From 3f4a0d5370ae6c34afe180df96add3b8522f4af1 Mon Sep 17 00:00:00 2001 From: mattkae Date: Wed, 11 May 2022 09:23:58 -0400 Subject: initial commit --- elpa/dash-20210826.1149/dash-autoloads.el | 74 + elpa/dash-20210826.1149/dash-pkg.el | 12 + elpa/dash-20210826.1149/dash.el | 3531 +++++++++++++++++++++ elpa/dash-20210826.1149/dash.elc | Bin 0 -> 138391 bytes elpa/dash-20210826.1149/dash.info | 4738 +++++++++++++++++++++++++++++ elpa/dash-20210826.1149/dir | 18 + 6 files changed, 8373 insertions(+) create mode 100644 elpa/dash-20210826.1149/dash-autoloads.el create mode 100644 elpa/dash-20210826.1149/dash-pkg.el create mode 100644 elpa/dash-20210826.1149/dash.el create mode 100644 elpa/dash-20210826.1149/dash.elc create mode 100644 elpa/dash-20210826.1149/dash.info create mode 100644 elpa/dash-20210826.1149/dir (limited to 'elpa/dash-20210826.1149') diff --git a/elpa/dash-20210826.1149/dash-autoloads.el b/elpa/dash-20210826.1149/dash-autoloads.el new file mode 100644 index 0000000..3a96693 --- /dev/null +++ b/elpa/dash-20210826.1149/dash-autoloads.el @@ -0,0 +1,74 @@ +;;; dash-autoloads.el --- automatically extracted autoloads +;; +;;; Code: + +(add-to-list 'load-path (directory-file-name + (or (file-name-directory #$) (car load-path)))) + + +;;;### (autoloads nil "dash" "dash.el" (0 0 0 0)) +;;; Generated autoloads from dash.el + +(autoload 'dash-fontify-mode "dash" "\ +Toggle fontification of Dash special variables. + +If called interactively, enable Dash-Fontify mode if ARG is +positive, and disable it if ARG is zero or negative. If called +from Lisp, also enable the mode if ARG is omitted or nil, and +toggle it if ARG is `toggle'; disable the mode otherwise. + +Dash-Fontify mode is a buffer-local minor mode intended for Emacs +Lisp buffers. Enabling it causes the special variables bound in +anaphoric Dash macros to be fontified. These anaphoras include +`it', `it-index', `acc', and `other'. In older Emacs versions +which do not dynamically detect macros, Dash-Fontify mode +additionally fontifies Dash macro calls. + +See also `dash-fontify-mode-lighter' and +`global-dash-fontify-mode'. + +\(fn &optional ARG)" t nil) + +(put 'global-dash-fontify-mode 'globalized-minor-mode t) + +(defvar global-dash-fontify-mode nil "\ +Non-nil if Global Dash-Fontify mode is enabled. +See the `global-dash-fontify-mode' command +for a description of this minor mode. +Setting this variable directly does not take effect; +either customize it (see the info node `Easy Customization') +or call the function `global-dash-fontify-mode'.") + +(custom-autoload 'global-dash-fontify-mode "dash" nil) + +(autoload 'global-dash-fontify-mode "dash" "\ +Toggle Dash-Fontify mode in all buffers. +With prefix ARG, enable Global Dash-Fontify mode if ARG is positive; +otherwise, disable it. If called from Lisp, enable the mode if +ARG is omitted or nil. + +Dash-Fontify mode is enabled in all buffers where +`dash--turn-on-fontify-mode' would do it. +See `dash-fontify-mode' for more information on Dash-Fontify mode. + +\(fn &optional ARG)" t nil) + +(autoload 'dash-register-info-lookup "dash" "\ +Register the Dash Info manual with `info-lookup-symbol'. +This allows Dash symbols to be looked up with \\[info-lookup-symbol]." t nil) + +(if (fboundp 'register-definition-prefixes) (register-definition-prefixes "dash" '("!cdr" "!cons" "--" "->" "-a" "-butlast" "-c" "-d" "-e" "-f" "-gr" "-i" "-juxt" "-keep" "-l" "-m" "-no" "-o" "-p" "-r" "-s" "-t" "-u" "-value-to-list" "-when-let" "-zip" "dash-"))) + +;;;*** + +;;;### (autoloads nil nil ("dash-pkg.el") (0 0 0 0)) + +;;;*** + +;; Local Variables: +;; version-control: never +;; no-byte-compile: t +;; no-update-autoloads: t +;; coding: utf-8 +;; End: +;;; dash-autoloads.el ends here diff --git a/elpa/dash-20210826.1149/dash-pkg.el b/elpa/dash-20210826.1149/dash-pkg.el new file mode 100644 index 0000000..7dc2d7a --- /dev/null +++ b/elpa/dash-20210826.1149/dash-pkg.el @@ -0,0 +1,12 @@ +(define-package "dash" "20210826.1149" "A modern list library for Emacs" + '((emacs "24")) + :commit "da167c51e9fd167a48d06c7c0ee8e3ac7abd9718" :authors + '(("Magnar Sveen" . "magnars@gmail.com")) + :maintainer + '("Magnar Sveen" . "magnars@gmail.com") + :keywords + '("extensions" "lisp") + :url "https://github.com/magnars/dash.el") +;; Local Variables: +;; no-byte-compile: t +;; End: diff --git a/elpa/dash-20210826.1149/dash.el b/elpa/dash-20210826.1149/dash.el new file mode 100644 index 0000000..6386c5f --- /dev/null +++ b/elpa/dash-20210826.1149/dash.el @@ -0,0 +1,3531 @@ +;;; dash.el --- A modern list library for Emacs -*- lexical-binding: t -*- + +;; Copyright (C) 2012-2021 Free Software Foundation, Inc. + +;; Author: Magnar Sveen +;; Version: 2.19.1 +;; Package-Requires: ((emacs "24")) +;; Keywords: extensions, lisp +;; Homepage: https://github.com/magnars/dash.el + +;; 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 . + +;;; Commentary: + +;; A modern list API for Emacs. +;; +;; See its overview at https://github.com/magnars/dash.el#functions. + +;;; Code: + +;; TODO: `gv' was introduced in Emacs 24.3, so remove this and all +;; calls to `defsetf' when support for earlier versions is dropped. +(eval-when-compile + (unless (fboundp 'gv-define-setter) + (require 'cl))) + +(defgroup dash () + "Customize group for Dash, a modern list library." + :group 'extensions + :group 'lisp + :prefix "dash-") + +(defmacro !cons (car cdr) + "Destructive: Set CDR to the cons of CAR and CDR." + (declare (debug (form symbolp))) + `(setq ,cdr (cons ,car ,cdr))) + +(defmacro !cdr (list) + "Destructive: Set LIST to the cdr of LIST." + (declare (debug (symbolp))) + `(setq ,list (cdr ,list))) + +(defmacro --each (list &rest body) + "Evaluate BODY for each element of LIST and return nil. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating BODY. +This is the anaphoric counterpart to `-each'." + (declare (debug (form body)) (indent 1)) + (let ((l (make-symbol "list")) + (i (make-symbol "i"))) + `(let ((,l ,list) + (,i 0) + it it-index) + (ignore it it-index) + (while ,l + (setq it (pop ,l) it-index ,i ,i (1+ ,i)) + ,@body)))) + +(defun -each (list fn) + "Call FN on each element of LIST. +Return nil; this function is intended for side effects. + +Its anaphoric counterpart is `--each'. + +For access to the current element's index in LIST, see +`-each-indexed'." + (declare (indent 1)) + (ignore (mapc fn list))) + +(defalias '--each-indexed '--each) + +(defun -each-indexed (list fn) + "Call FN on each index and element of LIST. +For each ITEM at INDEX in LIST, call (funcall FN INDEX ITEM). +Return nil; this function is intended for side effects. + +See also: `-map-indexed'." + (declare (indent 1)) + (--each list (funcall fn it-index it))) + +(defmacro --each-while (list pred &rest body) + "Evaluate BODY for each item in LIST, while PRED evaluates to non-nil. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating PRED or BODY. Once +an element is reached for which PRED evaluates to nil, no further +BODY is evaluated. The return value is always nil. +This is the anaphoric counterpart to `-each-while'." + (declare (debug (form form body)) (indent 2)) + (let ((l (make-symbol "list")) + (i (make-symbol "i")) + (elt (make-symbol "elt"))) + `(let ((,l ,list) + (,i 0) + ,elt it it-index) + (ignore it it-index) + (while (and ,l (setq ,elt (pop ,l) it ,elt it-index ,i) ,pred) + (setq it ,elt it-index ,i ,i (1+ ,i)) + ,@body)))) + +(defun -each-while (list pred fn) + "Call FN on each ITEM in LIST, while (PRED ITEM) is non-nil. +Once an ITEM is reached for which PRED returns nil, FN is no +longer called. Return nil; this function is intended for side +effects. + +Its anaphoric counterpart is `--each-while'." + (declare (indent 2)) + (--each-while list (funcall pred it) (funcall fn it))) + +(defmacro --each-r (list &rest body) + "Evaluate BODY for each element of LIST in reversed order. +Each element of LIST in turn, starting at its end, is bound to +`it' and its index within LIST to `it-index' before evaluating +BODY. The return value is always nil. +This is the anaphoric counterpart to `-each-r'." + (declare (debug (form body)) (indent 1)) + (let ((v (make-symbol "vector")) + (i (make-symbol "i"))) + ;; Implementation note: building a vector is considerably faster + ;; than building a reversed list (vector takes less memory, so + ;; there is less GC), plus `length' comes naturally. In-place + ;; `nreverse' would be faster still, but BODY would be able to see + ;; that, even if the modification was undone before we return. + `(let* ((,v (vconcat ,list)) + (,i (length ,v)) + it it-index) + (ignore it it-index) + (while (> ,i 0) + (setq ,i (1- ,i) it-index ,i it (aref ,v ,i)) + ,@body)))) + +(defun -each-r (list fn) + "Call FN on each element of LIST in reversed order. +Return nil; this function is intended for side effects. + +Its anaphoric counterpart is `--each-r'." + (--each-r list (funcall fn it))) + +(defmacro --each-r-while (list pred &rest body) + "Eval BODY for each item in reversed LIST, while PRED evals to non-nil. +Each element of LIST in turn, starting at its end, is bound to +`it' and its index within LIST to `it-index' before evaluating +PRED or BODY. Once an element is reached for which PRED +evaluates to nil, no further BODY is evaluated. The return value +is always nil. +This is the anaphoric counterpart to `-each-r-while'." + (declare (debug (form form body)) (indent 2)) + (let ((v (make-symbol "vector")) + (i (make-symbol "i")) + (elt (make-symbol "elt"))) + `(let* ((,v (vconcat ,list)) + (,i (length ,v)) + ,elt it it-index) + (ignore it it-index) + (while (when (> ,i 0) + (setq ,i (1- ,i) it-index ,i) + (setq ,elt (aref ,v ,i) it ,elt) + ,pred) + (setq it-index ,i it ,elt) + ,@body)))) + +(defun -each-r-while (list pred fn) + "Call FN on each ITEM in reversed LIST, while (PRED ITEM) is non-nil. +Once an ITEM is reached for which PRED returns nil, FN is no +longer called. Return nil; this function is intended for side +effects. + +Its anaphoric counterpart is `--each-r-while'." + (--each-r-while list (funcall pred it) (funcall fn it))) + +(defmacro --dotimes (num &rest body) + "Evaluate BODY NUM times, presumably for side effects. +BODY is evaluated with the local variable `it' temporarily bound +to successive integers running from 0, inclusive, to NUM, +exclusive. BODY is not evaluated if NUM is less than 1. +This is the anaphoric counterpart to `-dotimes'." + (declare (debug (form body)) (indent 1)) + (let ((n (make-symbol "num")) + (i (make-symbol "i"))) + `(let ((,n ,num) + (,i 0) + it) + (ignore it) + (while (< ,i ,n) + (setq it ,i ,i (1+ ,i)) + ,@body)))) + +(defun -dotimes (num fn) + "Call FN NUM times, presumably for side effects. +FN is called with a single argument on successive integers +running from 0, inclusive, to NUM, exclusive. FN is not called +if NUM is less than 1. + +This function's anaphoric counterpart is `--dotimes'." + (declare (indent 1)) + (--dotimes num (funcall fn it))) + +(defun -map (fn list) + "Apply FN to each item in LIST and return the list of results. + +This function's anaphoric counterpart is `--map'." + (mapcar fn list)) + +(defmacro --map (form list) + "Eval FORM for each item in LIST and return the list of results. +Each element of LIST in turn is bound to `it' before evaluating +FORM. +This is the anaphoric counterpart to `-map'." + (declare (debug (def-form form))) + `(mapcar (lambda (it) (ignore it) ,form) ,list)) + +(defmacro --reduce-from (form init list) + "Accumulate a value by evaluating FORM across LIST. +This macro is like `--each' (which see), but it additionally +provides an accumulator variable `acc' which it successively +binds to the result of evaluating FORM for the current LIST +element before processing the next element. For the first +element, `acc' is initialized with the result of evaluating INIT. +The return value is the resulting value of `acc'. If LIST is +empty, FORM is not evaluated, and the return value is the result +of INIT. +This is the anaphoric counterpart to `-reduce-from'." + (declare (debug (form form form))) + `(let ((acc ,init)) + (--each ,list (setq acc ,form)) + acc)) + +(defun -reduce-from (fn init list) + "Reduce the function FN across LIST, starting with INIT. +Return the result of applying FN to INIT and the first element of +LIST, then applying FN to that result and the second element, +etc. If LIST is empty, return INIT without calling FN. + +This function's anaphoric counterpart is `--reduce-from'. + +For other folds, see also `-reduce' and `-reduce-r'." + (--reduce-from (funcall fn acc it) init list)) + +(defmacro --reduce (form list) + "Accumulate a value by evaluating FORM across LIST. +This macro is like `--reduce-from' (which see), except the first +element of LIST is taken as INIT. Thus if LIST contains a single +item, it is returned without evaluating FORM. If LIST is empty, +FORM is evaluated with `it' and `acc' bound to nil. +This is the anaphoric counterpart to `-reduce'." + (declare (debug (form form))) + (let ((lv (make-symbol "list-value"))) + `(let ((,lv ,list)) + (if ,lv + (--reduce-from ,form (car ,lv) (cdr ,lv)) + ;; Explicit nil binding pacifies lexical "variable left uninitialized" + ;; warning. See issue #377 and upstream https://bugs.gnu.org/47080. + (let ((acc nil) (it nil)) + (ignore acc it) + ,form))))) + +(defun -reduce (fn list) + "Reduce the function FN across LIST. +Return the result of applying FN to the first two elements of +LIST, then applying FN to that result and the third element, etc. +If LIST contains a single element, return it without calling FN. +If LIST is empty, return the result of calling FN with no +arguments. + +This function's anaphoric counterpart is `--reduce'. + +For other folds, see also `-reduce-from' and `-reduce-r'." + (if list + (-reduce-from fn (car list) (cdr list)) + (funcall fn))) + +(defmacro --reduce-r-from (form init list) + "Accumulate a value by evaluating FORM across LIST in reverse. +This macro is like `--reduce-from', except it starts from the end +of LIST. +This is the anaphoric counterpart to `-reduce-r-from'." + (declare (debug (form form form))) + `(let ((acc ,init)) + (--each-r ,list (setq acc ,form)) + acc)) + +(defun -reduce-r-from (fn init list) + "Reduce the function FN across LIST in reverse, starting with INIT. +Return the result of applying FN to the last element of LIST and +INIT, then applying FN to the second-to-last element and the +previous result of FN, etc. That is, the first argument of FN is +the current element, and its second argument the accumulated +value. If LIST is empty, return INIT without calling FN. + +This function is like `-reduce-from' but the operation associates +from the right rather than left. In other words, it starts from +the end of LIST and flips the arguments to FN. Conceptually, it +is like replacing the conses in LIST with applications of FN, and +its last link with INIT, and evaluating the resulting expression. + +This function's anaphoric counterpart is `--reduce-r-from'. + +For other folds, see also `-reduce-r' and `-reduce'." + (--reduce-r-from (funcall fn it acc) init list)) + +(defmacro --reduce-r (form list) + "Accumulate a value by evaluating FORM across LIST in reverse order. +This macro is like `--reduce', except it starts from the end of +LIST. +This is the anaphoric counterpart to `-reduce-r'." + (declare (debug (form form))) + `(--reduce ,form (reverse ,list))) + +(defun -reduce-r (fn list) + "Reduce the function FN across LIST in reverse. +Return the result of applying FN to the last two elements of +LIST, then applying FN to the third-to-last element and the +previous result of FN, etc. That is, the first argument of FN is +the current element, and its second argument the accumulated +value. If LIST contains a single element, return it without +calling FN. If LIST is empty, return the result of calling FN +with no arguments. + +This function is like `-reduce' but the operation associates from +the right rather than left. In other words, it starts from the +end of LIST and flips the arguments to FN. Conceptually, it is +like replacing the conses in LIST with applications of FN, +ignoring its last link, and evaluating the resulting expression. + +This function's anaphoric counterpart is `--reduce-r'. + +For other folds, see also `-reduce-r-from' and `-reduce'." + (if list + (--reduce-r (funcall fn it acc) list) + (funcall fn))) + +(defmacro --reductions-from (form init list) + "Return a list of FORM's intermediate reductions across LIST. +That is, a list of the intermediate values of the accumulator +when `--reduce-from' (which see) is called with the same +arguments. +This is the anaphoric counterpart to `-reductions-from'." + (declare (debug (form form form))) + `(nreverse + (--reduce-from (cons (let ((acc (car acc))) (ignore acc) ,form) acc) + (list ,init) + ,list))) + +(defun -reductions-from (fn init list) + "Return a list of FN's intermediate reductions across LIST. +That is, a list of the intermediate values of the accumulator +when `-reduce-from' (which see) is called with the same +arguments. + +This function's anaphoric counterpart is `--reductions-from'. + +For other folds, see also `-reductions' and `-reductions-r'." + (--reductions-from (funcall fn acc it) init list)) + +(defmacro --reductions (form list) + "Return a list of FORM's intermediate reductions across LIST. +That is, a list of the intermediate values of the accumulator +when `--reduce' (which see) is called with the same arguments. +This is the anaphoric counterpart to `-reductions'." + (declare (debug (form form))) + (let ((lv (make-symbol "list-value"))) + `(let ((,lv ,list)) + (if ,lv + (--reductions-from ,form (car ,lv) (cdr ,lv)) + (let (acc it) + (ignore acc it) + (list ,form)))))) + +(defun -reductions (fn list) + "Return a list of FN's intermediate reductions across LIST. +That is, a list of the intermediate values of the accumulator +when `-reduce' (which see) is called with the same arguments. + +This function's anaphoric counterpart is `--reductions'. + +For other folds, see also `-reductions' and `-reductions-r'." + (if list + (--reductions-from (funcall fn acc it) (car list) (cdr list)) + (list (funcall fn)))) + +(defmacro --reductions-r-from (form init list) + "Return a list of FORM's intermediate reductions across reversed LIST. +That is, a list of the intermediate values of the accumulator +when `--reduce-r-from' (which see) is called with the same +arguments. +This is the anaphoric counterpart to `-reductions-r-from'." + (declare (debug (form form form))) + `(--reduce-r-from (cons (let ((acc (car acc))) (ignore acc) ,form) acc) + (list ,init) + ,list)) + +(defun -reductions-r-from (fn init list) + "Return a list of FN's intermediate reductions across reversed LIST. +That is, a list of the intermediate values of the accumulator +when `-reduce-r-from' (which see) is called with the same +arguments. + +This function's anaphoric counterpart is `--reductions-r-from'. + +For other folds, see also `-reductions' and `-reductions-r'." + (--reductions-r-from (funcall fn it acc) init list)) + +(defmacro --reductions-r (form list) + "Return a list of FORM's intermediate reductions across reversed LIST. +That is, a list of the intermediate values of the accumulator +when `--reduce-re' (which see) is called with the same arguments. +This is the anaphoric counterpart to `-reductions-r'." + (declare (debug (form list))) + (let ((lv (make-symbol "list-value"))) + `(let ((,lv (reverse ,list))) + (if ,lv + (--reduce-from (cons (let ((acc (car acc))) (ignore acc) ,form) acc) + (list (car ,lv)) + (cdr ,lv)) + ;; Explicit nil binding pacifies lexical "variable left uninitialized" + ;; warning. See issue #377 and upstream https://bugs.gnu.org/47080. + (let ((acc nil) (it nil)) + (ignore acc it) + (list ,form)))))) + +(defun -reductions-r (fn list) + "Return a list of FN's intermediate reductions across reversed LIST. +That is, a list of the intermediate values of the accumulator +when `-reduce-r' (which see) is called with the same arguments. + +This function's anaphoric counterpart is `--reductions-r'. + +For other folds, see also `-reductions-r-from' and +`-reductions'." + (if list + (--reductions-r (funcall fn it acc) list) + (list (funcall fn)))) + +(defmacro --filter (form list) + "Return a new list of the items in LIST for which FORM evals to non-nil. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. +This is the anaphoric counterpart to `-filter'. +For the opposite operation, see also `--remove'." + (declare (debug (form form))) + (let ((r (make-symbol "result"))) + `(let (,r) + (--each ,list (when ,form (push it ,r))) + (nreverse ,r)))) + +(defun -filter (pred list) + "Return a new list of the items in LIST for which PRED returns non-nil. + +Alias: `-select'. + +This function's anaphoric counterpart is `--filter'. + +For similar operations, see also `-keep' and `-remove'." + (--filter (funcall pred it) list)) + +(defalias '-select '-filter) +(defalias '--select '--filter) + +(defmacro --remove (form list) + "Return a new list of the items in LIST for which FORM evals to nil. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. +This is the anaphoric counterpart to `-remove'. +For the opposite operation, see also `--filter'." + (declare (debug (form form))) + `(--filter (not ,form) ,list)) + +(defun -remove (pred list) + "Return a new list of the items in LIST for which PRED returns nil. + +Alias: `-reject'. + +This function's anaphoric counterpart is `--remove'. + +For similar operations, see also `-keep' and `-filter'." + (--remove (funcall pred it) list)) + +(defalias '-reject '-remove) +(defalias '--reject '--remove) + +(defmacro --remove-first (form list) + "Remove the first item from LIST for which FORM evals to non-nil. