! Copyright (C) 2008 Doug Coleman, Michael Judge. ! See http://factorcode.org/license.txt for BSD license. USING: assocs combinators generalizations kernel locals math math.functions math.order math.vectors sequences sequences.private sorting fry arrays grouping sets ; IN: math.statistics : power-mean ( seq p -- x ) [ '[ _ ^ ] map-sum ] [ [ length / ] [ recip ^ ] bi* ] 2bi ; : mean ( seq -- x ) [ sum ] [ length ] bi / ; : quadratic-mean ( seq -- x ) ! root-mean-square [ [ sq ] map-sum ] [ length ] bi / sqrt ; : geometric-mean ( seq -- x ) [ length ] [ product ] bi nth-root ; : harmonic-mean ( seq -- x ) [ recip ] map-sum recip ; : contraharmonic-mean ( seq -- x ) [ [ sq ] map-sum ] [ sum ] bi / ; i! 0 :> j! 0 :> l! 0 :> x! seq length 1 - :> m! [ l m < ] [ k seq nth x! l i! m j! [ i j <= ] [ [ i seq nth-quot call x quot call ] [ i 1 + i! ] while [ x j seq nth-quot call quot call ] [ j 1 - j! ] while i j <= [ i j seq exchange-quot call i 1 + i! j 1 - j! ] when ] do while j k < [ i l! ] when k i < [ j m! ] when ] while k seq nth ; inline : (kth-object) ( seq k nth-quot exchange-quot quot: ( x y -- ? ) -- elt ) [ clone ] 4dip ((kth-object)) ; inline : kth-object-unsafe ( seq k quot: ( x y -- ? ) -- elt ) [ [ nth-unsafe ] [ exchange-unsafe ] ] dip (kth-object) ; inline : kth-objects-unsafe ( seq kths quot: ( x y -- ? ) -- elts ) [ clone ] 2dip '[ [ nth-unsafe ] [ exchange-unsafe ] _ ((kth-object)) ] with map ; inline PRIVATE> : kth-object ( seq k quot: ( x y -- ? ) -- elt ) [ [ nth ] [ exchange ] ] dip (kth-object) ; inline : kth-objects ( seq kths quot: ( x y -- ? ) -- elts ) [ clone ] 2dip '[ [ nth ] [ exchange ] _ ((kth-object)) ] with map ; inline : kth-smallests ( seq kths -- elts ) [ < ] kth-objects-unsafe ; : kth-smallest ( seq k -- elt ) [ < ] kth-object-unsafe ; : kth-largests ( seq kths -- elts ) [ > ] kth-objects-unsafe ; : kth-largest ( seq k -- elt ) [ > ] kth-object-unsafe ; : count-relative ( seq k -- lt eq gt ) [ 0 0 0 ] 2dip '[ _ <=> { { +lt+ [ [ 1 + ] 2dip ] } { +gt+ [ 1 + ] } { +eq+ [ [ 1 + ] dip ] } } case ] each ; : minmax-relative ( seq k -- lt eq gt lt-max gt-min ) [ 0 0 0 -1/0. 1/0. ] 2dip '[ dup _ <=> { { +lt+ [ [ 1 + ] 5 ndip '[ _ max ] dip ] } { +gt+ [ [ 1 + ] 3dip min ] } { +eq+ [ [ 1 + ] 4dip drop ] } } case ] each ; : lower-median-index ( seq -- n ) [ midpoint@ ] [ length odd? [ 1 - ] unless ] bi ; : lower-median ( seq -- elt ) [ ] [ lower-median-index ] bi kth-smallest ; : upper-median ( seq -- elt ) dup midpoint@ kth-smallest ; : medians ( seq -- lower upper ) [ ] [ [ lower-median-index ] [ midpoint@ ] bi 2array ] bi kth-smallests first2 ; : median ( seq -- x ) dup length odd? [ lower-median ] [ medians + 2 / ] if ; ! quantile can be any n-tile. quartile is n = 4, percentile is n = 100 ! a,b,c,d parameters, N - number of samples, q is quantile (1/2 for median, 1/4 for 1st quartile) ! http://mathworld.wolfram.com/Quantile.html ! a + (N + b) q - 1 ! could subtract 1 from a : quantile-x ( a b N q -- x ) [ + ] dip * + 1 - ; inline ! 2+1/4 frac is 1/4 : frac ( x -- x' ) >fraction [ /mod nip ] keep / ; inline :: quantile-indices ( seq qs a b c d -- seq ) qs [ [ a b seq length ] dip quantile-x ] map ; :: qabcd ( y-floor y-ceiling x c d -- qabcd ) y-floor y-ceiling y-floor - c d x frac * + * + ; :: quantile-abcd ( seq qs a b c d -- quantile ) seq qs a b c d quantile-indices :> indices indices [ [ floor ] [ ceiling ] bi 2array ] map concat :> index-pairs seq index-pairs kth-smallests 2 group indices [ [ first2 ] dip c d qabcd ] 2map ; : quantile1 ( seq qs -- seq' ) 0 0 1 0 quantile-abcd ; : quantile3 ( seq qs -- seq' ) 1/2 0 0 0 quantile-abcd ; : quantile4 ( seq qs -- seq' ) 0 0 0 1 quantile-abcd ; : quantile5 ( seq qs -- seq' ) 1/2 0 0 1 quantile-abcd ; : quantile6 ( seq qs -- seq' ) 0 1 0 1 quantile-abcd ; : quantile7 ( seq qs -- seq' ) 1 -1 0 1 quantile-abcd ; : quantile8 ( seq qs -- seq' ) 1/3 1/3 0 1 quantile-abcd ; : quantile9 ( seq qs -- seq' ) 3/8 1/4 0 1 quantile-abcd ; : quartile ( seq -- seq' ) { 1/4 1/2 3/4 } quantile5 ; assoc) ( seq map-quot: ( x -- ..y ) insert-quot: ( ..y assoc -- ) assoc -- assoc ) [ swap curry compose each ] keep ; inline PRIVATE> : sequence>assoc! ( assoc seq map-quot: ( x -- ..y ) insert-quot: ( ..y assoc -- ) -- assoc ) 4 nrot (sequence>assoc) ; inline : sequence>assoc ( seq map-quot: ( x -- ..y ) insert-quot: ( ..y assoc -- ) exemplar -- assoc ) clone (sequence>assoc) ; inline : sequence>hashtable ( seq map-quot: ( x -- ..y ) insert-quot: ( ..y assoc -- ) -- hashtable ) H{ } sequence>assoc ; inline : histogram! ( hashtable seq -- hashtable ) [ ] [ inc-at ] sequence>assoc! ; : histogram-by ( seq quot: ( x -- bin ) -- hashtable ) [ inc-at ] sequence>hashtable ; inline : histogram ( seq -- hashtable ) [ ] histogram-by ; : sorted-histogram ( seq -- alist ) histogram sort-values ; : collect-pairs ( seq quot: ( x -- v k ) -- hashtable ) [ push-at ] sequence>hashtable ; inline : collect-by ( seq quot: ( x -- x' ) -- hashtable ) [ dup ] prepose collect-pairs ; inline : mode ( seq -- x ) histogram >alist [ ] [ [ [ second ] bi@ > ] most ] map-reduce first ; ERROR: empty-sequence ; : minmax ( seq -- min max ) [ empty-sequence ] [ [ first dup ] keep [ [ min ] [ max ] bi-curry bi* ] each ] if-empty ; : range ( seq -- x ) minmax swap - ; : sample-var ( seq -- x ) #! normalize by N-1 dup length 1 <= [ drop 0 ] [ [ [ mean ] keep [ - sq ] with map-sum ] [ length 1 - ] bi / ] if ; : full-var ( seq -- x ) dup length 1 <= [ drop 0 ] [ [ [ mean ] keep [ - sq ] with map-sum ] [ length ] bi / ] if ; ALIAS: var sample-var : sample-std ( seq -- x ) sample-var sqrt ; : full-std ( seq -- x ) full-var sqrt ; ALIAS: std sample-std : mean-dev ( seq -- x ) dup mean v-n vabs mean ; : median-dev ( seq -- x ) dup median v-n vabs mean ; : sample-ste ( seq -- x ) [ sample-std ] [ length ] bi sqrt / ; : full-ste ( seq -- x ) [ full-std ] [ length ] bi sqrt / ; ALIAS: ste sample-ste : ((r)) ( mean(x) mean(y) {x} {y} -- (r) ) ! finds sigma((xi-mean(x))(yi-mean(y)) 0 [ [ [ pick ] dip swap - ] bi@ * + ] 2reduce 2nip ; : (r) ( mean(x) mean(y) {x} {y} sx sy -- r ) * recip [ [ ((r)) ] keep length 1 - / ] dip * ; : [r] ( {{x,y}...} -- mean(x) mean(y) {x} {y} sx sy ) first2 [ [ [ mean ] bi@ ] 2keep ] 2keep [ std ] bi@ ; : r ( {{x,y}...} -- r ) [r] (r) ; : r^2 ( {{x,y}...} -- r ) r sq ; : least-squares ( {{x,y}...} -- alpha beta ) [r] { [ 2dup ] [ ] [ ] [ ] [ ] } spread ! stack is mean(x) mean(y) mean(x) mean(y) {x} {y} sx sy [ (r) ] 2keep ! stack is mean(x) mean(y) r sx sy swap / * ! stack is mean(x) mean(y) beta [ swapd * - ] keep ; : cov ( {x} {y} -- cov ) [ dup mean v-n ] bi@ v* mean ; : sample-corr ( {x} {y} -- corr ) [ cov ] [ [ sample-var ] bi@ * sqrt ] 2bi / ; : full-corr ( {x} {y} -- corr ) [ cov ] [ [ full-var ] bi@ * sqrt ] 2bi / ; ALIAS: corr sample-corr : cum-sum ( seq -- seq' ) 0 swap [ + dup ] map nip ; : cum-product ( seq -- seq' ) 1 swap [ * dup ] map nip ; : cum-min ( seq -- seq' ) [ ?first ] keep [ min dup ] map nip ; : cum-max ( seq -- seq' ) [ ?first ] keep [ max dup ] map nip ; : entropy ( seq -- n ) dup members [ [ = ] curry count ] with map dup sum v/n dup [ log ] map v* sum neg ; : binary-entropy ( p -- h ) [ dup log * ] [ 1 swap - dup log * ] bi + neg 2 log / ; : standardize ( u -- v ) [ dup mean v-n ] [ std ] bi v/n ; : differences ( u -- v ) [ 1 tail-slice ] keep [ - ] 2map ; : rescale ( u -- v ) dup minmax over - [ v-n ] [ v/n ] bi* ;