}
+
+ (a1 a2 a3 ...) - bind 0th car of list to @var{a1}, 1st to @var{a2}, 2nd
to @var{a3} ...
+
+ (a1 a2 a3 ... aN . rest) - as above, but bind the Nth cdr to @var{rest}.
+
+Vectors:
+
+ [a] - bind 0th element of a non-list sequence to @var{a} (works with
+ vectors, strings, bit arrays...)
+
+ [a1 a2 a3 ...] - bind 0th element of non-list sequence to @var{a0}, 1st to
+ @var{a1}, 2nd to @var{a2}, ...
+ If the @var{pattern} is shorter than @var{source}, the
values at
+ places not in @var{pattern} are ignored.
+ If the @var{pattern} is longer than @var{source}, an
@code{error} is
+ thrown.
+
+ [a1 a2 a3 ... &rest rest] ) - as above, but bind the rest of
+ the sequence to @var{rest}. This is
+ conceptually the same as improper list
+ matching (a1 a2 ... aN . rest)
+
+Key/value stores:
+
+ (&plist key0 a0 ... keyN aN) - bind value mapped by keyK in the
+ @var{source} plist to aK. If the
+ value is not found, aK is nil.
+
+ (&alist key0 a0 ... keyN aN) - bind value mapped by keyK in the
+ @var{source} alist to aK. If the
+ value is not found, aK is nil.
+
+ (&hash key0 a0 ... keyN aN) - bind value mapped by keyK in the
+ @var{source} hash table to aK. If the
+ value is not found, aK is nil.
+
+Further, special keyword &keys supports "inline" matching of
+plist-like key-value pairs, similarly to &keys keyword of
address@hidden
+
+ (a1 a2 ... aN &keys key1 b1 ... keyN bK)
+
+This binds @var{n} values from the list to a1 ... aN, then interprets
+the cdr as a plist (see key/value matching above).
+
address@hidden
address@hidden
+(-let (([a (b c) d] [1 (2 3) 4])) (list a b c d))
+ @result{} '(1 2 3 4)
address@hidden group
address@hidden
+(-let [(a b c . d) (list 1 2 3 4 5 6)] (list a b c d))
+ @result{} '(1 2 3 (4 5 6))
address@hidden group
address@hidden
+(-let [(&plist :foo foo :bar bar) (list :baz 3 :foo 1 :qux 4 :bar 2)] (list
foo bar))
+ @result{} '(1 2)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -let* (varlist &rest body)
+Bind variables according to @var{varlist} then eval @var{body}.
+
address@hidden is a list of lists of the form (@var{pattern} @var{source}).
Each
address@hidden is matched against the @var{source} structurally. @var{source}
is
+only evaluated once for each @var{pattern}.
+
+Each @var{source} can refer to the symbols already bound by this
address@hidden This is useful if you want to destructure @var{source}
+recursively but also want to name the intermediate structures.
+
+See @code{-let} (@pxref{-let}) for the list of all possible patterns.
+
address@hidden
address@hidden
+(-let* (((a . b) (cons 1 2)) ((c . d) (cons 3 4))) (list a b c d))
+ @result{} '(1 2 3 4)
address@hidden group
address@hidden
+(-let* (((a . b) (cons 1 (cons 2 3))) ((c . d) b)) (list a b c d))
+ @result{} '(1 (2 . 3) 2 3)
address@hidden group
address@hidden
+(-let* (((&alist "foo" foo "bar" bar) (list (cons "foo" 1) (cons "bar" (list
'a 'b 'c)))) ((a b c) bar)) (list foo a b c bar))
+ @result{} '(1 a b c (a b c))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -lambda (match-form &rest body)
+Return a lambda which destructures its input as @var{match-form} and executes
@var{body}.
+
+Note that you have to enclose the @var{match-form} in a pair of parens,
+such that:
+
+ (-lambda (x) body)
+ (-lambda (x y ...) body)
+
+has the usual semantics of @code{lambda}. Furthermore, these get
+translated into normal lambda, so there is no performance
+penalty.
+
+See @code{-let} (@pxref{-let}) for the description of destructuring mechanism.