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. This is a +non-destructive operation, but only the front of LIST leading up +to the removed item is a copy; the rest is LIST's original tail. +If no item is removed, then the result is a complete copy. +This is the anaphoric counterpart to `-remove-first'." + (declare (debug (form form))) + (let ((front (make-symbol "front")) + (tail (make-symbol "tail"))) + `(let ((,tail ,list) ,front) + (--each-while ,tail (not ,form) + (push (pop ,tail) ,front)) + (if ,tail + (nconc (nreverse ,front) (cdr ,tail)) + (nreverse ,front))))) + +(defun -remove-first (pred list) + "Remove the first item from LIST for which PRED returns non-nil. +This is a non-destructive operation, but only the front of LIST +leading up to the removed item is a copy; the rest is LIST's +original tail. If no item is removed, then the result is a +complete copy. + +Alias: `-reject-first'. + +This function's anaphoric counterpart is `--remove-first'. + +See also `-map-first', `-remove-item', and `-remove-last'." + (--remove-first (funcall pred it) list)) + +(defalias '-reject-first '-remove-first) +(defalias '--reject-first '--remove-first) + +(defmacro --remove-last (form list) + "Remove the last item from LIST for which FORM evals to non-nil. +Each element of LIST in turn is bound to `it' before evaluating +FORM. The result is a copy of LIST regardless of whether an +element is removed. +This is the anaphoric counterpart to `-remove-last'." + (declare (debug (form form))) + `(nreverse (--remove-first ,form (reverse ,list)))) + +(defun -remove-last (pred list) + "Remove the last item from LIST for which PRED returns non-nil. +The result is a copy of LIST regardless of whether an element is +removed. + +Alias: `-reject-last'. + +This function's anaphoric counterpart is `--remove-last'. + +See also `-map-last', `-remove-item', and `-remove-first'." + (--remove-last (funcall pred it) list)) + +(defalias '-reject-last '-remove-last) +(defalias '--reject-last '--remove-last) + +(defalias '-remove-item #'remove + "Return a copy of LIST with all occurrences of ITEM removed. +The comparison is done with `equal'. +\n(fn ITEM LIST)") + +(defmacro --keep (form list) + "Eval FORM for each item in LIST and return the non-nil results. +Like `--filter', but returns the non-nil results of FORM instead +of the corresponding elements of LIST. Each element of LIST in +turn is bound to `it' and its index within LIST to `it-index' +before evaluating FORM. +This is the anaphoric counterpart to `-keep'." + (declare (debug (form form))) + (let ((r (make-symbol "result")) + (m (make-symbol "mapped"))) + `(let (,r) + (--each ,list (let ((,m ,form)) (when ,m (push ,m ,r)))) + (nreverse ,r)))) + +(defun -keep (fn list) + "Return a new list of the non-nil results of applying FN to each item in LIST. +Like `-filter', but returns the non-nil results of FN instead of +the corresponding elements of LIST. + +Its anaphoric counterpart is `--keep'." + (--keep (funcall fn it) list)) + +(defun -non-nil (list) + "Return a copy of LIST with all nil items removed." + (declare (pure t) (side-effect-free t)) + (--filter it list)) + +(defmacro --map-indexed (form list) + "Eval FORM for each item in LIST and return the list of results. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. This is like +`--map', but additionally makes `it-index' available to FORM. + +This is the anaphoric counterpart to `-map-indexed'." + (declare (debug (form form))) + (let ((r (make-symbol "result"))) + `(let (,r) + (--each ,list + (push ,form ,r)) + (nreverse ,r)))) + +(defun -map-indexed (fn list) + "Apply FN to each index and item in LIST and return the list of results. +This is like `-map', but FN takes two arguments: the index of the +current element within LIST, and the element itself. + +This function's anaphoric counterpart is `--map-indexed'. + +For a side-effecting variant, see also `-each-indexed'." + (--map-indexed (funcall fn it-index it) list)) + +(defmacro --map-when (pred rep list) + "Anaphoric form of `-map-when'." + (declare (debug (form form form))) + (let ((r (make-symbol "result"))) + `(let (,r) + (--each ,list (!cons (if ,pred ,rep it) ,r)) + (nreverse ,r)))) + +(defun -map-when (pred rep list) + "Return a new list where the elements in LIST that do 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'" + (--map-when (funcall pred it) (funcall rep it) list)) + +(defalias '-replace-where '-map-when) +(defalias '--replace-where '--map-when) + +(defun -map-first (pred rep list) + "Replace first item in LIST satisfying PRED with result of REP called on this item. + +See also: `-map-when', `-replace-first'" + (let (front) + (while (and list (not (funcall pred (car list)))) + (push (car list) front) + (!cdr list)) + (if list + (-concat (nreverse front) (cons (funcall rep (car list)) (cdr list))) + (nreverse front)))) + +(defmacro --map-first (pred rep list) + "Anaphoric form of `-map-first'." + (declare (debug (def-form def-form form))) + `(-map-first (lambda (it) ,pred) (lambda (it) (ignore it) ,rep) ,list)) + +(defun -map-last (pred rep list) + "Replace last item in LIST satisfying PRED with result of REP called on this item. + +See also: `-map-when', `-replace-last'" + (nreverse (-map-first pred rep (reverse list)))) + +(defmacro --map-last (pred rep list) + "Anaphoric form of `-map-last'." + (declare (debug (def-form def-form form))) + `(-map-last (lambda (it) ,pred) (lambda (it) (ignore it) ,rep) ,list)) + +(defun -replace (old new list) + "Replace all OLD items in LIST with NEW. + +Elements are compared using `equal'. + +See also: `-replace-at'" + (declare (pure t) (side-effect-free t)) + (--map-when (equal it old) new list)) + +(defun -replace-first (old new list) + "Replace the first occurrence of OLD with NEW in LIST. + +Elements are compared using `equal'. + +See also: `-map-first'" + (declare (pure t) (side-effect-free t)) + (--map-first (equal old it) new list)) + +(defun -replace-last (old new list) + "Replace the last occurrence of OLD with NEW in LIST. + +Elements are compared using `equal'. + +See also: `-map-last'" + (declare (pure t) (side-effect-free t)) + (--map-last (equal old it) new list)) + +(defmacro --mapcat (form list) + "Anaphoric form of `-mapcat'." + (declare (debug (form form))) + `(apply 'append (--map ,form ,list))) + +(defun -mapcat (fn list) + "Return the concatenation of the result of mapping FN over LIST. +Thus function FN should return a list." + (--mapcat (funcall fn it) list)) + +(defmacro --iterate (form init n) + "Anaphoric version of `-iterate'." + (declare (debug (form form form))) + (let ((res (make-symbol "result")) + (len (make-symbol "n"))) + `(let ((,len ,n)) + (when (> ,len 0) + (let* ((it ,init) + (,res (list it))) + (dotimes (_ (1- ,len)) + (push (setq it ,form) ,res)) + (nreverse ,res)))))) + +(defun -iterate (fun init n) + "Return a list of iterated applications of FUN to INIT. + +This means a list of the form: + + (INIT (FUN INIT) (FUN (FUN INIT)) ...) + +N is the length of the returned list." + (--iterate (funcall fun it) init n)) + +(defun -flatten (l) + "Take a nested list L and return its contents as a single, flat list. + +Note that because `nil' represents a list of zero elements (an +empty list), any mention of nil in L will disappear after +flattening. If you need to preserve nils, consider `-flatten-n' +or map them to some unique symbol and then map them back. + +Conses of two atoms are considered \"terminals\", that is, they +aren't flattened further. + +See also: `-flatten-n'" + (declare (pure t) (side-effect-free t)) + (if (and (listp l) (listp (cdr l))) + (-mapcat '-flatten l) + (list l))) + +(defun -flatten-n (num list) + "Flatten NUM levels of a nested LIST. + +See also: `-flatten'" + (declare (pure t) (side-effect-free t)) + (dotimes (_ num) + (setq list (apply #'append (mapcar #'-list list)))) + list) + +(defun -concat (&rest lists) + "Return a new list with the concatenation of the elements in the supplied LISTS." + (declare (pure t) (side-effect-free t)) + (apply 'append lists)) + +(defalias '-copy 'copy-sequence + "Create a shallow copy of LIST. + +\(fn LIST)") + +(defun -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', `-insert-at'" + (let (r) + (--each list + (if (funcall pred it) + (let ((new (funcall fun it))) + (--each new (!cons it r))) + (!cons it r))) + (nreverse r))) + +(defmacro --splice (pred form list) + "Anaphoric form of `-splice'." + (declare (debug (def-form def-form form))) + `(-splice (lambda (it) ,pred) (lambda (it) ,form) ,list)) + +(defun -splice-list (pred new-list list) + "Splice NEW-LIST in place of elements matching PRED in LIST. + +See also: `-splice', `-insert-at'" + (-splice pred (lambda (_) new-list) list)) + +(defmacro --splice-list (pred new-list list) + "Anaphoric form of `-splice-list'." + (declare (debug (def-form form form))) + `(-splice-list (lambda (it) ,pred) ,new-list ,list)) + +(defun -cons* (&rest args) + "Make a new list from the elements of ARGS. +The last 2 elements of ARGS are used as the final cons of the +result, so if the final element of ARGS is not a list, the result +is a dotted list. With no ARGS, return nil." + (declare (pure t) (side-effect-free t)) + (let* ((len (length args)) + (tail (nthcdr (- len 2) args)) + (last (cdr tail))) + (if (null last) + (car args) + (setcdr tail (car last)) + args))) + +(defun -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." + (-concat list (list elem) elements)) + +(defmacro --first (form list) + "Return the first item in LIST for which FORM evals to non-nil. +Return nil if no such element is found. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. +This is the anaphoric counterpart to `-first'." + (declare (debug (form form))) + (let ((n (make-symbol "needle"))) + `(let (,n) + (--each-while ,list (or (not ,form) + (ignore (setq ,n it)))) + ,n))) + +(defun -first (pred list) + "Return the first item in LIST for which PRED returns non-nil. +Return nil if no such element is found. +To get the first item in the list no questions asked, use `car'. + +Alias: `-find'. + +This function's anaphoric counterpart is `--first'." + (--first (funcall pred it) list)) + +(defalias '-find '-first) +(defalias '--find '--first) + +(defmacro --some (form list) + "Return non-nil if FORM evals to non-nil for at least one item in LIST. +If so, return the first such result of FORM. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. +This is the anaphoric counterpart to `-some'." + (declare (debug (form form))) + (let ((n (make-symbol "needle"))) + `(let (,n) + (--each-while ,list (not (setq ,n ,form))) + ,n))) + +(defun -some (pred list) + "Return (PRED x) for the first LIST item where (PRED x) is non-nil, else nil. + +Alias: `-any'. + +This function's anaphoric counterpart is `--some'." + (--some (funcall pred it) list)) + +(defalias '-any '-some) +(defalias '--any '--some) + +(defmacro --every (form list) + "Return non-nil if FORM evals to non-nil for all items in LIST. +If so, return the last such result of FORM. Otherwise, once an +item is reached for which FORM yields nil, return nil without +evaluating FORM for any further LIST elements. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. + +This macro is like `--every-p', but on success returns the last +non-nil result of FORM instead of just t. + +This is the anaphoric counterpart to `-every'." + (declare (debug (form form))) + (let ((a (make-symbol "all"))) + `(let ((,a t)) + (--each-while ,list (setq ,a ,form)) + ,a))) + +(defun -every (pred list) + "Return non-nil if PRED returns non-nil for all items in LIST. +If so, return the last such result of PRED. Otherwise, once an +item is reached for which PRED returns nil, return nil without +calling PRED on any further LIST elements. + +This function is like `-every-p', but on success returns the last +non-nil result of PRED instead of just t. + +This function's anaphoric counterpart is `--every'." + (--every (funcall pred it) list)) + +(defmacro --last (form list) + "Anaphoric form of `-last'." + (declare (debug (form form))) + (let ((n (make-symbol "needle"))) + `(let (,n) + (--each ,list + (when ,form (setq ,n it))) + ,n))) + +(defun -last (pred list) + "Return the last x in LIST where (PRED x) is non-nil, else nil." + (--last (funcall pred it) list)) + +(defalias '-first-item 'car + "Return the first item of LIST, or nil on an empty list. + +See also: `-second-item', `-last-item'. + +\(fn LIST)") + +;; Ensure that calls to `-first-item' are compiled to a single opcode, +;; just like `car'. +(put '-first-item 'byte-opcode 'byte-car) +(put '-first-item 'byte-compile 'byte-compile-one-arg) + +(defalias '-second-item 'cadr + "Return the second item of LIST, or nil if LIST is too short. + +See also: `-third-item'. + +\(fn LIST)") + +(defalias '-third-item + (if (fboundp 'caddr) + #'caddr + (lambda (list) (car (cddr list)))) + "Return the third item of LIST, or nil if LIST is too short. + +See also: `-fourth-item'. + +\(fn LIST)") + +(defun -fourth-item (list) + "Return the fourth item of LIST, or nil if LIST is too short. + +See also: `-fifth-item'." + (declare (pure t) (side-effect-free t)) + (car (cdr (cdr (cdr list))))) + +(defun -fifth-item (list) + "Return the fifth item of LIST, or nil if LIST is too short. + +See also: `-last-item'." + (declare (pure t) (side-effect-free t)) + (car (cdr (cdr (cdr (cdr list)))))) + +(defun -last-item (list) + "Return the last item of LIST, or nil on an empty list." + (declare (pure t) (side-effect-free t)) + (car (last list))) + +;; Use `with-no-warnings' to suppress unbound `-last-item' or +;; undefined `gv--defsetter' warnings arising from both +;; `gv-define-setter' and `defsetf' in certain Emacs versions. +(with-no-warnings + (if (fboundp 'gv-define-setter) + (gv-define-setter -last-item (val x) `(setcar (last ,x) ,val)) + (defsetf -last-item (x) (val) `(setcar (last ,x) ,val)))) + +(defun -butlast (list) + "Return a list of all items in list except for the last." + ;; no alias as we don't want magic optional argument + (declare (pure t) (side-effect-free t)) + (butlast list)) + +(defmacro --count (pred list) + "Anaphoric form of `-count'." + (declare (debug (form form))) + (let ((r (make-symbol "result"))) + `(let ((,r 0)) + (--each ,list (when ,pred (setq ,r (1+ ,r)))) + ,r))) + +(defun -count (pred list) + "Counts the number of items in LIST where (PRED item) is non-nil." + (--count (funcall pred it) list)) + +(defun ---truthy? (obj) + "Return OBJ as a boolean value (t or nil)." + (declare (pure t) (side-effect-free t)) + (and obj t)) + +(defmacro --any? (form list) + "Anaphoric form of `-any?'." + (declare (debug (form form))) + `(and (--some ,form ,list) t)) + +(defun -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? (funcall pred it) list)) + +(defalias '-some? '-any?) +(defalias '--some? '--any?) +(defalias '-any-p '-any?) +(defalias '--any-p '--any?) +(defalias '-some-p '-any?) +(defalias '--some-p '--any?) + +(defmacro --all? (form list) + "Return t if FORM evals to non-nil for all items in LIST. +Otherwise, once an item is reached for which FORM yields nil, +return nil without evaluating FORM for any further LIST elements. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. + +The similar macro `--every' is more widely useful, since it +returns the last non-nil result of FORM instead of just t on +success. + +Alias: `--all-p', `--every-p', `--every?'. + +This is the anaphoric counterpart to `-all?'." + (declare (debug (form form))) + `(and (--every ,form ,list) t)) + +(defun -all? (pred list) + "Return t if (PRED X) is non-nil for all X in LIST, else nil. +In the latter case, stop after the first X for which (PRED X) is +nil, without calling PRED on any subsequent elements of LIST. + +The similar function `-every' is more widely useful, since it +returns the last non-nil result of PRED instead of just t on +success. + +Alias: `-all-p', `-every-p', `-every?'. + +This function's anaphoric counterpart is `--all?'." + (--all? (funcall pred it) list)) + +(defalias '-every? '-all?) +(defalias '--every? '--all?) +(defalias '-all-p '-all?) +(defalias '--all-p '--all?) +(defalias '-every-p '-all?) +(defalias '--every-p '--all?) + +(defmacro --none? (form list) + "Anaphoric form of `-none?'." + (declare (debug (form form))) + `(--all? (not ,form) ,list)) + +(defun -none? (pred list) + "Return t if (PRED x) is nil for all x in LIST, else nil. + +Alias: `-none-p'" + (--none? (funcall pred it) list)) + +(defalias '-none-p '-none?) +(defalias '--none-p '--none?) + +(defmacro --only-some? (form list) + "Anaphoric form of `-only-some?'." + (declare (debug (form form))) + (let ((y (make-symbol "yes")) + (n (make-symbol "no"))) + `(let (,y ,n) + (--each-while ,list (not (and ,y ,n)) + (if ,form (setq ,y t) (setq ,n t))) + (---truthy? (and ,y ,n))))) + +(defun -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? (funcall pred it) list)) + +(defalias '-only-some-p '-only-some?) +(defalias '--only-some-p '--only-some?) + +(defun -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." + (declare (pure t) (side-effect-free t)) + (let ((length (length list)) + (new-list nil)) + ;; to defaults to the end of the list + (setq to (or to length)) + (setq step (or step 1)) + ;; handle negative indices + (when (< from 0) + (setq from (mod from length))) + (when (< to 0) + (setq to (mod to length))) + + ;; iterate through the list, keeping the elements we want + (--each-while list (< it-index to) + (when (and (>= it-index from) + (= (mod (- from it-index) step) 0)) + (push it new-list))) + (nreverse new-list))) + +(defmacro --take-while (form list) + "Take successive items from LIST for which FORM evals to non-nil. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. Return a new +list of the successive elements from the start of LIST for which +FORM evaluates to non-nil. +This is the anaphoric counterpart to `-take-while'." + (declare (debug (form form))) + (let ((r (make-symbol "result"))) + `(let (,r) + (--each-while ,list ,form (push it ,r)) + (nreverse ,r)))) + +(defun -take-while (pred list) + "Take successive items from LIST for which PRED returns non-nil. +PRED is a function of one argument. Return a new list of the +successive elements from the start of LIST for which PRED returns +non-nil. + +This function's anaphoric counterpart is `--take-while'. + +For another variant, see also `-drop-while'." + (--take-while (funcall pred it) list)) + +(defmacro --drop-while (form list) + "Drop successive items from LIST for which FORM evals to non-nil. +Each element of LIST in turn is bound to `it' and its index +within LIST to `it-index' before evaluating FORM. Return the +tail (not a copy) of LIST starting from its first element for +which FORM evaluates to nil. +This is the anaphoric counterpart to `-drop-while'." + (declare (debug (form form))) + (let ((l (make-symbol "list"))) + `(let ((,l ,list)) + (--each-while ,l ,form (pop ,l)) + ,l))) + +(defun -drop-while (pred list) + "Drop successive items from LIST for which PRED returns non-nil. +PRED is a function of one argument. Return the tail (not a copy) +of LIST starting from its first element for which PRED returns +nil. + +This function's anaphoric counterpart is `--drop-while'. + +For another variant, see also `-take-while'." + (--drop-while (funcall pred it) list)) + +(defun -take (n list) + "Return a copy of the first N items in LIST. +Return a copy of LIST if it contains N items or fewer. +Return nil if N is zero or less. + +See also: `-take-last'." + (declare (pure t) (side-effect-free t)) + (--take-while (< it-index n) list)) + +(defun -take-last (n list) + "Return a copy of the last N items of LIST in order. +Return a copy of LIST if it contains N items or fewer. +Return nil if N is zero or less. + +See also: `-take'." + (declare (pure t) (side-effect-free t)) + (copy-sequence (last list n))) + +(defalias '-drop #'nthcdr + "Return the tail (not a copy) of LIST without the first N items. +Return nil if LIST contains N items or fewer. +Return LIST if N is zero or less. + +For another variant, see also `-drop-last'. +\n(fn N LIST)") + +(defun -drop-last (n list) + "Return a copy of LIST without its last N items. +Return a copy of LIST if N is zero or less. +Return nil if LIST contains N items or fewer. + +See also: `-drop'." + (declare (pure t) (side-effect-free t)) + (nbutlast (copy-sequence list) n)) + +(defun -split-at (n list) + "Split LIST into two sublists after the Nth element. +The result is a list of two elements (TAKE DROP) where TAKE is a +new list of the first N elements of LIST, and DROP is the +remaining elements of LIST (not a copy). TAKE and DROP are like +the results of `-take' and `-drop', respectively, but the split +is done in a single list traversal." + (declare (pure t) (side-effect-free t)) + (let (result) + (--each-while list (< it-index n) + (push (pop list) result)) + (list (nreverse result) list))) + +(defun -rotate (n list) + "Rotate LIST N places to the right (left if N is negative). +The time complexity is O(n)." + (declare (pure t) (side-effect-free t)) + (cond ((null list) ()) + ((zerop n) (copy-sequence list)) + ((let* ((len (length list)) + (n-mod-len (mod n len)) + (new-tail-len (- len n-mod-len))) + (append (nthcdr new-tail-len list) (-take new-tail-len list)))))) + +(defun -insert-at (n x list) + "Return a list with X inserted into LIST at position N. + +See also: `-splice', `-splice-list'" + (declare (pure t) (side-effect-free t)) + (let ((split-list (-split-at n list))) + (nconc (car split-list) (cons x (cadr split-list))))) + +(defun -replace-at (n x list) + "Return a list with element at Nth position in LIST replaced with X. + +See also: `-replace'" + (declare (pure t) (side-effect-free t)) + (let ((split-list (-split-at n list))) + (nconc (car split-list) (cons x (cdr (cadr split-list)))))) + +(defun -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'" + (let ((split-list (-split-at n list))) + (nconc (car split-list) (cons (funcall func (car (cadr split-list))) (cdr (cadr split-list)))))) + +(defmacro --update-at (n form list) + "Anaphoric version of `-update-at'." + (declare (debug (form def-form form))) + `(-update-at ,n (lambda (it) ,form) ,list)) + +(defun -remove-at (n list) + "Return a list with element at Nth position in LIST removed. + +See also: `-remove-at-indices', `-remove'" + (declare (pure t) (side-effect-free t)) + (-remove-at-indices (list n) list)) + +(defun -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', `-remove'" + (declare (pure t) (side-effect-free t)) + (let* ((indices (-sort '< indices)) + (diffs (cons (car indices) (-map '1- (-zip-with '- (cdr indices) indices)))) + r) + (--each diffs + (let ((split (-split-at it list))) + (!cons (car split) r) + (setq list (cdr (cadr split))))) + (!cons list r) + (apply '-concat (nreverse r)))) + +(defmacro --split-with (pred list) + "Anaphoric form of `-split-with'." + (declare (debug (form form))) + (let ((l (make-symbol "list")) + (r (make-symbol "result")) + (c (make-symbol "continue"))) + `(let ((,l ,list) + (,r nil) + (,c t)) + (while (and ,l ,c) + (let ((it (car ,l))) + (if (not ,pred) + (setq ,c nil) + (!cons it ,r) + (!cdr ,l)))) + (list (nreverse ,r) ,l)))) + +(defun -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 (funcall pred it) list)) + +(defmacro -split-on (item list) + "Split the LIST each time ITEM is found. + +Unlike `-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'" + (declare (debug (def-form form))) + `(-split-when (lambda (it) (equal it ,item)) ,list)) + +(defmacro --split-when (form list) + "Anaphoric version of `-split-when'." + (declare (debug (def-form form))) + `(-split-when (lambda (it) ,form) ,list)) + +(defun -split-when (fn list) + "Split the LIST on each element where FN returns non-nil. + +Unlike `-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'." + (let (r s) + (while list + (if (not (funcall fn (car list))) + (push (car list) s) + (when s (push (nreverse s) r)) + (setq s nil)) + (!cdr list)) + (when s (push (nreverse s) r)) + (nreverse r))) + +(defmacro --separate (form list) + "Anaphoric form of `-separate'." + (declare (debug (form form))) + (let ((y (make-symbol "yes")) + (n (make-symbol "no"))) + `(let (,y ,n) + (--each ,list (if ,form (!cons it ,y) (!cons it ,n))) + (list (nreverse ,y) (nreverse ,n))))) + +(defun -separate (pred list) + "Return a list of ((-filter PRED LIST) (-remove PRED LIST)), in one pass through the list." + (--separate (funcall pred it) list)) + +(defun dash--partition-all-in-steps-reversed (n step list) + "Used by `-partition-all-in-steps' and `-partition-in-steps'." + (when (< step 1) + (signal 'wrong-type-argument + `("Step size < 1 results in juicy infinite loops" ,step))) + (let (result) + (while list + (push (-take n list) result) + (setq list (nthcdr step list))) + result)) + +(defun -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." + (declare (pure t) (side-effect-free t)) + (nreverse (dash--partition-all-in-steps-reversed n step list))) + +(defun -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." + (declare (pure t) (side-effect-free t)) + (let ((result (dash--partition-all-in-steps-reversed n step list))) + (while (and result (< (length (car result)) n)) + (!cdr result)) + (nreverse result))) + +(defun -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." + (declare (pure t) (side-effect-free t)) + (-partition-all-in-steps n n list)) + +(defun -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." + (declare (pure t) (side-effect-free t)) + (-partition-in-steps n n list)) + +(defmacro --partition-by (form list) + "Anaphoric form of `-partition-by'." + (declare (debug (form form))) + (let ((r (make-symbol "result")) + (s (make-symbol "sublist")) + (v (make-symbol "value")) + (n (make-symbol "new-value")) + (l (make-symbol "list"))) + `(let ((,l ,list)) + (when ,l + (let* ((,r nil) + (it (car ,l)) + (,s (list it)) + (,v ,form) + (,l (cdr ,l))) + (while ,l + (let* ((it (car ,l)) + (,n ,form)) + (unless (equal ,v ,n) + (!cons (nreverse ,s) ,r) + (setq ,s nil) + (setq ,v ,n)) + (!cons it ,s) + (!cdr ,l))) + (!cons (nreverse ,s) ,r) + (nreverse ,r)))))) + +(defun -partition-by (fn list) + "Apply FN to each item in LIST, splitting it each time FN returns a new value." + (--partition-by (funcall fn it) list)) + +(defmacro --partition-by-header (form list) + "Anaphoric form of `-partition-by-header'." + (declare (debug (form form))) + (let ((r (make-symbol "result")) + (s (make-symbol "sublist")) + (h (make-symbol "header-value")) + (b (make-symbol "seen-body?")) + (n (make-symbol "new-value")) + (l (make-symbol "list"))) + `(let ((,l ,list)) + (when ,l + (let* ((,r nil) + (it (car ,l)) + (,s (list it)) + (,h ,form) + (,b nil) + (,l (cdr ,l))) + (while ,l + (let* ((it (car ,l)) + (,n ,form)) + (if (equal ,h ,n) + (when ,b + (!cons (nreverse ,s) ,r) + (setq ,s nil) + (setq ,b nil)) + (setq ,b t)) + (!cons it ,s) + (!cdr ,l))) + (!cons (nreverse ,s) ,r) + (nreverse ,r)))))) + +(defun -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 (funcall fn it) list)) + +(defmacro --partition-after-pred (form list) + "Partition LIST after each element for which FORM evaluates to non-nil. +Each element of LIST in turn is bound to `it' before evaluating +FORM. + +This is the anaphoric counterpart to `-partition-after-pred'." + (let ((l (make-symbol "list")) + (r (make-symbol "result")) + (s (make-symbol "sublist"))) + `(let ((,l ,list) ,r ,s) + (when ,l + (--each ,l + (push it ,s) + (when ,form + (push (nreverse ,s) ,r) + (setq ,s ()))) + (when ,s + (push (nreverse ,s) ,r)) + (nreverse ,r))))) + +(defun -partition-after-pred (pred list) + "Partition LIST after each element for which PRED returns non-nil. + +This function's anaphoric counterpart is `--partition-after-pred'." + (--partition-after-pred (funcall pred it) list)) + +(defun -partition-before-pred (pred list) + "Partition directly before each time PRED is true on an element of LIST." + (nreverse (-map #'reverse + (-partition-after-pred pred (reverse list))))) + +(defun -partition-after-item (item list) + "Partition directly after each time ITEM appears in LIST." + (-partition-after-pred (lambda (ele) (equal ele item)) + list)) + +(defun -partition-before-item (item list) + "Partition directly before each time ITEM appears in LIST." + (-partition-before-pred (lambda (ele) (equal ele item)) + list)) + +(defmacro --group-by (form list) + "Anaphoric form of `-group-by'." + (declare (debug t)) + (let ((n (make-symbol "n")) + (k (make-symbol "k")) + (grp (make-symbol "grp"))) + `(nreverse + (-map + (lambda (,n) + (cons (car ,n) + (nreverse (cdr ,n)))) + (--reduce-from + (let* ((,k (,@form)) + (,grp (assoc ,k acc))) + (if ,grp + (setcdr ,grp (cons it (cdr ,grp))) + (push + (list ,k it) + acc)) + acc) + nil ,list))))) + +(defun -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 (funcall fn it) list)) + +(defun -interpose (sep list) + "Return a new list of all elements in LIST separated by SEP." + (declare (pure t) (side-effect-free t)) + (let (result) + (when list + (!cons (car list) result) + (!cdr list)) + (while list + (setq result (cons (car list) (cons sep result))) + (!cdr list)) + (nreverse result))) + +(defun -interleave (&rest lists) + "Return a new list of the first item in each list, then the second etc." + (declare (pure t) (side-effect-free t)) + (when lists + (let (result) + (while (-none? 'null lists) + (--each lists (!cons (car it) result)) + (setq lists (-map 'cdr lists))) + (nreverse result)))) + +(defmacro --zip-with (form list1 list2) + "Anaphoric form of `-zip-with'. + +The elements in list1 are bound as symbol `it', the elements in list2 as symbol `other'." + (declare (debug (form form form))) + (let ((r (make-symbol "result")) + (l1 (make-symbol "list1")) + (l2 (make-symbol "list2"))) + `(let ((,r nil) + (,l1 ,list1) + (,l2 ,list2)) + (while (and ,l1 ,l2) + (let ((it (car ,l1)) + (other (car ,l2))) + (!cons ,form ,r) + (!cdr ,l1) + (!cdr ,l2))) + (nreverse ,r)))) + +(defun -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 symbol `it', +and the elements from LIST2 as symbol `other'." + (--zip-with (funcall fn it other) list1 list2)) + +(defun -zip-lists (&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. + +The return value is always list of lists, which is a difference +from `-zip-pair' which returns a cons-cell in case two input +lists are provided. + +See also: `-zip'" + (declare (pure t) (side-effect-free t)) + (when lists + (let (results) + (while (-none? 'null lists) + (setq results (cons (mapcar 'car lists) results)) + (setq lists (mapcar 'cdr lists))) + (nreverse results)))) + +(defun -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. + +Use `-zip-lists' if you need the return value to always be a list +of lists. + +Alias: `-zip-pair' + +See also: `-zip-lists'" + (declare (pure t) (side-effect-free t)) + (when lists + (let (results) + (while (-none? 'null lists) + (setq results (cons (mapcar 'car lists) results)) + (setq lists (mapcar 'cdr lists))) + (setq results (nreverse results)) + (if (= (length lists) 2) + ;; to support backward compatibility, return + ;; a cons cell if two lists were provided + (--map (cons (car it) (cadr it)) results) + results)))) + +(defalias '-zip-pair '-zip) + +(defun -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." + (declare (pure t) (side-effect-free t)) + (apply '-zip (apply '-pad (cons fill-value lists)))) + +(defun -unzip (lists) + "Unzip LISTS. + +This works just like `-zip' but takes a list of lists instead of +a variable number of arguments, such that + + (-unzip (-zip L1 L2 L3 ...)) + +is identity (given that the lists are the same length). + +Note in particular that calling this on a list of two lists will +return a list of cons-cells such that the above identity works. + +See also: `-zip'" + (apply '-zip lists)) + +(defun -cycle (list) + "Return an infinite circular copy of LIST. +The returned list cycles through the elements of LIST and repeats +from the beginning." + (declare (pure t) (side-effect-free t)) + ;; Also works with sequences that aren't lists. + (let ((newlist (append list ()))) + (nconc newlist newlist))) + +(defun -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." + (let* ((annotations (-annotate 'length lists)) + (n (-max (-map 'car annotations)))) + (--map (append (cdr it) (-repeat (- n (car it)) fill-value)) annotations))) + +(defun -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." + (-zip (-map fn list) list)) + +(defmacro --annotate (form list) + "Anaphoric version of `-annotate'." + (declare (debug (def-form form))) + `(-annotate (lambda (it) ,form) ,list)) + +(defun dash--table-carry (lists restore-lists &optional re) + "Helper for `-table' and `-table-flat'. + +If a list overflows, carry to the right and reset the list." + (while (not (or (car lists) + (equal lists '(nil)))) + (setcar lists (car restore-lists)) + (pop (cadr lists)) + (!cdr lists) + (!cdr restore-lists) + (when re + (push (nreverse (car re)) (cadr re)) + (setcar re nil) + (!cdr re)))) + +(defun -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'" + (let ((restore-lists (copy-sequence lists)) + (last-list (last lists)) + (re (make-list (length lists) nil))) + (while (car last-list) + (let ((item (apply fn (-map 'car lists)))) + (push item (car re)) + (setcar lists (cdar lists)) ;; silence byte compiler + (dash--table-carry lists restore-lists re))) + (nreverse (car (last re))))) + +(defun -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)) (apply \\='-table fn lists)) + +but the implementation here is much more efficient. + +See also: `-flatten-n', `-table'" + (let ((restore-lists (copy-sequence lists)) + (last-list (last lists)) + re) + (while (car last-list) + (let ((item (apply fn (-map 'car lists)))) + (push item re) + (setcar lists (cdar lists)) ;; silence byte compiler + (dash--table-carry lists restore-lists))) + (nreverse re))) + +(defun -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." + (declare (pure t) (side-effect-free t)) + (car (-elem-indices elem list))) + +(defun -elem-indices (elem list) + "Return the indices of all elements in LIST equal to the query +element ELEM, in ascending order." + (declare (pure t) (side-effect-free t)) + (-find-indices (-partial 'equal elem) list)) + +(defun -find-indices (pred list) + "Return the indices of all elements in LIST satisfying the +predicate PRED, in ascending order." + (apply 'append (--map-indexed (when (funcall pred it) (list it-index)) list))) + +(defmacro --find-indices (form list) + "Anaphoric version of `-find-indices'." + (declare (debug (def-form form))) + `(-find-indices (lambda (it) ,form) ,list)) + +(defun -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. + +See also `-first'." + (car (-find-indices pred list))) + +(defmacro --find-index (form list) + "Anaphoric version of `-find-index'." + (declare (debug (def-form form))) + `(-find-index (lambda (it) ,form) ,list)) + +(defun -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. + +See also `-last'." + (-last-item (-find-indices pred list))) + +(defmacro --find-last-index (form list) + "Anaphoric version of `-find-last-index'." + (declare (debug (def-form form))) + `(-find-last-index (lambda (it) ,form) ,list)) + +(defun -select-by-indices (indices list) + "Return a list whose elements are elements from LIST selected +as `(nth i list)` for all i from INDICES." + (declare (pure t) (side-effect-free t)) + (let (r) + (--each indices + (!cons (nth it list) r)) + (nreverse r))) + +(defun -select-columns (columns table) + "Select COLUMNS from TABLE. + +TABLE is a list of lists where each element represents one row. +It is assumed each row has the same length. + +Each row is transformed such that only the specified COLUMNS are +selected. + +See also: `-select-column', `-select-by-indices'" + (declare (pure t) (side-effect-free t)) + (--map (-select-by-indices columns it) table)) + +(defun -select-column (column table) + "Select COLUMN from TABLE. + +TABLE is a list of lists where each element represents one row. +It is assumed each row has the same length. + +The single selected column is returned as a list. + +See also: `-select-columns', `-select-by-indices'" + (declare (pure t) (side-effect-free t)) + (--mapcat (-select-by-indices (list column) it) table)) + +(defmacro -> (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." + (declare (debug (form &rest [&or symbolp (sexp &rest form)]))) + (cond + ((null form) x) + ((null more) (if (listp form) + `(,(car form) ,x ,@(cdr form)) + (list form x))) + (:else `(-> (-> ,x ,form) ,@more)))) + +(defmacro ->> (x &optional 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." + (declare (debug ->)) + (cond + ((null form) x) + ((null more) (if (listp form) + `(,@form ,x) + (list form x))) + (:else `(->> (->> ,x ,form) ,@more)))) + +(defmacro --> (x &rest forms) + "Starting with the value of X, thread each expression through FORMS. + +Insert X at the position signified by the symbol `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." + (declare (debug (form body))) + `(-as-> ,x it ,@forms)) + +(defmacro -as-> (value variable &rest forms) + "Starting with VALUE, thread VARIABLE through FORMS. + +In the first form, bind VARIABLE to VALUE. In the second form, bind +VARIABLE to the result of the first form, and so forth." + (declare (debug (form symbolp body))) + (if (null forms) + `,value + `(let ((,variable ,value)) + (-as-> ,(if (symbolp (car forms)) + (list (car forms) variable) + (car forms)) + ,variable + ,@(cdr forms))))) + +(defmacro -some-> (x &optional form &rest more) + "When expr is non-nil, thread it through the first form (via `->'), +and when that result is non-nil, through the next form, etc." + (declare (debug ->) + (indent 1)) + (if (null form) x + (let ((result (make-symbol "result"))) + `(-some-> (-when-let (,result ,x) + (-> ,result ,form)) + ,@more)))) + +(defmacro -some->> (x &optional form &rest more) + "When expr is non-nil, thread it through the first form (via `->>'), +and when that result is non-nil, through the next form, etc." + (declare (debug ->) + (indent 1)) + (if (null form) x + (let ((result (make-symbol "result"))) + `(-some->> (-when-let (,result ,x) + (->> ,result ,form)) + ,@more)))) + +(defmacro -some--> (expr &rest forms) + "Thread EXPR through FORMS via `-->', while the result is non-nil. +When EXPR evaluates to non-nil, thread the result through the +first of FORMS, and when that result is non-nil, thread it +through the next form, etc." + (declare (debug (form &rest &or symbolp consp)) (indent 1)) + (if (null forms) expr + (let ((result (make-symbol "result"))) + `(-some--> (-when-let (,result ,expr) + (--> ,result ,(car forms))) + ,@(cdr forms))))) + +(defmacro -doto (init &rest forms) + "Evaluate INIT and pass it as argument to FORMS with `->'. +The RESULT of evaluating INIT is threaded through each of FORMS +individually using `->', which see. The return value is RESULT, +which FORMS may have modified by side effect." + (declare (debug (form &rest &or symbolp consp)) (indent 1)) + (let ((retval (make-symbol "result"))) + `(let ((,retval ,init)) + ,@(mapcar (lambda (form) `(-> ,retval ,form)) forms) + ,retval))) + +(defmacro --doto (init &rest forms) + "Anaphoric form of `-doto'. +This just evaluates INIT, binds the result to `it', evaluates +FORMS, and returns the final value of `it'. +Note: `it' need not be used in each form." + (declare (debug (form body)) (indent 1)) + `(let ((it ,init)) + ,@forms + it)) + +(defun -grade-up (comparator list) + "Grade elements of LIST using COMPARATOR relation. +This yields a permutation vector such that applying this +permutation to LIST sorts it in ascending order." + (->> (--map-indexed (cons it it-index) list) + (-sort (lambda (it other) (funcall comparator (car it) (car other)))) + (mapcar #'cdr))) + +(defun -grade-down (comparator list) + "Grade elements of LIST using COMPARATOR relation. +This yields a permutation vector such that applying this +permutation to LIST sorts it in descending order." + (->> (--map-indexed (cons it it-index) list) + (-sort (lambda (it other) (funcall comparator (car other) (car it)))) + (mapcar #'cdr))) + +(defvar dash--source-counter 0 + "Monotonic counter for generated symbols.") + +(defun dash--match-make-source-symbol () + "Generate a new dash-source symbol. + +All returned symbols are guaranteed to be unique." + (prog1 (make-symbol (format "--dash-source-%d--" dash--source-counter)) + (setq dash--source-counter (1+ dash--source-counter)))) + +(defun dash--match-ignore-place-p (symbol) + "Return non-nil if SYMBOL is a symbol and starts with _." + (and (symbolp symbol) + (eq (aref (symbol-name symbol) 0) ?_))) + +(defun dash--match-cons-skip-cdr (skip-cdr source) + "Helper function generating idiomatic shifting code." + (cond + ((= skip-cdr 0) + `(pop ,source)) + (t + `(prog1 ,(dash--match-cons-get-car skip-cdr source) + (setq ,source ,(dash--match-cons-get-cdr (1+ skip-cdr) source)))))) + +(defun dash--match-cons-get-car (skip-cdr source) + "Helper function generating idiomatic code to get nth car." + (cond + ((= skip-cdr 0) + `(car ,source)) + ((= skip-cdr 1) + `(cadr ,source)) + (t + `(nth ,skip-cdr ,source)))) + +(defun dash--match-cons-get-cdr (skip-cdr source) + "Helper function generating idiomatic code to get nth cdr." + (cond + ((= skip-cdr 0) + source) + ((= skip-cdr 1) + `(cdr ,source)) + (t + `(nthcdr ,skip-cdr ,source)))) + +(defun dash--match-cons (match-form source) + "Setup a cons matching environment and call the real matcher." + (let ((s (dash--match-make-source-symbol)) + (n 0) + (m match-form)) + (while (and (consp m) + (dash--match-ignore-place-p (car m))) + (setq n (1+ n)) (!cdr m)) + (cond + ;; when we only have one pattern in the list, we don't have to + ;; create a temporary binding (--dash-source--) for the source + ;; and just use the input directly + ((and (consp m) + (not (cdr m))) + (dash--match (car m) (dash--match-cons-get-car n source))) + ;; handle other special types + ((> n 0) + (dash--match m (dash--match-cons-get-cdr n source))) + ;; this is the only entry-point for dash--match-cons-1, that's + ;; why we can't simply use the above branch, it would produce + ;; infinite recursion + (t + (cons (list s source) (dash--match-cons-1 match-form s)))))) + +(defun dash--get-expand-function (type) + "Get expand function name for TYPE." + (intern-soft (format "dash-expand:%s" type))) + +(defun dash--match-cons-1 (match-form source &optional props) + "Match MATCH-FORM against SOURCE. + +MATCH-FORM is a proper or improper list. Each element of +MATCH-FORM is either a symbol, which gets bound to the respective +value in source or another match form which gets destructured +recursively. + +If the cdr of last cons cell in the list is `nil', matching stops +there. + +SOURCE is a proper or improper list." + (let ((skip-cdr (or (plist-get props :skip-cdr) 0))) + (cond + ((consp match-form) + (cond + ((cdr match-form) + (cond + ((and (symbolp (car match-form)) + (functionp (dash--get-expand-function (car match-form)))) + (dash--match-kv (dash--match-kv-normalize-match-form match-form) (dash--match-cons-get-cdr skip-cdr source))) + ((dash--match-ignore-place-p (car match-form)) + (dash--match-cons-1 (cdr match-form) source + (plist-put props :skip-cdr (1+ skip-cdr)))) + (t + (-concat (dash--match (car match-form) (dash--match-cons-skip-cdr skip-cdr source)) + (dash--match-cons-1 (cdr match-form) source))))) + (t ;; Last matching place, no need for shift + (dash--match (car match-form) (dash--match-cons-get-car skip-cdr source))))) + ((eq match-form nil) + nil) + (t ;; Handle improper lists. Last matching place, no need for shift + (dash--match match-form (dash--match-cons-get-cdr skip-cdr source)))))) + +(defun dash--match-vector (match-form source) + "Setup a vector matching environment and call the real matcher." + (let ((s (dash--match-make-source-symbol))) + (cond + ;; don't bind `s' if we only have one sub-pattern + ((= (length match-form) 1) + (dash--match (aref match-form 0) `(aref ,source 0))) + ;; if the source is a symbol, we don't need to re-bind it + ((symbolp source) + (dash--match-vector-1 match-form source)) + ;; don't bind `s' if we only have one sub-pattern which is not ignored + ((let* ((ignored-places (mapcar 'dash--match-ignore-place-p match-form)) + (ignored-places-n (length (-remove 'null ignored-places)))) + (when (= ignored-places-n (1- (length match-form))) + (let ((n (-find-index 'null ignored-places))) + (dash--match (aref match-form n) `(aref ,source ,n)))))) + (t + (cons (list s source) (dash--match-vector-1 match-form s)))))) + +(defun dash--match-vector-1 (match-form source) + "Match MATCH-FORM against SOURCE. + +MATCH-FORM is a vector. Each element of MATCH-FORM is either a +symbol, which gets bound to the respective value in source or +another match form which gets destructured recursively. + +If second-from-last place in MATCH-FORM is the symbol &rest, the +next element of the MATCH-FORM is matched against the tail of +SOURCE, starting at index of the &rest symbol. This is +conceptually the same as the (head . tail) match for improper +lists, where dot plays the role of &rest. + +SOURCE is a vector. + +If the MATCH-FORM vector is shorter than SOURCE vector, only +the (length MATCH-FORM) places are bound, the rest of the SOURCE +is discarded." + (let ((i 0) + (l (length match-form)) + (re)) + (while (< i l) + (let ((m (aref match-form i))) + (push (cond + ((and (symbolp m) + (eq m '&rest)) + (prog1 (dash--match + (aref match-form (1+ i)) + `(substring ,source ,i)) + (setq i l))) + ((and (symbolp m) + ;; do not match symbols starting with _ + (not (eq (aref (symbol-name m) 0) ?