Primality by trial division: Difference between revisions
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{{task|Prime Numbers}} |
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{{task|Prime Numbers}}Write a boolean function that tells whether a given integer is prime. Remember that 1 and all non-positive numbers are not prime. |
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;Task: |
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Use trial division. Even numbers may be eliminated right away. A loop from 3 to √(n) will suffice, but other loops are allowed. |
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Write a boolean function that tells whether a given integer is prime. |
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Remember that '''1''' and all non-positive numbers are not prime. |
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Use trial division. |
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Even numbers greater than '''2''' may be eliminated right away. |
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A loop from '''3''' to '''√{{overline| n }} ''' will suffice, but other loops are allowed. |
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;Related tasks: |
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* [[count in factors]] |
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* [[prime decomposition]] |
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* [[AKS test for primes]] |
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* [[factors of an integer]] |
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* [[Sieve of Eratosthenes]] |
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* [[factors of a Mersenne number]] |
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* [[trial factoring of a Mersenne number]] |
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* [[partition an integer X into N primes]] |
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* [[sequence of primes by Trial Division]] |
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<br><br> |
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=={{header|11l}}== |
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<syntaxhighlight lang="11l">F is_prime(n) |
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I n < 2 |
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R 0B |
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L(i) 2..Int(sqrt(n)) |
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I n % i == 0 |
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R 0B |
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R 1B</syntaxhighlight> |
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=={{header|360 Assembly}}== |
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<syntaxhighlight lang="360asm">* Primality by trial division 26/03/2017 |
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PRIMEDIV CSECT |
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USING PRIMEDIV,R13 base register |
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B 72(R15) skip savearea |
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DC 17F'0' savearea |
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STM R14,R12,12(R13) save previous context |
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ST R13,4(R15) link backward |
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ST R15,8(R13) link forward |
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LR R13,R15 set addressability |
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LA R10,PG pgi=0 |
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LA R6,1 i=1 |
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DO WHILE=(C,R6,LE,=F'50') do i=1 to 50 |
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LR R1,R6 i |
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BAL R14,ISPRIME call isprime(i) |
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IF C,R0,EQ,=F'1' THEN if isprime(i) then |
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XDECO R6,XDEC edit i |
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MVC 0(4,R10),XDEC+8 output i |
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LA R10,4(R10) pgi+=4 |
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ENDIF , endif |
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LA R6,1(R6) i++ |
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ENDDO , enddo i |
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XPRNT PG,L'PG print buffer |
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L R13,4(0,R13) restore previous savearea pointer |
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LM R14,R12,12(R13) restore previous context |
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XR R15,R15 rc=0 |
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BR R14 exit |
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*------- ---- ---------------------------------------- |
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ISPRIME EQU * function isprime(n) |
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IF C,R1,LE,=F'1' THEN if n<=1 then |
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LA R0,0 return(0) |
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BR R14 return |
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ENDIF , endif |
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IF C,R1,EQ,=F'2' THEN if n=2 then |
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LA R0,1 return(1) |
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BR R14 return |
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ENDIF , endif |
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LR R4,R1 n |
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N R4,=X'00000001' n and 1 |
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IF LTR,R4,Z,R4 THEN if mod(n,2)=0 then |
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LA R0,0 return(0) |
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BR R14 return |
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ENDIF , endif |
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LA R7,3 j=3 |
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LA R5,9 r5=j*j |
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DO WHILE=(CR,R5,LE,R1) do j=3 by 2 while j*j<=n |
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LR R4,R1 n |
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SRDA R4,32 ~ |
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DR R4,R7 /j |
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IF LTR,R4,Z,R4 THEN if mod(n,j)=0 then |
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LA R0,0 return(0) |
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BR R14 return |
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ENDIF , endif |
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LA R7,2(R7) j+=2 |
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LR R5,R7 j |
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MR R4,R7 r5=j*j |
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ENDDO , enddo j |
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LA R0,1 return(1) |
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BR R14 return |
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*------- ---- ---------------------------------------- |
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PG DC CL80' ' buffer |
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XDEC DS CL12 temp for xdeco |
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YREGS |
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END PRIMEDIV</syntaxhighlight> |
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{{out}} |
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2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 |
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=={{header|68000 Assembly}}== |
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<syntaxhighlight lang="68000devpac">isPrime: |
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; REG USAGE: |
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; D0 = input (unsigned 32-bit integer) |
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; D1 = temp storage for D0 |
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; D2 = candidates for possible factors |
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; D3 = temp storage for quotient/remainder |
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; D4 = total count of proper divisors. |
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MOVEM.L D1-D4,-(SP) ;push data regs except D0 |
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MOVE.L #0,D1 |
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MOVEM.L D1,D2-D4 ;clear regs D1 thru D4 |
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CMP.L #0,D0 |
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BEQ notPrime |
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CMP.L #1,D0 |
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BEQ notPrime |
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CMP.L #2,D0 |
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BEQ wasPrime |
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MOVE.L D0,D1 ;D1 will be used for temp storage. |
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AND.L #1,D1 ;is D1 even? |
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BEQ notPrime ;if so, it's not prime! |
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MOVE.L D0,D1 ;restore D1 |
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MOVE.L #3,D2 ;start with 3 |
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computeFactors: |
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DIVU D2,D1 ;remainder is in top 2 bytes, quotient in bottom 2. |
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MOVE.L D1,D3 ;temporarily store into D3 to check the remainder |
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SWAP D3 ;swap the high and low words of D3. Now bottom 2 bytes contain remainder. |
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CMP.W #0,D3 ;is the bottom word equal to 0? |
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BNE D2_Wasnt_A_Divisor ;if not, D2 was not a factor of D1. |
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ADDQ.L #1,D4 ;increment the count of proper divisors. |
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CMP.L #2,D4 ;is D4 two or greater? |
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BCC notPrime ;if so, it's not prime! (Ends early. We'll need to check again if we made it to the end.) |
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D2_Wasnt_A_Divisor: |
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MOVE.L D0,D1 ;restore D1. |
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ADDQ.L #1,D2 ;increment D2 |
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CMP.L D2,D1 ;is D2 now greater than D1? |
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BLS computeFactors ;if not, loop again |
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CMP.L #1,D4 ;was there only one factor? |
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BEQ wasPrime ;if so, D0 was prime. |
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notPrime: |
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MOVE.L #0,D0 ;return false |
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MOVEM.L (SP)+,D1-D4 ;pop D1-D4 |
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RTS |
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wasPrime: |
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MOVE.L #1,D0 ;return true |
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MOVEM.L (SP)+,D1-D4 ;pop D1-D4 |
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RTS |
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;end of program</syntaxhighlight> |
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=={{header|AArch64 Assembly}}== |
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{{works with|as|Raspberry Pi 3B version Buster 64 bits}} |
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<syntaxhighlight lang="aarch64 assembly"> |
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/* ARM assembly AARCH64 Raspberry PI 3B */ |
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/* program testPrime64.s */ |
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/*******************************************/ |
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/* Constantes file */ |
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/*******************************************/ |
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/* for this file see task include a file in language AArch64 assembly*/ |
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.include "../includeConstantesARM64.inc" |
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/*******************************************/ |
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/* Initialized data */ |
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/*******************************************/ |
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.data |
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szMessStartPgm: .asciz "Program start \n" |
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szMessEndPgm: .asciz "Program normal end.\n" |
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szMessNotPrime: .asciz "Not prime.\n" |
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szMessPrime: .asciz "Prime\n" |
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szCarriageReturn: .asciz "\n" |
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/*******************************************/ |
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/* UnInitialized data */ |
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/*******************************************/ |
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.bss |
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.align 4 |
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/*******************************************/ |
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/* code section */ |
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/*******************************************/ |
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.text |
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.global main |
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main: // program start |
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ldr x0,qAdrszMessStartPgm // display start message |
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bl affichageMess |
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ldr x0,qVal |
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bl isPrime // test prime ? |
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cmp x0,#0 |
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beq 1f |
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ldr x0,qAdrszMessPrime // yes |
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bl affichageMess |
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b 2f |
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1: |
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ldr x0,qAdrszMessNotPrime // no |
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bl affichageMess |
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2: |
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ldr x0,qAdrszMessEndPgm // display end message |
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bl affichageMess |
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100: // standard end of the program |
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mov x0,0 // return code |
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mov x8,EXIT // request to exit program |
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svc 0 // perform system call |
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qAdrszMessStartPgm: .quad szMessStartPgm |
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qAdrszMessEndPgm: .quad szMessEndPgm |
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qAdrszCarriageReturn: .quad szCarriageReturn |
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qAdrszMessNotPrime: .quad szMessNotPrime |
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qAdrszMessPrime: .quad szMessPrime |
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//qVal: .quad 1042441 // test not prime |
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//qVal: .quad 1046527 // test prime |
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//qVal: .quad 37811 // test prime |
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//qVal: .quad 1429671721 // test not prime (37811 * 37811) |
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qVal: .quad 100000004437 // test prime |
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/******************************************************************/ |
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/* test if number is prime */ |
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/******************************************************************/ |
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/* x0 contains the number */ |
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/* x0 return 1 if prime else return 0 */ |
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isPrime: |
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stp x1,lr,[sp,-16]! // save registers |
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cmp x0,1 // <= 1 ? |
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ble 98f |
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cmp x0,3 // 2 and 3 prime |
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ble 97f |
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tst x0,1 // even ? |
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beq 98f |
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mov x11,3 // first divisor |
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1: |
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udiv x12,x0,x11 |
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msub x13,x12,x11,x0 // compute remainder |
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cbz x13,98f // end if zero |
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add x11,x11,#2 // increment divisor |
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cmp x11,x12 // divisors<=quotient ? |
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ble 1b // loop |
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97: |
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mov x0,1 // return prime |
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b 100f |
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98: |
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mov x0,0 // not prime |
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b 100f |
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100: |
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ldp x1,lr,[sp],16 // restaur 2 registers |
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ret // return to address lr x30 |
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/********************************************************/ |
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/* File Include fonctions */ |
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/********************************************************/ |
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/* for this file see task include a file in language AArch64 assembly */ |
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.include "../includeARM64.inc" |
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</syntaxhighlight> |
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=={{header|ABAP}}== |
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<syntaxhighlight lang="abap">class ZMLA_ROSETTA definition |
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public |
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create public . |
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public section. |
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types: |
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enumber TYPE N LENGTH 60 . |
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types: |
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listof_enumber TYPE TABLE OF enumber . |
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class-methods IS_PRIME |
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importing |
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value(N) type ENUMBER |
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returning |
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value(OFLAG) type ABAP_BOOL . |
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class-methods IS_PRIME_I |
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importing |
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value(N) type I |
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returning |
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value(OFLAG) type ABAP_BOOL . |
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protected section. |
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private section. |
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ENDCLASS. |
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CLASS ZMLA_ROSETTA IMPLEMENTATION. |
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* <SIGNATURE>---------------------------------------------------------------------------------------+ |
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* | Static Public Method ZMLA_ROSETTA=>IS_PRIME |
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* +-------------------------------------------------------------------------------------------------+ |
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* | [--->] N TYPE ENUMBER |
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* | [<-()] OFLAG TYPE ABAP_BOOL |
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* +--------------------------------------------------------------------------------------</SIGNATURE> |
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method IS_PRIME. |
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IF n < 2. |
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oflag = abap_false. |
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RETURN. |
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ENDIF. |
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IF n = 2 or n = 3. |
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oflag = abap_true. |
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RETURN. |
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ENDIF. |
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IF n mod 2 = 0 or n mod 3 = 0. |
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oflag = abap_false. |
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RETURN. |
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ENDIF. |
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DATA: lim type enumber, |
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d type enumber, |
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i TYPE i VALUE 2. |
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lim = sqrt( n ). |
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d = 5. |
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WHILE d <= lim. |
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IF n mod d = 0. |
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oflag = abap_false. |
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RETURN. |
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ENDIF. |
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d = d + i. |
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i = 6 - i. " this modifies 2 into 4 and viceversa |
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ENDWHILE. |
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oflag = abap_true. |
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RETURN. |
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endmethod. |
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* <SIGNATURE>---------------------------------------------------------------------------------------+ |
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* | Static Public Method ZMLA_ROSETTA=>IS_PRIME_I |
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* +-------------------------------------------------------------------------------------------------+ |
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* | [--->] N TYPE I |
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* | [<-()] OFLAG TYPE ABAP_BOOL |
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* +--------------------------------------------------------------------------------------</SIGNATURE> |
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method IS_PRIME_I. |
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IF n < 2. |
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oflag = abap_false. |
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RETURN. |
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ENDIF. |
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IF n = 2 or n = 3. |
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oflag = abap_true. |
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RETURN. |
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ENDIF. |
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IF n mod 2 = 0 or n mod 3 = 0. |
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oflag = abap_false. |
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RETURN. |
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ENDIF. |
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DATA: lim type i, |
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d type i, |
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i TYPE i VALUE 2. |
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lim = sqrt( n ). |
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d = 5. |
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WHILE d <= lim. |
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IF n mod d = 0. |
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oflag = abap_false. |
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RETURN. |
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ENDIF. |
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d = d + i. |
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i = 6 - i. " this modifies 2 into 4 and viceversa |
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ENDWHILE. |
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oflag = abap_true. |
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RETURN. |
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endmethod. |
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ENDCLASS.</syntaxhighlight> |
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=={{header|ABC}}== |
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<syntaxhighlight lang="ABC">HOW TO REPORT prime n: |
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REPORT n>=2 AND NO d IN {2..floor root n} HAS n mod d = 0 |
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FOR n IN {1..100}: |
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IF prime n: WRITE n</syntaxhighlight> |
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{{out}} |
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<pre>2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97</pre> |
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=={{header|ACL2}}== |
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<syntaxhighlight lang="lisp">(defun is-prime-r (x i) |
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(declare (xargs :measure (nfix (- x i)))) |
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(if (zp (- (- x i) 1)) |
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t |
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(and (/= (mod x i) 0) |
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(is-prime-r x (1+ i))))) |
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(defun is-prime (x) |
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(or (= x 2) |
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(is-prime-r x 2)))</syntaxhighlight> |
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=={{header|Action!}}== |
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<syntaxhighlight lang="action!">BYTE FUNC IsPrime(CARD a) |
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CARD i |
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IF a<=1 THEN |
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RETURN (0) |
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FI |
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FOR i=2 TO a/2 |
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DO |
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IF a MOD i=0 THEN |
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RETURN (0) |
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FI |
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OD |
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RETURN (1) |
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PROC Test(CARD a) |
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IF IsPrime(a) THEN |
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PrintF("%I is prime%E",a) |
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ELSE |
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PrintF("%I is not prime%E",a) |
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FI |
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RETURN |
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PROC Main() |
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Test(13) |
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Test(997) |
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Test(1) |
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Test(6) |
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Test(120) |
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Test(0) |
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RETURN</syntaxhighlight> |
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{{out}} |
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[https://gitlab.com/amarok8bit/action-rosetta-code/-/raw/master/images/Primality_by_trial_division.png Screenshot from Atari 8-bit computer] |
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<pre> |
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13 is prime |
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997 is prime |
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1 is not prime |
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6 is not prime |
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120 is not prime |
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0 is not prime |
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</pre> |
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=={{header|ActionScript}}== |
=={{header|ActionScript}}== |
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< |
<syntaxhighlight lang="actionscript">function isPrime(n:int):Boolean |
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{ |
{ |
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if(n < 2) return false; |
if(n < 2) return false; |
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Line 12: | Line 442: | ||
if(n % i == 0) return false; |
if(n % i == 0) return false; |
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return true; |
return true; |
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}</ |
}</syntaxhighlight> |
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=={{header|Ada}}== |
=={{header|Ada}}== |
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< |
<syntaxhighlight lang="ada">function Is_Prime(Item : Positive) return Boolean is |
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Result : Boolean := True; |
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Test : Natural; |
Test : Natural; |
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begin |
begin |
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if Item |
if Item = 1 then |
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return False; |
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elsif Item = 2 then |
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return True; |
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elsif Item mod 2 = 0 then |
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return False; |
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else |
else |
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Test := 3; |
Test := 3; |
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while Test < Integer(Sqrt(Float(Item))) loop |
while Test <= Integer(Sqrt(Float(Item))) loop |
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if Item mod Test = 0 then |
if Item mod Test = 0 then |
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return False; |
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exit; |
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end if; |
end if; |
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Test := Test + 2; |
Test := Test + 2; |
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end loop; |
end loop; |
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end if; |
end if; |
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return |
return True; |
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end Is_Prime;</ |
end Is_Prime;</syntaxhighlight> |
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<code>Sqrt</code> is made visible by a with / use clause on <code>Ada.Numerics.Elementary_Functions</code>. |
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=={{header|ALGOL 68}}== |
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<lang algol68>main:(</lang> |
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With Ada 2012, the function can be made more compact as an expression function (but without loop optimized by skipping even numbers) : |
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<syntaxhighlight lang="ada">function Is_Prime(Item : Positive) return Boolean is |
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(Item /= 1 and then |
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(for all Test in 2..Integer(Sqrt(Float(Item))) => Item mod Test /= 0));</syntaxhighlight> |