+
address@hidden
address@hidden
+(-map (-lambda ((x y)) (+ x y)) '((1 2) (3 4) (5 6)))
+ @result{} '(3 7 11)
address@hidden group
address@hidden
+(-map (-lambda ([x y]) (+ x y)) '([1 2] [3 4] [5 6]))
+ @result{} '(3 7 11)
address@hidden group
address@hidden
+(funcall (-lambda ((_ . a) (_ . b)) (-concat a b)) '(1 2 3) '(4 5 6))
+ @result{} '(2 3 5 6)
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Side-effects
address@hidden Side-effects
+
+
+Functions iterating over lists for side-effect only.
+
+
address@hidden
address@hidden -each (list fn)
+Call @var{fn} with every item in @var{list}. Return nil, used for side-effects
only.
+
address@hidden
address@hidden
+(let (s) (-each '(1 2 3) (lambda (item) (setq s (cons item s)))))
+ @result{} nil
address@hidden group
address@hidden
+(let (s) (-each '(1 2 3) (lambda (item) (setq s (cons item s)))) s)
+ @result{} '(3 2 1)
address@hidden group
address@hidden
+(let (s) (--each '(1 2 3) (setq s (cons it s))) s)
+ @result{} '(3 2 1)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -each-while (list pred fn)
+Call @var{fn} with every item in @var{list} while (@var{pred} item) is non-nil.
+Return nil, used for side-effects only.
+
address@hidden
address@hidden
+(let (s) (-each-while '(2 4 5 6) 'even? (lambda (item) (!cons item s))) s)
+ @result{} '(4 2)
address@hidden group
address@hidden
+(let (s) (--each-while '(1 2 3 4) (< it 3) (!cons it s)) s)
+ @result{} '(2 1)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -dotimes (num fn)
+Repeatedly calls @var{fn} (presumably for side-effects) passing in integers
from 0 through @var{num-1}.
+
address@hidden
address@hidden
+(let (s) (-dotimes 3 (lambda (n) (!cons n s))) s)
+ @result{} '(2 1 0)
address@hidden group
address@hidden
+(let (s) (--dotimes 5 (!cons it s)) s)
+ @result{} '(4 3 2 1 0)
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Destructive operations
address@hidden Destructive operations
+
address@hidden
address@hidden !cons (car cdr)
+Destructive: Set @var{cdr} to the cons of @var{car} and @var{cdr}.
+
address@hidden
address@hidden
+(let (l) (!cons 5 l) l)
+ @result{} '(5)
address@hidden group
address@hidden
+(let ((l '(3))) (!cons 5 l) l)
+ @result{} '(5 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden !cdr (list)
+Destructive: Set @var{list} to the cdr of @var{list}.
+
address@hidden
address@hidden
+(let ((l '(3))) (!cdr l) l)
+ @result{} '()
address@hidden group
address@hidden
+(let ((l '(3 5))) (!cdr l) l)
+ @result{} '(5)
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Function combinators
address@hidden Function combinators
+
+
+These combinators require Emacs 24 for its lexical scope. So they are offered
in a separate package: `dash-functional`.
+
+
address@hidden
address@hidden -partial (fn &rest args)
+Takes a function @var{fn} and fewer than the normal arguments to @var{fn},
+and returns a fn that takes a variable number of additional @var{args}.
+When called, the returned function calls @var{fn} with @var{args} first and
+then additional args.
+
address@hidden
address@hidden
+(funcall (-partial '- 5) 3)
+ @result{} 2
address@hidden group
address@hidden
+(funcall (-partial '+ 5 2) 3)
+ @result{} 10
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -rpartial (fn &rest args)
+Takes a function @var{fn} and fewer than the normal arguments to @var{fn},
+and returns a fn that takes a variable number of additional @var{args}.
+When called, the returned function calls @var{fn} with the additional
+args first and then @var{args}.
+
address@hidden
address@hidden
+(funcall (-rpartial '- 5) 8)
+ @result{} 3
address@hidden group
address@hidden
+(funcall (-rpartial '- 5 2) 10)
+ @result{} 3
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -juxt (&rest fns)
+Takes a list of functions and returns a fn that is the
+juxtaposition of those fns. The returned fn takes a variable
+number of args, and returns a list containing the result of
+applying each fn to the args (left-to-right).
