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Line 1: {{~~draft~~ task}} The '''[[wp:Recamán's sequence\|Recamán's sequence]]''' generates Natural numbers.~~<br>~~ Starting from zero, the n'th term <code>a(n)</code> is the previous term minus <code>n</code> i.e <code>a(n) = a(n-1) - n</code> but only if this is '''both''' positive ''and'' has not been previousely generated.<br> Starting from a(0)=0, the n'th term <code>a(n)</code>, where n>0, is the previous term minus <code>n</code> i.e <code>a(n) = a(n-1) - n</code> but only if this is '''both''' positive ''and'' has not been previously generated.<br> If the conditions ''don't'' hold then <code>a(n) = a(n-1) + n</code>. ;Task: # Generate and show here the first 15 members of the sequence. # Find and show here, the first duplicated number in the sequence. # '''Optionally''': Find and show here, ~~How~~how many terms of the sequence are needed until all the integers 0..1000, inclusive, are generated. Line 14 ⟶ 16: * [https://oeis.org/A005132 A005132], The On-Line Encyclopedia of Integer Sequences. * [https://www.youtube.com/watch?v=FGC5TdIiT9U The Slightly Spooky Recamán Sequence], Numberphile video. * [https://en.wikipedia.org/wiki/Recam%C3%A1n%27s_sequence Recamán's sequence], on Wikipedia. <br><br> =={{header\|C11l}}== {{trans\|GoPython}} ~~<lang c>#include <stdio.h>~~ ~~#include <stdlib.h>~~ <syntaxhighlight lang="11l">F recamanSucc(seen, n, r) ~~#define TRUE 1~~ ‘The successor for a given Recaman term, ~~#define FALSE 0~~ given the set of Recaman terms seen so far.’ V back = r - n R I 0 > back \| (back C seen) {n + r} E back F recamanUntil(p) ~~typedef int bool;~~ ‘All terms of the Recaman series before the first term for which the predicate p holds.’ V n = 1 V r = 0 V rs = [r] V seen = Set(rs) V blnNew = 1B L !p(seen, n, r, blnNew) r = recamanSucc(seen, n, r) blnNew = r !C seen seen.add(r) rs.append(r) n = 1 + n R rs F enumFromTo(m) ~~bool used[1001];~~ ‘Integer enumeration from m to n.’ R n -> @m .< 1 + n print("First 15 Recaman:\n "recamanUntil((seen, n, r, _) -> n == 15)) ~~bool contains(int a[], int b, int len) {~~ print("First duplicated Recaman:\n "recamanUntil((seen, n, r, blnNew) -> !blnNew).last) ~~int i;~~ V setK = Set(enumFromTo(0)(1000)) ~~for (i = 0; i < len; ++i) {~~ print("Number of Recaman terms needed to generate all integers from [0..1000]:\n "(recamanUntil((seen, n, r, blnNew) -> (blnNew & r < 1001 & :setK.is_subset(seen))).len - 1))</syntaxhighlight> ~~if (a[i] == b) return TRUE;~~ } ~~return FALSE;~~ } {{out}} ~~int firstFalse(int start) {~~ <pre> ~~int i;~~ First 15 Recaman: ~~for (i = start; i <= 1000; ++i) {~~ [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] ~~if (!used[i]) return i;~~ First duplicated Recaman: 42 Number of Recaman terms needed to generate all integers from [0..1000]: 328002 </pre> =={{header\|ALGOL W}}== <syntaxhighlight lang="algolw">begin % calculate Recaman's sequence values % % a hash table element - holds n, A(n) and a link to the next element with the % % same hash value % record AValue ( integer eN, eAn ; reference(AValue) eNext ); % hash modulus % integer HMOD; HMOD := 100000; begin reference(AValue) array hashTable ( 0 :: HMOD - 1 ); integer array A ( 0 :: 14 ); integer le1000Count, firstN, duplicateN, duplicateValue, n, An, An1, prevN, maxS; % adds an element to the hash table, returns true if an element with value An % % was already present, false otherwise % % if the value was already present, its eN value is returned in prevN % logical procedure addAValue( integer value n, An ; integer result prevN ) ; begin integer hash; logical duplicate; reference(AValue) element; hash := An rem HMOD; element := hashTable( hash ); duplicate := false; while element not = null and eAn(element) not = An do element := eNext(element); duplicate := element not = null; if not duplicate then hashTable( hash ) := AValue( n, An, hashTable( hash ) ) else prevN := eN(element); duplicate end addAValue ; % initialise the hash table % for h := 0 until HMOD - 1 do hashTable( h ) := null; % calculate the values of the sequence until we have found values that % % include all numbers in 1..1000 % % also store the first 15 values % A( 0 ) := An1 := n := 0; le1000Count := 0; maxS := firstN := duplicateN := duplicateValue := -1; while le1000Count < 1000 do begin logical le0, duplicate; n := n + 1; An := An1 - n; le0 := ( An <= 0 ); if le0 then An := An1 + n; prevN := -1; duplicate := addAValue( n, An, prevN ); if duplicate and not le0 then begin An := An1 + n; duplicate := addAValue( n, An, prevN ) end if_duplicate_and_not_le0 ; if duplicate then begin % the value was already present % if firstN < 0 then begin % have the first duplicate % firstN := n; duplicateN := prevN; duplicateValue := An; end if_firstN_lt_0 end else if An <= 1000 then le1000Count := le1000Count + 1;; if n < 15 then A( n ) := An; if An > maxS then maxS := An; An1 := An end while_le1000Count_lt_1000 ; % show the first 15 values of the sequence % write( "A( 0 .. 14 ): " ); for n := 0 until 14 do writeon( i_w := 1, A( n ) ); % positions of the first duplicate % write( i_w := 1 , s_w := 0 , "First duplicates: " , duplicateN , " " , firstN , " (" , duplicateValue , ")" ); % number of elements required to include the first 1000 integers % write( i_w := 1, "first element to include all 1..1000: ", n ); write( i_w := 1, "max sequence value encountered: ", maxS ) end end.</syntaxhighlight> {{out}} <pre> A( 0 .. 14 ): 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicates: 20 24 (42) first element to include all 1..1000: 328002 max sequence value encountered: 1942300 </pre> =={{header\|APL}}== {{works with\|Dyalog APL}} <syntaxhighlight lang="apl">recaman←{⎕IO←0 genNext←{ R←⍵[N-1]-N←≢⍵ (R<0)∨(R∊⍵):⍵,⍵[N-1]+N ⍵,⍵[N-1]-N } ~~return~~⎕←'First ~~-1;~~15: ' ⎕←reca←(genNext⍣14),0 } ⎕←'First repetition: ' ⎕←⊃⌽reca←genNext⍣{⍺≢∪⍺}⊢reca ⎕←'Length of sequence containing [0..1000]:' ⎕←≢reca←genNext⍣{(⍳1001)∧.∊⊂⍺}⊢reca }</syntaxhighlight> {{out}} ~~void init() {~~ ~~int i;~~ <pre>First 15: ~~used[0] = TRUE;~~ 0 1 3 6 ~~for~~2 (i7 =13 1;20 i12 <=21 ~~1000;~~11 ~~++i)~~22 ~~used[i]~~10 =23 ~~FALSE;~~9 First repetition: 42 Length of sequence containing [0..1000]: 328003</pre> =={{header\|AppleScript}}== The third of these tasks probably stretches Applescript a bit beyond the point of its usefulness – it takes about 1 minute to find the result, and even that requires the use of NSMutableSet, from the Apple Foundation classes. <syntaxhighlight lang="applescript">use AppleScript version "2.4" use framework "Foundation" use scripting additions on run -- FIRST FIFTEEN RECAMANs ------------------------------------------------------ script term15 on \|λ\|(i) 15 = (i as integer) end \|λ\| end script set strFirst15 to unwords(snd(recamanUpto(true, term15))) set strFirstMsg to "First 15 Recamans:" & linefeed display notification strFirstMsg & strFirst15 delay 2 -- FIRST DUPLICATE RECAMAN ---------------------------------------------------- script firstDuplicate on \|λ\|(_, seen, rs) setSize(seen) as integer is not (length of (rs as list)) end \|λ\| end script set strDuplicate to (item -1 of snd(recamanUpto(true, firstDuplicate))) as integer as string set strDupMsg to "First duplicated Recaman:" & linefeed display notification strDupMsg & strDuplicate delay 2 -- NUMBER OF RECAMAN TERMS NEEDED TO GET ALL OF [0..1000] -- (takes about a minute, depending on system) set setK to setFromList(enumFromTo(0, 1000)) script supersetK on \|λ\|(i, setR) setK's isSubsetOfSet:(setR) end \|λ\| end script display notification "Superset size result will take c. 1 min to find ..." set dteStart to current date set strSetSize to (fst(recamanUpto(false, supersetK)) - 1) as string set dteEnd to current date set strSetSizeMsg to "Number of Recaman terms needed to generate" & ¬ linefeed & "all integers from [0..1000]:" & linefeed set strElapsed to "(Last result took c. " & (dteEnd - dteStart) & " seconds to find)" display notification strSetSizeMsg & linefeed & strSetSize -- CLEARED REFERENCE TO NSMUTABLESET ------------------------------------- set setK to missing value -- REPORT ---------------------------------------------------------------- unlines({strFirstMsg & strFirst15, "", ¬ strDupMsg & strDuplicate, "", ¬ strSetSizeMsg & strSetSize, "", ¬ strElapsed}) end run -- nextR :: Set Int -> Int -> Int on nextR(seen, i, n) set bk to n - i if 0 > bk or setMember(bk, seen) then n + i else bk end if end nextR -- recamanUpto :: Bool -> (Int -> Set Int > [Int] -> Bool) -> (Int, [Int]) on recamanUpto(bln, p) script recaman property mp : mReturn(p)'s \|λ\| on \|λ\|() set i to 1 set r to 0 set rs to {r} set seen to setFromList(rs) repeat while not mp(i, seen, rs) set r to nextR(seen, i, r) setInsert(r, seen) if bln then set end of rs to r set i to i + 1 end repeat set seen to missing value -- clear pointer to NSMutableSet {i, rs} end \|λ\| end script recaman's \|λ\|() end recamanUpto -- GENERIC FUNCTIONS ------------------------------------------------------- -- enumFromTo :: Int -> Int -> [Int] on enumFromTo(m, n) if m ≤ n then set lst to {} repeat with i from m to n set end of lst to i end repeat return lst else return {} end if end enumFromTo -- fst :: (a, b) -> a on fst(tpl) if class of tpl is record then \|1\| of tpl else item 1 of tpl end if end fst -- intercalateS :: String -> [String] -> String on intercalateS(sep, xs) set {dlm, my text item delimiters} to {my text item delimiters, sep} set s to xs as text set my text item delimiters to dlm return s end intercalateS -- Lift 2nd class handler function into 1st class script wrapper -- mReturn :: First-class m => (a -> b) -> m (a -> b) on mReturn(f) if class of f is script then f else script property \|λ\| : f end script end if end mReturn -- NB All names of NSMutableSets should be set to missing value -- before the script exits. -- ( scpt files containing residual ObjC pointer values can not be saved) -- setFromList :: Ord a => [a] -> Set a on setFromList(xs) set ca to current application ca's NSMutableSet's ¬ setWithArray:(ca's NSArray's arrayWithArray:(xs)) end setFromList -- setMember :: Ord a => a -> Set a -> Bool on setMember(x, objcSet) missing value is not (objcSet's member:(x)) end setMember -- setInsert :: Ord a => a -> Set a -> Set a on setInsert(x, objcSet) objcSet's addObject:(x) objcSet end setInsert -- setSize :: Set a -> Int on setSize(objcSet) objcSet's \|count\|() as integer end setSize -- snd :: (a, b) -> b on snd(tpl) if class of tpl is record then \|2\| of tpl else item 2 of tpl end if end snd -- unlines :: [String] -> String on unlines(xs) set {dlm, my text item delimiters} to ¬ {my text item delimiters, linefeed} set str to xs as text set my text item delimiters to dlm str end unlines -- unwords :: [String] -> String on unwords(xs) intercalateS(space, xs) end unwords</syntaxhighlight> {{Out}} <pre>First 15 Recamans: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicated Recaman: 42 Number of Recaman terms needed to generate all integers from [0..1000]: 328002 (Last result took c. 40 seconds to find)</pre> =={{header\|Arturo}}== {{trans\|Python}} <syntaxhighlight lang="rebol">recamanSucc: function [seen, n, r].memoize[ back: r - n (or? 0 > back contains? seen back)? -> n + r -> back ] recamanUntil: function [p][ n: new 1 r: 0 rs: new @[r] seen: rs blnNew: true while [not? do p][ r: recamanSucc seen n r blnNew: not? in? r seen seen: unique seen ++ r 'rs ++ r inc 'n ] return rs ] print "First 15 Recaman numbers:" print recamanUntil [n = 15] print "" print "First duplicate Recaman number:" print last recamanUntil [not? blnNew]</syntaxhighlight> {{out}} <pre>First 15 Recaman numbers: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicate Recaman number: 42</pre> =={{header\|AWK}}== <syntaxhighlight lang="awk"> # syntax: GAWK -f