(in-package :losh.iterate)
(defmacro expand-iterate-sequence-keywords ()
'(list
:from iterate::from
:upfrom iterate::upfrom
:downfrom iterate::downfrom
:to iterate::to
:downto iterate::downto
:above iterate::above
:below iterate::below
:by iterate::by
:with-index iterate::with-index))
(defmacro-driver (FOR var IN-WHATEVER seq)
"Iterate over items in the given sequence.
Unlike iterate's own `in-sequence` this won't use the horrifyingly inefficient
`elt`/`length` functions on a list.
"
(let ((kwd (if generate 'generate 'for)))
(with-gensyms (is-list source i len)
`(progn
(with ,source = ,seq)
(with ,is-list = (typep ,source 'list))
(with ,len = (if ,is-list -1 (length ,source)))
(for ,i :from 0)
(,kwd ,var next (if ,is-list
(if ,source
(pop ,source)
(terminate))
(if (< ,i ,len)
(elt ,source ,i)
(terminate))))))))
(defmacro-driver (FOR var MODULO divisor &sequence)
"Iterate numerically with `var` bound modulo `divisor`.
This driver iterates just like the vanilla `for`, but each resulting value
will be modulo'ed by `divisor` before being bound to `var`.
Note that the modulo doesn't affect the *iteration*, it just affects the
variable you *see*. It is as if you had written two clauses:
(for temp :from foo :to bar)
(for var = (mod temp divisor))
Example:
(iterate (for i :from 0 :to 20 :by 3) (collect i))
(0 3 6 9 12 15 18)
(iterate (for i :modulo 10 :from 0 :to 20 :by 3) (collect i))
(0 3 6 9 2 5 8)
"
(let ((kwd (if generate 'generate 'for)))
(with-gensyms (i d)
`(progn
(with ,d = ,divisor)
(generate ,i ,@(expand-iterate-sequence-keywords))
(,kwd ,var next (mod (next ,i) ,d))))))
(defmacro-driver (FOR var PAIRS-OF-LIST list)
"Iterate over the all pairs of `list` (including `(last . first)`).
Examples:
(iterate (for p :pairs-of-list (list 1 2 3 4))
(collect p))
=>
((1 . 2) (2 . 3) (3 . 4) (4 . 1))
"
(let ((kwd (if generate 'generate 'for)))
(with-gensyms (current l)
`(progn
(with ,l = ,list)
(with ,current = ,l)
(,kwd ,var next
(cond
((null ,current)
(terminate))
((null (cdr ,current))
(prog1
(cons (first ,current) (car ,l))
(setf ,current nil)))
(t (prog1
(cons (first ,current) (second ,current))
(setf ,current (cdr ,current))))))))))
(defmacro-clause (AVERAGING expr &optional INTO var)
"Maintain a running average of `expr` in `var`.
If `var` is omitted the final average will be returned instead.
Examples:
(iterate (for x :in '(0 10 0 10))
(averaging x))
=>
5
(iterate (for x :in '(1.0 1 2 3 4))
(averaging (/ x 10) :into avg)
(collect avg))
=>
(0.1 0.1 0.13333334 0.17500001 0.22)
"
(with-gensyms (count total)
(let ((average (or var iterate::*result-var*)))
`(progn
(for ,count :from 1)
(sum ,expr :into ,total)
(for ,average = (/ ,total ,count))))))
(defmacro-clause (TIMING time-type &optional
SINCE-START-INTO since-var
PER-ITERATION-INTO per-var
SECONDS seconds?)
"Time [real/run]-time into variables.
`time-type` should be either the symbol `run-time` or `real-time`, depending
on which kind of time you want to track. Times are reported in internal time
units, unless `seconds?` is given, in which case they will be converted to
a `single-float` by dividing by `internal-time-units-per-second`.
If `since-var` is given, on each iteration it will be bound to the amount of
time that has passed since the beginning of the loop.
If `per-var` is given, on each iteration it will be bound to the amount of
time that has passed since the last time it was set. On the first iteration
it will be bound to the amount of time since the loop started.
If neither var is given, it is as if `since-var` were given and returned as
the value of the `iterate` statement.
`seconds?` is checked at compile time, not runtime.
Note that the position of this clause in the `iterate` statement matters.