+
address@hidden
address@hidden
+(funcall (-juxt '+ '-) 3 5)
+ @result{} '(8 -2)
address@hidden group
address@hidden
+(-map (-juxt 'identity 'square) '(1 2 3))
+ @result{} '((1 1) (2 4) (3 9))
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -compose (&rest fns)
+Takes a list of functions and returns a fn that is the
+composition of those fns. The returned fn takes a variable
+number of arguments, and returns the result of applying
+each fn to the result of applying the previous fn to
+the arguments (right-to-left).
+
address@hidden
address@hidden
+(funcall (-compose 'square '+) 2 3)
+ @result{} (square (+ 2 3))
address@hidden group
address@hidden
+(funcall (-compose 'identity 'square) 3)
+ @result{} (square 3)
address@hidden group
address@hidden
+(funcall (-compose 'square 'identity) 3)
+ @result{} (square 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -applify (fn)
+Changes an n-arity function @var{fn} to a 1-arity function that
+expects a list with n items as arguments
+
address@hidden
address@hidden
+(-map (-applify '+) '((1 1 1) (1 2 3) (5 5 5)))
+ @result{} '(3 6 15)
address@hidden group
address@hidden
+(-map (-applify (lambda (a b c) (\` ((\, a) ((\, b) ((\, c))))))) '((1 1 1) (1
2 3) (5 5 5)))
+ @result{} '((1 (1 (1))) (1 (2 (3))) (5 (5 (5))))
address@hidden group
address@hidden
+(funcall (-applify '<) '(3 6))
+ @result{} t
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -on (operator transformer)
+Return a function of two arguments that first applies
address@hidden to each of them and then applies @var{operator} on the
+results (in the same order).
+
+In types: (b -> b -> c) -> (a -> b) -> a -> a -> c
+
address@hidden
address@hidden
+(-sort (-on '< 'length) '((1 2 3) (1) (1 2)))
+ @result{} '((1) (1 2) (1 2 3))
address@hidden group
address@hidden
+(-min-by (-on '> 'length) '((1 2 3) (4) (1 2)))
+ @result{} '(4)
address@hidden group
address@hidden
+(-min-by (-on 'string-lessp 'int-to-string) '(2 100 22))
+ @result{} 22
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -flip (func)
+Swap the order of arguments for binary function @var{func}.
+
+In types: (a -> b -> c) -> b -> a -> c
+
address@hidden
address@hidden
+(funcall (-flip '<) 2 1)
+ @result{} t
address@hidden group
address@hidden
+(funcall (-flip '-) 3 8)
+ @result{} 5
address@hidden group
address@hidden
+(-sort (-flip '<) '(4 3 6 1))
+ @result{} '(6 4 3 1)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -const (c)
+Return a function that returns @var{c} ignoring any additional arguments.
+
+In types: a -> b -> a
+
address@hidden
address@hidden
+(funcall (-const 2) 1 3 "foo")
+ @result{} 2
address@hidden group
address@hidden
+(-map (-const 1) '("a" "b" "c" "d"))
+ @result{} '(1 1 1 1)
address@hidden group
address@hidden
+(-sum (-map (-const 1) '("a" "b" "c" "d")))
+ @result{} 4
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -cut (&rest params)
+Take n-ary function and n arguments and specialize some of them.
+Arguments denoted by <> will be left unspecialized.
+
+See @var{srfi-26} for detailed description.
+
address@hidden
address@hidden
+(funcall (-cut list 1 <> 3 <> 5) 2 4)
+ @result{} '(1 2 3 4 5)
address@hidden group
address@hidden
+(-map (-cut funcall <> 5) '(1+ 1- (lambda (x) (/ 1.0 x))))
+ @result{} '(6 4 0.2)
address@hidden group
address@hidden
+(-filter (-cut < <> 5) '(1 3 5 7 9))
+ @result{} '(1 3)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -not (pred)
+Take an unary predicates @var{pred} and return an unary predicate
+that returns t if @var{pred} returns nil and nil if @var{pred} returns
+non-nil.
