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Line 1: {{task}} ''Reduce'' is a function or method that is used to take the values in an array or a list and apply a function to successive members of the list to produce (or reduce them to), a single value. ;Task: Show how ''reduce'' (or ''foldl'' or ''foldr'' etc), work (or would be implemented) in your language. ;See also: * Wikipedia article:   [[wp:Fold (higher-order function)\|Fold]] * Wikipedia article:   [[wp:Catamorphism\|Catamorphism]] <br><br> =={{header\|11l}}== <syntaxhighlight lang="11l">print((1..3).reduce((x, y) -> x + y)) print((1..3).reduce(3, (x, y) -> x + y)) print([1, 1, 3].reduce((x, y) -> x + y)) print([1, 1, 3].reduce(2, (x, y) -> x + y))</syntaxhighlight> {{out}} <pre> 6 9 5 7 </pre> =={{header\|6502 Assembly}}== {{works with\|https://skilldrick.github.io/easy6502/ Easy6502}} <syntaxhighlight lang="6502asm">define catbuf $10 define catbuf_temp $12 ldx #0 ramloop: txa sta $00,x inx cpx #$10 bne ramloop ;load zero page addresses $00-$0f with values equal ;to that address ldx #0 ;zero X loop_cata: lda $00,x ;load the zeroth element clc adc $01,x ;add the first to it. inx inx ;inx twice. Otherwise the same element ;would get added twice sta catbuf_temp ;store in temp ram lda catbuf clc adc catbuf_temp ;add to previously stored value sta catbuf ;store in result cpx #$10 ;is the range over? bne loop_cata ;if not, loop again ldx #$00 lda catbuf sta $00,x ;store the sum in the zeroth entry of the range inx lda #$00 ;now clear the rest of zeropage, leaving only the sum clear_ram: sta $00,x inx cpx #$ff bne clear_ram</syntaxhighlight> =={{header\|ABAP}}== This works in ABAP version 7.40 and above. <syntaxhighlight lang="abap"> report z_catamorphism. data(numbers) = value int4_table( ( 1 ) ( 2 ) ( 3 ) ( 4 ) ( 5 ) ). write: \|numbers = { reduce string( init output = `[` index = 1 for number in numbers next output = cond string( when index eq lines( numbers ) then \|{ output }, { number } ]\| when index > 1 then \|{ output }, { number }\| else \|{ output } { number }\| ) index = index + 1 ) }\|, /. write: \|sum(numbers) = { reduce int4( init result = 0 for number in numbers next result = result + number ) }\|, /. write: \|product(numbers) = { reduce int4( init result = 1 for number in numbers next result = result * number ) }\|, /. data(strings) = value stringtab( ( `reduce` ) ( `in` ) ( `ABAP` ) ). write: \|strings = { reduce string( init output = `[` index = 1 for string in strings next output = cond string( when index eq lines( strings ) then \|{ output }, { string } ]\| when index > 1 then \|{ output }, { string }\| else \|{ output } { string }\| ) index = index + 1 ) }\|, /. write: \|concatenation(strings) = { reduce string( init text = `` for string in strings next text = \|{ text } { string }\| ) }\|, /. </syntaxhighlight> {{out}} <pre> numbers = [ 1, 2, 3, 4, 5 ] sum(numbers) = 15 product(numbers) = 120 strings = [ reduce, in, ABAP ] concatenation(strings) = reduce in ABAP </pre> =={{header\|Ada}}== <syntaxhighlight lang="ada">with Ada.Text_IO; procedure Catamorphism is type Fun is access function (Left, Right: Natural) return Natural; type Arr is array(Natural range <>) of Natural; function Fold_Left (F: Fun; A: Arr) return Natural is Result: Natural := A(A'First); begin for I in A'First+1 .. A'Last loop Result := F(Result, A(I)); end loop; return Result; end Fold_Left; function Max (L, R: Natural) return Natural is (if L > R then L else R); function Min (L, R: Natural) return Natural is (if L < R then L else R); function Add (Left, Right: Natural) return Natural is (Left + Right); function Mul (Left, Right: Natural) return Natural is (Left * Right); package NIO is new Ada.Text_IO.Integer_IO(Natural); begin NIO.Put(Fold_Left(Min'Access, (1,2,3,4)), Width => 3); NIO.Put(Fold_Left(Max'Access, (1,2,3,4)), Width => 3); NIO.Put(Fold_Left(Add'Access, (1,2,3,4)), Width => 3); NIO.Put(Fold_Left(Mul'Access, (1,2,3,4)), Width => 3); end Catamorphism;</syntaxhighlight> {{out}} <pre> 1 4 10 24</pre> =={{header\|Aime}}== <syntaxhighlight lang="aime">integer s; s = 0; list(1, 2, 3, 4, 5, 6, 7, 8, 9).ucall(add_i, 1, s); o_(s, "\n");</syntaxhighlight> {{Out}} <pre>45</pre> =={{header\|ALGOL 68}}== <syntaxhighlight lang="algol68"># applies fn to successive elements of the array of values # # the result is 0 if there are no values # PROC reduce = ( []INT values, PROC( INT, INT )INT fn )INT: IF UPB values < LWB values THEN # no elements # 0 ELSE # there are some elements # INT result := values[ LWB values ]; FOR pos FROM LWB values + 1 TO UPB values DO result := fn( result, values[ pos ] ) OD; result FI; # reduce # # test the reduce procedure # BEGIN print( ( reduce( ( 1, 2, 3, 4, 5 ), ( INT a, b )INT: a + b ), newline ) ) # sum # ; print( ( reduce( ( 1, 2, 3, 4, 5 ), ( INT a, b )INT: a * b ), newline ) ) # product # ; print( ( reduce( ( 1, 2, 3, 4, 5 ), ( INT a, b )INT: a - b ), newline ) ) # difference # END</syntaxhighlight> {{out}} <pre> +15 +120 -13 </pre> =={{header\|APL}}== <em>Reduce</em> is a built-in APL operator, written as <code>/</code>. <syntaxhighlight lang="apl"> +/ 1 2 3 4 5 6 7 28 ×/ 1 2 3 4 5 6 7 5040</syntaxhighlight> For built-in functions, the seed value is automatically chosen to make sense. <syntaxhighlight lang="apl"> +/⍬ 0 ×/⍬ 1 ⌈/⍬ ⍝ this gives the minimum supported value ¯1.797693135E308</syntaxhighlight> For user-supplied functions, the last element in the list is considered the seed. If <code>F/</code> is called with a list of only one element, <code>F</code> itself is never called, and calling <code>F/</code> with the empty list is an error. <syntaxhighlight lang="apl"> {⎕←'Input:',⍺,⍵ ⋄ ⍺+⍵}/ 1 2 3 4 5 Input: 4 5 Input: 3 9 Input: 2 12 Input: 1 14 15 {⎕←'Input:',⍺,⍵ ⋄ ⍺+⍵}/ 1 1 {⎕←'Input:',⍺,⍵ ⋄ ⍺+⍵}/ ⍬ DOMAIN ERROR</syntaxhighlight> =={{header\|AppleScript}}== {{Trans\|JavaScript}} Iteratively implemented '''foldl''' and '''foldr''', using the same argument sequence as in the corresponding JavaScript array methods '''reduce()''' and '''reduceRight()'''. (Note that to obtain first-class functions from user-defined AppleScript handlers, we have to 'lift' them into script objects). <syntaxhighlight lang="applescript">---------------------- CATAMORPHISMS --------------------- -- the arguments available to the called function f(a, x, i, l) are -- a: current accumulator value -- x: current item in list -- i: [ 1-based index in list ] optional -- l: [ a reference to the list itself ] optional -- foldl :: (a -> b -> a) -> a -> [b] -> a on foldl(f, startValue, xs) tell mReturn(f) set v to startValue set lng to length of xs repeat with i from 1 to lng set v to \|λ\|(v, item i of xs, i, xs) end repeat return v end tell end foldl -- the arguments available to the called function f(a, x, i, l) are -- a: current accumulator value -- x: current item in list -- i: [ 1-based index in list ] optional -- l: [ a reference to the list itself ] optional -- foldr :: (a -> b -> a) -> a -> [b] -> a on foldr(f, startValue, xs) tell mReturn(f) set v to startValue set lng to length of xs repeat with i from lng to 1 by -1 set v to \|λ\|(v, item i of xs, i, xs) end repeat return v end tell end foldr --- OTHER FUNCTIONS DEFINED IN TERMS OF FOLDL AND FOLDR -- -- concat :: [String] -> string on concat(xs) foldl(my append, "", xs) end concat -- product :: Num a => [a] -> a on product(xs) script on \|λ\|(a, b) a * b end \|λ\| end script foldr(result, 1, xs) end product -- str :: a -> String on str(x) x as string end str -- sum :: Num a => [a] -> a on sum(xs) script on \|λ\|(a, b) a + b end \|λ\| end script foldl(result, 0, xs) end sum --------------------------- TEST ------------------------- on run set xs to {1, 2, 3, 4, 5, 6, 7, 8, 9, 10} {sum(xs), product(xs), concat(map(str, xs))} --> {55, 3628800, "10987654321"} end run -------------------- GENERIC FUNCTIONS ------------------- -- append :: String -> String -> String on append(a, b) a & b end append -- map :: (a -> b) -> [a] -> [b] on map(f, xs) -- The list obtained by applying f -- to each element of xs. tell mReturn(f) set lng to length of xs set lst to {} repeat with i from 1 to lng set end of lst to \|λ\|(item i of xs, i, xs) end repeat return lst end tell end map -- Lift 2nd class handler function into 1st class script wrapper -- mReturn :: Handler -> Script on mReturn(f) if class of f is script then f else script property \|λ\| : f end script end if end mReturn</syntaxhighlight> {{out}} <pre>{55, 3628800, "12345678910"}</pre> =={{header\|Arturo}}== ~~<lang rebol>; find the sum, with seed:0 (default)~~ <syntaxhighlight lang="rebol">; find the sum, with seed:0 (default) ~~print fold [1 2 3 4] => (+)~~ print fold [1 2 3 4] => add ; find the product, with seed:1 print fold [1 2 3 4] .seed:1 => ~~()~~mul</syntaxhighlight> ~~</lang>~~ {{out}} <pre>10 24</pre> =={{header\|BASIC}}== ==={{header\|BASIC256}}=== {{trans\|Run BASIC}} <syntaxhighlight lang="basic256">arraybase 1 global n dim n = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10} print " +: "; " "; cat(10, "+") print " -: "; " "; cat(10, "-") print " : "; " "; cat(10, "") print " /: "; " "; cat(10, "/") print " ^: "; " "; cat(10, "^") print "max: "; " "; cat(10, "max") print "min: "; " "; cat(10, "min") print "avg: "; " "; cat(10, "avg") print "cat: "; " "; cat(10, "cat") end function min(a, b) if a < b then return a else return b end function function max(a, b) if a > b then return a else return b end function function cat(cont, op$) temp = n[1] temp$ = "" for i = 2 to cont if op$ = "+" then temp += n[i] if op$ = "-" then temp -= n[i] if op$ = "" then temp = n[i] if op$ = "/" then temp /= n[i] if op$ = "^" then temp = temp ^ n[i] if op$ = "max" then temp = max(temp, n[i]) if op$ = "min" then temp = min(temp, n[i]) if op$ = "avg" then temp += n[i] if op$ = "cat" then temp$ += string(n[i]) next i if op$ = "avg" then temp /= cont if op$ = "cat" then temp = int(string(n[1]) + temp$) return temp end function</syntaxhighlight> ==={{header\|Chipmunk Basic}}=== {{trans\|Run BASIC}} {{works with\|Chipmunk Basic\|3.6.4}} <syntaxhighlight lang="qbasic">100 DIM n(10) 110 FOR i = 1 TO 10 : n(i) = i : NEXT i 120 SUB cat(cnt,op$) 130 temp = n(1) 140 FOR i = 2 TO cnt 150 IF op$ = "+" THEN temp = temp+n(i) 160 IF op$ = "-" THEN temp = temp-n(i) 170 IF op$ = "" THEN temp = tempn(i) 180 IF op$ = "/" THEN temp = temp/n(i) 190 IF op$ = "^" THEN temp = temp^n(i) 200 IF op$ = "max" THEN temp = FN MAX(temp,n(i)) 210 IF op$ = "min" THEN temp = FN MIN(temp,n(i)) 220 IF op$ = "avg" THEN temp = temp+n(i) 230 IF op$ = "cat" THEN temp$ = temp$+STR$(n(i)) 240 NEXT i 250 IF op$ = "avg" THEN temp = temp/cnt 260 IF op$ = "cat" THEN temp = VAL(STR$(n(1))+temp$) 270 cat = temp 280 END SUB 290 ' 300 PRINT " +: ";cat(10,"+") 310 PRINT " -: ";cat(10,"-") 320 PRINT " : ";cat(10,"") 330 PRINT " /: ";cat(10,"/") 340 PRINT " ^: ";cat(10,"^") 350 PRINT "min: ";cat(10,"min") 360 PRINT "max: ";cat(10,"max") 370 PRINT "avg: ";cat(10,"avg") 380 PRINT "cat: ";cat(10,"cat") 390 END</syntaxhighlight> ==={{header\|QBasic}}=== {{works with\|QBasic\|1.1}} {{trans\|Run BASIC}} <syntaxhighlight lang="qbasic">DIM SHARED n(10) FOR i = 1 TO 10: n(i) = i: NEXT i FUNCTION FNMIN (a, b) IF (a < b) THEN FNMIN = a ELSE FNMIN = b END FUNCTION FUNCTION FNMAX (a, b) IF (a < b) THEN FNMAX = b ELSE FNMAX = a END