RECAMANS_SEQUENCE.AWK # converted from Microsoft Small Basic BEGIN { found_dup = 0 n = -1 do { n++ ap = a[n-1] + n if (a[n-1] <= n) { a[n] = ap b[ap] = 1 } else { am = a[n-1] - n if (b[am] == 1) { a[n] = ap b[ap] = 1 } else { a[n] = am b[am] = 1 } } if (n <= 14) { terms = sprintf("%s%s ",terms,a[n]) if (n == 14) { printf("first %d terms: %s\n",n+1,terms) } } if (!found_dup) { if (dup[a[n]] == 1) { printf("first duplicated term: a[%d]=%d\n",n,a[n]) found_dup = 1 } dup[a[n]] = 1 } if (a[n] <= 1000) { arr[a[n]] = "" } } while (n <= 15 \|\| !found_dup \|\| length(arr) < 1001) printf("terms needed to generate integers 0 - 1000: %d\n",n) exit(0) } </syntaxhighlight> {{out}} <pre> first 15 terms: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 first duplicated term: a[24]=42 terms needed to generate integers 0 - 1000: 328002 </pre> =={{header\|BASIC}}== <syntaxhighlight lang="gwbasic">10 DEFINT A-Z: DIM A(100) 20 PRINT "First 15 terms:" 30 FOR N=0 TO 14: GOSUB 100: PRINT A(N);: NEXT 35 PRINT 40 PRINT "First repeated term:" 50 GOSUB 100 55 FOR M=0 TO N-1: IF A(M)=A(N) THEN 70 ELSE NEXT 60 N=N+1: GOTO 50 70 PRINT "A(";N;") =";A(N) 80 END 100 IF N=0 THEN A(0)=0: RETURN 110 X = A(N-1)-N: IF X<0 THEN 160 120 FOR M=0 TO N-1 130 IF A(M)=X THEN 160 140 NEXT 150 A(N)=X: RETURN 160 A(N)=A(N-1)+N: RETURN</syntaxhighlight> {{out}} <pre>First 15 terms: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First repeated term: A( 24 ) = 42</pre> ==={{header\|Applesoft BASIC}}=== {{trans\|BASIC}} {{works with\|Chipmunk Basic}} {{works with\|QBasic}} <syntaxhighlight lang="qbasic">10 DIM A(100) 20 PRINT "First 15 terms:" 30 FOR N=0 TO 14: GOSUB 100: PRINT A(N); " ";: NEXT 35 PRINT 40 PRINT "First repeated term:" 50 GOSUB 100 55 FOR M=0 TO N-1 56 IF A(M)=A(N) THEN 70 57 NEXT 60 N=N+1: GOTO 50 70 PRINT "A(";N;") = ";A(N) 80 END 100 IF N=0 THEN A(0)=0: RETURN 110 X = A(N-1)-N: IF X<0 THEN 160 120 FOR M=0 TO N-1 130 IF A(M)=X THEN 160 140 NEXT 150 A(N)=X: RETURN 160 A(N)=A(N-1)+N: RETURN</syntaxhighlight> ==={{header\|Chipmunk Basic}}=== {{works with\|Chipmunk Basic\|3.6.4}} The [[#BASIC\|BASIC]] solution works without any changes. ==={{header\|GW-BASIC}}=== {{works with\|PC-BASIC\|any}} {{works with\|BASICA}} The [[#BASIC\|BASIC]] solution works without any changes. ==={{header\|Minimal BASIC}}=== {{trans\|BASIC}} {{works with\|Quite BASIC}} <syntaxhighlight lang="qbasic">10 DIM A(100) 20 PRINT "FIRST 15 TERMS:" 30 FOR N=0 TO 14 40 GOSUB 170 50 PRINT A(N);" "; 60 NEXT N 70 PRINT 80 PRINT "FIRST REPEATED TERM:" 90 GOSUB 170 100 FOR M=0 TO N-1 110 IF A(M)=A(N) THEN 150 120 NEXT M 130 LET N=N+1 140 GOTO 90 150 PRINT "A(";N;") = ";A(N) 160 STOP 170 IF N=0 THEN 280 180 LET X = A(N-1)-N 190 IF X<0 THEN 250 200 FOR M=0 TO N-1 210 IF A(M)=X THEN 250 220 NEXT M 230 LET A(N)=X 240 RETURN 250 LET A(N)=A(N-1)+N 260 RETURN 270 STOP 280 LET A(0)=0 290 RETURN 300 END</syntaxhighlight> ==={{header\|MSX Basic}}=== {{works with\|MSX BASIC\|any}} The [[#BASIC\|BASIC]] solution works without any changes. ==={{header\|Quite BASIC}}=== The [[#Minimal BASIC\|Minimal BASIC]] solution works without any changes. =={{header\|BCPL}}== <syntaxhighlight lang="bcpl">get "libhdr" // Generate the N'th term of the Recaman sequence // given terms 0 to N-1. let generate(a, n) be a!n := n=0 -> 0, valof $( let subterm = a!(n-1) - n let addterm = a!(n-1) + n if subterm <= 0 resultis addterm for i=0 to n-1 if a!i = subterm resultis addterm resultis subterm $) let start() be $( let a = vec 50 and n = 15 and rep = ? writef("First %N members:N", n) for i = 0 to n-1 $( generate(a, i) writef("%N ", a!i) $) writef("NFirst repeated term:N") rep := valof $( generate(a, n) for i = 0 to n-1 if a!i = a!n resultis n n := n + 1 $) repeat writef("a!%N = %NN", rep, a!rep) $)</syntaxhighlight> {{out}} <pre>First 15 members: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First repeated term: a!24 = 42</pre> =={{header\|C}}== {{libheader\|GLib}} {{trans\|Go}} <syntaxhighlight lang="c">#include <stdio.h> #include <stdlib.h> #include <gmodule.h> typedef int bool; int main() { int i, n, k = 0, next, a; bool foundDup = FALSE; gboolean alreadyUsed; ~~init();~~ GHashTable used = g_hash_table_new(g_direct_hash, g_direct_equal); GHashTable* used1000 = g_hash_table_new(g_direct_hash, g_direct_equal); a = malloc(400000 * sizeof(int)); a[0] = 0; g_hash_table_add(used, GINT_TO_POINTER(0)); ~~for (n = 1; n <= 15 \|\| !foundDup \|\| k != -1; ++n) {~~ g_hash_table_add(used1000, GINT_TO_POINTER(0)); for (n = 1; n <= 15 \|\| !foundDup \|\| k < 1001; ++n) { next = a[n - 1] - n; if (next < 1 \|\| ~~contains~~g_hash_table_contains(aused, GINT_TO_POINTER(next~~, n~~))) { next += 2 * n; } alreadyUsed = g_hash_table_contains(used, GINT_TO_POINTER(next)); a[n] = next; ~~if (next >= 0 && next <= 1000) used[next] = TRUE;~~ if (!alreadyUsed) { g_hash_table_add(used, GINT_TO_POINTER(next)); if (next >= 0 && next <= 1000) { g_hash_table_add(used1000, GINT_TO_POINTER(next)); } } if (n == 14) { printf("The first 15 terms of the Recaman's sequence are: "); Line 69 ⟶ 663: printf("\b]\n"); } ~~if (!foundDup && contains(a, next, n)) {~~ if (!foundDup && alreadyUsed) { printf("The first duplicated term is a[%d] = %d\n", n, next); foundDup = TRUE; } k = ~~firstFalse~~g_hash_table_size(kused1000); ~~if (k == -1) {~~ if (k == 1001) { printf("Terms up to a[%d] are needed to generate 0 to 1000\n", n); } } g_hash_table_destroy(used); g_hash_table_destroy(used1000); free(a); return 0; }</~~lang~~syntaxhighlight> {{out}} Line 89 ⟶ 687: </pre> =={{header\|GoC sharp\|C#}}== {{trans\|Kotlin}} ~~<lang go>package main~~ <syntaxhighlight lang="csharp">using System; using System.Collections.Generic; namespace RecamanSequence { ~~import "fmt"~~ class Program { static void Main(string[] args) { ~~func contains(a []int, b int) bool {~~ ~~for~~ _, j := ~~range~~ List<int> a = new List<int>() { 0 }; if j = HashSet<int> used = bnew HashSet<int>() { 0 }; ~~return~~HashSet<int> ~~true~~used1000 = new HashSet<int>() { 0 }; bool foundDup = false; int n = 1; while (n <= 15 \|\| !foundDup \|\| used1000.Count < 1001) { int next = a[n - 1] - n; if (next < 1 \|\| used.Contains(next)) { next += 2 * n; } bool alreadyUsed = used.Contains(next); a.Add(next); if (!alreadyUsed) { used.Add(next); if (0 <= next && next <= 1000) { used1000.Add(next); } } if (n == 14) { Console.WriteLine("The first 15 terms of the Recaman sequence are: [{0}]", string.Join(", ", a)); } if (!foundDup && alreadyUsed) { Console.WriteLine("The first duplicated term is a[{0}] = {1}", n, next); foundDup = true; } if (used1000.Count == 1001) { Console.WriteLine("Terms up to a[{0}] are needed to generate 0 to 1000", n); } n++; } } } }</syntaxhighlight> ~~return false~~ {{out}} <pre>The first 15 terms of the Recaman sequence are: [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] The first duplicated term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000</pre> =={{header\|C++}}== {{trans\|C#}} <syntaxhighlight lang="cpp">#include <iostream> #include <ostream> #include <set> #include <vector> template<typename T> std::ostream& operator<<(std::ostream& os, const std::vector<T>& v) { auto i = v.cbegin(); auto e = v.cend(); os << '['; if (i != e) { os << i; i = std::next(i); } while (i != e) { os << ", " << i; i = std::next(i); } return os << ']'; } int main() { using namespace std; vector<int> a{ 0 }; set<int> used{ 0 }; set<int> used1000{ 0 }; bool foundDup = false; int n = 1; while (n <= 15 \|\| !foundDup \|\| used1000.size() < 1001) { int next = a[n - 1] - n; if (next < 1 \|\| used.find(next) != used.end()) { next += 2 * n; } bool alreadyUsed = used.find(next) != used.end(); a.push_back(next); if (!alreadyUsed) { used.insert(next); if (0 <= next && next <= 1000) { used1000.insert(next); } } if (n == 14) { cout << "The first 15 terms of the Recaman sequence are: " << a << '\n'; } if (!foundDup && alreadyUsed) { cout << "The first duplicated term is a[" << n << "] = " << next << '\n'; foundDup = true; } if (used1000.size() == 1001) { cout << "Terms up to a[" << n << "] are needed to generate 0 to 1000\n"; } n++; } return 0; }</syntaxhighlight> {{out}} <pre>The first 15 terms of the Recaman sequence are: [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] The first duplicated term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000</pre> =={{header\|CLU}}== <syntaxhighlight lang="clu">% Recaman sequence recaman = cluster is new, fetch rep = array[int] new = proc () returns (cvt) a: rep := rep$predict(0,1000000) rep$addh(a,0) return(a) end new % Find the N'th element of the Recaman sequence fetch = proc (a: cvt, n: int) returns (int) if n > rep$high(a) then extend(a,n) end return(a[n]) end fetch % See if N has already been generated prev = proc (a: rep, n: int) returns (bool) for el: int in rep$elements(a) do if el = n then return(true) end end return(false) end prev % Generate members of the sequence until 'top' is reached extend = proc (a: rep, top: int) while rep$high(a) < top do n: int := rep$high(a) + 1 sub: int := a[n-1] - n add: int := a[n-1] + n if sub>0 cand ~prev(a, sub) then rep$addh(a, sub) else rep$addh(a, add) end end end extend end recaman start_up = proc () po: stream := stream$primary_output() A: recaman := recaman$new() % Print the first 15 members stream$puts(po, "First 15 items:") for i: int in int$from_to(0, 14) do stream$puts(po, " " \|\| int$unparse(A[i])) end % Find the first duplicated number begin i: int := 0 while true do i := i + 1 for j: int in int$from_to(0, i-1) do if A[i]=A[j] then exit found(i, A[i]) end end end end except when found(i, n: int): stream$putl(po, "\nFirst duplicated number: A(" \|\| int$unparse(i) \|\| ") = " \|\| int$unparse(n)) end % Find the amount of terms needed to generate all integers 0..1000 begin seen: array[bool] := array[bool]$fill(0,1001,false) left: int := 1001 n: int := -1 while left > 0 do n := n + 1 if A[n] <= 1000 cand ~seen[A[n]] then left := left - 1 seen[A[n]] := true end end stream$putl(po, "Terms needed to generate [0..1000]: " \|\| int$unparse(n)) end end start_up</syntaxhighlight> {{out}} <pre>First 15 items: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicated number: A(24) = 42 Terms needed to generate [0..1000]: 328002</pre> =={{header\|Comal}}== <syntaxhighlight lang="comal">0010 DIM a#(0:100) 0020 // 0030 // Print the first 15 items 0040 PRINT "First 15 items: ", 0050 FOR i#:=0 TO 14 DO PRINT reca#(i#); 0060 PRINT 0070 // 0080 // Find and print the first repeated item 0090 i#:=15 0100 WHILE NOT find#(i#,reca#(i#)) DO i#:+1 0110 PRINT "First repeated item: A(",i#,") = ",a#(i#) 0120 // 0130 // Generate the n'th member of the Recaman sequence 0140 FUNC reca#(n#) 0150 IF n#=0 THEN RETURN 0 0160 a#(n#):=a#(n#-1)-n# 0180 IF a#(n#)<=0 OR find#(n#,a#(n#)) THEN a#(n#):=a#(n#-1)+n# 0190 RETURN a#(n#) 0200 ENDFUNC reca# 0210 // 0220 // See if a number occurs before the n'th member of the Recaman sequence 0230 FUNC find#(n#,num#) 0240 FOR x#:=0 TO n#-1 DO IF a#(x#)=num# THEN RETURN x# 0250 RETURN 0 0260 ENDFUNC find# 0270 END</syntaxhighlight> {{out}} <pre>First 15 items: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First repeated item: A(24) = 42</pre> =={{header\|COBOL}}== <syntaxhighlight lang="cobol"> IDENTIFICATION DIVISION. PROGRAM-ID. RECAMAN. DATA DIVISION. WORKING-STORAGE SECTION. 01 RECAMAN-SEQUENCE COMP. 02 A PIC 999 OCCURS 99 TIMES INDEXED BY I. 02 N PIC 999 VALUE 0. 01 VARIABLES COMP. 02 ADDC PIC S999. 02 SUBC PIC S999. 02 SPTR PIC 99 VALUE 1. 01 OUTPUT-FORMAT. 02 OUTI PIC Z9. 02 OUTN PIC BZ9. 