mirror of
https://git.savannah.gnu.org/git/emacs.git
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1223 lines
40 KiB
EmacsLisp
1223 lines
40 KiB
EmacsLisp
;;; cl-loaddefs.el --- automatically extracted autoloads
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;;
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;;; Code:
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;;;### (autoloads (cl-prettyexpand cl-macroexpand-all cl-remprop
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;;;;;; cl-do-remf cl-set-getf getf get* tailp list-length nreconc
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;;;;;; revappend concatenate subseq cl-float-limits random-state-p
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;;;;;; make-random-state random* signum rem* mod* round* truncate*
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;;;;;; ceiling* floor* isqrt lcm gcd cl-progv-before cl-set-frame-visible-p
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;;;;;; cl-map-overlays cl-map-intervals cl-map-keymap-recursively
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;;;;;; notevery notany every some mapcon mapcan mapl maplist map
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;;;;;; cl-mapcar-many equalp coerce) "cl-extra" "cl-extra.el" "7988f2bc52c60f3e7cac9970430d1df3")
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;;; Generated autoloads from cl-extra.el
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(autoload 'coerce "cl-extra" "\
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Coerce OBJECT to type TYPE.
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TYPE is a Common Lisp type specifier.
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\(fn OBJECT TYPE)" nil nil)
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(autoload 'equalp "cl-extra" "\
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Return t if two Lisp objects have similar structures and contents.
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This is like `equal', except that it accepts numerically equal
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numbers of different types (float vs. integer), and also compares
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strings case-insensitively.
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\(fn X Y)" nil nil)
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(autoload 'cl-mapcar-many "cl-extra" "\
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Not documented
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\(fn CL-FUNC CL-SEQS)" nil nil)
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(autoload 'map "cl-extra" "\
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Map a FUNCTION across one or more SEQUENCEs, returning a sequence.
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TYPE is the sequence type to return.
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\(fn TYPE FUNCTION SEQUENCE...)" nil nil)
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(autoload 'maplist "cl-extra" "\
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Map FUNCTION to each sublist of LIST or LISTs.
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Like `mapcar', except applies to lists and their cdr's rather than to
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the elements themselves.
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\(fn FUNCTION LIST...)" nil nil)
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(autoload 'mapl "cl-extra" "\
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Like `maplist', but does not accumulate values returned by the function.
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\(fn FUNCTION LIST...)" nil nil)
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(autoload 'mapcan "cl-extra" "\
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Like `mapcar', but nconc's together the values returned by the function.
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\(fn FUNCTION SEQUENCE...)" nil nil)
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(autoload 'mapcon "cl-extra" "\
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Like `maplist', but nconc's together the values returned by the function.
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\(fn FUNCTION LIST...)" nil nil)
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(autoload 'some "cl-extra" "\
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Return true if PREDICATE is true of any element of SEQ or SEQs.
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If so, return the true (non-nil) value returned by PREDICATE.
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\(fn PREDICATE SEQ...)" nil nil)
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(autoload 'every "cl-extra" "\
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Return true if PREDICATE is true of every element of SEQ or SEQs.
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\(fn PREDICATE SEQ...)" nil nil)
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(autoload 'notany "cl-extra" "\
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Return true if PREDICATE is false of every element of SEQ or SEQs.
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\(fn PREDICATE SEQ...)" nil nil)
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(autoload 'notevery "cl-extra" "\
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Return true if PREDICATE is false of some element of SEQ or SEQs.
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\(fn PREDICATE SEQ...)" nil nil)
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(defalias 'cl-map-keymap 'map-keymap)
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(autoload 'cl-map-keymap-recursively "cl-extra" "\
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Not documented
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\(fn CL-FUNC-REC CL-MAP &optional CL-BASE)" nil nil)
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(autoload 'cl-map-intervals "cl-extra" "\
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Not documented
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\(fn CL-FUNC &optional CL-WHAT CL-PROP CL-START CL-END)" nil nil)
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(autoload 'cl-map-overlays "cl-extra" "\
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Not documented
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\(fn CL-FUNC &optional CL-BUFFER CL-START CL-END CL-ARG)" nil nil)
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(autoload 'cl-set-frame-visible-p "cl-extra" "\
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Not documented
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\(fn FRAME VAL)" nil nil)
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(autoload 'cl-progv-before "cl-extra" "\
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Not documented
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\(fn SYMS VALUES)" nil nil)
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(autoload 'gcd "cl-extra" "\
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Return the greatest common divisor of the arguments.
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\(fn &rest ARGS)" nil nil)
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(autoload 'lcm "cl-extra" "\
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Return the least common multiple of the arguments.
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\(fn &rest ARGS)" nil nil)
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(autoload 'isqrt "cl-extra" "\
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Return the integer square root of the argument.
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\(fn X)" nil nil)
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(autoload 'floor* "cl-extra" "\
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Return a list of the floor of X and the fractional part of X.
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With two arguments, return floor and remainder of their quotient.
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\(fn X &optional Y)" nil nil)
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(autoload 'ceiling* "cl-extra" "\
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Return a list of the ceiling of X and the fractional part of X.
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With two arguments, return ceiling and remainder of their quotient.
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\(fn X &optional Y)" nil nil)
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(autoload 'truncate* "cl-extra" "\
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Return a list of the integer part of X and the fractional part of X.
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With two arguments, return truncation and remainder of their quotient.
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\(fn X &optional Y)" nil nil)
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(autoload 'round* "cl-extra" "\
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Return a list of X rounded to the nearest integer and the remainder.
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With two arguments, return rounding and remainder of their quotient.
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\(fn X &optional Y)" nil nil)
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(autoload 'mod* "cl-extra" "\
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The remainder of X divided by Y, with the same sign as Y.
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\(fn X Y)" nil nil)
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(autoload 'rem* "cl-extra" "\
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The remainder of X divided by Y, with the same sign as X.
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\(fn X Y)" nil nil)
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(autoload 'signum "cl-extra" "\
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Return 1 if X is positive, -1 if negative, 0 if zero.