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As an alternative, one can use the generic function Prime_Numbers.Is_Prime, as specified in [[Prime decomposition#Ada]], which also implements trial division. |
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<syntaxhighlight lang="ada">with Prime_Numbers; |
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procedure Test_Prime is |
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package Integer_Numbers is new |
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Prime_Numbers (Natural, 0, 1, 2); |
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use Integer_Numbers; |
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begin |
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if Is_Prime(12) or (not Is_Prime(13)) then |
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raise Program_Error with "Test_Prime failed!"; |
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end if; |
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end Test_Prime;</syntaxhighlight> |
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=={{header|ALGOL 60}}== |
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{{works with|A60}} |
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<syntaxhighlight lang = "algol"> |
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begin |
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boolean procedure isprime(n); |
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value n; integer n; |
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begin |
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comment - local procedure tests whether n is even; |
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boolean procedure even(n); |
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value n; integer n; |
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even := entier(n / 2) * 2 = n; |
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if n < 2 then |
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isprime := false |
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else if even(n) then |
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isprime := (n = 2) |
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else |
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begin |
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comment - check odd divisors up to sqrt(n); |
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integer i, limit; |
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boolean divisible; |
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i := 3; |
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limit := entier(sqrt(n)); |
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divisible := false; |
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for i := i while i <= limit and not divisible do |
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begin |
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if entier(n / i) * i = n then |
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divisible := true; |
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i := i + 2 |
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end; |
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isprime := if divisible then false else true; |
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end; |
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end; |
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comment - exercise the procedure; |
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integer i; |
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outstring(1,"Testing first 50 numbers for primality:\n"); |
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for i := 1 step 1 until 50 do |
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if isprime(i) then |
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outinteger(1,i); |
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end |
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</syntaxhighlight> |
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{{out}} |
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<pre> |
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Testing first 50 numbers for primality: |
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2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 |
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</pre> |
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=={{header|ALGOL 68}}== |
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{{works with|ALGOL 68|Revision 1 - no extensions to language used}} |
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{{works with|ALGOL 68G|Any - tested with release [http://sourceforge.net/projects/algol68/files/algol68g/algol68g-1.18.0/algol68g-1.18.0-9h.tiny.el5.centos.fc11.i386.rpm/download 1.18.0-9h.tiny]}} |
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{{wont work with|ELLA ALGOL 68|Any (with appropriate job cards) - tested with release [http://sourceforge.net/projects/algol68/files/algol68toc/algol68toc-1.8.8d/algol68toc-1.8-8d.fc9.i386.rpm/download 1.8-8d] - due to extensive use of FORMATted transput}} |
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{{prelude/is_prime.a68}}; |
{{prelude/is_prime.a68}}; |
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<syntaxhighlight lang="algol68">main:( |
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INT upb=100; |
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printf(($" The primes up to "g(-3)" are:"l$,upb)); |
printf(($" The primes up to "g(-3)" are:"l$,upb)); |
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FOR i TO upb DO |
FOR i TO upb DO |
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Line 46: | Line 552: | ||
OD; |
OD; |
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printf($l$) |
printf($l$) |
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)</ |
)</syntaxhighlight> |
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{{out}} |
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Output: |
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The primes up to 100 are: |
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2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 |
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 |
||
=={{ |
=={{header|ALGOL-M}}== |
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<syntaxhighlight lang="algol"> |
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BEGIN |
|||
% RETURN P MOD Q % |
|||
INTEGER FUNCTION MOD(P, Q); |
|||
INTEGER P, Q; |
|||
BEGIN |
|||
MOD := P - Q * (P / Q); |
|||
END; |
|||
% RETURN INTEGER SQUARE ROOT OF N % |
|||
INTEGER FUNCTION ISQRT(N); |
|||
INTEGER N; |
|||
BEGIN |
|||
INTEGER R1, R2; |
|||
R1 := N; |
|||
R2 := 1; |
|||
WHILE R1 > R2 DO |
|||
BEGIN |
|||
R1 := (R1+R2) / 2; |
|||
R2 := N / R1; |
|||
END; |
|||
ISQRT := R1; |
|||
END; |
|||
% RETURN 1 IF N IS PRIME, OTHERWISE 0 % |
|||
INTEGER FUNCTION ISPRIME(N); |
|||
INTEGER N; |
|||
BEGIN |
|||
IF N = 2 THEN |
|||
ISPRIME := 1 |
|||
ELSE IF (N < 2) OR (MOD(N,2) = 0) THEN |
|||
ISPRIME := 0 |
|||
ELSE % TEST ODD NUMBERS UP TO SQRT OF N % |
|||
BEGIN |
|||
INTEGER I, LIMIT; |
|||
LIMIT := ISQRT(N); |
|||
I := 3; |
|||
WHILE I <= LIMIT AND MOD(N,I) <> 0 DO |
|||
I := I + 2; |
|||
ISPRIME := (IF I <= LIMIT THEN 0 ELSE 1); |
|||
END; |
|||
END; |
|||
% TEST FOR PRIMES IN RANGE 1 TO 50 % |
|||
INTEGER I; |
|||
WRITE(""); |
|||
FOR I := 1 STEP 1 UNTIL 50 DO |
|||
BEGIN |
|||
IF ISPRIME(I)=1 THEN WRITEON(I," "); % WORKS FOR 80 COL SCREEN % |
|||
END; |
|||
END |
|||
</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2 3 5 7 11 13 17 19 23 29 |
|||
31 37 41 43 47 |
|||
</pre> |
|||
=={{header|ALGOL W}}== |
|||
<syntaxhighlight lang="algolw">% returns true if n is prime, false otherwise % |
|||
% uses trial division % |
|||
logical procedure isPrime ( integer value n ) ; |
|||
if n < 3 or not odd( n ) then n = 2 |
|||
else begin |
|||
% odd number > 2 % |
|||
integer f, rootN; |
|||
logical havePrime; |
|||
f := 3; |
|||
rootN := entier( sqrt( n ) ); |
|||
havePrime := true; |
|||
while f <= rootN and havePrime do begin |
|||
havePrime := ( n rem f ) not = 0; |
|||
f := f + 2 |
|||
end; |
|||
havePrime |
|||
end isPrime ;</syntaxhighlight> |
|||
Test program: |
|||
<syntaxhighlight lang="algolw">begin |
|||
logical procedure isPrime ( integer value n ) ; algol "isPrime" ; |
|||
for i := 0 until 32 do if isPrime( i ) then writeon( i_w := 1,s_w := 1, i ) |
|||
end.</syntaxhighlight> |
|||
{{out}} |
|||
2 3 5 7 11 13 17 19 23 29 31 |
|||
=={{header|APL}}== |
|||
<syntaxhighlight lang="APL">prime ← 2=0+.=⍳|⊣</syntaxhighlight> |
|||
{{out}} |
|||
<syntaxhighlight lang="APL"> (⊢(/⍨)prime¨)⍳100 |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97</syntaxhighlight> |
|||
=={{header|AppleScript}}== |
|||
<syntaxhighlight lang="applescript">on isPrime(n) |
|||
if (n < 3) then return (n is 2) |
|||
if (n mod 2 is 0) then return false |
|||
repeat with i from 3 to (n ^ 0.5) div 1 by 2 |
|||
if (n mod i is 0) then return false |
|||
end repeat |
|||
return true |
|||
end isPrime |
|||
-- Test code: |
|||
set output to {} |
|||
repeat with n from -7 to 100 |
|||
if (isPrime(n)) then set end of output to n |
|||
end repeat |
|||
return output</syntaxhighlight> |
|||
Or eliminating multiples of 3 at the start as well as those of 2: |
|||
<syntaxhighlight lang="applescript">on isPrime(n) |
|||
if (n < 4) then return (n > 1) |
|||
if ((n mod 2 is 0) or (n mod 3 is 0)) then return false |
|||
repeat with i from 5 to (n ^ 0.5) div 1 by 6 |
|||
if ((n mod i is 0) or (n mod (i + 2) is 0)) then return false |
|||
end repeat |
|||
return true |
|||
end isPrime |
|||
-- Test code: |
|||
set output to {} |
|||
repeat with n from -7 to 100 |
|||
if (isPrime(n)) then set end of output to n |
|||
end repeat |
|||
return output</syntaxhighlight> |
|||
{{output}} |
|||
<syntaxhighlight lang="applescript">{2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97}</syntaxhighlight> |
|||
=={{header|ARM Assembly}}== |
|||
{{works with|as|Raspberry Pi <br> or android 32 bits with application Termux}} |
|||
<syntaxhighlight lang ARM Assembly> |
|||
/* ARM assembly Raspberry PI */ |
|||
/* program testtrialprime.s */ |
|||
/************************************/ |
|||
/* Constantes */ |
|||
/************************************/ |
|||
/* for this file see task include a file in language ARM assembly*/ |
|||
.include "../constantes.inc" |
|||
//.include "../../ficmacros32.inc" @ for debugging developper |
|||
/************************************/ |
|||
/* Initialized data */ |
|||
/************************************/ |
|||
.data |
|||
szMessPrime: .asciz " is prime.\n" |
|||
szMessNotPrime: .asciz " is not prime.\n" |
|||
szCarriageReturn: .asciz "\n" |
|||
szMessStart: .asciz "Program 32 bits start.\n" |
|||
/************************************/ |
|||
/* UnInitialized data */ |
|||
/************************************/ |
|||
.bss |
|||
sZoneConv: .skip 24 |
|||
/************************************/ |
|||
/* code section */ |
|||
/************************************/ |
|||
.text |
|||
.global main |
|||
main: @ entry of program |
|||
ldr r0,iAdrszMessStart |
|||
bl affichageMess |
|||
mov r0,#19 |
|||
bl testPrime |
|||
ldr r0,iStart @ number |
|||
bl testPrime |
|||
ldr r0,iStart1 @ number |
|||
bl testPrime |
|||
100: @ standard end of the program |
|||
mov r0, #0 @ return code |
|||
mov r7, #EXIT @ request to exit program |
|||
swi 0 @ perform the system call |
|||
iAdrsZoneConv: .int sZoneConv |
|||
iAdrszMessPrime: .int szMessPrime |
|||
iAdrszMessNotPrime: .int szMessNotPrime |
|||
iAdrszCarriageReturn: .int szCarriageReturn |
|||
iAdrszMessStart: .int szMessStart |
|||
iStart: .int 2600002183 |
|||
iStart1: .int 4124163031 |
|||
/******************************************************************/ |
|||
/* test if number is prime */ |
|||
/******************************************************************/ |
|||
/* r0 contains the number */ |
|||
testPrime: |
|||
push {r1,r2,lr} @ save registers |
|||
mov r2,r0 |
|||
ldr r1,iAdrsZoneConv |
|||
bl conversion10 @ decimal conversion |
|||
ldr r0,iAdrsZoneConv |
|||
bl affichageMess |
|||
mov r0,r2 |
|||
bl isPrime |
|||
cmp r0,#0 |
|||
beq 1f |
|||
ldr r0,iAdrszMessPrime |
|||
bl affichageMess |
|||
b 100f |
|||
1: |
|||
ldr r0,iAdrszMessNotPrime |
|||
bl affichageMess |
|||
100: |
|||
pop {r1,r2,pc} @ restaur registers |
|||
/******************************************************************/ |
|||
/* test if number is prime */ |
|||
/******************************************************************/ |
|||
/* r0 contains the number */ |
|||
/* r0 return 1 if prime else return 0 */ |
|||
isPrime: |
|||
push {r4,lr} @ save registers |
|||
cmp r0,#1 @ <= 1 ? |
|||
movls r0,#0 @ not prime |
|||
bls 100f |
|||
cmp r0,#3 @ 2 and 3 prime |
|||
movls r0,#1 |
|||
bls 100f |
|||
tst r0,#1 @ even ? |
|||
moveq r0,#0 @ not prime |
|||
beq 100f |
|||
mov r4,r0 @ save number |
|||
mov r1,#3 @ first divisor |
|||
1: |
|||
mov r0,r4 @ number |
|||
bl division |
|||
add r1,r1,#2 @ increment divisor |
|||
cmp r3,#0 @ remainder = zero ? |
|||
moveq r0,#0 @ not prime |
|||
beq 100f |
|||
cmp r1,r2 @ divisors<=quotient ? |
|||
ble 1b @ loop |
|||
mov r0,#1 @ return prime |
|||
100: |
|||
pop {r4,pc} @ restaur registers |
|||
/***************************************************/ |
|||
/* ROUTINES INCLUDE */ |
|||
/***************************************************/ |
|||
/* for this file see task include a file in language ARM assembly*/ |
|||
.include "../affichage.inc" |
|||
</syntaxhighlight> |
|||
{{Out}} |
|||
<pre> |
|||
Program 32 bits start. |
|||
19 is prime. |
|||
2600002183 is prime. |
|||
4124163031 is not prime. |
|||
</pre> |
|||
=={{header|Arturo}}== |
|||
<syntaxhighlight lang="rebol">isPrime?: function [n][ |
|||
if n=2 -> return true |
|||
if n=3 -> return true |
|||
if or? n=<1 0=n%2 -> return false |
|||
high: to :integer sqrt n |
|||
loop high..2 .step: 3 'i [ |
|||
if 0=n%i -> return false |
|||
] |
|||
return true |
|||
] |
|||
loop 1..20 'i [ |
|||
print ["isPrime?" i "=" isPrime? i ] |
|||
]</syntaxhighlight> |
|||
{{out}} |
|||
<pre>isPrime? 1 = false |
|||
isPrime? 2 = true |
|||
isPrime? 3 = true |
|||
isPrime? 4 = false |
|||
isPrime? 5 = true |
|||
isPrime? 6 = false |
|||
isPrime? 7 = true |
|||
isPrime? 8 = false |
|||
isPrime? 9 = false |
|||
isPrime? 10 = false |
|||
isPrime? 11 = true |
|||
isPrime? 12 = false |
|||
isPrime? 13 = true |
|||
isPrime? 14 = false |
|||
isPrime? 15 = false |
|||
isPrime? 16 = false |
|||
isPrime? 17 = true |
|||
isPrime? 18 = false |
|||
isPrime? 19 = true |
|||
isPrime? 20 = false</pre> |
|||
=={{header|AutoHotkey}}== |
|||
[http://www.autohotkey.com/forum/topic44657.html Discussion] |
[http://www.autohotkey.com/forum/topic44657.html Discussion] |
||
< |
<syntaxhighlight lang="autohotkey">MsgBox % IsPrime(1995937) |
||
Loop |
Loop |
||
MsgBox % A_Index-3 . " is " . (IsPrime(A_Index-3) ? "" : "not ") . "prime." |
MsgBox % A_Index-3 . " is " . (IsPrime(A_Index-3) ? "" : "not ") . "prime." |
||
Line 61: | Line 863: | ||
d := k+(k<7 ? 1+(k>2) : SubStr("6-----4---2-4---2-4---6-----2",Mod(k,30),1)) |
d := k+(k<7 ? 1+(k>2) : SubStr("6-----4---2-4---2-4---6-----2",Mod(k,30),1)) |
||
Return n < 3 ? n>1 : Mod(n,k) ? (d*d <= n ? IsPrime(n,d) : 1) : 0 |
Return n < 3 ? n>1 : Mod(n,k) ? (d*d <= n ? IsPrime(n,d) : 1) : 0 |
||
}</ |
}</syntaxhighlight> |
||
=={{header|AutoIt}}== |
|||
<syntaxhighlight lang="autoit">#cs ---------------------------------------------------------------------------- |
|||
AutoIt Version: 3.3.8.1 |
|||
Author: Alexander Alvonellos |
|||
Script Function: |
|||
Perform primality test on a given integer $number. |
|||
RETURNS: TRUE/FALSE |
|||
#ce ---------------------------------------------------------------------------- |
|||
Func main() |
|||
ConsoleWrite("The primes up to 100 are: " & @LF) |
|||
For $i = 1 To 100 Step 1 |
|||
If(isPrime($i)) Then |
|||
If($i <> 97) Then |
|||
ConsoleWrite($i & ", ") |
|||
Else |
|||
ConsoleWrite($i) |
|||
EndIf |
|||
EndIf |
|||
Next |
|||
EndFunc |
|||
Func isPrime($n) |
|||
If($n < 2) Then Return False |
|||
If($n = 2) Then Return True |
|||
If(BitAnd($n, 1) = 0) Then Return False |
|||
For $i = 3 To Sqrt($n) Step 2 |
|||
If(Mod($n, $i) = 0) Then Return False |
|||
Next |
|||
Return True |
|||
EndFunc |
|||
main()</syntaxhighlight> |
|||
=={{header|AWK}}== |
=={{header|AWK}}== |
||
$ awk 'func prime(n){for(d=2;d<=sqrt(n);d++)if(!(n%d)){return 0};return 1}{print prime($1)}' |
$ awk 'func prime(n){for(d=2;d<=sqrt(n);d++)if(!(n%d)){return 0};return 1}{print prime($1)}' |
||
Or more legibly, and with n <= 1 handling |
|||
<syntaxhighlight lang="awk">function prime(n) { |
|||
if (n <= 1) return 0 |
|||
for (d = 2; d <= sqrt(n); d++) |
|||
if (!(n % d)) return 0 |
|||
return 1 |
|||
} |
|||
{print prime($1)}</syntaxhighlight> |
|||
=={{header|B}}== |
|||
==={{header|B as on PDP7/UNIX0}}=== |
|||
{{trans|C}} |
|||
{{works with|B as on PDP7/UNIX0|(proto-B?)}} |
|||
<syntaxhighlight lang="b">isprime(n) { |
|||
auto p; |
|||
if(n<2) return(0); |
|||
if(!(n%2)) return(n==2); |
|||
p=3; |
|||
while(n/p>p) { |
|||
if(!(n%p)) return(0); |
|||
p=p+2; |
|||
} |
|||
return(1); |
|||
}</syntaxhighlight> |
|||
=={{header|BASIC}}== |
=={{header|BASIC}}== |
||
==={{header|Applesoft BASIC}}=== |
|||
<syntaxhighlight lang="basic"> 100 DEF FN MOD(NUM) = NUM - INT (NUM / DIV) * DIV: REM NUM MOD DIV |
|||
110 FOR I = 1 TO 99 |
|||
120 V = I: GOSUB 200"ISPRIME |
|||
130 IF ISPRIME THEN PRINT " "I; |
|||
140 NEXT I |
|||
150 END |
|||
200 ISPRIME = FALSE: IF V < 2 THEN RETURN |
|||
210 DIV = 2:ISPRIME = FN MOD(V): IF NOT ISPRIME THEN ISPRIME = V = 2: RETURN |
|||
220 LIMIT = SQR (V): IF LIMIT > = 3 THEN FOR DIV = 3 TO LIMIT STEP 2:ISPRIME = FN MOD(V): IF ISPRIME THEN NEXT DIV |
|||
230 RETURN</syntaxhighlight> |
|||
==={{header|BASIC256}}=== |
|||
{{trans|FreeBASIC}} |
|||
<syntaxhighlight lang="freebasic">for i = 1 to 99 |
|||
if isPrime(i) then print string(i); " "; |
|||
next i |
|||
end |
|||
function isPrime(v) |
|||
if v < 2 then return False |
|||
if v mod 2 = 0 then return v = 2 |
|||
if v mod 3 = 0 then return v = 3 |
|||
d = 5 |
|||
while d * d <= v |
|||
if v mod d = 0 then return False else d += 2 |
|||
end while |
|||
return True |
|||
end function</syntaxhighlight> |
|||
==={{header|BBC BASIC}}=== |
|||
<syntaxhighlight lang="bbcbasic"> FOR i% = -1 TO 100 |
|||
IF FNisprime(i%) PRINT ; i% " is prime" |
|||
NEXT |
|||
END |
|||
DEF FNisprime(n%) |
|||
IF n% <= 1 THEN = FALSE |
|||
IF n% <= 3 THEN = TRUE |
|||
IF (n% AND 1) = 0 THEN = FALSE |
|||
LOCAL t% |
|||
FOR t% = 3 TO SQR(n%) STEP 2 |
|||
IF n% MOD t% = 0 THEN = FALSE |
|||
NEXT |
|||
= TRUE</syntaxhighlight> |
|||
{{out}} |
|||
<pre>2 is prime |
|||
3 is prime |
|||
5 is prime |
|||
7 is prime |
|||
11 is prime |
|||
13 is prime |
|||
17 is prime |
|||
19 is prime |
|||
23 is prime |
|||
29 is prime |
|||
31 is prime |
|||
37 is prime |
|||
41 is prime |
|||
43 is prime |
|||
47 is prime |
|||
53 is prime |
|||
59 is prime |
|||
61 is prime |
|||
67 is prime |
|||
71 is prime |
|||
73 is prime |
|||
79 is prime |
|||
83 is prime |
|||
89 is prime |
|||
97 is prime</pre> |
|||
==={{header|Craft Basic}}=== |
|||
<syntaxhighlight lang="basic">for i = 1 to 50 |
|||
if i < 2 then |
|||
let p = 0 |
|||
else |
|||
if i = 2 then |
|||
let p = 1 |
|||
else |
|||
if i % 2 = 0 then |
|||
let p = 0 |
|||
else |
|||
let p = 1 |
|||
for j = 3 to int(i ^ .5) step 2 |
|||
if i % j = 0 then |
|||
let p = 0 |
|||
break j |
|||
endif |
|||
wait |
|||
next j |
|||
endif |
|||
endif |
|||
endif |
|||
if p <> 0 then |
|||
print i |
|||
endif |
|||
next i</syntaxhighlight> |
|||
{{out| Output}}<pre>2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 </pre> |
|||
==={{header|FBSL}}=== |
|||
The second function (included by not used) I would have thought would be faster because it lacks the SQR() function. As it happens, the first is over twice as fast. |
|||
<syntaxhighlight lang="qbasic">#APPTYPE CONSOLE |
|||
FUNCTION ISPRIME(n AS INTEGER) AS INTEGER |
|||
IF n = 2 THEN |
|||
RETURN TRUE |
|||
ELSEIF n <= 1 ORELSE n MOD 2 = 0 THEN |
|||
RETURN FALSE |
|||
ELSE |
|||
FOR DIM i = 3 TO SQR(n) STEP 2 |
|||
IF n MOD i = 0 THEN |
|||
RETURN FALSE |
|||
END IF |
|||
NEXT |
|||
RETURN TRUE |
|||
END IF |
|||
END FUNCTION |
|||
FUNCTION ISPRIME2(N AS INTEGER) AS INTEGER |
|||
IF N <= 1 THEN RETURN FALSE |
|||
DIM I AS INTEGER = 2 |
|||
WHILE I * I <= N |
|||
IF N MOD I = 0 THEN |
|||
RETURN FALSE |
|||
END IF |
|||
I = I + 1 |
|||
WEND |
|||
RETURN TRUE |
|||
END FUNCTION |
|||
' Test and display primes 1 .. 50 |
|||
DIM n AS INTEGER |
|||
FOR n = 1 TO 50 |
|||
IF ISPRIME(n) THEN |
|||
PRINT n, " "; |
|||
END IF |
|||
NEXT |
|||
PAUSE</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 |
|||
Press any key to continue... |
|||
</pre> |
|||
==={{header|FreeBASIC}}=== |
|||
<syntaxhighlight lang="freebasic">' FB 1.05.0 Win64 |
|||
Function isPrime(n As Integer) As Boolean |
|||
If n < 2 Then Return False |
|||
If n = 2 Then Return True |
|||
If n Mod 2 = 0 Then Return False |
|||
Dim limit As Integer = Sqr(n) |
|||
For i As Integer = 3 To limit Step 2 |
|||
If n Mod i = 0 Then Return False |
|||
Next |
|||
Return True |
|||
End Function |
|||
' To test this works, print all primes under 100 |
|||
For i As Integer = 1 To 99 |
|||
If isPrime(i) Then |
|||
Print Str(i); " "; |
|||
End If |
|||
Next |
|||
Print : Print |
|||
Print "Press any key to quit" |
|||
Sleep</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 |
|||
</pre> |
|||
==={{header|FutureBasic}}=== |
|||
<syntaxhighlight lang="futurebasic">window 1, @"Primality By Trial Division", (0,0,480,270) |
|||
local fn isPrime( n as long ) as Boolean |
|||
long i |
|||
Boolean result |
|||
if n < 2 then result = NO : exit fn |
|||
if n = 2 then result = YES : exit fn |
|||
if n mod 2 == 0 then result = NO : exit fn |
|||
result = YES |
|||
for i = 3 to int( n^.5 ) step 2 |
|||
if n mod i == 0 then result = NO : break |
|||
next i |
|||
end fn = result |
|||
long i, j = 0 |
|||
print "Prime numbers between 0 and 1000:" |
|||
for i = 0 to 1000 |
|||
if ( fn isPrime(i) != _false ) |
|||
printf @"%3d\t",i : j++ |
|||
if j mod 10 == 0 then print |
|||
end if |
|||
next |
|||
HandleEvents</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
Prime numbers between 0 and 1000: |
|||
2 3 5 7 11 13 17 19 23 29 |
|||
31 37 41 43 47 53 59 61 67 71 |
|||
73 79 83 89 97 101 103 107 109 113 |
|||
127 131 137 139 149 151 157 163 167 173 |
|||
179 181 191 193 197 199 211 223 227 229 |
|||
233 239 241 251 257 263 269 271 277 281 |
|||
283 293 307 311 313 317 331 337 347 349 |
|||
353 359 367 373 379 383 389 397 401 409 |
|||
419 421 431 433 439 443 449 457 461 463 |
|||
467 479 487 491 499 503 509 521 523 541 |
|||
547 557 563 569 571 577 587 593 599 601 |
|||
607 613 617 619 631 641 643 647 653 659 |
|||
661 673 677 683 691 701 709 719 727 733 |
|||
739 743 751 757 761 769 773 787 797 809 |
|||
811 821 823 827 829 839 853 857 859 863 |
|||
877 881 883 887 907 911 919 929 937 941 |
|||
947 953 967 971 977 983 991 997 |
|||
</pre> |
|||
==={{header|Gambas}}=== |
|||
'''[https://gambas-playground.proko.eu/?gist=85fbc7936b17b3009af282752aa29df7 Click this link to run this code]''' |
|||
<syntaxhighlight lang="gambas">'Reworked from the BBC Basic example |
|||
Public Sub Main() |
|||
Dim iNum As Integer |
|||
For iNum = 1 To 100 |
|||
If FNisprime(iNum) Then Print iNum & " is prime" |
|||
Next |
|||
End |
|||
'___________________________________________________ |
|||
Public Sub FNisprime(iNum As Integer) As Boolean |
|||
Dim iLoop As Integer |
|||
Dim bReturn As Boolean = True |
|||
If iNum <= 1 Then bReturn = False |
|||
If iNum <= 3 Then bReturn = True |
|||
If (iNum And 1) = 0 Then bReturn = False |
|||
For iLoop = 3 To Sqr(iNum) Step 2 |
|||
If iNum Mod iLoop = 0 Then bReturn = False |
|||
Next |
|||
Return bReturn |
|||
End</syntaxhighlight> |
|||
{{out}} |
|||
<pre>1 is prime |
|||
3 is prime |
|||
5 is prime |
|||
7 is prime |
|||
11 is prime |
|||
...... |
|||
73 is prime |
|||
79 is prime |
|||
83 is prime |
|||
89 is prime |
|||
97 is prime</pre> |
|||
==={{header|GW-BASIC}}=== |
|||
{{trans|Craft Basic}} |
|||
{{works with|PC-BASIC|any}} |
|||
{{works with|BASICA}} |
|||
{{works with|QBasic}} |
|||
{{works with|QB64}} |
|||
<syntaxhighlight lang="qbasic">100 FOR I = 1 TO 99 |
|||
110 IF I < 2 THEN P = 0 : GOTO 180 |
|||
120 IF I = 2 THEN P = 1 : GOTO 180 |
|||
130 IF I MOD 2 = 0 THEN P = 0 : GOTO 180 |
|||
140 P = 1 |
|||
150 FOR J = 3 TO SQR(I) STEP 2 |
|||
160 IF I MOD J = 0 THEN P = 0 : GOTO 180 |
|||
170 NEXT J |
|||
180 IF P <> 0 THEN PRINT I; |
|||
190 NEXT I |
|||
200 END</syntaxhighlight> |
|||
{{out}} |
|||
<pre> 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97</pre> |
|||
==={{header|IS-BASIC}}=== |
|||
<syntaxhighlight lang="is-basic">100 PROGRAM "Prime.bas" |
|||
110 FOR X=0 TO 100 |
|||
120 IF PRIME(X) THEN PRINT X; |
|||
130 NEXT |
|||
140 DEF PRIME(N) |
|||
150 IF N=2 THEN |
|||
160 LET PRIME=-1 |
|||
170 ELSE IF N<=1 OR MOD(N,2)=0 THEN |
|||
180 LET PRIME=0 |
|||
190 ELSE |
|||
200 LET PRIME=-1 |
|||
210 FOR I=3 TO CEIL(SQR(N)) STEP 2 |
|||
220 IF MOD(N,I)=0 THEN LET PRIME=0:EXIT FOR |
|||
230 NEXT |
|||
240 END IF |
|||
250 END DEF</syntaxhighlight> |
|||
==={{header|Liberty BASIC}}=== |
|||
{{works with|Just BASIC}} |
|||
<syntaxhighlight lang="lb">print "Rosetta Code - Primality by trial division" |
|||
print |
|||
[start] |
|||
input "Enter an integer: "; x |
|||
if x=0 then print "Program complete.": end |
|||
if isPrime(x) then print x; " is prime" else print x; " is not prime" |
|||
goto [start] |
|||
function isPrime(p) |
|||
p=int(abs(p)) |
|||
if p=2 then isPrime=1: exit function 'prime |
|||
if p=0 or p=1 or (p mod 2)=0 then exit function 'not prime |
|||
for i=3 to sqr(p) step 2 |
|||
if (p mod i)=0 then exit function 'not prime |
|||
next i |
|||
isPrime=1 |
|||
end function</syntaxhighlight> |
|||
{{out}} |
|||
<pre>Rosetta Code - Primality by trial division |
|||
Enter an integer: 1 |
|||
1 is not prime |
|||
Enter an integer: 2 |
|||
2 is prime |
|||
Enter an integer: |
|||
Program complete.</pre> |
|||
==={{header|PureBasic}}=== |
|||
<syntaxhighlight lang="purebasic">Procedure.i IsPrime(n) |
|||
Protected k |
|||
If n = 2 |
|||
ProcedureReturn #True |
|||
EndIf |
|||
If n <= 1 Or n % 2 = 0 |
|||
ProcedureReturn #False |
|||
EndIf |
|||
For k = 3 To Int(Sqr(n)) Step 2 |
|||
If n % k = 0 |
|||
ProcedureReturn #False |
|||
EndIf |
|||
Next |
|||
ProcedureReturn #True |
|||
EndProcedure</syntaxhighlight> |
|||
==={{header|QuickBASIC}}=== |
|||
{{works with|QBasic|1.1}} |
|||
{{works with|QuickBasic|4.5}} |
{{works with|QuickBasic|4.5}} |
||
{{works with|QB64}} |
|||
Returns 1 for prime, 0 for non-prime |
|||
<syntaxhighlight lang="qbasic">' Primality by trial division |
|||
' Test and display primes 1 .. 50 |
|||
Going with the classic 1 for "true" and 0 for "false": |
|||
DECLARE FUNCTION prime% (n!) |
|||
FOR n = 1 TO 50 |
|||
IF prime(n) = 1 THEN PRINT n; |
|||
NEXT n |
|||
FOR a = 3 TO INT(SQR(n)) STEP 2 |
|||
IF n MOD a = 0 THEN prime = 0 |
|||
NEXT a |
|||
prime = 1 |
|||
END FUNCTION |
|||
FUNCTION prime% (n!) |
|||
STATIC i AS INTEGER |
|||
IF n = 2 THEN |
|||
prime = 1 |
|||
ELSEIF n <= 1 OR n MOD 2 = 0 THEN |
|||
prime = 0 |
|||
ELSE |
|||
prime = 1 |
|||
FOR i = 3 TO INT(SQR(n)) STEP 2 |
|||
IF n MOD i = 0 THEN |
|||
prime = 0 |
|||
EXIT FUNCTION |
|||
END IF |
|||
NEXT i |
|||
END IF |
|||
END FUNCTION</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 |
|||
</pre> |
|||
==={{header|Run BASIC}}=== |
|||
{{works with|Just BASIC}} |
|||
<syntaxhighlight lang="runbasic">' Test and display primes 1 .. 50 |
|||
for i = 1 TO 50 |
|||
if prime(i) <> 0 then print i;" "; |
|||
next i |
|||
FUNCTION prime(n) |
|||
if n < 2 then prime = 0 : goto [exit] |
|||
if n = 2 then prime = 1 : goto [exit] |
|||
if n mod 2 = 0 then prime = 0 : goto [exit] |
|||
prime = 1 |
|||
for i = 3 to int(n^.5) step 2 |
|||
if n mod i = 0 then prime = 0 : goto [exit] |
|||
next i |
|||
[exit] |
|||
END FUNCTION</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2 3 5 7 11 13 17 19 23 25 29 31 37 41 43 47 |
|||
</pre> |
|||
==={{header|S-BASIC}}=== |
|||
<syntaxhighlight lang="s-basic"> |
|||
$lines |
|||
$constant FALSE = 0 |
|||
$constant TRUE = 0FFFFH |
|||
rem - return p mod q |
|||
function mod(p, q = integer) = integer |
|||
end = p - q * (p / q) |
|||
rem - return true (-1) if n is prime, otherwise false (0) |
|||
function isprime(n = integer) = integer |
|||
var i, limit, result = integer |
|||
if n = 2 then |
|||
result = TRUE |
|||
else if (n < 2) or (mod(n,2) = 0) then |
|||
result = FALSE |
|||
else |
|||
begin |
|||
limit = int(sqr(n)) |
|||
i = 3 |
|||
while (i <= limit) and (mod(n, i) <> 0) do |
|||
i = i + 2 |
|||
result = not (i <= limit) |
|||
end |
|||
end = result |
|||
rem - test by looking for primes in range 1 to 50 |
|||
var i = integer |
|||
for i = 1 to 50 |
|||
if isprime(i) then print using "#####";i; |
|||
next i |
|||
end |
|||
</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 |
|||
</pre> |
|||
==={{header|TI-83 BASIC}}=== |
|||
Prompt A |
|||
If A=2:Then |
|||
Disp "PRIME" |
|||
Stop |
|||
End |
|||
If (fPart(A/2)=0 and A>0) or A<2:Then |
|||
Disp "NOT PRIME" |
|||
Stop |
|||
End |
|||
1→P |
|||
For(B,3,int(√(A))) |
|||
If FPart(A/B)=0:Then |
|||
0→P |
|||
√(A)→B |
|||
End |
|||
B+1→B |
|||
End |
|||
If P=1:Then |
|||
Disp "PRIME" |
|||
Else |
|||
Disp "NOT PRIME" |
|||
End |
|||
==={{header|Tiny BASIC}}=== |
|||
{{works with|TinyBasic}} |
|||
<syntaxhighlight lang="basic">10 REM Primality by trial division |
|||
20 PRINT "Enter a number " |
|||
30 INPUT P |
|||
40 GOSUB 1000 |
|||
50 IF Z = 1 THEN PRINT "It is prime." |
|||
60 IF Z = 0 THEN PRINT "It is not prime." |
|||
70 END |
|||
990 REM Primality of the number P by trial division |
|||
1000 IF P < 2 THEN RETURN |
|||
1010 LET Z = 1 |
|||
1020 IF P < 4 THEN RETURN |
|||
1030 LET I = 2 |
|||
1040 IF (P / I) * I = P THEN LET Z = 0 |
|||
1050 IF Z = 0 THEN RETURN |
|||
1060 LET I = I + 1 |
|||
1070 IF I * I <= P THEN GOTO 1040 |
|||
1080 RETURN</syntaxhighlight> |
|||
==={{header|True BASIC}}=== |
|||
{{trans|QuickBASIC}} |
|||
<syntaxhighlight lang="qbasic">FUNCTION isPrime (n) |
|||
IF n = 2 THEN |
|||
LET isPrime = 1 |
|||
ELSEIF n <= 1 OR REMAINDER(n, 2) = 0 THEN |
|||
LET isPrime = 0 |
|||
ELSE |
|||
LET isPrime = 1 |
|||
FOR i = 3 TO INT(SQR(n)) STEP 2 |
|||
IF REMAINDER(n, i) = 0 THEN |
|||
LET isPrime = 0 |
|||
EXIT FUNCTION |
|||
END IF |
|||
NEXT i |
|||
END IF |
|||
END FUNCTION |
|||
FOR n = 1 TO 50 |
|||
IF isPrime(n) = 1 THEN PRINT n; |
|||
NEXT n |
|||
END</syntaxhighlight> |
|||
==={{header|uBasic/4tH}}=== |
|||
<syntaxhighlight lang="text">10 LET n=0: LET p=0 |
|||
20 INPUT "Enter number: ";n |
|||
30 LET p=0 : IF n>1 THEN GOSUB 1000 |
|||
40 IF p=0 THEN PRINT n;" is not prime!" |
|||
50 IF p#0 THEN PRINT n;" is prime!" |
|||
60 GOTO 10 |
|||
1000 REM *************** |
|||
1001 REM * PRIME CHECK * |
|||
1002 REM *************** |
|||
1010 LET p=0 |
|||
1020 IF (n%2)=0 THEN RETURN |
|||
1030 LET p=1 : PUSH n,0 : GOSUB 9030 |
|||
1040 FOR i=3 TO POP() STEP 2 |
|||
1050 IF (n%i)=0 THEN LET p=0: PUSH n,0 : GOSUB 9030 : LET i=POP() |
|||
1060 NEXT i |
|||
1070 RETURN |
|||
9030 Push ((10^(Pop()*2))*Pop()) : @(255)=Tos() |
|||
9040 Push (@(255) + (Tos()/@(255)))/2 |
|||
If Abs(@(255)-Tos())<2 Then @(255)=Pop() : If Pop() Then Push @(255) : Return |
|||
@(255) = Pop() : Goto 9040 |
|||
REM ** This is an integer SQR subroutine. Output is scaled by 10^(TOS()).</syntaxhighlight> |
|||
==={{header|VBA}}=== |
|||
<syntaxhighlight lang="vb">Option Explicit |
|||
Sub FirstTwentyPrimes() |
|||
Dim count As Integer, i As Long, t(19) As String |
|||
Do |
|||
i = i + 1 |
|||
If IsPrime(i) Then |
|||
t(count) = i |
|||
count = count + 1 |
|||
End If |
|||
Loop While count <= UBound(t) |
|||
Debug.Print Join(t, ", ") |
|||
End Sub |
|||
Function IsPrime(Nb As Long) As Boolean |
|||
If Nb = 2 Then |
|||
IsPrime = True |
|||
ElseIf Nb < 2 Or Nb Mod 2 = 0 Then |
|||
Exit Function |
|||
Else |
|||
Dim i As Long |
|||
For i = 3 To Sqr(Nb) Step 2 |
|||
If Nb Mod i = 0 Then Exit Function |
|||
Next |
|||
IsPrime = True |
|||
End If |
|||
End Function</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71 |
|||
</pre> |
|||
==={{header|VBScript}}=== |
|||
{{trans|QuickBASIC}} |
|||
<syntaxhighlight lang="vb">Function IsPrime(n) |
|||
If n = 2 Then |
|||
IsPrime = True |
|||
ElseIf n <= 1 Or n Mod 2 = 0 Then |
|||
IsPrime = False |
|||
Else |
|||
IsPrime = True |
|||
For i = 3 To Int(Sqr(n)) Step 2 |
|||
If n Mod i = 0 Then |
|||
IsPrime = False |
|||
Exit For |
|||
End If |
|||
Next |
|||
End If |
|||
End Function |
|||
For n = 1 To 50 |
|||
If IsPrime(n) Then |
|||
WScript.StdOut.Write n & " " |
|||
End If |
|||
Next</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 |
|||
</pre> |
|||
==={{header|Yabasic}}=== |
|||
{{trans|FreeBASIC}} |
|||
<syntaxhighlight lang="yabasic">for i = 1 to 99 |
|||
if isPrime(i) print str$(i), " "; |
|||
next i |
|||
print |
|||
end |
|||
sub isPrime(v) |
|||
if v < 2 return False |
|||
if mod(v, 2) = 0 return v = 2 |
|||
if mod(v, 3) = 0 return v = 3 |
|||
d = 5 |
|||
while d * d <= v |
|||
if mod(v, d) = 0 then return False else d = d + 2 : fi |
|||
wend |
|||
return True |
|||
end sub</syntaxhighlight> |
|||
==={{header|ZX Spectrum Basic}}=== |
|||
<syntaxhighlight lang="zxbasic">10 LET n=0: LET p=0 |
|||
20 INPUT "Enter number: ";n |
|||
30 IF n>1 THEN GO SUB 1000 |
|||
40 IF p=0 THEN PRINT n;" is not prime!" |
|||
50 IF p<>0 THEN PRINT n;" is prime!" |
|||
60 GO TO 10 |
|||
1000 REM *************** |
|||
1001 REM * PRIME CHECK * |
|||
1002 REM *************** |
|||
1010 LET p=0 |
|||
1020 IF n/2=INT (n/2) THEN RETURN |
|||
1030 LET p=1 |
|||
1040 FOR i=3 TO SQR (n) STEP 2 |
|||
1050 IF n/i=INT (n/i) THEN LET p=0: LET i= SQR (n) |
|||
1060 NEXT i |
|||
1070 RETURN |
|||
</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
15 is not prime! |
|||
17 is prime! |
|||
119 is not prime! |
|||
137 is prime!</pre> |
|||
=={{header|bc}}== |
|||
<syntaxhighlight lang="bc">/* Return 1 if n is prime, 0 otherwise */ |
|||
define p(n) { |
|||
auto i |
|||
if (n < 2) return(0) |
|||
if (n == 2) return(1) |
|||
if (n % 2 == 0) return(0) |
|||
for (i = 3; i * i <= n; i += 2) { |
|||
if (n % i == 0) return(0) |
|||
} |
|||
return(1) |
|||
}</syntaxhighlight> |
|||
=={{header|BCPL}}== |
|||
<syntaxhighlight lang="bcpl">get "libhdr" |
|||
let sqrt(s) = |
|||
s <= 1 -> 1, |
|||
valof |
|||
$( let x0 = s >> 1 |
|||
let x1 = (x0 + s/x0) >> 1 |
|||
while x1 < x0 |
|||
$( x0 := x1 |
|||
x1 := (x0 + s/x0) >> 1 |
|||
$) |
|||
resultis x0 |