Also, the code movement of `iterate` can change things around. Overall the
results should be pretty intuitive, but if you need absolute accuracy you
should use something else.
Examples:
; sleep BEFORE the timing clause
(iterate (repeat 3)
(sleep 1.0)
(timing real-time :since-start-into s :per-iteration-into p)
(collect (list (/ s internal-time-units-per-second 1.0)
(/ p internal-time-units-per-second 1.0))))
=>
((1.0003 1.0003)
(2.0050 1.0047)
(3.0081 1.0030))
; sleep AFTER the timing clause
(iterate (repeat 3)
(timing real-time :since-start-into s :per-iteration-into p :seconds t)
(sleep 1.0)
(collect (list s p)))
=>
((0.0 0.0)
(1.001 1.001)
(2.005 1.004))
"
(let ((timing-function (ccase time-type
((:real-time real-time) 'get-internal-real-time)
((:run-time run-time) 'get-internal-run-time)))
(since-var (or since-var (when (null per-var)
iterate::*result-var*))))
(flet ((convert (val)
(if seconds?
`(/ ,val internal-time-units-per-second 1.0f0)
val)))
(with-gensyms (start-time current-time previous-time)
`(progn
(with ,start-time = (,timing-function))
(for ,current-time = (,timing-function))
,@(when since-var
`((for ,since-var = ,(convert `(- ,current-time ,start-time)))))
,@(when per-var
`((for ,previous-time :previous ,current-time :initially ,start-time)
(for ,per-var = ,(convert `(- ,current-time ,previous-time))))))))))
(defmacro-driver (FOR var IN-LISTS lists)
"Iterate each element of each list in `lists` in turn.
Examples:
(iterate (with things = (list (list 1 2 3) nil (list :a :b :c)))
(for val :in-lists things)
(collect val))
=>
(1 2 3 :a :b :c)
"
(let ((kwd (if generate 'generate 'for)))
(with-gensyms (list)
`(progn
(generate ,list :in (remove nil ,lists))
(,kwd ,var next (progn (when (null ,list)
(next ,list))
(pop ,list)))))))
(defun seq-done-p (seq len idx)
(if idx
(= idx len)
(null seq)))
(defmacro-driver (FOR var IN-SEQUENCES seqs)
"Iterate each element of each sequence in `seqs` in turn.
Examples:
(iterate (with things = (list (list 1 2 3) nil #(:a :b :c) #()))
(for val :in-sequences things)
(collect val))
=>
(1 2 3 :a :b :c)
"
(let ((kwd (if generate 'generate 'for)))
(with-gensyms (seq len idx)
`(progn
(with ,len = nil)
(with ,idx = nil)
(generate ,seq :in-whatever (remove-if #'alexandria:emptyp ,seqs))
(,kwd ,var next
(progn
(when (seq-done-p ,seq ,len ,idx)
(etypecase (next ,seq)
(cons (setf ,len nil ,idx nil))
(sequence (setf ,len (length ,seq)
,idx 0))))
(if ,idx
(prog1 (elt ,seq ,idx)
(incf ,idx))
(pop ,seq))))))))
(defmacro-driver (FOR var AROUND seq)
"Iterate cyclically around items in the given sequence.
The results are undefined if the sequence is empty.
"
(let ((kwd (if generate 'generate 'for)))
(with-gensyms (is-list original source i len)
`(progn
(with ,original = ,seq)
(with ,source = ,original)
(with ,is-list = (typep ,source 'list))
(with ,len = (if ,is-list -1 (length ,source)))
(with ,i = -1)
(,kwd ,var :next (if ,is-list
(progn (unless ,source (setf ,source ,original))
(pop ,source))
(progn (incf ,i)
(when (= ,i ,len)
(setf ,i 0))
(elt ,source ,i))))))))
(defclause-sequence ACROSS-FLAT-ARRAY INDEX-OF-FLAT-ARRAY
:access-fn 'row-major-aref
:size-fn 'array-total-size
:sequence-type 'array
:element-type t)
(defun calculate-array-floors (array)
(iterate (for (nil . later) :on (array-dimensions array))
(collect (apply #'* later) :result-type vector)))
(defmacro-driver (FOR binding-form IN-ARRAY array)
"Iterate over `array`, binding the things in `binding-form` each time.
This driver iterates over every element in `array`. Multidimensional arrays
are supported -- the array will be stepped in row-major order.