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\(fn X)" nil nil)
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(autoload 'random* "cl-extra" "\
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Return a random nonnegative number less than LIM, an integer or float.
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Optional second arg STATE is a random-state object.
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\(fn LIM &optional STATE)" nil nil)
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(autoload 'make-random-state "cl-extra" "\
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Return a copy of random-state STATE, or of `*random-state*' if omitted.
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If STATE is t, return a new state object seeded from the time of day.
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\(fn &optional STATE)" nil nil)
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(autoload 'random-state-p "cl-extra" "\
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Return t if OBJECT is a random-state object.
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\(fn OBJECT)" nil nil)
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(autoload 'cl-float-limits "cl-extra" "\
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Not documented
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\(fn)" nil nil)
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(autoload 'subseq "cl-extra" "\
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Return the subsequence of SEQ from START to END.
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If END is omitted, it defaults to the length of the sequence.
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If START or END is negative, it counts from the end.
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\(fn SEQ START &optional END)" nil nil)
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(autoload 'concatenate "cl-extra" "\
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Concatenate, into a sequence of type TYPE, the argument SEQUENCEs.
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\(fn TYPE SEQUENCE...)" nil nil)
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(autoload 'revappend "cl-extra" "\
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Equivalent to (append (reverse X) Y).
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\(fn X Y)" nil nil)
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(autoload 'nreconc "cl-extra" "\
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Equivalent to (nconc (nreverse X) Y).
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\(fn X Y)" nil nil)
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(autoload 'list-length "cl-extra" "\
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Return the length of list X. Return nil if list is circular.
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\(fn X)" nil nil)
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(autoload 'tailp "cl-extra" "\
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Return true if SUBLIST is a tail of LIST.
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\(fn SUBLIST LIST)" nil nil)
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(autoload 'get* "cl-extra" "\
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Return the value of SYMBOL's PROPNAME property, or DEFAULT if none.
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\(fn SYMBOL PROPNAME &optional DEFAULT)" nil nil)
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(autoload 'getf "cl-extra" "\
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Search PROPLIST for property PROPNAME; return its value or DEFAULT.
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PROPLIST is a list of the sort returned by `symbol-plist'.
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\(fn PROPLIST PROPNAME &optional DEFAULT)" nil nil)
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(autoload 'cl-set-getf "cl-extra" "\
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Not documented
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\(fn PLIST TAG VAL)" nil nil)
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(autoload 'cl-do-remf "cl-extra" "\
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Not documented
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\(fn PLIST TAG)" nil nil)
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(autoload 'cl-remprop "cl-extra" "\
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Remove from SYMBOL's plist the property PROPNAME and its value.
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\(fn SYMBOL PROPNAME)" nil nil)
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(defalias 'remprop 'cl-remprop)
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(defalias 'cl-gethash 'gethash)
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(defalias 'cl-puthash 'puthash)
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(defalias 'cl-remhash 'remhash)
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(defalias 'cl-clrhash 'clrhash)
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(defalias 'cl-maphash 'maphash)
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(defalias 'cl-make-hash-table 'make-hash-table)
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(defalias 'cl-hash-table-p 'hash-table-p)
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(defalias 'cl-hash-table-count 'hash-table-count)
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(autoload 'cl-macroexpand-all "cl-extra" "\
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Expand all macro calls through a Lisp FORM.
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This also does some trivial optimizations to make the form prettier.
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\(fn FORM &optional ENV)" nil nil)
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(autoload 'cl-prettyexpand "cl-extra" "\
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Not documented
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\(fn FORM &optional FULL)" nil nil)
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;;;***
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;;;### (autoloads (compiler-macroexpand define-compiler-macro assert
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;;;;;; check-type typep cl-struct-setf-expander defstruct define-modify-macro
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;;;;;; callf2 callf letf* letf rotatef shiftf remf cl-do-pop psetf
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;;;;;; setf get-setf-method defsetf define-setf-method declare the
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;;;;;; locally multiple-value-setq multiple-value-bind lexical-let*
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;;;;;; lexical-let symbol-macrolet macrolet labels flet progv psetq
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;;;;;; do-all-symbols do-symbols dotimes dolist do* do loop return-from
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;;;;;; return block etypecase typecase ecase case load-time-value
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;;;;;; eval-when destructuring-bind function* defmacro* defun* gentemp
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;;;;;; gensym) "cl-macs" "cl-macs.el" "5eed0057bf35ca41a5e133d1ec6204d0")
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;;; Generated autoloads from cl-macs.el
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(autoload 'gensym "cl-macs" "\
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Generate a new uninterned symbol.
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The name is made by appending a number to PREFIX, default \"G\".
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\(fn &optional PREFIX)" nil nil)
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(autoload 'gentemp "cl-macs" "\
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Generate a new interned symbol with a unique name.
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The name is made by appending a number to PREFIX, default \"G\".
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\(fn &optional PREFIX)" nil nil)
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(autoload 'defun* "cl-macs" "\
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Define NAME as a function.
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Like normal `defun', except ARGLIST allows full Common Lisp conventions,
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and BODY is implicitly surrounded by (block NAME ...).
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\(fn NAME ARGLIST [DOCSTRING] BODY...)" nil (quote macro))
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(autoload 'defmacro* "cl-macs" "\
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Define NAME as a macro.
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Like normal `defmacro', except ARGLIST allows full Common Lisp conventions,
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and BODY is implicitly surrounded by (block NAME ...).
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\(fn NAME ARGLIST [DOCSTRING] BODY...)" nil (quote macro))
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(autoload 'function* "cl-macs" "\
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Introduce a function.
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Like normal `function', except that if argument is a lambda form,
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its argument list allows full Common Lisp conventions.
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\(fn FUNC)" nil (quote macro))
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(autoload 'destructuring-bind "cl-macs" "\
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Not documented
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\(fn ARGS EXPR &rest BODY)" nil (quote macro))
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(autoload 'eval-when "cl-macs" "\
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Control when BODY is evaluated.
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If `compile' is in WHEN, BODY is evaluated when compiled at top-level.