|||
$) |
|||
let isprime(n) = |
|||
n < 2 -> false, |
|||
(n & 1) = 0 -> n = 2, |
|||
valof |
|||
$( for i = 3 to sqrt(n) by 2 |
|||
if n rem i = 0 resultis false |
|||
resultis true |
|||
$) |
|||
let start() be |
|||
$( for i=1 to 100 |
|||
if isprime(i) then writef("%N ",i) |
|||
wrch('*N') |
|||
$)</syntaxhighlight> |
|||
{{out}} |
|||
<pre>2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97</pre> |
|||
=={{header|Befunge}}== |
|||
Reads the value to test from stdin and outputs ''Yes'' if prime and ''No'' if not. |
|||
To avoid dealing with Befunge's limited data cells, the implementation is entirely stack-based. However, this requires compressing multiple values into a single stack cell, which imposes an upper limit of 1,046,529 (1023<sup>2</sup>), thus a maximum testable prime of 1,046,527. |
|||
<syntaxhighlight lang="befunge">&>:48*:** \1`!#^_2v |
|||
v_v#`\*:%*:*84\/*:*84::+< |
|||
v >::48*:*/\48*:*%%!#v_1^ |
|||
>0"seY" >:#,_@#: "No">#0<</syntaxhighlight> |
|||
{{out}} (multiple runs) |
|||
<pre>0 |
|||
No |
|||
17 |
|||
Yes |
|||
49 |
|||
No |
|||
97 |
|||
Yes |
|||
1042441 |
|||
No |
|||
1046527 |
|||
Yes</pre> |
|||
=={{header|Bracmat}}== |
|||
<syntaxhighlight lang="bracmat"> ( prime |
|||
= incs n I inc |
|||
. 4 2 4 2 4 6 2 6:?incs |
|||
& 2:?n |
|||
& 1 2 2 !incs:?I |
|||
& whl |
|||
' ( !n*!n:~>!arg |
|||
& div$(!arg.!n)*!n:~!arg |
|||
& (!I:%?inc ?I|!incs:%?inc ?I) |
|||
& !n+!inc:?n |
|||
) |
|||
& !n*!n:>!arg |
|||
) |
|||
& 100000000000:?p |
|||
& whl |
|||
' ( !p+1:<100000000100:?p |
|||
& ( prime$!p |
|||
& out$!p |
|||
| |
|||
) |
|||
) |
|||
& ;</syntaxhighlight> |
|||
{{out}} |
|||
<pre>100000000003 |
|||
100000000019 |
|||
100000000057 |
|||
100000000063 |
|||
100000000069 |
|||
100000000073 |
|||
100000000091</pre> |
|||
=={{header|Brainf***}}== |
|||
<syntaxhighlight lang="bf">>->,[.>,]>-<++++++[-<+[---------<+]->+[->+]-<]>+<-<+[-<+]>>+[-<[->++++++++++<]>> |
|||
+]++++[->++++++++<]>.<+++++++[->++++++++++<]>+++.++++++++++.<+++++++++[->------- |
|||
--<]>--.[-]<<<->[->+>+<<]>>-[+<[[->>+>>+<<<<]>>[-<<+>>]<]>>[->-[>+>>]>[+[-<+>]>> |
|||
>]<<<<<]>[-]>[>+>]<<[-]+[-<+]->>>--]<[->+>+<<]>>>>>>>[-<<<<<->>>>>]<<<<<--[>++++ |
|||
++++++[->+++++++++++<]>.+.+++++.>++++[->++++++++<]>.>]++++++++++[->+++++++++++<] |
|||
>++.++.---------.++++.--------.>++++++++++.</syntaxhighlight> |
|||
Explanation: |
|||
<syntaxhighlight lang="bf">> |
|||
->,[.>,]>-<++++++[-<+[---------<+]->+[->+]-<]>+<-<+[-<+]>>+[-<[->++++++++++<]>>+]< takes input |
|||
>++++[->++++++++<]>.<+++++++[->++++++++++<]>+++.++++++++++.<+++++++++[->---------<]>--.[-]<< " is " |
|||
<-> |
|||
[->+>+<<]>>-[+<[[->>+>>+<<<<]>>[-<<+>>]<]>>[->-[>+>>]>[+[-<+>]>>>]<<<<<]>[-]>[>+>]<<[-]+[-<+]->>>--] finds # of divisors from 1 to n |
|||
<[->+>+<<]>>>>>>>[-<<<<<->>>>>]<<<<<-- |
|||
[>++++++++++[->+++++++++++<]>.+.+++++.>++++[->++++++++<]>.>] "not " |
|||
++++++++++[->+++++++++++<]>++.++.---------.++++.--------.>++++++++++. "prime" new line</syntaxhighlight> |
|||
Will format as "# is/is not prime", naturally limited by cell size. |
|||
=={{header|Burlesque}}== |
|||
<syntaxhighlight lang="burlesque">fcL[2==</syntaxhighlight> |
|||
Implicit trial division is done by the ''fc'' function. It checks if the number has exactly two divisors. |
|||
Version not using the ''fc'' function: |
|||
<syntaxhighlight lang="burlesque">blsq ) 11^^2\/?dr@.%{0==}ayn! |
|||
1 |
|||
blsq ) 12^^2\/?dr@.%{0==}ayn! |
|||
0 |
|||
blsq ) 13^^2\/?dr@.%{0==}ayn! |
|||
1</syntaxhighlight> |
|||
Explanation. Given ''n'' generates a block containing ''2..n-1''. Calculates a block of modolus and check if it contains ''0''. If it contains ''0'' |
|||
it is not a prime. |
|||
=={{header|C}}== |
=={{header|C}}== |
||
<syntaxhighlight lang="c">int is_prime(unsigned int n) |
|||
<lang c>#include <math.h> |
|||
#define FALSE 0 |
|||
#define TRUE 1 |
|||
int isPrime( unsigned int n ) |
|||
{ |
{ |
||
unsigned int p; |
|||
if (!(n & 1) || n < 2 ) return n == 2; |
|||
return TRUE; |
|||
/* comparing p*p <= n can overflow */ |
|||
if ( n <= 1 || ( n & 1 ) == 0 ) |
|||
for (p = 3; p <= n/p; p += 2) |
|||
if (!(n % p)) return 0; |
|||
for ( i = 3 ; i <= sqrt( n ) ; i += 2 ) |
|||
return 1; |
|||
if ( n % i == 0 ) |
|||
}</syntaxhighlight> |
|||
return FALSE; |
|||
return TRUE; |
|||
=={{header|C sharp|C#}}== |
|||
}</lang> |
|||
<syntaxhighlight lang="csharp">static bool isPrime(int n) |
|||
{ |
|||
if (n <= 1) return false; |
|||
for (int i = 2; i * i <= n; i++) |
|||
if (n % i == 0) return false; |
|||
return true; |
|||
}</syntaxhighlight> |
|||
=={{header|C++}}== |
=={{header|C++}}== |
||
< |
<syntaxhighlight lang="cpp">#include <cmath> |
||
bool is_prime(unsigned int n) |
bool is_prime(unsigned int n) |
||
Line 110: | Line 1,777: | ||
return false; |
return false; |
||
return true; |
return true; |
||
}</ |
}</syntaxhighlight> |
||
=={{header|Chapel}}== |
|||
{{trans|C++}} |
|||
<syntaxhighlight lang="chapel">proc is_prime(n) |
|||
{ |
|||
if n == 2 then |
|||
return true; |
|||
if n <= 1 || n % 2 == 0 then |
|||
return false; |
|||
for i in 3..floor(sqrt(n)):int by 2 do |
|||
if n % i == 0 then |
|||
return false; |
|||
return true; |
|||
}</syntaxhighlight> |
|||
=={{header|Clojure}}== |
=={{header|Clojure}}== |
||
The function used in both versions: |
|||
<syntaxhighlight lang="clojure">(defn divides? [k n] (zero? (mod k n)))</syntaxhighlight> |
|||
Testing divisors are in range from '''3''' to '''√{{overline| n }} ''' with step '''2''': |
|||
The symbol # is a shortcut for creating lambda functions; the arguments in such a function are %1, %2, %3... (or simply % if there is only one argument). Thus, #(< (* % %) n) is equivalent to (fn [x] (< (* x x) n)) or more mathematically f(x) = x * x < n. |
|||
<syntaxhighlight lang="clojure">(defn prime? [x] |
|||
( |
(or (= 2 x) |
||
(and (< 1 x) |
|||
(odd? x) |
|||
(not-any? (partial divides? x) |
|||
(range 3 (inc (Math/sqrt x)) 2))))) |
|||
</syntaxhighlight> |
|||
Testing only prime divisors: |
|||
<syntaxhighlight lang="clojure">(declare prime?) |
|||
(def primes (filter prime? (range))) |
|||
(defn prime? [x] |
|||
(and (integer? x) |
|||
(< 1 x) |
|||
(not-any? (partial divides? x) |
|||
(take-while (partial >= (Math/sqrt x)) primes)))) |
|||
</syntaxhighlight> |
|||
=={{header|CLU}}== |
|||
<syntaxhighlight lang="clu">isqrt = proc (s: int) returns (int) |
|||
x0: int := s/2 |
|||
if x0=0 then return(s) end |
|||
x1: int := (x0 + s/x0)/2 |
|||
while x1 < x0 do |
|||
x0 := x1 |
|||
x1 := (x0 + s/x0)/2 |
|||
end |
|||
return(x0) |
|||
end isqrt |
|||
prime = proc (n: int) returns (bool) |
|||
if n<=2 then return(n=2) end |
|||
if n//2=0 then return(false) end |
|||
for d: int in int$from_to_by(3,isqrt(n),2) do |
|||
if n//d=0 then return(false) end |
|||
end |
|||
return(true) |
|||
end prime |
|||
start_up = proc () |
|||
po: stream := stream$primary_input() |
|||
for i: int in int$from_to(1,100) do |
|||
if prime(i) then |
|||
stream$puts(po, int$unparse(i) || " ") |
|||
end |
|||
end |
|||
end start_up</syntaxhighlight> |
|||
{{out}} |
|||
<pre>2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97</pre> |
|||
=={{header|CMake}}== |
|||
<syntaxhighlight lang="cmake"># Prime predicate: does n be a prime number? Sets var to true or false. |
|||
function(primep var n) |
|||
if(n GREATER 2) |
|||
math(EXPR odd "${n} % 2") |
|||
if(odd) |
|||
# n > 2 and n is odd. |
|||
set(factor 3) |
|||
# Loop for odd factors from 3, while factor <= n / factor. |
|||
math(EXPR quot "${n} / ${factor}") |
|||
while(NOT factor GREATER quot) |
|||
math(EXPR rp "${n} % ${factor}") # Trial division |
|||
if(NOT rp) |
|||
# factor divides n, so n is not prime. |
|||
set(${var} false PARENT_SCOPE) |
|||
return() |
|||
endif() |
|||
math(EXPR factor "${factor} + 2") # Next odd factor |
|||
math(EXPR quot "${n} / ${factor}") |
|||
endwhile(NOT factor GREATER quot) |
|||
# Loop found no factor, so n is prime. |
|||
set(${var} true PARENT_SCOPE) |
|||
else() |
|||
# n > 2 and n is even, so n is not prime. |
|||
set(${var} false PARENT_SCOPE) |
|||
endif(odd) |
|||
elseif(n EQUAL 2) |
|||
set(${var} true PARENT_SCOPE) # 2 is prime. |
|||
else() |
|||
set(${var} false PARENT_SCOPE) # n < 2 is not prime. |
|||
endif() |
|||
endfunction(primep)</syntaxhighlight> |
|||
<syntaxhighlight lang="cmake"># Quick example. |
|||
foreach(i -5 1 2 3 37 39) |
|||
primep(b ${i}) |
|||
if(b) |
|||
message(STATUS "${i} is prime.") |
|||
else() |
|||
message(STATUS "${i} is _not_ prime.") |
|||
endif(b) |
|||
endforeach(i)</syntaxhighlight> |
|||
=={{header|COBOL}}== |
|||
<syntaxhighlight lang="cobol"> Identification Division. |
|||
Program-Id. Primality-By-Subdiv. |
|||
Data Division. |
|||
Working-Storage Section. |
|||
78 True-Val Value 0. |
|||
78 False-Val Value 1. |
|||
Local-Storage Section. |
|||
01 lim Pic 9(10). |
|||
01 i Pic 9(10). |
|||
Linkage Section. |
|||
01 num Pic 9(10). |
|||
01 result Pic 9. |
|||
Procedure Division Using num result. |
|||
Main. |
|||
If num <= 1 |
|||
Move False-Val To result |
|||
Goback |
|||
Else If num = 2 |
|||
Move True-Val To result |
|||
Goback |
|||
End-If |
|||
Compute lim = Function Sqrt(num) + 1 |
|||
Perform Varying i From 3 By 1 Until lim < i |
|||
If Function Mod(num, i) = 0 |
|||
Move False-Val To result |
|||
Goback |
|||
End-If |
|||
End-Perform |
|||
Move True-Val To Result |
|||
Goback |
|||
.</syntaxhighlight> |
|||
=={{header|CoffeeScript}}== |
|||
<syntaxhighlight lang="coffeescript">is_prime = (n) -> |
|||
# simple prime detection using trial division, works |
|||
# for all integers |
|||
return false if n <= 1 # by definition |
|||
p = 2 |
|||
while p * p <= n |
|||
return false if n % p == 0 |
|||
p += 1 |
|||
true |
|||
for i in [-1..100] |
|||
(defn prime? [n] |
|||
console.log i if is_prime i</syntaxhighlight> |
|||
(if (< n 2) |
|||
false |
|||
(empty? (filter #(divides? % n) (take-while #(<= (* % %) n) (range 2 n)))))) |
|||
=={{header|Common Lisp}}== |
=={{header|Common Lisp}}== |
||
<syntaxhighlight lang="lisp">(defun primep (n) |
|||
<lang Lisp> |
|||
(defun primep (a) |
|||
(cond ((= a 2) T) |
|||
((or (<= a 1) (= (mod a 2) 0)) nil) |
|||
((loop for i from 3 to (sqrt a) by 2 do |
|||
(if (= (mod a i) 0) |
|||
(return nil))) nil) |
|||
(T T))) |
|||
</lang> |
|||
<lang Lisp> |
|||
(defun primep (n) |
|||
"Is N prime?" |
"Is N prime?" |
||
(and (> n 1) |
(and (> n 1) |
||
(or (= n 2) (oddp n)) |
(or (= n 2) (oddp n)) |
||
(loop for i from 3 to (isqrt n) by 2 |
(loop for i from 3 to (isqrt n) by 2 |
||
never (zerop (rem n i))))) |
never (zerop (rem n i)))))</syntaxhighlight> |
||
===Alternate solution=== |
|||
</lang> |
|||
I use [https://franz.com/downloads/clp/survey Allegro CL 10.1] |
|||
<syntaxhighlight lang="lisp">;; Project : Primality by trial division |
|||
(defun prime(n) |
|||
(setq flag 0) |
|||
(loop for i from 2 to (- n 1) do |
|||
(if (= (mod n i) 0) |
|||
(setq flag 1))) |
|||
(if (= flag 0) |
|||
(format t "~d is a prime number" n) |
|||
(format t "~d is not a prime number" n))) |
|||
(prime 7) |
|||
(prime 8)</syntaxhighlight> |
|||
Output: |
|||
7 is a prime number |
|||
8 is not a prime number |
|||
=={{header|Cowgol}}== |
|||
<syntaxhighlight lang="cowgol">include "cowgol.coh"; |
|||
sub prime(n: uint32): (isprime: uint8) is |
|||
isprime := 1; |
|||
if n < 2 then |
|||
isprime := 0; |
|||
return; |
|||
end if; |
|||
if n & 1 == 0 then |
|||
if n != 2 then |
|||
isprime := 0; |
|||
end if; |
|||
return; |
|||
end if; |
|||
var factor: uint32 := 3; |
|||
while factor * factor <= n loop |
|||
if n % factor == 0 then |
|||
isprime := 0; |
|||
return; |
|||
end if; |
|||
factor := factor + 2; |
|||
end loop; |
|||
end sub; |
|||
var i: uint32 := 0; |
|||
while i <= 100 loop |
|||
if prime(i) != 0 then |
|||
print_i32(i); |
|||
print_nl(); |
|||
end if; |
|||
i := i + 1; |
|||
end loop;</syntaxhighlight> |
|||
{{out}} |
|||
<pre>2 |
|||
3 |
|||
5 |
|||
7 |
|||
11 |
|||
13 |
|||
17 |
|||
19 |
|||
23 |
|||
29 |
|||
31 |
|||
37 |
|||
41 |
|||
43 |
|||
47 |
|||
53 |
|||
59 |
|||
61 |
|||
67 |
|||
71 |
|||
73 |
|||
79 |
|||
83 |
|||
89 |
|||
97</pre> |
|||
=={{header|Crystal}}== |
|||
Mathematicaly basis of Prime Generators |
|||
https://www.academia.edu/19786419/PRIMES-UTILS_HANDBOOK |
|||
https://www.academia.edu/42734410/Improved_Primality_Testing_and_Factorization_in_Ruby_revised |
|||
<syntaxhighlight lang="ruby">require "big" |
|||
require "benchmark" |
|||
# the simplest PG primality test using the P3 prime generator |
|||
# reduces the number space for primes to 2/6 (33.33%) of all integers |
|||
def primep3?(n) # P3 Prime Generator primality test |
|||
# P3 = 6*k + {5, 7} # P3 primes candidates (pc) sequence |
|||
n = n.to_big_i |
|||
return n | 1 == 3 if n < 5 # n: 0,1,4|false, 2,3|true |
|||
return false if n.gcd(6) != 1 # 1/3 (2/6) of integers are P3 pc |
|||
p = typeof(n).new(5) # first P3 sequence value |
|||
until p > isqrt(n) |
|||
return false if n % p == 0 || n % (p + 2) == 0 # if n is composite |
|||
p += 6 # first prime candidate for next kth residues group |
|||
end |
|||
true |
|||
end |
|||
# PG primality test using the P5 prime generator |
|||
# reduces the number space for primes to 8/30 (26.67%) of all integers |
|||
def primep5?(n) # P5 Prime Generator primality test |
|||
# P5 = 30*k + {7,11,13,17,19,23,29,31} # P5 primes candidates sequence |
|||
n = n.to_big_i |
|||
return [2, 3, 5].includes?(n) if n < 7 # for small and negative values |
|||
return false if n.gcd(30) != 1 # 4/15 (8/30) of integers are P5 pc |
|||
p = typeof(n).new(7) # first P5 sequence value |
|||
until p > isqrt(n) |
|||
return false if # if n is composite |
|||
n % (p) == 0 || n % (p+4) == 0 || n % (p+6) == 0 || n % (p+10) == 0 || |
|||
n % (p+12) == 0 || n % (p+16) == 0 || n % (p+22) == 0 || n % (p+24) == 0 |
|||
p += 30 # first prime candidate for next kth residues group |
|||
end |
|||
true |
|||
end |
|||
# PG primality test using the P7 prime generator |
|||
# reduces the number space for primes to 48/210 (22.86%) of all integers |
|||
def primep7?(n) |
|||
# P7 = 210*k + {11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83, |
|||
# 89,97,101,103,107,109,113,121,127,131,137,139,143,149,151,157,163, |
|||
# 167,169,173,179,181,187,191,193,197,199,209,211} |
|||
n = n.to_big_i |
|||
return [2, 3, 5, 7].includes?(n) if n < 11 |
|||
return false if n.gcd(210) != 1 # 8/35 (48/210) of integers are P7 pc |
|||
p = typeof(n).new(11) # first P7 sequence value |
|||
until p > isqrt(n) |
|||
return false if |
|||
n % (p) == 0 || n % (p+2) == 0 || n % (p+6) == 0 || n % (p+8) == 0 || |
|||
n % (p+12) == 0 || n % (p+18) == 0 || n % (p+20) == 0 || n % (p+26) == 0 || |
|||
n % (p+30) == 0 || n % (p+32) == 0 || n % (p+36) == 0 || n % (p+42) == 0 || |
|||
n % (p+48) == 0 || n % (p+50) == 0 || n % (p+56) == 0 || n % (p+60) == 0 || |
|||
n % (p+62) == 0 || n % (p+68) == 0 || n % (p+72) == 0 || n % (p+78) == 0 || |
|||
n % (p+86) == 0 || n % (p+90) == 0 || n % (p+92) == 0 || n % (p+96) == 0 || |
|||
n % (p+98) == 0 || n % (p+102) == 0 || n % (p+110) == 0 || n % (p+116) == 0 || |
|||
n % (p+120) == 0 || n % (p+126) == 0 || n % (p+128) == 0 || n % (p+132) == 0 || |
|||
n % (p+138) == 0 || n % (p+140) == 0 || n % (p+146) == 0 || n % (p+152) == 0 || |
|||
n % (p+156) == 0 || n % (p+158) == 0 || n % (p+162) == 0 || n % (p+168) == 0 || |
|||
n % (p+170) == 0 || n % (p+176) == 0 || n % (p+180) == 0 || n % (p+182) == 0 || |
|||
n % (p+186) == 0 || n % (p+188) == 0 || n % (p+198) == 0 || n % (p+200) == 0 |
|||
p += 210 # first prime candidate for next kth residues group |
|||
end |
|||
true |
|||
end |
|||
# Newton's method for integer squareroot |
|||
def isqrt(n) |
|||
raise ArgumentError.new "Input must be non-negative integer" if n < 0 |
|||
return n if n < 2 |
|||
bits = n.bit_length |
|||
one = typeof(n).new(1) # value 1 of type self |
|||
x = one << ((bits - 1) >> 1) | n >> ((bits >> 1) + 1) |
|||
while (t = n // x) < x; x = (x + t) >> 1 end |
|||
x # output is same integer class as input |
|||
end |
|||
# Benchmarks to test for various size primes |
|||
p = 541 |
|||
Benchmark.ips do |b| |
|||
print "\np = #{p}" |
|||
b.report("primep3?") { primep3?(p) } |
|||
b.report("primep5?") { primep5?(p) } |
|||
b.report("primep7?") { primep7?(p) } |
|||
puts |
|||
end |
|||
p = 1000003 |
|||
Benchmark.ips do |b| |
|||
print "\np = #{p}" |
|||
b.report("primep3?") { primep3?(p) } |
|||
b.report("primep5?") { primep5?(p) } |
|||
b.report("primep7?") { primep7?(p) } |
|||
puts |
|||
end |
|||
p = 2147483647i32 # largest I32 prime |
|||
Benchmark.ips do |b| |
|||
print "\np = #{p}" |
|||
b.report("primep3?") { primep3?(p) } |
|||
b.report("primep5?") { primep5?(p) } |
|||
b.report("primep7?") { primep7?(p) } |
|||
puts |
|||
end |
|||
p = 4294967291u32 # largest U32 prime |
|||
Benchmark.ips do |b| |
|||
print "\np = #{p}" |
|||
b.report("primep3?") { primep3?(p) } |
|||
b.report("primep5?") { primep5?(p) } |
|||
b.report("primep7?") { primep7?(p) } |
|||
puts |
|||
end |
|||
p = 4294967311 # first prime > 2**32 |
|||
Benchmark.ips do |b| |
|||
print "\np = #{p}" |
|||
b.report("primep3?") { primep3?(p) } |
|||
b.report("primep5?") { primep5?(p) } |
|||
b.report("primep7?") { primep7?(p) } |
|||
puts |
|||
end</syntaxhighlight> |
|||
{{out}} |
|||
<pre>p = 541 |
|||
primep3? 290.17k ( 3.45µs) (± 2.76%) 1.35kB/op 1.64× slower |
|||
primep5? 476.47k ( 2.10µs) (± 1.75%) 802B/op fastest |
|||
primep7? 128.44k ( 7.79µs) (± 2.82%) 2.66kB/op 3.71× slower |
|||
p = 1000003 |
|||
primep3? 11.24k ( 88.97µs) (± 2.34%) 33.9kB/op 2.48× slower |
|||
primep5? 21.91k ( 45.64µs) (± 2.88%) 16.6kB/op 1.27× slower |
|||
primep7? 27.83k ( 35.94µs) (± 2.68%) 11.9kB/op fastest |
|||
p = 2147483647 |
|||
primep3? 105.11 ( 9.51ms) (± 3.25%) 3.89MB/op 5.56× slower |
|||
primep5? 317.49 ( 3.15ms) (± 2.40%) 1.2MB/op 1.84× slower |
|||
primep7? 584.92 ( 1.71ms) (± 3.09%) 591kB/op fastest |
|||
p = 4294967291 |
|||
primep3? 168.56 ( 5.93ms) (± 2.39%) 2.17MB/op 2.69× slower |
|||
primep5? 349.24 ( 2.86ms) (± 2.86%) 1.03MB/op 1.30× slower |
|||
primep7? 454.08 ( 2.20ms) (± 2.62%) 739kB/op fastest |
|||
p = 4294967311 |
|||
primep3? 84.61 ( 11.82ms) (± 2.35%) 4.68MB/op 5.02× slower |
|||
primep5? 248.62 ( 4.02ms) (± 2.21%) 1.54MB/op 1.71× slower |
|||
primep7? 424.61 ( 2.36ms) (± 2.73%) 813kB/op fastest |
|||
</pre> |
|||
=={{header|D}}== |
=={{header|D}}== |
||
===Simple Version=== |
|||
<lang d>import std.math: sqrt; |
|||
<syntaxhighlight lang="d">import std.stdio, std.algorithm, std.range, std.math; |
|||
bool isPrime(int n) { |
|||
if (n == 2) |
|||
bool isPrime1(T)(in T n) pure nothrow { |
|||
if (n == 2) |
|||
return true; |
return true; |
||
if (n <= 1 || (n & 1) == 0) |
if (n <= 1 || (n & 1) == 0) |
||
return false; |
return false; |
||
for( |
for(T i = 3; i <= real(n).sqrt; i += 2) |
||
if (n % i == 0) |
if (n % i == 0) |
||
return false; |
return false; |
||
return true; |
return true; |
||
} |
|||
}</lang> |
|||
void main() { |
|||
iota(2, 40).filter!isPrime1.writeln; |
|||
}</syntaxhighlight> |
|||
{{out}} |
|||
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37] |
|||
===Version with excluded multiplies of 2 and 3=== |
===Version with excluded multiplies of 2 and 3=== |
||
Same output. |
|||
<lang d>/** |
|||
<syntaxhighlight lang="d">bool isPrime2(It)(in It n) pure nothrow { |
|||
* to compile: |
|||
// Adapted from: http://www.devx.com/vb2themax/Tip/19051 |
|||
* $ dmd -run prime_trial.d |
|||
// Test 1, 2, 3 and multiples of 2 and 3: |
|||
* to optimize: |
|||
if (n == 2 || n == 3) |
|||
* $ dmd -O -inline -release prime_trial.d |
|||
return true; |
|||
*/ |
|||
else if (n < 2 || n % 2 == 0 || n % 3 == 0) |
|||
module prime_trial; |
|||
return false; |
|||
// We can now avoid to consider multiples of 2 and 3. This |
|||
import std.conv : to; |
|||
// can be done really simply by starting at 5 and |
|||
import std.stdio : writefln; |
|||
// incrementing by 2 and 4 alternatively, that is: |
|||
// 5, 7, 11, 13, 17, 19, 23, 25, 29, 31, 35, 37, ... |
|||
// We don't need to go higher than the square root of the n. |
|||
for (It div = 5, inc = 2; div ^^ 2 <= n; div += inc, inc = 6 - inc) |
|||
if (n % div == 0) |
|||
return false; |
|||
/// Adapted from: http://www.devx.com/vb2themax/Tip/19051 |
|||
bool |
|||
isprime(Integer)(in Integer number) |
|||
{ |
|||
/* manually test 1, 2, 3 and multiples of 2 and 3 */ |
|||
if (number == 2 || number == 3) |
|||
return true; |
return true; |
||
} |
|||
else if (number < 2 || number % 2 == 0 || number % 3 == 0) |
|||
return false; |
|||
/* we can now avoid to consider multiples |
|||
* of 2 and 3. This can be done really simply |
|||
* by starting at 5 and incrementing by 2 and 4 |
|||
* alternatively, that is: |
|||
* 5, 7, 11, 13, 17, 19, 23, 25, 29, 31, 35, 37, ... |
|||
* we don't need to go higher than the square root of the number */ |
|||
for (Integer divisor = 5, increment = 2; divisor*divisor <= number; |
|||
divisor += increment, increment = 6 - increment) |
|||
if (number % divisor == 0) |
|||
return false; |
|||
void main() { |
|||
return true; // if we get here, the number is prime |
|||
import std.stdio, std.algorithm, std.range; |
|||
iota(2, 40).filter!isPrime2.writeln; |
|||
}</syntaxhighlight> |
|||
===Two Way Test=== |
|||
Odd divisors is generated both from increasing and decreasing sequence, may improve performance for numbers that have large minimum factor. |
|||
Same output. |
|||
<syntaxhighlight lang="d">import std.stdio, std.algorithm, std.range, std.math; |
|||
bool isPrime3(T)(in T n) pure nothrow { |
|||
if (n % 2 == 0 || n <= 1) |
|||
return n == 2; |
|||
T head = 3, tail = (cast(T)real(n).sqrt / 2) * 2 + 1; |
|||
for ( ; head <= tail ; head +=2, tail -= 2) |
|||
if ((n % head) == 0 || (n % tail) == 0) |
|||
return false; |
|||
return true; |
|||
} |
} |
||
void main() { |
|||
/// print all prime numbers less then a given limit |
|||
iota(2, 40).filter!isPrime3.writeln; |
|||
void main(char[][] args) |
|||
}</syntaxhighlight> |
|||
{ |
|||
const limit = (args.length == 2) ? to!(uint)(args[1]) : 100; |
|||
for (uint i = 0; i < limit; ++i) |
|||
if (isprime(i)) |
|||
writefln(i); |
|||
}</lang> |
|||
=={{header| |
=={{header|Dart}}== |
||
<syntaxhighlight lang="dart">import 'dart:math'; |
|||
bool isPrime(int n) { |
|||
if (n <= 1) return false; |
|||
if (n == 2) return true; |
|||
for (int i = 2; i <= sqrt(n); ++i) if (n % i == 0) return false; |
|||
return true; |
|||
} |
|||
void main() { |
|||
for (int i = 1; i <= 99; ++i) if (isPrime(i)) print('$i '); |
|||
}</syntaxhighlight> |
|||
=={{header|Delphi}}== |
|||
=== First === |
|||
<syntaxhighlight lang="delphi">function IsPrime(aNumber: Integer): Boolean; |
|||
var |
|||
I: Integer; |
|||
begin |
|||
Result:= True; |
|||
if(aNumber = 2) then Exit; |
|||
Result:= not ((aNumber mod 2 = 0) or |
|||
(aNumber <= 1)); |
|||
if not Result then Exit; |
|||
for I:=3 to Trunc(Sqrt(aNumber)) do |
|||
if(aNumber mod I = 0) then |
|||
begin |
|||
Result:= False; |
|||
Break; |
|||
end; |
|||
end;</syntaxhighlight> |
|||
=== Second === |
|||
<syntaxhighlight lang="delphi">function IsPrime(const x: integer): Boolean; |
|||
var |
|||
i: integer; |
|||
begin |
|||
i := 2; |
|||
repeat |
|||
if X mod i = 0 then |
|||
begin |
|||
Result := False; |
|||
Exit; |
|||
end; |
|||
Inc(i); |
|||
until i > Sqrt(x); |
|||
Result := True; |
|||
end;</syntaxhighlight> |
|||
=={{header|Draco}}== |
|||
<syntaxhighlight lang="draco">proc prime(word n) bool: |
|||
word factor; |
|||
bool composite; |
|||
if n<=4 then |
|||
n=2 or n=3 |
|||
elif n&1 = 0 then |
|||
false |
|||
else |
|||
factor := 3; |
|||
composite := false; |
|||
while not composite and factor*factor <= n do |
|||
composite := n % factor = 0; |
|||
factor := factor + 2 |
|||
od; |
|||
not composite |
|||
fi |
|||
corp |
|||
proc main() void: |
|||
word i; |
|||
for i from 0 upto 100 do |
|||
if prime(i) then |
|||
writeln(i) |
|||
fi |
|||
od |
|||
corp</syntaxhighlight> |
|||
{{out}} |
|||
<pre>2 |
|||
3 |
|||
5 |
|||
7 |
|||
11 |
|||
13 |
|||
17 |
|||
19 |
|||
23 |
|||
29 |
|||
31 |
|||
37 |
|||
41 |
|||
43 |
|||
47 |
|||
53 |
|||
59 |
|||
61 |
|||
67 |
|||
71 |
|||
73 |
|||
79 |
|||
83 |
|||
89 |
|||
97</pre> |
|||
=={{header|E}}== |
|||
{{trans|D}} |
{{trans|D}} |
||
<syntaxhighlight lang="e">def isPrime(n :int) { |
|||
<lang e> |
|||
def isPrime(n :int) { |
|||
if (n == 2) { |
if (n == 2) { |
||
return true |
return true |
||
Line 219: | Line 2,386: | ||
return true |
return true |
||
} |
} |
||
}</ |
}</syntaxhighlight> |
||
=={{header|EasyLang}}== |
|||
<syntaxhighlight lang="easylang"> |
|||
func isprim n . |
|||
if n < 2 |
|||
return 0 |
|||
. |
|||
if n mod 2 = 0 and n > 2 |
|||
return 0 |
|||
. |
|||
i = 3 |
|||
sq = sqrt n |
|||
while i <= sq |
|||
if n mod i = 0 |
|||
return 0 |
|||
. |
|||
i += 2 |
|||
. |
|||
return 1 |
|||
. |
|||
print isprim 1995937 |
|||
</syntaxhighlight> |
|||
=={{header|EchoLisp}}== |
|||
<syntaxhighlight lang="scheme">(lib 'sequences) |
|||
;; Try divisors iff n = 2k + 1 |
|||
(define (is-prime? p) |
|||
(cond |
|||
[(< p 2) #f] |
|||
[(zero? (modulo p 2)) (= p 2)] |
|||
[else |
|||
(for/and ((d [3 5 .. (1+ (sqrt p))] )) (!zero? (modulo p d)))])) |
|||
(filter is-prime? (range 1 100)) |
|||
→ (2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97) |
|||
;; Improve performance , try divisors iff n = 6k+1 or n = 6k+5 |
|||
(define (is-prime? p) |
|||
(cond |
|||
[(< p 2) #f] |
|||
[(zero? (modulo p 2)) (= p 2)] |
|||
[(zero? (modulo p 3)) (= p 3)] |
|||
[(zero? (modulo p 5)) (= p 5)] |
|||
[else ;; step 6 : try divisors 6n+1 or 6n+5 |
|||
(for ((d [7 13 .. (1+ (sqrt p))] )) |
|||
#:break (zero? (modulo p d)) => #f |
|||
#:break (zero? (modulo p (+ d 4))) => #f |
|||
#t )])) |
|||
(filter is-prime? (range 1 100)) |
|||
→ (2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97)</syntaxhighlight> |
|||
=={{header|Eiffel}}== |
|||
<syntaxhighlight lang="eiffel">class |
|||
APPLICATION |
|||
create |
|||
make |
|||
feature |
|||
make |
|||
-- Tests the feature is_prime. |
|||
do |
|||
io.put_boolean (is_prime (1)) |
|||
io.new_line |
|||
io.put_boolean (is_prime (2)) |
|||
io.new_line |
|||
io.put_boolean (is_prime (3)) |
|||
io.new_line |
|||
io.put_boolean (is_prime (4)) |
|||
io.new_line |
|||
io.put_boolean (is_prime (97)) |
|||
io.new_line |
|||
io.put_boolean (is_prime (15589)) |
|||
io.new_line |
|||
end |
|||
is_prime (n: INTEGER): BOOLEAN |
|||
-- Is 'n' a prime number? |
|||
require |
|||
positiv_input: n > 0 |
|||
local |
|||
i: INTEGER |
|||
max: REAL_64 |
|||
math: DOUBLE_MATH |
|||
do |
|||
create math |
|||
if n = 2 then |
|||
Result := True |
|||
elseif n <= 1 or n \\ 2 = 0 then |
|||
Result := False |
|||
else |
|||
Result := True |
|||
max := math.sqrt (n) |
|||
from |
|||
i := 3 |
|||
until |
|||
i > max |
|||
loop |
|||
if n \\ i = 0 then |
|||
Result := False |
|||
end |
|||
i := i + 2 |
|||
end |
|||
end |
|||
end |
|||
end</syntaxhighlight> |
|||
<pre>False |
|||
True |
|||
True |
|||
False |
|||
True |
|||
False</pre> |
|||
=={{header|Elixir}}== |
|||
{{trans|Erlang}} |
|||
<syntaxhighlight lang="elixir">defmodule RC do |
|||
def is_prime(2), do: true |
|||
def is_prime(n) when n<2 or rem(n,2)==0, do: false |
|||
def is_prime(n), do: is_prime(n,3) |
|||
def is_prime(n,k) when n<k*k, do: true |
|||
def is_prime(n,k) when rem(n,k)==0, do: false |
|||
def is_prime(n,k), do: is_prime(n,k+2) |
|||
end |
|||
IO.inspect for n <- 1..50, RC.is_prime(n), do: n</syntaxhighlight> |
|||
{{out}} |
|||
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47] |
|||
=={{header|Emacs Lisp}}== |
|||
{{libheader|cl-lib}} |
|||
<syntaxhighlight lang="lisp">(defun prime (a) |
|||
(not (or (< a 2) |
|||
(cl-loop for x from 2 to (sqrt a) |
|||
when (zerop (% a x)) |
|||
return t))))</syntaxhighlight> |
|||
More concise, a little bit faster: |
|||
<syntaxhighlight lang="lisp">(defun prime2 (a) |
|||
(and (> a 1) |
|||
(cl-loop for x from 2 to (sqrt a) |
|||
never (zerop (% a x)))))</syntaxhighlight> |
|||
A little bit faster: |
|||
<syntaxhighlight lang="lisp">(defun prime3 (a) |
|||
(and (> a 1) |
|||
(or (= a 2) (cl-oddp a)) |
|||
(cl-loop for x from 3 to (sqrt a) by 2 |
|||
never (zerop (% a x)))))</syntaxhighlight> |
|||
More than 2 times faster, than the previous, doesn't use <tt>loop</tt> macro: |
|||
<syntaxhighlight lang="lisp">(defun prime4 (a) |
|||
(not (or (< a 2) |
|||
(cl-some (lambda (x) (zerop (% a x))) (number-sequence 2 (sqrt a))))))</syntaxhighlight> |
|||
Almost 2 times faster, than the previous: |
|||
<syntaxhighlight lang="lisp">(defun prime5 (a) |
|||
(not (or (< a 2) |
|||
(and (/= a 2) (cl-evenp a)) |
|||
(cl-some (lambda (x) (zerop (% a x))) (number-sequence 3 (sqrt a) 2)))))</syntaxhighlight> |
|||
=={{header|Erlang}}== |
|||
<syntaxhighlight lang="erlang">is_prime(N) when N == 2 -> true; |
|||
is_prime(N) when N < 2 orelse N rem 2 == 0 -> false; |
|||
is_prime(N) -> is_prime(N,3). |
|||
is_prime(N,K) when K*K > N -> true; |
|||
is_prime(N,K) when N rem K == 0 -> false; |
|||
is_prime(N,K) -> is_prime(N,K+2).</syntaxhighlight> |
|||
=={{header|ERRE}}== |
|||
<syntaxhighlight lang="erre">PROGRAM PRIME_TRIAL |
|||
PROCEDURE ISPRIME(N%->OK%) |
|||
LOCAL T% |
|||
IF N%<=1 THEN OK%=FALSE EXIT PROCEDURE END IF |
|||
IF N%<=3 THEN OK%=TRUE EXIT PROCEDURE END IF |
|||
IF (N% AND 1)=0 THEN OK%=FALSE EXIT PROCEDURE END IF |
|||
FOR T%=3 TO SQR(N%) STEP 2 DO |
|||
IF N% MOD T%=0 THEN OK%=FALSE EXIT PROCEDURE END IF |
|||
END FOR |
|||
OK%=TRUE |
|||
END PROCEDURE |
|||
BEGIN |
|||
FOR I%=1 TO 100 DO |
|||
ISPRIME(I%->OK%) |
|||
IF OK% THEN PRINT(i%;"is prime") END IF |
|||
END FOR |
|||
END PROGRAM</syntaxhighlight> |
|||
{{out}} |
|||
2 is prime |
|||
3 is prime |
|||
5 is prime |
|||
7 is prime |
|||
11 is prime |
|||
13 is prime |
|||
17 is prime |
|||
19 is prime |
|||
23 is prime |
|||
29 is prime |
|||
31 is prime |
|||
37 is prime |
|||
41 is prime |
|||
43 is prime |
|||
47 is prime |
|||
53 is prime |
|||
59 is prime |
|||
61 is prime |
|||
67 is prime |
|||
71 is prime |
|||
73 is prime |
|||
79 is prime |
|||
83 is prime |
|||
89 is prime |
|||
97 is prime |
|||
=={{header|Euphoria}}== |
|||
<syntaxhighlight lang="euphoria">function is_prime(integer n) |
|||
if n<=2 or remainder(n,2)=0 then |
|||
return 0 |
|||
else |
|||
for i=3 to sqrt(n) by 2 do |
|||
if remainder(n,i)=0 then |
|||
return 0 |
|||
end if |
|||
end for |
|||
return 1 |
|||
end if |
|||
end function</syntaxhighlight> |
|||
=={{header|F Sharp|F#}}== |
|||
<syntaxhighlight lang="fsharp">open NUnit.Framework |
|||
open FsUnit |
|||
let inline isPrime n = not ({uint64 2..uint64 (sqrt (double n))} |> Seq.exists (fun (i:uint64) -> uint64 n % i = uint64 0)) |
|||
[<Test>] |
|||
let ``Validate that 2 is prime`` () = |
|||
isPrime 2 |> should equal true |
|||
[<Test>] |
|||
let ``Validate that 4 is not prime`` () = |
|||
isPrime 4 |> should equal false |
|||
[<Test>] |
|||
let ``Validate that 3 is prime`` () = |
|||
isPrime 3 |> should equal true |
|||
[<Test>] |
|||
let ``Validate that 9 is not prime`` () = |
|||
isPrime 9 |> should equal false |
|||
[<Test>] |
|||
let ``Validate that 5 is prime`` () = |
|||
isPrime 5 |> should equal true |
|||
[<Test>] |
|||
let ``Validate that 277 is prime`` () = |
|||
isPrime 277 |> should equal true</syntaxhighlight> |
|||
{{out}} |
|||
> isPrime 1111111111111111111UL;; |
|||
val it : bool = true |
|||
and if you want to test really big numbers, use System.Numerics.BigInteger, but it's slower: |
|||
<syntaxhighlight lang="fsharp"> |
|||
let isPrimeI x = |
|||
if x < 2I then false else |
|||
if x = 2I then true else |
|||
if x % 2I = 0I then false else |
|||
let rec test n = |
|||
if n * n > x then true else |
|||
if x % n = 0I then false else test (n + 2I) in test 3I</syntaxhighlight> |
|||
If you have a lot of prime numbers to test, caching a sequence of primes can speed things up considerably, so you only have to do the divisions against prime numbers. |
|||
<syntaxhighlight lang="fsharp">let rec primes = Seq.cache(Seq.append (seq[ 2; 3; 5 ]) (Seq.unfold (fun state -> Some(state, state + 2)) 7 |> Seq.filter (fun x -> IsPrime x))) |
|||
and IsPrime number = |
|||
let rec IsPrimeCore number current limit = |
|||
let cprime = primes |> Seq.nth current |
|||
if cprime >= limit then |
|||
true |
|||
else if number % cprime = 0 then |
|||
false |
|||
else |
|||
IsPrimeCore number (current + 1) (number/cprime) |
|||
if number = 2 then |
|||
true |
|||
else if number < 2 then |
|||
false |
|||
else |
|||
IsPrimeCore number 0 number</syntaxhighlight> |
|||
=={{header|Factor}}== |
=={{header|Factor}}== |
||
< |
<syntaxhighlight lang="factor">USING: combinators kernel math math.functions math.ranges sequences ; |
||
: prime? ( n -- ? ) |
: prime? ( n -- ? ) |
||
Line 229: | Line 2,693: | ||
{ [ dup even? ] [ 2 = ] } |
{ [ dup even? ] [ 2 = ] } |
||
[ 3 over sqrt 2 <range> [ mod 0 > ] with all? ] |
[ 3 over sqrt 2 <range> [ mod 0 > ] with all? ] |
||
} cond ;</ |
} cond ;</syntaxhighlight> |
||
=={{header|FALSE}}== |
=={{header|FALSE}}== |
||
<syntaxhighlight lang="false">[0\$2=$[@~@@]?~[$$2>\1&&[\~\ |
|||
3[\$@$@1+\$*>][\$@$@$@$@\/*=[%\~\$]?2+]#% |
3[\$@$@1+\$*>][\$@$@$@$@\/*=[%\~\$]?2+]#% |
||
]?]?%]p:</syntaxhighlight> |
|||
=={{header|Forth}}== |
|||
=={{header|Forth}}== |
|||
: prime? ( n -- ? ) |
|||
<syntaxhighlight lang="forth">: prime? ( n -- f ) |
|||
dup 2 < if drop false |
dup 2 < if drop false |
||
else dup 2 = if drop true |
else dup 2 = if drop true |
||
else dup 1 and 0= if drop false |
else dup 1 and 0= if drop false |
||
else 3 |
else 3 |
||
begin 2dup dup * >= |
begin 2dup dup * >= |
||
while 2dup mod 0= |
while 2dup mod 0= |
||
Line 248: | Line 2,712: | ||
then 2 + |
then 2 + |
||
repeat 2drop true |
repeat 2drop true |
||
then then then ; |
then then then ;</syntaxhighlight> |
||
=={{header|Fortran}}== |
=={{header|Fortran}}== |
||
{{works with|Fortran|90 and later}} |
{{works with|Fortran|90 and later}} |
||
< |
<syntaxhighlight lang="fortran"> FUNCTION isPrime(number) |
||
LOGICAL :: isPrime |
LOGICAL :: isPrime |
||
INTEGER, INTENT(IN) :: number |
INTEGER, INTENT(IN) :: number |
||
Line 270: | Line 2,734: | ||
END DO |
END DO |
||
END IF |
END IF |
||
END FUNCTION</ |
END FUNCTION</syntaxhighlight> |
||
=={{header|Frink}}== |
|||
It is unnecessary to write this function because Frink has an efficient <CODE>isPrime[x]</CODE> function to test primality of arbitrarily-large integers. Here is a version that works for arbitrarily-large integers. Beware some of these solutions that calculate up to <CODE>sqrt[x]</CODE> but because of floating-point error the square root is slightly smaller than the true square root! |
|||
<syntaxhighlight lang="frink">isPrimeByTrialDivision[x] := |
|||
{ |
|||
for p = primes[] |
|||
{ |
|||
if p*p > x |
|||
return true |
|||
if x mod p == 0 |
|||
return false |
|||
} |
|||
return true |
|||
}</syntaxhighlight> |
|||
=={{header|FunL}}== |
|||
<syntaxhighlight lang="funl">import math.sqrt |
|||
def |
|||
isPrime( 2 ) = true |
|||
isPrime( n ) |
|||