FUNCTION FUNCTION cat# (cont, op$) temp = n(1) FOR i = 2 TO cont IF op$ = "+" THEN temp = temp + n(i) IF op$ = "-" THEN temp = temp - n(i) IF op$ = "" THEN temp = temp * n(i) IF op$ = "/" THEN temp = temp / n(i) IF op$ = "^" THEN temp = temp ^ n(i) IF op$ = "max" THEN temp = FNMAX(temp, n(i)) IF op$ = "min" THEN temp = FNMIN(temp, n(i)) IF op$ = "avg" THEN temp = temp + n(i) NEXT i IF op$ = "avg" THEN temp = temp / cont cat = temp END FUNCTION PRINT " +: "; " "; cat(10, "+") PRINT " -: "; " "; cat(10, "-") PRINT " : "; " "; cat(10, "") PRINT " /: "; " "; cat(10, "/") PRINT " ^: "; " "; cat(10, "^") PRINT "min: "; " "; cat(10, "min") PRINT "max: "; " "; cat(10, "max") PRINT "avg: "; " "; cat(10, "avg")</syntaxhighlight> ==={{header\|True BASIC}}=== <syntaxhighlight lang="qbasic">SHARE n(10) FOR i = 1 to 10 LET n(i) = i NEXT i FUNCTION fnmin(a,b) IF (a < b) then LET fnmin = a else LET fnmin = b END FUNCTION FUNCTION fnmax(a,b) IF (a < b) then LET fnmax = b else LET fnmax = a END FUNCTION FUNCTION cat(cont, op$) LET temp = n(1) LET temp$ = "" FOR i = 2 TO cont IF op$ = "+" then LET temp = temp+n(i) IF op$ = "-" then LET temp = temp-n(i) IF op$ = "" then LET temp = tempn(i) IF op$ = "/" then LET temp = temp/n(i) IF op$ = "^" then LET temp = temp^n(i) IF op$ = "max" then LET temp = fnmax(temp,n(i)) IF op$ = "min" then LET temp = fnmin(temp,n(i)) IF op$ = "avg" then LET temp = temp+n(i) IF op$ = "cat" then LET temp$ = temp$ & str$(n(i)) NEXT i IF op$ = "avg" then LET temp = temp / cont END IF IF op$ = "cat" then LET t$ = str$(n(1)) & temp$ LET temp = VAL(t$) END IF LET cat = temp END FUNCTION PRINT " +: "; " "; cat(10, "+") PRINT " -: "; " "; cat(10, "-") PRINT " : "; " "; cat(10, "") PRINT " /: "; " "; cat(10, "/") PRINT " ^: "; " "; cat(10, "^") PRINT "min: "; " "; cat(10, "min") PRINT "max: "; " "; cat(10, "max") PRINT "avg: "; " "; cat(10, "avg") PRINT "cat: "; " "; cat(10, "cat") END</syntaxhighlight> ==={{header\|Yabasic}}=== {{trans\|Run BASIC}} <syntaxhighlight lang="freebasic">dim n(10) for i = 1 to 10 : n(i) = i : next i print " +: ", " ", cat(10, "+") print " -: ", " ", cat(10, "-") print " : ", " ", cat(10, "") print " /: ", " ", cat(10, "/") print " ^: ", " ", cat(10, "^") print "min: ", " ", cat(10, "min") print "max: ", " ", cat(10, "max") print "avg: ", " ", cat(10, "avg") end sub cat(cont,op$) cat = n(1) for i = 2 to cont if op$ = "+" cat = cat + n(i) if op$ = "-" cat = cat - n(i) if op$ = "" cat = cat n(i) if op$ = "/" cat = cat / n(i) if op$ = "^" cat = cat ^ n(i) if op$ = "max" cat = max(cat,n(i)) if op$ = "min" cat = min(cat,n(i)) if op$ = "avg" cat = cat + n(i) next i if op$ = "avg" cat = cat / cont return cat end sub</syntaxhighlight> =={{header\|BBC BASIC}}== <syntaxhighlight lang="bbcbasic"> DIM a(4) a() = 1, 2, 3, 4, 5 PRINT FNreduce(a(), "+") PRINT FNreduce(a(), "-") PRINT FNreduce(a(), "") END DEF FNreduce(arr(), op$) REM!Keep tmp, arr() LOCAL I%, tmp tmp = arr(0) FOR I% = 1 TO DIM(arr(), 1) tmp = EVAL("tmp " + op$ + " arr(I%)") NEXT = tmp </syntaxhighlight> {{out}} <pre> 15 -13 120</pre> =={{header\|BCPL}}== <syntaxhighlight lang="bcpl">get "libhdr" let reduce(f, v, len, seed) = len = 0 -> seed, reduce(f, v+1, len-1, f(!v, seed)) let start() be $( let add(x, y) = x+y let mul(x, y) = xy let nums = table 1,2,3,4,5,6,7 writef("%NN", reduce(add, nums, 7, 0)) writef("%NN", reduce(mul, nums, 7, 1)) $)</syntaxhighlight> {{out}} <pre>28 5040</pre> =={{header\|Binary Lambda Calculus}}== A minimal size (right) fold in lambda calculus is <code>fold = \f\z (let go = \l.l(\h\t\z.f h (go t))z in go)</code> which corresponds to the 69-bit BLC program <pre>000001000110100000010110000000010111111110111001011111101111101101110</pre> =={{header\|BQN}}== BQN has two different primitives for catamorphism: <ul> <li>Fold(<code>´</code>): Works on lists only.</li> <li>Insert(<code>˝</code>): Works on arrays with higher rank.</li> </ul> Both of these primitives take a dyadic function, and an optional initial element. <pre>•Show +´ 30‿1‿20‿2‿10 •Show +˝ 30‿1‿20‿2‿10 •Show tab ← (2+↕5) \|⌜ 9+↕3 •Show +˝ tab</pre> <pre>63 ┌· · 63 ┘ ┌─ ╵ 1 0 1 0 1 2 1 2 3 4 0 1 3 4 5 ┘ ⟨ 9 7 12 ⟩</pre> =={{header\|Bracmat}}== <syntaxhighlight lang="bracmat">( ( fold = f xs init first rest . !arg:(?f.?xs.?init) & ( !xs:&!init \| !xs:%?first ?rest & !f$(!first.fold$(!f.!rest.!init)) ) ) & out $ ( fold $ ( (=a b.!arg:(?a.?b)&!a+!b) . 1 2 3 4 5 . 0 ) ) & (product=a b.!arg:(?a.?b)&!a!b) & out$(fold$(product.1 2 3 4 5.1)) );</syntaxhighlight> Output: <pre>15 120</pre> =={{header\|C}}== <syntaxhighlight lang="c">#include <stdio.h> typedef int (intFn)(int, int); int reduce(intFn fn, int size, int elms) { int i, val = elms; for (i = 1; i < size; ++i) val = fn(val, elms[i]); return val; } int add(int a, int b) { return a + b; } int sub(int a, int b) { return a - b; } int mul(int a, int b) { return a * b; } int main(void) { int nums[] = {1, 2, 3, 4, 5}; printf("%d\n", reduce(add, 5, nums)); printf("%d\n", reduce(sub, 5, nums)); printf("%d\n", reduce(mul, 5, nums)); return 0; }</syntaxhighlight> {{out}} <pre>15 -13 120</pre> =={{header\|C sharp\|C#}}== <syntaxhighlight lang="csharp">var nums = Enumerable.Range(1, 10); int summation = nums.Aggregate((a, b) => a + b); int product = nums.Aggregate((a, b) => a * b); string concatenation = nums.Aggregate(String.Empty, (a, b) => a.ToString() + b.ToString()); Console.WriteLine("{0} {1} {2}", summation, product, concatenation);</syntaxhighlight> =={{header\|C++}}== <syntaxhighlight lang="cpp">#include <iostream> #include <numeric> #include <functional> #include <vector> int main() { std::vector<int> nums = { 1, 2, 3, 4, 5 }; auto nums_added = std::accumulate(std::begin(nums), std::end(nums), 0, std::plus<int>()); auto nums_other = std::accumulate(std::begin(nums), std::end(nums), 0, [](const int& a, const int& b) { return a + 2 * b; }); std::cout << "nums_added: " << nums_added << std::endl; std::cout << "nums_other: " << nums_other << std::endl; }</syntaxhighlight> {{out}} <pre>nums_added: 15 nums_other: 30</pre> =={{header\|Clojure}}== For more detail, check Rich Hickey's [http://clojure.com/blog/2012/05/08/reducers-a-library-and-model-for-collection-processing.html blog post on Reducers]. <syntaxhighlight lang="clojure">; Basic usage > (reduce * '(1 2 3 4 5)) 120 ; Using an initial value > (reduce + 100 '(1 2 3 4 5)) 115 </syntaxhighlight> =={{header\|CLU}}== <syntaxhighlight lang="clu">% Reduction. % First type = sequence type (must support S$elements and yield R) % Second type = right (input) datatype % Third type = left (output) datatype reduce = proc [S,R,L: type] (f: proctype (L,R) returns (L), id: L, seq: S) returns (L) where S has elements: itertype (S) yields (R) for elem: R in S$elements(seq) do id := f(id, elem) end return(id) end reduce % This is necessary to get rid of the exceptions add = proc (a,b: int) returns (int) return (a+b) end add mul = proc (a,b: int) returns (int) return (ab) end mul % Usage start_up = proc () % abbreviation - reducing int->int->int function over an array[int] int_reduce = reduce[array[int], int, int] po: stream := stream$primary_output() nums: array[int] := array[int]$[1,2,3,4,5,6,7,8,9,10] % find the sum and the product using reduce sum: int := int_reduce(add, 0, nums) product: int := int_reduce(mul, 1, nums) stream$putl(po, "The sum of [1..10] is: " \|\| int$unparse(sum)) stream$putl(po, "The product of [1..10] is: " \|\| int$unparse(product)) end start_up</syntaxhighlight> {{out}} <pre>The sum of [1..10] is: 55 The product of [1..10] is: 3628800</pre> =={{header\|Common Lisp}}== <syntaxhighlight lang="lisp">; Basic usage > (reduce #' '(1 2 3 4 5)) 120 ; Using an initial value > (reduce #'+ '(1 2 3 4 5) :initial-value 100) 115 ; Using only a subsequence > (reduce #'+ '(1 2 3 4 5) :start 1 :end 4) 9 ; Apply a function to each element first > (reduce #'+ '((a 1) (b 2) (c 3)) :key #'cadr) 6 ; Right-associative reduction > (reduce #'expt '(2 3 4) :from-end T) 2417851639229258349412352 ; Compare with > (reduce #'expt '(2 3 4)) 4096</syntaxhighlight> =={{header\|D}}== <syntaxhighlight lang="d">void main() { import std.stdio, std.algorithm, std.range, std.meta, std.numeric, std.conv, std.typecons; auto list = iota(1, 11); alias ops = AliasSeq!(q{a + b}, q{a * b}, min, max, gcd); foreach (op; ops) writeln(op.stringof, ": ", list.reduce!op); // std.algorithm.reduce supports multiple functions in parallel: reduce!(ops[0], ops[3], text)(tuple(0, 0.0, ""), list).writeln; }</syntaxhighlight> {{out}} <pre>"a + b": 55 "a * b": 3628800 min(T1,T2,T...) if (is(typeof(a < b))): 1 max(T1,T2,T...) if (is(typeof(a < b))): 10 gcd(T): 1 Tuple!(int,double,string)(55, 10, "12345678910")</pre> =={{header\|DCL}}== <syntaxhighlight lang="dcl">$ list = "1,2,3,4,5" $ call reduce list "+" $ show symbol result $ $ numbers = "5,4,3,2,1" $ call reduce numbers "-" $ show symbol result $ $ call reduce list "" $ show symbol result $ exit $ $ reduce: subroutine $ local_list = 'p1 $ value = f$integer( f$element( 0, ",", local_list )) $ i = 1 $ loop: $ element = f$element( i, ",", local_list ) $ if element .eqs. "," then $ goto done $ value = value 'p2 f$integer( element ) $ i = i + 1 $ goto loop $ done: $ result == value $ exit $ endsubroutine</syntaxhighlight> {{out}} <pre>$ @catamorphism RESULT == 15 Hex = 0000000F Octal = 00000000017 RESULT == -5 Hex = FFFFFFFB Octal = 37777777773 RESULT == 120 Hex = 00000078 Octal = 00000000170</pre> =={{header\|Delphi}}== See [https://rosettacode.org/wiki/Catamorphism#Pascal Pascal]. =={{header\|Déjà Vu}}== This is a foldl: <syntaxhighlight lang="dejavu">reduce f lst init: if lst: f reduce @f lst init pop-from lst else: init !. reduce @+ [ 1 10 200 ] 4 !. reduce @- [ 1 10 200 ] 4 </syntaxhighlight> {{out}} <pre>215 -207</pre> =={{header\|EchoLisp}}== <syntaxhighlight lang="scheme"> ;; rem : the foldX family always need an initial value ;; fold left a list (foldl + 0 (iota 10)) ;; 0 + 1 + .. + 9 → 45 ;; fold left a sequence (lib 'sequences) (foldl 1 [ 1 .. 10]) → 362880 ;; 10! ;; folding left and right (foldl / 1 ' ( 1 2 3 4)) → 8/3 (foldr / 1 '(1 2 3 4)) → 3/8 ;;scanl gives the list (or sequence) of intermediate values : (scanl * 1 '( 1 2 3 4 5)) → (1 1 2 6 24 120) </syntaxhighlight> =={{header\|Elena}}== ELENA 5.0 : <syntaxhighlight lang="elena">import system'collections; import system'routines; import extensions; import extensions'text; public program() { var numbers := new Range(1,10).summarize(new ArrayList()); var summary := numbers.accumulate(new Variable(0), (a,b => a + b)); var product := numbers.accumulate(new Variable(1), (a,b => a * b)); var concatenation := numbers.accumulate(new StringWriter(), (a,b => a.toPrintable() + b.toPrintable())); console.printLine(summary," ",product," ",concatenation) }</syntaxhighlight> {{out}} <pre> 55 362880 12345678910 </pre> =={{header\|Elixir}}== <syntaxhighlight lang="elixir">iex(1)> Enum.reduce(1..10, fn i,acc -> i+acc end) 55 iex(2)> Enum.reduce(1..10, fn i,acc -> iacc end) 3628800 iex(3)> Enum.reduce(10..