Add ASCII demo with cl-charms
author |
Steve Losh <steve@stevelosh.com> |
date |
Sat, 16 Jul 2016 22:04:38 +0000 |
parents |
6f72eefef02e |
children |
579c965d6ae5 |
(in-package #:sand.utils)
;;;; Miscellaneous
(defmacro zap% (place function &rest arguments &environment env)
"Update `place` by applying `function` to its current value and `arguments`.
`arguments` should contain the symbol `%`, which is treated as a placeholder
where the current value of the place will be substituted into the function
call.
For example:
(zap% foo #'- % 10) => (setf foo (- foo 10)
(zap% foo #'- 10 %) => (setf foo (- 10 foo)
"
;; original idea/name from http://malisper.me/2015/09/29/zap/
(assert (find '% arguments) ()
"Placeholder % not included in zap macro form.")
(multiple-value-bind (temps exprs stores store-expr access-expr)
(get-setf-expansion place env)
`(let* (,@(mapcar #'list temps exprs)
(,(car stores)
(funcall ,function
,@(substitute access-expr '% arguments))))
,store-expr)))
(defmacro recursively (bindings &body body)
"Execute body recursively, like Clojure's `loop`/`recur`.
`bindings` should contain a list of symbols and (optional) default values.
In `body`, `recur` will be bound to the function for recurring.
Example:
(defun length (some-list)
(recursively ((list some-list) (n 0))
(if (null list)
n
(recur (cdr list) (1+ n)))))
"
(flet ((extract-var (binding)
(if (atom binding) binding (first binding)))
(extract-val (binding)
(if (atom binding) nil (second binding))))
`(labels ((recur ,(mapcar #'extract-var bindings)
,@body))
(recur ,@(mapcar #'extract-val bindings)))))
(defmacro dis (arglist &body body)
"Disassemble the code generated for a `lambda*` with `arglist` and `body`.
It will also spew compiler notes so you can see why the garbage box isn't
doing what you think it should be doing.
"
`(->> '(lambda* ,arglist
(declare (optimize speed))
,@body)
macroexpand-1
(compile nil)
disassemble))
;;;; Sets
;;; Janky implementation of basic sets.
(defclass hash-set ()
((data :initarg :data)))
(defun make-set (&key (test #'eql) (initial-data nil))
(let ((set (make-instance 'hash-set
:data (make-hash-table :test test))))
(mapcar (curry #'set-add set) initial-data)
set))
(defun set-contains-p (set value)
(nth-value 1 (gethash value (slot-value set 'data))))
(defun set-empty-p (set)
(zerop (hash-table-count (slot-value set 'data))))
(defun set-add (set value)
(setf (gethash value (slot-value set 'data)) t)
value)
(defun set-add-all (set seq)
(map nil (curry #'set-add set) seq))
(defun set-remove (set value)
(remhash value (slot-value set 'data))
value)
(defun set-remove-all (set seq)
(map nil (curry #'set-remove set) seq))
(defun set-clear (set)
(clrhash (slot-value set 'data))
set)
(defun set-random (set)
(if (set-empty-p set)
(values nil nil)
(loop :with data = (slot-value set 'data)
:with target = (random (hash-table-count data))
:for i :from 0
:for k :being :the :hash-keys :of data
:when (= i target)
:do (return (values k t)))))
(defun set-pop (set)
(multiple-value-bind (val found) (set-random set)
(if found
(progn
(set-remove set val)
(values val t))
(values nil nil))))
(defmethod print-object ((set hash-set) stream)
(print-unreadable-object (set stream :type t)
(format stream "~{~S~^ ~}"
(hash-keys (slot-value set 'data)))))
;;;; Iterate
(defmacro-clause (AVERAGING expr &optional INTO var)
(with-gensyms (count)
(let ((average (or var (gensym "average"))))
`(progn
(for ,average
:first ,expr
;; continuously recompute the running average instead of keeping
;; a running total to avoid bignums when possible
:then (/ (+ (* ,average ,count)
,expr)
(1+ ,count)))
(for ,count :from 1)
,(when (null var)
;; todo handle this better
`(finally (return ,average)))))))
(defmacro-clause (TIMING time-type &optional SINCE-START-INTO var PER-ITERATION-INTO per)
(let ((timing-function (ecase time-type
((real-time) #'get-internal-real-time)
((run-time) #'get-internal-run-time)))
(since (or var (gensym))))
(with-gensyms (start-time current-time previous-time)
`(progn
(with ,start-time = (funcall ,timing-function))
(for ,current-time = (funcall ,timing-function))
(for ,previous-time :previous ,current-time :initially ,start-time)
(for ,since = (- ,current-time ,start-time))
,(when per
`(for ,per = (- ,current-time ,previous-time)))
,(when (and (null var) (null per))
`(finally (return ,since)))))))