02 OUTS PIC X(79). PROCEDURE DIVISION. BEGIN. PERFORM GENERATE-NEXT-ITEM 15 TIMES. PERFORM COLLATE-ITEM VARYING I FROM 1 BY 1 UNTIL I IS GREATER THAN 15. DISPLAY 'First 15 items:' OUTS. FIND-REPEATING. PERFORM GENERATE-NEXT-ITEM. SET I TO 1. SEARCH A VARYING I WHEN I IS NOT LESS THAN N NEXT SENTENCE WHEN A(I) IS EQUAL TO A(N) SUBTRACT 1 FROM N GIVING OUTI MOVE A(N) TO OUTN DISPLAY 'First repeated item: A(' OUTI ') =' OUTN STOP RUN. GO TO FIND-REPEATING. GENERATE-NEXT-ITEM. IF N IS EQUAL TO ZERO MOVE ZERO TO A(1) ELSE ADD N, A(N) GIVING ADDC SUBTRACT N FROM A(N) GIVING SUBC IF SUBC IS NOT GREATER THAN ZERO MOVE ADDC TO A(N + 1) ELSE SET I TO 1 SEARCH A VARYING I WHEN I IS NOT LESS THAN N MOVE SUBC TO A(N + 1) WHEN A(I) IS EQUAL TO SUBC MOVE ADDC TO A(N + 1). ADD 1 TO N. COLLATE-ITEM. MOVE A(I) TO OUTN. STRING OUTN DELIMITED BY SIZE INTO OUTS WITH POINTER SPTR.</syntaxhighlight> {{out}} <pre>First 15 items: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First repeated item: A(24) = 42</pre> =={{header\|D}}== {{trans\|Kotlin}} <syntaxhighlight lang="d">import std.stdio; void main() { int[] a; bool[int] used; bool[int] used1000; bool foundDup; a ~= 0; used[0] = true; used1000[0] = true; int n = 1; while (n <= 15 \|\| !foundDup \|\| used1000.length < 1001) { int next = a[n - 1] - n; if (next < 1 \|\| (next in used) !is null) { next += 2 * n; } bool alreadyUsed = (next in used) !is null; a ~= next; if (!alreadyUsed) { used[next] = true; if (0 <= next && next <= 1000) { used1000[next] = true; } } if (n == 14) { writeln("The first 15 terms of the Recaman sequence are: ", a); } if (!foundDup && alreadyUsed) { writefln("The first duplicated term is a[%d] = %d", n, next); foundDup = true; } if (used1000.length == 1001) { writefln("Terms up to a[%d] are needed to generate 0 to 1000", n); } n++; } }</syntaxhighlight> {{out}} <pre>The first 15 terms of the Recaman sequence are: [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] The first duplicated term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000</pre> =={{header\|Draco}}== <syntaxhighlight lang="draco">proc nonrec find([] int A; word top; int n) bool: word i; bool found; i := 0; found := false; while i < top and not found do found := A[i] = n; i := i + 1 od; found corp proc nonrec gen_next([] int A; word n) int: int add, sub; add := A[n-1] + n; sub := A[n-1] - n; A[n] := if sub > 0 and not find(A, n, sub) then sub else add fi; A[n] corp proc nonrec main() void: [30] int A; word i; A[0] := 0; write("First 15 items: 0"); for i from 1 upto 14 do write(gen_next(A, i):3) od; writeln(); while not find(A, i, gen_next(A, i)) do i := i + 1 od; writeln("First repeated item: A(", i:2, ") = ", A[i]:2) corp </syntaxhighlight> {{out}} <pre>First 15 items: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First repeated item: A(24) = 42</pre> =={{header\|EasyLang}}== <syntaxhighlight lang="easylang"> arrbase a[] 0 arrbase seen[] 0 len seen[] 100 # a[] &= 0 seen[0] = 1 i = 1 repeat h = a[i - 1] - i if h <= 0 or seen[h] = 1 h = a[i - 1] + i . until seen[h] = 1 seen[h] = 1 a[] &= h if i = 14 print a[] . i += 1 . print h </syntaxhighlight> =={{header\|Forth}}== {{works with\|gforth\|0.7.3}} <syntaxhighlight lang="forth">: array ( n -- ) ( i -- addr) create cells allot does> swap cells + ; 100 array sequence : sequence. ( n -- ) cr 0 ?do i sequence @ . loop ; : ?unused ( n -- t \| n ) 100 0 ?do dup i sequence @ = if unloop exit then loop drop true ; : sequence-next ( n -- a[n] ) dup 0= if 0 0 sequence ! exit then ( case a[0]=0 ) dup dup 1- sequence @ swap - ( a[n]=a[n-1]-n ) dup dup 0> swap ?unused true = and if nip exit then drop dup 1- sequence @ swap + ; ( a[n]=a[n-1]+n ) : sequence-gen ( n -- ) 0 ?do i sequence-next i sequence ! loop ; : sequence-repeated 100 0 ?do i 0 ?do i sequence @ j sequence @ = if cr ." first repeated : a[" i . ." ]=a[" j . ." ]=" i sequence @ . unloop unloop exit then loop loop ; 100 sequence-gen 15 sequence. sequence-repeated</syntaxhighlight> {{out}} <pre>0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 first repeated : a[20 ]=a[24 ]=42 ok</pre> =={{header\|FreeBASIC}}== <syntaxhighlight lang="freebasic">' version 26-01-2019 ' compile with: fbc -s console Dim As UByte used() Dim As Integer sum, temp Dim As UInteger n, max, count, i max = 1000 : ReDim used(max) Print "The first 15 terms are 0"; For n = 0 To 14 temp = sum - n If temp < 1 OrElse used(temp) = 1 Then temp = sum + n End If If temp <= max Then used(temp) = 1 sum = temp Print sum; Next sum = 0 : max = 1000 : ReDim used(max) Print : Print For n = 0 To 50 temp = sum - n If temp < 1 OrElse used(temp) = 1 Then temp = sum + n End If If used(temp) = 1 Then Print "First duplicated number is a(" + Str(n) + ")" Exit For End If If temp <= max Then used(temp) = 1 sum = temp Next sum = 0 : max = 2000000 : ReDim used(max) Print : Print For n = 0 To max temp = sum - n If temp < 1 OrElse used(temp) = 1 Then temp = sum + n End If If temp <= max Then used(temp) = 1 If i = temp Then While used(i) = 1 i += 1 If i > 1000 Then Exit For End If Wend End If sum = temp count += 1 Next Print "All integers from 0 to 1000 are generated in " & count & " terms" Print ' empty keyboard buffer While Inkey <> "" : Wend Print : Print "hit any key to end program" Sleep End</syntaxhighlight> {{out}} <pre>The first 15 terms are 0 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicated number is a(24) All integers from 0 to 1000 are generated in 328002 terms</pre> =={{header\|FOCAL}}== <syntaxhighlight lang="focal">01.10 T "FIRST 15" 01.20 F N=0,14;D 2;T %2,A(N) 01.30 T !"FIRST REPEATED" 01.40 D 2;S Y=1 01.50 F M=0,N-1;S Y=Y(A(M)-A(N)) 01.60 I (Y)1.7,1.8,1.7 01.70 S N=N+1;G 1.4 01.80 T A(N)," AT A(",N,")"! 01.90 Q 02.05 I (N)2.1,2.06,2.1 02.06 A(0)=0;R 02.10 S X=A(N-1)-N 02.20 I (X)2.7 02.30 S Y=1 02.40 F M=0,N-1;S Y=Y(A(M)-X) 02.50 I (Y)2.6,2.7,2.6 02.60 S A(N)=X;R 02.70 S A(N)=A(N-1)+N</syntaxhighlight> {{out}} <pre>FIRST 15= 0= 1= 3= 6= 2= 7= 13= 20= 12= 21= 11= 22= 10= 23= 9 FIRST REPEATED= 42 AT A(= 24)</pre> =={{header\|Fōrmulæ}}== {{FormulaeEntry\|page=https://formulae.org/?script=examples/Recam%C3%A1n%27s_sequence}} '''Solution''' The following snippet generates the Recaman's sequence of a given number of terms: [[File:Fōrmulæ - Recamán's sequence 01.png]] '''Case 1''' * Generate and show here the first 15 members of the sequence. * Find and show here, the first duplicated number in the sequence. * Optionally. Find and show here, How many terms of the sequence are needed until all the integers 0..1000, inclusive, are generated. [[File:Fōrmulæ - Recamán's sequence 02.png]] [[File:Fōrmulæ - Recamán's sequence 03.png]] [[File:Fōrmulæ - Recamán's sequence 04.png]] '''Case 2. Plotting the sequence''' [[File:Fōrmulæ - Recamán's sequence 05.png]] [[File:Fōrmulæ - Recamán's sequence 06.png]] '''Case 3. Drawing the sequence as it was shown in the Numberphile video''' [[File:Fōrmulæ - Recamán's sequence 07.png]] [[File:Fōrmulæ - Recamán's sequence 08.png]] [[File:Fōrmulæ - Recamán's sequence 09.png]] =={{header\|Go}}== <syntaxhighlight lang="go">package main import "fmt" func main() { Line 107 ⟶ 1,282: used := make(map[int]bool, 1001) used[0] = true used1000 := make(map[int]bool, 1001) ~~for n, foundDup := 1, false; n <= 15 \|\| !foundDup \|\| len(used) < 1001; n++ {~~ used1000[0] = true for n, foundDup := 1, false; n <= 15 \|\| !foundDup \|\| len(used1000) < 1001; n++ { next := a[n-1] - n if next < 1 \|\| ~~contains(a,~~ used[next)] { next += 2 * n } alreadyUsed := used[next] a = append(a, next) ~~if next >= 0 && next <= 1000 {~~ if !alreadyUsed { used[next] = true if next >= 0 && next <= 1000 { used1000[next] = true } } if n == 14 { fmt.Println("The first 15 terms of the Recaman's sequence are:", a) } ~~if !foundDup && contains(a[:n], next) {~~ if !foundDup && alreadyUsed { fmt.Printf("The first duplicated term is a[%d] = %d\n", n, next) foundDup = true } ~~if len(used) == 1001 {~~ if len(used1000) == 1001 { fmt.Printf("Terms up to a[%d] are needed to generate 0 to 1000\n", n) } } }</~~lang~~syntaxhighlight> {{out}} Line 137 ⟶ 1,322: =={{header\|Haskell}}== ===Recursion=== ~~<lang haskell>import Data.List (find)~~ A basic recursive function for the first N terms, ~~import Data.Maybe (isNothing)~~ <syntaxhighlight lang="haskell">recaman :: Int -> [Int] ~~recaman :: Int -> [Int]~~ recaman n = fst <$> reverse (go n) where go x0 = [] \|go 1 ~~> x~~ = [(0, 1)] ~~\| 1 ==~~go x = ~~[(0, 1)]~~ ~~\| otherwise =~~ let xs@((r, i):_) = go (pred x) back = r - i in ( if 0 < back && ~~isNothing~~not (~~find~~any ((back ==) . fst) xs) then back else r + i Line 156 ⟶ 1,339: main :: IO () main = print $ recaman 15</~~lang~~syntaxhighlight> {{Out}} <pre>[0,1,3,6,2,7,13,20,12,21,11,22,10,23,9]</pre> ===Conditional iteration=== Or, a little more flexibly, a '''recamanUpto''' (predicate) function. {{Trans\|JavaScript}} <syntaxhighlight lang="haskell">import Data.Set (Set, fromList, insert, isSubsetOf, member, size) import Data.Bool (bool) firstNRecamans :: Int -> [Int] firstNRecamans n = reverse $ recamanUpto (\(_, i, _) -> n == i) firstDuplicateR :: Int firstDuplicateR = head $ recamanUpto (\(rs, _, set) -> size set /= length rs) recamanSuperset :: Set Int -> [Int] recamanSuperset setInts = tail $ recamanUpto (\(_, _, setR) -> isSubsetOf setInts setR) recamanUpto :: (([Int], Int, Set Int) -> Bool) -> [Int] recamanUpto p = rs where (rs, _, _) = until p (\(rs@(r:_), i, seen) -> let n = nextR seen i r in (n : rs, succ i, insert n seen)) ([0], 1, fromList [0]) nextR :: Set Int -> Int -> Int -> Int nextR seen i r = let back = r - i in bool back (r + i) (0 > back \|\| member back seen) -- TEST --------------------------------------------------------------- main :: IO () main = (putStrLn . unlines) [ "First 15 Recamans:" , show $ firstNRecamans 15 , [] , "First duplicated Recaman:" , show firstDuplicateR , [] , "Length of Recaman series required to include [0..1000]:" , (show . length . recamanSuperset) $ fromList [0 .. 1000] ]</syntaxhighlight> {{Out}} <pre>First 15 Recamans: [0,1,3,6,2,7,13,20,12,21,11,22,10,23,9] First duplicated Recaman: 42 Length of Recaman series required to include [0..1000]: 328002</pre> ===Lazy search over infinite lists=== For a lazier solution, we could define an infinite series of Recaman sequences of growing length, starting with '''[0]''', and simply search through them for the first series of length 15, or the first to include a duplicated integer. For the third task, it would be enough to search through an infinite stream of Recaman-generated integer '''sets''' of increasing size, until we find the first that contains [0..1000] as a subset. <syntaxhighlight lang="haskell">import Data.List (find, findIndex, nub) import Data.Maybe (fromJust) import Data.Set (Set, fromList, insert, isSubsetOf, member) --- INFINITE STREAM OF RECAMAN SERIES OF GROWING LENGTH -- rSeries :: [[Int]] rSeries = scanl ( \rs@(r : _) i -> let back = r - i nxt \| 0 > back \|\| elem back rs = r + i \| otherwise = back in nxt : rs ) [0] [1 ..] ----------- INFINITE STREAM OF RECAMAN-GENERATED --------- --------------- INTEGER SETS OF GROWING SIZE ------------- rSets :: [(Set Int, Int)] rSets = scanl ( \(seen, r) i -> let back = r - i nxt \| 0 > back \|\| member back seen = r + i \| otherwise = back in (insert nxt seen, nxt) ) (fromList [0], 0) [1 ..] --------------------------- TEST ------------------------- main :: IO () main = do let setK = fromList [0 .. 1000] (putStrLn . unlines) [ "First 15 Recamans:", show . reverse . fromJust $ find ((15 ==) . length) rSeries, [], "First duplicated Recaman:", show . head . fromJust $ find ((/=) <$> length <> (length . nub)) rSeries, [], "Length of Recaman series required to include [0..1000]:", show . fromJust $ findIndex (\(setR, _) -> isSubsetOf setK setR) rSets ]</syntaxhighlight> {{Out}} <pre>First 15 Recamans: [0,1,3,6,2,7,13,20,12,21,11,22,10,23,9] First duplicated Recaman: 42 Length of Recaman series required to include [0..1000]: 328002</pre> =={{header\|J}}== <pre> positive =: >&0 unique =: -.