`binding-form` should be a list of `(value ...index-vars...)`. An index
variable can be `nil` to ignore it. Missing index variables are ignored. If
no index variables are needed, `binding-form` can simply be the value symbol.
`generate` is supported. Call `next` on the value symbol to use it.
Examples:
(iterate (for (height x y) :in-array some-2d-heightmap-array)
(draw-terrain x y height))
(iterate (for (val nil nil z) :in-array some-3d-array)
(collect (cons z val)))
(iterate (for val :in-array any-array)
(print val))
"
(destructuring-bind (var &rest index-vars
&aux (kwd (if generate 'generate 'for)))
(ensure-list binding-form)
(with-gensyms (i arr dims floors)
`(progn
(with ,arr = ,array)
,@(when (some #'identity index-vars)
`((with ,dims = (coerce (array-dimensions ,arr) 'vector))
(with ,floors = (calculate-array-floors ,arr))))
(generate ,i :from 0 :below (array-total-size ,arr))
,@(iterate (for index :in index-vars)
(for dim-number :from 0)
(when index
(collect `(generate ,index :next
(mod (floor ,i (svref ,floors ,dim-number))
(svref ,dims ,dim-number))))))
(,kwd ,var :next
(progn
(next ,i)
,@(iterate (for index :in index-vars)
(when index (collect `(next ,index))))
(row-major-aref ,arr ,i)))))))
(defun parse-sequence-arguments
(from upfrom downfrom to downto above below by)
(let* ((start (or from upfrom downfrom))
(end (or to downto above below))
(increment (or by 1))
(down (or downfrom downto above))
(exclusive (or below above))
(done-p (if exclusive
(if down '<= '>=)
(if down '< '>)))
(op (if down '- '+)))
(values start end increment op done-p)))
(defmacro-driver (FOR var CYCLING on-cycle &sequence)
"Iterate numerically as with `for`, but cycle around once finished.
`on-cycle` should be a form to execute every time the number cycles back to
the beginning. The value of `var` during this form's execution is undefined.
`generate` is supported.
Results are undefined if the cycle doesn't contain at least one number.
Examples:
(iterate (repeat 10)
(for x :cycling t :from 0 :to 3)
(collect x))
=>
(0 1 2 3 0 1 2 3 0 1)
(iterate (repeat 5)
(for x :cycling (print 'beep) :from 1 :downto 0 :by 0.5)
(print x))
=>
1.0
0.5
0.0
BEEP
1.0
0.5
"
(declare (ignore iterate::with-index))
(multiple-value-bind (start end increment op done-p)
(parse-sequence-arguments iterate::from iterate::upfrom iterate::downfrom
iterate::to iterate::downto
iterate::above iterate::below
iterate::by)
(let ((kwd (if generate 'generate 'for)))
(with-gensyms (%counter %start %end %increment)
`(progn
(with ,%end = ,end)
(with ,%increment = ,increment)
(with ,%counter)
;; ugly hack to get numeric contagion right for the first val
;; (borrowed from Alexandria)
(with ,%start = (- (+ ,start ,%increment) ,%increment))
(,kwd ,var next
(progn
(setf ,%counter
(if-first-time ,%start (,op ,%counter ,%increment)))
(if (,done-p ,%counter ,%end)
(prog1
(setf ,%counter ,%start)
,on-cycle)
,%counter))))))))
(defmacro-clause (GENERATE-NESTED forms CONTROL-VAR control-var)
(iterate
(for (var . args) :in forms)
(for prev :previous var :initially nil)
;; we basically turn
;; (for-nested ((x :from 0 :to n)
;; (y :from 0 :to m)
;; (z :from 0 :to q)))
;; into
;; (generate x :from 0 :to n)
;; (generate y :cycling (next x) :from 0 :to m)
;; (generate z :cycling (next y) :from 0 :to q)
;; (generate control-var
;; :next (if-first-time
;; (progn (next x) (next y) (next z))
;; (next z)))
(collect var :into vars)
(collect `(generate ,var
,@(when prev `(:cycling (next ,prev)))
,@args)
:into cycling-forms)
(finally (return `(progn
,@cycling-forms
(declare (ignorable ,control-var))
(generate ,control-var :next
(if-first-time
(progn ,@(iterate (for v :in vars)
(collect `(next ,v))))
(next ,var))))))))
(defmacro-clause (FOR-NESTED forms)
"Iterate the given `forms` in a nested fashion.