+
address@hidden
address@hidden
+(funcall (-not 'even?) 5)
+ @result{} t
address@hidden group
address@hidden
+(-filter (-not (-partial '< 4)) '(1 2 3 4 5 6 7 8))
+ @result{} '(1 2 3 4)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -orfn (&rest preds)
+Take list of unary predicates @var{preds} and return an unary
+predicate with argument x that returns non-nil if at least one of
+the @var{preds} returns non-nil on x.
+
+In types: [a -> Bool] -> a -> Bool
+
address@hidden
address@hidden
+(-filter (-orfn 'even? (-partial (-flip '<) 5)) '(1 2 3 4 5 6 7 8 9 10))
+ @result{} '(1 2 3 4 6 8 10)
address@hidden group
address@hidden
+(funcall (-orfn 'stringp 'even?) "foo")
+ @result{} t
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -andfn (&rest preds)
+Take list of unary predicates @var{preds} and return an unary
+predicate with argument x that returns non-nil if all of the
address@hidden returns non-nil on x.
+
+In types: [a -> Bool] -> a -> Bool
+
address@hidden
address@hidden
+(funcall (-andfn (-cut < <> 10) 'even?) 6)
+ @result{} t
address@hidden group
address@hidden
+(funcall (-andfn (-cut < <> 10) 'even?) 12)
+ @result{} nil
address@hidden group
address@hidden
+(-filter (-andfn (-not 'even?) (-cut >= 5 <>)) '(1 2 3 4 5 6 7 8 9 10))
+ @result{} '(1 3 5)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -iteratefn (fn n)
+Return a function @var{fn} composed @var{n} times with itself.
+
address@hidden is a unary function. If you need to use a function of higher
+arity, use @code{-applify} (@pxref{-applify}) first to turn it into an unary
function.
+
+With n = 0, this acts as identity function.
+
+In types: (a -> a) -> Int -> a -> a.
+
+This function satisfies the following law:
+
+ (funcall (-iteratefn fn n) init) = (-last-item (-iterate fn init (1+ n))).
+
address@hidden
address@hidden
+(funcall (-iteratefn (lambda (x) (* x x)) 3) 2)
+ @result{} 256
address@hidden group
address@hidden
+(funcall (-iteratefn '1+ 3) 1)
+ @result{} 4
address@hidden group
address@hidden
+(funcall (-iteratefn 'cdr 3) '(1 2 3 4 5))
+ @result{} '(4 5)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -fixfn (fn &optional equal-test halt-test)
+Return a function that computes the (least) fixpoint of @var{fn}.
+
address@hidden must be a unary function. The returned lambda takes a single
+argument, @var{x}, the initial value for the fixpoint iteration. The
+iteration halts when either of the following conditions is satisified:
+
+ 1. Iteration converges to the fixpoint, with equality being
+ tested using @var{equal-test}. If @var{equal-test} is not specified,
+ @code{equal} is used. For functions over the floating point
+ numbers, it may be necessary to provide an appropriate
+ appoximate comparsion test.
+
+ 2. @var{halt-test} returns a non-nil value. @var{halt-test} defaults to a
+ simple counter that returns t after @code{-fixfn-max-iterations},
+ to guard against infinite iteration. Otherwise, @var{halt-test}
+ must be a function that accepts a single argument, the
+ current value of @var{x}, and returns non-nil as long as iteration
+ should continue. In this way, a more sophisticated
+ convergence test may be supplied by the caller.
+
+The return value of the lambda is either the fixpoint or, if
+iteration halted before converging, a cons with car @code{halted} and
+cdr the final output from @var{halt-test}.
+
+In types: (a -> a) -> a -> a.
+
address@hidden
address@hidden
+(funcall (-fixfn 'cos 'approx-equal) 0.7)
+ @result{} 0.7390851332151607
address@hidden group
address@hidden
+(funcall (-fixfn (lambda (x) (expt (+ x 10) 0.25))) 2.0)
+ @result{} 1.8555845286409378
address@hidden group
address@hidden
+(funcall (-fixfn 'sin 'approx-equal) 0.1)
+ @result{} '(halted . t)
address@hidden group
address@hidden example
address@hidden defun
+
address@hidden
address@hidden -prodfn (&rest fns)
+Take a list of n functions and return a function that takes a
+list of length n, applying i-th function to i-th element of the
+input list. Returns a list of length n.