@:e. condition =: (positive@:] . unique~) ({: - #) NB. with the agenda set by the condition, add or subtract tail with tally recaman_term =: ({: + #)`({: - #)@.condition NB. generate four hundred thousand terms and display the first 15 15 {. R=:(, recaman_term)^:400000]0 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 NB. plot the sequence to see why numberphile might be interested. load'plot' plot 470{.R NB. binaryish search for first duplicate. (-:&# ~.) 100 {. R 0 (-:&# ~.) 50 {. R 0 (-:&# ~.) 25 {. R 0 (-:&# ~.) 12 {. R 1 (-:&# ~.) 18 {. R 1 (-:&# ~.) 21 {. R 1 (-:&# ~.) 23 {. R 1 (-:&# ~.) 24 {. R 1 (-:&# ~.) 25 {. R 0 </pre> Let's write a binary search adverb. <syntaxhighlight lang="j"> average =: +/ % # NB. extra_data u Bsearch bounds NB. Bsearch returns narrowed bounds depending if u return 0 (left) or 1 (right) NB. u is called as extra_data u index NB. or as index u index NB. u is invoked as a dyad Bsearch =: 1 :'((0 1 + (u <.@:average)) { ({. , <.@:average, {:)@:])^:_' </syntaxhighlight> <pre> NB. f expresses "not all [0, 1000] are in the first y members of list x" f =: ([: -. [: ./ (i.1001) e. ~.)@:{.~ R f Bsearch 0 , #R 328002 328003 (<: 328002 328003) { R 328881 879 </pre> The sequence begins 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 . With 0 as the first term, We've learned that 25 terms are required to generate a duplicate, and that 328003 terms are needed to generate 0 through 1000 inclusively. =={{header\|Java}}== {{Trans\|Kotlin}} <syntaxhighlight lang="java">import java.util.ArrayList; import java.util.HashSet; import java.util.List; import java.util.Set; public class RecamanSequence { public static void main(String[] args) { List<Integer> a = new ArrayList<>(); a.add(0); Set<Integer> used = new HashSet<>(); used.add(0); Set<Integer> used1000 = new HashSet<>(); used1000.add(0); boolean foundDup = false; int n = 1; while (n <= 15 \|\| !foundDup \|\| used1000.size() < 1001) { int next = a.get(n - 1) - n; if (next < 1 \|\| used.contains(next)) { next += 2 n; } boolean alreadyUsed = used.contains(next); a.add(next); if (!alreadyUsed) { used.add(next); if (0 <= next && next <= 1000) { used1000.add(next); } } if (n == 14) { System.out.printf("The first 15 terms of the Recaman sequence are : %s\n", a); } if (!foundDup && alreadyUsed) { System.out.printf("The first duplicate term is a[%d] = %d\n", n, next); foundDup = true; } if (used1000.size() == 1001) { System.out.printf("Terms up to a[%d] are needed to generate 0 to 1000\n", n); } n++; } } }</syntaxhighlight> {{out}} <pre>The first 15 terms of the Recaman sequence are : [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] The first duplicate term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000</pre> =={{header\|JavaScript}}== {{Trans\|Haskell}} <syntaxhighlight lang="javascript">(() => { const main = () => { console.log( 'First 15 Recaman:\n' + recamanUpto(i => 15 === i) ); console.log( '\n\nFirst duplicated Recaman:\n' + last(recamanUpto( (_, set, rs) => set.size !== rs.length )) ); const setK = new Set(enumFromTo(0, 1000)); console.log( '\n\nNumber of Recaman terms needed to generate' + '\nall integers from [0..1000]:\n' + (recamanUpto( (_, setR) => isSubSetOf(setK, setR) ).length - 1) ); }; // RECAMAN -------------------------------------------- // recamanUpto :: (Int -> Set Int > [Int] -> Bool) -> [Int] const recamanUpto = p => { let i = 1, r = 0, // First term of series rs = [r]; const seen = new Set(rs); while (!p(i, seen, rs)) { r = nextR(seen, i, r); seen.add(r); rs.push(r); i++; } return rs; } // Next Recaman number. // nextR :: Set Int -> Int -> Int const nextR = (seen, i, n) => { const back = n - i; return (0 > back \|\| seen.has(back)) ? ( n + i ) : back; }; // GENERIC -------------------------------------------- // enumFromTo :: Int -> Int -> [Int] const enumFromTo = (m, n) => m <= n ? iterateUntil( x => n <= x, x => 1 + x, m ) : []; // isSubsetOf :: Ord a => Set a -> Set a -> Bool const isSubSetOf = (a, b) => { for (let x of a) { if (!b.has(x)) return false; } return true; }; // iterateUntil :: (a -> Bool) -> (a -> a) -> a -> [a] const iterateUntil = (p, f, x) => { const vs = [x]; let h = x; while (!p(h))(h = f(h), vs.push(h)); return vs; }; // last :: [a] -> a const last = xs => 0 < xs.length ? xs.slice(-1)[0] : undefined; // MAIN ------------------------------------------------ return main(); })();</syntaxhighlight> {{Out}} <pre>First 15 Recaman: 0,1,3,6,2,7,13,20,12,21,11,22,10,23,9 First duplicated Recaman: 42 Number of Recaman terms needed to generate all integers from [0..1000]: 328002</pre> =={{header\|jq}}== {{works with\|jq}} '''Works with gojq, the Go implementation of jq''' Two jq solutions are provided here. The first is a monolithic "all-in-one" approach in which a single function or procedure does all the work in one pass. This approach has the disadvantage of neither providing or using reusable components. The second solution is a stream-oriented one that separates the generation of the sequence from other computations. This approach can be just as efficient as the monolithic approach, but for the sake of illustration, the solution offered here provides separate functions for generation and for each of the three specific tasks. === Monolithic approach=== '''Adapted from [[#Go\|Go]]''' The main point of potential interest in this implementation is that the main function only retains the first few elements of the sequence required to print them as an array. <syntaxhighlight lang="jq"> # Let R[n] be the Recaman sequence, n >= 0, so R[0]=0. # Input: a number, $required, specifying the required range of integers, [1 .. $required] # to be covered by R[0] ... R[.n] # $capture: the number of elements of the sequence to retain. # Output: an object as described below. # Note that .a\|length will be equal to $capture. # def recaman_required($capture): . as $required \| { n: 0, current: 0, # R[.n] previous: null, # R[.n-1] a: [0], # only maintained up to a[$capture-1] used: { "0": true }, # hash for checking whether a value has already occurred found: { "0": true }, # hash for checking how many in [0 .. $required] inclusive have been found nfound: 1, # .found\|length foundDup: null, # the first duplicated entry in the sequence foundDupAt: null # .foundDup == R[.foundDupAt] } \| until ((.n >= $capture) and .foundDup and (.nfound > $required); .n += 1 \| .current -= .n \| if (.current < 1 or .used[.current\|tostring]) then .current = .current + 2.n else . end \| (.current\|tostring) as $s \| .used[$s] as $alreadyUsed \| if .n < $capture then .a += [.current] else . end \| if ($alreadyUsed\|not) then .used[$s] = true \| if (.current >= 0 and .current <= $required) then .found[$s] = true \| .nfound+=1 else . end else . end \| if (.foundDup\|not) and $alreadyUsed then .foundDup = .current \| .foundDupAt = .n else . end ); 1000 as $required \| 15 as $capture \| $required \| recaman_required($capture) \| "The first \($capture) terms of Recaman's sequence are: \(.a)", "The first duplicated term is a[\(.foundDupAt)] = \(.foundDup)", "Terms up to a[\(.n)] are needed to generate 0 to \($required) inclusive."</syntaxhighlight> {{out}} <pre> The first 15 terms of Recaman's sequence are: [0,1,3,6,2,7,13,20,12,21,11,22,10,23,9] The first duplicated term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000 inclusive. </pre> === A stream-oriented solution=== <syntaxhighlight lang="jq"> # Output: the stream of elements in the Recaman sequence, beginning with 0. def recaman: 0, foreach range(1; infinite) as $i ({used: {"0": true}, current: 0}; (.current - $i) as $next \| .current = (if ($next < 1 or .used[$next\|tostring]) then $next + 2 $i else $next end) \| .used[.current\|tostring] = true; .current ); # emit [.i, $x] for duplicated terms using IO==0 def duplicated(s): foreach s as $x ({used: {}, i: -1}; .i += 1 \| ($x\|tostring) as $xs \| if .used[$xs] then .emit = [.i, $x] else .used[$xs] = true end; select(.emit) \| .emit); # Input: an integer, $required # s: a stream of non-negative integers # Output: the index of the item in the stream s at which the stream up to and including # that item includes all integers in the closed interval [0 .. $required]. # def covers(s): . as $required \| first(foreach s as $x ( { i: -1, found: {}, nfound: 0}; .i += 1 \| ($x\|tostring) as $xs \| if .found[$xs] then . elif $x <= $required then .found[$xs] = true \| .nfound += 1 \| if .nfound > $required then .emit=.i else . end else . end; select(.emit).emit) );</syntaxhighlight> '''The three tasks:''' <syntaxhighlight lang="jq"> "First 15:", limit(15; recaman), "\First duplicated:", first(duplicated(recaman)), "\Index of first element to include 0 to 1000 inclusive:", (1000\|covers(recaman)) </syntaxhighlight> {{out}} <pre> First 15: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicated: [24,42] Index of first element to include 0 to 1000 inclusive: 328002 </pre> =={{header\|Julia}}== {{trans\|Go}} <syntaxhighlight lang="julia">function recaman() a = Vector{Int}([0]) used = Dict{Int, Bool}(0 => true) used1000 = Set(0) founddup = false termcount = 1 while length(used1000) <= 1000 nextterm = a[termcount] - termcount if nextterm < 1 \|\| haskey(used, nextterm) nextterm += termcount + termcount end push!(a, nextterm) if !haskey(used, nextterm) used[nextterm] = true if 1 <= nextterm <= 1000 push!(used1000, nextterm) end elseif !founddup println("The first duplicated term is a[$(termcount + 1)] = $nextterm.") founddup = true end if termcount == 14 println("The first 15 terms of the Recaman sequence are $a") end termcount += 1 end println("Terms up to $(termcount - 1) are needed to generate 0 to 1000.") end recaman() </syntaxhighlight>{{output}}<pre> The first 15 terms of the Recaman sequence are [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] The first duplicated term is a[25] = 42. Terms up to 328002 are needed to generate 0 to 1000. </pre> =={{header\|Kotlin}}== {{trans\|Go}} <syntaxhighlight lang="scala">// Version 1.2.60 fun main(args: Array<String>) { val a = mutableListOf(0) val used = mutableSetOf(0) val used1000 = mutableSetOf(0) var foundDup = false var n = 1 while (n <= 15 \|\| !foundDup \|\| used1000.size < 1001) { var next = a[n - 1] - n if (next < 1 \|\| used.contains(next)) next += 2 * n val alreadyUsed = used.contains(next) a.add(next) if (!alreadyUsed) { used.add(next) if (next in 0..1000) used1000.add(next) } if (n == 14) { println("The first 15 terms of the Recaman's sequence are: $a") } if (!foundDup && alreadyUsed) { println("The first duplicated term is a[$n] = $next") foundDup = true } if (used1000.size == 1001) { println("Terms up to a[$n] are needed to generate 0 to 1000") } n++ } }</syntaxhighlight> {{output}} <pre> The first 15 terms of the Recaman's sequence are: [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] The first duplicated term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000 </pre> =={{header\|Lua}}== This runs out of memory determining the final part :( {{trans\|C++}} <syntaxhighlight lang="lua">local a = {[0]=0} local used = {[0]=true} local used1000 = {[0]=true} local foundDup = false local n = 1 while n<=15 or not foundDup or #used1000<1001 do local nxt = a[n - 1] - n if nxt<1 or used[nxt] ~= nil then nxt = nxt + 2 * n end local alreadyUsed = used[nxt] ~= nil table.insert(a, nxt) if not alreadyUsed then used[nxt] = true if 0<=nxt and nxt<=1000 then used1000[nxt] = true end end if n==14 then io.write("The first 15 terms of the Recaman sequence are:") for k=0,#a do io.write(" "..a[k]) end print() end if not foundDup and alreadyUsed then print("The first duplicated term is a["..n.."] = "..nxt) foundDup = true end if #used1000 == 1001 then print("Terms up to a["..n.."] are needed to generate 0 to 1000") end n = n + 1 end</syntaxhighlight> {{out}} <pre>The first 15 terms of the Recaman sequence are: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 The first duplicated term is a[24] = 42 lua: not enough memory</pre> =={{header\|MAD}}== <syntaxhighlight lang="mad"> NORMAL MODE IS INTEGER VECTOR VALUES ELEMF = $2HA(,I2,4H) = ,I2$ DIMENSION A(100) A(0) = 0 PRINT COMMENT $ FIRST 15 ELEMENTS$ PRINT FORMAT ELEMF,0,0 THROUGH EL, FOR I=1, 1, I.GE.15 EL PRINT FORMAT ELEMF,I,NEXT.