-(ns sicp.ch2_3)
+(ns sicp.ch2_3
+ (:use [sicp.utils :only (error)]
+ [sicp.ex2_54 :only (equal?)]))
(defn memq [item x]
(cond
(empty? x) false
(= (first x) item) x
- :else (memq item (rest x))))
\ No newline at end of file
+ :else (memq item (rest x))))
+
+;; differentiation
+
+;; take it for granted the following primitives.
+(declare variable? same-variable? sum? addend augend make-sum product? make-product multiplier multiplicand)
+
+(defn deriv [exp var]
+ (cond (number? exp) 0
+ (variable? exp) (if (same-variable? exp var) 1 0)
+ (sum? exp) (make-sum (deriv (addend exp) var)
+ (deriv (augend exp) var))
+ (product? exp) (make-sum (make-product (multiplier exp)
+ (deriv (multiplicand exp) var))
+ (make-product (deriv (multiplier exp) var)
+ (multiplicand exp)))
+ :else (error "unknown expression type -- derive")))
+
+(defn variable? [x]
+ (symbol? x))
+
+(defn same-variable? [v1 v2]
+ (and (variable? v1)
+ (variable? v2)
+ (= v1 v2)))
+
+(defn =number? [exp num]
+ (and (number? exp) (= exp num)))
+
+(defn make-sum [a1 a2]
+ (cond (=number? a1 0) a2
+ (=number? a2 0) a1
+ (and (number? a1) (number? a2)) (+ a1 a2)
+ :else (list '+ a1 a2)))
+
+(defn make-product [m1 m2]
+ (cond (or (=number? m1 0) (=number? m2 0)) 0
+ (=number? m1 1) m2
+ (=number? m2 1) m1
+ (and (number? m1) (number? m2)) (* m1 m2)
+ :else (list '* m1 m2)))
+
+(defn sum? [x]
+ (and (list? x) (= (first x) '+)))
+
+(defn addend [s]
+ (second s))
+
+(defn augend [s]
+ (second (rest s)))
+
+(defn product? [x]
+ (and (list? x) (= (first x) '*)))
+
+(defn multiplier [p]
+ (second p))
+
+(defn multiplicand [p]
+ (second (rest p)))
+
+;;;; 2.3.3 sets
+(defn element-of-set? [x set]
+ (cond (empty? set) false
+ (equal? x (first set)) true
+ :else (element-of-set? x (rest set))))
+
+;; add an element to the set, if not already part of the set and return the set. If
+;; already part of the set, then return the set
+(defn adjoin-set [x set]
+ (if (element-of-set? x set)
+ set
+ (cons x set)))
+
+;; intersection of two sets (i.e. elements of the set which are present in both the
+;; sets)
+(defn intersection-set [set1 set2]
+ (cond (or (empty? set1) (empty? set2)) ()
+ (element-of-set? (first set1) set2) (cons (first set1)
+ (intersection-set (rest set1) set2))
+ :else (intersection-set (rest set1) set2)))
+
+
+;;; sets as ordered list
+(defn element-of-set? [x set]
+ (cond (empty? set) false
+ (= (first set) x) true
+ (< x (first set)) false
+ :else (element-of-set? x (rest set))))
+
+(defn intersection-set [set1 set2]
+ (if (or (empty? set1) (empty? set2))
+ ()
+ (let [x1 (first set1)
+ x2 (first set2)]
+ (cond (= x1 x2) (cons x1 (intersection-set (rest set1)
+ (rest set2)))
+ (< x1 x2) (intersection-set (rest set1) set2)
+ (< x2 x1) (intersection-set (rest set2) set1)))))
+
+;;; sets as trees
+;;; trees using lists
+;;; every node is a list of 3 elements: entry, left tree and right tree
+(defn entry [tree]
+ (first tree))
+
+(defn left-branch [tree]
+ (second tree))
+
+(defn right-branch [tree]
+ (second (rest tree)))
+
+(defn make-tree [entry left right]
+ (list entry left right))
+
+(defn element-of-set? [x set]
+ (cond (empty? set) false
+ (= (entry set) x) true
+ (< x (entry set)) (element-of-set? x (left-branch set))
+ (> x (entry set)) (element-of-set? x (right-branch set))))
+
+(defn adjoin-set [x set]
+ (cond (empty? set) (make-tree x '() '())
+ (= x (entry set)) set
+ (< x (entry set)) (make-tree (entry set)
+ (adjoin-set x (left-branch set))
+ (right-branch set))
+ (> x (entry set)) (make-tree (entry set)
+ (left-branch set)
+ (adjoin-set x (right-branch set)))))
+
+
+;;; key lookup
+(defn lookup [given-key set-of-records]
+ (cond (empty? set-of-records) false
+ (equal? given-key (key (first set-of-records))) (first set-of-records)
+ :else (lookup given-key (rest set-of-records))))
\ No newline at end of file