| n < 3 or 2|n = false |
|||
| otherwise = (3..int(sqrt(n)) by 2).forall( (/|n) ) |
|||
(10^10..10^10+50).filter( isPrime ).foreach( println )</syntaxhighlight> |
|||
{{out}} |
|||
10000000019 |
|||
10000000033 |
|||
=={{header|GAP}}== |
|||
<syntaxhighlight lang="gap">IsPrimeTrial := function(n) |
|||
local k, m; |
|||
if n < 5 then |
|||
return (n = 2) or (n = 3); |
|||
fi; |
|||
if RemInt(n, 2) = 0 then |
|||
return false; |
|||
fi; |
|||
m := RootInt(n); |
|||
k := 3; |
|||
while k <= m do |
|||
if RemInt(n, k) = 0 then |
|||
return false; |
|||
fi; |
|||
k := k + 2; |
|||
od; |
|||
return true; |
|||
end; |
|||
Filtered([1 .. 100], IsPrimeTrial); |
|||
# [ 2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97 ]</syntaxhighlight> |
|||
=={{header|Go}}== |
|||
<syntaxhighlight lang="go">func IsPrime(n int) bool { |
|||
if n < 0 { n = -n } |
|||
switch { |
|||
case n == 2: |
|||
return true |
|||
case n < 2 || n % 2 == 0: |
|||
return false |
|||
default: |
|||
for i = 3; i*i <= n; i += 2 { |
|||
if n % i == 0 { return false } |
|||
} |
|||
} |
|||
return true |
|||
}</syntaxhighlight> |
|||
Or, using recursion: |
|||
<syntaxhighlight lang="go">func IsPrime(n int) bool { |
|||
if n < 0 { n = -n } |
|||
if n <= 2 { |
|||
return n == 2 |
|||
} |
|||
return n % 2 != 0 && isPrime_r(n, 3) |
|||
} |
|||
func isPrime_r(n, i int) bool { |
|||
if i*i <= n { |
|||
return n % i != 0 && isPrime_r(n, i+2) |
|||
} |
|||
return true |
|||
}</syntaxhighlight> |
|||
=={{header|Groovy}}== |
=={{header|Groovy}}== |
||
< |
<syntaxhighlight lang="groovy">def isPrime = { |
||
it == 2 || |
it == 2 || |
||
it > 1 && |
it > 1 && |
||
Line 279: | Line 2,831: | ||
} |
} |
||
(0..20).grep(isPrime)</ |
(0..20).grep(isPrime)</syntaxhighlight> |
||
{{out}} |
|||
[2, 3, 5, 7, 11, 13, 17, 19] |
|||
Sample output: |
|||
<pre>[2, 3, 5, 7, 11, 13, 17, 19]</pre> |
|||
=={{header|Haskell}}== |
=={{header|Haskell}}== |
||
(used [[Emirp_primes#List-based|here]] and [[Sequence_of_primes_by_Trial_Division#Haskell|here]]). The basic divisibility test by odd numbers: |
|||
<syntaxhighlight lang="haskell">isPrime n = n==2 || n>2 && all ((> 0).rem n) (2:[3,5..floor.sqrt.fromIntegral $ n+1])</syntaxhighlight> |
|||
Testing by prime numbers only is faster. Primes list is saved for reuse. Precalculation of primes pays off if testing more than just a few numbers, and/or primes are generated efficiently enough: |
|||
Without square roots: |
|||
<syntaxhighlight lang="haskell">noDivsBy factors n = foldr (\f r-> f*f>n || ((rem n f /= 0) && r)) True factors |
|||
-- primeNums = filter (noDivsBy [2..]) [2..] |
|||
divides k n = n `mod` k == 0 |
|||
-- = 2 : filter (noDivsBy [3,5..]) [3,5..] |
|||
primeNums = 2 : 3 : filter (noDivsBy $ tail primeNums) [5,7..] |
|||
isPrime :: Integer -> Bool |
|||
isPrime n | n < 2 = False |
|||
isPrime n = n > 1 && noDivsBy primeNums n</syntaxhighlight> |
|||
| otherwise = not $ any (`divides` n) $ takeWhile (\k -> k*k <= n) (2:[3,5..]) |
|||
Any increasing ''unbounded'' sequence of numbers that includes all primes (above the first few, perhaps) could be used with the testing function <code>noDivsBy</code> to define the <code>isPrime</code> function -- but using just primes is better, produced e.g. by [[Sieve of Eratosthenes#Haskell|Sieve of Eratosthenes]], or <code>noDivsBy</code> itself can be used to define <code>primeNums</code> as shown above, because it stops when the square root is reached (so there's no infinite recursion, no "vicious circle"). |
|||
A less efficient, more basic variant: |
|||
<syntaxhighlight lang="haskell">isPrime n = n > 1 && []==[i | i <- [2..n-1], rem n i == 0]</syntaxhighlight> |
|||
The following is an attempt at improving it, resulting in absolutely worst performing prime testing code I've ever seen, ever. A curious oddity. |
|||
<syntaxhighlight lang="haskell">isPrime n = n > 1 && []==[i | i <- [2..n-1], isPrime i && rem n i == 0]</syntaxhighlight> |
|||
=={{header|HicEst}}== |
|||
<syntaxhighlight lang="hicest"> DO n = 1, 1E6 |
|||
Euler = n^2 + n + 41 |
|||
IF( Prime(Euler) == 0 ) WRITE(Messagebox) Euler, ' is NOT prime for n =', n |
|||
ENDDO ! e.g. 1681 = 40^2 + 40 + 41 is NOT prime |
|||
END |
|||
FUNCTION Prime(number) |
|||
Prime = number == 2 |
|||
IF( (number > 2) * MOD(number,2) ) THEN |
|||
DO i = 3, number^0.5, 2 |
|||
IF(MOD(number,i) == 0) THEN |
|||
Prime = 0 |
|||
RETURN |
|||
ENDIF |
|||
ENDDO |
|||
Prime = 1 |
|||
ENDIF |
|||
END</syntaxhighlight> |
|||
=={{header|Icon}} and {{header|Unicon}}== |
|||
Procedure shown without a main program. |
|||
<syntaxhighlight lang="icon">procedure isprime(n) #: return n if prime (using trial division) or fail |
|||
if not n = integer(n) | n < 2 then fail # ensure n is an integer greater than 1 |
|||
every if 0 = (n % (2 to sqrt(n))) then fail |
|||
return n |
|||
end</syntaxhighlight> |
|||
=={{header|J}}== |
=={{header|J}}== |
||
{{eff note|J|1&p:}} |
{{eff note|J|1&p:}} |
||
< |
<syntaxhighlight lang="j">isprime=: 3 : 'if. 3>:y do. 1<y else. 0 *./@:< y|~2+i.<.%:y end.'</syntaxhighlight> |
||
=={{header|Java}}== |
=={{header|Java}}== |
||
< |
<syntaxhighlight lang="java">public static boolean prime(long a){ |
||
if(a == 2){ |
if(a == 2){ |
||
return true; |
return true; |
||
Line 305: | Line 2,894: | ||
return false; |
return false; |
||
} |
} |
||
long max = (long)Math.sqrt(a); |
|||
for(long n= 3; n <= max; n+= 2){ |
|||
if(a % n == 0){ return false; } |
if(a % n == 0){ return false; } |
||
} |
} |
||
return true; |
return true; |
||
}</ |
}</syntaxhighlight> |
||
===By Regular Expression=== |
===By Regular Expression=== |
||
< |
<syntaxhighlight lang="java">public static boolean prime(int n) { |
||
return !new String(new char[n]).matches(".?|(..+?)\\1+"); |
return !new String(new char[n]).matches(".?|(..+?)\\1+"); |
||
}</ |
}</syntaxhighlight> |
||
=={{header|JavaScript}}== |
|||
<syntaxhighlight lang="javascript">function isPrime(n) { |
|||
if (n == 2 || n == 3 || n == 5 || n == 7) { |
|||
return true; |
|||
} else if ((n < 2) || (n % 2 == 0)) { |
|||
return false; |
|||
} else { |
|||
for (var i = 3; i <= Math.sqrt(n); i += 2) { |
|||
if (n % i == 0) |
|||
return false; |
|||
} |
|||
return true; |
|||
} |
|||
}</syntaxhighlight> |
|||
=={{header|Joy}}== |
=={{header|Joy}}== |
||
<syntaxhighlight lang joy>DEFINE prime == |
|||
From http://www.latrobe.edu.au/philosophy/phimvt/joy/jp-imper.html |
|||
2 [[dup * >] nullary [rem 0 >] dip and] |
|||
<lang joy> |
|||
[succ] while dup * <.</syntaxhighlight> |
|||
DEFINE prime == |
|||
2 |
|||
=={{header|jq}}== |
|||
[ [dup * >] nullary [rem 0 >] dip and ] |
|||
<tt> def is_prime: |
|||
[ succ ] |
|||
if . == 2 then true |
|||
else 2 < . and . % 2 == 1 and |
|||
. as $in |
|||
</lang> |
|||
| (($in + 1) | sqrt) as $m |
|||
| (((($m - 1) / 2) | floor) + 1) as $max |
|||
| all( range(1; $max) ; $in % ((2 * .) + 1) > 0 ) |
|||
end;</tt> |
|||
Example -- the command line is followed by alternating lines of input and output: |
|||
<tt> $ jq -f is_prime.jq |
|||
-2 |
|||
false |
|||
1 |
|||
false |
|||
2 |
|||
true |
|||
100 |
|||
false</tt> |
|||
''Note: if your jq does not have <tt>all</tt>, the following will suffice:'' |
|||
def all(generator; condition): |
|||
reduce generator as $i (true; . and ($i|condition)); |
|||
=={{header|Julia}}== |
|||
Julia already has an <tt>isprime</tt> function, so this function has the verbose name <tt>isprime_trialdivision</tt> to avoid overriding the built-in function. Note this function relies on the fact that Julia skips <tt>for</tt>-loops having invalid ranges. Otherwise the function would have to include additional logic to check the odd numbers less than 9. |
|||
<syntaxhighlight lang="julia">function isprime_trialdivision{T<:Integer}(n::T) |
|||
1 < n || return false |
|||
n != 2 || return true |
|||
isodd(n) || return false |
|||
for i in 3:isqrt(n) |
|||
n%i != 0 || return false |
|||
end |
|||
return true |
|||
end |
|||
n = 100 |
|||
a = filter(isprime_trialdivision, [1:n]) |
|||
if all(a .== primes(n)) |
|||
println("The primes <= ", n, " are:\n ", a) |
|||
else |
|||
println("The function does not accurately calculate primes.") |
|||
end</syntaxhighlight> |
|||
{{out}} |
|||
The primes <= 100 are: |
|||
[2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97] |
|||
=={{header|K}}== |
|||
<syntaxhighlight lang="k"> isprime:{(x>1)&&/x!'2_!1+_sqrt x} |
|||
&isprime'!100 |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97</syntaxhighlight> |
|||
=={{header|Kotlin}}== |
|||
<syntaxhighlight lang="scala">// version 1.1.2 |
|||
fun isPrime(n: Int): Boolean { |
|||
if (n < 2) return false |
|||
if (n % 2 == 0) return n == 2 |
|||
val limit = Math.sqrt(n.toDouble()).toInt() |
|||
return (3..limit step 2).none { n % it == 0 } |
|||
} |
|||
fun main(args: Array<String>) { |
|||
// test by printing all primes below 100 say |
|||
(2..99).filter { isPrime(it) }.forEach { print("$it ") } |
|||
}</syntaxhighlight> |
|||
{{out}} |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 |
|||
=={{header|Lambdatalk}}== |
|||
<syntaxhighlight lang="scheme"> |
|||
1) the simplest |
|||
{def isprime1 |
|||
{def isprime1.loop |
|||
{lambda {:n :m :i} |
|||
{if {> :i :m} |
|||
then true |
|||
else {if {= {% :n :i} 0} |
|||
then false |
|||
else {isprime1.loop :n :m {+ :i 1}} } |
|||
}}} |
|||
{lambda {:n} |
|||
{isprime1.loop :n {sqrt :n} 2} |
|||
}} |
|||
-> isprime1 |
|||
2) slightly improved |
|||
{def isprime2 |
|||
{def isprime2.loop |
|||
{lambda {:n :m :i} |
|||
{if {> :i :m} |
|||
then true |
|||
else {if {= {% :n :i} 0} |
|||
then false |
|||
else {isprime2.loop :n :m {+ :i 2}} |
|||
}}}} |
|||
{lambda {:n} |
|||
{if {or {= :n 2} {= :n 3} {= :n 5} {= :n 7}} |
|||
then true |
|||
else {if {or {< : n 2} {= {% :n 2} 0}} |
|||
then false |
|||
else {isprime2.loop :n {sqrt :n} 3} |
|||
}}}} |
|||
-> isprime2 |
|||
3) testing |
|||
{isprime1 1299709} -> stackoverflow on my iPad Pro |
|||
{isprime2 1299709} -> true |
|||
{def primesTo |
|||
{lambda {:f :n} |
|||
{S.replace \s by space in |
|||
{S.map {{lambda {:f :i} {if {:f :i} then :i else}} :f} |
|||
{S.serie 2 :n}}} }} |
|||
-> primesTo |
|||
{primesTo isprime1 100} |
|||
-> 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 in 25ms |
|||
{primesTo isprime2 100} |
|||
-> 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 in 20ms |
|||
{primesTo isprime1 1000000} in about 30000ms |
|||
{primesTo isprime2 1000000} in about 15000ms |
|||
</syntaxhighlight> |
|||
=={{header|langur}}== |
|||
=== Functional === |
|||
{{trans|Raku}} |
|||
following the Raku example, which states, "Integer $i is prime if it is greater than one and is divisible by none of 2, 3, up to the square root of $i" (plus an adjustment for the prime number 2) |
|||
<syntaxhighlight lang="langur"> |
|||
val isPrime = fn(i) { |
|||
i == 2 or i > 2 and |
|||
not any(fn x:i div x, pseries(2 .. i ^/ 2)) |
|||
} |
|||
writeln filter(isPrime, series(100)) |
|||
</syntaxhighlight> |
|||
=== Recursive === |
|||
{{trans|Go}} |
|||
<syntaxhighlight lang="langur"> |
|||
val isPrime = fn(i) { |
|||
val n = abs(i) |
|||
if n <= 2: return n == 2 |
|||
val chkdiv = fn(n, i) { |
|||
if i * i <= n { |
|||
return n ndiv i and fn((n, i+2)) |
|||
} |
|||
return true |
|||
} |
|||
return n ndiv 2 and chkdiv(n, 3) |
|||
} |
|||
writeln filter(isPrime, series(100)) |
|||
</syntaxhighlight> |
|||
{{out}} |
|||
<pre>[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97]</pre> |
|||
=={{header|Lingo}}== |
|||
<syntaxhighlight lang="lingo">on isPrime (n) |
|||
if n<=1 or (n>2 and n mod 2=0) then return FALSE |
|||
sq = sqrt(n) |
|||
repeat with i = 3 to sq |
|||
if n mod i = 0 then return FALSE |
|||
end repeat |
|||
return TRUE |
|||
end</syntaxhighlight> |
|||
<syntaxhighlight lang="lingo">primes = [] |
|||
repeat with i = 0 to 100 |
|||
if isPrime(i) then primes.add(i) |
|||
end repeat |
|||
put primes</syntaxhighlight> |
|||
{{out}} |
|||
-- [2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97] |
|||
=={{header|Logo}}== |
=={{header|Logo}}== |
||
<syntaxhighlight lang="logo">to prime? :n |
|||
if :n < 2 [output "false] |
if :n < 2 [output "false] |
||
if :n = 2 [output "true] |
if :n = 2 [output "true] |
||
Line 334: | Line 3,117: | ||
for [i 3 [sqrt :n] 2] [if equal? 0 modulo :n :i [output "false]] |
for [i 3 [sqrt :n] 2] [if equal? 0 modulo :n :i [output "false]] |
||
output "true |
output "true |
||
end</syntaxhighlight> |
|||
end |
|||
=={{header|LSE64}}== |
=={{header|LSE64}}== |
||
<syntaxhighlight lang="lse64">over : 2 pick |
|||
2dup : over over |
2dup : over over |
||
even? : 1 & 0 = |
even? : 1 & 0 = |
||
Line 351: | Line 3,134: | ||
prime? : dup even? then drop false |
prime? : dup even? then drop false |
||
prime? : dup 2 = then drop true |
prime? : dup 2 = then drop true |
||
prime? : dup 2 < then drop false |
prime? : dup 2 < then drop false</syntaxhighlight> |
||
=={{header|Lua}}== |
|||
<syntaxhighlight lang="lua">function IsPrime( n ) |
|||
if n <= 1 or ( n ~= 2 and n % 2 == 0 ) then |
|||
return false |
|||
end |
|||
for i = 3, math.sqrt(n), 2 do |
|||
if n % i == 0 then |
|||
return false |
|||
end |
|||
end |
|||
return true |
|||
end</syntaxhighlight> |
|||
Type of number Decimal. |
|||
=={{header|M2000 Interpreter}}== |
|||
<syntaxhighlight lang="m2000 interpreter"> |
|||
Module Primality_by_trial_division { |
|||
Inventory Known1=2@, 3@ |
|||
IsPrime=lambda Known1 (x as decimal) -> { |
|||
=false |
|||
if exist(Known1, x) then =true : exit |
|||
if x<=5 OR frac(x) then {if x == 2 OR x == 3 OR x == 5 then Append Known1, x : =true |
|||
Break} |
|||
if frac(x/2) else exit |
|||
if frac(x/3) else exit |
|||
x1=sqrt(x):d = 5@ |
|||
do |
|||
if frac(x/d) else exit |
|||
d += 2: if d>x1 then Append Known1, x : =true : exit |
|||
if frac(x/d) else exit |
|||
d += 4: if d<= x1 else Append Known1, x : =true: exit |
|||
always |
|||
} |
|||
i=2 |
|||
While Len(Known1)<20 |
|||
dummy=Isprime(i) |
|||
i++ |
|||
End While |
|||
Print "first ";len(known1);" primes" |
|||
Print Known1 |
|||
Print "From 110 to 130" |
|||
count=0 |
|||
For i=110 to 130 |
|||
If isPrime(i) Then Print i, : count++ |
|||
Next |
|||
Print |
|||
Print "Found ";count;" primes" |
|||
} |
|||
Primality_by_trial_division |
|||
</syntaxhighlight> |
|||
=={{header|M4}}== |
=={{header|M4}}== |
||
<syntaxhighlight lang="m4">define(`testnext', |
|||
<lang M4> |
|||
define(`testnext', |
|||
`ifelse(eval($2*$2>$1),1, |
`ifelse(eval($2*$2>$1),1, |
||
1, |
1, |
||
Line 369: | Line 3,205: | ||
isprime(9) |
isprime(9) |
||
isprime(11) |
isprime(11)</syntaxhighlight> |
||
{{out}} |
|||
</lang> |
|||
0 |
|||
1 |
|||
=={{header|MAD}}== |
|||
Output: |
|||
<syntaxhighlight lang="MAD"> NORMAL MODE IS INTEGER |
|||
<pre> |
|||
INTERNAL FUNCTION(N) |
|||
ENTRY TO PRIME. |
|||
WHENEVER N.L.2, FUNCTION RETURN 0B |
|||
WHENEVER N.E.N/2*2, FUNCTION RETURN N.E.2 |
|||
THROUGH TRIAL, FOR FAC=3, 2, FAC*FAC.G.N |
|||
TRIAL WHENEVER N.E.N/FAC*FAC, FUNCTION RETURN 0B |
|||
FUNCTION RETURN 1B |
|||
END OF FUNCTION |
|||
PRINT COMMENT $ PRIMES UNDER 100 $ |
|||
THROUGH CAND, FOR C=0, 1, C.G.100 |
|||
CAND WHENEVER PRIME.(C), PRINT FORMAT PR,C |
|||
VECTOR VALUES PR = $ I3*$ |
|||
END OF PROGRAM</syntaxhighlight> |
|||
{{out}} |
|||
<pre>PRIMES UNDER 100 |
|||
2 |
|||
3 |
|||
5 |
|||
7 |
|||
11 |
|||
13 |
|||
17 |
|||
19 |
|||
23 |
|||
29 |
|||
31 |
|||
37 |
|||
41 |
|||
43 |
|||
47 |
|||
53 |
|||
59 |
|||
61 |
|||
67 |
|||
71 |
|||
73 |
|||
79 |
|||
83 |
|||
89 |
|||
97</pre> |
|||
=={{header|Maple}}== |
|||
This could be coded in myriad ways; here is one. |
|||
<syntaxhighlight lang="maple">TrialDivision := proc( n :: integer ) |
|||
if n <= 1 then |
|||
false |
|||
elif n = 2 then |
|||
true |
|||
elif type( n, 'even' ) then |
|||
false |
|||
else |
|||
for local i from 3 by 2 while i * i <= n do |
|||
if irem( n, i ) = 0 then |
|||
return false |
|||
end if |
|||
end do; |
|||
true |
|||
end if |
|||
end proc:</syntaxhighlight> |
|||
Using this to pick off the primes up to 30, we get: |
|||
<syntaxhighlight lang="maple">> select( TrialDivision, [seq]( 1 .. 30 ) ); |
|||
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29]</syntaxhighlight> |
|||
Here is a way to check that TrialDivision above agrees with Maple's built-in primality test (isprime). |
|||
<syntaxhighlight lang="maple">> N := 10000: evalb( select( TrialDivision, [seq]( 1 .. N ) ) = select( isprime, [seq]( 1 .. N ) ) ); |
|||
true</syntaxhighlight> |
|||
=={{header|Mathematica}}/{{header|Wolfram Language}}== |
|||
<syntaxhighlight lang="mathematica">IsPrime[n_Integer] := Block[{}, |
|||
If[n <= 1, Return[False]]; |
|||
If[n == 2, Return[True]]; If[Mod[n, 2] == 0, Return[False]]; |
|||
For[k = 3, k <= Sqrt[n], k += 2, If[Mod[n, k] == 0, Return[False]]]; |
|||
Return[True]]</syntaxhighlight> |
|||
=={{header|MATLAB}}== |
|||
<syntaxhighlight lang="matlab">function isPrime = primalityByTrialDivision(n) |
|||
if n == 2 |
|||
isPrime = true; |
|||
return |
|||
elseif (mod(n,2) == 0) || (n <= 1) |
|||
isPrime = false; |
|||
return |
|||
end |
|||
%First n mod (3 to sqrt(n)) is taken. This will be a vector where the |
|||
%first element is equal to n mod 3 and the last element is equal to n |
|||
%mod sqrt(n). Then the all function is applied to that vector. If all |
|||
%of the elements of this vector are non-zero (meaning n is prime) then |
|||
%all() returns true. Otherwise, n is composite, so it returns false. |
|||
%This return value is then assigned to the variable isPrime. |
|||
isPrime = all(mod(n, (3:round(sqrt(n))) )); |
|||
end</syntaxhighlight> |
|||
{{out|Sample output}} |
|||
<syntaxhighlight lang="matlab">>> arrayfun(@primalityByTrialDivision,(1:14)) |
|||
ans = |
|||
0 1 1 0 1 0 1 0 0 0 1 0 1 0</syntaxhighlight> |
|||
=={{header|Maxima}}== |
|||
<syntaxhighlight lang="maxima">isprme(n):= catch( |
|||
for k: 2 thru sqrt(n) do if mod(n, k)=0 then throw(false), |
|||
true); |
|||
map(isprme, [2, 3, 4, 65, 100, 181, 901]); |
|||
/* [true, true, false, false, false, true, false] */</syntaxhighlight> |
|||
=={{header|min}}== |
|||
{{works with|min|0.19.3}} |
|||
<syntaxhighlight lang="min">( |
|||
:n 3 :i n sqrt :m true :p |
|||
(i m <=) ( |
|||
(n i mod 0 ==) (m @i false @p) when |
|||
i 2 + @i |
|||
) while p |
|||
) :_prime? ; helper function |
|||
( |
|||
( |
|||
((2 <) (false)) |
|||
((dup even?) (2 ==)) |
|||
((true) (_prime?)) |
|||
) case |
|||
) :prime?</syntaxhighlight> |
|||
=={{header|Miranda}}== |
|||
<syntaxhighlight lang="miranda">main :: [sys_message] |
|||
main = [Stdout (show (filter prime [1..100])), |
|||
Stdout "\n"] |
|||
prime :: num->bool |
|||
prime n = n=2 \/ n=3, if n<=4 |
|||
= False, if n mod 2=0 |
|||
= #[d | d<-[3, 5..sqrt n]; n mod d=0]=0, otherwise</syntaxhighlight> |
|||
{{out}} |
|||
<pre>[2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97]</pre> |
|||
=={{header|МК-61/52}}== |
|||
<syntaxhighlight lang="text">П0 1 - x#0 34 2 - /-/ x<0 32 |
|||
ИП0 2 / {x} x#0 34 |
|||
3 П4 ИП0 ИП4 / {x} x#0 34 КИП4 КИП4 |
|||
ИП0 КвКор ИП4 - x<0 16 1 С/П 0 С/П</syntaxhighlight> |
|||
=={{header|Modula-2}}== |
|||
<syntaxhighlight lang="modula2">MODULE TrialDivision; |
|||
FROM InOut IMPORT WriteCard, WriteLn; |
|||
CONST |
|||
Max = 100; |
|||
VAR |
|||
i: CARDINAL; |
|||
PROCEDURE prime(n: CARDINAL): BOOLEAN; |
|||
VAR |
|||
factor: CARDINAL; |
|||
BEGIN |
|||
IF n <= 4 THEN |
|||
RETURN (n = 2) OR (n = 3) |
|||
ELSIF n MOD 2 = 0 THEN |
|||
RETURN FALSE |
|||
ELSE |
|||
factor := 3; |
|||
WHILE factor * factor <= n DO |
|||
IF n MOD factor = 0 THEN |
|||
RETURN FALSE |
|||
END; |
|||
INC(factor, 2) |
|||
END |
|||
END; |
|||
RETURN TRUE |
|||
END prime; |
|||
BEGIN |
|||
FOR i := 0 TO Max DO |
|||
IF prime(i) THEN |
|||
WriteCard(i,3); |
|||
WriteLn |
|||
END |
|||
END |
|||
END TrialDivision.</syntaxhighlight> |
|||
{{out}} |
|||
<pre> 2 |
|||
3 |
|||
5 |
|||
7 |
|||
11 |
|||
13 |
|||
17 |
|||
19 |
|||
23 |
|||
29 |
|||
31 |
|||
37 |
|||
41 |
|||
43 |
|||
47 |
|||
53 |
|||
59 |
|||
61 |
|||
67 |
|||
71 |
|||
73 |
|||
79 |
|||
83 |
|||
89 |
|||
97</pre> |
|||
=={{header|MUMPS}}== |
|||
<syntaxhighlight lang="mumps">ISPRIME(N) |
|||
QUIT:(N=2) 1 |
|||
NEW I,R |
|||
SET R=N#2 |
|||
IF R FOR I=3:2:(N**.5) SET R=N#I Q:'R |
|||
KILL I |
|||
QUIT R</syntaxhighlight> |
|||
Usage (0 is false, nonzero is true): |
|||
<pre>USER>W $$ISPRIME^ROSETTA(2) |
|||
1 |
|||
USER>W $$ISPRIME^ROSETTA(4) |
|||
0 |
0 |
||
USER>W $$ISPRIME^ROSETTA(7) |
|||
1 |
1 |
||
USER>W $$ISPRIME^ROSETTA(97) |
|||
</pre> |
|||
7 |
|||
USER>W $$ISPRIME^ROSETTA(99) |
|||
0</pre> |
|||
=={{header| |
=={{header|NetRexx}}== |
||
<syntaxhighlight lang="netrexx">/* NetRexx */ |
|||
fn isPrime n = |
|||
( |
|||
options replace format comments java crossref savelog symbols nobinary |
|||
if n == 2 then |
|||
( |
|||
parse arg nbr rangeBegin rangeEnd . |
|||
return true |
|||
) |
|||
if nbr = '' | nbr = '.' then do |
|||
if rangeBegin = '' | rangeBegin = '.' then rangeBegin = 1 |
|||
( |
|||
if rangeEnd = '' | rangeEnd = '.' then rangeEnd = 100 |
|||
return false |
|||
if rangeEnd > rangeBegin then direction = 1 |
|||
) |
|||
else direction = -1 |
|||
for i in 3 to (sqrt n) by 2 do |
|||
say 'List of prime numbers from' rangeBegin 'to' rangeEnd':' |
|||
( |
|||
primes = '' |
|||
if mod n i == 0 then return false |
|||
loop nn = rangeBegin to rangeEnd by direction |
|||
) |
|||
if isPrime(nn) then primes = primes nn |
|||
true |
|||
end nn |
|||
) |
|||
primes = primes.strip |
|||
say ' 'primes.changestr(' ', ',') |
|||
say ' Total number of primes:' primes.words |
|||
end |
|||
else do |
|||
if isPrime(nbr) then say nbr.right(20) 'is prime' |
|||
else say nbr.right(20) 'is not prime' |
|||
end |
|||
return |
|||
method isPrime(nbr = long) public static binary returns boolean |
|||
ip = boolean |
|||
select |
|||
when nbr < 2 then do |
|||
ip = isFalse |
|||
end |
|||
when '2 3 5 7'.wordpos(Rexx(nbr)) \= 0 then do |
|||
-- crude shortcut ripped from the Rexx example |
|||
ip = isTrue |
|||
end |
|||
when nbr // 2 == 0 | nbr // 3 == 0 then do |
|||
-- another shortcut permitted by the one above |
|||
ip = isFalse |
|||
end |
|||
otherwise do |
|||
nn = long |
|||
nnStartTerm = long 3 -- a reasonable start term - nn <= 2 is never prime |
|||
nnEndTerm = long Math.ceil(Math.sqrt(nbr)) -- a reasonable end term |
|||
ip = isTrue -- prime the pump (pun intended) |
|||
loop nn = nnStartTerm to nnEndTerm by 2 |
|||
-- Note: in Rexx and NetRexx "//" is the 'remainder of division operator' (which is not the same as modulo) |
|||
if nbr // nn = 0 then do |
|||
ip = isFalse |
|||
leave nn |
|||
end |
|||
end nn |
|||
end |
|||
end |
|||
return ip |
|||
method isTrue public static returns boolean |
|||
return 1 == 1 |
|||
method isFalse public static returns boolean |
|||
return \isTrue</syntaxhighlight> |
|||
{{out}} |
|||
<pre>$ java -cp . RCPrimality |
|||
List of prime numbers from 1 to 100: |
|||
2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97 |
|||
Total number of primes: 25 |
|||
$ java -cp . RCPrimality 91 |
|||
91 is not prime |
|||
$ java -cp . RCPrimality 101 |
|||
101 is prime |
|||
$ java -cp . RCPrimality . . 25 |
|||
List of prime numbers from 1 to 25: |
|||
2,3,5,7,11,13,17,19,23 |
|||
Total number of primes: 9 |
|||
$ java -cp . RCPrimality . 9900 10010 |
|||
List of prime numbers from 9900 to 10010: |
|||
9901,9907,9923,9929,9931,9941,9949,9967,9973,10007,10009 |
|||
Total number of primes: 11 |
|||
$ java -cp . RCPrimality . -57 1 |
|||
List of prime numbers from -57 to 1: |
|||
Total number of primes: 0 |
|||
$ java -cp . RCPrimality . 100 -57 |
|||
List of prime numbers from 100 to -57: |
|||
97,89,83,79,73,71,67,61,59,53,47,43,41,37,31,29,23,19,17,13,11,7,5,3,2 |
|||
Total number of primes: 25</pre> |
|||
===[[#REXX|Rexx]] version reimplemented in [[NetRexx]]=== |
|||
{{trans|REXX}} |
|||
<syntaxhighlight lang="netrexx">/* NetRexx */ |
|||
options replace format comments java crossref savelog symbols nobinary |
|||
/*REXX program tests for primality using (kinda smartish) trial division*/ |
|||
parse arg n . /*let user choose how many, maybe*/ |
|||
if n=='' then n=10000 /*if not, then assume the default*/ |
|||
p=0 /*a count of primes (so far). */ |
|||
/*I like Heinz's 57 varieties... */ |
|||
loop j=-57 to n /*start in the cellar and work up*/ |
|||
if \isprime(j) then iterate /*if not prime, keep looking. */ |
|||
p=p+1 /*bump the jelly bean counter. */ |
|||
if j.length>2 then iterate /*only show two-digit primes. */ |
|||
say j.right(20) 'is prime.' /*Just blab about the wee primes.*/ |
|||
end |
|||
say |
|||
say "there're" p "primes up to" n '(inclusive).' |
|||
exit |
|||
/*-------------------------------------ISPRIME subroutine---------------*/ |
|||
method isprime(x) public static returns boolean |
|||
--isprime: procedure; arg x /*get the number in question*/ |
|||
if '2 3 5 7'.wordpos(x)\==0 then return 1 /*is it a teacher's pet? */ |
|||
if x<2 | x//2==0 | x//3==0 then return 0 /*weed out the riff-raff. */ |
|||
/*Note: // is modulus. */ |
|||
loop j=5 by 6 until j*j>x /*skips multiples of three. */ |
|||
if x//j==0 | x//(j+2)==0 then return 0 /*do a pair of divides (mod)*/ |
|||
end |
|||
return 1 /*I'm exhausted, it's prime!*/</syntaxhighlight> |
|||
=={{header|newLISP}}== |
|||
Short-circuit evaluation ensures that the many Boolean expressions are calculated in the right order so as not to waste time. |
|||
<syntaxhighlight lang="newlisp">; Here are some simpler functions to help us: |
|||
(define (divisible? larger-number smaller-number) |
|||
(zero? (% larger-number smaller-number))) |
|||
(define (int-root number) |
|||
(floor (sqrt number))) |
|||
(define (even-prime? number) |
|||
(= number 2)) |
|||
; Trial division for odd numbers |
|||
(define (find-odd-factor? odd-number) |
|||
(catch |
|||
(for (possible-factor 3 (int-root odd-number) 2) |
|||
(if (divisible? odd-number possible-factor) |
|||
(throw true))))) |
|||
(define (odd-prime? number) |
|||
(and |
|||
(odd? number) |
|||
(or |
|||
(= number 3) |
|||
(and |
|||
(> number 3) |
|||
(not (find-odd-factor? number)))))) |
|||
; Now for the final overall Boolean function. |
|||
(define (is-prime? possible-prime) |
|||
(or |
|||
(even-prime? possible-prime) |
|||
(odd-prime? possible-prime))) |
|||
; Let's use this to actually find some prime numbers. |
|||
(println (filter is-prime? (sequence 1 100))) |
|||
(exit)</syntaxhighlight> |
|||
{{Output}} |
|||
(2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97) |
|||
=={{header|Nim}}== |
|||
Here are three ways to test primality using trial division. |
|||
<syntaxhighlight lang="nim">import sequtils, math |
|||
proc prime(a: int): bool = |
|||
if a == 2: return true |
|||
if a < 2 or a mod 2 == 0: return false |
|||
for i in countup(3, sqrt(a.float).int, 2): |
|||
if a mod i == 0: |
|||
return false |
|||
return true |
|||
proc prime2(a: int): bool = |
|||
result = not (a < 2 or any(toSeq(2 .. sqrt(a.float).int), a mod it == 0)) |
|||
proc prime3(a: int): bool = |
|||
if a == 2: return true |
|||
if a < 2 or a mod 2 == 0: return false |
|||
return not any(toSeq countup(3, sqrt(a.float).int, 2), a mod it == 0) |
|||
for i in 2..30: |
|||
echo i, " ", prime(i)</syntaxhighlight> |
|||
{{out}} |
|||
<pre>2 true |
|||
3 true |
|||
4 false |
|||
5 true |
|||
6 false |
|||
7 true |
|||
8 false |
|||
9 false |
|||
10 false |
|||
11 true |
|||
12 false |
|||
13 true |
|||
14 false |
|||
15 false |
|||
16 false |
|||
17 true |
|||
18 false |
|||
19 true |
|||
20 false |
|||
21 false |
|||
22 false |
|||
23 true |
|||
24 false |
|||
25 false |
|||
26 false |
|||
27 false |
|||
28 false |
|||
29 true |
|||
30 false</pre> |
|||
=={{header|Objeck}}== |
|||
<syntaxhighlight lang="objeck">function : IsPrime(n : Int) ~ Bool { |
|||
if(n <= 1) { |
|||
return false; |
|||
}; |
|||
for(i := 2; i * i <= n; i += 1;) { |
|||
if(n % i = 0) { |
|||
return false; |
|||
}; |
|||
}; |
|||
return true; |
|||
}</syntaxhighlight> |
|||
=={{header|OCaml}}== |
=={{header|OCaml}}== |
||
< |
<syntaxhighlight lang="ocaml">let is_prime n = |
||
let rec test x = |
|||
x * x > n || n mod x <> 0 && n mod (x + 2) <> 0 && test (x + 6) |
|||
in |
|||
if n < 5 |
|||
then n lor 1 = 3 |
|||
if k * k > n then true |
|||
else n land 1 <> 0 && n mod 3 <> 0 && test 5</syntaxhighlight> |
|||
else loop (k+2) |
|||
in loop 3</lang> |
|||
=={{header|Octave}}== |
=={{header|Octave}}== |
||
This function works on vectors and matrix. |
This function works on vectors and matrix. |
||
<syntaxhighlight lang="octave">function b = isthisprime(n) |
|||
<lang octave>function b = isthisprime(n) |
|||
for r = 1:rows(n) |
for r = 1:rows(n) |
||
for c = 1:columns(n) |
for c = 1:columns(n) |
||
Line 436: | Line 3,725: | ||
p = [1:100]; |
p = [1:100]; |
||
pv = isthisprime(p); |
pv = isthisprime(p); |
||
disp(p( pv ));</ |
disp(p( pv ));</syntaxhighlight> |
||
=={{header| |
=={{header|Oforth}}== |
||
<syntaxhighlight lang="oforth">Integer method: isPrime |
|||
A more idiomatic solution: |
|||
| i | |
|||
<lang perl>sub prime { my $n = shift || $_; |
|||
self 1 <= ifTrue: [ false return ] |
|||
self 3 <= ifTrue: [ true return ] |
|||
$n > 1 |
|||
self isEven ifTrue: [ false return ] |
|||
} |
|||
3 self sqrt asInteger for: i [ self i mod ifzero: [ false return ] ] |
|||
true ;</syntaxhighlight> |
|||
{{out}} |
|||
<pre>#isPrime 1000 seq filter println |
|||
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 8 |
|||
9, 97, 101, 103, 107, 109, 113, 127, 131, 137, 139, 149, 151, 157, 163, 167, 173, 179, 181 |
|||
, 191, 193, 197, 199, 211, 223, 227, 229, 233, 239, 241, 251, 257, 263, 269, 271, 277, 281 |
|||
, 283, 293, 307, 311, 313, 317, 331, 337, 347, 349, 353, 359, 367, 373, 379, 383, 389, 397 |
|||
, 401, 409, 419, 421, 431, 433, 439, 443, 449, 457, 461, 463, 467, 479, 487, 491, 499, 503 |
|||
, 509, 521, 523, 541, 547, 557, 563, 569, 571, 577, 587, 593, 599, 601, 607, 613, 617, 619 |
|||
, 631, 641, 643, 647, 653, 659, 661, 673, 677, 683, 691, 701, 709, 719, 727, 733, 739, 743 |
|||
, 751, 757, 761, 769, 773, 787, 797, 809, 811, 821, 823, 827, 829, 839, 853, 857, 859, 863 |
|||
, 877, 881, 883, 887, 907, 911, 919, 929, 937, 941, 947, 953, 967, 971, 977, 983, 991, 997 |
|||
]</pre> |
|||
=={{header|Ol}}== |
|||
print join(', ' => grep prime, 1..100), "\n";</lang> |
|||
<syntaxhighlight lang="scheme"> |
|||
(define (prime? number) |
|||
(define max (sqrt number)) |
|||
(define (loop divisor) |
|||
(or (> divisor max) |
|||
(and (> (modulo number divisor) 0) |
|||
(loop (+ divisor 2))))) |
|||
(or (= number 1) |
|||
(= number 2) |
|||
(and |
|||
(> (modulo number 2) 0) |
|||
(loop 3)))) |
|||
</syntaxhighlight> |
|||
Testing: |
|||
<syntaxhighlight lang="scheme"> |
|||
; first prime numbers less than 100 |
|||
(for-each (lambda (n) |
|||
(if (prime? n) |
|||
(display n)) |
|||
(display " ")) |
|||
(iota 100)) |
|||
(print) |
|||
; few more sintetic tests |
|||
===By Regular Expression=== |
|||
(for-each (lambda (n) |
|||
{{trans|Python}} |
|||
(print n " - prime? " (prime? n))) |
|||
<lang perl>sub isprime { |
|||
'( |
|||
('1' x shift) !~ /^1?$|^(11+?)\1+$/ |
|||
1234567654321 ; 1111111 * 1111111 |
|||
} |
|||
679390005787 ; really prime, I know that |
|||
679390008337 ; same |
|||
666810024403 ; 680633 * 979691 (multiplication of two prime numbers) |
|||
12345676543211234567654321 |
|||
12345676543211234567654321123456765432112345676543211234567654321123456765432112345676543211234567654321 |
|||
)) |
|||
</syntaxhighlight> |
|||
{{out}} |
|||
<pre> 1 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 |
|||
1234567654321 - prime? #false |
|||
679390005787 - prime? #true |
|||
679390008337 - prime? #true |
|||
666810024403 - prime? #false |
|||
12345676543211234567654321 - prime? #false |
|||
12345676543211234567654321123456765432112345676543211234567654321123456765432112345676543211234567654321 - prime? #false |
|||
</pre> |
|||
=={{header|Oz}}== |
|||
# A quick test |
|||
<syntaxhighlight lang="oz"> fun {Prime N} |
|||
print join(', ', grep(isprime($_), 0..39)), "\n";</lang> |
|||
local IPrime in |
|||
fun {IPrime N Acc} |
|||
if N < Acc*Acc then true |
|||
elseif (N mod Acc) == 0 then false |
|||
else {IPrime N Acc+1} |
|||
end |
|||
end |
|||
if N < 2 then false |
|||
else {IPrime N 2} end |
|||
end |
|||
end</syntaxhighlight> |
|||
=={{header| |
=={{header|Panda}}== |
||
In Panda you write a boolean function by making it filter, either returning it's input or nothing. |
|||
{{works with|Rakudo|#22 "Thousand Oaks"}} |
|||
<syntaxhighlight lang="panda">fun prime(p) type integer->integer |
|||
p.gt(1) where q=p.sqrt NO(p.mod(2..q)==0) |
|||
1..100.prime</syntaxhighlight> |
|||
Most simply: |
|||
=={{header|PARI/GP}}== |
|||
<lang perl6>sub prime (Int $n) { $n > 1 and $n !% none 2 .. sqrt $n }</lang> |
|||
<syntaxhighlight lang="parigp">trial(n)={ |
|||
if(n < 4, return(n > 1)); /* Handle negatives */ |
|||
forprime(p=2,sqrtint(n), |
|||
if(n%p == 0, return(0)) |
|||
); |
|||
1 |
|||
};</syntaxhighlight> |
|||
=={{header|Pascal}}== |
|||
Skipping even numbers when possible: |
|||
{{trans|QuickBASIC}} |
|||
<syntaxhighlight lang="pascal">program primes; |
|||
function prime(n: integer): boolean; |
|||
<lang perl6>sub prime (Int $n where (* > 0)) returns Bool { |
|||
var |
|||
when $n == 1 { False } |
|||
i: integer; max: real; |
|||
when $n == 2|3 { True } |
|||
begin |
|||
when $n < 25 { $n % 2 and $n % 3 } |
|||
if n = 2 then |
|||
default { $n !% none 2, 3 ... * + 2, sqrt $n } |
|||
prime := true |
|||
}</lang> |
|||
else if (n <= 1) or (n mod 2 = 0) then |
|||
prime := false |
|||
else begin |
|||
prime := true; i := 3; max := sqrt(n); |
|||
while i <= max do begin |
|||
if n mod i = 0 then begin |
|||
prime := false; exit |
|||
end; |
|||
i := i + 2 |
|||
end |
|||
end |
|||
end; |
|||
{ Test and display primes 0 .. 50 } |
|||
Testing: |
|||
var |
|||
n: integer; |
|||
begin |
|||
for n := 0 to 50 do |
|||
if (prime(n)) then |
|||
write(n, ' '); |
|||
end.</syntaxhighlight> |
|||
{{out}} |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 |
|||
===improved using number wheel=== |
|||
{{libheader|primTrial}}{{works with|Free Pascal}} |
|||
<syntaxhighlight lang="pascal">program TestTrialDiv; |
|||
{$IFDEF FPC} |
|||
{$MODE DELPHI}{$Smartlink ON} |
|||
{$ELSE} |
|||
{$APPLICATION CONSOLE}// for Delphi |
|||
{$ENDIF} |
|||
uses |
|||
primtrial; |
|||
{ Test and display primes 0 .. 50 } |
|||
begin |
|||
repeat |
|||
write(actPrime,' '); |
|||
until nextPrime > 50; |
|||
end.</syntaxhighlight> |
|||
;Output: |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 |
|||
=={{header|PascalABC.NET}}== |
|||
<lang perl6>say "$_ is{ prime($_) ?? '' !! 'n\'t' } prime." for 1 .. 100;</lang> |
|||
<syntaxhighlight lang="delphi"> |
|||
function IsPrime(N: integer): boolean; |
|||
begin |
|||
if N = 1 then |
|||
Result := False |
|||
else Result := True; |
|||
for var i:=2 to N.Sqrt.Round do |
|||
if N.Divs(i) then |
|||
begin |
|||
Result := False; |
|||
exit |
|||
end; |
|||
end; |
|||
begin |
|||
for var i:=1 to 1000 do |
|||
if IsPrime(i) then |
|||
Print(i) |
|||