`forms` should be a list of iteration forms. Each one should have the same
format as a standard `(for var ...)` numeric iteration clause, but WITHOUT
the `for`.
The forms will iterate numerically as if in a series of nested loops, with
later forms cycling around as many times as is necessary.
Examples:
(iterate (for-nested ((x :from 0 :to 3)
(y :from 0 :below 1 :by 0.4)))
(print (list x y)))
=>
(0 0)
(0 0.4)
(0 0.8)
(1 0)
(1 0.4)
(1 0.8)
(2 0)
(2 0.4)
(2 0.8)
(3 0)
(3 0.4)
(3 0.8)
"
(with-gensyms (control)
`(progn
(generate-nested ,forms :control-var ,control)
(next ,control))))
(defmacro-clause (FOR delta-vars WITHIN-RADIUS radius &optional
SKIP-ORIGIN should-skip-origin
ORIGIN origin)
"Iterate through a number of delta values within a given radius.
Imagine you have a 2D array and you want to find all the neighbors of a given
cell:
.........
...nnn...
...nXn...
...nnn...
.........
You'll need to iterate over the cross product of the array indices from
`(- target 1)` to `(+ target 1)`.
You may want to have a larger radius, and you may or may not want to include
the origin (delta `(0 0)`).
This clause handles calculating the deltas for you, without needless consing.
Examples:
(iterate (for (x) :within-radius 2)
(collect (list x)))
=>
((-2) (-1) (0) (1) (2))
(iterate (for (x y) :within-radius 1 :skip-origin t)
(collect (list x y)))
=>
((-1 -1)
(-1 0)
(-1 1)
( 0 -1)
( 0 1)
( 1 -1)
( 1 0)
( 1 1))
(iterate (for (x y z) :within-radius 3)
(collect (list x y z)))
=>
; ... a bigass list of deltas,
; the point it is works in arbitrary dimensions.
"
(let* ((delta-vars (ensure-list delta-vars))
(origin-vars (mapcar (lambda (dv) (gensym (mkstr 'origin- dv)))
delta-vars))
(origin-vals (if (null origin)
(mapcar (constantly 0) delta-vars)
origin)))
(with-gensyms (r control skip)
`(progn
(with ,r = ,radius)
,@(mapcar (lambda (ovar oval)
`(with ,ovar = ,oval))
origin-vars origin-vals)
(generate-nested ,(iterate (for var :in delta-vars)
(for orig :in origin-vars)
(collect `(,var :from (- ,orig ,r) :to (+ ,orig ,r))))
:control-var ,control)
(next ,control)
,@(unless (null should-skip-origin)
`((with ,skip = ,should-skip-origin)
(when (and ,skip
,@(iterate (for var :in (ensure-list delta-vars))
(collect `(zerop ,var))))
(next ,control))))))))
(defmacro-driver (FOR var EVERY-NTH n DO form)
"Iterate `var` numerically modulo `n` and run `form` every `n`th iteration.
The driver can be used to perform an action every N times through the loop.
`var` itself will be a counter that counts up from to to `n - 1`.
`generate` is supported.
Example:
(iterate (for i :from 1 :to 7)
(print `(iteration ,i))
(for tick :every-nth 3 :do (print 'beep))
(print `(tick ,tick)) (terpri))
; =>
(ITERATION 1)
(TICK 0)
(ITERATION 2)
(TICK 1)
(ITERATION 3)
BEEP
(TICK 2)
(ITERATION 4)
(TICK 0)
(ITERATION 5)
(TICK 1)
(ITERATION 6)
BEEP
(TICK 2)
(ITERATION 7)
(TICK 0)
"
(let ((kwd (if generate 'generate 'for)))
(with-gensyms (counter limit)
`(progn
(with ,limit = ,n)
(generate ,counter :modulo ,limit :from 0)
(,kwd ,var :next (prog1 (next ,counter)
(when (= ,counter (1- ,limit))
,form)))))))
(defmacro-clause (COLLECT-HASH key-and-value &optional
INTO var
TEST (test '#'eql))
"Collect keys and values into a hash table at `var`.
If `var` is omitted the hash table will be returned instead.