_))) + (list (list m `(aref ,source ,i)))) + ((not (symbolp m)) + (dash--match m `(aref ,source ,i)))) + re) + (setq i (1+ i)))) + (-flatten-n 1 (nreverse re)))) + +(defun dash--match-kv-normalize-match-form (pattern) + "Normalize kv PATTERN. + +This method normalizes PATTERN to the format expected by +`dash--match-kv'. See `-let' for the specification." + (let ((normalized (list (car pattern))) + (skip nil) + (fill-placeholder (make-symbol "--dash-fill-placeholder--"))) + (-each (apply '-zip (-pad fill-placeholder (cdr pattern) (cddr pattern))) + (lambda (pair) + (let ((current (car pair)) + (next (cdr pair))) + (if skip + (setq skip nil) + (if (or (eq fill-placeholder next) + (not (or (and (symbolp next) + (not (keywordp next)) + (not (eq next t)) + (not (eq next nil))) + (and (consp next) + (not (eq (car next) 'quote))) + (vectorp next)))) + (progn + (cond + ((keywordp current) + (push current normalized) + (push (intern (substring (symbol-name current) 1)) normalized)) + ((stringp current) + (push current normalized) + (push (intern current) normalized)) + ((and (consp current) + (eq (car current) 'quote)) + (push current normalized) + (push (cadr current) normalized)) + (t (error "-let: found key `%s' in kv destructuring but its pattern `%s' is invalid and can not be derived from the key" current next))) + (setq skip nil)) + (push current normalized) + (push next normalized) + (setq skip t)))))) + (nreverse normalized))) + +(defun dash--match-kv (match-form source) + "Setup a kv matching environment and call the real matcher. + +kv can be any key-value store, such as plist, alist or hash-table." + (let ((s (dash--match-make-source-symbol))) + (cond + ;; don't bind `s' if we only have one sub-pattern (&type key val) + ((= (length match-form) 3) + (dash--match-kv-1 (cdr match-form) source (car match-form))) + ;; if the source is a symbol, we don't need to re-bind it + ((symbolp source) + (dash--match-kv-1 (cdr match-form) source (car match-form))) + (t + (cons (list s source) (dash--match-kv-1 (cdr match-form) s (car match-form))))))) + +(defun dash-expand:&hash (key source) + "Generate extracting KEY from SOURCE for &hash destructuring." + `(gethash ,key ,source)) + +(defun dash-expand:&plist (key source) + "Generate extracting KEY from SOURCE for &plist destructuring." + `(plist-get ,source ,key)) + +(defun dash-expand:&alist (key source) + "Generate extracting KEY from SOURCE for &alist destructuring." + `(cdr (assoc ,key ,source))) + +(defun dash-expand:&hash? (key source) + "Generate extracting KEY from SOURCE for &hash? destructuring. +Similar to &hash but check whether the map is not nil." + (let ((src (make-symbol "src"))) + `(let ((,src ,source)) + (when ,src (gethash ,key ,src))))) + +(defalias 'dash-expand:&keys 'dash-expand:&plist) + +(defun dash--match-kv-1 (match-form source type) + "Match MATCH-FORM against SOURCE of type TYPE. + +MATCH-FORM is a proper list of the form (key1 place1 ... keyN +placeN). Each placeK is either a symbol, which gets bound to the +value of keyK retrieved from the key-value store, or another +match form which gets destructured recursively. + +SOURCE is a key-value store of type TYPE, which can be a plist, +an alist or a hash table. + +TYPE is a token specifying the type of the key-value store. +Valid values are &plist, &alist and &hash." + (-flatten-n 1 (-map + (lambda (kv) + (let* ((k (car kv)) + (v (cadr kv)) + (getter + (funcall (dash--get-expand-function type) k source))) + (cond + ((symbolp v) + (list (list v getter))) + (t (dash--match v getter))))) + (-partition 2 match-form)))) + +(defun dash--match-symbol (match-form source) + "Bind a symbol. + +This works just like `let', there is no destructuring." + (list (list match-form source))) + +(defun dash--match (match-form source) + "Match MATCH-FORM against SOURCE. + +This function tests the MATCH-FORM and dispatches to specific +matchers based on the type of the expression. + +Key-value stores are disambiguated by placing a token &plist, +&alist or &hash as a first item in the MATCH-FORM." + (cond + ((symbolp match-form) + (dash--match-symbol match-form source)) + ((consp match-form) + (cond + ;; Handle the "x &as" bindings first. + ((and (consp (cdr match-form)) + (symbolp (car match-form)) + (eq '&as (cadr match-form))) + (let ((s (car match-form))) + (cons (list s source) + (dash--match (cddr match-form) s)))) + ((functionp (dash--get-expand-function (car match-form))) + (dash--match-kv (dash--match-kv-normalize-match-form match-form) source)) + (t (dash--match-cons match-form source)))) + ((vectorp match-form) + ;; We support the &as binding in vectors too + (cond + ((and (> (length match-form) 2) + (symbolp (aref match-form 0)) + (eq '&as (aref match-form 1))) + (let ((s (aref match-form 0))) + (cons (list s source) + (dash--match (substring match-form 2) s)))) + (t (dash--match-vector match-form source)))))) + +(defun dash--normalize-let-varlist (varlist) + "Normalize VARLIST so that every binding is a list. + +`let' allows specifying a binding which is not a list but simply +the place which is then automatically bound to nil, such that all +three of the following are identical and evaluate to nil. + + (let (a) a) + (let ((a)) a) + (let ((a nil)) a) + +This function normalizes all of these to the last form." + (--map (if (consp it) it (list it nil)) varlist)) + +(defmacro -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' for the list of all possible patterns." + (declare (debug ((&rest [&or (sexp form) sexp]) body)) + (indent 1)) + (let* ((varlist (dash--normalize-let-varlist varlist)) + (bindings (--mapcat (dash--match (car it) (cadr it)) varlist))) + `(let* ,bindings + ,@body))) + +(defmacro -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' 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. + Uses `plist-get' to fetch values. + + (&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. + Uses `assoc' to fetch values. + + (&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. + Uses `gethash' to fetch values. + +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). + +A shorthand notation for kv-destructuring exists which allows the +patterns be optionally left out and derived from the key name in +the following fashion: + +- a key :foo is converted into `foo' pattern, +- a key 'bar is converted into `bar' pattern, +- a key \"baz\" is converted into `baz' pattern. + +That is, the entire value under the key is bound to the derived +variable without any further destructuring. + +This is possible only when the form following the key is not a +valid pattern (i.e. not a symbol, a cons cell or a vector). +Otherwise the matching proceeds as usual and in case of an +invalid spec fails with an error. + +Thus the patterns are normalized as follows: + + ;; derive all the missing patterns + (&plist :foo 'bar \"baz\") => (&plist :foo foo 'bar bar \"baz\" baz) + + ;; we can specify some but not others + (&plist :foo 'bar explicit-bar) => (&plist :foo foo 'bar explicit-bar) + + ;; nothing happens, we store :foo in x + (&plist :foo x) => (&plist :foo x) + + ;; nothing happens, we match recursively + (&plist :foo (a b c)) => (&plist :foo (a b c)) + +You can name the source using the syntax SYMBOL &as PATTERN. +This syntax works with lists (proper or improper), vectors and +all types of maps. + + (list &as a b c) (list 1 2 3) + +binds A to 1, B to 2, C to 3 and LIST to (1 2 3). + +Similarly: + + (bounds &as beg . end) (cons 1 2) + +binds BEG to 1, END to 2 and BOUNDS to (1 . 2). + + (items &as first . rest) (list 1 2 3) + +binds FIRST to 1, REST to (2 3) and ITEMS to (1 2 3) + + [vect &as _ b c] [1 2 3] + +binds B to 2, C to 3 and VECT to [1 2 3] (_ avoids binding as usual). + + (plist &as &plist :b b) (list :a 1 :b 2 :c 3) + +binds B to 2 and PLIST to (:a 1 :b 2 :c 3). Same for &alist and &hash. + +This is especially useful when we want to capture the result of a +computation and destructure at the same time. Consider the +form (function-returning-complex-structure) returning a list of +two vectors with two items each. We want to capture this entire +result and pass it to another computation, but at the same time +we want to get the second item from each vector. We can achieve +it with pattern + + (result &as [_ a] [_ b]) (function-returning-complex-structure) + +Note: Clojure programmers may know this feature as the \":as +binding\". The difference is that we put the &as at the front +because we need to support improper list binding." + (declare (debug ([&or (&rest [&or (sexp form) sexp]) + (vector [&rest [sexp form]])] + body)) + (indent 1)) + (if (vectorp varlist) + `(let* ,(dash--match (aref varlist 0) (aref varlist 1)) + ,@body) + (let* ((varlist (dash--normalize-let-varlist varlist)) + (inputs (--map-indexed (list (make-symbol (format "input%d" it-index)) (cadr it)) varlist)) + (new-varlist (--map (list (caar it) (cadr it)) (-zip varlist inputs)))) + `(let ,inputs + (-let* ,new-varlist ,@body))))) + +(defmacro -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' for a description of the destructuring mechanism." + (declare (doc-string 2) (indent defun) + (debug (&define sexp + [&optional stringp] + [&optional ("interactive" interactive)] + def-body))) + (cond + ((nlistp match-form) + (signal 'wrong-type-argument (list #'listp match-form))) + ;; No destructuring, so just return regular `lambda' for speed. + ((-all? #'symbolp match-form) + `(lambda ,match-form ,@body)) + ((let ((inputs (--map-indexed + (list it (make-symbol (format "input%d" it-index))) + match-form))) + ;; TODO: because inputs to the `lambda' are evaluated only once, + ;; `-let*' need not create the extra bindings to ensure that. + ;; We should find a way to optimize that. Not critical however. + `(lambda ,(mapcar #'cadr inputs) + (-let* ,inputs ,@body)))))) + +(defmacro -setq (&rest forms) + "Bind each MATCH-FORM to the value of its VAL. + +MATCH-FORM destructuring is done according to the rules of `-let'. + +This macro allows you to bind multiple variables by destructuring +the value, so for example: + + (-setq (a b) x + (&plist :c c) plist) + +expands roughly speaking to the following code + + (setq a (car x) + b (cadr x) + c (plist-get plist :c)) + +Care is taken to only evaluate each VAL once so that in case of +multiple assignments it does not cause unexpected side effects. + +\(fn [MATCH-FORM VAL]...)" + (declare (debug (&rest sexp form)) + (indent 1)) + (when (= (mod (length forms) 2) 1) + (signal 'wrong-number-of-arguments (list '-setq (1+ (length forms))))) + (let* ((forms-and-sources + ;; First get all the necessary mappings with all the + ;; intermediate bindings. + (-map (lambda (x) (dash--match (car x) (cadr x))) + (-partition 2 forms))) + ;; To preserve the logic of dynamic scoping we must ensure + ;; that we `setq' the variables outside of the `let*' form + ;; which holds the destructured intermediate values. For + ;; this we generate for each variable a placeholder which is + ;; bound to (lexically) the result of the destructuring. + ;; Then outside of the helper `let*' form we bind all the + ;; original variables to their respective placeholders. + ;; TODO: There is a lot of room for possible optimization, + ;; for start playing with `special-variable-p' to eliminate + ;; unnecessary re-binding. + (variables-to-placeholders + (-mapcat + (lambda (bindings) + (-map + (lambda (binding) + (let ((var (car binding))) + (list var (make-symbol (concat "--dash-binding-" (symbol-name var) "--"))))) + (--filter (not (string-prefix-p "--" (symbol-name (car it)))) bindings))) + forms-and-sources))) + `(let ,(-map 'cadr variables-to-placeholders) + (let* ,(-flatten-n 1 forms-and-sources) + (setq ,@(-flatten (-map 'reverse variables-to-placeholders)))) + (setq ,@(-flatten variables-to-placeholders))))) + +(defmacro -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*'. VALS are evaluated +sequentially, and evaluation stops after the first nil VAL is +encountered." + (declare (debug ((&rest (sexp form)) form body)) + (indent 2)) + (->> vars-vals + (--mapcat (dash--match (car it) (cadr it))) + (--reduce-r-from + (let ((var (car it)) + (val (cadr it))) + `(let ((,var ,val)) + (if ,var ,acc ,@else))) + then))) + +(defmacro -if-let (var-val then &rest else) + "If VAL evaluates to non-nil, bind it to VAR and do THEN, +otherwise do ELSE. + +Note: binding is done according to `-let'. + +\(fn (VAR VAL) THEN &rest ELSE)" + (declare (debug ((sexp form) form body)) + (indent 2)) + `(-if-let* (,var-val) ,then ,@else)) + +(defmacro --if-let (val then &rest else) + "If VAL evaluates to non-nil, bind it to symbol `it' and do THEN, +otherwise do ELSE." + (declare (debug (form form body)) + (indent 2)) + `(-if-let (it ,val) ,then ,@else)) + +(defmacro -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*'. VALS are evaluated +sequentially, and evaluation stops after the first nil VAL is +encountered." + (declare (debug ((&rest (sexp form)) body)) + (indent 1)) + `(-if-let* ,vars-vals (progn ,@body))) + +(defmacro -when-let (var-val &rest body) + "If VAL evaluates to non-nil, bind it to VAR and execute body. + +Note: binding is done according to `-let'. + +\(fn (VAR VAL) &rest BODY)" + (declare (debug ((sexp form) body)) + (indent 1)) + `(-if-let ,var-val (progn ,@body))) + +(defmacro --when-let (val &rest body) + "If VAL evaluates to non-nil, bind it to symbol `it' and +execute body." + (declare (debug (form body)) + (indent 1)) + `(--if-let ,val (progn ,@body))) + +(defvar -compare-fn nil + "Tests for equality use this function or `equal' if this is nil. +It should only be set using dynamic scope with a let, like: + + (let ((-compare-fn #\\='=)) (-union numbers1 numbers2 numbers3)") + +(defun -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'" + ;; Implementation note: The speedup gained from hash table lookup + ;; starts to outweigh its overhead for lists of length greater than + ;; 32. See discussion in PR #305. + (let* ((len (length list)) + (lut (and (> len 32) + ;; Check that `-compare-fn' is a valid hash-table + ;; lookup function or `nil'. + (memq -compare-fn '(nil equal eq eql)) + (make-hash-table :test (or -compare-fn #'equal) + :size len)))) + (if lut + (--filter (unless (gethash it lut) + (puthash it t lut)) + list) + (--each list (unless (-contains? lut it) (!cons it lut))) + (nreverse lut)))) + +(defalias '-uniq '-distinct) + +(defun -union (list list2) + "Return a new list containing the elements of LIST and elements of LIST2 that are not in LIST. +The test for equality is done with `equal', +or with `-compare-fn' if that's non-nil." + ;; We fall back to iteration implementation if the comparison + ;; function isn't one of `eq', `eql' or `equal'. + (let* ((result (reverse list)) + ;; TODO: get rid of this dynamic variable, pass it as an + ;; argument instead. + (-compare-fn (if (bound-and-true-p -compare-fn) + -compare-fn + 'equal))) + (if (memq -compare-fn '(eq eql equal)) + (let ((ht (make-hash-table :test -compare-fn))) + (--each list (puthash it t ht)) + (--each list2 (unless (gethash it ht) (!cons it result)))) + (--each list2 (unless (-contains? result it) (!cons it result)))) + (nreverse result))) + +(defun -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." + (--filter (-contains? list2 it) list)) + +(defun -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." + (--filter (not (-contains? list2 it)) list)) + +(defun -powerset (list) + "Return the power set of LIST." + (if (null list) '(()) + (let ((last (-powerset (cdr list)))) + (append (mapcar (lambda (x) (cons (car list) x)) last) + last)))) + +(defun -permutations (list) + "Return the permutations of LIST." + (if (null list) '(()) + (apply #'append + (mapcar (lambda (x) + (mapcar (lambda (perm) (cons x perm)) + (-permutations (remove x list)))) + list)))) + +(defun -inits (list) + "Return all prefixes of LIST." + (let ((res (list list))) + (setq list (reverse list)) + (while list + (push (reverse (!cdr list)) res)) + res)) + +(defun -tails (list) + "Return all suffixes of LIST" + (-reductions-r-from 'cons nil list)) + +(defun -common-prefix (&rest lists) + "Return the longest common prefix of LISTS." + (declare (pure t) (side-effect-free t)) + (--reduce (--take-while (and acc (equal (pop acc) it)) it) + lists)) + +(defun -common-suffix (&rest lists) + "Return the longest common suffix of LISTS." + (nreverse (apply #'-common-prefix (mapcar #'reverse lists)))) + +(defun -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'" + (not + (null + (cond + ((null -compare-fn) (member element list)) + ((eq -compare-fn 'eq) (memq element list)) + ((eq -compare-fn 'eql) (memql element list)) + (t + (let ((lst list)) + (while (and lst + (not (funcall -compare-fn element (car lst)))) + (setq lst (cdr lst))) + lst)))))) + +(defalias '-contains-p '-contains?) + +(defun -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'" + (let ((length-a (length list)) + (length-b (length list2))) + (and + (= length-a length-b) + (= length-a (length (-intersection list list2)))))) + +(defalias '-same-items-p '-same-items?) + +(defun -is-prefix? (prefix list) + "Return non-nil if PREFIX is a prefix of LIST. + +Alias: `-is-prefix-p'." + (declare (pure t) (side-effect-free t)) + (--each-while list (and (equal (car prefix) it) + (!cdr prefix))) + (null prefix)) + +(defun -is-suffix? (suffix list) + "Return non-nil if SUFFIX is a suffix of LIST. + +Alias: `-is-suffix-p'." + (declare (pure t) (side-effect-free t)) + (equal suffix (last list (length suffix)))) + +(defun -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'" + (declare (pure t) (side-effect-free t)) + (let (done) + (while (and (not done) list) + (setq done (-is-prefix? infix list)) + (!cdr list)) + done)) + +(defalias '-is-prefix-p '-is-prefix?) +(defalias '-is-suffix-p '-is-suffix?) +(defalias '-is-infix-p '-is-infix?) + +(defun -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 (copy-sequence list) comparator)) + +(defmacro --sort (form list) + "Anaphoric form of `-sort'." + (declare (debug (def-form form))) + `(-sort (lambda (it other) ,form) ,list)) + +(defun -list (&optional arg &rest args) + "Ensure ARG is a list. +If ARG is already a list, return it as is (not a copy). +Otherwise, return a new list with ARG as its only element. + +Another supported calling convention is (-list &rest ARGS). +In this case, if ARG is not a list, a new list with all of +ARGS as elements is returned. This use is supported for +backward compatibility and is otherwise deprecated." + (declare (advertised-calling-convention (arg) "2.18.0") + (pure t) (side-effect-free t)) + (if (listp arg) arg (cons arg args))) + +(defun -repeat (n x) + "Return a new list of length N with each element being X. +Return nil if N is less than 1." + (declare (pure t) (side-effect-free t)) + (and (natnump n) (make-list n x))) + +(defun -sum (list) + "Return the sum of LIST." + (declare (pure t) (side-effect-free t)) + (apply '+ list)) + +(defun -running-sum (list) + "Return a list with running sums of items in LIST. +LIST must be non-empty." + (declare (pure t) (side-effect-free t)) + (or list (signal 'wrong-type-argument (list #'consp list))) + (-reductions #'+ list)) + +(defun -product (list) + "Return the product of LIST." + (declare (pure t) (side-effect-free t)) + (apply '* list)) + +(defun -running-product (list) + "Return a list with running products of items in LIST. +LIST must be non-empty." + (declare (pure t) (side-effect-free t)) + (or list (signal 'wrong-type-argument (list #'consp list))) + (-reductions #'* list)) + +(defun -max (list) + "Return the largest value from LIST of numbers or markers." + (declare (pure t) (side-effect-free t)) + (apply 'max list)) + +(defun -min (list) + "Return the smallest value from LIST of numbers or markers." + (declare (pure t) (side-effect-free t)) + (apply 'min list)) + +(defun -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' which can transform the values before +comparing them." + (--reduce (if (funcall comparator it acc) it acc) list)) + +(defun -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' which can transform the values before +comparing them." + (--reduce (if (funcall comparator it acc) acc it) list)) + +(defmacro --max-by (form list) + "Anaphoric version of `-max-by'. + +The items for the comparator form