(I) PRINT COMMENT $ $ PRINT COMMENT $ FIRST REPEATED ELEMENT$ RPT THROUGH RPT, FOR I=I, 1, FIND.(I,NEXT.(I)) PRINT FORMAT ELEMF,I,A(I) INTERNAL FUNCTION(N,TOP) ENTRY TO FIND. FI=0 SRCH WHENEVER FI.GE.TOP, FUNCTION RETURN 0B WHENEVER A(FI).E.N, FUNCTION RETURN 1B FI=FI+1 TRANSFER TO SRCH END OF FUNCTION INTERNAL FUNCTION(N) ENTRY TO NEXT. HI=A(N-1)+N LO=A(N-1)-N WHENEVER LO.L.0 A(N)=HI OR WHENEVER FIND.(LO,N) A(N)=HI OTHERWISE A(N)=LO END OF CONDITIONAL FUNCTION RETURN A(N) END OF FUNCTION END OF PROGRAM </syntaxhighlight> {{out}} <pre>FIRST 15 ELEMENTS A( 0) = 0 A( 1) = 1 A( 2) = 3 A( 3) = 6 A( 4) = 2 A( 5) = 7 A( 6) = 13 A( 7) = 20 A( 8) = 12 A( 9) = 21 A(10) = 11 A(11) = 22 A(12) = 10 A(13) = 23 A(14) = 9 FIRST REPEATED ELEMENT A(20) = 42</pre> =={{header\|Mathematica}} / {{header\|Wolfram Language}}== <syntaxhighlight lang="mathematica">ClearAll[f] f[s_List] := Block[{a = s[[-1]], len = Length@s}, Append[s, If[a > len && ! MemberQ[s, a - len], a - len, a + len]]]; g = Nest[f, {0}, 70] g = Nest[f, {0}, 70]; Take[g, 15] p = Select[Tally[g], Last / EqualTo[2]][[All, 1]] p = Flatten[Position[g, #]] & /@ p; TakeSmallestBy[p, Last, 1][[1]]</syntaxhighlight> {{out}} <pre>{0,1,3,6,2,7,13,20,12,21,11,22,10,23,9} {43,42,79,78} {21,25}</pre> =={{header\|Microsoft Small Basic}}== Inefficency of associative array allocation in Small Basic ban to provide the optional task. <syntaxhighlight lang="smallbasic">' Recaman's sequence - smallbasic - 05/08/2015 nn=15 TextWindow.WriteLine("Recaman's sequence for the first " + nn + " numbers:") recaman() TextWindow.WriteLine(Text.GetSubTextToEnd(recaman,2)) nn="firstdup" recaman() TextWindow.WriteLine("The first duplicated term is a["+n+"]="+a[n]) Sub recaman a="" b="" dup="" recaman="" firstdup="" If nn="firstdup" Then nn=1000 firstdup="True" EndIf For n=0 To nn-1 ap=a[n-1]+n If a[n-1]<=n Then a[n]=ap 'a[n]=a[n-1]+n b[ap]=1 Else am=a[n-1]-n If b[am]=1 Then a[n]=ap 'a[n]=a[n-1]+n b[ap]=1 Else a[n]=am 'a[n]=a[n-1]-n b[am]=1 EndIf EndIf If firstdup Then If dup[a[n]]=1 Then Goto exitsub EndIf dup[a[n]]=1 EndIf recaman=recaman+","+a[n] EndFor exitsub: EndSub </syntaxhighlight> {{out}} <pre> Recaman's sequence for the first 15 numbers: 0,1,3,6,2,7,13,20,12,21,11,22,10,23,9 The first duplicated term is a[24]=42 </pre> =={{header\|Nim}}== <syntaxhighlight lang="nim">import sequtils, sets, strutils iterator recaman(num: Positive = Natural.high): tuple[n, a: int; duplicate: bool] = var a = 0 yield (0, a, false) var known = [0].toHashSet for n in 1..<num: var next = a - n if next <= 0 or next in known: next = a + n a = next yield (n, a, a in known) known.incl a echo "First 15 numbers in Recaman’s sequence: ", toSeq(recaman(15)).mapIt(it.a).join(" ") for (n, a, dup) in recaman(): if dup: echo "First duplicate found: a($1) = $2".format(n, a) break var target = toSeq(0..1000).toHashSet for (n, a, dup) in recaman(): target.excl a if target.card == 0: echo "All numbers from 0 to 1000 generated after $1 terms.".format(n) break</syntaxhighlight> {{out}} <pre>First 15 numbers in Recaman’s sequence: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicate found: a(24) = 42 All numbers from 0 to 1000 generated after 328002 terms.</pre> =={{header\|Objeck}}== {{trans\|Java}} <syntaxhighlight lang="objeck">use Collection.Generic; class RecamanSequence { function : Main(args : String[]) ~ Nil { GenerateSequence(); } function : native : GenerateSequence() ~ Nil { a := Vector->New()<IntHolder>; a->AddBack(0); used := Set->New()<IntHolder>; used->Insert(0); used1000 := Set->New()<IntHolder>; used1000->Insert(0); foundDup := false; n := 1; while (n <= 15 \| <>foundDup \| used1000->Size() < 1001) { next := a->Get(n - 1) - n; if (next < 1 \| used->Has(next)) { next += 2 * n; }; alreadyUsed := used->Has(next); a->AddBack(next); if (<>alreadyUsed) { used->Insert(next); if (0 <= next & next <= 1000) { used1000->Insert(next); }; }; if (n = 14) { str := ToString(a); "The first 15 terms of the Recaman sequence are : {$str}"->PrintLine(); }; if (<>foundDup & alreadyUsed) { "The first duplicate term is a[{$n}] := {$next}"->PrintLine(); foundDup := true; }; if (used1000->Size() = 1001) { "Terms up to a[{$n}] are needed to generate 0 to 1000"->PrintLine(); }; n++; }; } function : ToString(a : Vector<IntHolder>) ~ String { out := "["; each(i : a) { out += a->Get(i)->Get(); if(i + 1 < a->Size()) { out += ','; }; }; out += ']'; return out; } }</syntaxhighlight> {{output}} <pre> The first 15 terms of the Recaman sequence are : [0,1,3,6,2,7,13,20,12,21,11,22,10,23,9] The first duplicate term is a[24] := 42 Terms up to a[328002] are needed to generate 0 to 1000 </pre> =={{header\|Perl}}== <syntaxhighlight lang="perl">use bignum; $max = 1000; $remaining += $_ for 1..$max; my @recamans = 0; my $previous = 0; while ($remaining > 0) { $term++; my $this = $previous - $term; $this = $previous + $term unless $this > 0 and !$seen{$this}; push @recamans, $this; $dup = $term if !$dup and defined $seen{$this}; $remaining -= $this if $this <= $max and ! defined $seen{$this}; $seen{$this}++; $previous = $this; } print "First fifteen terms of Recaman's sequence: " . join(' ', @recamans[0..14]) . "\n"; print "First duplicate at term: a[$dup]\n"; print "Range 0..1000 covered by terms up to a[$term]\n";</syntaxhighlight> {{out}} <pre>First fifteen terms of Recaman's sequence: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicate at term: a[24] Range 0..1000 covered by terms up to a[328002]</pre> =={{header\|Phix}}== {{trans\|D}} <!--<syntaxhighlight lang="phix">(phixonline)--> <span style="color: #008080;">with</span> <span style="color: #008080;">javascript_semantics</span> <span style="color: #004080;">bool</span> <span style="color: #000000;">found_duplicate</span> <span style="color: #0000FF;">=</span> <span style="color: #004600;">false</span> <span style="color: #004080;">sequence</span> <span style="color: #000000;">a</span> <span style="color: #0000FF;">=</span> <span style="color: #0000FF;">{</span><span style="color: #000000;">0</span><span style="color: #0000FF;">},</span> <span style="color: #000000;">used</span> <span style="color: #0000FF;">=</span> <span style="color: #0000FF;">{}</span> <span style="color: #000080;font-style:italic;">-- (grows to 1,942,300 entries)</span> <span style="color: #004080;">integer</span> <span style="color: #000000;">all_used</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">0</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">n</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">1</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">next</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">prev</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">0</span> <span style="color: #008080;">while</span> <span style="color: #000000;">n</span><span style="color: #0000FF;"><=</span><span style="color: #000000;">15</span> <span style="color: #008080;">or</span> <span style="color: #008080;">not</span> <span style="color: #000000;">found_duplicate</span> <span style="color: #008080;">or</span> <span style="color: #000000;">all_used</span><span style="color: #0000FF;"><</span><span style="color: #000000;">1000</span> <span style="color: #008080;">do</span> <span style="color: #000000;">next</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">prev</span> <span style="color: #0000FF;">-</span> <span style="color: #000000;">n</span> <span style="color: #008080;">if</span> <span style="color: #000000;">next</span><span style="color: #0000FF;"><</span><span style="color: #000000;">1</span> <span style="color: #008080;">or</span> <span style="color: #0000FF;">(</span><span style="color: #000000;">next</span><span style="color: #0000FF;"><=</span><span style="color: #7060A8;">length</span><span style="color: #0000FF;">(</span><span style="color: #000000;">used</span><span style="color: #0000FF;">)</span> <span style="color: #008080;">and</span> <span style="color: #000000;">used</span><span style="color: #0000FF;">[</span><span style="color: #000000;">next</span><span style="color: #0000FF;">])</span> <span style="color: #008080;">then</span> <span style="color: #000000;">next</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">prev</span> <span style="color: #0000FF;">+</span> <span style="color: #000000;">n</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> <span style="color: #000000;">a</span> <span style="color: #0000FF;">&=</span> <span style="color: #000000;">next</span> <span style="color: #004080;">integer</span> <span style="color: #000000;">padlen</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">next</span><span style="color: #0000FF;">-</span><span style="color: #7060A8;">length</span><span style="color: #0000FF;">(</span><span style="color: #000000;">used</span><span style="color: #0000FF;">)</span> <span style="color: #004080;">bool</span> <span style="color: #000000;">already_used</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">padlen</span><span style="color: #0000FF;"><=</span><span style="color: #000000;">0</span> <span style="color: #008080;">and</span> <span style="color: #000000;">used</span><span style="color: #0000FF;">[</span><span style="color: #000000;">next</span><span style="color: #0000FF;">]</span> <span style="color: #008080;">if</span> <span style="color: #008080;">not</span> <span style="color: #000000;">already_used</span> <span style="color: #008080;">then</span> <span style="color: #008080;">if</span> <span style="color: #000000;">padlen</span><span style="color: #0000FF;">></span><span style="color: #000000;">0</span> <span style="color: #008080;">then</span> <span style="color: #000000;">used</span> <span style="color: #0000FF;">&=</span> <span style="color: #7060A8;">repeat</span><span style="color: #0000FF;">(</span><span style="color: #004600;">false</span><span style="color: #0000FF;">,</span><span style="color: #000000;">padlen</span><span style="color: #0000FF;">)</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> <span style="color: #000000;">used</span><span style="color: #0000FF;">[</span><span style="color: #000000;">next</span><span style="color: #0000FF;">]</span> <span style="color: #0000FF;">=</span> <span style="color: #004600;">true</span> <span style="color: #008080;">while</span> <span style="color: #000000;">all_used</span><span style="color: #0000FF;"><</span><span style="color: #7060A8;">length</span><span style="color: #0000FF;">(</span><span style="color: #000000;">used</span><span style="color: #0000FF;">)</span> <span style="color: #008080;">and</span> <span style="color: #000000;">used</span><span style="color: #0000FF;">[</span><span style="color: #000000;">all_used</span><span style="color: #0000FF;">+</span><span style="color: #000000;">1</span><span style="color: #0000FF;">]</span> <span style="color: #008080;">do</span> <span style="color: #000000;">all_used</span> <span style="color: #0000FF;">+=</span> <span style="color: #000000;">1</span> <span style="color: #008080;">end</span> <span style="color: #008080;">while</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> <span style="color: #008080;">if</span> <span style="color: #7060A8;">length</span><span style="color: #0000FF;">(</span><span style="color: #000000;">a</span><span style="color: #0000FF;">)=</span><span style="color: #000000;">15</span> <span style="color: #008080;">then</span> <span style="color: #7060A8;">printf</span><span style="color: #0000FF;">(</span><span style="color: #000000;">1</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"The