`key-and-value` should be a list of `(key-expr value-expr)`.
`test` specifies the test used for the hash table.
Example:
(iterate (for x :from 0)
(for y :in '(a b c))
(collect-hash ((1+ x) y)))
; => {1 a
; 2 b
; 3 c}
"
(destructuring-bind (key value) key-and-value
(let ((hash-table (or var iterate::*result-var*)))
`(progn
(with ,hash-table = (make-hash-table :test ,test))
(setf (gethash ,key ,hash-table) ,value)))))
(defmacro-clause (COLLECT-SET element &optional
INTO var
TEST (test '#'eql))
"Collect elements into a hash set at `var`.
If `var` is omitted the hash set will be returned instead.
`test` specifies the test used for the hash set.
Example:
(iterate (for y :in '(a b a))
(collect-set y))
; => {a b}
"
(let ((hash-set (or var iterate::*result-var*)))
`(progn
(with ,hash-set = (make-hash-set :test ,test))
(hset-insert! ,hash-set ,element))))
(defmacro-clause (COLLECT-FREQUENCIES expr &optional
INTO var
TEST (test '#'eql))
"Collect frequencies of `expr` values into a hash table at `var`.
If `var` is omitted the hash table will be returned instead.
`test` specifies the test used for the hash table.
Example:
(iterate (for x :in '(b a n a n a s))
(collect-frequencies x))
; => {b 1
; a 3
; n 2
; s 1}
"
(let ((hash-table (or var iterate::*result-var*)))
`(progn
(with ,hash-table = (make-hash-table :test ,test))
(incf (gethash ,expr ,hash-table 0)))))
(defmacro-clause (ORING expr &optional INTO var)
(let ((result (or var iterate::*result-var*)))
`(reducing ,expr :by #'or :into ,result :initial-value nil)))
(defmacro-clause (ANDING expr &optional INTO var)
(let ((result (or var iterate::*result-var*)))
`(reducing ,expr :by #'and :into ,result :initial-value t)))
(defun keywordize-clause (clause)
(iterate
(for (k v . nil) :on clause :by #'cddr)
(collect (alexandria:make-keyword k))
(collect v)))
(defun keywordize-some-of-clause (clause)
; please kill me
(append (list (first clause) (second clause))
(keywordize-clause (nthcdr 2 clause))))
(defun macroexpand-iterate (clause)
"Macroexpand the given iterate clause/driver.
Example:
(macroexpand-iterate '(averaging (+ x 10) :into avg))
=>
(PROGN
(FOR #:COUNT630 :FROM 1)
(SUM (+ X 10) :INTO #:TOTAL631)
(FOR AVG = (/ #:TOTAL631 #:COUNT630)))
"
;; Given a clause like (for foo in-whatever bar) we need to:
;;
;; 1. Look up the appropriate macro (confusingly named via gentemp). This
;; requires calling `iterate::get-clause-info` with an appropriately-formed
;; clause.
;;
;; The first item in the clause must be a normal (non-keyword) symbol, but
;; the rest of the clause keywords must be actual keyword symbols.
;;
;; 2. Build the appropriate list to `macroexpand-1`. This should be of the
;; form `(the-wierdly-named-macro ...)`.
;;
;; Note that the macro will be expecting the clause to come in as keyword
;; arguments, so unlike in step 1 ALL the clause keywords need to be actual
;; keywords, including the first.
;;
;; We'll also bind `iterate::*result-var*` so any macros that use it won't
;; immediately shit the bed.
(let ((iterate::*result-var* 'iterate::*result-var*))
(values
(macroexpand-1 (cons (iterate::clause-info-function
(iterate::get-clause-info
(keywordize-some-of-clause clause)))
(keywordize-clause clause))))))
(defmacro-driver (FOR var IN-HASHSET hset)
(let ((kwd (if generate 'generate 'for)))
`(,kwd (,var) :in-hashtable (losh.hash-sets::hash-set-storage ,hset))))
(defmacro-driver (FOR var IN-RING-BUFFER ring-buffer)
"Iterate over the elements of `ring-buffer`, oldest to newest."