are exposed as \"it\" and \"other\"." + (declare (debug (def-form form))) + `(-max-by (lambda (it other) ,form) ,list)) + +(defmacro --min-by (form list) + "Anaphoric version of `-min-by'. + +The items for the comparator form are exposed as \"it\" and \"other\"." + (declare (debug (def-form form))) + `(-min-by (lambda (it other) ,form) ,list)) + +(defun -iota (count &optional start step) + "Return a list containing COUNT numbers. +Starts from START and adds STEP each time. The default START is +zero, the default STEP is 1. +This function takes its name from the corresponding primitive in +the APL language." + (declare (pure t) (side-effect-free t)) + (unless (natnump count) + (signal 'wrong-type-argument (list #'natnump count))) + (or start (setq start 0)) + (or step (setq step 1)) + (if (zerop step) + (make-list count start) + (--iterate (+ it step) start count))) + +(defun -fix (fn list) + "Compute the (least) fixpoint of FN with initial input LIST. + +FN is called at least once, results are compared with `equal'." + (let ((re (funcall fn list))) + (while (not (equal list re)) + (setq list re) + (setq re (funcall fn re))) + re)) + +(defmacro --fix (form list) + "Anaphoric form of `-fix'." + (declare (debug (def-form form))) + `(-fix (lambda (it) ,form) ,list)) + +(defun -unfold (fun seed) + "Build a list from SEED using FUN. + +This is \"dual\" operation to `-reduce-r': while -reduce-r +consumes a list to produce a single value, `-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." + (let ((last (funcall fun seed)) r) + (while last + (push (car last) r) + (setq last (funcall fun (cdr last)))) + (nreverse r))) + +(defmacro --unfold (form seed) + "Anaphoric version of `-unfold'." + (declare (debug (def-form form))) + `(-unfold (lambda (it) ,form) ,seed)) + +(defun -cons-pair? (obj) + "Return non-nil if OBJ is a true cons pair. +That is, a cons (A . B) where B is not a list. + +Alias: `-cons-pair-p'." + (declare (pure t) (side-effect-free t)) + (nlistp (cdr-safe obj))) + +(defalias '-cons-pair-p '-cons-pair?) + +(defun -cons-to-list (con) + "Convert a cons pair to a list with `car' and `cdr' of the pair respectively." + (declare (pure t) (side-effect-free t)) + (list (car con) (cdr con))) + +(defun -value-to-list (val) + "Convert a value to a list. + +If the value is a cons pair, make a list with two elements, `car' +and `cdr' of the pair respectively. + +If the value is anything else, wrap it in a list." + (declare (pure t) (side-effect-free t)) + (cond + ((-cons-pair? val) (-cons-to-list val)) + (t (list val)))) + +(defun -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'. + +This is the same as calling `-tree-reduce-from' after `-tree-map' +but is twice as fast as it only traverse the structure once." + (cond + ((not tree) nil) + ((-cons-pair? tree) (funcall fn tree)) + ((listp tree) + (-reduce-r-from folder init-value (mapcar (lambda (x) (-tree-mapreduce-from fn folder init-value x)) tree))) + (t (funcall fn tree)))) + +(defmacro --tree-mapreduce-from (form folder init-value tree) + "Anaphoric form of `-tree-mapreduce-from'." + (declare (debug (def-form def-form form form))) + `(-tree-mapreduce-from (lambda (it) ,form) (lambda (it acc) ,folder) ,init-value ,tree)) + +(defun -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'. + +This is the same as calling `-tree-reduce' after `-tree-map' +but is twice as fast as it only traverse the structure once." + (cond + ((not tree) nil) + ((-cons-pair? tree) (funcall fn tree)) + ((listp tree) + (-reduce-r folder (mapcar (lambda (x) (-tree-mapreduce fn folder x)) tree))) + (t (funcall fn tree)))) + +(defmacro --tree-mapreduce (form folder tree) + "Anaphoric form of `-tree-mapreduce'." + (declare (debug (def-form def-form form))) + `(-tree-mapreduce (lambda (it) ,form) (lambda (it acc) ,folder) ,tree)) + +(defun -tree-map (fn tree) + "Apply FN to each element of TREE while preserving the tree structure." + (cond + ((not tree) nil) + ((-cons-pair? tree) (funcall fn tree)) + ((listp tree) + (mapcar (lambda (x) (-tree-map fn x)) tree)) + (t (funcall fn tree)))) + +(defmacro --tree-map (form tree) + "Anaphoric form of `-tree-map'." + (declare (debug (def-form form))) + `(-tree-map (lambda (it) ,form) ,tree)) + +(defun -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." + (cond + ((not tree) nil) + ((-cons-pair? tree) tree) + ((listp tree) + (-reduce-r-from fn init-value (mapcar (lambda (x) (-tree-reduce-from fn init-value x)) tree))) + (t tree))) + +(defmacro --tree-reduce-from (form init-value tree) + "Anaphoric form of `-tree-reduce-from'." + (declare (debug (def-form form form))) + `(-tree-reduce-from (lambda (it acc) ,form) ,init-value ,tree)) + +(defun -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' for how exactly are lists of zero or one element handled." + (cond + ((not tree) nil) + ((-cons-pair? tree) tree) + ((listp tree) + (-reduce-r fn (mapcar (lambda (x) (-tree-reduce fn x)) tree))) + (t tree))) + +(defmacro --tree-reduce (form tree) + "Anaphoric form of `-tree-reduce'." + (declare (debug (def-form form))) + `(-tree-reduce (lambda (it acc) ,form) ,tree)) + +(defun -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." + (if (funcall pred tree) + (funcall fun tree) + (if (and (listp tree) + (not (-cons-pair? tree))) + (-map (lambda (x) (-tree-map-nodes pred fun x)) tree) + tree))) + +(defmacro --tree-map-nodes (pred form tree) + "Anaphoric form of `-tree-map-nodes'." + (declare (debug (def-form def-form form))) + `(-tree-map-nodes (lambda (it) ,pred) (lambda (it) ,form) ,tree)) + +(defun -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." + (cons tree + (when (funcall branch tree) + (-mapcat (lambda (x) (-tree-seq branch children x)) + (funcall children tree))))) + +(defmacro --tree-seq (branch children tree) + "Anaphoric form of `-tree-seq'." + (declare (debug (def-form def-form form))) + `(-tree-seq (lambda (it) ,branch) (lambda (it) ,children) ,tree)) + +(defun -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." + (declare (pure t) (side-effect-free t)) + (-tree-map 'identity list)) + +;;; Combinators + +(defalias '-partial #'apply-partially) + +(defun -rpartial (fn &rest args) + "Return a function that is a partial application of FN to ARGS. +ARGS is a list of the last N arguments to pass to FN. The result +is a new function which does the same as FN, except that the last +N arguments are fixed at the values with which this function was +called. This is like `-partial', except the arguments are fixed +starting from the right rather than the left." + (declare (pure t) (side-effect-free t)) + (lambda (&rest args-before) (apply fn (append args-before args)))) + +(defun -juxt (&rest fns) + "Return a function that is the juxtaposition of FNS. +The returned function takes a variable number of ARGS, applies +each of FNS in turn to ARGS, and returns the list of results." + (declare (pure t) (side-effect-free t)) + (lambda (&rest args) (mapcar (lambda (x) (apply x args)) fns))) + +(defun -compose (&rest fns) + "Compose FNS into a single composite function. +Return a function that takes a variable number of ARGS, applies +the last function in FNS to ARGS, and returns the result of +calling each remaining function on the result of the previous +function, right-to-left. If no FNS are given, return a variadic +`identity' function." + (declare (pure t) (side-effect-free t)) + (let* ((fns (nreverse fns)) + (head (car fns)) + (tail (cdr fns))) + (cond (tail + (lambda (&rest args) + (--reduce-from (funcall it acc) (apply head args) tail))) + (fns head) + ((lambda (&optional arg &rest _) arg))))) + +(defun -applify (fn) + "Return a function that applies FN to a single list of args. +This changes the arity of FN from taking N distinct arguments to +taking 1 argument which is a list of N arguments." + (declare (pure t) (side-effect-free t)) + (lambda (args) (apply fn args))) + +(defun -on (op trans) + "Return a function that calls TRANS on each arg and OP on the results. +The returned function takes a variable number of arguments, calls +the function TRANS on each one in turn, and then passes those +results as the list of arguments to OP, in the same order. + +For example, the following pairs of expressions are morally +equivalent: + + (funcall (-on #\\='+ #\\='1+) 1 2 3) = (+ (1+ 1) (1+ 2) (1+ 3)) + (funcall (-on #\\='+ #\\='1+)) = (+)" + (declare (pure t) (side-effect-free t)) + (lambda (&rest args) + ;; This unrolling seems to be a relatively cheap way to keep the + ;; overhead of `mapcar' + `apply' in check. + (cond ((cddr args) + (apply op (mapcar trans args))) + ((cdr args) + (funcall op (funcall trans (car args)) (funcall trans (cadr args)))) + (args + (funcall op (funcall trans (car args)))) + ((funcall op))))) + +(defun -flip (fn) + "Return a function that calls FN with its arguments reversed. +The returned function takes the same number of arguments as FN. + +For example, the following two expressions are morally +equivalent: + + (funcall (-flip #\\='-) 1 2) = (- 2 1) + +See also: `-rotate-args'." + (declare (pure t) (side-effect-free t)) + (lambda (&rest args) ;; Open-code for speed. + (cond ((cddr args) (apply fn (nreverse args))) + ((cdr args) (funcall fn (cadr args) (car args))) + (args (funcall fn (car args))) + ((funcall fn))))) + +(defun -rotate-args (n fn) + "Return a function that calls FN with args rotated N places to the right. +The returned function takes the same number of arguments as FN, +rotates the list of arguments N places to the right (left if N is +negative) just like `-rotate', and applies FN to the result. + +See also: `-flip'." + (declare (pure t) (side-effect-free t)) + (if (zerop n) + fn + (let ((even (= (% n 2) 0))) + (lambda (&rest args) + (cond ((cddr args) ;; Open-code for speed. + (apply fn (-rotate n args))) + ((cdr args) + (let ((fst (car args)) + (snd (cadr args))) + (funcall fn (if even fst snd) (if even snd fst)))) + (args + (funcall fn (car args))) + ((funcall fn))))))) + +(defun -const (c) + "Return a function that returns C ignoring any additional arguments. + +In types: a -> b -> a" + (declare (pure t) (side-effect-free t)) + (lambda (&rest _) c)) + +(defmacro -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." + (declare (debug (&optional sexp &rest &or "<>" form))) + (let* ((i 0) + (args (--keep (when (eq it '<>) + (setq i (1+ i)) + (make-symbol (format "D%d" i))) + params))) + `(lambda ,args + ,(let ((body (--map (if (eq it '<>) (pop args) it) params))) + (if (eq (car params) '<>) + (cons #'funcall body) + body))))) + +(defun -not (pred) + "Return a predicate that negates the result of PRED. +The returned predicate passes its arguments to PRED. If PRED +returns nil, the result is non-nil; otherwise the result is nil. + +See also: `-andfn' and `-orfn'." + (declare (pure t) (side-effect-free t)) + (lambda (&rest args) (not (apply pred args)))) + +(defun -orfn (&rest preds) + "Return a predicate that returns the first non-nil result of PREDS. +The returned predicate takes a variable number of arguments, +passes them to each predicate in PREDS in turn until one of them +returns non-nil, and returns that non-nil result without calling +the remaining PREDS. If all PREDS return nil, or if no PREDS are +given, the returned predicate returns nil. + +See also: `-andfn' and `-not'." + (declare (pure t) (side-effect-free t)) + ;; Open-code for speed. + (cond ((cdr preds) (lambda (&rest args) (--some (apply it args) preds))) + (preds (car preds)) + (#'ignore))) + +(defun -andfn (&rest preds) + "Return a predicate that returns non-nil if all PREDS do so. +The returned predicate P takes a variable number of arguments and +passes them to each predicate in PREDS in turn. If any one of +PREDS returns nil, P also returns nil without calling the +remaining PREDS. If all PREDS return non-nil, P returns the last +such value. If no PREDS are given, P always returns non-nil. + +See also: `-orfn' and `-not'." + (declare (pure t) (side-effect-free t)) + ;; Open-code for speed. + (cond ((cdr preds) (lambda (&rest args) (--every (apply it args) preds))) + (preds (car preds)) + ;; As a `pure' function, this runtime check may generate + ;; backward-incompatible bytecode for `(-andfn)' at compile-time, + ;; but I doubt that's a problem in practice (famous last words). + ((fboundp 'always) #'always) + ((lambda (&rest _) t)))) + +(defun -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' first to turn it into a 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)))." + (lambda (x) (--dotimes n (setq x (funcall fn x))) x)) + +(defun -counter (&optional beg end inc) + "Return a closure that counts from BEG to END, with increment INC. + +The closure will return the next value in the counting sequence +each time it is called, and nil after END is reached. BEG +defaults to 0, INC defaults to 1, and if END is nil, the counter +will increment indefinitely. + +The closure accepts any number of arguments, which are discarded." + (let ((inc (or inc 1)) + (n (or beg 0))) + (lambda (&rest _) + (when (or (not end) (< n end)) + (prog1 n + (setq n (+ n inc))))))) + +(defvar -fixfn-max-iterations 1000 + "The default maximum number of iterations performed by `-fixfn' + unless otherwise specified.") + +(defun -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 satisfied: + + 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 + approximate comparison 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." + (let ((eqfn (or equal-test 'equal)) + (haltfn (or halt-test + (-not + (-counter 0 -fixfn-max-iterations))))) + (lambda (x) + (let ((re (funcall fn x)) + (halt? (funcall haltfn x))) + (while (and (not halt?) (not (funcall eqfn x re))) + (setq x re + re (funcall fn re) + halt? (funcall haltfn re))) + (if halt? (cons 'halted halt?) + re))))) + +(defun -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))" + (lambda (x) (-zip-with 'funcall fns x))) + +;;; Font lock + +(defvar dash--keywords + `(;; TODO: Do not fontify the following automatic variables + ;; globally; detect and limit to their local anaphoric scope. + (,(rx symbol-start (| "acc" "it" "it-index" "other") symbol-end) + 0 font-lock-variable-name-face) + ;; Macros in dev/examples.el. Based on `lisp-mode-symbol-regexp'. + (,(rx ?\( (group (| "defexamples" "def-example-group")) symbol-end + (+ (in "\t ")) + (group (* (| (syntax word) (syntax symbol) (: ?\\ nonl))))) + (1 font-lock-keyword-face) + (2 font-lock-function-name-face)) + ;; Symbols in dev/examples.el. + ,(rx symbol-start (| "=>" "~>" "!!>") symbol-end) + ;; Elisp macro fontification was static prior to Emacs 25. + ,@(when (< emacs-major-version 25) + (let ((macs '("!cdr" + "!cons" + "-->" + "--all?" + "--annotate" + "--any?" + "--count" + "--dotimes" + "--doto" + "--drop-while" + "--each" + "--each-r" + "--each-r-while" + "--each-while" + "--filter" + "--find-index" + "--find-indices" + "--find-last-index" + "--first" + "--fix" + "--group-by" + "--if-let" + "--iterate" + "--keep" + "--last" + "--map" + "--map-first" + "--map-indexed" + "--map-last" + "--map-when" + "--mapcat" + "--max-by" + "--min-by" + "--none?" + "--only-some?" + "--partition-by" + "--partition-by-header" + "--reduce" + "--reduce-from" + "--reduce-r" + "--reduce-r-from" + "--reductions" + "--reductions-from" + "--reductions-r" + "--reductions-r-from" + "--remove" + "--remove-first" + "--remove-last" + "--separate" + "--some" + "--sort" + "--splice" + "--splice-list" + "--split-when" + "--split-with" + "--take-while" + "--tree-map" + "--tree-map-nodes" + "--tree-mapreduce" + "--tree-mapreduce-from" + "--tree-reduce" + "--tree-reduce-from" + "--tree-seq" + "--unfold" + "--update-at" + "--when-let" + "--zip-with" + "->" + "->>" + "-as->" + "-doto" + "-if-let" + "-if-let*" + "-lambda" + "-let" + "-let*" + "-setq" + "-some-->" + "-some->" + "-some->>" + "-split-on" + "-when-let" + "-when-let*"))) + `((,(concat "(" (regexp-opt macs 'symbols)) . 1))))) + "Font lock keywords for `dash-fontify-mode'.") + +(defcustom dash-fontify-mode-lighter nil + "Mode line lighter for `dash-fontify-mode'. +Either a string to display in the mode line when +`dash-fontify-mode' is on, or nil to display +nothing (the default)." + :package-version '(dash . "2.18.0") + :group 'dash + :type '(choice (string :tag "Lighter" :value " Dash") + (const :tag "Nothing" nil))) + +;;;###autoload +(define-minor-mode dash-fontify-mode + "Toggle fontification of Dash special variables. + +Dash-Fontify mode is a buffer-local minor mode intended for Emacs +Lisp buffers. Enabling it causes the special variables bound in +anaphoric Dash macros to be fontified. These anaphoras include +`it', `it-index', `acc', and `other'. In older Emacs versions +which do not dynamically detect macros, Dash-Fontify mode +additionally fontifies Dash macro calls. + +See also `dash-fontify-mode-lighter' and +`global-dash-fontify-mode'." + :group 'dash :lighter dash-fontify-mode-lighter + (if dash-fontify-mode + (font-lock-add-keywords nil dash--keywords t) + (font-lock-remove-keywords nil dash--keywords)) + (cond ((fboundp 'font-lock-flush) ;; Added in Emacs 25. + (font-lock-flush)) + ;; `font-lock-fontify-buffer' unconditionally enables + ;; `font-lock-mode' and is marked `interactive-only' in later + ;; Emacs versions which have `font-lock-flush', so we guard + ;; and pacify as needed, respectively. + (font-lock-mode + (with-no-warnings + (font-lock-fontify-buffer))))) + +(defun dash--turn-on-fontify-mode () + "Enable `dash-fontify-mode' if in an Emacs Lisp buffer." + (when (derived-mode-p #'emacs-lisp-mode) + (dash-fontify-mode))) + +;;;###autoload +(define-globalized-minor-mode global-dash-fontify-mode + dash-fontify-mode dash--turn-on-fontify-mode + :group 'dash) + +(defcustom dash-enable-fontlock nil + "If non-nil, fontify Dash macro calls and special variables." + :group 'dash + :set (lambda (sym val) + (set-default sym val) + (global-dash-fontify-mode (if val 1 0))) + :type 'boolean) + +(make-obsolete-variable + 'dash-enable-fontlock #'global-dash-fontify-mode "2.18.0") + +(define-obsolete-function-alias + 'dash-enable-font-lock #'global-dash-fontify-mode "2.18.0") + +;;; Info + +(defvar dash--info-doc-spec '("(dash) Index" nil "^ -+ .*: " "\\( \\|$\\)") + "The Dash :doc-spec entry for `info-lookup-alist'. +It is based on that for `emacs-lisp-mode'.") + +(defun dash--info-elisp-docs () + "Return the `emacs-lisp-mode' symbol docs from `info-lookup-alist'. +Specifically, return the cons containing their +`info-lookup->doc-spec' so that we can modify it." + (defvar info-lookup-alist) + (nthcdr 3 (assq #'emacs-lisp-mode (cdr (assq 'symbol info-lookup-alist))))) + +;;;###autoload +(defun dash-register-info-lookup () + "Register the Dash Info manual with `info-lookup-symbol'. +This allows Dash symbols to be looked up with \\[info-lookup-symbol]." + (interactive) + (require 'info-look) + (let ((docs (dash--info-elisp-docs))) + (setcar docs (append (car docs) (list dash--info-doc-spec))) + (info-lookup-reset))) + +(defun dash-unload-function () + "Remove Dash from `info-lookup-alist'. +Used by `unload-feature', which see." + (let ((docs (and (featurep 'info-look) + (dash--info-elisp-docs)))) + (when (member dash--info-doc-spec (car docs)) + (setcar docs (remove dash--info-doc-spec (car docs))) + (info-lookup-reset))) + nil) + +(provide 'dash) +;;; dash.el ends here diff --git a/elpa/dash-20210826.1149/dash.elc b/elpa/dash-20210826.1149/dash.elc new file mode 100644 index 0000000..c37e49e Binary files /dev/null and b/elpa/dash-20210826.1149/dash.elc differ diff --git a/elpa/dash-20210826.1149/dash.info b/elpa/dash-20210826.1149/dash.info new file mode 100644 index 0000000..a6a2dc6 --- /dev/null +++ b/elpa/dash-20210826.1149/dash.info @@ -0,0 +1,4738 @@ +This is dash.info, produced by makeinfo version 6.7 from dash.texi. + +This manual is for Dash version 2.19.1. + + Copyright © 2012–2021 Free Software Foundation, Inc. + + Permission is granted to copy, distribute and/or modify this + document under the terms of the GNU Free Documentation License, + Version 1.3 or any later version published by the Free Software + Foundation; with the Invariant Sections being “GNU General Public + License,” and no Front-Cover Texts or Back-Cover Texts. A copy of + the license is included in the section entitled “GNU Free + Documentation License”. +INFO-DIR-SECTION Emacs +START-INFO-DIR-ENTRY +* Dash: (dash.info). A modern list library for GNU Emacs. +END-INFO-DIR-ENTRY + + +File: dash.info, Node: Top, Next: Installation, Up: (dir) + +Dash +**** + +This manual is for Dash version 2.19.1. + + Copyright © 2012–2021 Free Software Foundation, Inc. + + Permission is granted to copy, distribute and/or modify this + document under the terms of the GNU Free Documentation License, + Version 1.3 or any later version published by the Free Software + Foundation; with the Invariant Sections being “GNU General Public + License,” and no Front-Cover Texts or Back-Cover Texts. A copy of + the license is included in the section entitled “GNU Free + Documentation License”. + +* Menu: + +* Installation:: Installing and configuring Dash. +* Functions:: Dash API reference. +* Development:: Contributing to Dash development. + +Appendices + +* FDL:: The license for this documentation. +* GPL:: Conditions for copying and changing Dash. +* Index:: Index including functions and macros. + + — The Detailed Node Listing — + +Installation + +* Using in a package:: Listing Dash as a package dependency. +* Fontification of special variables:: Font Lock of anaphoric macro variables. +* Info symbol lookup:: Looking up Dash symbols in this manual. + +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. +* Contributors:: List of contributors. + + +File: dash.info, Node: Installation, Next: Functions, Prev: Top, Up: Top + +1 Installation +************** + +Dash is available on GNU ELPA (https://elpa.gnu.org/), GNU-devel ELPA +(https://elpa.gnu.org/devel/), and MELPA (https://melpa.org/), and can +be