end. |
|||
</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157 163 167 173 179 181 191 193 197 199 211 223 227 229 233 239 241 251 257 263 269 271 277 281 283 293 307 311 313 317 331 337 347 349 353 359 367 373 379 383 389 397 401 409 419 421 431 433 439 443 449 457 461 463 467 479 487 491 499 503 509 521 523 541 547 557 563 569 571 577 587 593 599 601 607 613 617 619 631 641 643 647 653 659 661 673 677 683 691 701 709 719 727 733 739 743 751 757 761 769 773 787 797 809 811 821 823 827 829 839 853 857 859 863 877 881 883 887 907 911 919 929 937 941 947 953 967 971 977 983 991 997 |
|||
</pre> |
|||
=={{header|Perl}}== |
|||
A simple idiomatic solution: |
|||
<syntaxhighlight lang="perl">sub prime { my $n = shift || $_; |
|||
$n % $_ or return for 2 .. sqrt $n; |
|||
$n > 1 |
|||
} |
|||
print join(', ' => grep prime, 1..100), "\n";</syntaxhighlight> |
|||
===Excluding multiples of 2 and 3=== |
|||
One of many ways of writing trial division using a mod-6 wheel. Almost 2x faster than the simple method shown earlier. |
|||
<syntaxhighlight lang="perl">sub isprime { |
|||
my $n = shift; |
|||
return ($n >= 2) if $n < 4; |
|||
return unless $n % 2 && $n % 3; |
|||
my $sqrtn = int(sqrt($n)); |
|||
for (my $i = 5; $i <= $sqrtn; $i += 6) { |
|||
return unless $n % $i && $n % ($i+2); |
|||
} |
|||
1; |
|||
} |
|||
my $s = 0; |
|||
$s += !!isprime($_) for 1..100000; |
|||
print "Pi(100,000) = $s\n";</syntaxhighlight> |
|||
===By Regular Expression=== |
|||
JAPH by Abigail 1999 [http://diswww.mit.edu/bloom-picayune.mit.edu/perl/12606] in conference slides 2000 [http://www.perlmonks.org/?node_id=21580]. |
|||
While this is extremely clever and often used for [[wp:Code golf|Code golf]], it should never be used for real work (it is extremely slow and uses lots of memory). |
|||
<syntaxhighlight lang="perl">sub isprime { |
|||
('1' x shift) !~ /^1?$|^(11+?)\1+$/ |
|||
} |
|||
print join(', ', grep(isprime($_), 0..39)), "\n";</syntaxhighlight> |
|||
=={{header|Phix}}== |
|||
<!--<syntaxhighlight lang="phix">(phixonline)--> |
|||
<span style="color: #008080;">function</span> <span style="color: #000000;">is_prime_by_trial_division</span><span style="color: #0000FF;">(</span><span style="color: #004080;">integer</span> <span style="color: #000000;">n</span><span style="color: #0000FF;">)</span> |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">n</span><span style="color: #0000FF;"><</span><span style="color: #000000;">2</span> <span style="color: #008080;">then</span> <span style="color: #008080;">return</span> <span style="color: #000000;">0</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">n</span><span style="color: #0000FF;">=</span><span style="color: #000000;">2</span> <span style="color: #008080;">then</span> <span style="color: #008080;">return</span> <span style="color: #000000;">1</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
<span style="color: #008080;">if</span> <span style="color: #7060A8;">remainder</span><span style="color: #0000FF;">(</span><span style="color: #000000;">n</span><span style="color: #0000FF;">,</span><span style="color: #000000;">2</span><span style="color: #0000FF;">)=</span><span style="color: #000000;">0</span> <span style="color: #008080;">then</span> <span style="color: #008080;">return</span> <span style="color: #000000;">0</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
<span style="color: #008080;">for</span> <span style="color: #000000;">i</span><span style="color: #0000FF;">=</span><span style="color: #000000;">3</span> <span style="color: #008080;">to</span> <span style="color: #7060A8;">floor</span><span style="color: #0000FF;">(</span><span style="color: #7060A8;">sqrt</span><span style="color: #0000FF;">(</span><span style="color: #000000;">n</span><span style="color: #0000FF;">))</span> <span style="color: #008080;">by</span> <span style="color: #000000;">2</span> <span style="color: #008080;">do</span> |
|||
<span style="color: #008080;">if</span> <span style="color: #7060A8;">remainder</span><span style="color: #0000FF;">(</span><span style="color: #000000;">n</span><span style="color: #0000FF;">,</span><span style="color: #000000;">i</span><span style="color: #0000FF;">)=</span><span style="color: #000000;">0</span> <span style="color: #008080;">then</span> |
|||
<span style="color: #008080;">return</span> <span style="color: #000000;">0</span> |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">for</span> |
|||
<span style="color: #008080;">return</span> <span style="color: #000000;">1</span> |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">function</span> |
|||
<span style="color: #0000FF;">?</span><span style="color: #7060A8;">filter</span><span style="color: #0000FF;">(</span><span style="color: #7060A8;">tagset</span><span style="color: #0000FF;">(</span><span style="color: #000000;">32</span><span style="color: #0000FF;">),</span><span style="color: #000000;">is_prime_by_trial_division</span><span style="color: #0000FF;">)</span> |
|||
<!--</syntaxhighlight>--> |
|||
{{out}} |
|||
<pre> |
|||
{2,3,5,7,11,13,17,19,23,29,31} |
|||
</pre> |
|||
=={{header|PHP}}== |
=={{header|PHP}}== |
||
< |
<syntaxhighlight lang="php"><?php |
||
function prime($a) { |
function prime($a) { |
||
if ($a < 2) |
if (($a % 2 == 0 && $a != 2) || $a < 2) |
||
return false; |
return false; |
||
$limit = sqrt($a); |
$limit = sqrt($a); |
||
Line 491: | Line 3,972: | ||
if (prime($x)) echo "$x\n"; |
if (prime($x)) echo "$x\n"; |
||
?></ |
?></syntaxhighlight> |
||
===By Regular Expression=== |
===By Regular Expression=== |
||
< |
<syntaxhighlight lang="php"><?php |
||
function prime($a) { |
function prime($a) { |
||
return !preg_match('/^1?$|^(11+?)\1+$/', str_repeat('1', $a)); |
return !preg_match('/^1?$|^(11+?)\1+$/', str_repeat('1', $a)); |
||
} |
} |
||
?></ |
?></syntaxhighlight> |
||
=={{header|Picat}}== |
|||
Here are four different versions. |
|||
===Iterative=== |
|||
<syntaxhighlight lang="picat">is_prime1(N) => |
|||
if N == 2 then |
|||
true |
|||
elseif N <= 1 ; N mod 2 == 0 then |
|||
false |
|||
else |
|||
foreach(I in 3..2..ceiling(sqrt(N))) |
|||
N mod I > 0 |
|||
end |
|||
end.</syntaxhighlight> |
|||
===Recursive=== |
|||
<syntaxhighlight lang="picat">is_prime2(N) => |
|||
(N == 2 ; is_prime2b(N,3)). |
|||
is_prime2b(N,_Div), N <= 1 => false. |
|||
is_prime2b(2,_Div) => true. |
|||
is_prime2b(N,_Div), N mod 2 == 0 => false. |
|||
is_prime2b(N,Div), Div > ceiling(sqrt(N)) => true. |
|||
is_prime2b(N,Div), Div > 2 => |
|||
(N mod Div == 0 -> |
|||
false |
|||
; |
|||
is_prime2b(N,Div+2) |
|||
).</syntaxhighlight> |
|||
===Functional=== |
|||
<syntaxhighlight lang="picat">is_prime3(2) => true. |
|||
is_prime3(3) => true. |
|||
is_prime3(P) => P > 3, P mod 2 =\= 0, not has_factor3(P,3). |
|||
has_factor3(N,L), N mod L == 0 => true. |
|||
has_factor3(N,L) => L * L < N, L2 = L + 2, has_factor3(N,L2).</syntaxhighlight> |
|||
===Generator approach=== |
|||
{{trans|Prolog}} |
|||
<code>prime2(N)</code> can be used to generate primes until memory is exhausted. |
|||
Difference from Prolog implementation: Picat does not support <code>between/3</code> with |
|||
"inf" as upper bound, so a high number (here 2**156+1) must be used. |
|||
<syntaxhighlight lang="picat">prime2(2). |
|||
prime2(N) :- |
|||
between(3, 2**156+1, N), |
|||
N mod 2 = 1, % odd |
|||
M is floor(sqrt(N+1)), % round-off paranoia |
|||
Max is (M-1) // 2, % integer division |
|||
foreach(I in 1..Max) N mod (2*I+1) > 0 end.</syntaxhighlight> |
|||
===Test=== |
|||
<syntaxhighlight lang="picat">go => |
|||
println([I : I in 1..100, is_prime1(I)]), |
|||
nl, |
|||
foreach(P in 1..6) |
|||
Primes = [ I : I in 1..10**P, is_prime1(I)], |
|||
println([10**P,Primes.len]) |
|||
end, |
|||
nl.</syntaxhighlight> |
|||
{{out}} |
|||
<pre>[2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97] |
|||
[10,4] |
|||
[100,25] |
|||
[1000,168] |
|||
[10000,1229] |
|||
[100000,9592] |
|||
[1000000,78498]</pre> |
|||
===Benchmark=== |
|||
Times for calculating the number of primes below 10, 100,1_000,10_000, 100_000, and 1_000_000 respectively. |
|||
* imperative: <code>is_prime1/1</code> (0.971) |
|||
* recursive: <code>is_prime2/1</code> (3.258s) |
|||
* functional: <code>is_prime3/1</code> (0.938s) |
|||
* test/generate <code>prime2/1</code> (2.129s) |
|||
=={{header|PicoLisp}}== |
|||
<syntaxhighlight lang="picolisp">(de prime? (N) |
|||
(or |
|||
(= N 2) |
|||
(and |
|||
(> N 1) |
|||
(bit? 1 N) |
|||
(let S (sqrt N) |
|||
(for (D 3 T (+ D 2)) |
|||
(T (> D S) T) |
|||
(T (=0 (% N D)) NIL) ) ) ) ) )</syntaxhighlight> |
|||
=={{header|PL/0}}== |
|||
The program waits for a number. Then it displays 1 if the number is prime, 0 otherwise. |
|||
<syntaxhighlight lang="pascal"> |
|||
var p, isprime; |
|||
procedure checkprimality; |
|||
var i, isichecked; |
|||
begin |
|||
isprime := 0; |
|||
if p = 2 then isprime := 1; |
|||
if p >= 3 then |
|||
begin |
|||
i := 2; isichecked := 0; |
|||
while isichecked = 0 do |
|||
begin |
|||
if (p / i) * i = p then isichecked := 1; |
|||
if isichecked <> 1 then |
|||
if i * i >= p then |
|||
begin |
|||
isprime := 1; isichecked := 1 |
|||
end; |
|||
i := i + 1 |
|||
end |
|||
end |
|||
end; |
|||
begin |
|||
? p; |
|||
call checkprimality; |
|||
! isprime |
|||
end. |
|||
</syntaxhighlight> |
|||
4 runs: |
|||
{{in}} |
|||
<pre>1</pre> |
|||
{{out}} |
|||
<pre> 0</pre> |
|||
{{in}} |
|||
<pre>25</pre> |
|||
{{out}} |
|||
<pre> 0</pre> |
|||
{{in}} |
|||
<pre>43</pre> |
|||
{{out}} |
|||
<pre> 1</pre> |
|||
{{in}} |
|||
<pre>101</pre> |
|||
{{out}} |
|||
<pre> 1</pre> |
|||
=={{header|PL/I}}== |
|||
<syntaxhighlight lang="pli">is_prime: procedure (n) returns (bit(1)); |
|||
declare n fixed (15); |
|||
declare i fixed (10); |
|||
if n < 2 then return ('0'b); |
|||
if n = 2 then return ('1'b); |
|||
if mod(n, 2) = 0 then return ('0'b); |
|||
do i = 3 to sqrt(n) by 2; |
|||
if mod(n, i) = 0 then return ('0'b); |
|||
end; |
|||
return ('1'b); |
|||
end is_prime;</syntaxhighlight> |
|||
=={{header|PL/M}}== |
|||
This can be compiled with the original 8080 PL/M compiler and run under CP/M or an emulator or clone. |
|||
<br>Note that all integers in 8080 PL/M are unsigned. |
|||
<syntaxhighlight lang="pli">100H: /* TEST FOR PRIMALITY BY TRIAL DIVISION */ |
|||
DECLARE FALSE LITERALLY '0', TRUE LITERALLY '0FFH'; |
|||
/* CP/M BDOS SYSTEM CALL */ |
|||
BDOS: PROCEDURE( FN, ARG ); DECLARE FN BYTE, ARG ADDRESS; GOTO 5; END; |
|||
PR$CHAR: PROCEDURE( C ); DECLARE C BYTE; CALL BDOS( 2, C ); END; |
|||
PR$STRING: PROCEDURE( S ); DECLARE S ADDRESS; CALL BDOS( 9, S ); END; |
|||
PR$NL: PROCEDURE; CALL PR$STRING( .( 0DH, 0AH, '$' ) ); END; |
|||
PR$NUMBER: PROCEDURE( N ); |
|||
DECLARE N ADDRESS; |
|||
DECLARE V ADDRESS, N$STR( 6 ) BYTE, W BYTE; |
|||
N$STR( W := LAST( N$STR ) ) = '$'; |
|||
N$STR( W := W - 1 ) = '0' + ( ( V := N ) MOD 10 ); |
|||
DO WHILE( ( V := V / 10 ) > 0 ); |
|||
N$STR( W := W - 1 ) = '0' + ( V MOD 10 ); |
|||
END; |
|||
CALL PR$STRING( .N$STR( W ) ); |
|||
END PR$NUMBER; |
|||
/* INTEGER SUARE ROOT: BASED ON THE ONE IN THE PL/M FOR FROBENIUS NUMBERS */ |
|||
SQRT: PROCEDURE( N )ADDRESS; |
|||
DECLARE ( N, X0, X1 ) ADDRESS; |
|||
IF N <= 3 THEN DO; |
|||
IF N = 0 THEN X0 = 0; ELSE X0 = 1; |
|||
END; |
|||
ELSE DO; |
|||
X0 = SHR( N, 1 ); |
|||
DO WHILE( ( X1 := SHR( X0 + ( N / X0 ), 1 ) ) < X0 ); |
|||
X0 = X1; |
|||
END; |
|||
END; |
|||
RETURN X0; |
|||
END SQRT; |
|||
IS$PRIME: PROCEDURE( N )BYTE; /* RETURNS TRUE IF N IS PRIME, FALSE IF NOT */ |
|||
DECLARE N ADDRESS; |
|||
IF N < 2 THEN RETURN FALSE; |
|||
ELSE IF ( N AND 1 ) = 0 THEN RETURN N = 2; |
|||
ELSE DO; |
|||
/* ODD NUMBER > 2 */ |
|||
DECLARE I ADDRESS; |
|||
DO I = 3 TO SQRT( N ) BY 2; |
|||
IF N MOD I = 0 THEN RETURN FALSE; |
|||
END; |
|||
RETURN TRUE; |
|||
END; |
|||
END IS$PRIME; |
|||
/* TEST THE IS$PRIME PROCEDURE */ |
|||
DECLARE I ADDRESS; |
|||
DO I = 0 TO 100; |
|||
IF IS$PRIME( I ) THEN DO; |
|||
CALL PR$CHAR( ' ' ); |
|||
CALL PR$NUMBER( I ); |
|||
END; |
|||
END; |
|||
CALL PR$NL; |
|||
EOF</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 |
|||
</pre> |
|||
=={{header|PowerShell}}== |
=={{header|PowerShell}}== |
||
<lang |
<syntaxhighlight lang="powershell"> |
||
function isPrime ($n) { |
|||
if ($n -eq 1) {$false} |
|||
elseif ($n -eq 2) {$true} |
|||
elseif ($n -eq 3) {$true} |
|||
return (@(2..[Math]::Sqrt($n) | Where-Object { $n % $_ -eq 0 }).Length -eq 0) |
|||
else{ |
|||
$m = [Math]::Floor([Math]::Sqrt($n)) |
|||
(@(2..$m | where {($_ -lt $n) -and ($n % $_ -eq 0) }).Count -eq 0) |
|||
} |
} |
||
} |
|||
}</lang> |
|||
1..15 | foreach{"isPrime $_ : $(isPrime $_)"}</syntaxhighlight> |
|||
<!-- Yes, I got a little carried away with the pipeline. This function checks whether the number of divisors between 2 and √n is zero and in that case it's a prime. --> |
|||
<b>Output:</b> |
|||
<pre>isPrime 1 : False |
|||
isPrime 2 : True |
|||
isPrime 3 : True |
|||
isPrime 4 : False |
|||
isPrime 5 : True |
|||
isPrime 6 : False |
|||
isPrime 7 : True |
|||
isPrime 8 : False |
|||
isPrime 9 : False |
|||
isPrime 10 : False |
|||
isPrime 11 : True |
|||
isPrime 12 : False |
|||
isPrime 13 : True |
|||
isPrime 14 : False |
|||
isPrime 15 : False</pre> |
|||
=={{header| |
=={{header|Prolog}}== |
||
The following predicate showcases Prolog's support for writing predicates suitable for both testing and generating. In this case, assuming the Prolog implemenation supports indefinitely large integers, prime(N) can be used to generate primes until memory is exhausted. |
|||
{{Works with |PureBasic| 4.41}} |
|||
<syntaxhighlight lang="prolog">prime(2). |
|||
<lang PureBasic>Procedure.i IsPrime(n) |
|||
prime(N) :- |
|||
Protected k |
|||
between(3, inf, N), |
|||
1 is N mod 2, % odd |
|||
M is floor(sqrt(N+1)), % round-off paranoia |
|||
Max is (M-1) // 2, % integer division |
|||
forall( between(1, Max, I), N mod (2*I+1) > 0 ).</syntaxhighlight> |
|||
Example using SWI-Prolog: |
|||
<pre>?- time( (bagof( P, (prime(P), ((P > 100000, !, fail); true)), Bag), |
|||
length(Bag,N), |
|||
last(Bag,Last), |
|||
writeln( (N,Last) ) )). |
|||
% 1,724,404 inferences, 1.072 CPU in 1.151 seconds (93% CPU, 1607873 Lips) |
|||
If n = 2 |
|||
Bag = [2, 3, 5, 7, 11, 13, 17, 19, 23|...], |
|||
ProcedureReturn #True |
|||
N = 9592, |
|||
EndIf |
|||
Last = 99991. |
|||
?- time( prime(99991) ). |
|||
If n <= 1 Or n % 2 = 0 |
|||
% 165 inferences, 0.000 CPU in 0.000 seconds (92% CPU, 1213235 Lips) |
|||
ProcedureReturn #False |
|||
true. |
|||
EndIf |
|||
For k = 3 To Int(Sqr(n)) Step 2 |
|||
If n % k = 0 |
|||
ProcedureReturn #False |
|||
EndIf |
|||
Next |
|||
?-</pre> |
|||
ProcedureReturn #True |
|||
EndProcedure</lang> |
|||
=={{header|Python}}== |
=={{header|Python}}== |
||
The simplest primality test, using trial division: |
The simplest primality test, using trial division: |
||
{{works with|Python|2.5}} |
{{works with|Python|2.5}} |
||
< |
<syntaxhighlight lang="python">def prime(a): |
||
return not (a < 2 or any(a % x == 0 for x in xrange(2, int(a**0.5) + 1)))</ |
return not (a < 2 or any(a % x == 0 for x in xrange(2, int(a**0.5) + 1)))</syntaxhighlight> |
||
Another test. Exclude even numbers first: |
Another test. Exclude even numbers first: |
||
<syntaxhighlight lang="python">def prime2(a): |
|||
<lang python>def prime2(a): |
|||
if a == 2: return True |
if a == 2: return True |
||
if a < 2 or a % 2 == 0: return False |
if a < 2 or a % 2 == 0: return False |
||
return not any(a % x == 0 for x in xrange(3, int(a**0.5) + 1, 2))</ |
return not any(a % x == 0 for x in xrange(3, int(a**0.5) + 1, 2))</syntaxhighlight> |
||
Yet another test. Exclude multiples of 2 and 3, see http://www.devx.com/vb2themax/Tip/19051: |
Yet another test. Exclude multiples of 2 and 3, see http://www.devx.com/vb2themax/Tip/19051: |
||
{{works with|Python|2.4}} |
{{works with|Python|2.4}} |
||
< |
<syntaxhighlight lang="python">def prime3(a): |
||
if a < 2: return False |
if a < 2: return False |
||
if a == 2 or a == 3: return True # manually test 2 and 3 |
if a == 2 or a == 3: return True # manually test 2 and 3 |
||
Line 561: | Line 4,282: | ||
i = 6 - i # this modifies 2 into 4 and viceversa |
i = 6 - i # this modifies 2 into 4 and viceversa |
||
return True</ |
return True</syntaxhighlight> |
||
===By Regular Expression=== |
===By Regular Expression=== |
||
Regular expression by "Abigail".<br> |
Regular expression by "Abigail".<br> |
||
(An explanation is given in "[http://paddy3118.blogspot.com/2009/08/story-of-regexp-and-primes.html The Story of the Regexp and the Primes]"). |
(An explanation is given in "[http://paddy3118.blogspot.com/2009/08/story-of-regexp-and-primes.html The Story of the Regexp and the Primes]"). |
||
< |
<syntaxhighlight lang="python">>>> import re |
||
>>> def isprime(n): |
>>> def isprime(n): |
||
return not re.match(r'^1?$|^(11+?)\1+$', '1' * n) |
return not re.match(r'^1?$|^(11+?)\1+$', '1' * n) |
||
Line 572: | Line 4,292: | ||
>>> # A quick test |
>>> # A quick test |
||
>>> [i for i in range(40) if isprime(i)] |
>>> [i for i in range(40) if isprime(i)] |
||
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37] |
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37]</syntaxhighlight> |
||
</lang> |
|||
=={{header|Qi}}== |
|||
<syntaxhighlight lang="qi">(define prime?-0 |
|||
K N -> true where (> (* K K) N) |
|||
K N -> false where (= 0 (MOD N K)) |
|||
K N -> (prime?-0 (+ K 2) N)) |
|||
(define prime? |
|||
1 -> false |
|||
2 -> true |
|||
N -> false where (= 0 (MOD N 2)) |
|||
N -> (prime?-0 3 N))</syntaxhighlight> |
|||
=={{header|Quackery}}== |
|||
<code>sqrt+</code> is defined at [[Isqrt (integer square root) of X#Quackery]]. |
|||
<syntaxhighlight lang="quackery"> [ dup 4 < iff [ 1 > ] done |
|||
dup 1 & not iff [ drop false ] done |
|||
true swap dup sqrt+ |
|||
0 = iff [ 2drop not ] done |
|||
1 >> times |
|||
[ dup i^ 1 << 3 + mod 0 = if |
|||
[ dip not conclude ] ] |
|||
drop ] is isprime ( n --> b ) |
|||
</syntaxhighlight> |
|||
=={{header|R}}== |
=={{header|R}}== |
||
<syntaxhighlight lang="rsplus">is.prime <- function(n) n == 2 || n > 2 && n %% 2 == 1 && (n < 9 || all(n %% seq(3, floor(sqrt(n)), 2) > 0)) |
|||
<lang R>isPrime <- function(n) { |
|||
if (n == 2) return(TRUE) |
|||
which(sapply(1:100, is.prime)) |
|||
if ( (n <= 1) || ( n %% 2 == 0 ) ) return(FALSE) |
|||
# [1] 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97</syntaxhighlight> |
|||
for( i in 3:sqrt(n) ) { |
|||
if ( n %% i == 0 ) return(FALSE) |
|||
=={{header|Racket}}== |
|||
} |
|||
<syntaxhighlight lang="racket">#lang racket |
|||
TRUE |
|||
}</lang> |
|||
(define (prime? number) |
|||
(cond ((not (positive? number)) #f) |
|||
((= 1 number) #f) |
|||
((even? number) (= 2 number)) |
|||
(else (for/and ((i (in-range 3 (ceiling (sqrt number))))) |
|||
(not (zero? (remainder number i)))))))</syntaxhighlight> |
|||
=={{header|Raku}}== |
|||
(formerly Perl 6) |
|||
Here we use a "none" junction which will autothread through the <tt>%%</tt> "is divisible by" operator to assert that <tt>$i</tt> is not divisible by 2 or any of the numbers up to its square root. Read it just as you would English: "Integer <tt>$i</tt> is prime if it is greater than one and is divisible by none of 2, 3, up to the square root of <tt>$i</tt>." |
|||
<syntaxhighlight lang="raku" line>sub prime (Int $i --> Bool) { |
|||
$i > 1 and so $i %% none 2..$i.sqrt; |
|||
}</syntaxhighlight> |
|||
This can easily be improved in two ways. First, we generate the primes so we only divide by those, instead of all odd numbers. Second, we memoize the result using the <tt>//=</tt> idiom of Perl, which does the right-hand calculation and assigns it only if the left side is undefined. We avoid recalculating the square root each time. Note the mutual recursion that depends on the implicit laziness of list evaluation: |
|||
<syntaxhighlight lang="raku" line>my @primes = 2, 3, 5, -> $p { ($p+2, $p+4 ... &prime)[*-1] } ... *; |
|||
my @isprime = False,False; # 0 and 1 are not prime by definition |
|||
sub prime($i) { |
|||
my \limit = $i.sqrt.floor; |
|||
@isprime[$i] //= so ($i %% none @primes ...^ { $_ > limit }) |
|||
} |
|||
say "$_ is{ "n't" x !prime($_) } prime." for 1 .. 100;</syntaxhighlight> |
|||
=={{header|REBOL}}== |
|||
<syntaxhighlight lang="rebol">prime?: func [n] [ |
|||
case [ |
|||
n = 2 [ true ] |
|||
n <= 1 or (n // 2 = 0) [ false ] |
|||
true [ |
|||
for i 3 round square-root n 2 [ |
|||
if n // i = 0 [ return false ] |
|||
] |
|||
true |
|||
] |
|||
] |
|||
]</syntaxhighlight> |
|||
<syntaxhighlight lang="rebol">repeat i 100 [ print [i prime? i]]</syntaxhighlight> |
|||
=={{header|REXX}}== |
|||
===compact version=== |
|||
This version uses a technique which increments by six for testing primality (up to the √{{overline| n }}). |
|||
Programming note: all the REXX programs below show all primes up and including the number specified. |
|||
::: If the number is negative, the absolute value of it is used for the upper limit, but no primes are shown. |
|||
::: The ''number'' of primes found is always shown. |
|||
Also, it was determined that computing the (integer) square root of the number to be tested in the '''isPrime''' |
|||
<br>function slowed up the function (for all three REXX versions), however, for larger numbers of '''N''', it would |
|||
<br>be faster. |
|||
<syntaxhighlight lang="rexx">/*REXX program tests for primality by using (kinda smartish) trial division. */ |
|||
parse arg n .; if n=='' then n=10000 /*let the user choose the upper limit. */ |
|||
tell=(n>0); n=abs(n) /*display the primes only if N > 0. */ |
|||
p=0 /*a count of the primes found (so far).*/ |
|||
do j=-57 to n /*start in the cellar and work up. */ |
|||
if \isPrime(j) then iterate /*if not prime, then keep looking. */ |
|||
p=p+1 /*bump the jelly bean counter. */ |
|||
if tell then say right(j,20) 'is prime.' /*maybe display prime to the terminal. */ |
|||
end /*j*/ |
|||
say |
|||
say "There are " p " primes up to " n ' (inclusive).' |
|||
exit /*stick a fork in it, we're all done. */ |
|||
/*──────────────────────────────────────────────────────────────────────────────────────*/ |
|||
isPrime: procedure; parse arg x /*get the number to be tested. */ |
|||
if wordpos(x, '2 3 5 7')\==0 then return 1 /*is number a teacher's pet? */ |
|||
if x<2 | x//2==0 | x//3==0 then return 0 /*weed out the riff-raff. */ |
|||
do k=5 by 6 until k*k>x /*skips odd multiples of 3. */ |
|||
if x//k==0 | x//(k+2)==0 then return 0 /*a pair of divides. ___ */ |
|||
end /*k*/ /*divide up through the √ x */ |
|||
/*Note: // is ÷ remainder.*/ |
|||
return 1 /*done dividing, it's prime. */</syntaxhighlight> |
|||
{{out|output|text= when using the default input of: <tt> 100 </tt>}} |
|||
<pre> |
|||
2 is prime. |
|||
3 is prime. |
|||
5 is prime. |
|||
7 is prime. |
|||
11 is prime. |
|||
13 is prime. |
|||
17 is prime. |
|||
19 is prime. |
|||
23 is prime. |
|||
29 is prime. |
|||
31 is prime. |
|||
37 is prime. |
|||
41 is prime. |
|||
43 is prime. |
|||
47 is prime. |
|||
53 is prime. |
|||
59 is prime. |
|||
61 is prime. |
|||
67 is prime. |
|||
71 is prime. |
|||
73 is prime. |
|||
79 is prime. |
|||
83 is prime. |
|||
89 is prime. |
|||
97 is prime. |
|||
There are 25 primes up to 100 (inclusive).</pre> |
|||
===optimized version=== |
|||
This version separates multiple-clause '''if''' statements, and also tests for low primes, |
|||
<br>making it about 8% faster. |
|||
<syntaxhighlight lang="rexx">/*REXX program tests for primality by using (kinda smartish) trial division. */ |
|||
parse arg n .; if n=='' then n=10000 /*let the user choose the upper limit. */ |
|||
tell=(n>0); n=abs(n) /*display the primes only if N > 0. */ |
|||
p=0 /*a count of the primes found (so far).*/ |
|||
do j=-57 to n /*start in the cellar and work up. */ |
|||
if \isPrime(j) then iterate /*if not prime, then keep looking. */ |
|||
p=p+1 /*bump the jelly bean counter. */ |
|||
if tell then say right(j,20) 'is prime.' /*maybe display prime to the terminal. */ |
|||
end /*j*/ |
|||
say |
|||
say "There are " p " primes up to " n ' (inclusive).' |
|||
exit /*stick a fork in it, we're all done. */ |
|||
/*──────────────────────────────────────────────────────────────────────────────────────*/ |
|||
isPrime: procedure; parse arg x /*get integer to be investigated.*/ |
|||
if x<11 then return wordpos(x, '2 3 5 7')\==0 /*is it a wee prime? */ |
|||
if x//2==0 then return 0 /*eliminate all the even numbers.*/ |
|||
if x//3==0 then return 0 /* ··· and eliminate the triples.*/ |
|||
do k=5 by 6 until k*k>x /*this skips odd multiples of 3. */ |
|||
if x//k ==0 then return 0 /*perform a divide (modulus), */ |
|||
if x//(k+2)==0 then return 0 /* ··· and the next umpty one. */ |
|||
end /*k*/ /*Note: REXX // is ÷ remainder.*/ |
|||
return 1 /*did all divisions, it's prime. */</syntaxhighlight> |
|||
{{out|output|text= is identical to the first version when the same input is used.}} |
|||
===unrolled version=== |
|||
This version uses an ''unrolled'' version (of the 2<sup>nd</sup> version) of some multiple-clause '''if''' statements, and |
|||
<br>also an optimized version of the testing of low primes is used, making it about 22% faster. |
|||
<br><br>Note that the '''do ... until ...''' was changed to '''do ... while ...'''. |
|||
<syntaxhighlight lang="rexx">/*REXX program tests for primality by using (kinda smartish) trial division. */ |
|||
parse arg n .; if n=='' then n=10000 /*let the user choose the upper limit. */ |
|||
tell=(n>0); n=abs(n) /*display the primes only if N > 0. */ |
|||
p=0 /*a count of the primes found (so far).*/ |
|||
do j=-57 to n /*start in the cellar and work up. */ |
|||
if \isPrime(j) then iterate /*if not prime, then keep looking. */ |
|||
p=p+1 /*bump the jelly bean counter. */ |
|||
if tell then say right(j,20) 'is prime.' /*maybe display prime to the terminal. */ |
|||
end /*j*/ |
|||
say |
|||
say "There are " p " primes up to " n ' (inclusive).' |
|||
exit /*stick a fork in it, we're all done. */ |
|||
/*──────────────────────────────────────────────────────────────────────────────────────*/ |
|||
isPrime: procedure; parse arg x /*get the integer to be investigated. */ |
|||
if x<107 then return wordpos(x, '2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53', |
|||
'59 61 67 71 73 79 83 89 97 101 103')\==0 /*some low primes.*/ |
|||
if x// 2 ==0 then return 0 /*eliminate all the even numbers. */ |
|||
if x// 3 ==0 then return 0 /* ··· and eliminate the triples. */ |
|||
parse var x '' -1 _ /* obtain the rightmost digit.*/ |
|||
if _ ==5 then return 0 /* ··· and eliminate the nickels. */ |
|||
if x// 7 ==0 then return 0 /* ··· and eliminate the luckies. */ |
|||
if x//11 ==0 then return 0 |
|||
if x//13 ==0 then return 0 |
|||
if x//17 ==0 then return 0 |
|||
if x//19 ==0 then return 0 |
|||
if x//23 ==0 then return 0 |
|||
if x//29 ==0 then return 0 |
|||
if x//31 ==0 then return 0 |
|||
if x//37 ==0 then return 0 |
|||
if x//41 ==0 then return 0 |
|||
if x//43 ==0 then return 0 |
|||
if x//47 ==0 then return 0 |
|||
if x//53 ==0 then return 0 |
|||
if x//59 ==0 then return 0 |
|||
if x//61 ==0 then return 0 |
|||
if x//67 ==0 then return 0 |
|||
if x//71 ==0 then return 0 |
|||
if x//73 ==0 then return 0 |
|||
if x//79 ==0 then return 0 |
|||
if x//83 ==0 then return 0 |
|||
if x//89 ==0 then return 0 |
|||
if x//97 ==0 then return 0 |
|||
if x//101==0 then return 0 |
|||
if x//103==0 then return 0 /*Note: REXX // is ÷ remainder. */ |
|||
do k=107 by 6 while k*k<=x /*this skips odd multiples of three. */ |
|||
if x//k ==0 then return 0 /*perform a divide (modulus), */ |
|||
if x//(k+2)==0 then return 0 /* ··· and the next also. ___ */ |
|||
end /*k*/ /*divide up through the √ x */ |
|||
return 1 /*after all that, ··· it's a prime. */</syntaxhighlight> |
|||
{{out|output|text= is identical to the first version when the same input is used.}}<br><br> |
|||
=={{header|Ring}}== |
|||
<syntaxhighlight lang="ring">give n |
|||
flag = isPrime(n) |
|||
if flag = 1 see n + " is a prime number" |
|||
else see n + " is not a prime number" ok |
|||
func isPrime num |
|||
if (num <= 1) return 0 ok |
|||
if (num % 2 = 0 and num != 2) return 0 ok |
|||
for i = 3 to floor(num / 2) -1 step 2 |
|||
if (num % i = 0) return 0 ok |
|||
next |
|||
return 1</syntaxhighlight> |
|||
=={{header|RPL}}== |
|||
{{trans|Python}} |
|||
This version use binary integers |
|||
{{works with|Halcyon Calc|4.2.7}} |
|||
{| class="wikitable" |
|||
! RPL code |
|||
! Comment |
|||
|- |
|||
| |
|||
≪ / LAST ROT * - #0 == ≫ '<span style="color:blue">BDIV?</span>' STO |
|||
≪ |
|||
'''IF''' DUP #3 ≤ '''THEN''' #2 / B→R |
|||
'''ELSE''' |
|||
'''IF''' DUP #2 <span style="color:blue">BDIV?</span> OVER #3 '''BDIV?''' OR |
|||
'''THEN''' DROP 0 |
|||
'''ELSE''' |
|||
DUP B→R √ R→B → a maxd |
|||
≪ a #2 #5 1 SF |
|||
'''WHILE''' 1 FS? OVER maxd ≤ AND '''REPEAT''' |
|||
'''IF''' a OVER <span style="color:blue">BDIV?</span> '''THEN''' 1 CF '''END''' |
|||
OVER + #6 ROT - SWAP '''END''' |
|||
≫ |
|||
SWAP DROP <span style="color:blue">BDIV?</span> NOT |
|||
'''END''' |
|||
'''END''' |
|||
≫ '<span style="color:blue">BPRIM?</span>' STO |
|||
| |
|||
<span style="color:blue">BDIV?</span> ''( #a #b -- boolean )'' |
|||
<span style="color:blue">BPRIM?</span> ''( #a -- boolean )'' |
|||
return 1 if a is 2 or 3 |
|||
if 2 or 3 divides a |
|||
return 0 |
|||
else |
|||
store a and root(a) |
|||
initialize stack with a i d and set flag 1 to control loop exit |
|||
while d <= root(a) |
|||
prepare loop exit if d divides a |
|||
i = 6 - i which modifies 2 into 4 and viceversa |
|||
empty stack and return result |
|||
|} |
|||
'''Floating point version''' |
|||
Faster but limited to 1E12. |
|||
<lang R>print(lapply(1:100, isPrime))</lang> |
|||
≪ '''IF''' DUP 5 ≤ '''THEN''' { 2 3 5 } SWAP POS |
|||
'''ELSE''' |
|||
'''IF''' DUP 2 MOD NOT '''THEN''' 2 |
|||
'''ELSE''' |
|||
DUP √ CEIL → lim |
|||
≪ 3 '''WHILE''' DUP2 MOD OVER lim ≤ AND '''REPEAT''' 2 + '''END''' |
|||
≫ |
|||
'''END''' MOD |
|||
'''END''' SIGN |
|||
≫ '<span style="color:blue">PRIM?</span>' STO |
|||
=={{header|Ruby}}== |
=={{header|Ruby}}== |
||
< |
<syntaxhighlight lang="ruby">def prime(a) |
||
if a == 2 |
if a == 2 |
||
true |
true |
||
Line 594: | Line 4,595: | ||
false |
false |
||
else |
else |
||
divisors = |
divisors = (3..Math.sqrt(a)).step(2) |
||
divisors.none? { |d| a % d == 0 } |
|||
# this also creates an enumerable object: divisors = (3..Math.sqrt(a)).step(2) |
|||
!divisors.any? { |d| a % d == 0 } |
|||
end |
end |
||
end |
end |
||
p (1..50).select{|i| prime(i)}</syntaxhighlight> |
|||
The mathn package in the stdlib for Ruby 1.9.2 contains this compact Prime#prime? method: |
|||
<lang ruby> def prime?(value, generator = Prime::Generator23.new) |
|||
The '''prime''' package in the stdlib for Ruby contains this compact <code>Prime#prime?</code> method: |
|||
return false if value < 2 |
|||
<syntaxhighlight lang="ruby">require "prime" |
|||
for num in generator |
|||
def prime?(value, generator = Prime::Generator23.new) |
|||
q,r = value.divmod num |
|||
return false if value < 2 |
|||
for num in generator |
|||
return false if r == 0 |
|||
q,r = value.divmod num |
|||
end |
|||
return true if q < num |
|||
end</lang> |
|||
return false if r == 0 |
|||
end |
|||
end |
|||
p (1..50).select{|i| prime?(i)}</syntaxhighlight> |
|||
Without any fancy stuff: |
Without any fancy stuff: |
||
< |
<syntaxhighlight lang="ruby">def primes(limit) |
||
(enclose = lambda { |primes| |
(enclose = lambda { |primes| |
||
primes.last.succ.upto(limit) do |trial_pri| |
primes.last.succ.upto(limit) do |trial_pri| |
||
if primes. |
if primes.none? { |pri| (trial_pri % pri).zero? } |
||
return enclose.call(primes << trial_pri) |
return enclose.call(primes << trial_pri) |
||
end |
end |
||
Line 618: | Line 4,623: | ||
primes |
primes |
||
}).call([2]) |
}).call([2]) |
||
end |
end |
||
p primes(50)</syntaxhighlight> |
|||
{{out}} |
|||
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47] |
|||
===By Regular Expression=== |
===By Regular Expression=== |
||
< |
<syntaxhighlight lang="ruby">def isprime(n) |
||
'1'*n !~ /^1?$|^(11+?)\1+$/ |
'1'*n !~ /^1?$|^(11+?)\1+$/ |
||
end</ |
end</syntaxhighlight> |
||
===Prime Generators Tests=== |
|||
Mathematicaly basis of Prime Generators |
|||
https://www.academia.edu/19786419/PRIMES-UTILS_HANDBOOK |
|||
https://www.academia.edu/42734410/Improved_Primality_Testing_and_Factorization_in_Ruby_revised |
|||
<syntaxhighlight lang="ruby">require "benchmark/ips" |
|||
# the simplest PG primality test using the P3 prime generator |
|||
# reduces the number space for primes to 2/6 (33.33%) of all integers |
|||
def primep3?(n) # P3 Prime Generator primality test |
|||
# P3 = 6*k + {5, 7} # P3 primes candidates (pc) sequence |
|||
return n | 1 == 3 if n < 5 # n: 0,1,4|false, 2,3|true |
|||
return false if n.gcd(6) != 1 # 1/3 (2/6) of integers are P3 pc |
|||
p, sqrtn = 5, Integer.sqrt(n) # first P3 sequence value |
|||
until p > sqrtn |
|||
return false if n % p == 0 || n % (p + 2) == 0 # if n is composite |
|||
p += 6 # first prime candidate for next kth residues group |
|||
end |
|||
true |
|||
end |
|||
# PG primality test using the P5 prime generator |
|||
# reduces the number space for primes to 8/30 (26.67%) of all integers |
|||
def primep5?(n) # P5 Prime Generator primality test |
|||
# P5 = 30*k + {7,11,13,17,19,23,29,31} # P5 primes candidates sequence |
|||
return [2, 3, 5].include?(n) if n < 7 # for small and negative values |
|||
return false if n.gcd(30) != 1 # 4/15 (8/30) of integers are P5 pc |
|||
p, sqrtn = 7, Integer.sqrt(n) # first P5 sequence value |
|||
until p > sqrtn |
|||
return false if # if n is composite |
|||
n % (p) == 0 || n % (p+4) == 0 || n % (p+6) == 0 || n % (p+10) == 0 || |
|||
n % (p+12) == 0 || n % (p+16) == 0 || n % (p+22) == 0 || n % (p+24) == 0 |
|||
p += 30 # first prime candidate for next kth residues group |
|||
end |
|||
true |
|||
end |
|||
# PG primality test using the P7 prime generator |
|||
# reduces the number space for primes to 48/210 (22.86%) of all integers |
|||
def primep7?(n) |
|||
# P7 = 210*k + {11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83, |
|||
# 89,97,101,103,107,109,113,121,127,131,137,139,143,149,151,157,163, |
|||
# 167,169,173,179,181,187,191,193,197,199,209,211} |
|||
return [2, 3, 5, 7].include?(n) if n < 11 |
|||
return false if n.gcd(210) != 1 # 8/35 (48/210) of integers are P7 pc |
|||
p, sqrtn = 11, Integer.sqrt(n) # first P7 sequence value |
|||
until p > sqrtn |
|||
return false if |
|||
n % (p) == 0 || n % (p+2) == 0 || n % (p+6) == 0 || n % (p+8) == 0 || |
|||
n % (p+12) == 0 || n % (p+18) == 0 || n % (p+20) == 0 || n % (p+26) == 0 || |
|||
n % (p+30) == 0 || n % (p+32) == 0 || n % (p+36) == 0 || n % (p+42) == 0 || |
|||
n % (p+48) == 0 || n % (p+50) == 0 || n % (p+56) == 0 || n % (p+60) == 0 || |
|||
n % (p+62) == 0 || n % (p+68) == 0 || n % (p+72) == 0 || n % (p+78) == 0 || |
|||
n % (p+86) == 0 || n % (p+90) == 0 || n % (p+92) == 0 || n % (p+96) == 0 || |