-10, "", fn i,acc -> acc <> to_string(i) end) "109876543210-1-2-3-4-5-6-7-8-9-10"</syntaxhighlight> =={{header\|Erlang}}== {{trans\|Haskell}} <syntaxhighlight lang="erlang"> -module(catamorphism). -export([test/0]). test() -> Nums = lists:seq(1,10), Summation = lists:foldl(fun(X, Acc) -> X + Acc end, 0, Nums), Product = lists:foldl(fun(X, Acc) -> X Acc end, 1, Nums), Concatenation = lists:foldr( fun(X, Acc) -> integer_to_list(X) ++ Acc end, "", Nums), {Summation, Product, Concatenation}. </syntaxhighlight> Output: <pre> {55,3628800,"12345678910"} </pre> =={{header\|Excel}}== ===LAMBDA=== Excel provides a good number of standard catamorphisms like SUM, PRODUCT, LEN etc out of the box, but in recent builds of Excel we can write more general catamorphisms as LAMBDA expressions, and bind names to them in the WorkBook Name Manager. Excel's compound data type is a non-empty array, for which we could write, for example, specialised column or row instances of fold, whether rightward or leftward. Here is an example of binding the name FOLDLROW to a left fold over a row of Excel cells. As an example of a binary operator to fold, with an accumulator, over a series of character values, we can define a custom: '''updateBracketDepth(accumulator)(character)''' which: # Increments the nesting depth given a "[" character # reduces it given a "]" character # leaves the nesting depth unchanged for any other character # updates the accumulator no further if the nesting depth ever becomes negative. or for a simple bracket count, we could just define a: '''bracketCount(accumulator)(character)''' which: # Increments the integer accumulator value on each "[" or "]" # Leaves the accumulator unchanged for other characters. (See [https://www.microsoft.com/en-us/research/blog/lambda-the-ultimatae-excel-worksheet-function/ LAMBDA: The ultimate Excel worksheet function]) {{Works with\|Office 365 betas 2021}} <syntaxhighlight lang="lisp">FOLDROW =LAMBDA(op, LAMBDA(a, LAMBDA(xs, LET( b, op(a)(HEADROW(xs)), IF(1 < COLUMNS(xs), FOLDROW(op)(b)( TAILROW(xs) ), b ) ) ) ) ) updatedBracketDepth =LAMBDA(depth, LAMBDA(c, IF(0 <= depth, IF("[" = c, 1 + depth, IF("]" = c, depth - 1, depth ) ), depth ) ) ) bracketCount =LAMBDA(a, LAMBDA(c, IF(ISNUMBER(FIND(c, "[]", 1)), 1 + a, a ) ) ) HEADROW =LAMBDA(xs, LET(REM, "The first item of each row in xs", INDEX( xs, SEQUENCE(ROWS(xs)), SEQUENCE(1, 1) ) ) ) TAILROW =LAMBDA(xs, LET(REM,"The tail of each row in the grid", n, COLUMNS(xs) - 1, IF(0 < n, INDEX( xs, SEQUENCE(ROWS(xs), 1, 1, 1), SEQUENCE(1, n, 2, 1) ), NA() ) ) ) CHARSROW =LAMBDA(s, MID(s, SEQUENCE(1, LEN(s), 1, 1), 1 ) )</syntaxhighlight> {{Out}} {\| class="wikitable" \|- \|\|\|style="text-align:right; font-family:serif; font-style:italic; font-size:120%;"\|fx ! colspan="3" style="text-align:left; vertical-align: bottom; font-family:Arial, Helvetica, sans-serif !important;"\|=FOLDROW( updatedBracketDepth )( 0 )( CHARSROW(C2) ) \|- style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff;" \| \| A \| B \| C \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 1 \| \| style="font-weight:bold" \| Final bracket nesting depth \| style="font-weight:bold" \| Sample string \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 2 \| \| style="text-align:center; background-color:#cbcefb" \| 0 \| [simply bracketed] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 3 \| \| style="text-align:center" \| 1 \| [[ ] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 4 \| \| style="text-align:center" \| -1 \| [ ]] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 5 \| \| style="text-align:center" \| 0 \| [[[ [] ]]] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 6 \| \| style="text-align:center" \| 0 \| [ [[[ [] ]]] [[[ ]]] [[[ [] ]]] ] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 7 \| \| style="text-align:center" \| 1 \| [ [[[ [ ]]] [[[ ]]] [[[ [] ]]] ] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 8 \| \| style="text-align:center" \| -1 \| ][ [[[ [ ]]] [[[ ]]] [[[ [] ]]] ] \|} Or for a simple count of bracket characters, ignoring other characters: {\| class="wikitable" \|- \|\|\|style="text-align:right; font-family:serif; font-style:italic; font-size:120%;"\|fx ! colspan="3" style="text-align:left; vertical-align: bottom; font-family:Arial, Helvetica, sans-serif !important;"\|=FOLDROW( bracketCount )( 0 )( CHARSROW(C2) ) \|- style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff;" \| \| A \| B \| C \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 1 \| \| style="font-weight:bold" \| Bracket character count \| style="font-weight:bold" \| Sample string \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 2 \| \| style="text-align:center; background-color:#cbcefb" \| 2 \| [simply bracketed] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 3 \| \| style="text-align:center" \| 3 \| [[ ] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 4 \| \| style="text-align:center" \| 3 \| [ ]] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 5 \| \| style="text-align:center" \| 8 \| [[[ [] ]]] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 6 \| \| style="text-align:center" \| 24 \| [ [[[ [] ]]] [[[ ]]] [[[ [] ]]] ] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 7 \| \| style="text-align:center" \| 23 \| [ [[[ [ ]]] [[[ ]]] [[[ [] ]]] ] \|- \| style="text-align:center; font-family:Arial, Helvetica, sans-serif !important; background-color:#000000; color:#ffffff" \| 8 \| \| style="text-align:center" \| 24 \| ][ [[[ [ ]]] [[[ ]]] [[[ [] ]]] ] \|} =={{header\|F_Sharp\|F#}}== <p>In the REPL:</p> <pre> > let nums = [1 .. 10];; val nums : int list = [1; 2; 3; 4; 5; 6; 7; 8; 9; 10] > let summation = List.fold (+) 0 nums;; val summation : int = 55 > let product = List.fold () 1 nums;; val product : int = 3628800 > let concatenation = List.foldBack (fun x y -> x + y) (List.map (fun i -> i.ToString()) nums) "";; val concatenation : string = "12345678910" </pre> =={{header\|Factor}}== <syntaxhighlight lang="factor">{ 1 2 4 6 10 } 0 [ + ] reduce .</syntaxhighlight> {{out}} <pre> 23 </pre> =={{header\|Forth}}== Forth has three traditions for iterating over the members of a data structure. Under the first, the data structure has words that help you navigate over it and normal Forth looping structures are used. Under the second, the data structure has dedicated looping words and you supply the code that's run for each member. Under the third, the data structure has a loop-over-members word that accepts a function to be run against each member. There's no need to distinguish between the different kinds of looping ("this one collects function returns into a list; this one threads an accumulator between the function-calls; this one threads two accumulators through the function-calls; this one expects no return values whatsoever from the function-calls") because in Forth all that the looping words have to do is make the data stack available for the function's use. When that's the case, all of these variations, that are so important in other languages, are functionally equivalent. Although it's possible to have a generic higher-order word that can operate under all kinds of data structures -- this just requires that one settle on an object system and then derive a collections library from it -- this is rarely done. Typically each data structure has its own looping words. To demonstrate the above points we'll just loop over the bytes of a string. Some helper words for these examples: <syntaxhighlight lang="forth">: lowercase? ( c -- f ) [char] a [ char z 1+ ] literal within ; : char-upcase ( c -- C ) dup lowercase? if bl xor then ;</syntaxhighlight> Using normal looping words: <syntaxhighlight lang="forth">: string-at ( c-addr u +n -- c ) nip + c@ ; : string-at! ( c-addr u +n c -- ) rot drop -rot + c! ; : type-lowercase ( c-addr u -- ) dup 0 ?do 2dup i string-at dup lowercase? if emit else drop then loop 2drop ; : upcase ( 'string' -- 'STRING' ) dup 0 ?do 2dup 2dup i string-at char-upcase i swap string-at! loop ; : count-lowercase ( c-addr u -- n ) 0 -rot dup 0 ?do 2dup i string-at lowercase? if rot 1+ -rot then loop 2drop ;</syntaxhighlight> Briefly, a variation: <syntaxhighlight lang="forth">: next-char ( a +n -- a' n' c -1 ) ( a 0 -- 0 ) dup if 2dup 1 /string 2swap drop c@ true else 2drop 0 then ; : type-lowercase ( c-addr u -- ) begin next-char while dup lowercase? if emit else drop then repeat ;</syntaxhighlight> Using dedicated looping words: <syntaxhighlight lang="forth">: each-char[ ( c-addr u -- ) postpone BOUNDS postpone ?DO postpone I postpone C@ ; immediate \ interim code: ( c -- ) : ]each-char ( -- ) postpone LOOP ; immediate : type-lowercase ( c-addr u -- ) each-char[ dup lowercase? if emit else drop then ]each-char ; : upcase ( 'string' -- 'STRING' ) 2dup each-char[ char-upcase i c! ]each-char ; : count-lowercase ( c-addr u -- n ) 0 -rot each-char[ lowercase? if 1+ then ]each-char ;</syntaxhighlight> Using higher-order words: <syntaxhighlight lang="forth">: each-char ( c-addr u xt -- ) {: xt :} bounds ?do i c@ xt execute loop ; : type-lowercase ( c-addr u -- ) [: dup lowercase? if emit else drop then ;] each-char ; \ producing a new string : upcase ( 'string' -- 'STRING' ) dup cell+ allocate throw -rot [: ( new-string-addr c -- new-string-addr ) upcase over c+! ;] each-char $@ ; : count-lowercase ( c-addr u -- n ) 0 -rot [: lowercase? if 1+ then ;] each-char ;</syntaxhighlight> In these examples COUNT-LOWERCASE updates an accumulator, UPCASE (mostly) modifies the string in-place, and TYPE-LOWERCASE performs side-effects and returns nothing to the higher-order word. =={{header\|Fortran}}== If Fortran were to offer the ability to pass a parameter "by name", as is used in [[Jensen's_Device#Fortran\|Jensen's device]], then the code might be something like <syntaxhighlight lang="fortran"> SUBROUTINE FOLD(t,F,i,ist,lst) INTEGER t BYNAME F DO i = ist,lst t = F END DO END SUBROUTINE FOLD !Result in temp. temp = a(1); CALL FOLD(temp,tempa(i),i,2,N)</syntaxhighlight> Here, the function manifests as the expression that is the second parameter of subroutine FOLD, and the "by name" protocol for parameter F means that within the subroutine whenever there is a reference to F, its value is evaluated afresh in the caller's environment using the current values of ''temp'' and ''i'' as modified by the subroutine - they being passed by reference so that changes within the subroutine affect the originals. An evaluation for a different function requires merely another statement with a different expression. Fortran however does not provide such a facility. Any parameter that is an expression is evaluated once in the caller's environment, the result placed in temporary storage, and the address of that storage location is passed to the subroutine. Repeated references to that parameter will elicit the same value. But there is special provision for passing a function to a routine, involving the special word EXTERNAL. For every different function in mind, one must diligently supply a name, and work through the overhead of declaring each such function. There is an additional word, INTRINSIC, for use when an intrinsic function (such as SIN) is to be passed as such a parameter since it will appear as its name only, and with the absence of the (...) that would be used for the function's parameters when in an arithmetic expression, it would otherwise be taken as being the name of an ordinary variable. Here is such an arrangement, in the style of F77 though somewhat affected by F90 in that the END statement names the routine being ended. Similarly, to abate petty complaints about