first 15 terms of the Recaman sequence are: %v\n"</span><span style="color: #0000FF;">,{</span><span style="color: #000000;">a</span><span style="color: #0000FF;">})</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> <span style="color: #008080;">if</span> <span style="color: #000000;">already_used</span> <span style="color: #008080;">and</span> <span style="color: #008080;">not</span> <span style="color: #000000;">found_duplicate</span> <span style="color: #008080;">then</span> <span style="color: #7060A8;">printf</span><span style="color: #0000FF;">(</span><span style="color: #000000;">1</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"The first duplicated term is a[%d] = %d\n"</span><span style="color: #0000FF;">,</span> <span style="color: #0000FF;">{</span><span style="color: #000000;">n</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">next</span><span style="color: #0000FF;">})</span> <span style="color: #000000;">found_duplicate</span> <span style="color: #0000FF;">=</span> <span style="color: #004600;">true</span><span style="color: #0000FF;">;</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> <span style="color: #008080;">if</span> <span style="color: #000000;">all_used</span><span style="color: #0000FF;">>=</span><span style="color: #000000;">1000</span> <span style="color: #008080;">then</span> <span style="color: #7060A8;">printf</span><span style="color: #0000FF;">(</span><span style="color: #000000;">1</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"Terms up to a[%d] are needed to generate 0 to 1000\n"</span><span style="color: #0000FF;">,</span> <span style="color: #0000FF;">{</span><span style="color: #000000;">n</span><span style="color: #0000FF;">});</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> <span style="color: #000000;">prev</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">next</span> <span style="color: #000000;">n</span> <span style="color: #0000FF;">+=</span> <span style="color: #000000;">1</span> <span style="color: #008080;">end</span> <span style="color: #008080;">while</span> <!--</syntaxhighlight>--> {{out}} <pre> The first 15 terms of the Recaman sequence are: {0,1,3,6,2,7,13,20,12,21,11,22,10,23,9} The first duplicated term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000 </pre> =={{header\|PHP}}== {{trans\|Java}} <syntaxhighlight lang="php"><?php $a = array(); array_push($a, 0); $used = array(); array_push($used, 0); $used1000 = array(); array_push($used1000, 0); $foundDup = false; $n = 1; while($n <= 15 \|\| !$foundDup \|\| count($used1000) < 1001) { $next = $a[$n - 1] - $n; if ($next < 1 \|\| in_array($next, $used)) { $next += 2 * $n; } $alreadyUsed = in_array($next, $used); array_push($a, $next); if (!$alreadyUsed) { array_push($used, $next); if (0 <= $next && $next <= 1000) { array_push($used1000, $next); } } if ($n == 14) { echo "The first 15 terms of the Recaman sequence are : ["; foreach($a as $i => $v) { if ( $i == count($a) - 1) echo "$v"; else echo "$v, "; } echo "]\n"; } if (!$foundDup && $alreadyUsed) { printf("The first duplicate term is a[%d] = %d\n", $n, $next); $foundDup = true; } if (count($used1000) == 1001) { printf("Terms up to a[%d] are needed to generate 0 to 1000\n", $n); } $n++; } </syntaxhighlight> {{out}} <pre> The first 15 terms of the Recaman sequence are : [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] The first duplicate term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000 </pre> =={{header\|PL/I}}== <syntaxhighlight lang="pli">recaman: procedure options(main); declare A(0:30) fixed; /* is X in the first N terms of the Recaman sequence? / find: procedure(x, n) returns(bit); declare (x, n, i) fixed; do i=0 to n-1; if A(i)=x then return('1'b); end; return('0'b); end find; / generate the N'th term of the Recaman sequence / generate: procedure(n) returns(fixed); declare n fixed; if n=0 then A(0) = 0; else do; declare (sub, add) fixed; sub = A(n-1) - n; add = A(n-1) + n; / A(n-1) - n not positive? / if sub <= 0 then A(n) = add; / A(n-1) - n already generated? / else if find(sub, n) then A(n) = add; else A(n) = sub; end; return(A(n)); end generate; declare i fixed; put skip list('First 15 members:'); do i=0 to 14; put edit(generate(i)) (F(3)); end; put skip list('First repeated term: '); do i=15 repeat(i+1) while(^find(generate(i), i)); end; put edit('A(',i,') = ',A(i)) (A,F(2),A,F(2)); end recaman;</syntaxhighlight> {{out}} <pre>First 15 members: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First repeated term: A(24) = 42</pre> =={{header\|PL/M}}== <syntaxhighlight lang="pli">100H: BDOS: PROCEDURE(F,A); DECLARE F BYTE, A ADDRESS; GO TO 5; END BDOS; EXIT: PROCEDURE; CALL BDOS(0,0); END EXIT; PRINT$CH: PROCEDURE(C); DECLARE C BYTE; CALL BDOS(2,C); END PRINT$CH; PRINT$STR: PROCEDURE(S); DECLARE S ADDRESS; CALL BDOS(9,S); END PRINT$STR; / PRINT NUMBER / PRINT$NUM: PROCEDURE(N); DECLARE (N, P) ADDRESS, C BASED P BYTE; DECLARE S(6) BYTE INITIAL('.....$'); P = .S(5); DIGIT: P = P-1; C = '0' + N MOD 10; N = N/10; IF N>0 THEN GO TO DIGIT; CALL PRINT$STR(P); END PRINT$NUM; / IS X IN THE FIRST N TERMS OF THE SEQUENCE / FIND: PROCEDURE(SEQ,X,N) BYTE; DECLARE SEQ ADDRESS, (I, X, N, A BASED SEQ) BYTE; DO I=0 TO N-1; IF A(I)=X THEN RETURN 0FFH; END; RETURN 0; END FIND; / GENERATE THE N'TH TERM OF THE SEQUENCE / GENERATE: PROCEDURE(SEQ,N) BYTE; DECLARE SEQ ADDRESS, (N, A BASED SEQ) BYTE; IF N=0 THEN A(N)=0; ELSE DO; DECLARE (SUB, ADD) BYTE; SUB = A(N-1) - N; ADD = A(N-1) + N; / A(N-1) - N NEGATIVE? / IF A(N-1) <= N THEN A(N) = ADD; / A(N-1) - N ALREADY GENERATED? / ELSE IF FIND(SEQ,SUB,N) THEN A(N) = ADD; ELSE A(N) = SUB; END; RETURN A(N); END GENERATE; DECLARE I BYTE, A(30) BYTE; CALL PRINT$STR(.'FIRST 15 MEMBERS: $'); DO I=0 TO 14; CALL PRINT$NUM(GENERATE(.A, I)); CALL PRINT$CH(' '); END; CALL PRINT$STR(.(13,10,'FIRST REPEATED TERM: A($')); I=15; DO WHILE NOT FIND(.A, GENERATE(.A, I), I); I = I+1; END; CALL PRINT$NUM(I); CALL PRINT$STR(.') = $'); CALL PRINT$NUM(A(I)); CALL PRINT$STR(.(13,10,'$')); CALL EXIT; EOF</syntaxhighlight> {{out}} <pre>FIRST 15 MEMBERS: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 FIRST REPEATED TERM: A(24) = 42</pre> =={{header\|PureBasic}}== <syntaxhighlight lang="purebasic">#MAX=500000 Dim a.i(#MAX) Dim b.b(1) Dim c.b(1000) FillMemory(@c(),1000,1,#PB_Byte) If OpenConsole() : Else : End 1 : EndIf For n_Count=0 To #MAX If n_Count=0 a(n_Count)=0 ElseIf a(n_Count-1)-n_Count>0 And b(a(n_Count-1)-n_Count)=0 a(n_Count)=a(n_Count-1)-n_Count Else a(n_Count)=a(n_Count-1)+n_Count EndIf If ArraySize(b())<a(n_Count) : ReDim b(a(n_Count)) : EndIf If b(a(n_Count))=1 And fitD=0 : fitD=n_Count : EndIf b(a(n_Count))=1 If CompareMemory(@b(),@c(),1000) And fit1000=0 : fit1000=n_Count : Break : EndIf Next Print("First 15 terms: ") : For i=0 To 14 : Print(RSet(Str(a(i)),4)) : Next : PrintN("") PrintN("First duplicate term : a("+Str(fitD)+") = "+Str(a(fitD))) PrintN("Number of Recaman terms needed to generate all integers from [0..1000]: "+Str(fit1000)) Input() End</syntaxhighlight> {{out}} <pre>First 15 terms: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicate term : a(24) = 42 Number of Recaman terms needed to generate all integers from [0..1000]: 328002 </pre> =={{header\|Python}}== ===Conditional iteration over a generator=== ~~<lang python>from itertools import islice~~ <syntaxhighlight lang="python">from itertools import islice class Recamans(): Line 202 ⟶ 2,496: if setn.issubset(recamans.a): print(f"Range 0 ..{n} is covered by terms up to a({recamans.n})") break</~~lang~~syntaxhighlight> {{out}} Line 208 ⟶ 2,502: First duplicate number in series is: a(24) = 42 Range 0 ..1000 is covered by terms up to a(328002)</pre> ===Parameterised query predicates=== Passing different query predicates to a single more general function: ( This turns out to be c. 8X faster than than the ''iteration over generator'' approach above, on a simple start to end measure using ''time.time()'') <syntaxhighlight lang="python">'''Recaman sequence''' # recamanUntil :: (Int -> Set Int > [Int] -> Bool) -> [Int] def recamanUntil(p): '''All terms of the Recaman series before the first term for which the predicate p holds.''' n = 1 r = 0 # First term of series rs = [r] seen = set(rs) blnNew = True while not p(seen, n, r, blnNew): r = recamanSucc(seen, n, r) blnNew = r not in seen seen.add(r) rs.append(r) n = 1 + n return rs # recamanSucc :: Set Int -> Int -> Int def recamanSucc(seen, n, r): '''The successor for a given Recaman term, given the set of Recaman terms seen so far.''' back = r - n return n + r if 0 > back or (back in seen) else back # ------------------------- TEST ------------------------- # main :: IO () def main(): '''Test''' print( 'First 15 Recaman:\r', recamanUntil( lambda seen, n, r, _: 15 == n ) ) print( 'First duplicated Recaman:\r', recamanUntil( lambda seen, n, r, blnNew: not blnNew )[-1] ) setK = set(enumFromTo(0)(1000)) print( 'Number of Recaman terms needed to generate', 'all integers from [0..1000]:\r', len(recamanUntil( lambda seen, n, r, blnNew: ( blnNew and 1001 > r and setK.issubset(seen) ) )) - 1 ) # ----------------------- GENERIC ------------------------ # enumFromTo :: (Int, Int) -> [Int] def enumFromTo(m): '''Integer enumeration from m to n.''' return lambda n: range(m, 1 + n) if __name__ == '__main__': main()</syntaxhighlight> {{Out}} <pre>First 15 Recaman: [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] First duplicated Recaman: 42 Number of Recaman terms needed to generate all integers from [0..1000]: 328002</pre> Alternatively, we can use query predicates in combination with the iteration of a function over a tuple,<br> and encapsulate the querying in the generic abstractions '''iterate''' and '''until'''. This additional level of abstraction reduces the amount of new code that we have to write, facilitates refactoring, and turns out to have insignificant cost. ( This version is still c. 8X faster than the ''conditional iteration over generator'' version, as measured by a simple start and end test using ''time.time()'' ). <syntaxhighlight lang="python">'''Recaman by iteration of a function over a tuple.''' from itertools import (islice) # recamanTupleSucc :: Set Int -> (Int, Int, Bool) -> (Int, Int, Bool) def recamanTupleSucc(seen): '''The Nth in a series of Recaman tuples, (N, previous term, boolPreviouslySeen?) given the set of all terms seen so far.''' def go(n, r, _): back = r - n nxt = n + r if 0 > back or (back in seen) else back bln = nxt in seen seen.add(nxt) return (1 + n, nxt, bln) return lambda tpl: go(tpl) # ------------------------- TEST ------------------------- # main :: IO() def main(): '''First 15, and first duplicated Recaman.''' f = recamanTupleSucc(set([0])) print( 'First 15 Recaman:\n', list(map( snd, take(15)(iterate(f)((1, 0, False))) )) ) f = recamanTupleSucc(set([0])) print( 'First duplicated Recaman:\n', until(lambda x: x[2])(f)( (1, 0, False) )[1] ) sk = set(enumFromTo(0)(1000)) sr = set([0]) f = recamanTupleSucc(sr) print( 'Number of Recaman terms needed to generate', 'all integers from [0..1000]:\n', until( lambda x: not x[2] and 1001 > x[1] and sk.issubset(sr) )(f)( (1, 0, False) )[0] - 1 ) # ----------------- GENERIC ABSTRACTIONS ----------------- # enumFromTo :: (Int, Int) -> [Int] def enumFromTo(m): '''Integer enumeration from m to n.''' return lambda n: range(m, 1 + n) # iterate :: (a -> a) -> a -> Gen [a] def iterate(f): '''An infinite list of repeated applications of f to x. ''' def go(x): v = x while True: yield v v = f(v) return go # snd :: (a, b) -> b def snd(tpl): '''Second component of a tuple.''' return tpl[1] # take :: Int -> [a] -> [a] # take :: Int -> String -> String def take(n): '''The prefix of xs of length n, or xs itself if n > length xs.''' return lambda xs: ( xs[0:n] if