+
+In types (for n=2): ((a -> b), (c -> d)) -> (a, c) -> (b, d)
+
+This function satisfies the following laws:
+
+ (-compose (-prodfn f g ...) (-prodfn f' g' ...)) = (-prodfn (-compose f
f') (-compose g g') ...)
+ (-prodfn f g ...) = (-juxt (-compose f (-partial 'nth 0)) (-compose g
(-partial 'nth 1)) ...)
+ (-compose (-prodfn f g ...) (-juxt f' g' ...)) = (-juxt (-compose f f')
(-compose g g') ...)
+ (-compose (-partial 'nth n) (-prod f1 f2 ...)) = (-compose fn (-partial
'nth n))
+
address@hidden
address@hidden
+(funcall (-prodfn '1+ '1- 'int-to-string) '(1 2 3))
+ @result{} '(2 1 "3")
address@hidden group
address@hidden
+(-map (-prodfn '1+ '1-) '((1 2) (3 4) (5 6) (7 8)))
+ @result{} '((2 1) (4 3) (6 5) (8 7))
address@hidden group
address@hidden
+(apply '+ (funcall (-prodfn 'length 'string-to-int) '((1 2 3) "15")))
+ @result{} 18
address@hidden group
address@hidden example
address@hidden defun
+
+
address@hidden Development
address@hidden Development
+
+The dash repository is hosted on GitHub:
address@hidden://github.com/magnars/dash.el}
+
address@hidden
+* Contribute:: How to contribute
+* Changes:: List of significant changes by version
+* Contributors:: List of contributors
address@hidden menu
+
address@hidden Contribute
address@hidden Contribute
+
+Yes, please do. Pure functions in the list manipulation realm only,
+please. There's a suite of tests in @verb{~dev/examples.el~}, so remember to
add
+tests for your function, or it might get broken later.
+
+Run the tests with @code{./run-tests.sh}. Create the docs with
address@hidden/create-docs.sh}. I highly recommend that you install these as a
+pre-commit hook, so that the tests are always running and the docs are
+always in sync:
+
address@hidden
+cp pre-commit.sh .git/hooks/pre-commit
address@hidden verbatim
+
+Oh, and don't edit @file{README.md} directly, it is auto-generated.
+Change @file{readme-template.md} or @file{examples-to-docs.el}
+instead. The same goes for the info manual.
+
address@hidden Changes
address@hidden Changes
+
address@hidden Changes in 2.10:
+
address@hidden
address@hidden
+Add @code{-let} destructuring to @code{-if-let} and @code{-when-let}
+(Fredrik Bergroth)
address@hidden itemize
+
address@hidden Changes in 2.9:
+
address@hidden
address@hidden
+Add @code{-let}, @code{-let*} and @code{-lambda} with destructuring
address@hidden
+Add @code{-tree-seq} and @code{-tree-map-nodes}
address@hidden
+Add @code{-non-nil}
address@hidden
+Add @code{-fix}
address@hidden
+Add @code{-fixfn} (dash-functional 1.2)
address@hidden
+Add @code{-copy} (Wilfred Hughes)
address@hidden itemize
+
address@hidden Changes in 2.8:
+
address@hidden
address@hidden
+Add @code{-butlast}
address@hidden itemize
+
address@hidden Changes in 2.7:
+
address@hidden
address@hidden
address@hidden now supports more than two lists (Steve Lamb)
address@hidden
+Add @code{-cycle}, @code{-pad}, @code{-annotate}, @code{-zip-fill}
+(Steve Lamb)
address@hidden
+Add @code{-table}, @code{-table-flat} (finite cartesian product)
address@hidden
+Add @code{-flatten-n}
address@hidden
address@hidden now supports "step" argument
address@hidden
+Add functional combinators @code{-iteratefn}, @code{-prodfn}
address@hidden
+Add @code{-replace}, @code{-splice}, @code{-splice-list} which
+generalize @code{-replace-at} and @code{-insert-at}
address@hidden
+Add @code{-compose}, @code{-iteratefn} and @code{-prodfn}
+(dash-functional 1.1)
address@hidden itemize
+
address@hidden Changes in 2.6:
+
address@hidden
address@hidden