the types of the functions being undeclared, explicit types are specified, though unselecting the compiler diagnostic for that would match the habits of earlier compilers. Also in F90 is the MODULE protocol which involves rather more organised checking of types and additional facilities for arrays [[Array_length#Fortran\|so that N need not be passed]] because secret additional parameters do so. However, only programmer diligence in devising functions with the correct type of result and the correct type and number of parameters will evade mishaps. Note that the EXTERNAL statement does not specify the number or type of parameters. If the function is invoked multiple times within a subroutine, the compiler may check for consistency. This may cause trouble when [[Leonardo_numbers#Fortran\|some parameters are optional]] so that different invocations do not match. The function's name is used as a working variable within the function (as well as it holding the function's value on exit) so that the expression <code>F(IFOLD,A(I))</code> is ''not'' a recursive invocation of function <code>IFOLD</code> because there are no (parameters) appended to the function's name. Earlier compilers did not allow such usage so that a separate working variable would be required. <syntaxhighlight lang="fortran"> INTEGER FUNCTION IFOLD(F,A,N) !"Catamorphism"... INTEGER F !We're working only with integers. EXTERNAL F !This is a function, not an array. INTEGER A() !An 1-D array, of unspecified size. INTEGER N !The number of elements. INTEGER I !A stepper. IFOLD = 0 !A default value. IF (N.LE.0) RETURN !Dodge silly invocations. IFOLD = A(1) !The function is to have two arguments. IF (N.EQ.1) RETURN !So, if there is only one element, silly. DO I = 2,N !Otherwise, stutter along the array. IFOLD = F(IFOLD,A(I)) !Applying the function. END DO !On to the next element. END FUNCTION IFOLD!Thus, F(A(1),A(2)), or F(F(A(1),A(2)),A(3)), or F(F(F(A(1),A(2)),A(3)),A(4)), etc. INTEGER FUNCTION IADD(I,J) INTEGER I,J IADD = I + J END FUNCTION IADD INTEGER FUNCTION IMUL(I,J) INTEGER I,J IMUL = IJ END FUNCTION IMUL INTEGER FUNCTION IDIV(I,J) INTEGER I,J IDIV = I/J END FUNCTION IDIV INTEGER FUNCTION IVID(I,J) INTEGER I,J IVID = J/I END FUNCTION IVID PROGRAM POKE INTEGER ENUFF PARAMETER (ENUFF = 6) INTEGER A(ENUFF) PARAMETER (A = (/1,2,3,4,5,6/)) INTEGER MSG EXTERNAL IADD,IMUL,IDIV,IVID !Warn that these are the names of functions. MSG = 6 !Standard output. WRITE (MSG,1) ENUFF,A 1 FORMAT ('To apply a function in the "catamorphic" style ', 1 "to the ",I0," values ",/,(20I3)) WRITE (MSG,) "Iadd",IFOLD(IADD,A,ENUFF) WRITE (MSG,) "Imul",IFOLD(IMUL,A,ENUFF) WRITE (MSG,) "Idiv",IFOLD(IDIV,A,ENUFF) WRITE (MSG,) "Ivid",IFOLD(IVID,A,ENUFF) END PROGRAM POKE </syntaxhighlight> Output: <pre> To apply a function in the "catamorphic" style to the 6 values 1 2 3 4 5 6 Iadd 21 Imul 720 Idiv 0 Ivid 6 </pre> =={{header\|FreeBASIC}}== <syntaxhighlight lang="freebasic">' FB 1.05.0 Win64 Type IntFunc As Function(As Integer, As Integer) As Integer Function reduce(a() As Integer, f As IntFunc) As Integer '' if array is empty or function pointer is null, return 0 say If UBound(a) = -1 OrElse f = 0 Then Return 0 Dim result As Integer = a(LBound(a)) For i As Integer = LBound(a) + 1 To UBound(a) result = f(result, a(i)) Next Return result End Function Function add(x As Integer, y As Integer) As Integer Return x + y End Function Function subtract(x As Integer, y As Integer) As Integer Return x - y End Function Function multiply(x As Integer, y As Integer) As Integer Return x * y End Function Function max(x As Integer, y As Integer) As Integer Return IIf(x > y, x, y) End Function Function min(x As Integer, y As Integer) As Integer Return IIf(x < y, x, y) End Function Dim a(4) As Integer = {1, 2, 3, 4, 5} Print "Sum is :"; reduce(a(), @add) Print "Difference is :"; reduce(a(), @subtract) Print "Product is :"; reduce(a(), @multiply) Print "Maximum is :"; reduce(a(), @max) Print "Minimum is :"; reduce(a(), @min) Print "No op is :"; reduce(a(), 0) Print Print "Press any key to quit" Sleep </syntaxhighlight> {{out}} <pre> Sum is : 15 Difference is :-13 Product is : 120 Maximum is : 5 Minimum is : 1 No op is : 0 </pre> =={{header\|Go}}== <syntaxhighlight lang="go">package main import ( "fmt" ) func main() { n := []int{1, 2, 3, 4, 5} fmt.Println(reduce(add, n)) fmt.Println(reduce(sub, n)) fmt.Println(reduce(mul, n)) } func add(a int, b int) int { return a + b } func sub(a int, b int) int { return a - b } func mul(a int, b int) int { return a * b } func reduce(rf func(int, int) int, m []int) int { r := m[0] for _, v := range m[1:] { r = rf(r, v) } return r }</syntaxhighlight> {{out}} <pre> 15 -13 120 </pre> =={{header\|Groovy}}== Groovy provides an "inject" method for all aggregate classes that performs a classic tail-recursive reduction, driven by a closure argument. The result of each iteration (closure invocation) is used as the accumulated valued for the next iteration. If a first argument is provided as well as a second closure argument, that first argument is used as a seed accumulator for the first iteration. Otherwise, the first element of the aggregate is used as the seed accumulator, with reduction iteration proceeding across elements 2 through n. <syntaxhighlight lang="groovy">def vector1 = [1,2,3,4,5,6,7] def vector2 = [7,6,5,4,3,2,1] def map1 = [a:1, b:2, c:3, d:4] println vector1.inject { acc, val -> acc + val } // sum println vector1.inject { acc, val -> acc + valval } // sum of squares println vector1.inject { acc, val -> acc val } // product println vector1.inject { acc, val -> acc<val?val:acc } // max println ([vector1,vector2].transpose().inject(0) { acc, val -> acc + val[0]val[1] }) //dot product (with seed 0) println (map1.inject { Map.Entry accEntry, Map.Entry entry -> // some sort of weird map-based reduction [(accEntry.key + entry.key):accEntry.value + entry.value ].entrySet().toList().pop() })</syntaxhighlight> {{out}} <pre>28 140 5040 7 84 abcd=10</pre> =={{header\|Haskell}}== <syntaxhighlight lang="haskell">main :: IO () main = putStrLn . unlines $ [ show . foldr (+) 0 -- sum , show . foldr () 1 -- product , foldr ((++) . show) "" -- concatenation ] <> [[1 .. 10]]</syntaxhighlight> {{Out}} <pre>55 3628800 12345678910</pre> and the generality of folds is such that if we replace all three of these (function, identity) combinations ((+), 0), ((), 1) ((++), "") with the Monoid operation '''mappend''' (<>) and identity '''mempty''', we can still obtain the same results: <syntaxhighlight lang="haskell">import Data.Monoid main :: IO () main = let xs = [1 .. 10] in (putStrLn . unlines) [ (show . getSum . foldr (<>) mempty) (Sum <$> xs) , (show . getProduct . foldr (<>) mempty) (Product <$> xs) , (show . foldr (<>) mempty) (show <$> xs) , (show . foldr (<>) mempty) (words "Love is one damned thing after each other") ]</syntaxhighlight> {{Out}} <pre>55 3628800 "12345678910" "Loveisonedamnedthingaftereachother"</pre> Also available are ''foldl1'' and ''foldr1'' which implicitly take first element as starting value. However they are not safe as they fail on empty lists. ''Prelude'' folds work only on lists, module ''Data.Foldable'' a typeclass for more general fold - interface remains the same. =={{header\|Icon}} and {{header\|Unicon}}== Works in both languages: <syntaxhighlight lang="unicon">procedure main(A) write(A[1],": ",curry(A[1],A[2:0])) end procedure curry(f,A) r := A[1] every r := f(r, !A[2:0]) return r end</syntaxhighlight> Sample runs: <pre> ->cata + 3 1 4 1 5 9 +: 23 ->cata - 3 1 4 1 5 9 -: -17 ->cata \* 3 1 4 1 5 9 : 540 ->cata "\|\|" 3 1 4 1 5 9 \|\|: 314159 </pre> =={{header\|J}}== '''Solution''':<syntaxhighlight lang="j"> /</syntaxhighlight> '''Example''':<syntaxhighlight lang="j"> +/ 1 2 3 4 5 15 / 1 2 3 4 5 120 !/ 1 2 3 4 5 NB. "n ! k" is "n choose k" 45</syntaxhighlight> Insert * into 1 2 3 4 5 becomes 1 * 2 * 3 * 4 * 5 evaluated right to left<syntaxhighlight lang="j"> 1 * 2 * 3 * 20 1 * 2 * 60 1 * 120 120 </syntaxhighlight> What are the implications for -/ ? For %/ ? =={{header\|Java}}== {{works with\|Java\|8}} <syntaxhighlight lang="java">import java.util.stream.Stream; public class ReduceTask { public static void main(String[] args) { System.out.println(Stream.of(1, 2, 3, 4, 5).mapToInt(i -> i).sum()); System.out.println(Stream.of(1, 2, 3, 4, 5).reduce(1, (a, b) -> a * b)); } }</syntaxhighlight> {{out}} <pre>15 120</pre> =={{header\|JavaScript}}== ===ES5=== <syntaxhighlight lang="javascript">var nums = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10]; function add(a, b) { return a + b; } var summation = nums.reduce(add); function mul(a, b) { return a * b; } var product = nums.reduce(mul, 1); var concatenation = nums.reduce(add, ""); console.log(summation, product, concatenation);</syntaxhighlight> Note that the JavaScript Array methods include a right fold ( '''.reduceRight()''' ) as well as a left fold: <syntaxhighlight lang="javascript">(function (xs) { 'use strict'; // foldl :: (b -> a -> b) -> b -> [a] -> b function foldl(f, acc, xs) { return xs.reduce(f, acc); } // foldr :: (b -> a -> b) -> b -> [a] -> b function foldr(f, acc, xs) { return xs.reduceRight(f, acc); } // Test folds in both directions return [foldl, foldr].map(function (f) { return f(function (acc, x) { return acc + (x * 2).toString() + ' '; }, [], xs); }); })([0, 1, 2, 3, 4, 5, 6, 7, 8, 9]);</syntaxhighlight> {{Out}} <pre>["0 2 4 6 8 10 12 14 16 18 ", "18 16 14 12 10 8 6 4 2 0 "]</pre> ===ES6=== <syntaxhighlight lang="javascript">var nums = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10]; console.log(nums.reduce((a, b) => a + b, 0)); // sum of 1..10 console.log(nums.reduce((a, b) => a * b, 1)); // product of 1..10 console.log(nums.reduce((a, b) => a + b, '')); // concatenation of 1..10</syntaxhighlight> =={{header\|jq}}== jq has an unusual and unusually powerful "reduce" control structure. A full description is beyond the scope of this short article, but an important point is that "reduce" is stream-oriented. Reduction of arrays is however trivially achieved using the ".[]" filter for converting an array to a stream of its values. The simplest use of "reduce" can be illustrated by this definition of "factorial": def factorial: reduce range(2;.