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If `load' is in WHEN, BODY is evaluated when loaded after top-level compile.
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If `eval' is in WHEN, BODY is evaluated when interpreted or at non-top-level.
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\(fn (WHEN...) BODY...)" nil (quote macro))
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(autoload 'load-time-value "cl-macs" "\
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Like `progn', but evaluates the body at load time.
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The result of the body appears to the compiler as a quoted constant.
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\(fn FORM &optional READ-ONLY)" nil (quote macro))
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(autoload 'case "cl-macs" "\
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Eval EXPR and choose among clauses on that value.
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Each clause looks like (KEYLIST BODY...). EXPR is evaluated and compared
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against each key in each KEYLIST; the corresponding BODY is evaluated.
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If no clause succeeds, case returns nil. A single atom may be used in
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place of a KEYLIST of one atom. A KEYLIST of t or `otherwise' is
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allowed only in the final clause, and matches if no other keys match.
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Key values are compared by `eql'.
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\(fn EXPR (KEYLIST BODY...)...)" nil (quote macro))
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(autoload 'ecase "cl-macs" "\
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Like `case', but error if no case fits.
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`otherwise'-clauses are not allowed.
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\(fn EXPR (KEYLIST BODY...)...)" nil (quote macro))
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(autoload 'typecase "cl-macs" "\
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Evals EXPR, chooses among clauses on that value.
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Each clause looks like (TYPE BODY...). EXPR is evaluated and, if it
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satisfies TYPE, the corresponding BODY is evaluated. If no clause succeeds,
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typecase returns nil. A TYPE of t or `otherwise' is allowed only in the
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final clause, and matches if no other keys match.
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\(fn EXPR (TYPE BODY...)...)" nil (quote macro))
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(autoload 'etypecase "cl-macs" "\
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Like `typecase', but error if no case fits.
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`otherwise'-clauses are not allowed.
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\(fn EXPR (TYPE BODY...)...)" nil (quote macro))
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(autoload 'block "cl-macs" "\
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Define a lexically-scoped block named NAME.
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NAME may be any symbol. Code inside the BODY forms can call `return-from'
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to jump prematurely out of the block. This differs from `catch' and `throw'
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in two respects: First, the NAME is an unevaluated symbol rather than a
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quoted symbol or other form; and second, NAME is lexically rather than
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dynamically scoped: Only references to it within BODY will work. These
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references may appear inside macro expansions, but not inside functions
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called from BODY.
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\(fn NAME &rest BODY)" nil (quote macro))
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(autoload 'return "cl-macs" "\
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Return from the block named nil.
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This is equivalent to `(return-from nil RESULT)'.
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\(fn &optional RESULT)" nil (quote macro))
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(autoload 'return-from "cl-macs" "\
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Return from the block named NAME.
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This jump out to the innermost enclosing `(block NAME ...)' form,
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returning RESULT from that form (or nil if RESULT is omitted).
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This is compatible with Common Lisp, but note that `defun' and
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`defmacro' do not create implicit blocks as they do in Common Lisp.
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\(fn NAME &optional RESULT)" nil (quote macro))
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(autoload 'loop "cl-macs" "\
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The Common Lisp `loop' macro.
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Valid clauses are:
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for VAR from/upfrom/downfrom NUM to/upto/downto/above/below NUM by NUM,
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for VAR in LIST by FUNC, for VAR on LIST by FUNC, for VAR = INIT then EXPR,
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for VAR across ARRAY, repeat NUM, with VAR = INIT, while COND, until COND,
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always COND, never COND, thereis COND, collect EXPR into VAR,
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append EXPR into VAR, nconc EXPR into VAR, sum EXPR into VAR,
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count EXPR into VAR, maximize EXPR into VAR, minimize EXPR into VAR,
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if COND CLAUSE [and CLAUSE]... else CLAUSE [and CLAUSE...],
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unless COND CLAUSE [and CLAUSE]... else CLAUSE [and CLAUSE...],
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do EXPRS..., initially EXPRS..., finally EXPRS..., return EXPR,
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finally return EXPR, named NAME.
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\(fn CLAUSE...)" nil (quote macro))
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(autoload 'do "cl-macs" "\
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The Common Lisp `do' loop.
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\(fn ((VAR INIT [STEP])...) (END-TEST [RESULT...]) BODY...)" nil (quote macro))
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(autoload 'do* "cl-macs" "\
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The Common Lisp `do*' loop.
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\(fn ((VAR INIT [STEP])...) (END-TEST [RESULT...]) BODY...)" nil (quote macro))
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||
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||
(autoload 'dolist "cl-macs" "\
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Loop over a list.
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Evaluate BODY with VAR bound to each `car' from LIST, in turn.
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Then evaluate RESULT to get return value, default nil.
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||
\(fn (VAR LIST [RESULT]) BODY...)" nil (quote macro))
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||
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||
(autoload 'dotimes "cl-macs" "\
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||
Loop a certain number of times.
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Evaluate BODY with VAR bound to successive integers from 0, inclusive,
|
||
to COUNT, exclusive. Then evaluate RESULT to get return value, default
|
||
nil.
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||
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||
\(fn (VAR COUNT [RESULT]) BODY...)" nil (quote macro))
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||
(autoload 'do-symbols "cl-macs" "\
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Loop over all symbols.
|
||
Evaluate BODY with VAR bound to each interned symbol, or to each symbol
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||
from OBARRAY.
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||
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\(fn (VAR [OBARRAY [RESULT]]) BODY...)" nil (quote macro))
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||
|
||
(autoload 'do-all-symbols "cl-macs" "\
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||
Not documented
|
||
|
||
\(fn SPEC &rest BODY)" nil (quote macro))
|
||
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||
(autoload 'psetq "cl-macs" "\
|
||
Set SYMs to the values VALs in parallel.
|
||
This is like `setq', except that all VAL forms are evaluated (in order)
|
||
before assigning any symbols SYM to the corresponding values.
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||
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||
\(fn SYM VAL SYM VAL ...)" nil (quote macro))
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||
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||
(autoload 'progv "cl-macs" "\
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Bind SYMBOLS to VALUES dynamically in BODY.