installed with the standard command ‘package-install’ (*note +(emacs)Package Installation::). + +‘M-x package-install dash ’ + Install the Dash library. + + Alternatively, you can just dump ‘dash.el’ in your ‘load-path’ +somewhere (*note (emacs)Lisp Libraries::). + +* Menu: + +* Using in a package:: Listing Dash as a package dependency. +* Fontification of special variables:: Font Lock of anaphoric macro variables. +* Info symbol lookup:: Looking up Dash symbols in this manual. + + +File: dash.info, Node: Using in a package, Next: Fontification of special variables, Up: Installation + +1.1 Using in a package +====================== + +If you use Dash in your own package, be sure to list it as a dependency +in the library’s headers as follows (*note (elisp)Library Headers::). + + ;; Package-Requires: ((dash "2.19.1")) + + +File: dash.info, Node: Fontification of special variables, Next: Info symbol lookup, Prev: Using in a package, Up: Installation + +1.2 Fontification of special variables +====================================== + +The autoloaded minor mode ‘dash-fontify-mode’ is provided for optional +fontification of anaphoric Dash variables (‘it’, ‘acc’, etc.) in Emacs +Lisp buffers using search-based Font Lock (*note (emacs)Font Lock::). +In older Emacs versions which do not dynamically detect macros, the +minor mode also fontifies calls to Dash macros. + + To automatically enable the minor mode in all Emacs Lisp buffers, +just call its autoloaded global counterpart ‘global-dash-fontify-mode’, +either interactively or from your ‘user-init-file’: + + (global-dash-fontify-mode) + + +File: dash.info, Node: Info symbol lookup, Prev: Fontification of special variables, Up: Installation + +1.3 Info symbol lookup +====================== + +While editing Elisp files, you can use ‘C-h S’ (‘info-lookup-symbol’) to +look up Elisp symbols in the relevant Info manuals (*note (emacs)Info +Lookup::). To enable the same for Dash symbols, use the command +‘dash-register-info-lookup’. It can be called directly when needed, or +automatically from your ‘user-init-file’. For example: + + (with-eval-after-load 'info-look + (dash-register-info-lookup)) + + +File: dash.info, Node: Functions, Next: Development, Prev: Installation, Up: Top + +2 Functions +*********** + +This chapter contains reference documentation for the Dash API +(Application Programming Interface). The names of all public functions +defined in the library are prefixed with a dash character (‘-’). + + The library also provides anaphoric macro versions of functions where +that makes sense. The names of these macros are prefixed with two +dashes (‘--’) instead of one. + + For instance, while the function ‘-map’ applies a function to each +element of a list, its anaphoric counterpart ‘--map’ evaluates a form +with the local variable ‘it’ temporarily bound to the current list +element instead. + + ;; Normal version. + (-map (lambda (n) (* n n)) '(1 2 3 4)) + ⇒ (1 4 9 16) + + ;; Anaphoric version. + (--map (* it it) '(1 2 3 4)) + ⇒ (1 4 9 16) + + The normal version can, of course, also be written as in the +following example, which demonstrates the utility of both versions. + + (defun my-square (n) + "Return N multiplied by itself." + (* n n)) + + (-map #'my-square '(1 2 3 4)) + ⇒ (1 4 9 16) + +* 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 a new list. + + -- Function: -map (fn list) + Apply FN to each item in LIST and return the list of results. + + This function’s anaphoric counterpart is ‘--map’. + + (-map (lambda (num) (* num num)) '(1 2 3 4)) + ⇒ (1 4 9 16) + (-map #'1+ '(1 2 3 4)) + ⇒ (2 3 4 5) + (--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 do 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-first (pred rep list) + Replace first item in LIST satisfying PRED with result of REP + called on this item. + + See also: ‘-map-when’ (*note -map-when::), ‘-replace-first’ (*note + -replace-first::) + + (-map-first 'even? 'square '(1 2 3 4)) + ⇒ (1 4 3 4) + (--map-first (> it 2) (* it it) '(1 2 3 4)) + ⇒ (1 2 9 4) + (--map-first (= it 2) 17 '(1 2 3 2)) + ⇒ (1 17 3 2) + + -- Function: -map-last (pred rep list) + Replace last item in LIST satisfying PRED with result of REP called + on this item. + + See also: ‘-map-when’ (*note -map-when::), ‘-replace-last’ (*note + -replace-last::) + + (-map-last 'even? 'square '(1 2 3 4)) + ⇒ (1 2 3 16) + (--map-last (> it 2) (* it it) '(1 2 3 4)) + ⇒ (1 2 3 16) + (--map-last (= it 2) 17 '(1 2 3 2)) + ⇒ (1 2 3 17) + + -- Function: -map-indexed (fn list) + Apply FN to each index and item in LIST and return the list of + results. This is like ‘-map’ (*note -map::), but FN takes two + arguments: the index of the current element within LIST, and the + element itself. + + This function’s anaphoric counterpart is ‘--map-indexed’. + + For a side-effecting variant, see also ‘-each-indexed’ (*note + -each-indexed::). + + (-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) + (-map-indexed #'* '(1 2 3 4)) + ⇒ (0 2 6 12) + + -- 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) + (--splice-list (keywordp it) '(a b c) '(1 :foo 2)) + ⇒ (1 a b c 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 (list) + 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 + non-nil. + + Alias: ‘-select’. + + This function’s anaphoric counterpart is ‘--filter’. + + For similar operations, see also ‘-keep’ (*note -keep::) and + ‘-remove’ (*note -remove::). + + (-filter (lambda (num) (= 0 (% num 2))) '(1 2 3 4)) + ⇒ (2 4) + (-filter #'natnump '(-2 -1 0 1 2)) + ⇒ (0 1 2) + (--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’. + + This function’s anaphoric counterpart is ‘--remove’. + + For similar operations, see also ‘-keep’ (*note -keep::) and + ‘-filter’ (*note -filter::). + + (-remove (lambda (num) (= 0 (% num 2))) '(1 2 3 4)) + ⇒ (1 3) + (-remove #'natnump '(-2 -1 0 1 2)) + ⇒ (-2 -1) + (--remove (= 0 (% it 2)) '(1 2 3 4)) + ⇒ (1 3) + + -- Function: -remove-first (pred list) + Remove the first item from LIST for which PRED returns non-nil. + This is a non-destructive operation, but only the front of LIST + leading up to the removed item is a copy; the rest is LIST’s + original tail. If no item is removed, then the result is a + complete copy. + + Alias: ‘-reject-first’. + + This function’s anaphoric counterpart is ‘--remove-first’. + + See also ‘-map-first’ (*note -map-first::), ‘-remove-item’ (*note + -remove-item::), and ‘-remove-last’ (*note -remove-last::). + + (-remove-first #'natnump '(-2 -1 0 1 2)) + ⇒ (-2 -1 1 2) + (-remove-first #'stringp '(1 2 "first" "second")) + ⇒ (1 2 "second") + (--remove-first (> it 3) '(1 2 3 4 5 6)) + ⇒ (1 2 3 5 6) + + -- Function: -remove-last (pred list) + Remove the last item from LIST for which PRED returns non-nil. The + result is a copy of LIST regardless of whether an element is + removed. + + Alias: ‘-reject-last’. + + This function’s anaphoric counterpart is ‘--remove-last’. + + See also ‘-map-last’ (*note -map-last::), ‘-remove-item’ (*note + -remove-item::), and ‘-remove-first’ (*note -remove-first::). + + (-remove-last #'natnump '(1 3 5 4 7 8 10 -11)) + ⇒ (1 3 5 4 7 8 -11) + (-remove-last #'stringp '(1 2 "last" "second")) + ⇒ (1 2 "last") + (--remove-last (> it 3) '(1 2 3 4 5 6 7 8 9 10)) + ⇒ (1 2 3 4 5 6 7 8 9) + + -- Function: -remove-item (item list) + Return a copy of LIST with all occurrences of ITEM removed. The + comparison is done with ‘equal’. + + (-remove-item 3 '(1 2 3 2 3 4 5 3)) + ⇒ (1 2 2 4 5) + (-remove-item 'foo '(foo bar baz foo)) + ⇒ (bar baz) + (-remove-item "bob" '("alice" "bob" "eve" "bob")) + ⇒ ("alice" "eve") + + -- Function: -non-nil (list) + Return a copy of LIST with all nil items removed. + + (-non-nil '(nil 1 nil 2 nil nil 3 4 nil 5 nil)) + ⇒ (1 2 3 4 5) + (-non-nil '((nil))) + ⇒ ((nil)) + (-non-nil ()) + ⇒ () + + -- 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 copy of the first N items in LIST. Return a copy of LIST + if it contains N items or fewer. Return nil if N is zero or less. + + See also: ‘-take-last’ (*note -take-last::). + + (-take 3 '(1 2 3 4 5)) + ⇒ (1 2 3) + (-take 17 '(1 2 3 4 5)) + ⇒ (1 2 3 4 5) + (-take 0 '(1 2 3 4 5)) + ⇒ () + + -- Function: -take-last (n list) + Return a copy of the last N items of LIST in order. Return a copy + of LIST if it contains N items or fewer. Return nil if N is zero + or less. + + See also: ‘-take’ (*note -take::). + + (-take-last 3 '(1 2 3 4 5)) + ⇒ (3 4 5) + (-take-last 17 '(1 2 3 4 5)) + ⇒ (1 2 3 4 5) + (-take-last 1 '(1 2 3 4 5)) + ⇒ (5) + + -- Function: -drop (n list) + Return the tail (not a copy) of LIST without the first N items. + Return nil if LIST contains N items or fewer. Return LIST if N is + zero or less. + + For another variant, see also ‘-drop-last’ (*note -drop-last::). + + (-drop 3 '(1 2 3 4 5)) + ⇒ (4 5) + (-drop 17 '(1 2 3 4 5)) + ⇒ () + (-drop 0 '(1 2 3 4 5)) + ⇒ (1 2 3 4 5) + + -- Function: -drop-last (n list) + Return a copy of LIST without its last N items. Return a copy of + LIST if N is zero or less. Return nil if LIST contains N items or + fewer. + + See also: ‘-drop’ (*note -drop::). + + (-drop-last 3 '(1 2 3 4 5)) + ⇒ (1 2) + (-drop-last 17 '(1 2 3 4 5)) + ⇒ () + (-drop-last 0 '(1 2 3 4 5)) + ⇒ (1 2 3 4 5) + + -- Function: -take-while (pred list) + Take successive items from LIST for which PRED returns non-nil. + PRED is a function of one argument. Return a new list of the + successive elements from the start of LIST for which PRED returns + non-nil. + + This function’s anaphoric counterpart is ‘--take-while’. + + For another variant, see also ‘-drop-while’ (*note -drop-while::). + + (-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) + Drop successive items from LIST for which PRED returns non-nil. + PRED is a function of one argument. Return the tail (not a copy) + of LIST starting from its first element for which PRED returns nil. + + This function’s anaphoric counterpart is ‘--drop-while’. + + For another variant, see also ‘-take-while’ (*note -take-while::). + + (-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") + + -- Function: -select-columns (columns table) + Select COLUMNS from TABLE. + + TABLE is a list of lists where each element represents one row. It + is assumed each row has the same length. + + Each row is transformed such that only the specified COLUMNS are + selected. + + See also: ‘-select-column’ (*note -select-column::), + ‘-select-by-indices’ (*note -select-by-indices::) + + (-select-columns '(0 2) '((1 2 3) (a b c) (:a :b :c))) + ⇒ ((1 3) (a c) (:a :c)) + (-select-columns '(1) '((1 2 3) (a b c) (:a :b :c))) + ⇒ ((2) (b) (:b)) + (-select-columns nil '((1 2 3) (a b c) (:a :b :c))) + ⇒ (nil nil nil) + + -- Function: -select-column (column table) + Select COLUMN from TABLE. + + TABLE is a list of lists where each element represents one row. It + is assumed each row has the same length. + + The single selected column is returned as a list. + + See also: ‘-select-columns’ (*note -select-columns::), + ‘-select-by-indices’ (*note -select-by-indices::) + + (-select-column 1 '((1 2 3) (a b c) (:a :b :c))) + ⇒ (2 b :b) + + +File: dash.info, Node: List to list, Next: Reductions, Prev: Sublist selection, Up: Functions + +2.3 List to list +================ + +Functions returning a modified copy of the input list. + + -- Function: -keep (fn list) + Return a new list of the non-nil results of applying FN to each + item in LIST. Like ‘-filter’ (*note -filter::), but returns the + non-nil results of FN instead of the corresponding elements of + LIST. + + Its anaphoric counterpart is ‘--keep’. + + (-keep #'cdr '((1 2 3) (4 5) (6))) + ⇒ ((2 3) (5)) + (-keep (lambda (n) (and (> n 3) (* 10 n))) '(1 2 3 4 5 6)) + ⇒ (40 50 60) + (--keep (and (> 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. + + Note that because ‘nil’ represents a list of zero elements (an + empty list), any mention of nil in L will disappear after + flattening. If you need to preserve nils, consider ‘-flatten-n’ + (*note -flatten-n::) or map them to some unique symbol and then map + them back. + + Conses of two atoms are considered "terminals", that is, they + aren’t flattened further. + + 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: -replace-first (old new list) + Replace the first occurrence of OLD with NEW in LIST. + + Elements are compared using ‘equal’. + + See also: ‘-map-first’ (*note -map-first::) + + (-replace-first 1 "1" '(1 2 3 4 3 2 1)) + ⇒ ("1" 2 3 4 3 2 1) + (-replace-first "foo" "bar" '("a" "nice" "foo" "sentence" "about" "foo")) + ⇒ ("a" "nice" "bar" "sentence" "about" "foo") + (-replace-first 1 2 nil) + ⇒ nil + + -- Function: -replace-last (old new list) + Replace the last occurrence of OLD with NEW in LIST. + + Elements are compared using ‘equal’. + + See also: ‘-map-last’ (*note -map-last::) + + (-replace-last 1 "1" '(1 2 3 4 3 2 1)) + ⇒ (1 2 3 4 3 2 "1") + (-replace-last "foo" "bar" '("a" "nice" "foo" "sentence" "about" "foo")) + ⇒ ("a" "nice" "foo" "sentence" "about" "bar") + (-replace-last 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 to a single value (which may also be a list). + + -- Function: -reduce-from (fn init list) + Reduce the function FN across LIST, starting with INIT. Return the + result of applying FN to INIT and the first element of LIST, then + applying FN to that result and the second element, etc. If LIST is + empty, return INIT without calling FN. + + This function’s anaphoric counterpart is ‘--reduce-from’. + + For other folds, see also ‘-reduce’ (*note -reduce::) and + ‘-reduce-r’ (*note -reduce-r::). + + (-reduce-from #'- 10 '(1 2 3)) + ⇒ 4 + (-reduce-from #'list 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 init list) + Reduce the function FN across LIST in reverse, starting with INIT. + Return the result of applying FN to the last element of LIST and + INIT, then applying FN to the second-to-last element and the + previous result of FN, etc. That is, the first argument of FN is + the current element, and its second argument the accumulated value. + If LIST is empty, return INIT without calling FN. + + This function is like ‘-reduce-from’ (*note -reduce-from::) but the + operation associates from the right rather than left. In other + words, it starts from the end of LIST and flips the arguments to + FN. Conceptually, it is like replacing the conses in LIST with + applications of FN, and its last link with INIT, and evaluating the + resulting expression. + + This function’s anaphoric counterpart is ‘--reduce-r-from’. + + For other folds, see also ‘-reduce-r’ (*note -reduce-r::) and + ‘-reduce’ (*note -reduce::). + + (-reduce-r-from #'- 10 '(1 2 3)) + ⇒ -8 + (-reduce-r-from #'list 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) + Reduce the function FN across LIST. Return the result of applying + FN to the first two elements of LIST, then applying FN to that + result and the third element, etc. If LIST contains a single + element, return it without calling FN. If LIST is empty, return + the result of calling FN with no arguments. + + This function’s anaphoric counterpart is ‘--reduce’. + + For other folds, see also ‘-reduce-from’ (*note -reduce-from::) and + ‘-reduce-r’ (*note -reduce-r::). + + (-reduce #'- '(1 2 3 4)) + ⇒ -8 + (-reduce #'list '(1 2 3 4)) + ⇒ (((1 2) 3) 4) + (--reduce (format "%s-%d" acc it) '(1 2 3)) + ⇒ "1-2-3" + + -- Function: -reduce-r (fn list) + Reduce the function FN across LIST in reverse. Return the result + of applying FN to the last two elements of LIST, then applying FN + to the third-to-last element and the previous result of FN, etc. + That is, the first argument of FN is the current element, and its + second argument the accumulated value. If LIST contains a single + element, return it without calling FN. If LIST is empty, return + the result of calling FN with no arguments. + + This function is like ‘-reduce’ (*note -reduce::) but the operation + associates from the right rather than left. In other words, it + starts from the end of LIST and flips the arguments to FN. + Conceptually, it is like replacing the conses in LIST with + applications of FN, ignoring its last link, and evaluating the + resulting expression. + + This function’s anaphoric counterpart is ‘--reduce-r’. + + For other folds, see also ‘-reduce-r-from’ (*note -reduce-r-from::) + and ‘-reduce’ (*note -reduce::). + + (-reduce-r #'- '(1 2 3 4)) + ⇒ -2 + (-reduce-r #'list '(1 2 3 4)) + ⇒ (1 (2 (3 4))) + (--reduce-r (format "%s-%d" acc it) '(1 2 3)) + ⇒ "3-2-1" + + -- Function: -reductions-from (fn init list) + Return a list of FN’s intermediate reductions across LIST. That + is, a list of the intermediate values of the accumulator when + ‘-reduce-from’ (*note -reduce-from::) (which see) is called with + the same arguments. + + This function’s anaphoric counterpart is ‘--reductions-from’. + + For other folds, see also ‘-reductions’ (*note -reductions::) and + ‘-reductions-r’ (*note -reductions-r::). + + (-reductions-from #'max 0 '(2 1 4 3)) + ⇒ (0 2 2 4 4) + (-reductions-from #'* 1 '(1 2 3 4)) + ⇒ (1 1 2 6 24) + (--reductions-from (format "(FN %s %d)" acc it) "INIT" '(1 2 3)) + ⇒ ("INIT" "(FN INIT 1)" "(FN (FN INIT 1) 2)" "(FN (FN (FN INIT 1) 2) 3)") + + -- Function: -reductions-r-from (fn init list) + Return a list of FN’s intermediate reductions across reversed LIST. + That is, a list of the intermediate values of the accumulator when + ‘-reduce-r-from’ (*note -reduce-r-from::) (which see) is called + with the same arguments. + + This function’s anaphoric counterpart is ‘--reductions-r-from’. + + For other folds, see also ‘-reductions’ (*note -reductions::) and + ‘-reductions-r’ (*note -reductions-r::). + + (-reductions-r-from #'max 0 '(2 1 4 3)) + ⇒ (4 4 4 3 0) + (-reductions-r-from #'* 1 '(1 2 3 4)) + ⇒ (24 24 12 4 1) + (--reductions-r-from (format "(FN %d %s)" it acc) "INIT" '(1 2 3)) + ⇒ ("(FN 1 (FN 2 (FN 3 INIT)))" "(FN 2 (FN 3 INIT))" "(FN 3 INIT)" "INIT") + + -- Function: -reductions (fn list) + Return a list of FN’s intermediate reductions across LIST. That + is, a list of the intermediate values of the accumulator when + ‘-reduce’ (*note -reduce::) (which see) is called with the same + arguments. + + This function’s anaphoric counterpart is ‘--reductions’. + + For other folds, see also ‘-reductions’ (*note -reductions::) and + ‘-reductions-r’ (*note -reductions-r::). + + (-reductions #'+ '(1 2 3 4)) + ⇒ (1 3 6 10) + (-reductions #'* '(1 2 3 4)) + ⇒ (1 2 6 24) + (--reductions (format "(FN %s %d)" acc it) '(1 2 3)) + ⇒ (1 "(FN 1 2)" "(FN (FN 1 2) 3)") + + -- Function: -reductions-r (fn list) + Return a list of FN’s intermediate reductions across reversed LIST. + That is, a list of the intermediate values of the accumulator when + ‘-reduce-r’ (*note -reduce-r::) (which see) is called with the same + arguments. + + This function’s anaphoric counterpart is ‘--reductions-r’. + + For other folds, see also ‘-reductions-r-from’ (*note + -reductions-r-from::) and ‘-reductions’ (*note -reductions::). + + (-reductions-r #'+ '(1 2 3 4)) + ⇒ (10 9 7 4) + (-reductions-r #'* '(1 2 3 4)) + ⇒ (24 24 12 4) + (--reductions-r (format "(FN %d %s)" it acc) '(1 2 3)) + ⇒ ("(FN 1 (FN 2 3))" "(FN 2 3)" 3) + + -- 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: -running-sum (list) + Return a list with running sums of items in LIST. LIST must be + non-empty. + + (-running-sum '(1 2 3 4)) + ⇒ (1 3 6 10) + (-running-sum '(1)) + ⇒ (1) + (-running-sum ()) + error→ Wrong type argument: consp, nil + + -- Function: -product (list) + Return the product of LIST. + + (-product ()) + ⇒ 1 + (-product '(1)) + ⇒ 1 + (-product '(1 2 3 4)) + ⇒ 24 + + -- Function: -running-product (list) + Return a list with running products of items in LIST. LIST must be + non-empty. + + (-running-product '(1 2 3 4)) + ⇒ (1 2 6 24) + (-running-product '(1)) + ⇒ (1) + (-running-product ()) + error→ Wrong type argument: consp, nil + + -- Function: -inits (list) + Return all prefixes of LIST. + + (-inits '(1 2 3 4)) + ⇒ (nil (1) (1 2) (1 2 3) (1 2 3 4)) + (-inits nil) + ⇒ (nil) + (-inits '(1)) + ⇒ (nil (1)) + + -- Function: -tails (list) + Return all suffixes of LIST + + (-tails '(1 2 3 4)) + ⇒ ((1 2 3 4) (2 3 4) (3 4) (4) nil) + (-tails nil) + ⇒ (nil) + (-tails '(1)) + ⇒ ((1) nil) + + -- Function: -common-prefix (&rest lists) + Return the longest common prefix of LISTS. + + (-common-prefix '(1)) + ⇒ (1) + (-common-prefix '(1 2) '(3 4) '(1 2)) + ⇒ () + (-common-prefix '(1 2) '(1 2 3) '(1 2 3 4)) + ⇒ (1 2) + + -- Function: -common-suffix (&rest lists) + Return the longest common suffix of LISTS. + + (-common-suffix '(1)) + ⇒ (1) + (-common-suffix '(1 2) '(3 4) '(1 2)) + ⇒ () + (-common-suffix '(1 2 3 4) '(2 3 4) '(3 4)) + ⇒ (3 4) + + -- 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 a 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 the 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 +============== + +Reductions of one or more lists to a boolean value. + + -- Function: -some (pred list) + Return (PRED x) for the first LIST item where (PRED x) is non-nil, + else nil. + + Alias: ‘-any’. + + This function’s anaphoric counterpart is ‘--some’. + + (-some #'stringp '(1 "2" 3)) + ⇒ t + (--some (string-match-p "x" it) '("foo" "axe" "xor")) + ⇒ 1 + (--some (= it-index 3) '(0 1 2)) + ⇒ nil + + -- Function: -every (pred list) + Return non-nil if PRED returns non-nil for all items in LIST. If + so, return the last such result of PRED. Otherwise, once an item + is reached for which PRED returns nil, return nil without calling + PRED on any further LIST elements. + + This function is like ‘-every-p’, but on success returns the last + non-nil result of PRED instead of just t. + + This function’s anaphoric counterpart is ‘--every’. + + (-every #'numberp '(1 2 3)) + ⇒ t + (--every (string-match-p "x" it) '("axe" "xor")) + ⇒ 0 + (--every (= it it-index) '(0 1 3)) + ⇒ nil + + -- 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? #'numberp '(nil 0 t)) + ⇒ t + (-any? #'numberp '(nil t t)) + ⇒ nil + (-any? #'null '(1 3 5)) + ⇒ nil + + -- Function: -all? (pred list) + Return t if (PRED X) is non-nil for all X in LIST, else nil. In + the latter case, stop after the first X for which (PRED X) is nil, + without calling PRED on any subsequent elements of LIST. + + The similar function ‘-every’ (*note -every::) is more widely + useful, since it returns the last non-nil result of PRED instead of + just t on success. + + Alias: ‘-all-p’, ‘-every-p’, ‘-every?’