+Add @code{-is-prefix-p}, @code{-is-suffix-p}, @code{-is-infix-p}
+(Matus Goljer)
address@hidden
+Add @code{-iterate}, @code{-unfold} (Matus Goljer)
address@hidden
+Add @code{-split-on}, @code{-split-when} (Matus Goljer)
address@hidden
+Add @code{-find-last-index} (Matus Goljer)
address@hidden
+Add @code{-list} (Johan Andersson)
address@hidden itemize
+
address@hidden Changes in 2.5:
+
address@hidden
address@hidden
+Add @code{-same-items?} (Johan Andersson)
address@hidden
+A few bugfixes
address@hidden itemize
+
address@hidden Changes in 2.4:
+
address@hidden
address@hidden
+Add @code{-snoc} (Matus Goljer)
address@hidden
+Add @code{-replace-at}, @code{-update-at}, @code{-remove-at}, and
address@hidden (Matus Goljer)
address@hidden itemize
+
address@hidden Changes in 2.3:
+
address@hidden
address@hidden
+Add tree operations (Matus Goljer)
address@hidden
+Make font-lock optional
address@hidden itemize
+
address@hidden Changes in 2.2:
+
address@hidden
address@hidden
+Add @code{-compose} (Christina Whyte)
address@hidden itemize
+
address@hidden Changes in 2.1:
+
address@hidden
address@hidden
+Add indexing operations (Matus Goljer)
address@hidden itemize
+
address@hidden Changes in 2.0:
+
address@hidden
address@hidden
+Split out @code{dash-functional.el} (Matus Goljer)
address@hidden
+Add @code{-andfn}, @code{-orfn}, @code{-not}, @code{-cut},
address@hidden, @code{-flip} and @code{-on}. (Matus Goljer)
address@hidden
+Fix @code{-min}, @code{-max}, @code{-min-by} and @code{-max-by} (Matus
+Goljer)
address@hidden itemize
+
address@hidden Changes in 1.8:
+
address@hidden
address@hidden
+Add @code{-first-item} and @code{-last-item} (Wilfred Hughes)
address@hidden itemize
+
address@hidden Changes in 1.7:
+
address@hidden
address@hidden
+Add @code{-rotate} (Matus Goljer)
address@hidden itemize
+
address@hidden Changes in 1.6:
+
address@hidden
address@hidden
+Add @code{-min}, @code{-max}, @code{-min-by} and @code{-max-by} (Johan
+Andersson)
address@hidden itemize
+
address@hidden Changes in 1.5:
+
address@hidden
address@hidden
+Add @code{-sum} and @code{-product} (Johan Andersson)
address@hidden itemize
+
address@hidden Changes in 1.4:
+
address@hidden
address@hidden
+Add @code{-sort}
address@hidden
+Add @code{-reduce-r} (Matus Goljer)
address@hidden
+Add @code{-reduce-r-from} (Matus Goljer)
address@hidden itemize
+
address@hidden Changes in 1.3:
+
address@hidden
address@hidden
+Add @code{-partition-in-steps}
address@hidden
+Add @code{-partition-all-in-steps}
address@hidden itemize
+
address@hidden Changes in 1.2:
+
address@hidden
address@hidden
+Add @code{-last} (Matus Goljer)
address@hidden
+Add @code{-insert-at} (Emanuel Evans)
address@hidden
+Add @code{-when-let} and @code{-if-let} (Emanuel Evans)
address@hidden
+Add @code{-when-let*} and @code{-if-let*} (Emanuel Evans)
address@hidden
+Some bugfixes
address@hidden itemize
+
address@hidden Contributors
address@hidden Contributors
+
address@hidden
address@hidden
address@hidden://github.com/Fuco1,Matus Goljer} contributed lots of
+features and functions.
address@hidden
address@hidden://github.com/tkf,Takafumi Arakaki} contributed
address@hidden
address@hidden
address@hidden://github.com/tali713,tali713} is the author of
address@hidden
address@hidden
address@hidden://github.com/vemv,Víctor M. Valenzuela} contributed
address@hidden
address@hidden
address@hidden://github.com/nicferrier,Nic Ferrier} contributed
address@hidden
address@hidden
address@hidden://github.com/Wilfred,Wilfred Hughes} contributed
address@hidden, @code{-first-item} and @code{-last-item}.