+1) as $i (1; . * $i); If the input is a non-negative integer, n, this will compute n!. To understand how this works, consider "3\|factorial". The computation starts by setting the implicit state variable to 1; range(2;4) will generate the sequence of values (2,3). The variable $i is set to each value in the stream in turn so that the state variable is multiplied by 2 (". * $i") and then by 3. Notice that since range/2 produces a stream, no array is ever constructed. For a more complex illustration, see [[Sorting_algorithms/Strand_sort#jq\|Strand sort]]. The "reduce" operator is typically used within a map/reduce framework, but the implicit state variable can be any JSON entity, and so "reduce" is also a general-purpose iterative control structure, the only limitation being that it does not have the equivalent of "break". For that, the "foreach" control structure in recent versions of jq can be used. =={{header\|Julia}}== {{Works with\|Julia 1.2}} <syntaxhighlight lang="julia">println([reduce(op, 1:5) for op in [+, -, ]]) println([foldl(op, 1:5) for op in [+, -, ]]) println([foldr(op, 1:5) for op in [+, -, ]])</syntaxhighlight> {{out}} <pre>[15, -13, 120] [15, -13, 120] [15, 3, 120]</pre> =={{header\|Kotlin}}== <syntaxhighlight lang="scala">fun main(args: Array<String>) { val a = intArrayOf(1, 2, 3, 4, 5) println("Array : ${a.joinToString(", ")}") println("Sum : ${a.reduce { x, y -> x + y }}") println("Difference : ${a.reduce { x, y -> x - y }}") println("Product : ${a.reduce { x, y -> x y }}") println("Minimum : ${a.reduce { x, y -> if (x < y) x else y }}") println("Maximum : ${a.reduce { x, y -> if (x > y) x else y }}") }</syntaxhighlight> {{out}} <pre> Array : 1, 2, 3, 4, 5 Sum : 15 Difference : -13 Product : 120 Minimum : 1 Maximum : 5 </pre> =={{header\|Lambdatalk}}== <syntaxhighlight lang="scheme"> {def nums 1 2 3 4 5} -> nums {S.reduce {lambda {:a :b} {+ :a :b}} {nums}} -> 15 {S.reduce {lambda {:a :b} {- :a :b}} {nums}} -> -13 {S.reduce {lambda {:a :b} {* :a :b}} {nums}} -> 120 {S.reduce min {nums}} -> 1 {S.reduce max {nums}} -> 5 </syntaxhighlight> =={{header\|Logtalk}}== The Logtalk standard library provides implementations of common meta-predicates such as fold left. The example that follow uses Logtalk's native support for lambda expressions to avoid the need for auxiliary predicates. <syntaxhighlight lang="logtalk"> :- object(folding_examples). :- public(show/0). show :- integer::sequence(1, 10, List), write('List: '), write(List), nl, meta::fold_left([Acc,N,Sum0]>>(Sum0 is Acc+N), 0, List, Sum), write('Sum of all elements: '), write(Sum), nl, meta::fold_left([Acc,N,Product0]>>(Product0 is AccN), 1, List, Product), write('Product of all elements: '), write(Product), nl, meta::fold_left([Acc,N,Concat0]>>(number_codes(N,NC), atom_codes(NA,NC), atom_concat(Acc,NA,Concat0)), '', List, Concat), write('Concatenation of all elements: '), write(Concat), nl. :- end_object. </syntaxhighlight> {{out}} <pre> \| ?- folding_examples::show. List: [1,2,3,4,5,6,7,8,9,10] Sum of all elements: 55 Product of all elements: 3628800 Concatenation of all elements: 12345678910 yes </pre> =={{header\|LOLCODE}}== {{trans\|C}} <syntaxhighlight lang="lolcode">HAI 1.3 HOW IZ I reducin YR array AN YR size AN YR fn I HAS A val ITZ array'Z SRS 0 IM IN YR loop UPPIN YR i TIL BOTH SAEM i AN DIFF OF size AN 1 val R I IZ fn YR val AN YR array'Z SRS SUM OF i AN 1 MKAY IM OUTTA YR loop FOUND YR val IF U SAY SO O HAI IM array I HAS A SRS 0 ITZ 1 I HAS A SRS 1 ITZ 2 I HAS A SRS 2 ITZ 3 I HAS A SRS 3 ITZ 4 I HAS A SRS 4 ITZ 5 KTHX HOW IZ I add YR a AN YR b, FOUND YR SUM OF a AN b, IF U SAY SO HOW IZ I sub YR a AN YR b, FOUND YR DIFF OF a AN b, IF U SAY SO HOW IZ I mul YR a AN YR b, FOUND YR PRODUKT OF a AN b, IF U SAY SO VISIBLE I IZ reducin YR array AN YR 5 AN YR add MKAY VISIBLE I IZ reducin YR array AN YR 5 AN YR sub MKAY VISIBLE I IZ reducin YR array AN YR 5 AN YR mul MKAY KTHXBYE</syntaxhighlight> {{out}} <pre>15 -13 120</pre> =={{header\|Lua}}== <syntaxhighlight lang="lua"> table.unpack = table.unpack or unpack -- 5.1 compatibility local nums = {1,2,3,4,5,6,7,8,9} function add(a,b) return a+b end function mult(a,b) return ab end function cat(a,b) return tostring(a)..tostring(b) end local function reduce(fun,a,b,...) if ... then return reduce(fun,fun(a,b),...) else return fun(a,b) end end local arithmetic_sum = function (...) return reduce(add,...) end local factorial5 = reduce(mult,5,4,3,2,1) print("Σ(1..9) : ",arithmetic_sum(table.unpack(nums))) print("5! : ",factorial5) print("cat {1..9}: ",reduce(cat,table.unpack(nums))) </syntaxhighlight> {{out}} <pre> Σ(1..9) : 45 5! : 120 cat {1..9}: 123456789 </pre> =={{header\|M2000 Interpreter}}== <syntaxhighlight lang="m2000 interpreter"> Module CheckIt { Function Reduce (a, f) { if len(a)=0 then Error "Nothing to reduce" if len(a)=1 then =Array(a) : Exit k=each(a, 2, -1) m=Array(a) While k { m=f(m, array(k)) } =m } a=(1, 2, 3, 4, 5) Print "Array", a Print "Sum", Reduce(a, lambda (x,y)->x+y) Print "Difference", Reduce(a, lambda (x,y)->x-y) Print "Product", Reduce(a, lambda (x,y)->xy) Print "Minimum", Reduce(a, lambda (x,y)->if(x<y->x, y)) Print "Maximum", Reduce(a, lambda (x,y)->if(x>y->x, y)) } CheckIt </syntaxhighlight> {{out}} <pre> Array 1 2 3 4 5 Sum 15 Difference -13 Product 120 Minimum 1 Maximum 5 </pre> =={{header\|Maple}}== The left fold operator in Maple is foldl, and foldr is the right fold operator. <syntaxhighlight lang="maple">> nums := seq( 1 .. 10 ); nums := 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 > foldl( `+`, 0, nums ); # compute sum using foldl 55 > foldr( ``, 1, nums ); # compute product using foldr 3628800</syntaxhighlight> Compute the horner form of a (sorted) polynomial: <syntaxhighlight lang="maple">> foldl( (a,b) ->aT+b, op(map2(op,1,[op( 72T^5+37T^4-23T^3+87T^2+44T+29 )]))); ((((72 T + 37) T - 23) T + 87) T + 44) T + 29</syntaxhighlight> =={{header\|Mathematica}} / {{header\|Wolfram Language}}== <syntaxhighlight lang="mathematica">Fold[f, x, {a, b, c, d}]</syntaxhighlight> {{Out}} <pre>f[f[f[f[x, a], b], c], d]</pre> =={{header\|Maxima}}== <syntaxhighlight lang="maxima">lreduce(f, [a, b, c, d], x0); /* (%o1) f(f(f(f(x0, a), b), c), d) /</syntaxhighlight> <syntaxhighlight lang="maxima">lreduce("+", [1, 2, 3, 4], 100); / (%o1) 110 /</syntaxhighlight> =={{header\|min}}== {{works with\|min\|0.19.3}} <syntaxhighlight lang="min">(1 2 3 4) 0 '+ reduce puts! ; sum (1 2 3 4) 1 ' reduce puts! ; product</syntaxhighlight> {{out}} <pre> 10 24 </pre> =={{header\|Modula-2}}== <syntaxhighlight lang="modula2">MODULE Catamorphism; FROM InOut IMPORT WriteString, WriteCard, WriteLn; (* Alas, there are no generic types. This function works for CARDINAL only - you would have to copy it and change the types to reduce functions of other types. ) TYPE Reduction = PROCEDURE (CARDINAL, CARDINAL): CARDINAL; PROCEDURE reduce(func: Reduction; arr: ARRAY OF CARDINAL; first: CARDINAL): CARDINAL; VAR i: CARDINAL; BEGIN FOR i := 0 TO HIGH(arr) DO first := func(first, arr[i]); END; RETURN first; END reduce; ( Demonstration ) PROCEDURE add(a,b: CARDINAL): CARDINAL; BEGIN RETURN a+b; END add; PROCEDURE mul(a,b: CARDINAL): CARDINAL; BEGIN RETURN ab; END mul; PROCEDURE Demonstration; VAR a: ARRAY [1..5] OF CARDINAL; i: CARDINAL; BEGIN FOR i := 1 TO 5 DO a[i] := i; END; WriteString("Sum of [1..5]: "); WriteCard(reduce(add, a, 0), 3); WriteLn; WriteString("Product of [1..5]: "); WriteCard(reduce(mul, a, 1), 3); WriteLn; END Demonstration; BEGIN Demonstration; END Catamorphism.</syntaxhighlight> {{out}} <pre>Sum of [1..5]: 15 Product of [1..5]: 120</pre> =={{header\|Nemerle}}== The <tt>Nemerle.Collections</tt> namespace defines <tt>FoldLeft</tt>, <tt>FoldRight</tt> and <tt>Fold</tt> (an alias for <tt>FoldLeft</tt>) on any sequence that implements the <tt>IEnumerable[T]</tt> interface. <syntaxhighlight lang="nemerle">def seq = [1, 4, 6, 3, 7]; def sum = seq.Fold(0, _ + _); // Fold takes an initial value and a function, here the + operator</syntaxhighlight> =={{header\|Nim}}== <syntaxhighlight lang="nim">import sequtils block: let numbers = @[5, 9, 11] addition = foldl(numbers, a + b) substraction = foldl(numbers, a - b) multiplication = foldl(numbers, a * b) words = @["nim", "is", "cool"] concatenation = foldl(words, a & b) block: let numbers = @[5, 9, 11] addition = foldr(numbers, a + b) substraction = foldr(numbers, a - b) multiplication = foldr(numbers, a * b) words = @["nim", "is", "cool"] concatenation = foldr(words, a & b)</syntaxhighlight> =={{header\|Oberon-2}}== {{Works with\| oo2c Version 2}} <syntaxhighlight lang="oberon2"> MODULE Catamorphism; IMPORT Object, NPCT:Tools, NPCT:Args, IntStr, Out; TYPE BinaryFunc= PROCEDURE (x,y: LONGINT): LONGINT; VAR data: POINTER TO ARRAY OF LONGINT; i: LONGINT; PROCEDURE Sum(x,y: LONGINT): LONGINT; BEGIN RETURN x + y END Sum; PROCEDURE Sub(x,y: LONGINT): LONGINT; BEGIN RETURN x - y; END Sub; PROCEDURE Mul(x,y: LONGINT): LONGINT; BEGIN RETURN x * y; END Mul; PROCEDURE Reduce(x: ARRAY OF LONGINT; f: BinaryFunc): LONGINT; VAR i,res: LONGINT; BEGIN res := x[0];i := 1; WHILE (i < LEN(x)) DO; res := f(res,x[i]); INC(i) END; RETURN res END Reduce; PROCEDURE InitData(VAR x: ARRAY OF LONGINT); VAR i, j: LONGINT; res: IntStr.ConvResults; aux: Object.CharsLatin1; BEGIN i := 0;j := 1; WHILE (j <= LEN(x)) DO aux := Tools.AsString(Args.Get(j)); IntStr.StrToInt(aux^,x[i],res); IF res # IntStr.strAllRight THEN Out.String("Incorrect format for data at index ");Out.LongInt(j,0);Out.Ln; HALT(1); END; INC(j);INC(i) END END InitData; BEGIN IF Args.Number() = 1 THEN Out.String("Invalid number of arguments. ");Out.Ln; HALT(0) ELSE NEW(data,Args.Number() - 1); InitData(data^); Out.LongInt(Reduce(data^,Sum),0);Out.Ln; Out.LongInt(Reduce(data^,Sub),0);Out.Ln; Out.LongInt(Reduce(data^,Mul),0);Out.Ln END END Catamorphism. </syntaxhighlight> {{out}} <pre> 1 -11 -14400 </pre> =={{header\|Objeck}}== <syntaxhighlight lang="objeck"> use Collection; class Reducer { function : Main(args : String[]) ~ Nil { values := IntVector->New([1, 2, 3, 4, 5]); values->Reduce(Add(Int, Int) ~ Int)->PrintLine(); values->Reduce(Mul(Int, Int) ~ Int)->PrintLine(); } function : Add(a : Int, b : Int) ~ Int { return a + b; } function : Mul(a : Int, b : Int) ~ Int { return a * b; } }</syntaxhighlight> Output <pre> 15 120 </pre> =={{header\|OCaml}}== <syntaxhighlight lang="ocaml"># let nums = [1;2;3;4;5;6;7;8;9;10];; val nums : int list = [1; 2; 3; 4; 5; 6; 7; 8; 9; 10] # let sum = List.fold_left (+) 0 nums;; val sum : int = 55 # let product = List.fold_left ( * ) 1 nums;; val product : int = 3628800</syntaxhighlight> =={{header\|Oforth}}== reduce is already defined into Collection class : <syntaxhighlight lang="oforth">[ 1, 2, 3, 4, 5 ] reduce(#max) [ "abc", "def", "gfi" ] reduce(#+)</syntaxhighlight> =={{header\|PARI/GP}}== <syntaxhighlight lang="parigp">reduce(f, v)={ my(t=v[1]); for(i=2,#v,t=f(t,v[i])); t }; reduce((a,b)->a+b, [1,2,3,4,5,6,7,8,9,10])</syntaxhighlight> {{works with\|PARI/GP\|2.8.1+}} <syntaxhighlight lang="parigp">fold((a,b)->a+b, [1..10])</syntaxhighlight> =={{header\|Pascal}}== {{works with\|Free Pascal}} Should work with many pascal dialects <syntaxhighlight lang="pascal">program reduceApp; type // tmyArray = array of LongInt; tmyArray = array[-5..5] of LongInt; tmyFunc = function (a,b:LongInt):LongInt; function add(x,y:LongInt):LongInt; begin add := x+y; end; function sub(k,l:LongInt):LongInt; begin sub := k-l; end; function mul(r,t:LongInt):LongInt; begin mul := rt; end; function reduce(myFunc:tmyFunc;a:tmyArray):LongInt; var i,res : LongInt; begin res := a[low(a)]; For i := low(a)+1 to high(a) do res := myFunc(res,a[i]); reduce := res; end; procedure InitMyArray(var a:tmyArray); var i: LongInt; begin For i := low(a) to high(a) do begin //no a[i] = 0 a[i] := i + ord(i=0); write(a[i],','); end; writeln(#8#32); end; var ma : tmyArray; BEGIN InitMyArray(ma); writeln(reduce(@add,ma)); writeln(reduce(@sub,ma)); writeln(reduce(@mul,ma)); END.</syntaxhighlight> output <pre>-5,-4,-3,-2,-1,1,1,2,3,4,5 1 -11 -1440</pre> =={{header\|Perl}}== Perl's reduce function is in a standard package. <syntaxhighlight lang="perl">use List::Util 'reduce'; # note the use of the odd $a and $b globals print +(reduce {$a + $b} 1 .. 10), "\n"; # first argument is really an anon function; you could also do this: sub func { $b & 1 ? "$a $b" : "$b $a" } print +(reduce \&func, 1 .. 