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The forms SYMBOLS and VALUES are evaluated, and must evaluate to lists.
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||
Each symbol in the first list is bound to the corresponding value in the
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second list (or made unbound if VALUES is shorter than SYMBOLS); then the
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||
BODY forms are executed and their result is returned. This is much like
|
||
a `let' form, except that the list of symbols can be computed at run-time.
|
||
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||
\(fn SYMBOLS VALUES &rest BODY)" nil (quote macro))
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||
|
||
(autoload 'flet "cl-macs" "\
|
||
Make temporary function definitions.
|
||
This is an analogue of `let' that operates on the function cell of FUNC
|
||
rather than its value cell. The FORMs are evaluated with the specified
|
||
function definitions in place, then the definitions are undone (the FUNCs
|
||
go back to their previous definitions, or lack thereof).
|
||
|
||
\(fn ((FUNC ARGLIST BODY...) ...) FORM...)" nil (quote macro))
|
||
|
||
(autoload 'labels "cl-macs" "\
|
||
Make temporary function bindings.
|
||
This is like `flet', except the bindings are lexical instead of dynamic.
|
||
Unlike `flet', this macro is fully compliant with the Common Lisp standard.
|
||
|
||
\(fn ((FUNC ARGLIST BODY...) ...) FORM...)" nil (quote macro))
|
||
|
||
(autoload 'macrolet "cl-macs" "\
|
||
Make temporary macro definitions.
|
||
This is like `flet', but for macros instead of functions.
|
||
|
||
\(fn ((NAME ARGLIST BODY...) ...) FORM...)" nil (quote macro))
|
||
|
||
(autoload 'symbol-macrolet "cl-macs" "\
|
||
Make symbol macro definitions.
|
||
Within the body FORMs, references to the variable NAME will be replaced
|
||
by EXPANSION, and (setq NAME ...) will act like (setf EXPANSION ...).
|
||
|
||
\(fn ((NAME EXPANSION) ...) FORM...)" nil (quote macro))
|
||
|
||
(autoload 'lexical-let "cl-macs" "\
|
||
Like `let', but lexically scoped.
|
||
The main visible difference is that lambdas inside BODY will create
|
||
lexical closures as in Common Lisp.
|
||
|
||
\(fn VARLIST BODY)" nil (quote macro))
|
||
|
||
(autoload 'lexical-let* "cl-macs" "\
|
||
Like `let*', but lexically scoped.
|
||
The main visible difference is that lambdas inside BODY will create
|
||
lexical closures as in Common Lisp.
|
||
|
||
\(fn VARLIST BODY)" nil (quote macro))
|
||
|
||
(autoload 'multiple-value-bind "cl-macs" "\
|
||
Collect multiple return values.
|
||
FORM must return a list; the BODY is then executed with the first N elements
|
||
of this list bound (`let'-style) to each of the symbols SYM in turn. This
|
||
is analogous to the Common Lisp `multiple-value-bind' macro, using lists to
|
||
simulate true multiple return values. For compatibility, (values A B C) is
|
||
a synonym for (list A B C).
|
||
|
||
\(fn (SYM...) FORM BODY)" nil (quote macro))
|
||
|
||
(autoload 'multiple-value-setq "cl-macs" "\
|
||
Collect multiple return values.
|
||
FORM must return a list; the first N elements of this list are stored in
|
||
each of the symbols SYM in turn. This is analogous to the Common Lisp
|
||
`multiple-value-setq' macro, using lists to simulate true multiple return
|
||
values. For compatibility, (values A B C) is a synonym for (list A B C).
|
||
|
||
\(fn (SYM...) FORM)" nil (quote macro))
|
||
|
||
(autoload 'locally "cl-macs" "\
|
||
Not documented
|
||
|
||
\(fn &rest BODY)" nil (quote macro))
|
||
|
||
(autoload 'the "cl-macs" "\
|
||
Not documented
|
||
|
||
\(fn TYPE FORM)" nil (quote macro))
|
||
|
||
(autoload 'declare "cl-macs" "\
|
||
Not documented
|
||
|
||
\(fn &rest SPECS)" nil (quote macro))
|
||
|
||
(autoload 'define-setf-method "cl-macs" "\
|
||
Define a `setf' method.
|
||
This method shows how to handle `setf's to places of the form (NAME ARGS...).
|
||
The argument forms ARGS are bound according to ARGLIST, as if NAME were
|
||
going to be expanded as a macro, then the BODY forms are executed and must
|
||
return a list of five elements: a temporary-variables list, a value-forms
|
||
list, a store-variables list (of length one), a store-form, and an access-
|
||
form. See `defsetf' for a simpler way to define most setf-methods.
|
||
|
||
\(fn NAME ARGLIST BODY...)" nil (quote macro))
|
||
|
||
(autoload 'defsetf "cl-macs" "\
|
||
Define a `setf' method.
|
||
This macro is an easy-to-use substitute for `define-setf-method' that works
|
||
well for simple place forms. In the simple `defsetf' form, `setf's of
|
||
the form (setf (NAME ARGS...) VAL) are transformed to function or macro
|
||
calls of the form (FUNC ARGS... VAL). Example:
|
||
|
||
(defsetf aref aset)
|
||
|
||
Alternate form: (defsetf NAME ARGLIST (STORE) BODY...).
|
||
Here, the above `setf' call is expanded by binding the argument forms ARGS
|
||
according to ARGLIST, binding the value form VAL to STORE, then executing
|
||
BODY, which must return a Lisp form that does the necessary `setf' operation.
|
||
Actually, ARGLIST and STORE may be bound to temporary variables which are
|
||
introduced automatically to preserve proper execution order of the arguments.
|
||
Example:
|
||
|
||
(defsetf nth (n x) (v) (list 'setcar (list 'nthcdr n x) v))
|
||
|
||
\(fn NAME [FUNC | ARGLIST (STORE) BODY...])" nil (quote macro))
|
||
|
||
(autoload 'get-setf-method "cl-macs" "\
|
||
Return a list of five values describing the setf-method for PLACE.