|||
n % (p+98) == 0 || n % (p+102) == 0 || n % (p+110) == 0 || n % (p+116) == 0 || |
|||
n % (p+120) == 0 || n % (p+126) == 0 || n % (p+128) == 0 || n % (p+132) == 0 || |
|||
n % (p+138) == 0 || n % (p+140) == 0 || n % (p+146) == 0 || n % (p+152) == 0 || |
|||
n % (p+156) == 0 || n % (p+158) == 0 || n % (p+162) == 0 || n % (p+168) == 0 || |
|||
n % (p+170) == 0 || n % (p+176) == 0 || n % (p+180) == 0 || n % (p+182) == 0 || |
|||
n % (p+186) == 0 || n % (p+188) == 0 || n % (p+198) == 0 || n % (p+200) == 0 |
|||
p += 210 # first prime candidate for next kth residues group |
|||
end |
|||
true |
|||
end |
|||
# Benchmarks to test for various size primes |
|||
p = 541 |
|||
Benchmark.ips do |b| |
|||
print "\np = #{p}" |
|||
b.report("primep3?") { primep3?(p) } |
|||
b.report("primep5?") { primep5?(p) } |
|||
b.report("primep7?") { primep7?(p) } |
|||
b.compare! |
|||
puts |
|||
end |
|||
p = 1000003 |
|||
Benchmark.ips do |b| |
|||
print "\np = #{p}" |
|||
b.report("primep3?") { primep3?(p) } |
|||
b.report("primep5?") { primep5?(p) } |
|||
b.report("primep7?") { primep7?(p) } |
|||
b.compare! |
|||
puts |
|||
end |
|||
p = 4294967291 # largest prime < 2**32 |
|||
Benchmark.ips do |b| |
|||
print "\np = #{p}" |
|||
b.report("primep3?") { primep3?(p) } |
|||
b.report("primep5?") { primep5?(p) } |
|||
b.report("primep7?") { primep7?(p) } |
|||
b.compare! |
|||
puts |
|||
end |
|||
p = (10 ** 16) * 2 + 3 |
|||
Benchmark.ips do |b| |
|||
print "\np = #{p}" |
|||
b.report("primep3?") { primep3?(p) } |
|||
b.report("primep5?") { primep5?(p) } |
|||
b.report("primep7?") { primep7?(p) } |
|||
b.compare! |
|||
puts |
|||
end</syntaxhighlight> |
|||
{{out}} |
|||
<pre>p = 541 |
|||
Warming up -------------------------------------- |
|||
primep3? 109.893k i/100ms |
|||
primep5? 123.949k i/100ms |
|||
primep7? 44.216k i/100ms |
|||
Calculating ------------------------------------- |
|||
primep3? 1.598M (± 3.4%) i/s - 8.022M in 5.025036s |
|||
primep5? 1.872M (± 6.3%) i/s - 9.420M in 5.059896s |
|||
primep7? 502.040k (± 1.2%) i/s - 2.520M in 5.020919s |
|||
Comparison: |
|||
primep5?: 1871959.0 i/s |
|||
primep3?: 1598489.8 i/s - 1.17x slower |
|||
primep7?: 502039.8 i/s - 3.73x slower |
|||
p = 1000003 |
|||
Warming up -------------------------------------- |
|||
primep3? 5.850k i/100ms |
|||
primep5? 9.013k i/100ms |
|||
primep7? 10.889k i/100ms |
|||
Calculating ------------------------------------- |
|||
primep3? 59.965k (± 1.1%) i/s - 304.200k in 5.073641s |
|||
primep5? 92.561k (± 2.1%) i/s - 468.676k in 5.065709s |
|||
primep7? 109.335k (± 0.8%) i/s - 555.339k in 5.079549s |
|||
Comparison: |
|||
primep7?: 109334.7 i/s |
|||
primep5?: 92561.4 i/s - 1.18x slower |
|||
primep3?: 59964.5 i/s - 1.82x slower |
|||
p = 4294967291 |
|||
Warming up -------------------------------------- |
|||
primep3? 92.000 i/100ms |
|||
primep5? 148.000 i/100ms |
|||
primep7? 184.000 i/100ms |
|||
Calculating ------------------------------------- |
|||
primep3? 926.647 (± 1.1%) i/s - 4.692k in 5.064067s |
|||
primep5? 1.480k (± 1.7%) i/s - 7.400k in 5.001399s |
|||
primep7? 1.804k (± 1.0%) i/s - 9.200k in 5.099110s |
|||
Comparison: |
|||
primep7?: 1804.4 i/s |
|||
primep5?: 1480.0 i/s - 1.22x slower |
|||
primep3?: 926.6 i/s - 1.95x slower |
|||
p = 20000000000000003 |
|||
Warming up -------------------------------------- |
|||
primep3? 1.000 i/100ms |
|||
primep5? 1.000 i/100ms |
|||
primep7? 1.000 i/100ms |
|||
Calculating ------------------------------------- |
|||
primep3? 0.422 (± 0.0%) i/s - 3.000 in 7.115929s |
|||
primep5? 0.671 (± 0.0%) i/s - 4.000 in 5.957077s |
|||
primep7? 0.832 (± 0.0%) i/s - 5.000 in 6.007834s |
|||
Comparison: |
|||
primep7?: 0.8 i/s |
|||
primep5?: 0.7 i/s - 1.24x slower |
|||
primep3?: 0.4 i/s - 1.97x slower |
|||
</pre> |
|||
=={{header|Rust}}== |
|||
<syntaxhighlight lang="rust">fn is_prime(n: u64) -> bool { |
|||
match n { |
|||
0 | 1 => false, |
|||
2 => true, |
|||
_even if n % 2 == 0 => false, |
|||
_ => { |
|||
let sqrt_limit = (n as f64).sqrt() as u64; |
|||
(3..=sqrt_limit).step_by(2).find(|i| n % i == 0).is_none() |
|||
} |
|||
} |
|||
} |
|||
fn main() { |
|||
for i in (1..30).filter(|i| is_prime(*i)) { |
|||
println!("{} ", i); |
|||
} |
|||
}</syntaxhighlight> |
|||
{{out}} |
|||
<pre>2 3 5 7 11 13 17 19 23 29 </pre> |
|||
=={{header|S-lang}}== |
|||
<syntaxhighlight lang="s-lang">define is_prime(n) |
|||
{ |
|||
if (n == 2) return(1); |
|||
if (n <= 1) return(0); |
|||
if ((n & 1) == 0) return(0); |
|||
variable mx = int(sqrt(n)), i; |
|||
_for i (3, mx, 1) { |
|||
if ((n mod i) == 0) |
|||
return(0); |
|||
} |
|||
return(1); |
|||
} |
|||
define ptest() |
|||
{ |
|||
variable lst = {}; |
|||
_for $1 (1, 64, 1) |
|||
if (is_prime($1)) |
|||
list_append(lst, string($1)); |
|||
print(strjoin(list_to_array(lst), ", ")); |
|||
} |
|||
ptest();</syntaxhighlight> |
|||
{{out}} |
|||
"2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61" |
|||
=={{header|SAS}}== |
|||
<syntaxhighlight lang="sas">data primes; |
|||
do n=1 to 1000; |
|||
link primep; |
|||
if primep then output; |
|||
end; |
|||
stop; |
|||
primep: |
|||
if n < 4 then do; |
|||
primep=n=2 or n=3; |
|||
return; |
|||
end; |
|||
primep=0; |
|||
if mod(n,2)=0 then return; |
|||
do k=3 to sqrt(n) by 2; |
|||
if mod(n,k)=0 then return; |
|||
end; |
|||
primep=1; |
|||
return; |
|||
keep n; |
|||
run;</syntaxhighlight> |
|||
=={{header|Scala}}== |
|||
===Simple version=== |
|||
<syntaxhighlight lang="scala"> def isPrime(n: Int) = |
|||
n > 1 && (Iterator.from(2) takeWhile (d => d * d <= n) forall (n % _ != 0))</syntaxhighlight> |
|||
===Accelerated version [[functional_programming|FP]] and parallel runabled=== |
|||
// {{Out}}Best seen running in your browser [https://scastie.scala-lang.org/1RLimJrRQUqkXWkUwUxgYg Scastie (remote JVM)]. |
|||
<syntaxhighlight lang="scala">object IsPrimeTrialDivision extends App { |
|||
def isPrime(n: Long) = |
|||
n > 1 && ((n & 1) != 0 || n == 2) && (n % 3 != 0 || n == 3) && |
|||
(5 to math.sqrt(n).toInt by 6).par.forall(d => n % d != 0 && n % (d + 2) != 0) |
|||
assert(!isPrime(-1)) |
|||
assert(!isPrime(1)) |
|||
assert(isPrime(2)) |
|||
assert(isPrime(100000000003L)) |
|||
assert(isPrime(100000000019L)) |
|||
assert(isPrime(100000000057L)) |
|||
assert(isPrime(100000000063L)) |
|||
assert(isPrime(100000000069L)) |
|||
assert(isPrime(100000000073L)) |
|||
assert(isPrime(100000000091L)) |
|||
println("10 Numbers tested. A moment please …\nNumber crunching biggest 63-bit prime …") |
|||
assert(isPrime(9223372036854775783L)) // Biggest 63-bit prime |
|||
println("All done") |
|||
}</syntaxhighlight> |
|||
===Accelerated version [[functional_programming|FP]], tail recursion=== |
|||
Tests 1.3 M numbers against OEIS prime numbers. |
|||
<syntaxhighlight lang="scala">import scala.annotation.tailrec |
|||
import scala.io.Source |
|||
object PrimesTestery extends App { |
|||
val rawText = Source.fromURL("https://oeis.org/A000040/a000040.txt") |
|||
val oeisPrimes = rawText.getLines().take(100000).map(_.split(" ")(1)).toVector |
|||
def isPrime(n: Long) = { |
|||
@tailrec |
|||
def inner(d: Int, end: Int): Boolean = { |
|||
if (d > end) true |
|||
else if (n % d != 0 && n % (d + 2) != 0) inner(d + 6, end) else false |
|||
} |
|||
n > 1 && ((n & 1) != 0 || n == 2) && |
|||
(n % 3 != 0 || n == 3) && inner(5, math.sqrt(n).toInt) |
|||
} |
|||
println(oeisPrimes.size) |
|||
for (i <- 0 to 1299709) assert(isPrime(i) == oeisPrimes.contains(i.toString), s"Wrong $i") |
|||
}</syntaxhighlight> |
|||
=={{header|Scheme}}== |
=={{header|Scheme}}== |
||
{{Works with|Scheme|R<math>^5</math>RS}} |
|||
<lang scheme>(define (is-prime? x) |
|||
<syntaxhighlight lang="scheme">(define (prime? number) |
|||
(cond ((< x 2) #f) |
|||
(define (*prime? divisor) |
|||
(or (> (* divisor divisor) number) |
|||
( |
(and (> (modulo number divisor) 0) |
||
(*prime? (+ divisor 1))))) |
|||
(and (> number 1) |
|||
(*prime? 2)))</syntaxhighlight> |
|||
((zero? (remainder x c)) #f) |
|||
(else (loop (+ c 2))))))))</lang> |
|||
<syntaxhighlight lang="scheme">; twice faster, testing only odd divisors |
|||
(define (prime? n) |
|||
(if (< n 4) (> n 1) |
|||
(and (odd? n) |
|||
(let loop ((k 3)) |
|||
(or (> (* k k) n) |
|||
(and (positive? (remainder n k)) |
|||
(loop (+ k 2))))))))</syntaxhighlight> |
|||
=={{header|Seed7}}== |
|||
<syntaxhighlight lang="seed7">const func boolean: isPrime (in integer: number) is func |
|||
result |
|||
var boolean: prime is FALSE; |
|||
local |
|||
var integer: upTo is 0; |
|||
var integer: testNum is 3; |
|||
begin |
|||
if number = 2 then |
|||
prime := TRUE; |
|||
elsif odd(number) and number > 2 then |
|||
upTo := sqrt(number); |
|||
while number rem testNum <> 0 and testNum <= upTo do |
|||
testNum +:= 2; |
|||
end while; |
|||
prime := testNum > upTo; |
|||
end if; |
|||
end func;</syntaxhighlight> |
|||
Original source: [http://seed7.sourceforge.net/algorith/math.htm#is_prime] |
|||
=={{header|SETL}}== |
|||
<syntaxhighlight lang="setl">program trial_division; |
|||
print({n : n in {1..100} | prime n}); |
|||
op prime(n); |
|||
return n>=2 and not exists d in {2..floor sqrt n} | n mod d = 0; |
|||
end op; |
|||
end program;</syntaxhighlight> |
|||
{{out}} |
|||
<pre>{2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97}</pre> |
|||
=={{header|Sidef}}== |
|||
<syntaxhighlight lang="ruby">func is_prime(a) { |
|||
given (a) { |
|||
when (2) { true } |
|||
case (a <= 1 || a.is_even) { false } |
|||
default { 3 .. a.isqrt -> any { .divides(a) } -> not } |
|||
} |
|||
}</syntaxhighlight> |
|||
{{trans|Perl}} |
|||
Alternative version, excluding multiples of 2 and 3: |
|||
<syntaxhighlight lang="ruby">func is_prime(n) { |
|||
return (n >= 2) if (n < 4) |
|||
return false if (n%%2 || n%%3) |
|||
for k in (5 .. n.isqrt -> by(6)) { |
|||
return false if (n%%k || n%%(k+2)) |
|||
} |
|||
return true |
|||
}</syntaxhighlight> |
|||
=={{header|Smalltalk}}== |
|||
<syntaxhighlight lang="smalltalk">| isPrime | |
|||
isPrime := [:n | |
|||
n even ifTrue: [ ^n=2 ] |
|||
ifFalse: [ |
|||
3 to: n sqrt do: [:i | |
|||
(n \\ i = 0) ifTrue: [ ^false ] |
|||
]. |
|||
^true |
|||
] |
|||
]</syntaxhighlight> |
|||
=={{header|SNOBOL4}}== |
|||
<syntaxhighlight lang="snobol4">define('isprime(n)i,max') :(isprime_end) |
|||
isprime isprime = n |
|||
le(n,1) :s(freturn) |
|||
eq(n,2) :s(return) |
|||
eq(remdr(n,2),0) :s(freturn) |
|||
max = sqrt(n); i = 1 |
|||
isp1 i = le(i + 2,max) i + 2 :f(return) |
|||
eq(remdr(n,i),0) :s(freturn)f(isp1) |
|||
isprime_end</syntaxhighlight> |
|||
===By Patterns=== |
|||
Using the Abigail regex transated to Snobol patterns. |
|||
<syntaxhighlight lang="snobol4"> define('rprime(n)str,pat1,pat2,m1') :(end_rprime) |
|||
rprime str = dupl('1',n); rprime = n |
|||
pat1 = ('1' | '') |
|||
pat2 = ('11' arbno('1')) $ m1 (*m1 arbno(*m1)) |
|||
str pos(0) (pat1 | pat2) rpos(0) :s(freturn)f(return) |
|||
end_rprime |
|||
* # Test and display primes 0 .. 50 |
|||
loop rprimes = rprimes rprime(n) ' ' |
|||
n = lt(n,50) n + 1 :s(loop) |
|||
output = rprimes |
|||
end</syntaxhighlight> |
|||
{{out}} |
|||
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 |
|||
=={{header|SparForte}}== |
|||
As a structured script. |
|||
<syntaxhighlight lang="ada">#!/usr/local/bin/spar |
|||
pragma annotate( summary, "prime" ); |
|||
pragma annotate( description, "Write a boolean function that tells whether a given" ); |
|||
pragma annotate( description, "integer is prime. Remember that 1 and all" ); |
|||
pragma annotate( description, "non-positive numbers are not prime. " ); |
|||
pragma annotate( see_also, "http://rosettacode.org/wiki/Primality_by_trial_division" ); |
|||
pragma annotate( author, "Ken O. Burtch" ); |
|||
pragma license( unrestricted ); |
|||
pragma restriction( no_external_commands ); |
|||
procedure prime is |
|||
function is_prime(item : positive) return boolean is |
|||
result : boolean := true; |
|||
test : natural; |
|||
begin |
|||
if item /= 2 and item mod 2 = 0 then |
|||
result := false; |
|||
else |
|||
test := 3; |
|||
while test < natural( numerics.sqrt( item ) ) loop |
|||
if natural(item) mod test = 0 then |
|||
result := false; |
|||
exit; |
|||
end if; |
|||
test := @ + 2; |
|||
end loop; |
|||
end if; |
|||
return result; |
|||
end is_prime; |
|||
number : positive; |
|||
result : boolean; |
|||
begin |
|||
number := 6; |
|||
result := is_prime( number ); |
|||
put( number ) @ ( " : " ) @ ( result ); |
|||
new_line; |
|||
number := 7; |
|||
result := is_prime( number ); |
|||
put( number ) @ ( " : " ) @ ( result ); |
|||
new_line; |
|||
number := 8; |
|||
result := is_prime( number ); |
|||
put( number ) @ ( " : " ) @ ( result ); |
|||
new_line; |
|||
end prime;</syntaxhighlight> |
|||
=={{header|SQL}}== |
|||
{{works with|T-SQL}} |
|||
<syntaxhighlight lang="tsql">declare @number int |
|||
set @number = 514229 -- number to check |
|||
;with cte(number) as |
|||
( |
|||
select 2 |
|||
union all |
|||
select number+1 |
|||
from cte |
|||
where number+1 < @number |
|||
) |
|||
select |
|||
cast(@number as varchar(100)) + |
|||
case |
|||
when exists |
|||
( |
|||
select * |
|||
from |
|||
( |
|||
select number, @number % number modNumber |
|||
from cte |
|||
) tmp |
|||
where tmp.modNumber = 0 |
|||
) |
|||
then ' is composite' |
|||
else |
|||
' is prime' |
|||
end primalityTest |
|||
option (maxrecursion 0)</syntaxhighlight> |
|||
=={{header|Standard ML}}== |
=={{header|Standard ML}}== |
||
< |
<syntaxhighlight lang="sml">fun is_prime n = |
||
if n = 2 then true |
if n = 2 then true |
||
else if n < 2 orelse n mod 2 = 0 then false |
else if n < 2 orelse n mod 2 = 0 then false |
||
Line 646: | Line 5,135: | ||
else loop (k+2) |
else loop (k+2) |
||
in loop 3 |
in loop 3 |
||
end</ |
end</syntaxhighlight> |
||
=={{header|Swift}}== |
|||
<syntaxhighlight lang="swift">import Foundation |
|||
extension Int { |
|||
func isPrime() -> Bool { |
|||
switch self { |
|||
case let x where x < 2: |
|||
return false |
|||
case 2: |
|||
return true |
|||
default: |
|||
return |
|||
self % 2 != 0 && |
|||
!stride(from: 3, through: Int(sqrt(Double(self))), by: 2).contains {self % $0 == 0} |
|||
} |
|||
} |
|||
}</syntaxhighlight> |
|||
A version that works with Swift 5.x and probably later. Does not need to import Foundation |
|||
<syntaxhighlight lang="swift"> |
|||
extension Int |
|||
{ |
|||
func isPrime() -> Bool |
|||
{ |
|||
if self < 3 |
|||
{ |
|||
return self == 2 |
|||
} |
|||
else |
|||
{ |
|||
let upperLimit = Int(Double(self).squareRoot()) |
|||
return !self.isMultiple(of: 2) && !stride(from: 3, through: upperLimit, by: 2) |
|||
.contains(where: { factor in self.isMultiple(of: factor) }) |
|||
} |
|||
} |
|||
} |
|||
</syntaxhighlight> |
|||
=={{header|Tcl}}== |
=={{header|Tcl}}== |
||
< |
<syntaxhighlight lang="tcl">proc is_prime n { |
||
if {$n <= 1} {return false} |
if {$n <= 1} {return false} |
||
if {$n == 2} {return true} |
if {$n == 2} {return true} |
||
Line 657: | Line 5,186: | ||
} |
} |
||
return true |
return true |
||
}</ |
}</syntaxhighlight> |
||
=={{header| |
=={{header|UNIX Shell}}== |
||
{{trans|C}} |
|||
Prompt A |
|||
{{works with|bash}} |
|||
If A=2:Then |
|||
{{works with|ksh93}} |
|||
Disp "PRIME" |
|||
{{works with|pdksh}} |
|||
Stop |
|||
{{works with|zsh}} |
|||
End |
|||
<syntaxhighlight lang="bash">function primep { |
|||
typeset n=$1 p=3 |
|||
If (fPart(A/2)=0 and A>0) or A<2:Then |
|||
(( n == 2 )) && return 0 # 2 is prime. |
|||
Disp "NOT PRIME" |
|||
(( n & 1 )) || return 1 # Other evens are not prime. |
|||
Stop |
|||
(( n >= 3 )) || return 1 |
|||
End |
|||
# Loop for odd p from 3 to sqrt(n). |
|||
1→P |
|||
# Comparing p * p <= n can overflow. |
|||
For(B,3,int(√(A))) |
|||
while (( p <= n / p )); do |
|||
If FPart(A/B)=0:Then |
|||
# If p divides n, then n is not prime. |
|||
0→P |
|||
(( n % p )) || return 1 |
|||
√(A)→B |
|||
(( p += 2 )) |
|||
End |
|||
done |
|||
B+1→B |
|||
return 0 # Yes, n is prime. |
|||
End |
|||
}</syntaxhighlight> |
|||
{{works with|Bourne Shell}} |
|||
If P=1:Then |
|||
<syntaxhighlight lang="bash">primep() { |
|||
Disp "PRIME" |
|||
set -- "$1" 3 |
|||
Else |
|||
test "$1" -eq 2 && return 0 # 2 is prime. |
|||
Disp "NOT PRIME" |
|||
expr "$1" \% 2 >/dev/null || return 1 # Other evens are not prime. |
|||
End |
|||
test "$1" -ge 3 || return 1 |
|||
# Loop for odd p from 3 to sqrt(n). |
|||
# Comparing p * p <= n can overflow. We use p <= n / p. |
|||
while expr $2 \<= "$1" / $2 >/dev/null; do |
|||
# If p divides n, then n is not prime. |
|||
expr "$1" % $2 >/dev/null || return 1 |
|||
set -- "$1" `expr $2 + 2` |
|||
done |
|||
return 0 # Yes, n is prime. |
|||
}</syntaxhighlight> |
|||
=={{header|Ursala}}== |
=={{header|Ursala}}== |
||
Excludes even numbers, and loops only up to the approximate square root or until a factor is found. |
|||
<syntaxhighlight lang="ursala">#import std |
|||
or until a factor is found |
|||
<lang Ursala> |
|||
#import std |
|||
#import nat |
#import nat |
||
prime = ~<{0,1}&& -={2,3}!| ~&h&& (all remainder)^Dtt/~& iota@K31 |
prime = ~<{0,1}&& -={2,3}!| ~&h&& (all remainder)^Dtt/~& iota@K31</syntaxhighlight> |
||
Test program to try it on a few numbers: |
|||
</lang> |
|||
<syntaxhighlight lang="ursala">#cast %bL |
|||
test program to try it on a few numbers: |
|||
<lang Ursala> |
|||
#cast %bL |
|||
test = prime* <5,6,7> |
test = prime* <5,6,7></syntaxhighlight> |
||
{{out}} |
|||
</lang> |
|||
<true,false,true> |
|||
output: |
|||
<pre> |
|||
<true,false,true> |
|||
</pre> |
|||
=={{header|V}}== |
=={{header|V}}== |
||
{{trans|Joy}} |
|||
like joy |
|||
<syntaxhighlight lang="v">[prime? |
|||
[prime? |
|||
2 |
2 |
||
[[dup * >] [true] [false] ifte [% 0 >] dip and] |
[[dup * >] [true] [false] ifte [% 0 >] dip and] |
||
[succ] |
[succ] |
||
while |
while |
||
dup * <]. |
dup * <].</syntaxhighlight> |
||
{{out|Using it}} |
|||
<syntaxhighlight lang="v">|11 prime? |
|||
=true |
|||
|4 prime? |
|||
=false</syntaxhighlight> |
|||
=={{header|Verilog}}== |
|||
<syntaxhighlight lang="Verilog">module main; |
|||
integer i, k; |
|||
initial begin |
|||
$display("Prime numbers between 0 and 100:"); |
|||
for(i = 2; i <= 99; i=i+1) begin |
|||
k=i; |
|||
if(i[0] != 1'b0) begin |
|||
if(k==3 | k==5 | k==7 | k==11 | k==13 | k==17 | k==19) $write(i); |
|||
else if(k%3==0 | k%5==0 | k%7==0 | k%11==0 | k%13==0 | k%17==0 | k%19==0) $write(""); |
|||
else $write(i); |
|||
end |
|||
if(i==10'b00 | i==10'b010) $write(i); |
|||
end |
|||
$finish; |
|||
end |
|||
endmodule</syntaxhighlight> |
|||
=={{header|V (Vlang)}}== |
|||
<syntaxhighlight lang="Zig"> |
|||
import math |
|||
const numbers = [5, 3, 14, 19, 25, 59, 88] |
|||
fn main() { |
|||
for num in numbers { |
|||
println("${num} is a prime number? " + if is_prime(num) == true {'yes'} else {'no'}) |
|||
} |
|||
} |
|||
fn is_prime(num int) bool { |
|||
if num <= 1 {return false} |
|||
if num % 2 == 0 && num != 2 {return false} |
|||
for idx := 3; idx <= math.floor(num / 2) - 1; idx += 2 { |
|||
if num % idx == 0 {return false} |
|||
} |
|||
return true |
|||
} |
|||
</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
5 is a prime number? yes |
|||
3 is a prime number? yes |
|||
14 is a prime number? no |
|||
19 is a prime number? yes |
|||
25 is a prime number? no |
|||
59 is a prime number? yes |
|||
88 is a prime number? no |
|||
</pre> |
|||
=={{header|Wren}}== |
|||
{{libheader|Wren-fmt}} |
|||
<syntaxhighlight lang="wren">import "./fmt" for Fmt |
|||
var isPrime = Fn.new { |n| |
|||
if (n < 2) return false |
|||
if (n%2 == 0) return n == 2 |
|||
var p = 3 |
|||
while (p * p <= n) { |
|||
if (n%p == 0) return false |
|||
p = p + 2 |
|||
} |
|||
return true |
|||
} |
|||
var tests = [2, 5, 12, 19, 57, 61, 97] |
|||
System.print("Are the following prime?") |
|||
for (test in tests) { |
|||
Fmt.print("$2d -> $y", test, isPrime.call(test)) |
|||
}</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
Are the following prime? |
|||
2 -> yes |
|||
5 -> yes |
|||
12 -> no |
|||
19 -> yes |
|||
57 -> no |
|||
61 -> yes |
|||
97 -> yes |
|||
</pre> |
|||
=={{header|XPL0}}== |
|||
<syntaxhighlight lang="xpl0">func Prime(N); \Return 'true' if N is a prime number |
|||
int N; |
|||
int I; |
|||
[if N <= 1 then return false; |
|||
for I:= 2 to sqrt(N) do |
|||
if rem(N/I) = 0 then return false; |
|||
return true; |
|||
]; |
|||
int Num; |
|||
repeat Num:= IntIn(0); |
|||
Text(0, if Prime(Num) then "is " else "not "); |
|||
Text(0, "prime^M^J"); |
|||
until Num = 0</syntaxhighlight> |
|||
{{out}} |
|||
<pre>777777777 |
|||
not prime |
|||
777777773 |
|||
is prime |
|||
0 |
|||
not prime</pre> |
|||
=={{header|zkl}}== |
|||
Using it |
|||
The Method filter1 stops at the first non False result, which, if there is one, is the first found diviser, thus short cutting the rest of the test |
|||
|11 prime? |
|||
<syntaxhighlight lang="zkl">fcn isPrime(n){ |
|||
=true |
|||
if(n.isEven or n<2) return(n==2); |
|||
|4 prime? |
|||
(not [3..n.toFloat().sqrt().toInt(),2].filter1('wrap(m){n%m==0})) |
|||
=false |
|||
}</syntaxhighlight> |
|||
{{out}} |
|||
<pre>zkl: [1..].filter(20,isPrime) |
|||
L(2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71) |
|||
zkl: isPrime(777777773) |
|||
True |
|||
zkl: isPrime(777777777) |
|||
False</pre> |
Latest revision as of 21:38, 23 June 2024
You are encouraged to solve this task according to the task description, using any language you may know.
- Task
Write a boolean function that tells whether a given integer is prime.
Remember that 1 and all non-positive numbers are not prime.
Use trial division.
Even numbers greater than 2 may be eliminated right away.
A loop from 3 to √ n will suffice, but other loops are allowed.
- Related tasks
- count in factors
- prime decomposition
- AKS test for primes
- factors of an integer
- Sieve of Eratosthenes
- factors of a Mersenne number
- trial factoring of a Mersenne number
- partition an integer X into N primes
- sequence of primes by Trial Division
11l
F is_prime(n)
I n < 2
R 0B
L(i) 2..Int(sqrt(n))
I n % i == 0
R 0B
R 1B
360 Assembly
* Primality by trial division 26/03/2017
PRIMEDIV CSECT
USING PRIMEDIV,R13 base register
B 72(R15) skip savearea
DC 17F'0' savearea
STM R14,R12,12(R13) save previous context
ST R13,4(R15) link backward
ST R15,8(R13) link forward
LR R13,R15 set addressability
LA R10,PG pgi=0
LA R6,1 i=1
DO WHILE=(C,R6,LE,=F'50') do i=1 to 50
LR R1,R6 i
BAL R14,ISPRIME call isprime(i)
IF C,R0,EQ,=F'1' THEN if isprime(i) then
XDECO R6,XDEC edit i
MVC 0(4,R10),XDEC+8 output i
LA R10,4(R10) pgi+=4
ENDIF , endif
LA R6,1(R6) i++
ENDDO , enddo i
XPRNT PG,L'PG print buffer
L R13,4(0,R13) restore previous savearea pointer
LM R14,R12,12(R13) restore previous context
XR R15,R15 rc=0
BR R14 exit
*------- ---- ----------------------------------------
ISPRIME EQU * function isprime(n)
IF C,R1,LE,=F'1' THEN if n<=1 then
LA R0,0 return(0)
BR R14 return
ENDIF , endif
IF C,R1,EQ,=F'2' THEN if n=2 then
LA R0,1 return(1)
BR R14 return
ENDIF , endif
LR R4,R1 n
N R4,=X'00000001' n and 1
IF LTR,R4,Z,R4 THEN if mod(n,2)=0 then
LA R0,0 return(0)
BR R14 return
ENDIF , endif
LA R7,3 j=3
LA R5,9 r5=j*j
DO WHILE=(CR,R5,LE,R1) do j=3 by 2 while j*j<=n
LR R4,R1 n
SRDA R4,32 ~
DR R4,R7 /j
IF LTR,R4,Z,R4 THEN if mod(n,j)=0 then
LA R0,0 return(0)
BR R14 return
ENDIF , endif
LA R7,2(R7) j+=2
LR R5,R7 j
MR R4,R7 r5=j*j
ENDDO , enddo j
LA R0,1 return(1)
BR R14 return
*------- ---- ----------------------------------------
PG DC CL80' ' buffer
XDEC DS CL12 temp for xdeco
YREGS
END PRIMEDIV
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
68000 Assembly
isPrime:
; REG USAGE:
; D0 = input (unsigned 32-bit integer)
; D1 = temp storage for D0
; D2 = candidates for possible factors
; D3 = temp storage for quotient/remainder
; D4 = total count of proper divisors.
MOVEM.L D1-D4,-(SP) ;push data regs except D0
MOVE.L #0,D1
MOVEM.L D1,D2-D4 ;clear regs D1 thru D4
CMP.L #0,D0
BEQ notPrime
CMP.L #1,D0
BEQ notPrime
CMP.L #2,D0
BEQ wasPrime
MOVE.L D0,D1 ;D1 will be used for temp storage.
AND.L #1,D1 ;is D1 even?
BEQ notPrime ;if so, it's not prime!
MOVE.L D0,D1 ;restore D1
MOVE.L #3,D2 ;start with 3
computeFactors:
DIVU D2,D1 ;remainder is in top 2 bytes, quotient in bottom 2.
MOVE.L D1,D3 ;temporarily store into D3 to check the remainder
SWAP D3 ;swap the high and low words of D3. Now bottom 2 bytes contain remainder.
CMP.W #0,D3 ;is the bottom word equal to 0?
BNE D2_Wasnt_A_Divisor ;if not, D2 was not a factor of D1.
ADDQ.L #1,D4 ;increment the count of proper divisors.
CMP.L #2,D4 ;is D4 two or greater?
BCC notPrime ;if so, it's not prime! (Ends early. We'll need to check again if we made it to the end.)
D2_Wasnt_A_Divisor:
MOVE.L D0,D1 ;restore D1.
ADDQ.L #1,D2 ;increment D2
CMP.L D2,D1 ;is D2 now greater than D1?
BLS computeFactors ;if not, loop again
CMP.L #1,D4 ;was there only one factor?
BEQ wasPrime ;if so, D0 was prime.
notPrime:
MOVE.L #0,D0 ;return false
MOVEM.L (SP)+,D1-D4 ;pop D1-D4
RTS
wasPrime:
MOVE.L #1,D0 ;return true
MOVEM.L (SP)+,D1-D4 ;pop D1-D4
RTS
;end of program
AArch64 Assembly
/* ARM assembly AARCH64 Raspberry PI 3B */
/* program testPrime64.s */
/*******************************************/
/* Constantes file */
/*******************************************/
/* for this file see task include a file in language AArch64 assembly*/
.include "../includeConstantesARM64.inc"
/*******************************************/
/* Initialized data */
/*******************************************/
.data
szMessStartPgm: .asciz "Program start \n"
szMessEndPgm: .asciz "Program normal end.\n"
szMessNotPrime: .asciz "Not prime.\n"
szMessPrime: .asciz "Prime\n"
szCarriageReturn: .asciz "\n"
/*******************************************/
/* UnInitialized data */
/*******************************************/
.bss
.align 4
/*******************************************/
/* code section */
/*******************************************/
.text
.global main
main: // program start
ldr x0,qAdrszMessStartPgm // display start message
bl affichageMess
ldr x0,qVal
bl isPrime // test prime ?
cmp x0,#0
beq 1f
ldr x0,qAdrszMessPrime // yes
bl affichageMess
b 2f
1:
ldr x0,qAdrszMessNotPrime // no
bl affichageMess
2:
ldr x0,qAdrszMessEndPgm // display end message
bl affichageMess
100: // standard end of the program
mov x0,0 // return code
mov x8,EXIT // request to exit program
svc 0 // perform system call
qAdrszMessStartPgm: .quad szMessStartPgm
qAdrszMessEndPgm: .quad szMessEndPgm
qAdrszCarriageReturn: .quad szCarriageReturn
qAdrszMessNotPrime: .quad szMessNotPrime
qAdrszMessPrime: .quad szMessPrime
//qVal: .quad 1042441 // test not prime
//qVal: .quad 1046527 // test prime
//qVal: .quad 37811 // test prime
//qVal: .quad 1429671721 // test not prime (37811 * 37811)
qVal: .quad 100000004437 // test prime
/******************************************************************/
/* test if number is prime */
/******************************************************************/
/* x0 contains the number */
/* x0 return 1 if prime else return 0 */
isPrime:
stp x1,lr,[sp,-16]! // save registers
cmp x0,1 // <= 1 ?
ble 98f
cmp x0,3 // 2 and 3 prime
ble 97f
tst x0,1 // even ?
beq 98f
mov x11,3 // first divisor
1:
udiv x12,x0,x11
msub x13,x12,x11,x0 // compute remainder
cbz x13,98f // end if zero
add x11,x11,#2 // increment divisor
cmp x11,x12 // divisors<=quotient ?
ble 1b // loop
97:
mov x0,1 // return prime
b 100f
98:
mov x0,0 // not prime
b 100f
100:
ldp x1,lr,[sp],16 // restaur 2 registers
ret // return to address lr x30
/********************************************************/
/* File Include fonctions */
/********************************************************/
/* for this file see task include a file in language AArch64 assembly */
.include "../includeARM64.inc"
ABAP
class ZMLA_ROSETTA definition
public
create public .
public section.
types:
enumber TYPE N LENGTH 60 .
types:
listof_enumber TYPE TABLE OF enumber .
class-methods IS_PRIME
importing
value(N) type ENUMBER
returning
value(OFLAG) type ABAP_BOOL .
class-methods IS_PRIME_I
importing
value(N) type I
returning
value(OFLAG) type ABAP_BOOL .
protected section.
private section.
ENDCLASS.
CLASS ZMLA_ROSETTA IMPLEMENTATION.
* <SIGNATURE>---------------------------------------------------------------------------------------+
* | Static Public Method ZMLA_ROSETTA=>IS_PRIME
* +-------------------------------------------------------------------------------------------------+
* | [--->] N TYPE ENUMBER
* | [<-()] OFLAG TYPE ABAP_BOOL
* +--------------------------------------------------------------------------------------</SIGNATURE>
method IS_PRIME.
IF n < 2.
oflag = abap_false.
RETURN.
ENDIF.
IF n = 2 or n = 3.
oflag = abap_true.
RETURN.
ENDIF.
IF n mod 2 = 0 or n mod 3 = 0.
oflag = abap_false.
RETURN.
ENDIF.
DATA: lim type enumber,
d type enumber,
i TYPE i VALUE 2.
lim = sqrt( n ).
d = 5.
WHILE d <= lim.
IF n mod d = 0.
oflag = abap_false.
RETURN.
ENDIF.
d = d + i.
i = 6 - i. " this modifies 2 into 4 and viceversa
ENDWHILE.
oflag = abap_true.
RETURN.
endmethod.
* <SIGNATURE>---------------------------------------------------------------------------------------+
* | Static Public Method ZMLA_ROSETTA=>IS_PRIME_I
* +-------------------------------------------------------------------------------------------------+
* | [--->] N TYPE I
* | [<-()] OFLAG TYPE ABAP_BOOL
* +--------------------------------------------------------------------------------------</SIGNATURE>
method IS_PRIME_I.
IF n < 2.
oflag = abap_false.
RETURN.
ENDIF.
IF n = 2 or n = 3.
oflag = abap_true.
RETURN.
ENDIF.
IF n mod 2 = 0 or n mod 3 = 0.
oflag = abap_false.
RETURN.
ENDIF.
DATA: lim type i,
d type i,
i TYPE i VALUE 2.
lim = sqrt( n ).
d = 5.
WHILE d <= lim.
IF n mod d = 0.
oflag = abap_false.
RETURN.
ENDIF.
d = d + i.
i = 6 - i. " this modifies 2 into 4 and viceversa
ENDWHILE.
oflag = abap_true.
RETURN.
endmethod.
ENDCLASS.
ABC
HOW TO REPORT prime n:
REPORT n>=2 AND NO d IN {2..floor root n} HAS n mod d = 0
FOR n IN {1..100}:
IF prime n: WRITE n
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
ACL2
(defun is-prime-r (x i)
(declare (xargs :measure (nfix (- x i))))
(if (zp (- (- x i) 1))
t
(and (/= (mod x i) 0)
(is-prime-r x (1+ i)))))
(defun is-prime (x)
(or (= x 2)
(is-prime-r x 2)))
Action!
BYTE FUNC IsPrime(CARD a)
CARD i
IF a<=1 THEN
RETURN (0)
FI
FOR i=2 TO a/2
DO
IF a MOD i=0 THEN
RETURN (0)
FI
OD
RETURN (1)
PROC Test(CARD a)
IF IsPrime(a) THEN
PrintF("%I is prime%E",a)
ELSE
PrintF("%I is not prime%E",a)
FI
RETURN
PROC Main()
Test(13)
Test(997)
Test(1)
Test(6)
Test(120)
Test(0)
RETURN
- Output:
Screenshot from Atari 8-bit computer
13 is prime 997 is prime 1 is not prime 6 is not prime 120 is not prime 0 is not prime
ActionScript
function isPrime(n:int):Boolean
{
if(n < 2) return false;
if(n == 2) return true;
if((n & 1) == 0) return false;
for(var i:int = 3; i <= Math.sqrt(n); i+= 2)
if(n % i == 0) return false;
return true;
}
Ada
function Is_Prime(Item : Positive) return Boolean is
Test : Natural;
begin
if Item = 1 then
return False;
elsif Item = 2 then
return True;
elsif Item mod 2 = 0 then
return False;
else
Test := 3;
while Test <= Integer(Sqrt(Float(Item))) loop
if Item mod Test = 0 then
return False;
end if;
Test := Test + 2;
end loop;
end if;
return True;
end Is_Prime;
Sqrt
is made visible by a with / use clause on Ada.Numerics.Elementary_Functions
.
With Ada 2012, the function can be made more compact as an expression function (but without loop optimized by skipping even numbers) :
function Is_Prime(Item : Positive) return Boolean is
(Item /= 1 and then
(for all Test in 2..Integer(Sqrt(Float(Item))) => Item mod Test /= 0));
As an alternative, one can use the generic function Prime_Numbers.Is_Prime, as specified in Prime decomposition#Ada, which also implements trial division.
with Prime_Numbers;
procedure Test_Prime is
package Integer_Numbers is new
Prime_Numbers (Natural, 0, 1, 2);
use Integer_Numbers;
begin
if Is_Prime(12) or (not Is_Prime(13)) then
raise Program_Error with "Test_Prime failed!";
end if;
end Test_Prime;
ALGOL 60
begin
boolean procedure isprime(n);
value n; integer n;
begin
comment - local procedure tests whether n is even;
boolean procedure even(n);
value n; integer n;
even := entier(n / 2) * 2 = n;
if n < 2 then
isprime := false
else if even(n) then
isprime := (n = 2)
else
begin
comment - check odd divisors up to sqrt(n);
integer i, limit;
boolean divisible;
i := 3;
limit := entier(sqrt(n));
divisible := false;
for i := i while i <= limit and not divisible do
begin
if entier(n / i) * i = n then
divisible := true;
i := i + 2
end;
isprime := if divisible then false else true;
end;
end;
comment - exercise the procedure;
integer i;
outstring(1,"Testing first 50 numbers for primality:\n");
for i := 1 step 1 until 50 do
if isprime(i) then
outinteger(1,i);
end
- Output:
Testing first 50 numbers for primality: 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
ALGOL 68
COMMENT This routine is used in more than one place, and is essentially a template that can by used for many different types, eg INT, LONG INT... USAGE MODE ISPRIMEINT = INT, LONG INT, etc PR READ "prelude/is_prime.a68" PR END COMMENT
PROC is prime = ( ISPRIMEINT p )BOOL: IF p <= 1 OR ( NOT ODD p AND p/= 2) THEN FALSE ELSE BOOL prime := TRUE; FOR i FROM 3 BY 2 TO ENTIER sqrt(p) WHILE prime := p MOD i /= 0 DO SKIP OD; prime FI
main:(
INT upb=100;
printf(($" The primes up to "g(-3)" are:"l$,upb));
FOR i TO upb DO
IF is prime(i) THEN
printf(($g(-4)$,i))
FI
OD;
printf($l$)
)
- Output:
The primes up to 100 are: 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
ALGOL-M
BEGIN
% RETURN P MOD Q %
INTEGER FUNCTION MOD(P, Q);
INTEGER P, Q;
BEGIN
MOD := P - Q * (P / Q);
END;
% RETURN INTEGER SQUARE ROOT OF N %
INTEGER FUNCTION ISQRT(N);
INTEGER N;
BEGIN
INTEGER R1, R2;
R1 := N;
R2 := 1;
WHILE R1 > R2 DO
BEGIN
R1 := (R1+R2) / 2;
R2 := N / R1;
END;
ISQRT := R1;
END;
% RETURN 1 IF N IS PRIME, OTHERWISE 0 %
INTEGER FUNCTION ISPRIME(N);
INTEGER N;
BEGIN
IF N = 2 THEN
ISPRIME := 1
ELSE IF (N < 2) OR (MOD(N,2) = 0) THEN
ISPRIME := 0
ELSE % TEST ODD NUMBERS UP TO SQRT OF N %
BEGIN
INTEGER I, LIMIT;
LIMIT := ISQRT(N);
I := 3;
WHILE I <= LIMIT AND MOD(N,I) <> 0 DO
I := I + 2;
ISPRIME := (IF I <= LIMIT THEN 0 ELSE 1);
END;
END;
% TEST FOR PRIMES IN RANGE 1 TO 50 %
INTEGER I;
WRITE("");
FOR I := 1 STEP 1 UNTIL 50 DO
BEGIN
IF ISPRIME(I)=1 THEN WRITEON(I," "); % WORKS FOR 80 COL SCREEN %
END;
END
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
ALGOL W
% returns true if n is prime, false otherwise %
% uses trial division %
logical procedure isPrime ( integer value n ) ;
if n < 3 or not odd( n ) then n = 2
else begin
% odd number > 2 %
integer f, rootN;
logical havePrime;
f := 3;
rootN := entier( sqrt( n ) );
havePrime := true;
while f <= rootN and havePrime do begin
havePrime := ( n rem f ) not = 0;
f := f + 2
end;
havePrime
end isPrime ;
Test program:
begin
logical procedure isPrime ( integer value n ) ; algol "isPrime" ;
for i := 0 until 32 do if isPrime( i ) then writeon( i_w := 1,s_w := 1, i )
end.