10), "\n"</syntaxhighlight> =={{header\|Phix}}== {{trans\|C}} <!--<syntaxhighlight lang="phix">(phixonline)--> <span style="color: #008080;">with</span> <span style="color: #008080;">javascript_semantics</span> <span style="color: #008080;">function</span> <span style="color: #000000;">add</span><span style="color: #0000FF;">(</span><span style="color: #004080;">integer</span> <span style="color: #000000;">a</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">b</span><span style="color: #0000FF;">)</span> <span style="color: #008080;">return</span> <span style="color: #000000;">a</span> <span style="color: #0000FF;">+</span> <span style="color: #000000;">b</span> <span style="color: #008080;">end</span> <span style="color: #008080;">function</span> <span style="color: #008080;">function</span> <span style="color: #000000;">sub</span><span style="color: #0000FF;">(</span><span style="color: #004080;">integer</span> <span style="color: #000000;">a</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">b</span><span style="color: #0000FF;">)</span> <span style="color: #008080;">return</span> <span style="color: #000000;">a</span> <span style="color: #0000FF;">-</span> <span style="color: #000000;">b</span> <span style="color: #008080;">end</span> <span style="color: #008080;">function</span> <span style="color: #008080;">function</span> <span style="color: #000000;">mul</span><span style="color: #0000FF;">(</span><span style="color: #004080;">integer</span> <span style="color: #000000;">a</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">b</span><span style="color: #0000FF;">)</span> <span style="color: #008080;">return</span> <span style="color: #000000;">a</span> <span style="color: #0000FF;"></span> <span style="color: #000000;">b</span> <span style="color: #008080;">end</span> <span style="color: #008080;">function</span> <span style="color: #008080;">function</span> <span style="color: #000000;">reduce</span><span style="color: #0000FF;">(</span><span style="color: #004080;">integer</span> <span style="color: #000000;">rid</span><span style="color: #0000FF;">,</span> <span style="color: #004080;">sequence</span> <span style="color: #000000;">s</span><span style="color: #0000FF;">)</span> <span style="color: #004080;">object</span> <span style="color: #000000;">res</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">s</span><span style="color: #0000FF;">[</span><span style="color: #000000;">1</span><span style="color: #0000FF;">]</span> <span style="color: #008080;">for</span> <span style="color: #000000;">i</span><span style="color: #0000FF;">=</span><span style="color: #000000;">2</span> <span style="color: #008080;">to</span> <span style="color: #7060A8;">length</span><span style="color: #0000FF;">(</span><span style="color: #000000;">s</span><span style="color: #0000FF;">)</span> <span style="color: #008080;">do</span> <span style="color: #000000;">res</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">rid</span><span style="color: #0000FF;">(</span><span style="color: #000000;">res</span><span style="color: #0000FF;">,</span><span style="color: #000000;">s</span><span style="color: #0000FF;">[</span><span style="color: #000000;">i</span><span style="color: #0000FF;">])</span> <span style="color: #008080;">end</span> <span style="color: #008080;">for</span> <span style="color: #008080;">return</span> <span style="color: #000000;">res</span> <span style="color: #008080;">end</span> <span style="color: #008080;">function</span> <span style="color: #0000FF;">?</span><span style="color: #000000;">reduce</span><span style="color: #0000FF;">(</span><span style="color: #000000;">add</span><span style="color: #0000FF;">,</span><span style="color: #7060A8;">tagset</span><span style="color: #0000FF;">(</span><span style="color: #000000;">5</span><span style="color: #0000FF;">))</span> <span style="color: #0000FF;">?</span><span style="color: #000000;">reduce</span><span style="color: #0000FF;">(</span><span style="color: #000000;">sub</span><span style="color: #0000FF;">,</span><span style="color: #7060A8;">tagset</span><span style="color: #0000FF;">(</span><span style="color: #000000;">5</span><span style="color: #0000FF;">))</span> <span style="color: #0000FF;">?</span><span style="color: #000000;">reduce</span><span style="color: #0000FF;">(</span><span style="color: #000000;">mul</span><span style="color: #0000FF;">,</span><span style="color: #7060A8;">tagset</span><span style="color: #0000FF;">(</span><span style="color: #000000;">5</span><span style="color: #0000FF;">))</span> <!--</syntaxhighlight>--> {{out}} <pre> 15 -13 120 </pre> =={{header\|Phixmonti}}== <syntaxhighlight lang="phixmonti">include ..\Utilitys.pmt def add + enddef def sub - enddef def mul * enddef def reduce >ps 1 get swap len 2 swap 2 tolist for get rot swap tps exec swap endfor ps> drop swap enddef ( 1 2 3 4 5 ) getid add reduce ? getid sub reduce ? getid mul reduce ?</syntaxhighlight> =={{header\|PicoLisp}}== <syntaxhighlight lang="picolisp">(de reduce ("Fun" "Lst") (let "A" (car "Lst") (for "N" (cdr "Lst") (setq "A" ("Fun" "A" "N")) ) "A" ) ) (println (reduce + (1 2 3 4 5)) (reduce * (1 2 3 4 5)) ) (bye)</syntaxhighlight> =={{header\|PowerShell}}== 'Filter' is a more common sequence function in PowerShell than 'reduce' or 'map', but here is one way to accomplish 'reduce': <syntaxhighlight lang="powershell"> 1..5 \| ForEach-Object -Begin {$result = 0} -Process {$result += $_} -End {$result} </syntaxhighlight> {{Out}} <pre> 15 </pre> =={{header\|Prolog}}== ===Using <code>foldl</code> from <code>library(apply)</code> and Lambda-Expressions from <code>library(lambda)</code>=== * SWI-Prolog's [https://www.swi-prolog.org/pldoc/man?section=apply library(apply)] provides a [https://www.swi-prolog.org/pldoc/doc_for?object=foldl/4 `foldl/4`] (the source code of which can be seen [https://www.swi-prolog.org/pldoc/doc/_SWI_/library/apply.pl?show=src#foldl/4 here]). * '''Ulrich Neumerkel''' wrote `library(lambda)` which can be found [http://www.complang.tuwien.ac.at/ulrich/Prolog-inedit/lambda.pl here]. (However, SWI-Prolog's Lambda Expressions are by default based on Paulo Moura's [https://www.swi-prolog.org/search?for=yall library(yall)]) <syntaxhighlight lang="prolog">:- use_module(library(lambda)). catamorphism :- numlist(1,10,L), foldl(\XS^YS^ZS^(ZS is XS+YS), L, 0, Sum), format('Sum of ~w is ~w~n', [L, Sum]), foldl(\XP^YP^ZP^(ZP is XPYP), L, 1, Prod), format('Prod of ~w is ~w~n', [L, Prod]), string_to_list(LV, ""), foldl(\XC^YC^ZC^(string_to_atom(XS, XC),string_concat(YC,XS,ZC)), L, LV, Concat), format('Concat of ~w is ~w~n', [L, Concat]).</syntaxhighlight> {{out}} <pre> ?- catamorphism. Sum of [1,2,3,4,5,6,7,8,9,10] is 55 Prod of [1,2,3,4,5,6,7,8,9,10] is 3628800 Concat of [1,2,3,4,5,6,7,8,9,10] is 12345678910 true. </pre> ===Bare Prolog=== This is based on SWI Prolog 8 and has the following specificities: The consbox functor is <code>[\|]</code> instead of <code>.</code> * The list is terminated by the special atomic thing <code>[]</code> (the empty list) <syntaxhighlight lang="prolog"> % List to be folded: % % +---+---+---+---[] <-- list backbone/spine, composed of nodes, terminating in the empty list % \| \| \| \| % a b c d <-- list items/entries/elements/members % </syntaxhighlight> ====linear <code>foldl</code>==== <syntaxhighlight lang="prolog"> % Computes "Out" as: % % starter value -->--f-->--f-->--f-->--f-->-- Out % \| \| \| \| % a b c d foldl(Foldy,[Item\|Items],Acc,Result) :- % case of nonempty list !, % GREEN CUT for determinism call(Foldy,Item,Acc,AccNext), % call Foldy(Item,Acc,AccNext) foldl(Foldy,Items,AccNext,Result). % then recurse (open to tail call optimization) foldl(_,[],Acc,Result) :- % case of empty list Acc=Result. % unification not in head for clarity </syntaxhighlight> ====linear <code>foldr</code>==== <syntaxhighlight lang="prolog"> % Computes "Out" as: % % Out --<--f--<--f--<--f--<--f--<-- starter value % \| \| \| \| % a b c d foldr(Foldy,[Item\|Items],Starter,AccUp) :- % case of nonempty list !, % GREEN CUT for determinism foldr(Foldy,Items,Starter,AccUpPrev), % recurse (NOT open to tail-call optimization) call(Foldy,Item,AccUpPrev,AccUp). % call Foldy(Item,AccupPrev,AccUp) as last action foldr(_,[],Starter,AccUp) :- % empty list: bounce Starter "upwards" into AccUp AccUp=Starter. % unification not in head for clarity </syntaxhighlight> ====Unit tests==== This is written using SWI-Prolog's [https://www.swi-prolog.org/pldoc/doc_for?object=section(%27packages/plunit.html%27) unit testing framework]. Functions (in predicate form) of interest for our test cases: <syntaxhighlight lang="prolog"> :- use_module(library(clpfd)). % We are using #= instead of the raw "is". foldy_len(_Item,ThreadIn,ThreadOut) :- succ(ThreadIn,ThreadOut). foldy_add(Item,ThreadIn,ThreadOut) :- ThreadOut #= Item+ThreadIn. foldy_mult(Item,ThreadIn,ThreadOut) :- ThreadOut #= ItemThreadIn. foldy_squadd(Item,ThreadIn,ThreadOut) :- ThreadOut #= Item+(ThreadIn^2). % '[\|]' is SWI-Prolog specific, replace by '.' as consbox constructor in other Prologs foldy_build(Item,ThreadIn,ThreadOut) :- ThreadOut = '[\|]'(Item,ThreadIn). foldy_join(Item,ThreadIn,ThreadOut) :- (ThreadIn \= "") -> with_output_to(string(ThreadOut),format("~w,~w",[Item,ThreadIn])) ; with_output_to(string(ThreadOut),format("~w",[Item])). % '=..' ("univ") constructs a term from a list of functor and arguments foldy_expr(Functor,Item,ThreadIn,ThreadOut) :- ThreadOut =.. [Functor,Item,ThreadIn]. </syntaxhighlight> <syntaxhighlight lang="prolog"> :- begin_tests(foldr). in([1,2,3,4,5]). ffr(Foldy,List,Starter,AccUp) :- foldr(Foldy,List,Starter,AccUp). test(foo_foldr_len) :- in(L),ffr(foldy_len , L , 0 , R), R=5. test(foo_foldr_add) :- in(L),ffr(foldy_add , L , 0 , R), R=15. test(foo_foldr_mult) :- in(L),ffr(foldy_mult , L , 1 , R), R=120. test(foo_foldr_build) :- in(L),ffr(foldy_build , L , [] , R), R=[1,2,3,4,5]. test(foo_foldr_squadd) :- in(L),ffr(foldy_squadd , L , 0 , R), R=507425426245. test(foo_foldr_join) :- in(L),ffr(foldy_join , L , "" , R), R="1,2,3,4,5". test(foo_foldr_expr) :- in(L),ffr(foldy_expr() , L , 1 , R), R=1(2(3(4(51)))). test(foo_foldr_len_empty) :- ffr(foldy_len , [], 0 , R), R=0. test(foo_foldr_add_empty) :- ffr(foldy_add , [], 0 , R), R=0. test(foo_foldr_mult_empty) :- ffr(foldy_mult , [], 1 , R), R=1. test(foo_foldr_build_empty) :- ffr(foldy_build , [], [] , R), R=[]. test(foo_foldr_squadd_empty) :- ffr(foldy_squadd , [], 0 , R), R=0. test(foo_foldr_join_empty) :- ffr(foldy_join , [], "" , R), R="". test(foo_foldr_expr_empty) :- ffr(foldy_expr() , [], 1 , R), R=1. % library(apply) has no "foldr" so no comparison tests! :- end_tests(foldr). :- begin_tests(foldl). in([1,2,3,4,5]). ffl(Foldy,List,Starter,Result) :- foldl(Foldy,List,Starter,Result). test(foo_foldl_len) :- in(L),ffl(foldy_len , L , 0 , R), R=5. test(foo_foldl_add) :- in(L),ffl(foldy_add , L, 0 , R), R=15. test(foo_foldl_mult) :- in(L),ffl(foldy_mult , L, 1 , R), R=120. test(foo_foldl_build) :- in(L),ffl(foldy_build , L, [] , R), R=[5,4,3,2,1]. test(foo_foldl_squadd) :- in(L),ffl(foldy_squadd , L, 0 , R), R=21909. test(foo_foldl_join) :- in(L),ffl(foldy_join , L, "" , R), R="5,4,3,2,1". test(foo_foldl_expr) :- in(L),ffl(foldy_expr() , L, 1 , R), R=5(4(3(2(11)))). test(foo_foldl_len_empty) :- ffl(foldy_len , [], 0 , R), R=0. test(foo_foldl_add_empty) :- ffl(foldy_add , [], 0 , R), R=0. test(foo_foldl_mult_empty) :- ffl(foldy_mult , [], 1 , R), R=1. test(foo_foldl_build_empty) :- ffl(foldy_build , [], [] , R), R=[]. test(foo_foldl_squadd_empty) :- ffl(foldy_squadd , [], 0 , R), R=0. test(foo_foldl_join_empty) :- ffl(foldy_join , [], "" , R), R="". test(foo_foldl_expr_empty) :- ffl(foldy_expr() , [], 1 , R), R=1. :- end_tests(foldl). rt :- run_tests(foldr),run_tests(foldl). </syntaxhighlight> =={{header\|PureBasic}}== <syntaxhighlight lang="purebasic">Procedure.i reduce(List l(),op$="+") If FirstElement(l()) x=l() While NextElement(l()) Select op$ Case "+" : x+l() Case "-" : x-l() Case "" : xl() EndSelect Wend EndIf ProcedureReturn x EndProcedure NewList fold() For i=1 To 5 : AddElement(fold()) : fold()=i : Next Debug reduce(fold()) Debug reduce(fold(),"-") Debug reduce(fold(),"")</syntaxhighlight> {{out}} <pre>15 -13 120</pre> =={{header\|Python}}== <syntaxhighlight lang="python">>>> # Python 2.X >>> from operator import add >>> listoflists = [['the', 'cat'], ['sat', 'on'], ['the', 'mat']] >>> help(reduce) Help on built-in function reduce in module __builtin__: reduce(...) reduce(function, sequence[, initial]) -> value Apply a function of two arguments cumulatively to the items of a sequence, from left to right, so as to reduce the sequence to a single value. For example, reduce(lambda x, y: x+y, [1, 2, 3, 4, 5]) calculates ((((1+2)+3)+4)+5). If initial is present, it is placed before the items of the sequence in the calculation, and serves as a default when the sequence is empty. >>> reduce(add, listoflists, []) ['the', 'cat', 'sat', 'on', 'the', 'mat'] >>> </syntaxhighlight> ===Additional example=== <syntaxhighlight lang="python"># Python 3.X from functools import reduce from operator import add, mul nums = range(1,11) summation = reduce(add, nums) product = reduce(mul, nums) concatenation = reduce(lambda a, b: str(a) + str(b), nums) print(summation, product, concatenation)</syntaxhighlight> =={{header\|Quackery}}== Among its many other uses, <code>witheach</code> can act like reduce. In the Quackery shell (REPL): <syntaxhighlight lang="quackery">/O> 0 ' [ 1 2 3 4 5 ] witheach + ... 1 ' [ 1 2 3 4 5 ] witheach * ... Stack: 15 120</syntaxhighlight> =={{header\|R}}== Sum the numbers in a vector: <syntaxhighlight lang="r"> Reduce('+', c(2,30,400,5000)) 5432 </syntaxhighlight> Put a 0 between each pair of numbers: <syntaxhighlight lang="r"> Reduce(function(a,b){c(a,0,b)}, c(2,3,4,5)) 2 0 3 0 4 0 5 </syntaxhighlight> Generate all prefixes of a string: <syntaxhighlight lang="r"> Reduce(paste0, unlist(strsplit("freedom", NULL)), accum=T) "f" "fr" "fre" "free" "freed" "freedo" "freedom" </syntaxhighlight> Filter and map: <syntaxhighlight lang="r"> Reduce(function(x,acc){if (0==x%%3) c(xx,acc) else acc}, 0:22, init=c(), right=T) 0 9 36 81 144 225 324 441 </syntaxhighlight> =={{header\|Racket}}== <syntaxhighlight lang="racket"> #lang racket (define (fold f xs init) (if (empty? xs) init (f (first xs) (fold f (rest xs) init)))) (fold + '(1 2 3) 0) ; the result is 6 </syntaxhighlight> =={{header\|Raku}}== (formerly Perl 6) {{works with\|Rakudo\|2018.03}} Any associative infix operator, either built-in or user-defined, may be turned into a reduce operator by putting it into square brackets (known as "the reduce metaoperator") and using it as a list operator. The operations will work left-to-right or right-to-left automatically depending on the natural associativity of the base operator. <syntaxhighlight lang="raku" line>my @list = 1..10; say [+] @list; say [] @list; say [~] @list; say min @list; say max @list; say [lcm] @list;</syntaxhighlight> {{out}} <pre>55 3628800 12345678910 1 10 2520</pre> In addition to the reduce metaoperator, a general higher-order function, <tt>reduce</tt>, can apply any appropriate function. Reproducing the above in this form, using the function names of those operators, we have: <syntaxhighlight lang="raku" line>my @list = 1..10; say reduce &infix:<+>, @list; say reduce &infix:<>, @list; say reduce &infix:<~>, @list; say reduce &infix:<min>, @list; say reduce &infix:<max>, @list; say reduce &infix:<lcm>, @list;</syntaxhighlight> =={{header\|Refal}}== <syntaxhighlight lang="refal">$ENTRY Go { , 1 2 3 4 5 6 7: e.List = <Prout <Reduce Add e.List>> <Prout <Reduce Mul e.List>>; }; Reduce { s.F t.I = t.I; s.F t.I t.J e.X = <Reduce s.F <Mu s.F t.I t.J> e.X>; };</syntaxhighlight> {{out}} <pre>28 5040</pre> =={{header\|REXX}}== This REXX example is modeled after the Raku example   (it is NOT a translation). Also, a   '''list'''   and   '''show'''   function were added, although they aren't a catamorphism, as they don't produce or reduce the values to a   ''single''   value, but are included here to help display the values in the list. <syntaxhighlight lang="rexx">/REXX program demonstrates a method for catamorphism for some simple functions. / @list= 1 2 3 4 5 6 7 8 9 10 say 'list:' fold(@list, "list") say ' sum:' fold(@list, "+" ) say 'prod:' fold(@list, "" ) say ' cat:' fold(@list, "\|\|" ) say ' min:' fold(@list, "min" ) say ' max:' fold(@list, "max" ) say ' avg:' fold(@list, "avg" ) say ' GCD:' fold(@list, "GCD" ) say ' LCM:' fold(@list, "LCM" ) exit /stick a fork in it, we're all done. / /──────────────────────────────────────────────────────────────────────────────────────/ fold: procedure; parse arg z; arg ,f; z = space(z); BIFs= 'MIN MAX LCM GCD' za= translate(z, f, ' '); zf= f"("translate(z, ',' , " ")')' if f== '+' \| f=="" then interpret "return" za if f== '\|\|' then return space(z, 0) if f== 'AVG' then interpret "return" fold(z, '+') "/" words(z) if wordpos(f, BIFs)\==0 then interpret "return" zf if f=='LIST' \| f=="SHOW" then return z return 'illegal function:' arg(2) /──────────────────────────────────────────────────────────────────────────────────────/ GCD: procedure; $=; do j=1 for arg(); $= $ arg(j) end /j/ parse var $ x z .; if x=0 then x= z / [↑] build an arg list./ x= abs(x) do k=2 to words($); y= abs( word($, k)); if y=0 then iterate do until _=0; _= x // y; x= y; y= _ end /until/ end /k/ return x /──────────────────────────────────────────────────────────────────────────────────────/ LCM: procedure; $=; do j=1 for arg(); $= $ arg(j) end /j/ x= abs(word($, 1)) / [↑] build an arg list./ do k=2 to words($); != abs(word($, k)); if !=0 then return 0 x= x! / GCD(x, !) /GCD does the heavy work/ end /k/ return x</syntaxhighlight> {{out\|output\|:}} <pre> list: 1 2 3 4 5 6 7 8 9 10 sum: 55 prod: 3628800 cat: 12345678910 min: 1 max: 10 avg: 5.5 GCD: 1 LCM: 2520 </pre> =={{header\|Ring}}== <syntaxhighlight lang="ring"> n = list(10) for i = 1 to 10 n[i] = i next see " +: " + cat(10,"+") + nl+ " -: " + cat(10,"-") + nl + " : " + cat(10,"") + nl + " /: " + cat(10,"/") + nl+ " ^: " + cat(10,"^") + nl + "min: " + cat(10,"min") + nl+ "max: " + cat(10,"max") + nl+ "avg: " + cat(10,"avg") + nl + "cat: " + cat(10,"cat") + nl func cat count,op cat = n[1] cat2 = "" for i = 2 to count switch op on "+" cat += n[i] on "-" cat -= n[i] on "" cat = n[i] on "/" cat /= n[i] on "^" cat ^= n[i] on "max" cat = max(cat,n[i]) on "min" cat = min(cat,n[i]) on "avg" cat += n[i] on "cat" cat2 += string(n[i]) off next if op = "avg" cat = cat / count ok if op = "cat" decimals(0) cat = string(n[1])+cat2 ok return cat </syntaxhighlight> =={{header\|RPL}}== ≪ → array op ≪ array 1 GET 2 '''WHILE''' DUP array SIZE ≤ '''REPEAT''' array OVER GET ROT SWAP op EVAL SWAP 1 + '''END''' DROP ≫ ≫ '<span style="color:blue">REDUCE</span>' STO [ 1 2 3 4 5 6 7 8 9 10 ] ≪ + ≫ <span style="color:blue">REDUCE</span> [ 1 2 3 4 5 6 7 8 9 10 ] ≪ - ≫ <span style="color:blue">REDUCE</span> [ 1 2 3 4 5 6 7 8 9 10 ] ≪ * ≫ <span style="color:blue">REDUCE</span> [ 1 2 3 4 5 6 7 8 9 10 ] ≪ MAX ≫ <span style="color:blue">REDUCE</span> [ 1 2 3 4 5 6 7 8 9 10 ] ≪ SQ + ≫ <span style="color:blue">REDUCE</span> {{out}} <pre> 5: 55 4: -53 3: 3628800 2: 10 1: 385 </pre> From HP-48G models, a built-in function named <code>STREAM</code> performs exactly the same as the above <code>REDUCE</code> one, but only with lists. =={{header\|Ruby}}== The method inject (and it's alias reduce) can be used in several ways; the simplest is to give a methodname as argument: <syntaxhighlight lang="ruby"># sum: p (1..10).inject(:+) # smallest number divisible by all numbers from 1 to 20: p (1..20).inject(:lcm) #lcm: lowest common multiple </syntaxhighlight>The most versatile way uses a accumulator object (memo) and a block. In this example Pascal's triangle is generated by using an array [1,1] and inserting the sum of each consecutive pair of numbers from the previous row. <syntaxhighlight lang="ruby">p row = [1] 10.times{p row = row.each_cons(2).inject([1,1]){\|ar,(a,b)\| ar.insert(-2, a+b)} } # [1] # [1, 1] # [1, 2, 1] # [1, 3, 3, 1] # [1, 4, 6, 4, 1] # [1, 5, 10, 10, 5, 1] # [1, 6, 15, 20, 15, 6, 1] # etc </syntaxhighlight> =={{header\|Run BASIC}}== <syntaxhighlight lang="runbasic">for i = 1 to 10 :n(i) = i:next i print " +: ";" ";cat(10,"+") print " -: ";" ";cat(10,"-") print " : ";" ";cat(10,"") print " /: ";" ";cat(10,"/") print " ^: ";" ";cat(10,"^") print "min: ";" ";cat(10,"min") print "max: ";" ";cat(10,"max") print "avg: ";" ";cat(10,"avg") print "cat: ";" ";cat(10,"cat") function cat(count,op$) cat = n(1) for i = 2 to count if op$ = "+" then cat = cat + n(i) if op$ = "-" then cat = cat - n(i) if op$ = "" then cat = cat n(i) if op$ = "/" then cat = cat / n(i) if op$ = "^" then cat = cat ^ n(i) if op$ = "max" then cat = max(cat,n(i)) if op$ = "min" then cat = min(cat,n(i)) if op$ = "avg" then cat = cat + n(i) if op$ = "cat" then cat$ = cat$ + str$(n(i)) next i if op$ = "avg" then cat = cat / count if op$ = "cat" then cat = val(str$(n(1))+cat$) end function</syntaxhighlight> <pre> +: 55 -: -53 : 3628800 /: 2.75573205e-7 ^: 1 min: 1 max: 10 avg: 5.5 cat: 12345678910</pre> =={{header\|Rust}}== <syntaxhighlight lang="rust">fn main() { println!("Sum: {}", (1..10).fold(0, \|acc, n\| acc + n)); println!("Product: {}", (1..10).fold(1, \|acc, n\| acc n)); let chars = ['a', 'b', 'c', 'd', 'e']; println!