|
||
PLACE may be any Lisp form which can appear as the PLACE argument to
|
||
a macro like `setf' or `incf'.
|
||
|
||
\(fn PLACE &optional ENV)" nil nil)
|
||
|
||
(autoload 'setf "cl-macs" "\
|
||
Set each PLACE to the value of its VAL.
|
||
This is a generalized version of `setq'; the PLACEs may be symbolic
|
||
references such as (car x) or (aref x i), as well as plain symbols.
|
||
For example, (setf (cadar x) y) is equivalent to (setcar (cdar x) y).
|
||
The return value is the last VAL in the list.
|
||
|
||
\(fn PLACE VAL PLACE VAL ...)" nil (quote macro))
|
||
|
||
(autoload 'psetf "cl-macs" "\
|
||
Set PLACEs to the values VALs in parallel.
|
||
This is like `setf', except that all VAL forms are evaluated (in order)
|
||
before assigning any PLACEs to the corresponding values.
|
||
|
||
\(fn PLACE VAL PLACE VAL ...)" nil (quote macro))
|
||
|
||
(autoload 'cl-do-pop "cl-macs" "\
|
||
Not documented
|
||
|
||
\(fn PLACE)" nil nil)
|
||
|
||
(autoload 'remf "cl-macs" "\
|
||
Remove TAG from property list PLACE.
|
||
PLACE may be a symbol, or any generalized variable allowed by `setf'.
|
||
The form returns true if TAG was found and removed, nil otherwise.
|
||
|
||
\(fn PLACE TAG)" nil (quote macro))
|
||
|
||
(autoload 'shiftf "cl-macs" "\
|
||
Shift left among PLACEs.
|
||
Example: (shiftf A B C) sets A to B, B to C, and returns the old A.
|
||
Each PLACE may be a symbol, or any generalized variable allowed by `setf'.
|
||
|
||
\(fn PLACE... VAL)" nil (quote macro))
|
||
|
||
(autoload 'rotatef "cl-macs" "\
|
||
Rotate left among PLACEs.
|
||
Example: (rotatef A B C) sets A to B, B to C, and C to A. It returns nil.
|
||
Each PLACE may be a symbol, or any generalized variable allowed by `setf'.
|
||
|
||
\(fn PLACE...)" nil (quote macro))
|
||
|
||
(autoload 'letf "cl-macs" "\
|
||
Temporarily bind to PLACEs.
|
||
This is the analogue of `let', but with generalized variables (in the
|
||
sense of `setf') for the PLACEs. Each PLACE is set to the corresponding
|
||
VALUE, then the BODY forms are executed. On exit, either normally or
|
||
because of a `throw' or error, the PLACEs are set back to their original
|
||
values. Note that this macro is *not* available in Common Lisp.
|
||
As a special case, if `(PLACE)' is used instead of `(PLACE VALUE)',
|
||
the PLACE is not modified before executing BODY.
|
||
|
||
\(fn ((PLACE VALUE) ...) BODY...)" nil (quote macro))
|
||
|
||
(autoload 'letf* "cl-macs" "\
|
||
Temporarily bind to PLACEs.
|
||
This is the analogue of `let*', but with generalized variables (in the
|
||
sense of `setf') for the PLACEs. Each PLACE is set to the corresponding
|
||
VALUE, then the BODY forms are executed. On exit, either normally or
|
||
because of a `throw' or error, the PLACEs are set back to their original
|
||
values. Note that this macro is *not* available in Common Lisp.
|
||
As a special case, if `(PLACE)' is used instead of `(PLACE VALUE)',
|
||
the PLACE is not modified before executing BODY.
|
||
|
||
\(fn ((PLACE VALUE) ...) BODY...)" nil (quote macro))
|
||
|
||
(autoload 'callf "cl-macs" "\
|
||
Set PLACE to (FUNC PLACE ARGS...).
|
||
FUNC should be an unquoted function name. PLACE may be a symbol,
|
||
or any generalized variable allowed by `setf'.
|
||
|
||
\(fn FUNC PLACE ARGS...)" nil (quote macro))
|
||
|
||
(autoload 'callf2 "cl-macs" "\
|
||
Set PLACE to (FUNC ARG1 PLACE ARGS...).
|
||
Like `callf', but PLACE is the second argument of FUNC, not the first.
|
||
|
||
\(fn FUNC ARG1 PLACE ARGS...)" nil (quote macro))
|
||
|
||
(autoload 'define-modify-macro "cl-macs" "\
|
||
Define a `setf'-like modify macro.
|
||
If NAME is called, it combines its PLACE argument with the other arguments
|
||
from ARGLIST using FUNC: (define-modify-macro incf (&optional (n 1)) +)
|
||
|
||
\(fn NAME ARGLIST FUNC &optional DOC)" nil (quote macro))
|
||
|
||
(autoload 'defstruct "cl-macs" "\
|
||
Define a struct type.
|
||
This macro defines a new Lisp data type called NAME, which contains data
|
||
stored in SLOTs. This defines a `make-NAME' constructor, a `copy-NAME'
|
||
copier, a `NAME-p' predicate, and setf-able `NAME-SLOT' accessors.
|
||
|
||
\(fn (NAME OPTIONS...) (SLOT SLOT-OPTS...)...)" nil (quote macro))
|
||
|
||
(autoload 'cl-struct-setf-expander "cl-macs" "\
|
||
Not documented
|
||
|
||
\(fn X NAME ACCESSOR PRED-FORM POS)" nil nil)
|
||
|
||
(autoload 'typep "cl-macs" "\
|
||
Check that OBJECT is of type TYPE.
|
||
TYPE is a Common Lisp-style type specifier.
|
||
|
||
\(fn OBJECT TYPE)" nil nil)
|
||
|
||
(autoload 'check-type "cl-macs" "\
|
||
Verify that FORM is of type TYPE; signal an error if not.
|
||
STRING is an optional description of the desired type.
