paomian/steam.clj

## steam.clj
;;不得不说，这思想很牛，但是理解起来也很绕，不知道这种代码到底是好还是不好。。。
;;想想不用这种方法怎么来实现这个功能，应该是用一个额外的表记录下所有前面的素数，然后用 (map (fn [x] (some (fn [y] (not-zero?(mod x y))) [primes list])) strems)
(defmacro my-delay [body]
  `(fn [] ~body))

(defn my-force [f]
  (f))

(def the-empty-stream [])

(def stream-null? empty?)

(defmacro cons-stream [x y]
  `[~x (my-delay ~y)])

(defn stream-car [x]
  (first x))

(defn stream-cdr [x]
  (my-force (second x)))

(defn stream-ref [s n]
  (if (= n 0)
    (stream-car s)
    (stream-ref (stream-cdr s) (dec n))))

#_(defn stream-map [f s]
    (println "hhh" s)
    (if (empty? s)
      the-empty-stream
      (cons-stream (f (stream-car s))
                   (stream-map f (stream-cdr s)))))

(defn stream-map [f & s]
  (if (empty? (first s))
    the-empty-stream
    (cons-stream
     (apply f (map stream-car s))
     (apply stream-map f
            (map stream-cdr s)))))

(defn stream-for-each [f s]
  (if (stream-null? s)
    'done
    (do (f (stream-car s))
        (stream-for-each f (stream-cdr s)))))

(defn display-line [x]
  (println x))

(defn display-stream [s]
  (stream-for-each display-line s))

(defn stream-enumerate-interval [low high]
  (if (> low high)
    the-empty-stream
    (cons-stream low (stream-enumerate-interval (inc low) high))))

(defn stream-filter [pred stream]
  (cond (stream-null? stream) the-empty-stream
        (pred (stream-car stream)) (cons-stream (stream-car stream)
                                                (stream-filter pred (stream-cdr stream)))
        :else (stream-filter pred (stream-cdr stream))))

(defn memo-proc [proc]
  (let [already-run? (volatile! false)
        result (volatile! false)]
    (fn []
      (if (not @already-run?)
        (do (vreset! result (proc))
            (vreset! already-run? true)
            @result)
        result))))

(defn integers-starting-from [n]
  (cons-stream n (integers-starting-from (inc n))))

(def integers (integers-starting-from 1))

(def no-sevens (stream-filter (fn [x] (not= 0 (mod x 7)))
                              integers))
(defn divisible? [n m]
  (zero? (mod n m)))

(defn sieve [stream]
  (cons-stream
   (stream-car stream)
   (sieve (stream-filter
           (fn [x] (not (divisible? x (stream-car stream))))
           (stream-cdr stream)))))

;;(def primes (sieve (integers-starting-from 2)))

(def ones (cons-stream 1 ones))

(defn add-streams [s1 s2]
  (stream-map + s1 s2))

(def integers (cons-stream 1 (add-streams ones integers)))

(def fibs (cons-stream 0 (cons-stream 1 (add-streams (stream-cdr fibs) fibs))))

(defn scale-stream [stream factor]
  (stream-map (fn [x] (* x factor)) stream))

(def my-double (cons-stream 1 (scale-stream my-double 2)))

(declare prime?)

(def primes (cons-stream 2 (stream-filter prime? (integers-starting-from 3))))

(defn prime? [n]
  (let [iter (fn iter [ps]
               (cond (> (square (stream-car ps)) n) true
                     (divisible? n (stream-car ps)) false
                     :else (iter (stream-cdr ps))))]
    (iter primes)))

(-> primes (stream-ref 50))
	;;不得不说，这思想很牛，但是理解起来也很绕，不知道这种代码到底是好还是不好。。。
	;;想想不用这种方法怎么来实现这个功能，应该是用一个额外的表记录下所有前面的素数，然后用 (map (fn [x] (some (fn [y] (not-zero?(mod x y))) [primes list])) strems)
	(defmacro my-delay [body]
	`(fn [] ~body))

	(defn my-force [f]
	(f))

	(def the-empty-stream [])

	(def stream-null? empty?)

	(defmacro cons-stream [x y]
	`[~x (my-delay ~y)])

	(defn stream-car [x]
	(first x))

	(defn stream-cdr [x]
	(my-force (second x)))

	(defn stream-ref [s n]
	(if (= n 0)
	(stream-car s)
	(stream-ref (stream-cdr s) (dec n))))

	#_(defn stream-map [f s]
	(println "hhh" s)
	(if (empty? s)
	the-empty-stream
	(cons-stream (f (stream-car s))
	(stream-map f (stream-cdr s)))))

	(defn stream-map [f & s]
	(if (empty? (first s))
	the-empty-stream
	(cons-stream
	(apply f (map stream-car s))
	(apply stream-map f
	(map stream-cdr s)))))

	(defn stream-for-each [f s]
	(if (stream-null? s)
	'done
	(do (f (stream-car s))
	(stream-for-each f (stream-cdr s)))))

	(defn display-line [x]
	(println x))

	(defn display-stream [s]
	(stream-for-each display-line s))

	(defn stream-enumerate-interval [low high]
	(if (> low high)
	the-empty-stream
	(cons-stream low (stream-enumerate-interval (inc low) high))))

	(defn stream-filter [pred stream]
	(cond (stream-null? stream) the-empty-stream
	(pred (stream-car stream)) (cons-stream (stream-car stream)
	(stream-filter pred (stream-cdr stream)))
	:else (stream-filter pred (stream-cdr stream))))

	(defn memo-proc [proc]
	(let [already-run? (volatile! false)
	result (volatile! false)]
	(fn []
	(if (not @already-run?)
	(do (vreset! result (proc))
	(vreset! already-run? true)
	@result)
	result))))

	(defn integers-starting-from [n]
	(cons-stream n (integers-starting-from (inc n))))

	(def integers (integers-starting-from 1))

	(def no-sevens (stream-filter (fn [x] (not= 0 (mod x 7)))
	integers))
	(defn divisible? [n m]
	(zero? (mod n m)))

	(defn sieve [stream]
	(cons-stream
	(stream-car stream)
	(sieve (stream-filter
	(fn [x] (not (divisible? x (stream-car stream))))
	(stream-cdr stream)))))

	;;(def primes (sieve (integers-starting-from 2)))

	(def ones (cons-stream 1 ones))

	(defn add-streams [s1 s2]
	(stream-map + s1 s2))

	(def integers (cons-stream 1 (add-streams ones integers)))

	(def fibs (cons-stream 0 (cons-stream 1 (add-streams (stream-cdr fibs) fibs))))

	(defn scale-stream [stream factor]
	(stream-map (fn [x] (* x factor)) stream))

	(def my-double (cons-stream 1 (scale-stream my-double 2)))

	(declare prime?)

	(def primes (cons-stream 2 (stream-filter prime? (integers-starting-from 3))))

	(defn prime? [n]
	(let [iter (fn iter [ps]
	(cond (> (square (stream-car ps)) n) true
	(divisible? n (stream-car ps)) false
	:else (iter (stream-cdr ps))))]
	(iter primes)))

	(-> primes (stream-ref 50))