("Concatenation: {}", chars.iter().map(\|&c\| (c as u8 + 1) as char).collect::<String>()); }</syntaxhighlight> {{out}} <pre> Sum: 45 Product: 362880 Concatenation: bcdef </pre> =={{header\|Scala}}== <syntaxhighlight lang="scala">object Main extends App { val a = Seq(1, 2, 3, 4, 5) println(s"Array : ${a.mkString(", ")}") println(s"Sum : ${a.sum}") println(s"Difference : ${a.reduce { (x, y) => x - y }}") println(s"Product : ${a.product}") println(s"Minimum : ${a.min}") println(s"Maximum : ${a.max}") }</syntaxhighlight> =={{header\|Scheme}}== ===Implementation=== reduce implemented for a single list: <syntaxhighlight lang="scheme">(define (reduce fn init lst) (do ((val init (fn (car rem) val)) ; accumulated value passed as second argument (rem lst (cdr rem))) ((null? rem) val))) (display (reduce + 0 '(1 2 3 4 5))) (newline) ; => 15 (display (reduce expt 2 '(3 4))) (newline) ; => 262144</syntaxhighlight> ===Using SRFI 1=== There is also an implementation of fold and fold-right in SRFI-1, for lists. These take a two-argument procedure: (lambda (value acc) ...) where value is the next value in the list, and acc is the accumulated value. The initial value is used for the first value of acc. <pre> > (import (srfi 1)) > (fold + 0 '(1 2 3 4 5)) 15 > (fold expt 2 '(3 4)) ; => (expt 4 (expt 3 2)) 262144 > (fold-right expt 2 '(3 4)) ; => (expt 3 (expt 4 2)) 43046721 </pre> More than one list may be folded over, when the function is passed one item from each list plus the accumulated value: <pre> > (fold + 0 '(1 2 3) '(4 5 6)) ; add up all the numbers in all the lists 21 </pre> =={{header\|Sidef}}== <syntaxhighlight lang="ruby">say (1..10 -> reduce('+')); say (1..10 -> reduce{\|a,b\| a + b});</syntaxhighlight> =={{header\|Standard ML}}== <syntaxhighlight lang="sml">- val nums = [1,2,3,4,5,6,7,8,9,10]; val nums = [1,2,3,4,5,6,7,8,9,10] : int list - val sum = foldl op+ 0 nums; val sum = 55 : int - val product = foldl op* 1 nums; val product = 3628800 : int</syntaxhighlight> =={{header\|Swift}}== <syntaxhighlight lang="swift">let nums = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10] print(nums.reduce(0, +)) print(nums.reduce(1, )) print(nums.reduce("", { $0 + String($1) }))</syntaxhighlight> {{out}} <pre>55 3628800 12345678910</pre> =={{header\|Tailspin}}== It is probably easier to just write the whole thing as an inline transform rather than create a utility. <syntaxhighlight lang="tailspin"> [1..5] -> \(@: $(1); $(2..last)... -> @: $@ + $; $@!\) -> '$; ' -> !OUT::write [1..5] -> \(@: $(1); $(2..last)... -> @: $@ - $; $@!\) -> '$; ' -> !OUT::write [1..5] -> \(@: $(1); $(2..last)... -> @: $@ $; $@!\) -> '$; ' -> !OUT::write </syntaxhighlight> {{out}} <pre> 15 -13 120 </pre> If you really want to make a utility, it could look like this: <syntaxhighlight lang="tailspin"> templates fold&{op:} @: $(1); $(2..last)... -> @: [$@, $] -> op; $@ ! end fold templates add $(1) + $(2) ! end add templates mul $(1) * $(2) ! end mul [1..5] -> fold&{op:add} -> '$; ' -> !OUT::write [1..5] -> fold&{op:mul} -> '$; ' -> !OUT::write </syntaxhighlight> {{out}} <pre> 15 120 </pre> =={{header\|Tcl}}== Tcl does not come with a built-in <tt>fold</tt> command, but it is easy to construct: <syntaxhighlight lang="tcl">proc fold {lambda zero list} { set accumulator $zero foreach item $list { set accumulator [apply $lambda $accumulator $item] } return $accumulator }</syntaxhighlight> Demonstrating: <syntaxhighlight lang="tcl">set 1to5 {1 2 3 4 5} puts [fold {{a b} {expr {$a+$b}}} 0 $1to5] puts [fold {{a b} {expr {$a$b}}} 1 $1to5] puts [fold {{a b} {return $a,$b}} x $1to5]</syntaxhighlight> {{out}} <pre> 15 120 x,1,2,3,4,5 </pre> Note that these particular operations would more conventionally be written as: <syntaxhighlight lang="tcl">puts [::tcl::mathop::+ {}$1to5] puts [::tcl::mathop::* {}$1to5] puts x,[join $1to5 ,]</syntaxhighlight> But those are not general catamorphisms. =={{header\|uBasic/4tH}}== {{trans\|FreeBASIC}} uBasic/4tH has only got one single array so passing its address makes little sense. Instead, its bounds are passed. <syntaxhighlight lang="uBasic/4tH">For x = 1 To 5 : @(x-1) = x : Next ' initialize array ' try different reductions Print "Sum is : "; FUNC(_Reduce(_add, 5)) Print "Difference is : "; FUNC(_Reduce(_subtract, 5)) Print "Product is : "; FUNC(_Reduce(_multiply, 5)) Print "Maximum is : "; FUNC(_Reduce(_max, 5)) Print "Minimum is : "; FUNC(_Reduce(_min, 5)) End ' several functions _add Param (2) : Return (a@ + b@) _subtract Param (2) : Return (a@ - b@) _multiply Param (2) : Return (a@ b@) _min Param (2) : Return (Min (a@, b@)) _max Param (2) : Return (Max (a@, b@)) _Reduce Param (2) ' function and array size Local (2) ' loop index and result ' set result and iterate array d@ = @(0) : For c@ = 1 To b@-1 : d@ = FUNC(a@ (d@, @(c@))) : Next Return (d@)</syntaxhighlight> This version incorporates a "no op" as well. <syntaxhighlight lang="text">Push 5, 4, 3, 2, 1: s = Used() - 1 For x = 0 To s: @(x) = Pop(): Next Print "Sum is : "; FUNC(_reduce(0, s, _add)) Print "Difference is : "; FUNC(_reduce(0, s, _subtract)) Print "Product is : "; FUNC(_reduce(0, s, _multiply)) Print "Maximum is : "; FUNC(_reduce(0, s, _max)) Print "Minimum is : "; FUNC(_reduce(0, s, _min)) Print "No op is : "; FUNC(_reduce(0, s, _noop)) End _reduce Param (3) Local (2) If (Line(c@) = 0) + ((b@ - a@) < 1) Then Return (0) d@ = @(a@) For e@ = a@ + 1 To b@ d@ = FUNC(c@ (d@, @(e@))) Next Return (d@) _add Param (2) : Return (a@ + b@) _subtract Param (2) : Return (a@ - b@) _multiply Param (2) : Return (a@ * b@) _max Param (2) : Return (Max(a@, b@)) _min Param (2) : Return (Min(a@, b@))</syntaxhighlight> {{out}} <pre>Sum is : 15 Difference is : -13 Product is : 120 Maximum is : 5 Minimum is : 1 No op is : 0 0 OK, 0:378 </pre> =={{header\|VBA}}== <syntaxhighlight lang="vb">Public Sub reduce() s = [{1,2,3,4,5}] Debug.Print WorksheetFunction.Sum(s) Debug.Print WorksheetFunction.Product(s) End Sub</syntaxhighlight> =={{header\|V (Vlang)}}== {{trans\|go}} <syntaxhighlight lang="v (vlang)"> fn main() { n := [1, 2, 3, 4, 5] println(reduce(add, n)) println(reduce(sub, n)) println(reduce(mul, n)) } fn add(a int, b int) int { return a + b } fn sub(a int, b int) int { return a - b } fn mul(a int, b int) int { return a * b } fn reduce(rf fn(int, int) int, m []int) int { mut r := m[0] for v in m[1..] { r = rf(r, v) } return r }</syntaxhighlight> {{out}} <pre> 15 -13 120 </pre> =={{header\|WDTE}}== Translated from the JavaScript ES6 example with a few modifications. <syntaxhighlight lang="wdte">let a => import 'arrays'; let s => import 'stream'; let str => import 'strings'; # Sum of [1, 10]: let nums => [1; 2; 3; 4; 5; 6; 7; 8; 9; 10]; a.stream nums -> s.reduce 0 + -- io.writeln io.stdout; # As an alternative to an array, a range stream can be used. Here's the product of [1, 11): s.range 1 11 -> s.reduce 1 * -- io.writeln io.stdout; # And here's a concatenation: s.range 1 11 -> s.reduce '' (str.format '{}{}') -- io.writeln io.stdout;</syntaxhighlight> =={{header\|Wortel}}== You can reduce an array with the <code>!/</code> operator. <syntaxhighlight lang="wortel">!/ ^+ [1 2 3] ; returns 6</syntaxhighlight> If you want to reduce with an initial value, you'll need the <code>@fold</code> operator. <syntaxhighlight lang="wortel">@fold ^+ 1 [1 2 3] ; returns 7</syntaxhighlight> {{out}} <pre>55 3628800 12345678910</pre> =={{header\|Wren}}== <syntaxhighlight lang="wren">var a = [1, 2, 3, 4, 5] var sum = a.reduce { \|acc, i\| acc + i } var prod = a.reduce { \|acc, i\| acc * i } var sumSq = a.reduce { \|acc, i\| acc + ii } System.print(a) System.print("Sum is %(sum)") System.print("Product is %(prod)") System.print("Sum of squares is %(sumSq)")</syntaxhighlight> {{out}} <pre> [1, 2, 3, 4, 5] Sum is 15 Product is 120 Sum of squares is 55 </pre> =={{header\|Zig}}== '''Works with:''' 0.10.x, 0.11.x, 0.12.0-dev.1591+3fc6a2f11 ===Reduce a slice=== <syntaxhighlight lang="zig">/// Asserts that `array`.len >= 1. pub fn reduce(comptime T: type, comptime applyFn: fn (T, T) T, array: []const T) T { var val: T = array[0]; for (array[1..]) \|elem\| { val = applyFn(val, elem); } return val; }</syntaxhighlight> Usage: <syntaxhighlight lang="zig">const std = @import("std"); fn add(a: i32, b: i32) i32 { return a + b; } fn mul(a: i32, b: i32) i32 { return a b; } fn min(a: i32, b: i32) i32 { return @min(a, b); } fn max(a: i32, b: i32) i32 { return @max(a, b); } pub fn main() void { const arr: [5]i32 = .{ 1, 2, 3, 4, 5 }; std.debug.print("Array: {any}\n", .{arr}); std.debug.print(" * Reduce with add: {d}\n", .{reduce(i32, add, &arr)}); std.debug.print(" * Reduce with mul: {d}\n", .{reduce(i32, mul, &arr)}); std.debug.print(" * Reduce with min: {d}\n", .{reduce(i32, min, &arr)}); std.debug.print(" * Reduce with max: {d}\n", .{reduce(i32, max, &arr)}); }</syntaxhighlight> {{out}} <pre> Array: { 1, 2, 3, 4, 5 } * Reduce with add: 15 * Reduce with mul: 120 * Reduce with min: 1 * Reduce with max: 5 </pre> ===Reduce a vector=== We use @reduce builtin function here to leverage special instructions if available, but only small set of reduce operators are available. @Vector and related builtings will use SIMD instructions if possible. If target platform does not support SIMD instructions, vectors operations will be compiled like in previous example (represented as arrays and operating with one element at a time). <syntaxhighlight lang="zig">const std = @import("std"); pub fn main() void { const vec: @Vector(5, i32) = .{ 1, 2, 3, 4, 5 }; std.debug.print("Vec: {any}\n", .{vec}); std.debug.print(" * Reduce with add: {d}\n", .{@reduce(.Add, vec)}); std.debug.print(" * Reduce with mul: {d}\n", .{@reduce(.Mul, vec)}); std.debug.print(" * Reduce with min: {d}\n", .{@reduce(.Min, vec)}); std.debug.print(" * Reduce with max: {d}\n", .{@reduce(.Max, vec)}); }</syntaxhighlight> {{out}} <pre> Vec: { 1, 2, 3, 4, 5 } * Reduce with add: 15 * Reduce with mul: 120 * Reduce with min: 1 * Reduce with max: 5 </pre> Note that std.builtin.ReduceOp.Add and std.builtin.ReduceOp.Mul operators wrap on overflow and underflow, unlike regular Zig operators, where they are considered illegal behaviour and checked in safe optimize modes. This can be demonstrated by this example (ReleaseSafe optimize mode, zig 0.11.0, Linux 6.5.11 x86_64): <syntaxhighlight lang="zig">const std = @import("std"); pub fn main() void { const vec: @Vector(2, i32) = .{ std.math.minInt(i32), std.math.minInt(i32) + 1 }; std.debug.print("Vec: {any}\n", .{vec}); std.debug.print(" * Reduce with .Add: {d}\n", .{@reduce(.Add, vec)}); std.debug.print(" * Reduce with .Mul: {d}\n", .{@reduce(.Mul, vec)}); var zero: usize = 0; // Small trick to make compiler not emit compile error for overflow below: std.debug.print(" * Reduce with regular add operator: {d}\n", .{vec[zero] + vec[1]}); std.debug.print(" * Reduce with regular mul operator: {d}\n", .{vec[zero] * vec[1]}); }</syntaxhighlight> {{out}} <pre> Vec: { -2147483648, -2147483647 } * Reduce with .Add: 1 * Reduce with .Mul: -2147483648 thread 5908 panic: integer overflow /home/bratishkaerik/test/catamorphism.zig:10:79: 0x20c4b0 in main (catamorphism) std.debug.print(" * Reduce with regular add operator: {d}\n", .{vec[zero] + vec[1]}); ^ /usr/lib64/zig/0.11.0/lib/std/start.zig:564:22: 0x20bee4 in posixCallMainAndExit (catamorphism) root.main(); ^ /usr/lib64/zig/0.11.0/lib/std/start.zig:243:5: 0x20bdc1 in _start (catamorphism) asm volatile (switch (native_arch) { ^ ???:?:?: 0x0 in ??? (???) [1] 5908 IOT instruction ./catamorphism </pre> For well-defined overflow/underflow behaviour you can use wrapping and saturating operators (for addition they are +% and +\| respectively). With +% and % (wrapping multiplication) operators, behaviour should be identical to .Add and .Mul reduce operators. =={{header\|zkl}}== Most sequence objects in zkl have a reduce method. <syntaxhighlight lang="zkl">T("foo","bar").reduce(fcn(p,n){p+n}) //--> "foobar" "123four5".reduce(fcn(p,c){p+(c.matches("[0-9]") and c or 0)}, 0) //-->11 File("foo.zkl").reduce('+(1).fpM("0-"),0) //->5 (lines in file)</syntaxhighlight> =={{header\|ZX Spectrum Basic}}== {{trans\|BBC_BASIC}} <syntaxhighlight lang="zxbasic">10 DIM a(5) 20 FOR i=1 TO 5 30 READ a(i) 40 NEXT i 50 DATA 1,2,3,4,5 60 LET o$="+": GO SUB 1000: PRINT tmp 70 LET o$="-": GO SUB 1000: PRINT tmp 80 LET o$="": GO SUB 1000: PRINT tmp 90 STOP 1000 REM Reduce 1010 LET tmp=a(1) 1020 FOR i=2 TO 5 1030 LET tmp=VAL ("tmp"+o$+"a(i)") 1040 NEXT i 1050 RETURN </syntaxhighlight>