|
||
|
||
\(fn FORM TYPE &optional STRING)" nil (quote macro))
|
||
|
||
(autoload 'assert "cl-macs" "\
|
||
Verify that FORM returns non-nil; signal an error if not.
|
||
Second arg SHOW-ARGS means to include arguments of FORM in message.
|
||
Other args STRING and ARGS... are arguments to be passed to `error'.
|
||
They are not evaluated unless the assertion fails. If STRING is
|
||
omitted, a default message listing FORM itself is used.
|
||
|
||
\(fn FORM &optional SHOW-ARGS STRING &rest ARGS)" nil (quote macro))
|
||
|
||
(autoload 'define-compiler-macro "cl-macs" "\
|
||
Define a compiler-only macro.
|
||
This is like `defmacro', but macro expansion occurs only if the call to
|
||
FUNC is compiled (i.e., not interpreted). Compiler macros should be used
|
||
for optimizing the way calls to FUNC are compiled; the form returned by
|
||
BODY should do the same thing as a call to the normal function called
|
||
FUNC, though possibly more efficiently. Note that, like regular macros,
|
||
compiler macros are expanded repeatedly until no further expansions are
|
||
possible. Unlike regular macros, BODY can decide to \"punt\" and leave the
|
||
original function call alone by declaring an initial `&whole foo' parameter
|
||
and then returning foo.
|
||
|
||
\(fn FUNC ARGS &rest BODY)" nil (quote macro))
|
||
|
||
(autoload 'compiler-macroexpand "cl-macs" "\
|
||
Not documented
|
||
|
||
\(fn FORM)" nil nil)
|
||
|
||
;;;***
|
||
|
||
;;;### (autoloads (tree-equal nsublis sublis nsubst-if-not nsubst-if
|
||
;;;;;; nsubst subst-if-not subst-if subsetp nset-exclusive-or set-exclusive-or
|
||
;;;;;; nset-difference set-difference nintersection intersection
|
||
;;;;;; nunion union rassoc-if-not rassoc-if rassoc* assoc-if-not
|
||
;;;;;; assoc-if assoc* cl-adjoin member-if-not member-if member*
|
||
;;;;;; merge stable-sort sort* search mismatch count-if-not count-if
|
||
;;;;;; count position-if-not position-if position find-if-not find-if
|
||
;;;;;; find nsubstitute-if-not nsubstitute-if nsubstitute substitute-if-not
|
||
;;;;;; substitute-if substitute delete-duplicates remove-duplicates
|
||
;;;;;; delete-if-not delete-if delete* remove-if-not remove-if remove*
|
||
;;;;;; replace fill reduce) "cl-seq" "cl-seq.el" "b6529074e320e8a9f65b2461474d0c6a")
|
||
;;; Generated autoloads from cl-seq.el
|
||
|
||
(autoload 'reduce "cl-seq" "\
|
||
Reduce two-argument FUNCTION across SEQ.
|
||
|
||
Keywords supported: :start :end :from-end :initial-value :key
|
||
|
||
\(fn FUNCTION SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'fill "cl-seq" "\
|
||
Fill the elements of SEQ with ITEM.
|
||
|
||
Keywords supported: :start :end
|
||
|
||
\(fn SEQ ITEM [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'replace "cl-seq" "\
|
||
Replace the elements of SEQ1 with the elements of SEQ2.
|
||
SEQ1 is destructively modified, then returned.
|
||
|
||
Keywords supported: :start1 :end1 :start2 :end2
|
||
|
||
\(fn SEQ1 SEQ2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'remove* "cl-seq" "\
|
||
Remove all occurrences of ITEM in SEQ.
|
||
This is a non-destructive function; it makes a copy of SEQ if necessary
|
||
to avoid corrupting the original SEQ.
|
||
|
||
Keywords supported: :test :test-not :key :count :start :end :from-end
|
||
|
||
\(fn ITEM SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'remove-if "cl-seq" "\
|
||
Remove all items satisfying PREDICATE in SEQ.
|
||
This is a non-destructive function; it makes a copy of SEQ if necessary
|
||
to avoid corrupting the original SEQ.
|
||
|
||
Keywords supported: :key :count :start :end :from-end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'remove-if-not "cl-seq" "\
|
||
Remove all items not satisfying PREDICATE in SEQ.
|
||
This is a non-destructive function; it makes a copy of SEQ if necessary
|
||
to avoid corrupting the original SEQ.
|
||
|
||
Keywords supported: :key :count :start :end :from-end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'delete* "cl-seq" "\
|
||
Remove all occurrences of ITEM in SEQ.
|
||
This is a destructive function; it reuses the storage of SEQ whenever possible.
|
||
|
||
Keywords supported: :test :test-not :key :count :start :end :from-end
|
||
|
||
\(fn ITEM SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'delete-if "cl-seq" "\
|
||
Remove all items satisfying PREDICATE in SEQ.
|
||
This is a destructive function; it reuses the storage of SEQ whenever possible.
|
||
|
||
Keywords supported: :key :count :start :end :from-end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'delete-if-not "cl-seq" "\
|
||
Remove all items not satisfying PREDICATE in SEQ.
|
||
This is a destructive function; it reuses the storage of SEQ whenever possible.
|
||
|
||
Keywords supported: :key :count :start :end :from-end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'remove-duplicates "cl-seq" "\
|
||
Return a copy of SEQ with all duplicate elements removed.
|
||
|
||
Keywords supported: :test :test-not :key :start :end :from-end
|
||
|
||
\(fn SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'delete-duplicates "cl-seq" "\
|
||
Remove all duplicate elements from SEQ (destructively).
|
||
|
||
Keywords supported: :test :test-not :key :start :end :from-end
|
||
|
||
\(fn SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'substitute "cl-seq" "\
|
||
Substitute NEW for OLD in SEQ.
|
||
This is a non-destructive function; it makes a copy of SEQ if necessary
|
||
to avoid corrupting the original SEQ.
|
||
|
||
Keywords supported: :test :test-not :key :count :start :end :from-end
|
||
|
||
\(fn NEW OLD SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'substitute-if "cl-seq" "\
|
||
Substitute NEW for all items satisfying PREDICATE in SEQ.