(let ((kwd (if generate 'generate 'for)))
(with-gensyms (rb r w d s)
`(progn
(with ,rb = ,ring-buffer)
(with ,r = (losh.ring-buffers::r ,rb))
(with ,w = (losh.ring-buffers::w ,rb))
(with ,d = (losh.ring-buffers::data ,rb))
(with ,s = (losh.ring-buffers::size ,rb))
(,kwd ,var :next (if (= ,r ,w)
(terminate)
(prog1 (svref ,d ,r)
(incf ,r)
(when (= ,r ,s)
(setf ,r 0)))))))))
(defmacro-driver (FOR var SEED seed THEN then)
"Bind `var` to `seed` initially, then to `then` on every iteration.
This differs from `(FOR … FIRST … THEN …)` and `(FOR … INITIALLY … THEN …)`
because `then` is evaluated on every iteration, *including* the first.
Example:
(iterate
(repeat 3)
(for x :first 0 :then (1+ x))
(for y :initially 0 :then (1+ y))
(for z :seed 0 :then (1+ z))
(collect (list x y z)))
; =>
((0 0 1)
(1 1 2)
(2 2 3))
"
(let ((kwd (if generate 'generate 'for)))
`(progn
(,kwd ,var :next ,then)
(initially (setf ,var ,seed)))))
(deftype sharp-quoted-function ()
'(cons (eql function)
(cons t null)))
(defmacro-clause (FINDING-ALL expr MINIMIZING m-expr &optional INTO var)
"Collect all `expr`s minimizing `m-expr` into a list at `var`.
The partial list at `var` is available for inspection at any point in the loop.
If `m-expr` is a sharp-quoted function, then it is called on `expr` instead of
being evaluated and compared itself.
"
;; TODO: result-type
(with-gensyms (min value m-value tail)
(let ((result (or var iterate::*result-var*)))
`(progn
(with ,result = '())
(with ,tail = nil)
(with ,min = nil)
,(typecase m-expr
(sharp-quoted-function
`(progn
(for ,value = ,expr)
(for ,m-value = (funcall ,m-expr ,value))
(cond
((or (null ,min)
(< ,m-value ,min)) (setf ,result (list ,value)
,tail ,result
,min ,m-value))
((= ,m-value ,min) (setf (cdr ,tail) (cons ,value nil)
,tail (cdr ,tail))))))
(t `(progn
(for ,m-value = ,m-expr)
(cond
((or (null ,min)
(< ,m-value ,min)) (setf ,result (list ,expr)
,tail ,result
,min ,m-value))
((= ,m-value ,min) (setf (cdr ,tail) (cons ,expr nil)
,tail (cdr ,tail)))))))))))
(defmacro-clause (FINDING-ALL expr MAXIMIZING m-expr &optional INTO var)
"Collect all `expr`s maximizing `m-expr` into a list at `var`.
The partial list at `var` is available for inspection at any point in the loop.
If `m-expr` is a sharp-quoted function, then it is called on `expr` instead of
being evaluated and compared itself.
"
;; TODO: result-type
(with-gensyms (max value m-value tail)
(let ((result (or var iterate::*result-var*)))
`(progn
(with ,result = '())
(with ,tail = nil)
(with ,max = nil)
,(typecase m-expr
(sharp-quoted-function
`(progn
(for ,value = ,expr)
(for ,m-value = (funcall ,m-expr ,value))
(cond
((or (null ,max)
(> ,m-value ,max)) (setf ,result (list ,value)
,tail ,result
,max ,m-value))
((= ,m-value ,max) (setf (cdr ,tail) (cons ,value nil)
,tail (cdr ,tail))))))
(t `(progn
(for ,m-value = ,m-expr)
(cond
((or (null ,max)
(> ,m-value ,max)) (setf ,result (list ,expr)
,tail ,result
,max ,m-value))
((= ,m-value ,max) (setf (cdr ,tail) (cons ,expr nil)
,tail (cdr ,tail)))))))))))
(defmacro-clause (FINDING-ALL expr SUCH-THAT test &optional INTO var RESULT-TYPE result-type)
"Collect all `expr`s for which `test` is true.
If `test` is a sharp-quoted function, then it is called on `expr` instead of
being evaluated and compared itself.
"
(let ((result (or var iterate::*result-var*)))
(typecase test
(sharp-quoted-function
(with-gensyms (value)
`(progn
(for ,value = ,expr)
(when (funcall ,test ,value)
(collect ,value :into ,result
,@(when result-type `(:result-type ,result-type)))))))
(t `(when ,test
(collect ,expr :into ,result
,@(when result-type `(:result-type ,result-type))))))))
(defmacro-clause (FINDING-FIRST expr SUCH-THAT test &optional INTO var)
"Collect the first `expr` for which `test` is true.
