! Copyright (C) 2003, 2007 Slava Pestov. ! See http://factorcode.org/license.txt for BSD license. USING: kernel math.private ; IN: math GENERIC: >fixnum ( x -- y ) foldable GENERIC: >bignum ( x -- y ) foldable GENERIC: >float ( x -- y ) foldable MATH: number= ( x y -- ? ) foldable M: object number= 2drop f ; MATH: < ( x y -- ? ) foldable MATH: <= ( x y -- ? ) foldable MATH: > ( x y -- ? ) foldable MATH: >= ( x y -- ? ) foldable MATH: + ( x y -- z ) foldable MATH: - ( x y -- z ) foldable MATH: * ( x y -- z ) foldable MATH: / ( x y -- z ) foldable MATH: /i ( x y -- z ) foldable MATH: mod ( x y -- z ) foldable MATH: /mod ( x y -- z w ) foldable MATH: bitand ( x y -- z ) foldable MATH: bitor ( x y -- z ) foldable MATH: bitxor ( x y -- z ) foldable GENERIC# shift 1 ( x n -- y ) foldable GENERIC: bitnot ( x -- y ) foldable GENERIC# bit? 1 ( x n -- ? ) foldable : log2 ( x -- n ) dup 0 <= [ "log2 expects positive inputs" throw ] [ (log2) ] if ; foldable GENERIC: zero? ( x -- ? ) foldable M: object zero? drop f ; GENERIC: sqrt ( x -- y ) foldable : 1+ ( x -- y ) 1 + ; foldable : 1- ( x -- y ) 1 - ; foldable : 2/ ( x -- y ) -1 shift ; foldable : sq ( x -- y ) dup * ; foldable : neg ( x -- -x ) 0 swap - ; foldable : recip ( x -- y ) 1 swap / ; foldable : /f ( x y -- z ) >r >float r> >float float/f ; inline : max ( x y -- z ) [ > ] most ; foldable : min ( x y -- z ) [ < ] most ; foldable : between? ( x y z -- ? ) pick >= [ >= ] [ 2drop f ] if ; inline : rem ( x y -- z ) tuck mod over + swap mod ; foldable : sgn ( x -- n ) dup 0 < -1 0 ? swap 0 > 1 0 ? bitor ; foldable : truncate ( x -- y ) dup 1 mod - ; inline : round ( x -- y ) dup sgn 2 / + truncate ; inline : floor ( x -- y ) dup 1 mod dup zero? [ drop ] [ dup 0 < [ - 1- ] [ - ] if ] if ; foldable : ceiling ( x -- y ) neg floor neg ; foldable : [-] ( x y -- z ) - 0 max ; inline : 2^ ( n -- 2^n ) 1 swap shift ; inline : even? ( n -- ? ) 1 bitand zero? ; : odd? ( n -- ? ) 1 bitand 1 number= ; : >fraction ( a/b -- a b ) dup numerator swap denominator ; inline UNION: integer fixnum bignum ; UNION: rational integer ratio ; UNION: real rational float ; UNION: number real complex ; GENERIC: fp-nan? ( x -- ? ) M: object fp-nan? drop f ; M: float fp-nan? double>bits -51 shift BIN: 111111111111 [ bitand ] keep number= ; ) ( x y -- z ) dup zero? [ drop ] [ ] if ; inline PRIVATE> : rect> ( x y -- z ) over real? over real? and [ (rect>) ] [ "Complex number must have real components" throw ] if ; inline : >rect ( z -- x y ) dup real swap imaginary ; inline : >float-rect ( z -- x y ) >rect swap >float swap >float ; inline : (next-power-of-2) ( i n -- n ) 2dup >= [ drop ] [ >r 1 shift r> (next-power-of-2) ] if ; : next-power-of-2 ( m -- n ) 2 swap (next-power-of-2) ; foldable r >r pick pick < r> r> if ; inline : iterate-step ( i n quot -- i n quot ) #! Apply quot to i, keep i and quot, hide n. swap >r 2dup 2slip r> swap ; inline : iterate-next >r >r 1+ r> r> ; inline PRIVATE> : (each-integer) ( i n quot -- ) [ iterate-step iterate-next (each-integer) ] [ 3drop ] if-iterate? ; inline : (find-integer) ( i n quot -- i ) [ iterate-step roll [ 2drop ] [ iterate-next (find-integer) ] if ] [ 3drop f ] if-iterate? ; inline : (all-integers?) ( i n quot -- ? ) [ iterate-step roll [ iterate-next (all-integers?) ] [ 3drop f ] if ] [ 3drop t ] if-iterate? ; inline : each-integer ( n quot -- ) iterate-prep (each-integer) ; inline : times ( n quot -- ) [ drop ] swap compose each-integer ; inline : find-integer ( n quot -- i ) iterate-prep (find-integer) ; inline : all-integers? ( n quot -- ? ) iterate-prep (all-integers?) ; inline : find-last-integer ( n quot -- i ) over 0 < [ 2drop f ] [ 2dup 2slip rot [ drop ] [ >r 1- r> find-last-integer ] if ] if ; inline