|
||
This is a non-destructive function; it makes a copy of SEQ if necessary
|
||
to avoid corrupting the original SEQ.
|
||
|
||
Keywords supported: :key :count :start :end :from-end
|
||
|
||
\(fn NEW PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'substitute-if-not "cl-seq" "\
|
||
Substitute NEW for all items not satisfying PREDICATE in SEQ.
|
||
This is a non-destructive function; it makes a copy of SEQ if necessary
|
||
to avoid corrupting the original SEQ.
|
||
|
||
Keywords supported: :key :count :start :end :from-end
|
||
|
||
\(fn NEW PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nsubstitute "cl-seq" "\
|
||
Substitute NEW for OLD in SEQ.
|
||
This is a destructive function; it reuses the storage of SEQ whenever possible.
|
||
|
||
Keywords supported: :test :test-not :key :count :start :end :from-end
|
||
|
||
\(fn NEW OLD SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nsubstitute-if "cl-seq" "\
|
||
Substitute NEW for all items satisfying PREDICATE in SEQ.
|
||
This is a destructive function; it reuses the storage of SEQ whenever possible.
|
||
|
||
Keywords supported: :key :count :start :end :from-end
|
||
|
||
\(fn NEW PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nsubstitute-if-not "cl-seq" "\
|
||
Substitute NEW for all items not satisfying PREDICATE in SEQ.
|
||
This is a destructive function; it reuses the storage of SEQ whenever possible.
|
||
|
||
Keywords supported: :key :count :start :end :from-end
|
||
|
||
\(fn NEW PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'find "cl-seq" "\
|
||
Find the first occurrence of ITEM in SEQ.
|
||
Return the matching ITEM, or nil if not found.
|
||
|
||
Keywords supported: :test :test-not :key :start :end :from-end
|
||
|
||
\(fn ITEM SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'find-if "cl-seq" "\
|
||
Find the first item satisfying PREDICATE in SEQ.
|
||
Return the matching item, or nil if not found.
|
||
|
||
Keywords supported: :key :start :end :from-end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'find-if-not "cl-seq" "\
|
||
Find the first item not satisfying PREDICATE in SEQ.
|
||
Return the matching item, or nil if not found.
|
||
|
||
Keywords supported: :key :start :end :from-end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'position "cl-seq" "\
|
||
Find the first occurrence of ITEM in SEQ.
|
||
Return the index of the matching item, or nil if not found.
|
||
|
||
Keywords supported: :test :test-not :key :start :end :from-end
|
||
|
||
\(fn ITEM SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'position-if "cl-seq" "\
|
||
Find the first item satisfying PREDICATE in SEQ.
|
||
Return the index of the matching item, or nil if not found.
|
||
|
||
Keywords supported: :key :start :end :from-end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'position-if-not "cl-seq" "\
|
||
Find the first item not satisfying PREDICATE in SEQ.
|
||
Return the index of the matching item, or nil if not found.
|
||
|
||
Keywords supported: :key :start :end :from-end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'count "cl-seq" "\
|
||
Count the number of occurrences of ITEM in SEQ.
|
||
|
||
Keywords supported: :test :test-not :key :start :end
|
||
|
||
\(fn ITEM SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'count-if "cl-seq" "\
|
||
Count the number of items satisfying PREDICATE in SEQ.
|
||
|
||
Keywords supported: :key :start :end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'count-if-not "cl-seq" "\
|
||
Count the number of items not satisfying PREDICATE in SEQ.
|
||
|
||
Keywords supported: :key :start :end
|
||
|
||
\(fn PREDICATE SEQ [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'mismatch "cl-seq" "\
|
||
Compare SEQ1 with SEQ2, return index of first mismatching element.
|
||
Return nil if the sequences match. If one sequence is a prefix of the
|
||
other, the return value indicates the end of the shorter sequence.
|
||
|
||
Keywords supported: :test :test-not :key :start1 :end1 :start2 :end2 :from-end
|
||
|
||
\(fn SEQ1 SEQ2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'search "cl-seq" "\
|
||
Search for SEQ1 as a subsequence of SEQ2.
|
||
Return the index of the leftmost element of the first match found;
|
||
return nil if there are no matches.
|
||
|
||
Keywords supported: :test :test-not :key :start1 :end1 :start2 :end2 :from-end
|
||
|
||
\(fn SEQ1 SEQ2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'sort* "cl-seq" "\
|
||
Sort the argument SEQ according to PREDICATE.
|
||
This is a destructive function; it reuses the storage of SEQ if possible.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn SEQ PREDICATE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'stable-sort "cl-seq" "\
|
||
Sort the argument SEQ stably according to PREDICATE.
|
||
This is a destructive function; it reuses the storage of SEQ if possible.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn SEQ PREDICATE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'merge "cl-seq" "\
|
||
Destructively merge the two sequences to produce a new sequence.
|
||
TYPE is the sequence type to return, SEQ1 and SEQ2 are the two argument
|
||
sequences, and PREDICATE is a `less-than' predicate on the elements.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn TYPE SEQ1 SEQ2 PREDICATE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'member* "cl-seq" "\
|
||
Find the first occurrence of ITEM in LIST.
|
||
Return the sublist of LIST whose car is ITEM.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn ITEM LIST [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'member-if "cl-seq" "\
|
||
Find the first item satisfying PREDICATE in LIST.
|
||
Return the sublist of LIST whose car matches.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn PREDICATE LIST [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'member-if-not "cl-seq" "\
|
||
Find the first item not satisfying PREDICATE in LIST.