Unlike vanilla `finding`, it does not block further iteration.
If `test` is a sharp-quoted function, then it is called on `expr` instead of
being evaluated and compared itself.
"
(with-gensyms (value found)
(let ((result (or var iterate::*result-var*)))
`(progn
(with ,found)
,@(when var (list `(with ,var)))
,(typecase test
(sharp-quoted-function
`(unless ,found
(for ,value = ,expr)
(when (funcall ,test ,value)
(setf ,found t ,result ,value))))
(t `(unless ,found
(when ,test
(setf ,found t ,result ,expr)))))))))
(defmacro returning (&rest values)
"Return `values` from the iterate clause.
Equivalent to `(finally (return (values ...)))`.
"
`(finally (return (values ,@values))))
(defmacro-driver (FOR var-or-vars MATCHING regex AGAINST string &optional OVERLAP overlap? START start END end)
"Iterate over the matches of `regex` in `string`, binding `var-or-vars`.
`regex` must be a suitable argument for passing to `ppcre:create-scanner`.
Note that `ppcre:create-scanner` accepts already-created scanners and returns
them unchanged, so you can provide an existing scanner if you wish.
`var-or-vars` will be bound to the successive matches. If it is a symbol, it
will be bound to the entire match. If it is a list of variables, they will be
bound to the register groups as if by `ppcre:register-groups-bind`.
If `overlap?` is true, after finding a match, the next match will be searched
for from the next character, instead of skipping past the entire previous
match.
`generate` is supported.
Examples:
(iterate (for word :matching \"\\\\w+\" :against \"foo bar baz\")
(collect word))
; =>
(\"foo\" \"bar\" \"baz\")
(iterate (for x :matching \"\\\\w\\\\w\" :against \"abcde\")
(collect x))
; =>
(\"ab\" \"cd\")
(iterate (for x :matching \"\\\\w\\\\w\" :against \"abcde\" :overlap t)
(collect x))
; =>
(\"ab\" \"bc\" \"cd\" \"de\")
(iterate (for ((#'string-upcase name) (#'parse-integer year month day))
:matching \"(\\\\w+)? (\\\\d+)-(\\\\d+)-(\\\\d+)\"
:against \"foo 2019-12-06 / 2010-11-14\")
(collect (list name year month day)))
; =>
((\"FOO\" 2019 12 6) (NIL 2010 11 14))
(iterate (for x :matching (ppcre:create-scanner \"foo+\" :case-insensitive-mode t)
:against \"FOOOOD\")
(collect x))
; =>
(\"FOOOO\")
"
(let* ((kwd (if generate 'generate 'for))
(single (symbolp var-or-vars))
(var (if single var-or-vars nil))
(vars (unless single
(iterate
(for spec :in var-or-vars)
(etypecase spec
(cons (destructuring-bind (function &rest vars) spec
(appending (mapcar (curry #'cons function) vars))))
(symbol (appending (list `(nil . ,spec)))))))))
(with-gensyms (scanner% pos% start% end% string% reg-start% reg-end% limit%)
`(progn
(with ,pos% = ,(or start 0))
(with ,string% = ,string)
(with ,limit% = ,(or end `(length ,string%)))
(with ,scanner% = (ppcre:create-scanner ,regex))
(,kwd ,(if single
var
`(values ,@(mapcar #'cdr vars)))
:next
(multiple-value-bind (,start% ,end% ,@(unless single `(,reg-start% ,reg-end%)))
(ppcre:scan ,scanner% ,string% :start ,pos% :end ,limit%)
(declare (ignorable ,end%))
(if (null ,start%)
(terminate)
(progn (setf ,pos% ,(if overlap? `(1+ ,start%) end%))
,(if single
`(subseq ,string% ,start% ,end%)
`(values
,@(iterate
(for i :from 0)
(for (function . nil) :in vars)
(collect
`(when (aref ,reg-start% ,i)
(,@(if function `(funcall ,function) `(progn))
(subseq ,string%
(aref ,reg-start% ,i)
(aref ,reg-end% ,i))))))))))))))))