isinstance(xs, list) else islice(xs, n) ) # until :: (a -> Bool) -> (a -> a) -> a -> a def until(p): '''The result of repeatedly applying f until p holds. The initial seed value is x. ''' def go(f): def g(x): v = x while not p(v): v = f(v) return v return g return go # MAIN --- if __name__ == '__main__': main()</syntaxhighlight> <pre>First 15 Recaman: [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] First duplicated Recaman: 42 Number of Recaman terms needed to generate all integers from [0..1000]: 328002</pre> =={{header\|Quackery}}== <syntaxhighlight lang="quackery"> [ stack 0 ] is seennumbers ( --> s ) [ bit seennumbers take \| seennumbers put ] is seen ( n --> ) [ dup 0 < iff [ drop true ] done bit seennumbers share & 0 != ] is seen? ( n --> b ) [ 1+ bit 1 - seennumbers share over & = ] is allseen? ( n --> b ) [ stack [ ] ] is repeats ( --> s ) [ 1 seennumbers replace [] repeats replace ' [ 0 ] 1 ] is startseq ( --> [ n ) [ over -1 peek over - dup seen? if [ over 2 * + dup seen? if [ repeats take over join repeats put ] ] dup seen swap dip join 1+ ] is nextterm ( [ n --> [ n ) say "first 15 terms: " startseq 14 times nextterm drop echo cr say "first duplicated term: " startseq [ repeats share [] = while nextterm again ] drop -1 peek echo cr say "terms needed to generate 0 to 1000: " startseq [ nextterm 1000 allseen? until ] nip 1 - echo cr </syntaxhighlight> {{out}} <pre>first 15 terms: [ 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 ] first duplicated term: 42 terms needed to generate 0 to 1000: 328002 </pre> =={{header\|R}}== A bit slow because the append() function is expensive. <syntaxhighlight lang="rsplus"> visited <- vector('logical', 1e8) terms <- vector('numeric') in_a_interval <- function(v) { visited[[v+1]] } add_value <- function(v) { visited[[v+1]] <<- TRUE terms <<- append(terms, v) } add_value(0) step <- 1 value <- 0 founddup <- FALSE repeat { if ((value-step>0) && (!in_a_interval(value-step))) { value <- value - step } else { value <- value + step } if (in_a_interval(value) && !founddup) { cat("The first duplicated term is a[",step,"] = ",value,"\n", sep = "") founddup <- TRUE } add_value(value) if (all(visited[1:1000])) { cat("Terms up to a[",step,"] are needed to generate 0 to 1000\n",sep = "") break } step <- step + 1 if (step == 15) { cat("The first 15 terms are :") for (aterm in terms) { cat(aterm," ", sep = "") } cat("\n") } } </syntaxhighlight> {{out}} <pre> The first 15 terms are :0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 The first duplicated term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000 </pre> =={{header\|Raku}}== (formerly Perl 6) {{works with\|Rakudo\|2018.06}} <syntaxhighlight lang="raku" line>my @recamans = 0, { state %seen; state $term; $term++; my $this = $^previous - $term; $this = $previous + $term unless ($this > 0) && !%seen{$this}; %seen{$this} = True; $this } … ; put "First fifteen terms of Recaman's sequence: ", @recamans[^15]; say "First duplicate at term: a[{ @recamans.first({@recamans[^$_].Bag.values.max == 2})-1 }]"; my @seen; my int $i = 0; loop { next if (my int $this = @recamans[$i++]) > 1000 or @seen[$this]; @seen[$this] = 1; say "Range 0..1000 covered by terms up to a[{$i - 1}]" and last if ++$ == 1001; }</syntaxhighlight> {{out}} <pre>First fifteen terms of Recaman's sequence: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicate at term: a[24] Range 0..1000 covered by terms up to a[328002]</pre> =={{header\|REXX}}== ===version 1=== ~~<lang rexx>/REXX program computes & displays the Recaman sequence (also known as Recamán sequence)/~~ Instead of using a subroutine to perform the three tasks with one invocation,   the subroutine was used three times <br>(once for each of the task's three requirements). Programmer's note:   the short-circuited   '''if'''   REXX statement   (lines '''14''' <small>&</small> '''15'''): if z<0 then z= _ + # else if !.z then z= _ + # could've been replaced with: if !.z \| z<0 then z= _ + # <syntaxhighlight lang="rexx">/REXX pgm computes a Recamán sequence up to N; the 1st dup; # terms for a range of #'s./ parse arg N h . /obtain optional arguments from the CL/ if N=='' \| N=="," then N= 15 /Not specified? Then use the default./ ~~say~~if ~~"Recamán~~h==''s ~~sequence~~\| ~~for~~h=="," ~~the~~ ~~first~~then h= 1000 / " N" " ~~numbers:~~ " " " / say "Recamán's sequence for the first " N " numbers: " recaman(N) ~~say recaman(N)~~ say; say "The first duplicate number in the Recamán's sequence is: " recaman(0) ~~say~~ say; say "The ~~first~~number ~~duplicate~~of ~~number~~terms into complete the ~~Recamán's~~range ~~sequence is:~~ 0───►"h ' is: ' recaman(0-h) exit 0 /stick a fork in it, we're all done. / /──────────────────────────────────────────────────────────────────────────────────────/ recaman: procedure; parse arg y ~~1 oy~~,,~~$ !.~~ d.; $=0; !.=0; u_=0; !.0=1 /U:init. array aand ~~unique flag~~vars. / if ~~y==0~~ ~~then~~ ~~do;~~ ~~y=1e8;~~ u r=1 y<0; ~~end~~ Reca= 0; hi= abs(y) /for ~~duplicate~~the ~~stuff~~2nd invoke. / ~~@.=0~~ o= y==0; if y<1 then y= 1e8 / " " 3rd " ~~/initialize @ array~~/ do j#=01 for y-1; jm z=j _ -1; # ~~p=@~~ /next # might be < 0.jm / if z<0 then z= _ + # /this is faster than: / ~~_=p+j~~ if ~~p<=j~~ ~~then~~ ~~do;~~ else if @!.jz then z= _; + # ~~!._=.;~~ ~~end~~ /~~for~~if ~~pository values~~!.z \| z<0 then ···/ !.z= 1; ~~else~~ ~~do;~~ m _=~~p-j~~ z /mark it; add to seq./ if r then do; if z>hi then ~~@.j=m~~ iterate /~~for~~ignore #'s ~~negatory~~too ~~values~~large./ if !d.mz==.'' then ~~do;~~Reca= Reca + 1 ~~@.j=_;~~ ~~!._=.~~ /~~was~~Unique? ~~defined before?~~Bump counter./ d.z= . ~~end~~ /mark # as a new low. / if ~~end~~Reca>=hi then return # /list is complete ≥ HI/ ~~z=@.j~~ ~~/get the @.J value./~~iterate if u ~~then~~ ~~do;~~ if ~~d.z==.~~end ~~then~~ ~~return~~ z; ~~d.z=.;~~ ~~iterate~~ /~~j/;~~ [↑] a ~~end~~range of #s. / if o ~~$=$ z~~ then do; if d.z==. then return z; d.z=.; iterate /~~append~~check if Zdup ~~to list~~#. / ~~end~~ ~~/j/~~ end ~~return~~ ~~strip(~~ $)= $ z /~~return~~add ~~the~~number to $ list.?/~~</lang>~~ end /#/; return $ /return the $ list. /</syntaxhighlight> {{out\|output\|text=  when using the default input:}} Run time was about   '''<sup>1</sup>/<sub>6</sub>'''   of a second,   which is over   '''230%'''   times faster than version 2. <pre> Recamán's sequence for the first 15 numbers: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 ~~0 1 3 6 2 7 13 20 12 21 11 22 10 23 9~~ The first duplicate number in the Recamán's sequence is: 42 The number of terms to complete the range 0───►1000 is: 328002 </pre> ===version 2=== <syntaxhighlight lang="rexx">/REXX program computes & displays the Recaman sequence / /improved using version 1's method for task 3 / Call time 'R' / Start timer / Parse Arg n If n='' Then n=15 Say 'the first' n 'elements:' recaman(n) Say ans.2 Say ans.3 Say time('E') 'seconds elapsed' Exit recaman: Parse Arg n / Wanted number of elements / have.=0 / Number not yet in sequence / e.0=0 / First element / have.0=1 / is in the sequence / s=0 / Sequence to be shodn / done=0 / turn on first duplicate switch / d.=0 d.0=1 dn=1 / number of elements <=1000 / Do i=1 until dn==1001 / Loop until all found / ip=i-1 / previous index / temp=e.ip-i / potential next element / If temp>0 & have.temp=0 Then / to be used / Nop Else / compute the alternative / temp=e.ip+i e.i=temp / Set next element / If words(s)<n Then / not enough in output / s=s temp / add the element to the output / If temp<=1000 Then Do / eligible for task 3 / If d.temp=0 Then Do / not yet encountered / d.temp=1 / Remember it's there / dn=dn+1 / count of integers<=1000 found / End End If done=0 & have.temp=1 Then Do ans.2='First duplicate ('temp') added in iteration' i, 'elapsed:' time('E') 'seconds' done=1 End ans.3='Element number' i 'is the last to satisfy task 3. It is' temp Have.temp=1 End Return s</syntaxhighlight> {{out}} <pre>the first 15 elements: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First duplicate (42) added in iteration 24 elapsed: 0 seconds Element number 328002 is the last to satisfy task 3. It is 879 7.126000 seconds elapsed</pre> =={{header\|Ring}}== <syntaxhighlight lang="ring"> load "zerolib.ring" recaman = Z(0:50) duplicate = 0 dup = [] recDuplicate = [] recnum = 0 see "working..." + nl see "the first 15 Recaman's numbers are:" + nl for n = 1 to len(recaman) - 1 if n = 1 recaman[0] = 0 add(dup,0) see "" + recaman[0] + " " ok recaman[n] = recaman[n-1] - n if recaman[n] <= 0 recaman[n] = recaman[n-1] + n ok fnrec = find(dup,recaman[n]) if fnrec > 0 del(dup,fnrec) recaman[n] = recaman[n-1] + n add(dup,recaman[n]) else add(dup,recaman[n]) ok recnum = recnum + 1 if recnum < 15 see "" + recaman[n] + " " ok add(recDuplicate,recaman[n]) next see nl see "the first duplicated term is a[" for n = len(recDuplicate) to 2 step -1 for m = n-1 to 1 step -1 if recDuplicate[n] = recDuplicate[m] duplicate = recDuplicate[n] dupnr = n ok next next see "" + dupnr + "] = " + duplicate + nl see "done..." + nl </syntaxhighlight> {{out}} <pre> working... the first 15 Recaman's numbers are: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 the first duplicated term is a[24] = 42 done... </pre> =={{header\|RPL}}== {{works with\|Halcyon Calc\|4.2.8}} {\| class="wikitable" ! RPL code ! Comment \|- \| ≪ 1 + RKMSQ SWAP OVER SIZE '''IF''' DUP2 ≤ '''THEN''' DROP GET '''ELSE''' SWAP 1 - '''FOR''' j DUP DUP SIZE GET j - '''IF''' DUP2 ABS POS OVER 0 < OR '''THEN''' j 2 + '''END''' + '''NEXT''' DUP ‘'''RKMSQ'''‘ STO DUP SIZE GET '''END''' ≫ ‘'''RECAM'''’ STO ≪ 0 { 0 } ‘'''RKMSQ'''’ STO '''DO''' 1 + '''RKMSQ''' OVER '''RECAM''' '''UNTIL''' POS '''END RECAM''' ≫ ‘'''TASK2'''’ STO \| ''' RECAM''' ''( n -- a(n) )'' get m = size of sequence in memory if n+1 ≤ m then recall sequence(n+1)=a(n) else for j=m to n get a(j-1)-n if already in sequence or <0 then a(j) = (a(j-1)-n)+2n add to sequence store updated sequence and recall a(n) . . Initialize variables Loop get a(n) until a(n) already in sequence . \|} {{in}} <pre> { 0 } 'RKMSQ’ STO 15 RECAM RKMSQ { 0 } ‘RKMSQ’ STO TASK2 </pre> {{out}} <pre> 3: 24 2: { 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 24 } 1: 42 </pre> =={{header\|Ruby}}== {{trans\|Kotlin}} <syntaxhighlight lang="ruby">require 'set' a = [0] used = Set[0] used1000 = Set[0] foundDup = false n = 1 while n <= 15 or not foundDup or used1000.size < 1001 nxt = a[n - 1] - n if nxt < 1 or used === nxt then nxt = nxt + 2 n end alreadyUsed = used === nxt a << nxt if not alreadyUsed then used << nxt if nxt >= 0 and nxt <= 1000 then used1000 << nxt end end if n == 14 then print "The first 15 terms of the Recaman's sequence are ", a, "\n" end if not foundDup and alreadyUsed then print "The first duplicated term is a[", n, "] = ", nxt, "\n" foundDup = true end if used1000.size == 1001 then print "Terms up to a[", n, "] are needed to generate 0 to 1000\n" end n = n + 1 end</syntaxhighlight> {{out}} <pre>The first 15 terms of the Recaman's sequence are [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] The first duplicated term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000</pre> =={{header\|Rust}}== <syntaxhighlight lang="rust"> use std::collections::HashSet ; fn main() { let mut recamans : Vec<i32> = Vec::new( ) ; let mut reca_set : HashSet<i32> = HashSet::new() ; let mut first_nums : HashSet<i32> = HashSet::new( ) ; for i in 0i32..=1000 { first_nums.insert( i ) ; } recamans.push( 0 ) ; reca_set.insert( 0 ) ; let mut current : i32 = 0 ; while ! first_nums.is_subset( &reca_set ) { current += 1 ; let mut nextnum : i32 = recamans[( current as usize ) - 1] - current ; if nextnum < 0 \|\| reca_set.contains( &nextnum ) { nextnum = recamans[(current as usize ) - 1 ] + current ; } recamans.push( nextnum ) ; reca_set.insert( nextnum ) ; if current == 15 { println!