|
||
Return the sublist of LIST whose car matches.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn PREDICATE LIST [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'cl-adjoin "cl-seq" "\
|
||
Not documented
|
||
|
||
\(fn CL-ITEM CL-LIST &rest CL-KEYS)" nil nil)
|
||
|
||
(autoload 'assoc* "cl-seq" "\
|
||
Find the first item whose car matches ITEM in LIST.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn ITEM LIST [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'assoc-if "cl-seq" "\
|
||
Find the first item whose car satisfies PREDICATE in LIST.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn PREDICATE LIST [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'assoc-if-not "cl-seq" "\
|
||
Find the first item whose car does not satisfy PREDICATE in LIST.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn PREDICATE LIST [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'rassoc* "cl-seq" "\
|
||
Find the first item whose cdr matches ITEM in LIST.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn ITEM LIST [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'rassoc-if "cl-seq" "\
|
||
Find the first item whose cdr satisfies PREDICATE in LIST.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn PREDICATE LIST [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'rassoc-if-not "cl-seq" "\
|
||
Find the first item whose cdr does not satisfy PREDICATE in LIST.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn PREDICATE LIST [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'union "cl-seq" "\
|
||
Combine LIST1 and LIST2 using a set-union operation.
|
||
The result list contains all items that appear in either LIST1 or LIST2.
|
||
This is a non-destructive function; it makes a copy of the data if necessary
|
||
to avoid corrupting the original LIST1 and LIST2.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn LIST1 LIST2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nunion "cl-seq" "\
|
||
Combine LIST1 and LIST2 using a set-union operation.
|
||
The result list contains all items that appear in either LIST1 or LIST2.
|
||
This is a destructive function; it reuses the storage of LIST1 and LIST2
|
||
whenever possible.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn LIST1 LIST2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'intersection "cl-seq" "\
|
||
Combine LIST1 and LIST2 using a set-intersection operation.
|
||
The result list contains all items that appear in both LIST1 and LIST2.
|
||
This is a non-destructive function; it makes a copy of the data if necessary
|
||
to avoid corrupting the original LIST1 and LIST2.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn LIST1 LIST2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nintersection "cl-seq" "\
|
||
Combine LIST1 and LIST2 using a set-intersection operation.
|
||
The result list contains all items that appear in both LIST1 and LIST2.
|
||
This is a destructive function; it reuses the storage of LIST1 and LIST2
|
||
whenever possible.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn LIST1 LIST2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'set-difference "cl-seq" "\
|
||
Combine LIST1 and LIST2 using a set-difference operation.
|
||
The result list contains all items that appear in LIST1 but not LIST2.
|
||
This is a non-destructive function; it makes a copy of the data if necessary
|
||
to avoid corrupting the original LIST1 and LIST2.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn LIST1 LIST2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nset-difference "cl-seq" "\
|
||
Combine LIST1 and LIST2 using a set-difference operation.
|
||
The result list contains all items that appear in LIST1 but not LIST2.
|
||
This is a destructive function; it reuses the storage of LIST1 and LIST2
|
||
whenever possible.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn LIST1 LIST2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'set-exclusive-or "cl-seq" "\
|
||
Combine LIST1 and LIST2 using a set-exclusive-or operation.
|
||
The result list contains all items that appear in exactly one of LIST1, LIST2.
|
||
This is a non-destructive function; it makes a copy of the data if necessary
|
||
to avoid corrupting the original LIST1 and LIST2.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn LIST1 LIST2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nset-exclusive-or "cl-seq" "\
|
||
Combine LIST1 and LIST2 using a set-exclusive-or operation.
|
||
The result list contains all items that appear in exactly one of LIST1, LIST2.
|
||
This is a destructive function; it reuses the storage of LIST1 and LIST2
|
||
whenever possible.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn LIST1 LIST2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'subsetp "cl-seq" "\
|
||
Return true if LIST1 is a subset of LIST2.
|
||
I.e., if every element of LIST1 also appears in LIST2.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn LIST1 LIST2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'subst-if "cl-seq" "\
|
||
Substitute NEW for elements matching PREDICATE in TREE (non-destructively).
|
||
Return a copy of TREE with all matching elements replaced by NEW.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn NEW PREDICATE TREE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'subst-if-not "cl-seq" "\
|
||
Substitute NEW for elts not matching PREDICATE in TREE (non-destructively).
|
||
Return a copy of TREE with all non-matching elements replaced by NEW.
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn NEW PREDICATE TREE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nsubst "cl-seq" "\
|
||
Substitute NEW for OLD everywhere in TREE (destructively).
|
||
Any element of TREE which is `eql' to OLD is changed to NEW (via a call
|
||
to `setcar').
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn NEW OLD TREE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nsubst-if "cl-seq" "\
|
||
Substitute NEW for elements matching PREDICATE in TREE (destructively).
|
||
Any element of TREE which matches is changed to NEW (via a call to `setcar').
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn NEW PREDICATE TREE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nsubst-if-not "cl-seq" "\
|
||
Substitute NEW for elements not matching PREDICATE in TREE (destructively).
|
||
Any element of TREE which matches is changed to NEW (via a call to `setcar').
|
||
|
||
Keywords supported: :key
|
||
|
||
\(fn NEW PREDICATE TREE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'sublis "cl-seq" "\
|
||
Perform substitutions indicated by ALIST in TREE (non-destructively).
|
||
Return a copy of TREE with all matching elements replaced.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn ALIST TREE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'nsublis "cl-seq" "\
|
||
Perform substitutions indicated by ALIST in TREE (destructively).
|
||
Any matching element of TREE is changed via a call to `setcar'.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn ALIST TREE [KEYWORD VALUE]...)" nil nil)
|
||
|
||
(autoload 'tree-equal "cl-seq" "\
|
||
Return t if trees TREE1 and TREE2 have `eql' leaves.
|
||
Atoms are compared by `eql'; cons cells are compared recursively.
|
||
|
||
Keywords supported: :test :test-not :key
|
||
|
||
\(fn TREE1 TREE2 [KEYWORD VALUE]...)" nil nil)
|
||
|
||
;;;***
|
||
|
||
;; Local Variables:
|
||
;; version-control: never
|
||
;; no-byte-compile: t
|
||
;; no-update-autoloads: t
|
||
;; End:
|
||
|
||
;; arch-tag: 08cc5aab-e992-47f6-992e-12a7428c1a0e
|
||
;;; cl-loaddefs.el ends here
|