. + + This function’s anaphoric counterpart is ‘--all?’. + + (-all? #'numberp '(1 2 3)) + ⇒ t + (-all? #'numberp '(2 t 6)) + ⇒ nil + (--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 a 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 a 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 + + -- Function: -cons-pair? (obj) + Return non-nil if OBJ is a true cons pair. That is, a cons (A . + B) where B is not a list. + + Alias: ‘-cons-pair-p’. + + (-cons-pair? '(1 . 2)) + ⇒ t + (-cons-pair? '(1 2)) + ⇒ nil + (-cons-pair? '(1)) + ⇒ nil + + +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) + Split LIST into two sublists after the Nth element. The result is + a list of two elements (TAKE DROP) where TAKE is a new list of the + first N elements of LIST, and DROP is the remaining elements of + LIST (not a copy). TAKE and DROP are like the results of ‘-take’ + (*note -take::) and ‘-drop’ (*note -drop::), respectively, but the + split is done in a single list traversal. + + (-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) + (-split-at 0 '(1 2 3 4 5)) + ⇒ (nil (1 2 3 4 5)) + + -- 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)) + + -- Macro: -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: -partition-after-pred (pred list) + Partition LIST after each element for which PRED returns non-nil. + + This function’s anaphoric counterpart is ‘--partition-after-pred’. + + (-partition-after-pred #'booleanp ()) + ⇒ () + (-partition-after-pred #'booleanp '(t t)) + ⇒ ((t) (t)) + (-partition-after-pred #'booleanp '(0 0 t t 0 t)) + ⇒ ((0 0 t) (t) (0 t)) + + -- Function: -partition-before-pred (pred list) + Partition directly before each time PRED is true on an element of + LIST. + + (-partition-before-pred #'booleanp ()) + ⇒ () + (-partition-before-pred #'booleanp '(0 t)) + ⇒ ((0) (t)) + (-partition-before-pred #'booleanp '(0 0 t 0 t t)) + ⇒ ((0 0) (t 0) (t) (t)) + + -- Function: -partition-before-item (item list) + Partition directly before each time ITEM appears in LIST. + + (-partition-before-item 3 ()) + ⇒ () + (-partition-before-item 3 '(1)) + ⇒ ((1)) + (-partition-before-item 3 '(3)) + ⇒ ((3)) + + -- Function: -partition-after-item (item list) + Partition directly after each time ITEM appears in LIST. + + (-partition-after-item 3 ()) + ⇒ () + (-partition-after-item 3 '(1)) + ⇒ ((1)) + (-partition-after-item 3 '(3)) + ⇒ ((3)) + + -- 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 +============ + +Functions retrieving or sorting based on list indices and related +predicates. + + -- 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. + + See also ‘-first’ (*note -first::). + + (-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. + + See also ‘-last’ (*note -last::). + + (-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. This yields 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. This yields 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 LIST and elements of + LIST2 that are not in LIST. 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: -powerset (list) + Return the power set of LIST. + + (-powerset ()) + ⇒ (nil) + (-powerset '(x y z)) + ⇒ ((x y z) (x y) (x z) (x) (y z) (y) (z) nil) + + -- Function: -permutations (list) + Return the permutations of LIST. + + (-permutations ()) + ⇒ (nil) + (-permutations '(1 2)) + ⇒ ((1 2) (2 1)) + (-permutations '(a b c)) + ⇒ ((a b c) (a c b) (b a c) (b c a) (c a b) (c b a)) + + -- 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) + (-distinct '(t t t)) + ⇒ (t) + + +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 (left if N is negative). 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) + (-rotate 16 '(1 2 3 4 5 6 7)) + ⇒ (6 7 1 2 3 4 5) + + -- Function: -repeat (n x) + Return a new list of length N with each element being X. 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 elements of + ARGS are used as the final cons of the result, so if the final + element of ARGS is not a list, the result is a dotted list. With + no ARGS, return nil. + + (-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: -iota (count &optional start step) + Return a list containing COUNT numbers. Starts from START and adds + STEP each time. The default START is zero, the default STEP is 1. + This function takes its name from the corresponding primitive in + the APL language. + + (-iota 6) + ⇒ (0 1 2 3 4 5) + (-iota 4 2.5 -2) + ⇒ (2.5 0.5 -1.5 -3.5) + (-iota -1) + error→ Wrong type argument: natnump, -1 + + -- 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 + symbol ‘it’, and the elements from LIST2 as symbol ‘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. + + Use ‘-zip-lists’ (*note -zip-lists::) if you need the return value + to always be a list of lists. + + Alias: ‘-zip-pair’ + + See also: ‘-zip-lists’ (*note -zip-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 5) '(6)) + ⇒ ((1 3 6)) + + -- Function: -zip-lists (&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. + + The return value is always list of lists, which is a difference + from ‘-zip-pair’ which returns a cons-cell in case two input lists + are provided. + + See also: ‘-zip’ (*note -zip::) + + (-zip-lists '(1 2 3) '(4 5 6)) + ⇒ ((1 4) (2 5) (3 6)) + (-zip-lists '(1 2 3) '(4 5 6 7)) + ⇒ ((1 4) (2 5) (3 6)) + (-zip-lists '(1 2) '(3 4 5) '(6)) + ⇒ ((1 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: -unzip (lists) + Unzip LISTS. + + This works just like ‘-zip’ (*note -zip::) but takes a list of + lists instead of a variable number of arguments, such that + + (-unzip (-zip L1 L2 L3 ...)) + + is identity (given that the lists are the same length). + + Note in particular that calling this on a list of two lists will + return a list of cons-cells such that the above identity works. + + See also: ‘-zip’ (*note -zip::) + + (-unzip (-zip '(1 2 3) '(a b c) '("e" "f" "g"))) + ⇒ ((1 2 3) (a b c) ("e" "f" "g")) + (-unzip '((1 2) (3 4) (5 6) (7 8) (9 10))) + ⇒ ((1 3 5 7 9) (2 4 6 8 10)) + (-unzip '((1 2) (3 4))) + ⇒ ((1 . 3) (2 . 4)) + + -- Function: -cycle (list) + Return an infinite circular copy of LIST. The returned list cycles + through the elements of LIST and repeats 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)) (apply ’-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 item in LIST for which PRED returns non-nil. + Return nil if no such element is found. To get the first item in + the list no questions asked, use ‘car’. + + Alias: ‘-find’. + + This function’s anaphoric counterpart is ‘--first’. + + (-first #'natnump '(-1 0 1)) + ⇒ 0 + (-first #'null '(1 2 3)) + ⇒ nil + (--first (> it 2) '(1 2 3)) + ⇒ 3 + + -- 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. + + See also: ‘-second-item’ (*note -second-item::), ‘-last-item’ + (*note -last-item::). + + (-first-item '(1 2 3)) + ⇒ 1 + (-first-item nil) + ⇒ nil + (let ((list (list 1 2 3))) (setf (-first-item list) 5) list) + ⇒ (5 2 3) + + -- Function: -second-item (list) + Return the second item of LIST, or nil if LIST is too short. + + See also: ‘-third-item’ (*note -third-item::). + + (-second-item '(1 2 3)) + ⇒ 2 + (-second-item nil) + ⇒ nil + + -- Function: -third-item (list) + Return the third item of LIST, or nil if LIST is too short. + + See also: ‘-fourth-item’ (*note -fourth-item::). + + (-third-item '(1 2 3)) + ⇒ 3 + (-third-item nil) + ⇒ nil + + -- Function: -fourth-item (list) + Return the fourth item of LIST, or nil if LIST is too short. + + See also: ‘-fifth-item’ (*note -fifth-item::). + + (-fourth-item '(1 2 3 4)) + ⇒ 4 + (-fourth-item nil) + ⇒ nil + + -- Function: -fifth-item (list) + Return the fifth item of LIST, or nil if LIST is too short. + + See also: ‘-last-item’ (*note -last-item::). + + (-fifth-item '(1 2 3 4 5)) + ⇒ 5 + (-fifth-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 + (let ((list (list 1 2 3))) (setf (-last-item list) 5) list) + ⇒ (1 2 5) + + -- 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 (arg) + Ensure ARG is a list. If ARG is already a list, return it as is + (not a copy). Otherwise, return a new list with ARG as its only + element. + + Another supported calling convention is (-list &rest ARGS). In + this case, if ARG is not a list, a new list with all of ARGS as + elements is returned. This use is supported for backward + compatibility and is otherwise deprecated. + + (-list 1) + ⇒ (1) + (-list ()) + ⇒ () + (-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))) + ⇒ ((1) (2) (3)) + (let ((l '((starwars scifi) (jedi starwars warrior)))) (--fix (-uniq (--mapcat (cons it (cdr (assq it l))) 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) '("" ("

" "text" "

") "")) + ⇒ (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 "")))) '(body (p "some words") (div "more" (b "bold") "words"))) + ⇒ "

some words

more bold words
" + + -- 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) "}" '((elisp-mode (foo (bar . booze)) (baz . qux)) (c-mode (foo . bla) (bum . bam))))) + ⇒ "{elisp-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 +===================== + +Macros that conditionally combine sequential forms for brevity or +readability. + + -- Macro: -> (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) + + -- Macro: ->> (x &optional 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 + + -- Macro: --> (x &rest forms) + Starting with the value of X, thread each expression through FORMS. + + Insert X at the position signified by the symbol ‘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" + + -- Macro: -as-> (value variable &rest forms) + Starting with VALUE, thread VARIABLE through FORMS. + + In the first form, bind VARIABLE to VALUE. In the second form, + bind VARIABLE to the result of the first form, and so forth. + + (-as-> 3 my-var (1+ my-var) (list my-var) (mapcar (lambda (ele) (* 2 ele)) my-var)) + ⇒ (8) + (-as-> 3 my-var 1+) + ⇒ 4 + (-as-> 3 my-var) + ⇒ 3 + + -- Macro: -some-> (x &optional form &rest more) + When expr is non-nil, thread it through the first form (via ‘->’ + (*note ->::)), and when that result is non-nil, through the next + form, etc. + + (-some-> '(2 3 5)) + ⇒ (2 3 5) + (-some-> 5 square) + ⇒ 25 + (-some-> 5 even? square) + ⇒ nil + + -- Macro: -some->> (x &optional form &rest more) + When expr is non-nil, thread it through the first form (via ‘->>’ + (*note ->>::)), and when that result is non-nil, through the next + form, etc. + + (-some->> '(1 2 3) (-map 'square)) + ⇒ (1 4 9) + (-some->> '(1 3 5) (-last 'even?) (+ 100)) + ⇒ nil + (-some->> '(2 4 6) (-last 'even?) (+ 100)) + ⇒ 106 + + -- Macro: -some--> (expr &rest forms) + Thread EXPR through FORMS via ‘-->’ (*note -->::), while the result + is non-nil. When EXPR evaluates to non-nil, thread the result + through the first of FORMS, and when that result is non-nil, thread + it through the next form, etc. + + (-some--> "def" (concat "abc" it "ghi")) + ⇒ "abcdefghi" + (-some--> nil (concat "abc" it "ghi")) + ⇒ nil + (-some--> '(0 1) (-remove #'natnump it) (append it it) (-map #'1+ it)) + ⇒ () + + -- Macro: -doto (init &rest forms) + Evaluate INIT and pass it as argument to FORMS with ‘->’ (*note + ->::). The RESULT of evaluating INIT is threaded through each of + FORMS individually using ‘->’ (*note ->::), which see. The return + value is RESULT, which FORMS may have modified by side effect. + + (-doto (list 1 2 3) pop pop) + ⇒ (3) + (-doto (cons 1 2) (setcar 3) (setcdr 4)) + ⇒ (3 . 4) + (gethash 'k (--doto (make-hash-table) (puthash 'k 'v it))) + ⇒ v + + +File: dash.info, Node: Binding, Next: Side effects, Prev: Threading macros, Up: Functions + +2.13 Binding +============ + +Macros that combine ‘let’ and ‘let*’ with destructuring and flow +control. + + -- Macro: -when-let ((var val) &rest body) + If VAL evaluates to non-nil, bind it to VAR and execute body. + + 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 + + -- Macro: -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*::). VALS + are evaluated sequentially, and evaluation stops after the first + nil VAL is encountered. + + (-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 + + -- Macro: -if-let ((var val) then &rest else) + If VAL evaluates to non-nil, bind it to VAR and do THEN, otherwise + do ELSE. + + 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 + + -- Macro: -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*::). VALS + are evaluated sequentially, and evaluation stops after the first + nil VAL is encountered. + + (-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 + + -- Macro: -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. Uses + ‘plist-get’ to fetch values. + + (&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. Uses + ‘assoc’ to fetch values. + + (&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. + Uses ‘gethash’ to fetch values. + + 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). + + A shorthand notation for kv-destructuring exists which allows the + patterns be optionally left out and derived from the key name in + the following fashion: + + - a key :foo is converted into ‘foo’ pattern, - a key ’bar is + converted into ‘bar’ pattern, - a key "baz" is converted into ‘baz’ + pattern. + + That is, the entire value under the key is bound to the derived + variable without any further destructuring. + + This is possible only when the form following the key is not a + valid pattern (i.e. not a symbol, a cons cell or a vector). + Otherwise the matching proceeds as usual and in case of an invalid + spec fails with an error. + + Thus the patterns are normalized as follows: + + ;; derive all the missing patterns (&plist :foo ’bar "baz") => + (&plist :foo foo ’bar bar "baz" baz) + + ;; we can specify some but not others (&plist :foo ’bar + explicit-bar) => (&plist :foo foo ’bar explicit-bar) + + ;; nothing happens, we store :foo in x (&plist :foo x) => (&plist + :foo x) + + ;; nothing happens, we match recursively (&plist :foo (a b c)) => + (&plist :foo (a b c)) + + You can name the source using the syntax SYMBOL &as PATTERN. This + syntax works with lists (proper or improper), vectors and all types + of maps. + + (list &as a b c) (list 1 2 3) + + binds A to 1, B to 2, C to 3 and LIST to (1 2 3). + + Similarly: + + (bounds &as beg . end) (cons 1 2) + + binds BEG to 1, END to 2 and BOUNDS to (1 . 2). + + (items &as first . rest) (list 1 2 3) + + binds FIRST to 1, REST to (2 3) and ITEMS to (1 2 3) + + [vect &as _ b c] [1 2 3] + + binds B to 2, C to 3 and VECT to [1 2 3] (_ avoids binding as + usual). + + (plist &as &plist :b b) (list :a 1 :b 2 :c 3) + + binds B to 2 and PLIST to (:a 1 :b 2 :c 3). Same for &alist and + &hash. + + This is especially useful when we want to capture the result of a + computation and destructure at the same time. Consider the form + (function-returning-complex-structure) returning a list of two + vectors with two items each. We want to capture this entire result + and pass it to another computation, but at the same time we want to + get the second item from each vector. We can achieve it with + pattern + + (result &as [_ a] [_ b]) (function-returning-complex-structure) + + Note: Clojure programmers may know this feature as the ":as + binding". The difference is that we put the &as at the front + because we need to support improper list binding. + + (-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) + + -- Macro: -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)) + + -- Macro: -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 a description of the 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) + + -- Macro: -setq ([match-form val] ...) + Bind each MATCH-FORM to the value of its VAL. + + MATCH-FORM destructuring is done according to the rules of ‘-let’ + (*note -let::). + + This macro allows you to bind multiple variables by destructuring + the value, so for example: + + (-setq (a b) x (&plist :c c) plist) + + expands roughly speaking to the following code + + (setq a (car x) b (cadr x) c (plist-get plist :c)) + + Care is taken to only evaluate each VAL once so that in case of + multiple assignments it does not cause unexpected side effects. + + (let (a) (-setq a 1) a) + ⇒ 1 + (let (a b) (-setq (a b) (list 1 2)) (list a b)) + ⇒ (1 2) + (let (c) (-setq (&plist :c c) (list :c "c")) c) + ⇒ "c" + + +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 on each element of LIST. Return nil; this function is + intended for side effects. + + Its anaphoric counterpart is ‘--each’. + + For access to the current element’s index in LIST, see + ‘-each-indexed’ (*note -each-indexed::). + + (let (l) (-each '(1 2 3) (lambda (x) (push x l))) l) + ⇒ (3 2 1) + (let (l) (--each '(1 2 3) (push it l)) l) + ⇒ (3 2 1) + (-each '(1 2 3) #'identity) + ⇒ nil + + -- Function: -each-while (list pred fn) + Call FN on each ITEM in LIST, while (PRED ITEM) is non-nil. Once + an ITEM is reached for which PRED returns nil, FN is no longer + called. Return nil; this function is intended for side effects. + + Its anaphoric counterpart is ‘--each-while’. + + (let (l) (-each-while '(2 4 5 6) #'even? (lambda (x) (push x l))) l) + ⇒ (4 2) + (let (l) (--each-while '(1 2 3 4) (< it 3) (push it l)) l) + ⇒ (2 1) + (let ((s 0)) (--each-while '(1 3 4 5) (< it 5) (setq s (+ s it))) s) + ⇒ 8 + + -- Function: -each-indexed (list fn) + Call FN on each index and element of LIST. For each ITEM at INDEX + in LIST, call (funcall FN INDEX ITEM). Return nil; this function + is intended for side effects. + + See also: ‘-map-indexed’ (*note -map-indexed::). + + (let (l) (-each-indexed '(a b c) (lambda (i x) (push (list x i) l))) l) + ⇒ ((c 2) (b 1) (a 0)) + (let (l) (--each-indexed '(a b c) (push (list it it-index) l)) l) + ⇒ ((c 2) (b 1) (a 0)) + (let (l) (--each-indexed () (push it l)) l) + ⇒ () + + -- Function: -each-r (list fn) + Call FN on each element of LIST in reversed order. Return nil; + this function is intended for side effects. + + Its anaphoric counterpart is ‘--each-r’. + + (let (l) (-each-r '(1 2 3) (lambda (x) (push x l))) l) + ⇒ (1 2 3) + (let (l) (--each-r '(1 2 3) (push it l)) l) + ⇒ (1 2 3) + (-each-r '(1 2 3) #'identity) + ⇒ nil + + -- Function: -each-r-while (list pred fn) + Call FN on each ITEM in reversed LIST, while (PRED ITEM) is + non-nil. Once an ITEM is reached for which PRED returns nil, FN is + no longer called. Return nil; this function is intended for side + effects. + + Its anaphoric counterpart is ‘--each-r-while’. + + (let (l) (-each-r-while '(2 4 5 6) #'even? (lambda (x) (push x l))) l) + ⇒ (6) + (let (l) (--each-r-while '(1 2 3 4) (>= it 3) (push it l)) l) + ⇒ (3 4) + (let ((s 0)) (--each-r-while '(1 2 3 5) (> it 1) (setq s (+ s it))) s) + ⇒ 10 + + -- Function: -dotimes (num fn) + Call FN NUM times, presumably for side effects. FN is called with + a single argument on successive integers running from 0, inclusive, + to NUM, exclusive. FN is not called if NUM is less than 1. + + This function’s anaphoric counterpart is ‘--dotimes’. + + (let (s) (-dotimes 3 (lambda (n) (push n s))) s) + ⇒ (2 1 0) + (let (s) (-dotimes 0 (lambda (n) (push n s))) s) + ⇒ () + (let (s) (--dotimes 5 (push 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 +=========================== + +Macros that modify variables holding lists. + + -- Macro: !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) + + -- Macro: !