("The first 15 numbers of the Recaman sequence are:" ) ; println!("{:?}" , recamans ) ; } } println!("To generate all numbers from 0 to 1000 , one has to go to element {}" , current) ; }</syntaxhighlight> {{Out}} <pre> The first 15 numbers of the Recaman sequence are: [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9, 24] To generate all numbers from 0 to 1000 , one has to go to element 328002 </pre> =={{header\|Scala}}== {{Out}}Best seen in running your browser either by [https://scalafiddle.io/sf/xjLHy7m/0 ScalaFiddle (ES aka JavaScript, non JVM)] or [https://scastie.scala-lang.org/FdJaIB68S8i5OSndpigBtA Scastie (remote JVM)]. <syntaxhighlight lang="scala">import scala.collection.mutable object RecamansSequence extends App { val (a, used) = (mutable.ArrayBuffer[Int](0), mutable.BitSet()) var (foundDup, hop, nUsed1000) = (false, 1, 0) while (nUsed1000 < 1000) { val _next = a(hop - 1) - hop val next = if (_next < 1 \|\| used.contains(_next)) _next + 2 * hop else _next val alreadyUsed = used.contains(next) a += next if (!alreadyUsed) { used.add(next) if (next <= 1000) nUsed1000 += 1 } if (!foundDup && alreadyUsed) { println(s"The first duplicate term is a($hop) = $next") foundDup = true } if (nUsed1000 == 1000) println(s"Terms up to $hop are needed to generate 0 to 1000") hop += 1 } println(s"The first 15 terms of the Recaman sequence are : ${a.take(15)}") }</syntaxhighlight> =={{header\|Scheme}}== {{works with\|Chez Scheme}} <syntaxhighlight lang="scheme">; Create a dynamically resizing vector (a "dynvec"). ; Returns a procedure that takes a variable number of arguments: ; 0 : () --> Returns the vector from index 0 through the maximum index set. ; 1 : (inx) --> Returns the value at the given index. ; 2 : (inx val) --> Sets the given value into the given index, and returns the value. (define make-dynvec (lambda (init-size extra-fact init-val) (let ((vec (make-vector init-size init-val)) (maxinx -1)) (lambda args (if (null? args) (let ((retvec (make-vector (1+ maxinx)))) (do ((index 0 (1+ index))) ((> index maxinx) retvec) (vector-set! retvec index (vector-ref vec index)))) (let ((inx (car args))) (when (>= inx (vector-length vec)) (let ((newvec (make-vector (inexact->exact (ceiling (* extra-fact inx))) init-val))) (do ((index 0 (1+ index))) ((>= index (vector-length vec))) (vector-set! newvec index (vector-ref vec index))) (set! vec newvec))) (when (pair? (cdr args)) (when (> inx maxinx) (set! maxinx inx)) (vector-set! vec inx (cadr args))) (vector-ref vec inx))))))) ; Generate the Recaman's sequence. ; Generate the terms of Recaman's sequence until the given "stop" procedure ; returns a true value; that returned value becomes the value of this procedure. ; The arguments to the "stop" procedure are: n, the value of the n'th term, ; #t if that term was seen before, #t if the term was arrived at by addition, ; the Recaman's sequence so far (as a dynvec), and a dynvec of the n's at which ; a value was first seen or #f if not previously seen ("seen1st"). (define recaman-sequence (lambda (stop-proc) (let ((recaman (make-dynvec 10 2 0)) (seen1st (make-dynvec 10 2 #f))) (do ((n 0 (1+ n)) (done-retval #f)) (done-retval done-retval) (if (= n 0) (begin (recaman n 0) (seen1st 0 n) (set! done-retval (stop-proc n 0 #f #f recaman seen1st))) (let ((try-sub (- (recaman (1- n)) n))) (if (and (> try-sub 0) (not (seen1st try-sub))) (begin (recaman n try-sub) (seen1st try-sub n) (set! done-retval (stop-proc n try-sub #f #f recaman seen1st))) (let* ((val-add (+ (recaman (1- n)) n)) (seen-prev (seen1st val-add))) (recaman n val-add) (unless (seen1st val-add) (seen1st val-add n)) (set! done-retval (stop-proc n val-add seen-prev #t recaman seen1st)))))))))) ; Generate and display the first 15 Recaman's numbers. (printf "First 15 Recaman's numbers: ~a~%" (recaman-sequence (lambda (n val seen-prev by-add recaman seen1st) (and (>= n (1- 15)) (recaman))))) ; Find and display the first duplicated Recaman's number. ; The only way to be a duplicate is if the number was arrived ; at by adding 'n' and the number has been seen before. (let ((dup-n-val-1st (recaman-sequence (lambda (n val seen-prev by-add recaman seen1st) (and by-add seen-prev (list n val (seen1st val))))))) (printf "First duplicate Recaman's number: a[~a] = a[~a] = ~a~%" (caddr dup-n-val-1st) (car dup-n-val-1st) (cadr dup-n-val-1st))) ; Find and display how many terms of the sequence are needed ; for all the integers 0..1000, inclusive, to be generated. (let* ((all-first 1001) (terms-to-gen-all (recaman-sequence (lambda (n val seen-prev by-add recaman seen1st) (do ((inx 0 (1+ inx))) ((or (>= inx all-first) (not (seen1st inx))) (and (>= inx all-first) (1+ n)))))))) (printf "Terms of Recaman's sequence to generate all integers 0..~a, inclusive: ~a~%" (1- all-first) terms-to-gen-all))</syntaxhighlight> {{out}} <pre>First 15 Recaman's numbers: #(0 1 3 6 2 7 13 20 12 21 11 22 10 23 9) First duplicate Recaman's number: a[20] = a[24] = 42 Terms of Recaman's sequence to generate all integers 0..1000, inclusive: 328003</pre> =={{header\|SETL}}== <syntaxhighlight lang="setl">program recaman; a := {[0,0]}; loop for i in [1..14] do extend(a); end loop; print("First 15:", [a(n) : n in [0..14]]); loop doing n := extend(a); until #(rept:=[[r,i] : r = a(i) \| r=n]) > 1 do pass; end loop; print("First repetition:", n, "at", {x:x in rept}{n}); proc extend(rw a); n := max/ domain a; t := a(n) - n-1; if t<0 or t in range a then t := a(n) + n+1; end if; return a(n+1) := t; end proc; end program;</syntaxhighlight> {{out}} <pre>First 15: [0 1 3 6 2 7 13 20 12 21 11 22 10 23 9] First repetition: 42 at {20 24}</pre> =={{header\|Sidef}}== <syntaxhighlight lang="ruby">func recamans_generator() { var term = 0 var prev = 0 var seen = Hash() { var this = (prev - term) if ((this <= 0) \|\| seen{this}) { this = (prev + term) } prev = this seen{this} = true term++ this } } with (recamans_generator()) { \|r\| say ("First 15 terms of the Recaman's sequence: ", 15.of { r.run }.join(', ')) } with (recamans_generator()) {\|r\| var seen = Hash() Inf.times {\|i\| var n = r.run if (seen{n}) { say "First duplicate term in the series is a(#{i}) = #{n}" break } seen{n} = true } } with (recamans_generator()) {\|r\| var seen = Hash() Inf.times {\|i\| var n = r.run if ((n <= 1000) && (seen{n} := true) && (seen.len == 1001)) { say "Terms up to a(#{i}) are needed to generate 0 to 1000" break } } }</syntaxhighlight> {{out}} <pre>First 15 terms of the Recaman's sequence: 0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9 First duplicate term in the series is a(24) = 42 Terms up to a(328002) are needed to generate 0 to 1000</pre> =={{header\|uBasic/4tH}}== <syntaxhighlight lang="basic">a = 0 ' the first one is free ;-) Print "First 15 numbers:" For i = 1 Step 1 ' start loop If i<16 Then Print a, ' print first 15 numbers b = Iif ((a-i<1) + (Func(_Peek(Max(0, a-i)))), a+i, a-i) If Func(_Peek(b)) Then Print "\nFirst repetition: ";b : Break Proc _Set(Set(a, b)) ' set bit in bitmap Next End ' terminate program ' bitmap functions _Set Param(1) : Let @(a@/32) = Func(_Poke(a@/32, a@%32)) : Return _Poke Param(2) : Return (Or(@(a@), Shl(1, b@))) _Peek Param(1) : Return (And(@(a@/32), Shl(1, a@%32))>0) </syntaxhighlight> {{out}} <pre> First 15 numbers: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 First repetition: 42 0 OK, 0:459 </pre> =={{header\|VBScript}}== {{trans\|Rexx}} To run in console mode with cscript. <syntaxhighlight lang="vb">' Recaman's sequence - vbscript - 04/08/2015 nx=15 h=1000 Wscript.StdOut.WriteLine "Recaman's sequence for the first " & nx & " numbers:" Wscript.StdOut.WriteLine recaman("seq",nx) Wscript.StdOut.WriteLine "The first duplicate number is: " & recaman("firstdup",0) Wscript.StdOut.WriteLine "The number of terms to complete the range 0--->"& h &" is: "& recaman("numterm",h) Wscript.StdOut.Write vbCrlf&".../...": zz=Wscript.StdIn.ReadLine() function recaman(op,nn) Dim b,d,h Set b = CreateObject("Scripting.Dictionary") Set d = CreateObject("Scripting.Dictionary") list="0" : firstdup=0 if op="firstdup" then nn=1000 : firstdup=1 end if if op="numterm" then h=nn : nn=10000000 : numterm=1 end if ax=0 'a(0)=0 b.Add 0,1 'b(0)=1 s=0 for n=1 to nn-1 an=ax-n if an<=0 then an=ax+n elseif b.Exists(an) then an=ax+n end if ax=an 'a(n)=an if not b.Exists(an) then b.Add an,1 'b(an)=1 if op="seq" then list=list&" "&an end if if firstdup then if d.Exists(an) then recaman="a("&n&")="&an exit function else d.Add an,1 'd(an)=1 end if end if if numterm then if an<=h then if not d.Exists(an) then s=s+1 d.Add an,1 'd(an)=1 end if if s>=h then recaman=n exit function end if end if end if next 'n recaman=list end function 'recaman</syntaxhighlight> {{out}} <pre> Recaman's sequence for the first 15 numbers: 0 1 3 6 2 7 13 20 12 21 11 22 10 23 9 The first duplicate number is: a(24)=42 The number of terms to complete the range 0--->1000 is: 328002 </pre> =={{header\|Visual Basic .NET}}== {{trans\|C#}} <syntaxhighlight lang="vbnet">Imports System Imports System.Collections.Generic Module Module1 Sub Main(ByVal args As String()) Dim a As List(Of Integer) = New List(Of Integer)() From { 0 }, used As HashSet(Of Integer) = New HashSet(Of Integer)() From { 0 }, used1000 As HashSet(Of Integer) = used.ToHashSet(), foundDup As Boolean = False For n As Integer = 1 to Integer.MaxValue Dim nv As Integer = a(n - 1) - n If nv < 1 OrElse used.Contains(nv) Then nv += 2 * n Dim alreadyUsed As Boolean = used.Contains(nv) : a.Add(nv) If Not alreadyUsed Then used.Add(nv) : If nv > 0 AndAlso nv <= 1000 Then used1000.Add(nv) If Not foundDup Then If a.Count = 15 Then _ Console.WriteLine("The first 15 terms of the Recamán sequence are: ({0})", String.Join(", ", a)) If alreadyUsed Then _ Console.WriteLine("The first duplicated term is a({0}) = {1}", n, nv) : foundDup = True End If If used1000.Count = 1001 Then _ Console.WriteLine("Terms up to a({0}) are needed to generate 0 to 1000", n) : Exit For Next End Sub End Module</syntaxhighlight>{{out}} <pre>The first 15 terms of the Recamán sequence are: (0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9) The first duplicated term is a(24) = 42 Terms up to a(328002) are needed to generate 0 to 1000</pre> =={{header\|Wren}}== {{trans\|Kotlin}} <syntaxhighlight lang="wren">var a = [0] var used = { 0: true } var used1000 = { 0: true } var foundDup = false var n = 1 while (n <= 15 \|\| !foundDup \|\| used1000.count < 1001) { var next = a[n-1] - n if (next < 1 \|\| used[next]) next = next + 2*n var alreadyUsed = used[next] a.add(next) if (!alreadyUsed) { used[next] = true if (next >= 0 && next <= 1000) used1000[next] = true } if (n == 14) System.print("The first 15 terms of the Recaman's sequence are:\n%(a)") if (!foundDup && alreadyUsed) { System.print("The first duplicated term is a[%(n)] = %(next)") foundDup = true } if (used1000.count == 1001) { System.print("Terms up to a[%(n)] are needed to generate 0 to 1000") } n = n + 1 }</syntaxhighlight> {{out}} <pre> The first 15 terms of the Recaman's sequence are: [0, 1, 3, 6, 2, 7, 13, 20, 12, 21, 11, 22, 10, 23, 9] The first duplicated term is a[24] = 42 Terms up to a[328002] are needed to generate 0 to 1000 </pre> =={{header\|zkl}}== <~~lang~~syntaxhighlight lang="zkl">fcn recamanW{ // -->iterator -->(n,a,True if a is a dup) Walker.tweak(fcn(rn,rp,d){ n,p,a := rn.value, rp.value, p - n; Line 251 ⟶ 3,519: return(rn.inc(),a,d[a]>1); }.fp(Ref(0),Ref(0),Dictionary()) ) }</~~lang~~syntaxhighlight> <~~lang~~syntaxhighlight lang="zkl">print("First 15 members of Recaman's sequence: "); recamanW().walk(15).apply("get",1).println(); Line 260 ⟶ 3,528: rw,ns,n,a,dup := recamanW(),1000,0,0,0; do{ n,a,dup=rw.next(); if(not dup and a<1000) ns-=1; }while(ns); println("Range 0..1000 is covered by terms up to a(%,d)".fmt(n));</~~lang~~syntaxhighlight> {{out}} <pre>