- Output:
2 3 5 7 11 13 17 19 23 29 31
APL
prime ← 2=0+.=⍳|⊣
- Output:
(⊢(/⍨)prime¨)⍳100
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
AppleScript
on isPrime(n)
if (n < 3) then return (n is 2)
if (n mod 2 is 0) then return false
repeat with i from 3 to (n ^ 0.5) div 1 by 2
if (n mod i is 0) then return false
end repeat
return true
end isPrime
-- Test code:
set output to {}
repeat with n from -7 to 100
if (isPrime(n)) then set end of output to n
end repeat
return output
Or eliminating multiples of 3 at the start as well as those of 2:
on isPrime(n)
if (n < 4) then return (n > 1)
if ((n mod 2 is 0) or (n mod 3 is 0)) then return false
repeat with i from 5 to (n ^ 0.5) div 1 by 6
if ((n mod i is 0) or (n mod (i + 2) is 0)) then return false
end repeat
return true
end isPrime
-- Test code:
set output to {}
repeat with n from -7 to 100
if (isPrime(n)) then set end of output to n
end repeat
return output
- Output:
{2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97}
ARM Assembly
/* ARM assembly Raspberry PI */
/* program testtrialprime.s */
/************************************/
/* Constantes */
/************************************/
/* for this file see task include a file in language ARM assembly*/
.include "../constantes.inc"
//.include "../../ficmacros32.inc" @ for debugging developper
/************************************/
/* Initialized data */
/************************************/
.data
szMessPrime: .asciz " is prime.\n"
szMessNotPrime: .asciz " is not prime.\n"
szCarriageReturn: .asciz "\n"
szMessStart: .asciz "Program 32 bits start.\n"
/************************************/
/* UnInitialized data */
/************************************/
.bss
sZoneConv: .skip 24
/************************************/
/* code section */
/************************************/
.text
.global main
main: @ entry of program
ldr r0,iAdrszMessStart
bl affichageMess
mov r0,#19
bl testPrime
ldr r0,iStart @ number
bl testPrime
ldr r0,iStart1 @ number
bl testPrime
100: @ standard end of the program
mov r0, #0 @ return code
mov r7, #EXIT @ request to exit program
swi 0 @ perform the system call
iAdrsZoneConv: .int sZoneConv
iAdrszMessPrime: .int szMessPrime
iAdrszMessNotPrime: .int szMessNotPrime
iAdrszCarriageReturn: .int szCarriageReturn
iAdrszMessStart: .int szMessStart
iStart: .int 2600002183
iStart1: .int 4124163031
/******************************************************************/
/* test if number is prime */
/******************************************************************/
/* r0 contains the number */
testPrime:
push {r1,r2,lr} @ save registers
mov r2,r0
ldr r1,iAdrsZoneConv
bl conversion10 @ decimal conversion
ldr r0,iAdrsZoneConv
bl affichageMess
mov r0,r2
bl isPrime
cmp r0,#0
beq 1f
ldr r0,iAdrszMessPrime
bl affichageMess
b 100f
1:
ldr r0,iAdrszMessNotPrime
bl affichageMess
100:
pop {r1,r2,pc} @ restaur registers
/******************************************************************/
/* test if number is prime */
/******************************************************************/
/* r0 contains the number */
/* r0 return 1 if prime else return 0 */
isPrime:
push {r4,lr} @ save registers
cmp r0,#1 @ <= 1 ?
movls r0,#0 @ not prime
bls 100f
cmp r0,#3 @ 2 and 3 prime
movls r0,#1
bls 100f
tst r0,#1 @ even ?
moveq r0,#0 @ not prime
beq 100f
mov r4,r0 @ save number
mov r1,#3 @ first divisor
1:
mov r0,r4 @ number
bl division
add r1,r1,#2 @ increment divisor
cmp r3,#0 @ remainder = zero ?
moveq r0,#0 @ not prime
beq 100f
cmp r1,r2 @ divisors<=quotient ?
ble 1b @ loop
mov r0,#1 @ return prime
100:
pop {r4,pc} @ restaur registers
/***************************************************/
/* ROUTINES INCLUDE */
/***************************************************/
/* for this file see task include a file in language ARM assembly*/
.include "../affichage.inc"
- Output:
Program 32 bits start. 19 is prime. 2600002183 is prime. 4124163031 is not prime.
Arturo
isPrime?: function [n][
if n=2 -> return true
if n=3 -> return true
if or? n=<1 0=n%2 -> return false
high: to :integer sqrt n
loop high..2 .step: 3 'i [
if 0=n%i -> return false
]
return true
]
loop 1..20 'i [
print ["isPrime?" i "=" isPrime? i ]
]
- Output:
isPrime? 1 = false isPrime? 2 = true isPrime? 3 = true isPrime? 4 = false isPrime? 5 = true isPrime? 6 = false isPrime? 7 = true isPrime? 8 = false isPrime? 9 = false isPrime? 10 = false isPrime? 11 = true isPrime? 12 = false isPrime? 13 = true isPrime? 14 = false isPrime? 15 = false isPrime? 16 = false isPrime? 17 = true isPrime? 18 = false isPrime? 19 = true isPrime? 20 = false
AutoHotkey
MsgBox % IsPrime(1995937)
Loop
MsgBox % A_Index-3 . " is " . (IsPrime(A_Index-3) ? "" : "not ") . "prime."
IsPrime(n,k=2) { ; testing primality with trial divisors not multiple of 2,3,5, up to sqrt(n)
d := k+(k<7 ? 1+(k>2) : SubStr("6-----4---2-4---2-4---6-----2",Mod(k,30),1))
Return n < 3 ? n>1 : Mod(n,k) ? (d*d <= n ? IsPrime(n,d) : 1) : 0
}
AutoIt
#cs ----------------------------------------------------------------------------
AutoIt Version: 3.3.8.1
Author: Alexander Alvonellos
Script Function:
Perform primality test on a given integer $number.
RETURNS: TRUE/FALSE
#ce ----------------------------------------------------------------------------
Func main()
ConsoleWrite("The primes up to 100 are: " & @LF)
For $i = 1 To 100 Step 1
If(isPrime($i)) Then
If($i <> 97) Then
ConsoleWrite($i & ", ")
Else
ConsoleWrite($i)
EndIf
EndIf
Next
EndFunc
Func isPrime($n)
If($n < 2) Then Return False
If($n = 2) Then Return True
If(BitAnd($n, 1) = 0) Then Return False
For $i = 3 To Sqrt($n) Step 2
If(Mod($n, $i) = 0) Then Return False
Next
Return True
EndFunc
main()
AWK
$ awk 'func prime(n){for(d=2;d<=sqrt(n);d++)if(!(n%d)){return 0};return 1}{print prime($1)}'
Or more legibly, and with n <= 1 handling
function prime(n) {
if (n <= 1) return 0
for (d = 2; d <= sqrt(n); d++)
if (!(n % d)) return 0
return 1
}
{print prime($1)}
B
B as on PDP7/UNIX0
isprime(n) {
auto p;
if(n<2) return(0);
if(!(n%2)) return(n==2);
p=3;
while(n/p>p) {
if(!(n%p)) return(0);
p=p+2;
}
return(1);
}
BASIC
Applesoft BASIC
100 DEF FN MOD(NUM) = NUM - INT (NUM / DIV) * DIV: REM NUM MOD DIV
110 FOR I = 1 TO 99
120 V = I: GOSUB 200"ISPRIME
130 IF ISPRIME THEN PRINT " "I;
140 NEXT I
150 END
200 ISPRIME = FALSE: IF V < 2 THEN RETURN
210 DIV = 2:ISPRIME = FN MOD(V): IF NOT ISPRIME THEN ISPRIME = V = 2: RETURN
220 LIMIT = SQR (V): IF LIMIT > = 3 THEN FOR DIV = 3 TO LIMIT STEP 2:ISPRIME = FN MOD(V): IF ISPRIME THEN NEXT DIV
230 RETURN
BASIC256
for i = 1 to 99
if isPrime(i) then print string(i); " ";
next i
end
function isPrime(v)
if v < 2 then return False
if v mod 2 = 0 then return v = 2
if v mod 3 = 0 then return v = 3
d = 5
while d * d <= v
if v mod d = 0 then return False else d += 2
end while
return True
end function
BBC BASIC
FOR i% = -1 TO 100
IF FNisprime(i%) PRINT ; i% " is prime"
NEXT
END
DEF FNisprime(n%)
IF n% <= 1 THEN = FALSE
IF n% <= 3 THEN = TRUE
IF (n% AND 1) = 0 THEN = FALSE
LOCAL t%
FOR t% = 3 TO SQR(n%) STEP 2
IF n% MOD t% = 0 THEN = FALSE
NEXT
= TRUE
- Output:
2 is prime 3 is prime 5 is prime 7 is prime 11 is prime 13 is prime 17 is prime 19 is prime 23 is prime 29 is prime 31 is prime 37 is prime 41 is prime 43 is prime 47 is prime 53 is prime 59 is prime 61 is prime 67 is prime 71 is prime 73 is prime 79 is prime 83 is prime 89 is prime 97 is prime
Craft Basic
for i = 1 to 50
if i < 2 then
let p = 0
else
if i = 2 then
let p = 1
else
if i % 2 = 0 then
let p = 0
else
let p = 1
for j = 3 to int(i ^ .5) step 2
if i % j = 0 then
let p = 0
break j
endif
wait
next j
endif
endif
endif
if p <> 0 then
print i
endif
next i
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
FBSL
The second function (included by not used) I would have thought would be faster because it lacks the SQR() function. As it happens, the first is over twice as fast.
#APPTYPE CONSOLE
FUNCTION ISPRIME(n AS INTEGER) AS INTEGER
IF n = 2 THEN
RETURN TRUE
ELSEIF n <= 1 ORELSE n MOD 2 = 0 THEN
RETURN FALSE
ELSE
FOR DIM i = 3 TO SQR(n) STEP 2
IF n MOD i = 0 THEN
RETURN FALSE
END IF
NEXT
RETURN TRUE
END IF
END FUNCTION
FUNCTION ISPRIME2(N AS INTEGER) AS INTEGER
IF N <= 1 THEN RETURN FALSE
DIM I AS INTEGER = 2
WHILE I * I <= N
IF N MOD I = 0 THEN
RETURN FALSE
END IF
I = I + 1
WEND
RETURN TRUE
END FUNCTION
' Test and display primes 1 .. 50
DIM n AS INTEGER
FOR n = 1 TO 50
IF ISPRIME(n) THEN
PRINT n, " ";
END IF
NEXT
PAUSE
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 Press any key to continue...
FreeBASIC
' FB 1.05.0 Win64
Function isPrime(n As Integer) As Boolean
If n < 2 Then Return False
If n = 2 Then Return True
If n Mod 2 = 0 Then Return False
Dim limit As Integer = Sqr(n)
For i As Integer = 3 To limit Step 2
If n Mod i = 0 Then Return False
Next
Return True
End Function
' To test this works, print all primes under 100
For i As Integer = 1 To 99
If isPrime(i) Then
Print Str(i); " ";
End If
Next
Print : Print
Print "Press any key to quit"
Sleep
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
FutureBasic
window 1, @"Primality By Trial Division", (0,0,480,270)
local fn isPrime( n as long ) as Boolean
long i
Boolean result
if n < 2 then result = NO : exit fn
if n = 2 then result = YES : exit fn
if n mod 2 == 0 then result = NO : exit fn
result = YES
for i = 3 to int( n^.5 ) step 2
if n mod i == 0 then result = NO : break
next i
end fn = result
long i, j = 0
print "Prime numbers between 0 and 1000:"
for i = 0 to 1000
if ( fn isPrime(i) != _false )
printf @"%3d\t",i : j++
if j mod 10 == 0 then print
end if
next
HandleEvents
- Output:
Prime numbers between 0 and 1000: 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157 163 167 173 179 181 191 193 197 199 211 223 227 229 233 239 241 251 257 263 269 271 277 281 283 293 307 311 313 317 331 337 347 349 353 359 367 373 379 383 389 397 401 409 419 421 431 433 439 443 449 457 461 463 467 479 487 491 499 503 509 521 523 541 547 557 563 569 571 577 587 593 599 601 607 613 617 619 631 641 643 647 653 659 661 673 677 683 691 701 709 719 727 733 739 743 751 757 761 769 773 787 797 809 811 821 823 827 829 839 853 857 859 863 877 881 883 887 907 911 919 929 937 941 947 953 967 971 977 983 991 997
Gambas
Click this link to run this code
'Reworked from the BBC Basic example
Public Sub Main()
Dim iNum As Integer
For iNum = 1 To 100
If FNisprime(iNum) Then Print iNum & " is prime"
Next
End
'___________________________________________________
Public Sub FNisprime(iNum As Integer) As Boolean
Dim iLoop As Integer
Dim bReturn As Boolean = True
If iNum <= 1 Then bReturn = False
If iNum <= 3 Then bReturn = True
If (iNum And 1) = 0 Then bReturn = False
For iLoop = 3 To Sqr(iNum) Step 2
If iNum Mod iLoop = 0 Then bReturn = False
Next
Return bReturn
End
- Output:
1 is prime 3 is prime 5 is prime 7 is prime 11 is prime ...... 73 is prime 79 is prime 83 is prime 89 is prime 97 is prime
GW-BASIC
100 FOR I = 1 TO 99
110 IF I < 2 THEN P = 0 : GOTO 180
120 IF I = 2 THEN P = 1 : GOTO 180
130 IF I MOD 2 = 0 THEN P = 0 : GOTO 180
140 P = 1
150 FOR J = 3 TO SQR(I) STEP 2
160 IF I MOD J = 0 THEN P = 0 : GOTO 180
170 NEXT J
180 IF P <> 0 THEN PRINT I;
190 NEXT I
200 END
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
IS-BASIC
100 PROGRAM "Prime.bas"
110 FOR X=0 TO 100
120 IF PRIME(X) THEN PRINT X;
130 NEXT
140 DEF PRIME(N)
150 IF N=2 THEN
160 LET PRIME=-1
170 ELSE IF N<=1 OR MOD(N,2)=0 THEN
180 LET PRIME=0
190 ELSE
200 LET PRIME=-1
210 FOR I=3 TO CEIL(SQR(N)) STEP 2
220 IF MOD(N,I)=0 THEN LET PRIME=0:EXIT FOR
230 NEXT
240 END IF
250 END DEF
Liberty BASIC
print "Rosetta Code - Primality by trial division"
print
[start]
input "Enter an integer: "; x
if x=0 then print "Program complete.": end
if isPrime(x) then print x; " is prime" else print x; " is not prime"
goto [start]
function isPrime(p)
p=int(abs(p))
if p=2 then isPrime=1: exit function 'prime
if p=0 or p=1 or (p mod 2)=0 then exit function 'not prime
for i=3 to sqr(p) step 2
if (p mod i)=0 then exit function 'not prime
next i
isPrime=1
end function
- Output:
Rosetta Code - Primality by trial division Enter an integer: 1 1 is not prime Enter an integer: 2 2 is prime Enter an integer: Program complete.
PureBasic
Procedure.i IsPrime(n)
Protected k
If n = 2
ProcedureReturn #True
EndIf
If n <= 1 Or n % 2 = 0
ProcedureReturn #False
EndIf
For k = 3 To Int(Sqr(n)) Step 2
If n % k = 0
ProcedureReturn #False
EndIf
Next
ProcedureReturn #True
EndProcedure
QuickBASIC
Returns 1 for prime, 0 for non-prime
' Primality by trial division
' Test and display primes 1 .. 50
DECLARE FUNCTION prime% (n!)
FOR n = 1 TO 50
IF prime(n) = 1 THEN PRINT n;
NEXT n
FUNCTION prime% (n!)
STATIC i AS INTEGER
IF n = 2 THEN
prime = 1
ELSEIF n <= 1 OR n MOD 2 = 0 THEN
prime = 0
ELSE
prime = 1
FOR i = 3 TO INT(SQR(n)) STEP 2
IF n MOD i = 0 THEN
prime = 0
EXIT FUNCTION
END IF
NEXT i
END IF
END FUNCTION
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
Run BASIC
' Test and display primes 1 .. 50
for i = 1 TO 50
if prime(i) <> 0 then print i;" ";
next i
FUNCTION prime(n)
if n < 2 then prime = 0 : goto [exit]
if n = 2 then prime = 1 : goto [exit]
if n mod 2 = 0 then prime = 0 : goto [exit]
prime = 1
for i = 3 to int(n^.5) step 2
if n mod i = 0 then prime = 0 : goto [exit]
next i
[exit]
END FUNCTION
- Output:
2 3 5 7 11 13 17 19 23 25 29 31 37 41 43 47
S-BASIC
$lines
$constant FALSE = 0
$constant TRUE = 0FFFFH
rem - return p mod q
function mod(p, q = integer) = integer
end = p - q * (p / q)
rem - return true (-1) if n is prime, otherwise false (0)
function isprime(n = integer) = integer
var i, limit, result = integer
if n = 2 then
result = TRUE
else if (n < 2) or (mod(n,2) = 0) then
result = FALSE
else
begin
limit = int(sqr(n))
i = 3
while (i <= limit) and (mod(n, i) <> 0) do
i = i + 2
result = not (i <= limit)
end
end = result
rem - test by looking for primes in range 1 to 50
var i = integer
for i = 1 to 50
if isprime(i) then print using "#####";i;
next i
end
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
TI-83 BASIC
Prompt A If A=2:Then Disp "PRIME" Stop End If (fPart(A/2)=0 and A>0) or A<2:Then Disp "NOT PRIME" Stop End 1→P For(B,3,int(√(A))) If FPart(A/B)=0:Then 0→P √(A)→B End B+1→B End If P=1:Then Disp "PRIME" Else Disp "NOT PRIME" End
Tiny BASIC
10 REM Primality by trial division
20 PRINT "Enter a number "
30 INPUT P
40 GOSUB 1000
50 IF Z = 1 THEN PRINT "It is prime."
60 IF Z = 0 THEN PRINT "It is not prime."
70 END
990 REM Primality of the number P by trial division
1000 IF P < 2 THEN RETURN
1010 LET Z = 1
1020 IF P < 4 THEN RETURN
1030 LET I = 2
1040 IF (P / I) * I = P THEN LET Z = 0
1050 IF Z = 0 THEN RETURN
1060 LET I = I + 1
1070 IF I * I <= P THEN GOTO 1040
1080 RETURN
True BASIC
FUNCTION isPrime (n)
IF n = 2 THEN
LET isPrime = 1
ELSEIF n <= 1 OR REMAINDER(n, 2) = 0 THEN
LET isPrime = 0
ELSE
LET isPrime = 1
FOR i = 3 TO INT(SQR(n)) STEP 2
IF REMAINDER(n, i) = 0 THEN
LET isPrime = 0
EXIT FUNCTION
END IF
NEXT i
END IF
END FUNCTION
FOR n = 1 TO 50
IF isPrime(n) = 1 THEN PRINT n;
NEXT n
END
uBasic/4tH
10 LET n=0: LET p=0
20 INPUT "Enter number: ";n
30 LET p=0 : IF n>1 THEN GOSUB 1000
40 IF p=0 THEN PRINT n;" is not prime!"
50 IF p#0 THEN PRINT n;" is prime!"
60 GOTO 10
1000 REM ***************
1001 REM * PRIME CHECK *
1002 REM ***************
1010 LET p=0
1020 IF (n%2)=0 THEN RETURN
1030 LET p=1 : PUSH n,0 : GOSUB 9030
1040 FOR i=3 TO POP() STEP 2
1050 IF (n%i)=0 THEN LET p=0: PUSH n,0 : GOSUB 9030 : LET i=POP()
1060 NEXT i
1070 RETURN
9030 Push ((10^(Pop()*2))*Pop()) : @(255)=Tos()
9040 Push (@(255) + (Tos()/@(255)))/2
If Abs(@(255)-Tos())<2 Then @(255)=Pop() : If Pop() Then Push @(255) : Return
@(255) = Pop() : Goto 9040
REM ** This is an integer SQR subroutine. Output is scaled by 10^(TOS()).
VBA
Option Explicit
Sub FirstTwentyPrimes()
Dim count As Integer, i As Long, t(19) As String
Do
i = i + 1
If IsPrime(i) Then
t(count) = i
count = count + 1
End If
Loop While count <= UBound(t)
Debug.Print Join(t, ", ")
End Sub
Function IsPrime(Nb As Long) As Boolean
If Nb = 2 Then
IsPrime = True
ElseIf Nb < 2 Or Nb Mod 2 = 0 Then
Exit Function
Else
Dim i As Long
For i = 3 To Sqr(Nb) Step 2
If Nb Mod i = 0 Then Exit Function
Next
IsPrime = True
End If
End Function
- Output:
2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71
VBScript
Function IsPrime(n)
If n = 2 Then
IsPrime = True
ElseIf n <= 1 Or n Mod 2 = 0 Then
IsPrime = False
Else
IsPrime = True
For i = 3 To Int(Sqr(n)) Step 2
If n Mod i = 0 Then
IsPrime = False
Exit For
End If
Next
End If
End Function
For n = 1 To 50
If IsPrime(n) Then
WScript.StdOut.Write n & " "
End If
Next
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
Yabasic
for i = 1 to 99
if isPrime(i) print str$(i), " ";
next i
print
end
sub isPrime(v)
if v < 2 return False
if mod(v, 2) = 0 return v = 2
if mod(v, 3) = 0 return v = 3
d = 5
while d * d <= v
if mod(v, d) = 0 then return False else d = d + 2 : fi
wend
return True
end sub
ZX Spectrum Basic
10 LET n=0: LET p=0
20 INPUT "Enter number: ";n
30 IF n>1 THEN GO SUB 1000
40 IF p=0 THEN PRINT n;" is not prime!"
50 IF p<>0 THEN PRINT n;" is prime!"
60 GO TO 10
1000 REM ***************
1001 REM * PRIME CHECK *
1002 REM ***************
1010 LET p=0
1020 IF n/2=INT (n/2) THEN RETURN
1030 LET p=1
1040 FOR i=3 TO SQR (n) STEP 2
1050 IF n/i=INT (n/i) THEN LET p=0: LET i= SQR (n)
1060 NEXT i
1070 RETURN
- Output:
15 is not prime! 17 is prime! 119 is not prime! 137 is prime!
bc
/* Return 1 if n is prime, 0 otherwise */
define p(n) {
auto i
if (n < 2) return(0)
if (n == 2) return(1)
if (n % 2 == 0) return(0)
for (i = 3; i * i <= n; i += 2) {
if (n % i == 0) return(0)
}
return(1)
}
BCPL
get "libhdr"
let sqrt(s) =
s <= 1 -> 1,
valof
$( let x0 = s >> 1
let x1 = (x0 + s/x0) >> 1
while x1 < x0
$( x0 := x1
x1 := (x0 + s/x0) >> 1
$)
resultis x0
$)
let isprime(n) =
n < 2 -> false,
(n & 1) = 0 -> n = 2,
valof
$( for i = 3 to sqrt(n) by 2
if n rem i = 0 resultis false
resultis true
$)
let start() be
$( for i=1 to 100
if isprime(i) then writef("%N ",i)
wrch('*N')
$)
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
Befunge
Reads the value to test from stdin and outputs Yes if prime and No if not.
To avoid dealing with Befunge's limited data cells, the implementation is entirely stack-based. However, this requires compressing multiple values into a single stack cell, which imposes an upper limit of 1,046,529 (10232), thus a maximum testable prime of 1,046,527.
&>:48*:** \1`!#^_2v
v_v#`\*:%*:*84\/*:*84::+<
v >::48*:*/\48*:*%%!#v_1^
>0"seY" >:#,_@#: "No">#0<
- Output:
(multiple runs)
0 No 17 Yes 49 No 97 Yes 1042441 No 1046527 Yes
Bracmat
( prime
= incs n I inc
. 4 2 4 2 4 6 2 6:?incs
& 2:?n
& 1 2 2 !incs:?I
& whl
' ( !n*!n:~>!arg
& div$(!arg.!n)*!n:~!arg
& (!I:%?inc ?I|!incs:%?inc ?I)
& !n+!inc:?n
)
& !n*!n:>!arg
)
& 100000000000:?p
& whl
' ( !p+1:<100000000100:?p
& ( prime$!p
& out$!p
|
)
)
& ;
- Output:
100000000003 100000000019 100000000057 100000000063 100000000069 100000000073 100000000091
Brainf***
>->,[.>,]>-<++++++[-<+[---------<+]->+[->+]-<]>+<-<+[-<+]>>+[-<[->++++++++++<]>>
+]++++[->++++++++<]>.<+++++++[->++++++++++<]>+++.++++++++++.<+++++++++[->-------
--<]>--.[-]<<<->[->+>+<<]>>-[+<[[->>+>>+<<<<]>>[-<<+>>]<]>>[->-[>+>>]>[+[-<+>]>>
>]<<<<<]>[-]>[>+>]<<[-]+[-<+]->>>--]<[->+>+<<]>>>>>>>[-<<<<<->>>>>]<<<<<--[>++++
++++++[->+++++++++++<]>.+.+++++.>++++[->++++++++<]>.>]++++++++++[->+++++++++++<]
>++.++.---------.++++.--------.>++++++++++.
Explanation:
>
->,[.>,]>-<++++++[-<+[---------<+]->+[->+]-<]>+<-<+[-<+]>>+[-<[->++++++++++<]>>+]< takes input
>++++[->++++++++<]>.<+++++++[->++++++++++<]>+++.++++++++++.<+++++++++[->---------<]>--.[-]<< " is "
<->
[->+>+<<]>>-[+<[[->>+>>+<<<<]>>[-<<+>>]<]>>[->-[>+>>]>[+[-<+>]>>>]<<<<<]>[-]>[>+>]<<[-]+[-<+]->>>--] finds # of divisors from 1 to n
<[->+>+<<]>>>>>>>[-<<<<<->>>>>]<<<<<--
[>++++++++++[->+++++++++++<]>.+.+++++.>++++[->++++++++<]>.>] "not "
++++++++++[->+++++++++++<]>++.++.---------.++++.--------.>++++++++++. "prime" new line
Will format as "# is/is not prime", naturally limited by cell size.
Burlesque
fcL[2==
Implicit trial division is done by the fc function. It checks if the number has exactly two divisors.
Version not using the fc function:
blsq ) 11^^2\/?dr@.%{0==}ayn!
1
blsq ) 12^^2\/?dr@.%{0==}ayn!
0
blsq ) 13^^2\/?dr@.%{0==}ayn!
1
Explanation. Given n generates a block containing 2..n-1. Calculates a block of modolus and check if it contains 0. If it contains 0 it is not a prime.
C
int is_prime(unsigned int n)
{
unsigned int p;
if (!(n & 1) || n < 2 ) return n == 2;
/* comparing p*p <= n can overflow */
for (p = 3; p <= n/p; p += 2)
if (!(n % p)) return 0;
return 1;
}
C#
static bool isPrime(int n)
{
if (n <= 1) return false;
for (int i = 2; i * i <= n; i++)
if (n % i == 0) return false;
return true;
}
C++
#include <cmath>
bool is_prime(unsigned int n)
{
if (n <= 1)
return false;
if (n == 2)
return true;
for (unsigned int i = 2; i <= sqrt(n); ++i)
if (n % i == 0)
return false;
return true;
}
Chapel
proc is_prime(n)
{
if n == 2 then
return true;
if n <= 1 || n % 2 == 0 then
return false;
for i in 3..floor(sqrt(n)):int by 2 do
if n % i == 0 then
return false;
return true;
}
Clojure
The function used in both versions:
(defn divides? [k n] (zero? (mod k n)))
Testing divisors are in range from 3 to √ n with step 2:
(defn prime? [x]
(or (= 2 x)
(and (< 1 x)
(odd? x)
(not-any? (partial divides? x)
(range 3 (inc (Math/sqrt x)) 2)))))
Testing only prime divisors:
(declare prime?)
(def primes (filter prime? (range)))
(defn prime? [x]
(and (integer? x)
(< 1 x)
(not-any? (partial divides? x)
(take-while (partial >= (Math/sqrt x)) primes))))
CLU
isqrt = proc (s: int) returns (int)
x0: int := s/2
if x0=0 then return(s) end
x1: int := (x0 + s/x0)/2
while x1 < x0 do
x0 := x1
x1 := (x0 + s/x0)/2
end
return(x0)
end isqrt
prime = proc (n: int) returns (bool)
if n<=2 then return(n=2) end
if n//2=0 then return(false) end
for d: int in int$from_to_by(3,isqrt(n),2) do
if n//d=0 then return(false) end
end
return(true)
end prime
start_up = proc ()
po: stream := stream$primary_input()
for i: int in int$from_to(1,100) do
if prime(i) then
stream$puts(po, int$unparse(i) || " ")
end
end
end start_up
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
CMake
# Prime predicate: does n be a prime number? Sets var to true or false.
function(primep var n)
if(n GREATER 2)
math(EXPR odd "${n} % 2")
if(odd)
# n > 2 and n is odd.
set(factor 3)
# Loop for odd factors from 3, while factor <= n / factor.
math(EXPR quot "${n} / ${factor}")
while(NOT factor GREATER quot)
math(EXPR rp "${n} % ${factor}") # Trial division
if(NOT rp)
# factor divides n, so n is not prime.
set(${var} false PARENT_SCOPE)
return()
endif()
math(EXPR factor "${factor} + 2") # Next odd factor
math(EXPR quot "${n} / ${factor}")
endwhile(NOT factor GREATER quot)
# Loop found no factor, so n is prime.
set(${var} true PARENT_SCOPE)
else()
# n > 2 and n is even, so n is not prime.
set(${var} false PARENT_SCOPE)
endif(odd)
elseif(n EQUAL 2)
set(${var} true PARENT_SCOPE) # 2 is prime.
else()
set(${var} false PARENT_SCOPE) # n < 2 is not prime.
endif()
endfunction(primep)
# Quick example.
foreach(i -5 1 2 3 37 39)
primep(b ${i})
if(b)
message(STATUS "${i} is prime.")
else()
message(STATUS "${i} is _not_ prime.")
endif(b)
endforeach(i)
COBOL
Identification Division.
Program-Id. Primality-By-Subdiv.
Data Division.
Working-Storage Section.
78 True-Val Value 0.
78 False-Val Value 1.
Local-Storage Section.
01 lim Pic 9(10).
01 i Pic 9(10).
Linkage Section.
01 num Pic 9(10).
01 result Pic 9.
Procedure Division Using num result.
Main.
If num <= 1
Move False-Val To result
Goback
Else If num = 2
Move True-Val To result
Goback
End-If
Compute lim = Function Sqrt(num) + 1
Perform Varying i From 3 By 1 Until lim < i
If Function Mod(num, i) = 0
Move False-Val To result
Goback
End-If
End-Perform
Move True-Val To Result
Goback
.
CoffeeScript
is_prime = (n) ->
# simple prime detection using trial division, works
# for all integers
return false if n <= 1 # by definition
p = 2
while p * p <= n
return false if n % p == 0
p += 1
true
for i in [-1..100]
console.log i if is_prime i
Common Lisp
(defun primep (n)
"Is N prime?"
(and (> n 1)
(or (= n 2) (oddp n))
(loop for i from 3 to (isqrt n) by 2
never (zerop (rem n i)))))
Alternate solution
I use Allegro CL 10.1
;; Project : Primality by trial division
(defun prime(n)
(setq flag 0)
(loop for i from 2 to (- n 1) do
(if (= (mod n i) 0)
(setq flag 1)))
(if (= flag 0)
(format t "~d is a prime number" n)
(format t "~d is not a prime number" n)))
(prime 7)
(prime 8)
Output:
7 is a prime number 8 is not a prime number
Cowgol
include "cowgol.coh";
sub prime(n: uint32): (isprime: uint8) is
isprime := 1;
if n < 2 then
isprime := 0;
return;
end if;
if n & 1 == 0 then
if n != 2 then
isprime := 0;
end if;
return;
end if;
var factor: uint32 := 3;
while factor * factor <= n loop
if n % factor == 0 then
isprime := 0;
return;
end if;
factor := factor + 2;
end loop;
end sub;
var i: uint32 := 0;
while i <= 100 loop
if prime(i) != 0 then
print_i32(i);
print_nl();
end if;
i := i + 1;
end loop;
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
Crystal
Mathematicaly basis of Prime Generators https://www.academia.edu/19786419/PRIMES-UTILS_HANDBOOK https://www.academia.edu/42734410/Improved_Primality_Testing_and_Factorization_in_Ruby_revised
require "big"
require "benchmark"
# the simplest PG primality test using the P3 prime generator
# reduces the number space for primes to 2/6 (33.33%) of all integers
def primep3?(n) # P3 Prime Generator primality test
# P3 = 6*k + {5, 7} # P3 primes candidates (pc) sequence
n = n.to_big_i
return n | 1 == 3 if n < 5 # n: 0,1,4|false, 2,3|true
return false if n.gcd(6) != 1 # 1/3 (2/6) of integers are P3 pc
p = typeof(n).new(5) # first P3 sequence value
until p > isqrt(n)
return false if n % p == 0 || n % (p + 2) == 0 # if n is composite
p += 6 # first prime candidate for next kth residues group
end
true
end
# PG primality test using the P5 prime generator
# reduces the number space for primes to 8/30 (26.67%) of all integers
def primep5?(n) # P5 Prime Generator primality test
# P5 = 30*k + {7,11,13,17,19,23,29,31} # P5 primes candidates sequence
n = n.to_big_i
return [2, 3, 5].includes?(n) if n < 7 # for small and negative values
return false if n.gcd(30) != 1 # 4/15 (8/30) of integers are P5 pc
p = typeof(n).new(7) # first P5 sequence value
until p > isqrt(n)
return false if # if n is composite
n % (p) == 0 || n % (p+4) == 0 || n % (p+6) == 0 || n % (p+10) == 0 ||
n % (p+12) == 0 || n % (p+16) == 0 || n % (p+22) == 0 || n % (p+24) == 0
p += 30 # first prime candidate for next kth residues group
end
true
end
# PG primality test using the P7 prime generator
# reduces the number space for primes to 48/210 (22.86%) of all integers
def primep7?(n)
# P7 = 210*k + {11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,
# 89,97,101,103,107,109,113,121,127,131,137,139,143,149,151,157,163,
# 167,169,173,179,181,187,191,193,197,199,209,211}
n = n.to_big_i
return [2, 3, 5, 7].includes?(n) if n < 11
return false if n.gcd(210) != 1 # 8/35 (48/210) of integers are P7 pc
p = typeof(n).new(11) # first P7 sequence value
until p > isqrt(n)
return false if
n % (p) == 0 || n % (p+2) == 0 || n % (p+6) == 0 || n % (p+8) == 0 ||
n % (p+12) == 0 || n % (p+18) == 0 || n % (p+20) == 0 || n % (p+26) == 0 ||
n % (p+30) == 0 || n % (p+32) == 0 || n % (p+36) == 0 || n % (p+42) == 0 ||
n % (p+48) == 0 || n % (p+50) == 0 || n % (p+56) == 0 || n % (p+60) == 0 ||
n % (p+62) == 0 || n % (p+68) == 0 || n % (p+72) == 0 || n % (p+78) == 0 ||
n % (p+86) == 0 || n % (p+90) == 0 || n % (p+92) == 0 || n % (p+96) == 0 ||
n % (p+98) == 0 || n % (p+102) == 0 || n % (p+110) == 0 || n % (p+116) == 0 ||
n % (p+120) == 0 || n % (p+126) == 0 || n % (p+128) == 0 || n % (p+132) == 0 ||
n % (p+138) == 0 || n % (p+140) == 0 || n % (p+146) == 0 || n % (p+152) == 0 ||
n % (p+156) == 0 || n % (p+158) == 0 || n % (p+162) == 0 || n % (p+168) == 0 ||
n % (p+170) == 0 || n % (p+176) == 0 || n % (p+180) == 0 || n % (p+182) == 0 ||
n % (p+186) == 0 || n % (p+188) == 0 || n % (p+198) == 0 || n % (p+200) == 0
p += 210 # first prime candidate for next kth residues group
end
true
end
# Newton's method for integer squareroot
def isqrt(n)
raise ArgumentError.new "Input must be non-negative integer" if n < 0
return n if n < 2
bits = n.bit_length
one = typeof(n).new(1) # value 1 of type self
x = one << ((bits - 1) >> 1) | n >> ((bits >> 1) + 1)
while (t = n // x) < x; x = (x + t) >> 1 end
x # output is same integer class as input
end
# Benchmarks to test for various size primes
p = 541
Benchmark.ips do |b|
print "\np = #{p}"
b.report("primep3?") { primep3?(p) }
b.report("primep5?") { primep5?(p) }
b.report("primep7?") { primep7?(p) }
puts
end
p = 1000003
Benchmark.ips do |b|
print "\np = #{p}"
b.report("primep3?") { primep3?(p) }
b.report("primep5?") { primep5?(p) }
b.report("primep7?") { primep7?(p) }
puts
end
p = 2147483647i32 # largest I32 prime
Benchmark.ips do |b|
print "\np = #{p}"
b.report("primep3?") { primep3?(p) }
b.report("primep5?") { primep5?(p) }
b.report("primep7?") { primep7?(p) }
puts
end
p = 4294967291u32 # largest U32 prime
Benchmark.ips do |b|
print "\np = #{p}"
b.report("primep3?") { primep3?(p) }
b.report("primep5?") { primep5?(p) }
b.report("primep7?") { primep7?(p) }
puts
end
p = 4294967311 # first prime > 2**32
Benchmark.ips do |b|
print "\np = #{p}"
b.report("primep3?") { primep3?(p) }
b.report("primep5?") { primep5?(p) }
b.report("primep7?") { primep7?(p) }
puts
end
- Output:
p = 541 primep3? 290.17k ( 3.45µs) (± 2.76%) 1.35kB/op 1.64× slower primep5? 476.47k ( 2.10µs) (± 1.75%) 802B/op fastest primep7? 128.44k ( 7.79µs) (± 2.82%) 2.66kB/op 3.71× slower p = 1000003 primep3? 11.24k ( 88.97µs) (± 2.34%) 33.9kB/op 2.48× slower primep5? 21.91k ( 45.64µs) (± 2.88%) 16.6kB/op 1.27× slower primep7? 27.83k ( 35.94µs) (± 2.68%) 11.9kB/op fastest p = 2147483647 primep3? 105.11 ( 9.51ms) (± 3.25%) 3.89MB/op 5.56× slower primep5? 317.49 ( 3.15ms) (± 2.40%) 1.2MB/op 1.84× slower primep7? 584.92 ( 1.71ms) (± 3.09%) 591kB/op fastest p = 4294967291 primep3? 168.56 ( 5.93ms) (± 2.39%) 2.17MB/op 2.69× slower primep5? 349.24 ( 2.86ms) (± 2.86%) 1.03MB/op 1.30× slower primep7? 454.08 ( 2.20ms) (± 2.62%) 739kB/op fastest p = 4294967311 primep3? 84.61 ( 11.82ms) (± 2.35%) 4.68MB/op 5.02× slower primep5? 248.62 ( 4.02ms) (± 2.21%) 1.54MB/op 1.71× slower primep7? 424.61 ( 2.36ms) (± 2.73%) 813kB/op fastest
D
Simple Version
import std.stdio, std.algorithm, std.range, std.math;
bool isPrime1(T)(in T n) pure nothrow {
if (n == 2)
return true;
if (n <= 1 || (n & 1) == 0)
return false;
for(T i = 3; i <= real(n).sqrt; i += 2)
if (n % i == 0)
return false;
return true;
}
void main() {
iota(2, 40).filter!isPrime1.writeln;
}
- Output:
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37]
Version with excluded multiplies of 2 and 3
Same output.
bool isPrime2(It)(in It n) pure nothrow {
// Adapted from: http://www.devx.com/vb2themax/Tip/19051
// Test 1, 2, 3 and multiples of 2 and 3:
if (n == 2 || n == 3)
return true;
else if (n < 2 || n % 2 == 0 || n % 3 == 0)
return false;
// We can now avoid to consider multiples of 2 and 3. This
// can be done really simply by starting at 5 and
// incrementing by 2 and 4 alternatively, that is:
// 5, 7, 11, 13, 17, 19, 23, 25, 29, 31, 35, 37, ...