address@hidden
address@hidden://github.com/shosti,Emanuel Evans} contributed
address@hidden, @code{-when-let} and @code{-insert-at}.
address@hidden
address@hidden://github.com/rejeep,Johan Andersson} contributed
address@hidden, @code{-product} and @code{-same-items?}
address@hidden
address@hidden://github.com/kurisuwhyte,Christina Whyte} contributed
address@hidden
address@hidden
address@hidden://github.com/steventlamb,Steve Lamb} contributed
address@hidden, @code{-pad}, @code{-annotate}, @code{-zip-fill} and an
+n-ary version of @code{-zip}.
address@hidden
address@hidden://github.com/fbergroth,Fredrik Bergroth} made the
address@hidden family use @code{-let} destructuring and improved
+script for generating documentation.
address@hidden
address@hidden://github.com/holomorph,Mark Oteiza} contributed the
+script to create an info manual.
address@hidden itemize
+
+Thanks!
+
address@hidden Index
address@hidden Index
+
address@hidden cp
+
address@hidden
- [elpa] externals/dash 549bfd3 366/426: Reorder macros to make sure they are declared before being used, (continued)
- [elpa] externals/dash 549bfd3 366/426: Reorder macros to make sure they are declared before being used, Phillip Lord, 2015/08/04
- [elpa] externals/dash db7f651 353/426: [-let] Simplify the conditions in dash--match-cons-1, Phillip Lord, 2015/08/04
- [elpa] externals/dash c6b92ae 324/426: Reorder the examples into more meaningful blocks, Phillip Lord, 2015/08/04
- [elpa] externals/dash 03b98ca 364/426: Make -if-let and -when-let families destructure their arguments, Phillip Lord, 2015/08/04
- [elpa] externals/dash 5e9c1a9 373/426: Add Fredrik Bergroth to the list of contributors, Phillip Lord, 2015/08/04
- [elpa] externals/dash 8707aaf 367/426: Update docs, Phillip Lord, 2015/08/04
- [elpa] externals/dash 63fa64f 368/426: Add links to references in readme, Phillip Lord, 2015/08/04
- [elpa] externals/dash d459b49 374/426: Fix typo, Phillip Lord, 2015/08/04
- [elpa] externals/dash 9e1a667 360/426: Do not map nodes on conses (be consistent with tree map), Phillip Lord, 2015/08/04
- [elpa] externals/dash 7185db8 311/426: [Issue #83] Add `step` to `-slice`, Phillip Lord, 2015/08/04
- [elpa] externals/dash 2b69c14 411/426: Add dash.info and dash.texi to repo,
Phillip Lord <=
- [elpa] externals/dash c61fc34 417/426: Add -remove-first/last, -map-first/last, -replace-first/last, Phillip Lord, 2015/08/04
- [elpa] externals/dash fb51f8f 304/426: Merge pull request #88 from steventlamb/topic/zip_cycle_pad, Phillip Lord, 2015/08/04
- [elpa] externals/dash d0c6fc0 371/426: Merge pull request #104 from fbergroth/linkify-docs, Phillip Lord, 2015/08/04
- [elpa] externals/dash c08fcba 299/426: Fixed documentation of `-last-item'., Phillip Lord, 2015/08/04
- [elpa] externals/dash f96196a 289/426: Merge pull request #75 from Fuco1/prefix, Phillip Lord, 2015/08/04
- [elpa] externals/dash afe2781 388/426: Merge pull request #109 from bbatsov/threading-indentation, Phillip Lord, 2015/08/04
- [elpa] externals/dash 6b64ea7 303/426: Add functions for flexibly zipping uneven lists, Phillip Lord, 2015/08/04
- [elpa] externals/dash cd137e0 310/426: `-slice` should not fill the returned list with nils if to > length, Phillip Lord, 2015/08/04
- [elpa] externals/dash 5219ac0 422/426: [-let] Eliminate useless re-binding of symbols when sources are immutable, Phillip Lord, 2015/08/04
- [elpa] externals/dash a06e66e 382/426: Add test for clean byte compilation, Phillip Lord, 2015/08/04