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 +========================= + +Functions that manipulate and compose other functions. + + -- Function: -partial (fun &rest args) + Return a function that is a partial application of FUN to ARGS. + ARGS is a list of the first N arguments to pass to FUN. The result + is a new function which does the same as FUN, except that the first + N arguments are fixed at the values with which this function was + called. + + (funcall (-partial #'+ 5)) + ⇒ 5 + (funcall (-partial #'- 5) 3) + ⇒ 2 + (funcall (-partial #'+ 5 2) 3) + ⇒ 10 + + -- Function: -rpartial (fn &rest args) + Return a function that is a partial application of FN to ARGS. + ARGS is a list of the last N arguments to pass to FN. The result + is a new function which does the same as FN, except that the last N + arguments are fixed at the values with which this function was + called. This is like ‘-partial’ (*note -partial::), except the + arguments are fixed starting from the right rather than the left. + + (funcall (-rpartial #'- 5)) + ⇒ -5 + (funcall (-rpartial #'- 5) 8) + ⇒ 3 + (funcall (-rpartial #'- 5 2) 10) + ⇒ 3 + + -- Function: -juxt (&rest fns) + Return a function that is the juxtaposition of FNS. The returned + function takes a variable number of ARGS, applies each of FNS in + turn to ARGS, and returns the list of results. + + (funcall (-juxt) 1 2) + ⇒ () + (funcall (-juxt #'+ #'- #'* #'/) 7 5) + ⇒ (12 2 35 1) + (mapcar (-juxt #'number-to-string #'1+) '(1 2)) + ⇒ (("1" 2) ("2" 3)) + + -- Function: -compose (&rest fns) + Compose FNS into a single composite function. Return a function + that takes a variable number of ARGS, applies the last function in + FNS to ARGS, and returns the result of calling each remaining + function on the result of the previous function, right-to-left. If + no FNS are given, return a variadic ‘identity’ function. + + (funcall (-compose #'- #'1+ #'+) 1 2 3) + ⇒ -7 + (funcall (-compose #'identity #'1+) 3) + ⇒ 4 + (mapcar (-compose #'not #'stringp) '(nil "")) + ⇒ (t nil) + + -- Function: -applify (fn) + Return a function that applies FN to a single list of args. This + changes the arity of FN from taking N distinct arguments to taking + 1 argument which is a list of N arguments. + + (funcall (-applify #'+) nil) + ⇒ 0 + (mapcar (-applify #'+) '((1 1 1) (1 2 3) (5 5 5))) + ⇒ (3 6 15) + (funcall (-applify #'<) '(3 6)) + ⇒ t + + -- Function: -on (op trans) + Return a function that calls TRANS on each arg and OP on the + results. The returned function takes a variable number of + arguments, calls the function TRANS on each one in turn, and then + passes those results as the list of arguments to OP, in the same + order. + + For example, the following pairs of expressions are morally + equivalent: + + (funcall (-on #’+ #’1+) 1 2 3) = (+ (1+ 1) (1+ 2) (1+ 3)) (funcall + (-on #’+ #’1+)) = (+) + + (-sort (-on #'< #'length) '((1 2 3) (1) (1 2))) + ⇒ ((1) (1 2) (1 2 3)) + (funcall (-on #'min #'string-to-number) "22" "2" "1" "12") + ⇒ 1 + (-min-by (-on #'> #'length) '((1 2 3) (4) (1 2))) + ⇒ (4) + + -- Function: -flip (fn) + Return a function that calls FN with its arguments reversed. The + returned function takes the same number of arguments as FN. + + For example, the following two expressions are morally equivalent: + + (funcall (-flip #’-) 1 2) = (- 2 1) + + See also: ‘-rotate-args’ (*note -rotate-args::). + + (-sort (-flip #'<) '(4 3 6 1)) + ⇒ (6 4 3 1) + (funcall (-flip #'-) 3 2 1 10) + ⇒ 4 + (funcall (-flip #'1+) 1) + ⇒ 2 + + -- Function: -rotate-args (n fn) + Return a function that calls FN with args rotated N places to the + right. The returned function takes the same number of arguments as + FN, rotates the list of arguments N places to the right (left if N + is negative) just like ‘-rotate’ (*note -rotate::), and applies FN + to the result. + + See also: ‘-flip’ (*note -flip::). + + (funcall (-rotate-args -1 #'list) 1 2 3 4) + ⇒ (2 3 4 1) + (funcall (-rotate-args 1 #'-) 1 10 100) + ⇒ 89 + (funcall (-rotate-args 2 #'list) 3 4 5 1 2) + ⇒ (1 2 3 4 5) + + -- 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 + (mapcar (-const 1) '("a" "b" "c" "d")) + ⇒ (1 1 1 1) + (-sum (mapcar (-const 1) '("a" "b" "c" "d"))) + ⇒ 4 + + -- Macro: -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) + (-map (-cut <> 1 2 3) '(list vector string)) + ⇒ ((1 2 3) [1 2 3] "\1\2\3") + + -- Function: -not (pred) + Return a predicate that negates the result of PRED. The returned + predicate passes its arguments to PRED. If PRED returns nil, the + result is non-nil; otherwise the result is nil. + + See also: ‘-andfn’ (*note -andfn::) and ‘-orfn’ (*note -orfn::). + + (funcall (-not #'numberp) "5") + ⇒ t + (-sort (-not #'<) '(5 2 1 0 6)) + ⇒ (6 5 2 1 0) + (-filter (-not (-partial #'< 4)) '(1 2 3 4 5 6 7 8)) + ⇒ (1 2 3 4) + + -- Function: -orfn (&rest preds) + Return a predicate that returns the first non-nil result of PREDS. + The returned predicate takes a variable number of arguments, passes + them to each predicate in PREDS in turn until one of them returns + non-nil, and returns that non-nil result without calling the + remaining PREDS. If all PREDS return nil, or if no PREDS are + given, the returned predicate returns nil. + + See also: ‘-andfn’ (*note -andfn::) and ‘-not’ (*note -not::). + + (-filter (-orfn #'natnump #'booleanp) '(1 nil "a" -4 b c t)) + ⇒ (1 nil t) + (funcall (-orfn #'symbolp (-cut string-match-p "x" <>)) "axe") + ⇒ 1 + (funcall (-orfn #'= #'+) 1 1) + ⇒ t + + -- Function: -andfn (&rest preds) + Return a predicate that returns non-nil if all PREDS do so. The + returned predicate P takes a variable number of arguments and + passes them to each predicate in PREDS in turn. If any one of + PREDS returns nil, P also returns nil without calling the remaining + PREDS. If all PREDS return non-nil, P returns the last such value. + If no PREDS are given, P always returns non-nil. + + See also: ‘-orfn’ (*note -orfn::) and ‘-not’ (*note -not::). + + (-filter (-andfn #'numberp (-cut < <> 5)) '(a 1 b 6 c 2)) + ⇒ (1 2) + (mapcar (-andfn #'numberp #'1+) '(a 1 b 6)) + ⇒ (nil 2 nil 7) + (funcall (-andfn #'= #'+) 1 1) + ⇒ 2 + + -- 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 a + 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 + satisfied: + + 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 approximate comparison 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=) 0.7) + ⇒ 0.7390851332151607 + (funcall (-fixfn (lambda (x) (expt (+ x 10) 0.25))) 2.0) + ⇒ 1.8555845286409378 + (funcall (-fixfn #'sin #'approx=) 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- 'number-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-number) '((1 2 3) "15"))) + ⇒ 18 + + +File: dash.info, Node: Development, Next: FDL, Prev: Functions, Up: Top + +3 Development +************* + +The Dash repository is hosted on GitHub at +. + +* Menu: + +* Contribute:: How to contribute. +* Contributors:: List of contributors. + + +File: dash.info, Node: Contribute, Next: Contributors, Up: Development + +3.1 Contribute +============== + +Yes, please do. Pure functions in the list manipulation realm only, +please. There’s a suite of examples/tests in ‘dev/examples.el’, so +remember to add tests for your additions, or they may get broken later. + + Run the tests with ‘make check’. Regenerate the docs with ‘make +docs’. Contributors are encouraged to install these commands as a Git +pre-commit hook, so that the tests are always running and the docs are +always in sync: + + $ cp dev/pre-commit.sh .git/hooks/pre-commit + + Oh, and don’t edit ‘README.md’ or ‘dash.texi’ directly, as they are +auto-generated. Instead, change their respective templates +‘readme-template.md’ or ‘dash-template.texi’. + + To ensure that Dash can be distributed with GNU ELPA or Emacs, we +require that all contributors assign copyright to the Free Software +Foundation. For more on this, *note (emacs)Copyright Assignment::. + + +File: dash.info, Node: Contributors, Prev: Contribute, Up: Development + +3.2 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 a variadic version of ‘-zip’. + • Fredrik Bergroth (https://github.com/fbergroth) made the ‘-if-let’ + family use ‘-let’ destructuring and improved the script for + generating documentation. + • Mark Oteiza (https://github.com/holomorph) contributed ‘-iota’ and + the script to create an Info manual. + • Vasilij Schneidermann (https://github.com/wasamasa) contributed + ‘-some’. + • William West (https://github.com/occidens) made ‘-fixfn’ more + robust at handling floats. + • Cam Saul (https://github.com/camsaul) contributed ‘-some->’, + ‘-some->>’, and ‘-some-->’. + • Basil L. Contovounesios (https://github.com/basil-conto) + contributed ‘-common-prefix’, ‘-common-suffix’, and various other + improvements. + • Paul Pogonyshev (https://github.com/doublep) contributed ‘-each-r’ + and ‘-each-r-while’. + + Thanks! + + New contributors are very welcome. *Note Contribute::. + + +File: dash.info, Node: FDL, Next: GPL, Prev: Development, Up: Top + +Appendix A GNU Free Documentation License +***************************************** + + Version 1.3, 3 November 2008 + + Copyright © 2000, 2001, 2002, 2007, 2008 Free Software Foundation, Inc. + + + Everyone is permitted to copy and distribute verbatim copies + of this license document, but changing it is not allowed. + + 0. PREAMBLE + + The purpose of this License is to make a manual, textbook, or other + functional and useful document “free” in the sense of freedom: to + assure everyone the effective freedom to copy and redistribute it, + with or without modifying it, either commercially or + noncommercially. Secondarily, this License preserves for the + author and publisher a way to get credit for their work, while not + being considered responsible for modifications made by others. + + This License is a kind of “copyleft”, which means that derivative + works of the document must themselves be free in the same sense. + It complements the GNU General Public License, which is a copyleft + license designed for free software. + + We have designed this License in order to use it for manuals for + free software, because free software needs free documentation: a + free program should come with manuals providing the same freedoms + that the software does. But this License is not limited to + software manuals; it can be used for any textual work, regardless + of subject matter or whether it is published as a printed book. We + recommend this License principally for works whose purpose is + instruction or reference. + + 1. 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Interpretation of Sections 15 and 16. + + If the disclaimer of warranty and limitation of liability provided + above cannot be given local legal effect according to their terms, + reviewing courts shall apply local law that most closely + approximates an absolute waiver of all civil liability in + connection with the Program, unless a warranty or assumption of + liability accompanies a copy of the Program in return for a fee. + +END OF TERMS AND CONDITIONS +=========================== + +How to Apply These Terms to Your New Programs +============================================= + +If you develop a new program, and you want it to be of the greatest +possible use to the public, the best way to achieve this is to make it +free software which everyone can redistribute and change under these +terms. + + To do so, attach the following notices to the program. It is safest +to attach them to the start of each source file to most effectively +state the exclusion of warranty; and each file should have at least the +“copyright” line and a pointer to where the full notice is found. + + ONE LINE TO GIVE THE PROGRAM'S NAME AND A BRIEF IDEA OF WHAT IT DOES. + Copyright (C) YEAR NAME OF AUTHOR + + 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 . + + Also add information on how to contact you by electronic and paper +mail. + + If the program does terminal interaction, make it output a short +notice like this when it starts in an interactive mode: + + PROGRAM Copyright (C) YEAR NAME OF AUTHOR + This program comes with ABSOLUTELY NO WARRANTY; for details type ‘show w’. + This is free software, and you are welcome to redistribute it + under certain conditions; type ‘show c’ for details. + + The hypothetical commands ‘show w’ and ‘show c’ should show the +appropriate parts of the General Public License. Of course, your +program’s commands might be different; for a GUI interface, you would +use an “about box”. + + You should also get your employer (if you work as a programmer) or +school, if any, to sign a “copyright disclaimer” for the program, if +necessary. For more information on this, and how to apply and follow +the GNU GPL, see . + + The GNU General Public License does not permit incorporating your +program into proprietary programs. If your program is a subroutine +library, you may consider it more useful to permit linking proprietary +applications with the library. If this is what you want to do, use the +GNU Lesser General Public License instead of this License. But first, +please read . + + +File: dash.info, Node: Index, Prev: GPL, Up: Top + +Index +***** + +[index] +* Menu: + +* !cdr: Destructive operations. + (line 16) +* !cons: Destructive operations. + (line 8) +* -->: Threading macros. (line 35) +* ->: Threading macros. (line 9) +* ->>: Threading macros. (line 22) +* -all?: Predicates. (line 53) +* -andfn: Function combinators. + (line 184) +* -annotate: Maps. (line 84) +* -any?: Predicates. (line 41) +* -applify: Function combinators. + (line 63) +* -as->: Threading macros. (line 49) +* -butlast: Other list operations. + (line 335) +* -clone: Tree operations. (line 122) +* -common-prefix: Reductions. (line 242) +* -common-suffix: Reductions. (line 252) +* -compose: Function combinators. + (line 49) +* -concat: List to list. (line 23) +* -cons*: Other list operations. + (line 30) +* -cons-pair?: Predicates. (line 167) +* -const: Function combinators. + (line 128) +* -contains?: Predicates. (line 100) +* -copy: Maps. (line 139) +* -count: Reductions. (line 172) +* -cut: Function combinators. + (line 140) +* -cycle: Other list operations. + (line 180) +* -difference: Set operations. (line 20) +* -distinct: Set operations. (line 62) +* -dotimes: Side effects. (line 80) +* -doto: Threading macros. (line 99) +* -drop: Sublist selection. (line 147) +* -drop-last: Sublist selection. (line 161) +* -drop-while: Sublist selection. (line 192) +* -each: Side effects. (line 8) +* -each-indexed: Side effects. (line 38) +* -each-r: Side effects. (line 52) +* -each-r-while: Side effects. (line 65) +* -each-while: Side effects. (line 24) +* -elem-index: Indexing. (line 9) +* -elem-indices: Indexing. (line 21) +* -every: Predicates. (line 23) +* -fifth-item: Other list operations. + (line 315) +* -filter: Sublist selection. (line 8) +* -find-index: Indexing. (line 32) +* -find-indices: Indexing. (line 60) +* -find-last-index: Indexing. (line 46) +* -first: Other list operations. + (line 246) +* -first-item: Other list operations. + (line 272) +* -fix: Other list operations. + (line 375) +* -fixfn: Function combinators. + (line 224) +* -flatten: List to list. (line 34) +* -flatten-n: List to list. (line 56) +* -flip: Function combinators. + (line 95) +* -fourth-item: Other list operations. + (line 305) +* -grade-down: Indexing. (line 81) +* -grade-up: Indexing. (line 71) +* -group-by: Partitioning. (line 194) +* -if-let: Binding. (line 34) +* -if-let*: Binding. (line 45) +* -inits: Reductions. (line 222) +* -insert-at: List to list. (line 110) +* -interleave: Other list operations. + (line 67) +* -interpose: Other list operations. + (line 57) +* -intersection: Set operations. (line 32) +* -iota: Other list operations. + (line 78) +* -is-infix?: Predicates. (line 153) +* -is-prefix?: Predicates. (line 129) +* -is-suffix?: Predicates. (line 141) +* -iterate: Unfolding. (line 9) +* -iteratefn: Function combinators. + (line 201) +* -juxt: Function combinators. + (line 37) +* -keep: List to list. (line 8) +* -lambda: Binding. (line 247) +* -last: Other list operations. + (line 262) +* -last-item: Other list operations. + (line 325) +* -let: Binding. (line 61) +* -let*: Binding. (line 227) +* -list: Other list operations. + (line 358) +* -map: Maps. (line 10) +* -map-first: Maps. (line 38) +* -map-indexed: Maps. (line 66) +* -map-last: Maps. (line 52) +* -map-when: Maps. (line 22) +* -mapcat: Maps. (line 128) +* -max: Reductions. (line 286) +* -max-by: Reductions. (line 296) +* -min: Reductions. (line 262) +* -min-by: Reductions. (line 272) +* -non-nil: Sublist selection. (line 94) +* -none?: Predicates. (line 73) +* -not: Function combinators. + (line 153) +* -on: Function combinators. + (line 75) +* -only-some?: Predicates. (line 85) +* -orfn: Function combinators. + (line 167) +* -pad: Other list operations. + (line 191) +* -partial: Function combinators. + (line 8) +* -partition: Partitioning. (line 80) +* -partition-after-item: Partitioning. (line 184) +* -partition-after-pred: Partitioning. (line 151) +* -partition-all: Partitioning. (line 92) +* -partition-all-in-steps: Partitioning. (line 115) +* -partition-before-item: Partitioning. (line 174) +* -partition-before-pred: Partitioning. (line 163) +* -partition-by: Partitioning. (line 127) +* -partition-by-header: Partitioning. (line 138) +* -partition-in-steps: Partitioning. (line 103) +* -permutations: Set operations. (line 52) +* -powerset: Set operations. (line 44) +* -prodfn: Function combinators. + (line 258) +* -product: Reductions. (line 201) +* -reduce: Reductions. (line 53) +* -reduce-from: Reductions. (line 8) +* -reduce-r: Reductions. (line 72) +* -reduce-r-from: Reductions. (line 26) +* -reductions: Reductions. (line 136) +* -reductions-from: Reductions. (line 100) +* -reductions-r: Reductions. (line 154) +* -reductions-r-from: Reductions. (line 118) +* -remove: Sublist selection. (line 26) +* -remove-at: List to list. (line 146) +* -remove-at-indices: List to list. (line 159) +* -remove-first: Sublist selection. (line 43) +* -remove-item: Sublist selection. (line 83) +* -remove-last: Sublist selection. (line 64) +* -repeat: Other list operations. + (line 19) +* -replace: List to list. (line 68) +* -replace-at: List to list. (line 121) +* -replace-first: List to list. (line 82) +* -replace-last: List to list. (line 96) +* -rotate: Other list operations. + (line 8) +* -rotate-args: Function combinators. + (line 112) +* -rpartial: Function combinators. + (line 22) +* -running-product: Reductions. (line 211) +* -running-sum: Reductions. (line 190) +* -same-items?: Predicates. (line 115) +* -second-item: Other list operations. + (line 285) +* -select-by-indices: Sublist selection. (line 208) +* -select-column: Sublist selection. (line 238) +* -select-columns: Sublist selection. (line 219) +* -separate: Partitioning. (line 69) +* -setq: Binding. (line 270) +* -slice: Sublist selection. (line 104) +* -snoc: Other list operations. + (line 43) +* -some: Predicates. (line 8) +* -some-->: Threading macros. (line 86) +* -some->: Threading macros. (line 62) +* -some->>: Threading macros. (line 74) +* -sort: Other list operations. + (line 345) +* -splice: Maps. (line 95) +* -splice-list: Maps. (line 115) +* -split-at: Partitioning. (line 8) +* -split-on: Partitioning. (line 34) +* -split-when: Partitioning. (line 52) +* -split-with: Partitioning. (line 23) +* -sum: Reductions. (line 180) +* -table: Other list operations. + (line 202) +* -table-flat: Other list operations. + (line 221) +* -tails: Reductions. (line 232) +* -take: Sublist selection. (line 120) +* -take-last: Sublist selection. (line 133) +* -take-while: Sublist selection. (line 175) +* -third-item: Other list operations. + (line 295) +* -tree-map: Tree operations. (line 28) +* -tree-map-nodes: Tree operations. (line 39) +* -tree-mapreduce: Tree operations. (line 84) +* -tree-mapreduce-from: Tree operations. (line 103) +* -tree-reduce: Tree operations. (line 52) +* -tree-reduce-from: Tree operations. (line 69) +* -tree-seq: Tree operations. (line 8) +* -unfold: Unfolding. (line 25) +* -union: Set operations. (line 8) +* -unzip: Other list operations. + (line 158) +* -update-at: List to list. (line 133) +* -when-let: Binding. (line 9) +* -when-let*: Binding. (line 21) +* -zip: Other list operations. + (line 107) +* -zip-fill: Other list operations. + (line 150) +* -zip-lists: Other list operations. + (line 131) +* -zip-with: Other list operations. + (line 91) +* dash-fontify-mode: Fontification of special variables. + (line 6) +* dash-register-info-lookup: Info symbol lookup. (line 6) +* global-dash-fontify-mode: Fontification of special variables. + (line 12) + + + +Tag Table: +Node: Top742 +Node: Installation2397 +Node: Using in a package3159 +Node: Fontification of special variables3504 +Node: Info symbol lookup4294 +Node: Functions4877 +Node: Maps6361 +Ref: -map6658 +Ref: -map-when7031 +Ref: -map-first7606 +Ref: -map-last8081 +Ref: -map-indexed8551 +Ref: -annotate9237 +Ref: -splice9724 +Ref: -splice-list10502 +Ref: -mapcat10961 +Ref: -copy11334 +Node: Sublist selection11522 +Ref: -filter11715 +Ref: -remove12262 +Ref: -remove-first12800 +Ref: -remove-last13642 +Ref: -remove-item14367 +Ref: -non-nil14767 +Ref: -slice15043 +Ref: -take15572 +Ref: -take-last15979 +Ref: -drop16410 +Ref: -drop-last16851 +Ref: -take-while17277 +Ref: -drop-while17892 +Ref: -select-by-indices18508 +Ref: -select-columns19019 +Ref: -select-column19722 +Node: List to list20185 +Ref: -keep20377 +Ref: -concat20941 +Ref: -flatten21235 +Ref: -flatten-n21991 +Ref: -replace22375 +Ref: -replace-first22836 +Ref: -replace-last23331 +Ref: -insert-at23819 +Ref: -replace-at24144 +Ref: -update-at24531 +Ref: -remove-at25019 +Ref: -remove-at-indices25504 +Node: Reductions26083 +Ref: -reduce-from26279 +Ref: -reduce-r-from27003 +Ref: -reduce28266 +Ref: -reduce-r29017 +Ref: -reductions-from30295 +Ref: -reductions-r-from31101 +Ref: -reductions31931 +Ref: -reductions-r32642 +Ref: -count33387 +Ref: -sum33611 +Ref: -running-sum33799 +Ref: -product34120 +Ref: -running-product34328 +Ref: -inits34669 +Ref: -tails34914 +Ref: -common-prefix35158 +Ref: -common-suffix35452 +Ref: -min35746 +Ref: -min-by35972 +Ref: -max36493 +Ref: -max-by36718 +Node: Unfolding37244 +Ref: -iterate37485 +Ref: -unfold37932 +Node: Predicates38737 +Ref: -some38914 +Ref: -every39331 +Ref: -any?40010 +Ref: -all?40341 +Ref: -none?41048 +Ref: -only-some?41350 +Ref: -contains?41835 +Ref: -same-items?42224 +Ref: -is-prefix?42609 +Ref: -is-suffix?42935 +Ref: -is-infix?43261 +Ref: -cons-pair?43615 +Node: 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+Ref: -each-while92096 +Ref: -each-indexed92698 +Ref: -each-r93284 +Ref: -each-r-while93720 +Ref: -dotimes94346 +Node: Destructive operations94899 +Ref: !cons95117 +Ref: !cdr95321 +Node: Function combinators95514 +Ref: -partial95718 +Ref: -rpartial96236 +Ref: -juxt96884 +Ref: -compose97336 +Ref: -applify97943 +Ref: -on98373 +Ref: -flip99145 +Ref: -rotate-args99669 +Ref: -const100298 +Ref: -cut100640 +Ref: -not101120 +Ref: -orfn101646 +Ref: -andfn102408 +Ref: -iteratefn103164 +Ref: -fixfn103866 +Ref: -prodfn105422 +Node: Development106480 +Node: Contribute106769 +Node: Contributors107781 +Node: FDL109874 +Node: GPL135194 +Node: Index172943 + +End Tag Table + + +Local Variables: +coding: utf-8 +End: diff --git a/elpa/dash-20210826.1149/dir b/elpa/dash-20210826.1149/dir new file mode 100644 index 0000000..7d473f4 --- /dev/null +++ b/elpa/dash-20210826.1149/dir @@ -0,0 +1,18 @@ +This is the file .../info/dir, which contains the +topmost node of the Info hierarchy, called (dir)Top. +The first time you invoke Info you start off looking at this node. + +File: dir, Node: Top This is the top of the INFO tree + + This (the Directory node) gives a menu of major topics. + Typing "q" exits, "H" lists all Info commands, "d" returns here, + "h" gives a primer for first-timers, + "mEmacs" visits the Emacs manual, etc. + + In Emacs, you can click mouse button 2 on a menu item or cross reference + to select it. + +* Menu: + +Emacs +* Dash: (dash.info). A modern list library for GNU Emacs. -- cgit v1.2.1