// We don't need to go higher than the square root of the n.
for (It div = 5, inc = 2; div ^^ 2 <= n; div += inc, inc = 6 - inc)
if (n % div == 0)
return false;
return true;
}
void main() {
import std.stdio, std.algorithm, std.range;
iota(2, 40).filter!isPrime2.writeln;
}
Two Way Test
Odd divisors is generated both from increasing and decreasing sequence, may improve performance for numbers that have large minimum factor. Same output.
import std.stdio, std.algorithm, std.range, std.math;
bool isPrime3(T)(in T n) pure nothrow {
if (n % 2 == 0 || n <= 1)
return n == 2;
T head = 3, tail = (cast(T)real(n).sqrt / 2) * 2 + 1;
for ( ; head <= tail ; head +=2, tail -= 2)
if ((n % head) == 0 || (n % tail) == 0)
return false;
return true;
}
void main() {
iota(2, 40).filter!isPrime3.writeln;
}
Dart
import 'dart:math';
bool isPrime(int n) {
if (n <= 1) return false;
if (n == 2) return true;
for (int i = 2; i <= sqrt(n); ++i) if (n % i == 0) return false;
return true;
}
void main() {
for (int i = 1; i <= 99; ++i) if (isPrime(i)) print('$i ');
}
Delphi
First
function IsPrime(aNumber: Integer): Boolean;
var
I: Integer;
begin
Result:= True;
if(aNumber = 2) then Exit;
Result:= not ((aNumber mod 2 = 0) or
(aNumber <= 1));
if not Result then Exit;
for I:=3 to Trunc(Sqrt(aNumber)) do
if(aNumber mod I = 0) then
begin
Result:= False;
Break;
end;
end;
Second
function IsPrime(const x: integer): Boolean;
var
i: integer;
begin
i := 2;
repeat
if X mod i = 0 then
begin
Result := False;
Exit;
end;
Inc(i);
until i > Sqrt(x);
Result := True;
end;
Draco
proc prime(word n) bool:
word factor;
bool composite;
if n<=4 then
n=2 or n=3
elif n&1 = 0 then
false
else
factor := 3;
composite := false;
while not composite and factor*factor <= n do
composite := n % factor = 0;
factor := factor + 2
od;
not composite
fi
corp
proc main() void:
word i;
for i from 0 upto 100 do
if prime(i) then
writeln(i)
fi
od
corp
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
E
def isPrime(n :int) {
if (n == 2) {
return true
} else if (n <= 1 || n %% 2 == 0) {
return false
} else {
def limit := (n :float64).sqrt().ceil()
var divisor := 1
while ((divisor += 2) <= limit) {
if (n %% divisor == 0) {
return false
}
}
return true
}
}
EasyLang
func isprim n .
if n < 2
return 0
.
if n mod 2 = 0 and n > 2
return 0
.
i = 3
sq = sqrt n
while i <= sq
if n mod i = 0
return 0
.
i += 2
.
return 1
.
print isprim 1995937
EchoLisp
(lib 'sequences)
;; Try divisors iff n = 2k + 1
(define (is-prime? p)
(cond
[(< p 2) #f]
[(zero? (modulo p 2)) (= p 2)]
[else
(for/and ((d [3 5 .. (1+ (sqrt p))] )) (!zero? (modulo p d)))]))
(filter is-prime? (range 1 100))
→ (2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97)
;; Improve performance , try divisors iff n = 6k+1 or n = 6k+5
(define (is-prime? p)
(cond
[(< p 2) #f]
[(zero? (modulo p 2)) (= p 2)]
[(zero? (modulo p 3)) (= p 3)]
[(zero? (modulo p 5)) (= p 5)]
[else ;; step 6 : try divisors 6n+1 or 6n+5
(for ((d [7 13 .. (1+ (sqrt p))] ))
#:break (zero? (modulo p d)) => #f
#:break (zero? (modulo p (+ d 4))) => #f
#t )]))
(filter is-prime? (range 1 100))
→ (2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97)
Eiffel
class
APPLICATION
create
make
feature
make
-- Tests the feature is_prime.
do
io.put_boolean (is_prime (1))
io.new_line
io.put_boolean (is_prime (2))
io.new_line
io.put_boolean (is_prime (3))
io.new_line
io.put_boolean (is_prime (4))
io.new_line
io.put_boolean (is_prime (97))
io.new_line
io.put_boolean (is_prime (15589))
io.new_line
end
is_prime (n: INTEGER): BOOLEAN
-- Is 'n' a prime number?
require
positiv_input: n > 0
local
i: INTEGER
max: REAL_64
math: DOUBLE_MATH
do
create math
if n = 2 then
Result := True
elseif n <= 1 or n \\ 2 = 0 then
Result := False
else
Result := True
max := math.sqrt (n)
from
i := 3
until
i > max
loop
if n \\ i = 0 then
Result := False
end
i := i + 2
end
end
end
end
False True True False True False
Elixir
defmodule RC do
def is_prime(2), do: true
def is_prime(n) when n<2 or rem(n,2)==0, do: false
def is_prime(n), do: is_prime(n,3)
def is_prime(n,k) when n<k*k, do: true
def is_prime(n,k) when rem(n,k)==0, do: false
def is_prime(n,k), do: is_prime(n,k+2)
end
IO.inspect for n <- 1..50, RC.is_prime(n), do: n
- Output:
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47]
Emacs Lisp
(defun prime (a)
(not (or (< a 2)
(cl-loop for x from 2 to (sqrt a)
when (zerop (% a x))
return t))))
More concise, a little bit faster:
(defun prime2 (a)
(and (> a 1)
(cl-loop for x from 2 to (sqrt a)
never (zerop (% a x)))))
A little bit faster:
(defun prime3 (a)
(and (> a 1)
(or (= a 2) (cl-oddp a))
(cl-loop for x from 3 to (sqrt a) by 2
never (zerop (% a x)))))
More than 2 times faster, than the previous, doesn't use loop macro:
(defun prime4 (a)
(not (or (< a 2)
(cl-some (lambda (x) (zerop (% a x))) (number-sequence 2 (sqrt a))))))
Almost 2 times faster, than the previous:
(defun prime5 (a)
(not (or (< a 2)
(and (/= a 2) (cl-evenp a))
(cl-some (lambda (x) (zerop (% a x))) (number-sequence 3 (sqrt a) 2)))))
Erlang
is_prime(N) when N == 2 -> true;
is_prime(N) when N < 2 orelse N rem 2 == 0 -> false;
is_prime(N) -> is_prime(N,3).
is_prime(N,K) when K*K > N -> true;
is_prime(N,K) when N rem K == 0 -> false;
is_prime(N,K) -> is_prime(N,K+2).
ERRE
PROGRAM PRIME_TRIAL
PROCEDURE ISPRIME(N%->OK%)
LOCAL T%
IF N%<=1 THEN OK%=FALSE EXIT PROCEDURE END IF
IF N%<=3 THEN OK%=TRUE EXIT PROCEDURE END IF
IF (N% AND 1)=0 THEN OK%=FALSE EXIT PROCEDURE END IF
FOR T%=3 TO SQR(N%) STEP 2 DO
IF N% MOD T%=0 THEN OK%=FALSE EXIT PROCEDURE END IF
END FOR
OK%=TRUE
END PROCEDURE
BEGIN
FOR I%=1 TO 100 DO
ISPRIME(I%->OK%)
IF OK% THEN PRINT(i%;"is prime") END IF
END FOR
END PROGRAM
- Output:
2 is prime 3 is prime 5 is prime 7 is prime 11 is prime 13 is prime 17 is prime 19 is prime 23 is prime 29 is prime 31 is prime 37 is prime 41 is prime 43 is prime 47 is prime 53 is prime 59 is prime 61 is prime 67 is prime 71 is prime 73 is prime 79 is prime 83 is prime 89 is prime 97 is prime
Euphoria
function is_prime(integer n)
if n<=2 or remainder(n,2)=0 then
return 0
else
for i=3 to sqrt(n) by 2 do
if remainder(n,i)=0 then
return 0
end if
end for
return 1
end if
end function
F#
open NUnit.Framework
open FsUnit
let inline isPrime n = not ({uint64 2..uint64 (sqrt (double n))} |> Seq.exists (fun (i:uint64) -> uint64 n % i = uint64 0))
[<Test>]
let ``Validate that 2 is prime`` () =
isPrime 2 |> should equal true
[<Test>]
let ``Validate that 4 is not prime`` () =
isPrime 4 |> should equal false
[<Test>]
let ``Validate that 3 is prime`` () =
isPrime 3 |> should equal true
[<Test>]
let ``Validate that 9 is not prime`` () =
isPrime 9 |> should equal false
[<Test>]
let ``Validate that 5 is prime`` () =
isPrime 5 |> should equal true
[<Test>]
let ``Validate that 277 is prime`` () =
isPrime 277 |> should equal true
- Output:
> isPrime 1111111111111111111UL;; val it : bool = true
and if you want to test really big numbers, use System.Numerics.BigInteger, but it's slower:
let isPrimeI x =
if x < 2I then false else
if x = 2I then true else
if x % 2I = 0I then false else
let rec test n =
if n * n > x then true else
if x % n = 0I then false else test (n + 2I) in test 3I
If you have a lot of prime numbers to test, caching a sequence of primes can speed things up considerably, so you only have to do the divisions against prime numbers.
let rec primes = Seq.cache(Seq.append (seq[ 2; 3; 5 ]) (Seq.unfold (fun state -> Some(state, state + 2)) 7 |> Seq.filter (fun x -> IsPrime x)))
and IsPrime number =
let rec IsPrimeCore number current limit =
let cprime = primes |> Seq.nth current
if cprime >= limit then
true
else if number % cprime = 0 then
false
else
IsPrimeCore number (current + 1) (number/cprime)
if number = 2 then
true
else if number < 2 then
false
else
IsPrimeCore number 0 number
Factor
USING: combinators kernel math math.functions math.ranges sequences ;
: prime? ( n -- ? )
{
{ [ dup 2 < ] [ drop f ] }
{ [ dup even? ] [ 2 = ] }
[ 3 over sqrt 2 <range> [ mod 0 > ] with all? ]
} cond ;
FALSE
[0\$2=$[@~@@]?~[$$2>\1&&[\~\
3[\$@$@1+\$*>][\$@$@$@$@\/*=[%\~\$]?2+]#%
]?]?%]p:
Forth
: prime? ( n -- f )
dup 2 < if drop false
else dup 2 = if drop true
else dup 1 and 0= if drop false
else 3
begin 2dup dup * >=
while 2dup mod 0=
if 2drop false exit
then 2 +
repeat 2drop true
then then then ;
Fortran
FUNCTION isPrime(number)
LOGICAL :: isPrime
INTEGER, INTENT(IN) :: number
INTEGER :: i
IF(number==2) THEN
isPrime = .TRUE.
ELSE IF(number < 2 .OR. MOD(number,2) == 0) THEN
isPRIME = .FALSE.
ELSE
isPrime = .TRUE.
DO i = 3, INT(SQRT(REAL(number))), 2
IF(MOD(number,i) == 0) THEN
isPrime = .FALSE.
EXIT
END IF
END DO
END IF
END FUNCTION
Frink
It is unnecessary to write this function because Frink has an efficient isPrime[x]
function to test primality of arbitrarily-large integers. Here is a version that works for arbitrarily-large integers. Beware some of these solutions that calculate up to sqrt[x]
but because of floating-point error the square root is slightly smaller than the true square root!
isPrimeByTrialDivision[x] :=
{
for p = primes[]
{
if p*p > x
return true
if x mod p == 0
return false
}
return true
}
FunL
import math.sqrt
def
isPrime( 2 ) = true
isPrime( n )
| n < 3 or 2|n = false
| otherwise = (3..int(sqrt(n)) by 2).forall( (/|n) )
(10^10..10^10+50).filter( isPrime ).foreach( println )
- Output:
10000000019 10000000033
GAP
IsPrimeTrial := function(n)
local k, m;
if n < 5 then
return (n = 2) or (n = 3);
fi;
if RemInt(n, 2) = 0 then
return false;
fi;
m := RootInt(n);
k := 3;
while k <= m do
if RemInt(n, k) = 0 then
return false;
fi;
k := k + 2;
od;
return true;
end;
Filtered([1 .. 100], IsPrimeTrial);
# [ 2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97 ]
Go
func IsPrime(n int) bool {
if n < 0 { n = -n }
switch {
case n == 2:
return true
case n < 2 || n % 2 == 0:
return false
default:
for i = 3; i*i <= n; i += 2 {
if n % i == 0 { return false }
}
}
return true
}
Or, using recursion:
func IsPrime(n int) bool {
if n < 0 { n = -n }
if n <= 2 {
return n == 2
}
return n % 2 != 0 && isPrime_r(n, 3)
}
func isPrime_r(n, i int) bool {
if i*i <= n {
return n % i != 0 && isPrime_r(n, i+2)
}
return true
}
Groovy
def isPrime = {
it == 2 ||
it > 1 &&
(2..Math.max(2, (int) Math.sqrt(it))).every{ k -> it % k != 0 }
}
(0..20).grep(isPrime)
- Output:
[2, 3, 5, 7, 11, 13, 17, 19]
Haskell
(used here and here). The basic divisibility test by odd numbers:
isPrime n = n==2 || n>2 && all ((> 0).rem n) (2:[3,5..floor.sqrt.fromIntegral $ n+1])
Testing by prime numbers only is faster. Primes list is saved for reuse. Precalculation of primes pays off if testing more than just a few numbers, and/or primes are generated efficiently enough:
noDivsBy factors n = foldr (\f r-> f*f>n || ((rem n f /= 0) && r)) True factors
-- primeNums = filter (noDivsBy [2..]) [2..]
-- = 2 : filter (noDivsBy [3,5..]) [3,5..]
primeNums = 2 : 3 : filter (noDivsBy $ tail primeNums) [5,7..]
isPrime n = n > 1 && noDivsBy primeNums n
Any increasing unbounded sequence of numbers that includes all primes (above the first few, perhaps) could be used with the testing function noDivsBy
to define the isPrime
function -- but using just primes is better, produced e.g. by Sieve of Eratosthenes, or noDivsBy
itself can be used to define primeNums
as shown above, because it stops when the square root is reached (so there's no infinite recursion, no "vicious circle").
A less efficient, more basic variant:
isPrime n = n > 1 && []==[i | i <- [2..n-1], rem n i == 0]
The following is an attempt at improving it, resulting in absolutely worst performing prime testing code I've ever seen, ever. A curious oddity.
isPrime n = n > 1 && []==[i | i <- [2..n-1], isPrime i && rem n i == 0]
HicEst
DO n = 1, 1E6
Euler = n^2 + n + 41
IF( Prime(Euler) == 0 ) WRITE(Messagebox) Euler, ' is NOT prime for n =', n
ENDDO ! e.g. 1681 = 40^2 + 40 + 41 is NOT prime
END
FUNCTION Prime(number)
Prime = number == 2
IF( (number > 2) * MOD(number,2) ) THEN
DO i = 3, number^0.5, 2
IF(MOD(number,i) == 0) THEN
Prime = 0
RETURN
ENDIF
ENDDO
Prime = 1
ENDIF
END
Icon and Unicon
Procedure shown without a main program.
J
isprime=: 3 : 'if. 3>:y do. 1<y else. 0 *./@:< y|~2+i.<.%:y end.'
Java
public static boolean prime(long a){
if(a == 2){
return true;
}else if(a <= 1 || a % 2 == 0){
return false;
}
long max = (long)Math.sqrt(a);
for(long n= 3; n <= max; n+= 2){
if(a % n == 0){ return false; }
}
return true;
}
By Regular Expression
public static boolean prime(int n) {
return !new String(new char[n]).matches(".?|(..+?)\\1+");
}
JavaScript
function isPrime(n) {
if (n == 2 || n == 3 || n == 5 || n == 7) {
return true;
} else if ((n < 2) || (n % 2 == 0)) {
return false;
} else {
for (var i = 3; i <= Math.sqrt(n); i += 2) {
if (n % i == 0)
return false;
}
return true;
}
}
Joy
DEFINE prime ==
2 [[dup * >] nullary [rem 0 >] dip and]
[succ] while dup * <.
jq
def is_prime:
if . == 2 then true else 2 < . and . % 2 == 1 and . as $in | (($in + 1) | sqrt) as $m | (((($m - 1) / 2) | floor) + 1) as $max | all( range(1; $max) ; $in % ((2 * .) + 1) > 0 ) end;
Example -- the command line is followed by alternating lines of input and output: $ jq -f is_prime.jq
-2 false 1 false 2 true 100 false
Note: if your jq does not have all, the following will suffice:
def all(generator; condition): reduce generator as $i (true; . and ($i|condition));
Julia
Julia already has an isprime function, so this function has the verbose name isprime_trialdivision to avoid overriding the built-in function. Note this function relies on the fact that Julia skips for-loops having invalid ranges. Otherwise the function would have to include additional logic to check the odd numbers less than 9.
function isprime_trialdivision{T<:Integer}(n::T)
1 < n || return false
n != 2 || return true
isodd(n) || return false
for i in 3:isqrt(n)
n%i != 0 || return false
end
return true
end
n = 100
a = filter(isprime_trialdivision, [1:n])
if all(a .== primes(n))
println("The primes <= ", n, " are:\n ", a)
else
println("The function does not accurately calculate primes.")
end
- Output:
The primes <= 100 are: [2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97]
K
isprime:{(x>1)&&/x!'2_!1+_sqrt x}
&isprime'!100
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
Kotlin
// version 1.1.2
fun isPrime(n: Int): Boolean {
if (n < 2) return false
if (n % 2 == 0) return n == 2
val limit = Math.sqrt(n.toDouble()).toInt()
return (3..limit step 2).none { n % it == 0 }
}
fun main(args: Array<String>) {
// test by printing all primes below 100 say
(2..99).filter { isPrime(it) }.forEach { print("$it ") }
}
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
Lambdatalk
1) the simplest
{def isprime1
{def isprime1.loop
{lambda {:n :m :i}
{if {> :i :m}
then true
else {if {= {% :n :i} 0}
then false
else {isprime1.loop :n :m {+ :i 1}} }
}}}
{lambda {:n}
{isprime1.loop :n {sqrt :n} 2}
}}
-> isprime1
2) slightly improved
{def isprime2
{def isprime2.loop
{lambda {:n :m :i}
{if {> :i :m}
then true
else {if {= {% :n :i} 0}
then false
else {isprime2.loop :n :m {+ :i 2}}
}}}}
{lambda {:n}
{if {or {= :n 2} {= :n 3} {= :n 5} {= :n 7}}
then true
else {if {or {< : n 2} {= {% :n 2} 0}}
then false
else {isprime2.loop :n {sqrt :n} 3}
}}}}
-> isprime2
3) testing
{isprime1 1299709} -> stackoverflow on my iPad Pro
{isprime2 1299709} -> true
{def primesTo
{lambda {:f :n}
{S.replace \s by space in
{S.map {{lambda {:f :i} {if {:f :i} then :i else}} :f}
{S.serie 2 :n}}} }}
-> primesTo
{primesTo isprime1 100}
-> 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 in 25ms
{primesTo isprime2 100}
-> 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 in 20ms
{primesTo isprime1 1000000} in about 30000ms
{primesTo isprime2 1000000} in about 15000ms
langur
Functional
following the Raku example, which states, "Integer $i is prime if it is greater than one and is divisible by none of 2, 3, up to the square root of $i" (plus an adjustment for the prime number 2)
val isPrime = fn(i) {
i == 2 or i > 2 and
not any(fn x:i div x, pseries(2 .. i ^/ 2))
}
writeln filter(isPrime, series(100))
Recursive
val isPrime = fn(i) {
val n = abs(i)
if n <= 2: return n == 2
val chkdiv = fn(n, i) {
if i * i <= n {
return n ndiv i and fn((n, i+2))
}
return true
}
return n ndiv 2 and chkdiv(n, 3)
}
writeln filter(isPrime, series(100))
- Output:
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97]
Lingo
on isPrime (n)
if n<=1 or (n>2 and n mod 2=0) then return FALSE
sq = sqrt(n)
repeat with i = 3 to sq
if n mod i = 0 then return FALSE
end repeat
return TRUE
end
primes = []
repeat with i = 0 to 100
if isPrime(i) then primes.add(i)
end repeat
put primes
- Output:
-- [2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97]
Logo
to prime? :n
if :n < 2 [output "false]
if :n = 2 [output "true]
if equal? 0 modulo :n 2 [output "false]
for [i 3 [sqrt :n] 2] [if equal? 0 modulo :n :i [output "false]]
output "true
end
LSE64
over : 2 pick
2dup : over over
even? : 1 & 0 =
# trial n d yields "n d 0/1 false" or "n d+2 true"
trial : 2 + true
trial : 2dup % 0 = then 0 false
trial : 2dup dup * < then 1 false
trial-loop : trial &repeat
# prime? n yields flag
prime? : 3 trial-loop >flag drop drop
prime? : dup even? then drop false
prime? : dup 2 = then drop true
prime? : dup 2 < then drop false
Lua
function IsPrime( n )
if n <= 1 or ( n ~= 2 and n % 2 == 0 ) then
return false
end
for i = 3, math.sqrt(n), 2 do
if n % i == 0 then
return false
end
end
return true
end
Type of number Decimal.
M2000 Interpreter
Module Primality_by_trial_division {
Inventory Known1=2@, 3@
IsPrime=lambda Known1 (x as decimal) -> {
=false
if exist(Known1, x) then =true : exit
if x<=5 OR frac(x) then {if x == 2 OR x == 3 OR x == 5 then Append Known1, x : =true
Break}
if frac(x/2) else exit
if frac(x/3) else exit
x1=sqrt(x):d = 5@
do
if frac(x/d) else exit
d += 2: if d>x1 then Append Known1, x : =true : exit
if frac(x/d) else exit
d += 4: if d<= x1 else Append Known1, x : =true: exit
always
}
i=2
While Len(Known1)<20
dummy=Isprime(i)
i++
End While
Print "first ";len(known1);" primes"
Print Known1
Print "From 110 to 130"
count=0
For i=110 to 130
If isPrime(i) Then Print i, : count++
Next
Print
Print "Found ";count;" primes"
}
Primality_by_trial_division
M4
define(`testnext',
`ifelse(eval($2*$2>$1),1,
1,
`ifelse(eval($1%$2==0),1,
0,
`testnext($1,eval($2+2))')')')
define(`isprime',
`ifelse($1,2,
1,
`ifelse(eval($1<=1 || $1%2==0),1,
0,
`testnext($1,3)')')')
isprime(9)
isprime(11)
- Output:
0 1
MAD
NORMAL MODE IS INTEGER
INTERNAL FUNCTION(N)
ENTRY TO PRIME.
WHENEVER N.L.2, FUNCTION RETURN 0B
WHENEVER N.E.N/2*2, FUNCTION RETURN N.E.2
THROUGH TRIAL, FOR FAC=3, 2, FAC*FAC.G.N
TRIAL WHENEVER N.E.N/FAC*FAC, FUNCTION RETURN 0B
FUNCTION RETURN 1B
END OF FUNCTION
PRINT COMMENT $ PRIMES UNDER 100 $
THROUGH CAND, FOR C=0, 1, C.G.100
CAND WHENEVER PRIME.(C), PRINT FORMAT PR,C
VECTOR VALUES PR = $ I3*$
END OF PROGRAM
- Output:
PRIMES UNDER 100 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
Maple
This could be coded in myriad ways; here is one.
TrialDivision := proc( n :: integer )
if n <= 1 then
false
elif n = 2 then
true
elif type( n, 'even' ) then
false
else
for local i from 3 by 2 while i * i <= n do
if irem( n, i ) = 0 then
return false
end if
end do;
true
end if
end proc:
Using this to pick off the primes up to 30, we get:
> select( TrialDivision, [seq]( 1 .. 30 ) );
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29]
Here is a way to check that TrialDivision above agrees with Maple's built-in primality test (isprime).
> N := 10000: evalb( select( TrialDivision, [seq]( 1 .. N ) ) = select( isprime, [seq]( 1 .. N ) ) );
true
Mathematica/Wolfram Language
IsPrime[n_Integer] := Block[{},
If[n <= 1, Return[False]];
If[n == 2, Return[True]]; If[Mod[n, 2] == 0, Return[False]];
For[k = 3, k <= Sqrt[n], k += 2, If[Mod[n, k] == 0, Return[False]]];
Return[True]]
MATLAB
function isPrime = primalityByTrialDivision(n)
if n == 2
isPrime = true;
return
elseif (mod(n,2) == 0) || (n <= 1)
isPrime = false;
return
end
%First n mod (3 to sqrt(n)) is taken. This will be a vector where the
%first element is equal to n mod 3 and the last element is equal to n
%mod sqrt(n). Then the all function is applied to that vector. If all
%of the elements of this vector are non-zero (meaning n is prime) then
%all() returns true. Otherwise, n is composite, so it returns false.
%This return value is then assigned to the variable isPrime.
isPrime = all(mod(n, (3:round(sqrt(n))) ));
end
- Sample output:
>> arrayfun(@primalityByTrialDivision,(1:14))
ans =
0 1 1 0 1 0 1 0 0 0 1 0 1 0
Maxima
isprme(n):= catch(
for k: 2 thru sqrt(n) do if mod(n, k)=0 then throw(false),
true);
map(isprme, [2, 3, 4, 65, 100, 181, 901]);
/* [true, true, false, false, false, true, false] */
min
(
:n 3 :i n sqrt :m true :p
(i m <=) (
(n i mod 0 ==) (m @i false @p) when
i 2 + @i
) while p
) :_prime? ; helper function
(
(
((2 <) (false))
((dup even?) (2 ==))
((true) (_prime?))
) case
) :prime?
Miranda
main :: [sys_message]
main = [Stdout (show (filter prime [1..100])),
Stdout "\n"]
prime :: num->bool
prime n = n=2 \/ n=3, if n<=4
= False, if n mod 2=0
= #[d | d<-[3, 5..sqrt n]; n mod d=0]=0, otherwise
- Output:
[2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97]
МК-61/52
П0 1 - x#0 34 2 - /-/ x<0 32
ИП0 2 / {x} x#0 34
3 П4 ИП0 ИП4 / {x} x#0 34 КИП4 КИП4
ИП0 КвКор ИП4 - x<0 16 1 С/П 0 С/П
Modula-2
MODULE TrialDivision;
FROM InOut IMPORT WriteCard, WriteLn;
CONST
Max = 100;
VAR
i: CARDINAL;
PROCEDURE prime(n: CARDINAL): BOOLEAN;
VAR
factor: CARDINAL;
BEGIN
IF n <= 4 THEN
RETURN (n = 2) OR (n = 3)
ELSIF n MOD 2 = 0 THEN
RETURN FALSE
ELSE
factor := 3;
WHILE factor * factor <= n DO
IF n MOD factor = 0 THEN
RETURN FALSE
END;
INC(factor, 2)
END
END;
RETURN TRUE
END prime;
BEGIN
FOR i := 0 TO Max DO
IF prime(i) THEN
WriteCard(i,3);
WriteLn
END
END
END TrialDivision.
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
MUMPS
ISPRIME(N)
QUIT:(N=2) 1
NEW I,R
SET R=N#2
IF R FOR I=3:2:(N**.5) SET R=N#I Q:'R
KILL I
QUIT R
Usage (0 is false, nonzero is true):
USER>W $$ISPRIME^ROSETTA(2) 1 USER>W $$ISPRIME^ROSETTA(4) 0 USER>W $$ISPRIME^ROSETTA(7) 1 USER>W $$ISPRIME^ROSETTA(97) 7 USER>W $$ISPRIME^ROSETTA(99) 0
NetRexx
/* NetRexx */
options replace format comments java crossref savelog symbols nobinary
parse arg nbr rangeBegin rangeEnd .
if nbr = '' | nbr = '.' then do
if rangeBegin = '' | rangeBegin = '.' then rangeBegin = 1
if rangeEnd = '' | rangeEnd = '.' then rangeEnd = 100
if rangeEnd > rangeBegin then direction = 1
else direction = -1
say 'List of prime numbers from' rangeBegin 'to' rangeEnd':'
primes = ''
loop nn = rangeBegin to rangeEnd by direction
if isPrime(nn) then primes = primes nn
end nn
primes = primes.strip
say ' 'primes.changestr(' ', ',')
say ' Total number of primes:' primes.words
end
else do
if isPrime(nbr) then say nbr.right(20) 'is prime'
else say nbr.right(20) 'is not prime'
end
return
method isPrime(nbr = long) public static binary returns boolean
ip = boolean
select
when nbr < 2 then do
ip = isFalse
end
when '2 3 5 7'.wordpos(Rexx(nbr)) \= 0 then do
-- crude shortcut ripped from the Rexx example
ip = isTrue
end
when nbr // 2 == 0 | nbr // 3 == 0 then do
-- another shortcut permitted by the one above
ip = isFalse
end
otherwise do
nn = long
nnStartTerm = long 3 -- a reasonable start term - nn <= 2 is never prime
nnEndTerm = long Math.ceil(Math.sqrt(nbr)) -- a reasonable end term
ip = isTrue -- prime the pump (pun intended)
loop nn = nnStartTerm to nnEndTerm by 2
-- Note: in Rexx and NetRexx "//" is the 'remainder of division operator' (which is not the same as modulo)
if nbr // nn = 0 then do
ip = isFalse
leave nn
end
end nn
end
end
return ip
method isTrue public static returns boolean
return 1 == 1
method isFalse public static returns boolean
return \isTrue
- Output:
$ java -cp . RCPrimality List of prime numbers from 1 to 100: 2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97 Total number of primes: 25 $ java -cp . RCPrimality 91 91 is not prime $ java -cp . RCPrimality 101 101 is prime $ java -cp . RCPrimality . . 25 List of prime numbers from 1 to 25: 2,3,5,7,11,13,17,19,23 Total number of primes: 9 $ java -cp . RCPrimality . 9900 10010 List of prime numbers from 9900 to 10010: 9901,9907,9923,9929,9931,9941,9949,9967,9973,10007,10009 Total number of primes: 11 $ java -cp . RCPrimality . -57 1 List of prime numbers from -57 to 1: Total number of primes: 0 $ java -cp . RCPrimality . 100 -57 List of prime numbers from 100 to -57: 97,89,83,79,73,71,67,61,59,53,47,43,41,37,31,29,23,19,17,13,11,7,5,3,2 Total number of primes: 25
Rexx version reimplemented in NetRexx
/* NetRexx */
options replace format comments java crossref savelog symbols nobinary
/*REXX program tests for primality using (kinda smartish) trial division*/
parse arg n . /*let user choose how many, maybe*/
if n=='' then n=10000 /*if not, then assume the default*/
p=0 /*a count of primes (so far). */
/*I like Heinz's 57 varieties... */
loop j=-57 to n /*start in the cellar and work up*/
if \isprime(j) then iterate /*if not prime, keep looking. */
p=p+1 /*bump the jelly bean counter. */
if j.length>2 then iterate /*only show two-digit primes. */
say j.right(20) 'is prime.' /*Just blab about the wee primes.*/
end
say
say "there're" p "primes up to" n '(inclusive).'
exit
/*-------------------------------------ISPRIME subroutine---------------*/
method isprime(x) public static returns boolean
--isprime: procedure; arg x /*get the number in question*/
if '2 3 5 7'.wordpos(x)\==0 then return 1 /*is it a teacher's pet? */
if x<2 | x//2==0 | x//3==0 then return 0 /*weed out the riff-raff. */
/*Note: // is modulus. */
loop j=5 by 6 until j*j>x /*skips multiples of three. */
if x//j==0 | x//(j+2)==0 then return 0 /*do a pair of divides (mod)*/
end
return 1 /*I'm exhausted, it's prime!*/
newLISP
Short-circuit evaluation ensures that the many Boolean expressions are calculated in the right order so as not to waste time.
; Here are some simpler functions to help us:
(define (divisible? larger-number smaller-number)
(zero? (% larger-number smaller-number)))
(define (int-root number)
(floor (sqrt number)))
(define (even-prime? number)
(= number 2))
; Trial division for odd numbers
(define (find-odd-factor? odd-number)
(catch
(for (possible-factor 3 (int-root odd-number) 2)
(if (divisible? odd-number possible-factor)
(throw true)))))
(define (odd-prime? number)
(and
(odd? number)
(or
(= number 3)
(and
(> number 3)
(not (find-odd-factor? number))))))
; Now for the final overall Boolean function.
(define (is-prime? possible-prime)
(or
(even-prime? possible-prime)
(odd-prime? possible-prime)))
; Let's use this to actually find some prime numbers.
(println (filter is-prime? (sequence 1 100)))
(exit)
- Output:
(2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97)
Nim
Here are three ways to test primality using trial division.
import sequtils, math
proc prime(a: int): bool =
if a == 2: return true
if a < 2 or a mod 2 == 0: return false
for i in countup(3, sqrt(a.float).int, 2):
if a mod i == 0:
return false
return true
proc prime2(a: int): bool =
result = not (a < 2 or any(toSeq(2 .. sqrt(a.float).int), a mod it == 0))
proc prime3(a: int): bool =
if a == 2: return true
if a < 2 or a mod 2 == 0: return false
return not any(toSeq countup(3, sqrt(a.float).int, 2), a mod it == 0)
for i in 2..30:
echo i, " ", prime(i)
- Output:
2 true 3 true 4 false 5 true 6 false 7 true 8 false 9 false 10 false 11 true 12 false 13 true 14 false 15 false 16 false 17 true 18 false 19 true 20 false 21 false 22 false 23 true 24 false 25 false 26 false 27 false 28 false 29 true 30 false
Objeck
function : IsPrime(n : Int) ~ Bool {
if(n <= 1) {
return false;
};
for(i := 2; i * i <= n; i += 1;) {
if(n % i = 0) {
return false;
};
};
return true;
}
OCaml
let is_prime n =
let rec test x =
x * x > n || n mod x <> 0 && n mod (x + 2) <> 0 && test (x + 6)
in
if n < 5
then n lor 1 = 3
else n land 1 <> 0 && n mod 3 <> 0 && test 5
Octave
This function works on vectors and matrix.
function b = isthisprime(n)
for r = 1:rows(n)
for c = 1:columns(n)
b(r,c) = false;
if ( n(r,c) == 2 )
b(r,c) = true;
elseif ( (n(r,c) < 2) || (mod(n(r,c),2) == 0) )
b(r,c) = false;
else
b(r,c) = true;
for i = 3:2:sqrt(n(r,c))
if ( mod(n(r,c), i) == 0 )
b(r,c) = false;
break;
endif
endfor
endif
endfor
endfor
endfunction
% as test, print prime numbers from 1 to 100
p = [1:100];
pv = isthisprime(p);
disp(p( pv ));
Oforth
Integer method: isPrime
| i |
self 1 <= ifTrue: [ false return ]
self 3 <= ifTrue: [ true return ]
self isEven ifTrue: [ false return ]
3 self sqrt asInteger for: i [ self i mod ifzero: [ false return ] ]
true ;
- Output:
#isPrime 1000 seq filter println [2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 8 9, 97, 101, 103, 107, 109, 113, 127, 131, 137, 139, 149, 151, 157, 163, 167, 173, 179, 181 , 191, 193, 197, 199, 211, 223, 227, 229, 233, 239, 241, 251, 257, 263, 269, 271, 277, 281 , 283, 293, 307, 311, 313, 317, 331, 337, 347, 349, 353, 359, 367, 373, 379, 383, 389, 397 , 401, 409, 419, 421, 431, 433, 439, 443, 449, 457, 461, 463, 467, 479, 487, 491, 499, 503 , 509, 521, 523, 541, 547, 557, 563, 569, 571, 577, 587, 593, 599, 601, 607, 613, 617, 619 , 631, 641, 643, 647, 653, 659, 661, 673, 677, 683, 691, 701, 709, 719, 727, 733, 739, 743 , 751, 757, 761, 769, 773, 787, 797, 809, 811, 821, 823, 827, 829, 839, 853, 857, 859, 863 , 877, 881, 883, 887, 907, 911, 919, 929, 937, 941, 947, 953, 967, 971, 977, 983, 991, 997 ]
Ol
(define (prime? number)
(define max (sqrt number))
(define (loop divisor)
(or (> divisor max)
(and (> (modulo number divisor) 0)
(loop (+ divisor 2)))))
(or (= number 1)
(= number 2)
(and
(> (modulo number 2) 0)
(loop 3))))
Testing:
; first prime numbers less than 100
(for-each (lambda (n)
(if (prime? n)
(display n))
(display " "))
(iota 100))
(print)
; few more sintetic tests
(for-each (lambda (n)
(print n " - prime? " (prime? n)))
'(
1234567654321 ; 1111111 * 1111111
679390005787 ; really prime, I know that
679390008337 ; same
666810024403 ; 680633 * 979691 (multiplication of two prime numbers)
12345676543211234567654321
12345676543211234567654321123456765432112345676543211234567654321123456765432112345676543211234567654321
))
- Output:
1 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 1234567654321 - prime? #false 679390005787 - prime? #true 679390008337 - prime? #true 666810024403 - prime? #false 12345676543211234567654321 - prime? #false 12345676543211234567654321123456765432112345676543211234567654321123456765432112345676543211234567654321 - prime? #false
Oz
fun {Prime N}
local IPrime in
fun {IPrime N Acc}
if N < Acc*Acc then true
elseif (N mod Acc) == 0 then false
else {IPrime N Acc+1}
end
end
if N < 2 then false
else {IPrime N 2} end
end
end
Panda
In Panda you write a boolean function by making it filter, either returning it's input or nothing.
fun prime(p) type integer->integer
p.gt(1) where q=p.sqrt NO(p.mod(2..q)==0)
1..100.prime
PARI/GP
trial(n)={
if(n < 4, return(n > 1)); /* Handle negatives */
forprime(p=2,sqrtint(n),
if(n%p == 0, return(0))
);
1
};
Pascal
program primes;
function prime(n: integer): boolean;
var
i: integer; max: real;
begin
if n = 2 then
prime := true
else if (n <= 1) or (n mod 2 = 0) then
prime := false
else begin
prime := true; i := 3; max := sqrt(n);
while i <= max do begin
if n mod i = 0 then begin
prime := false; exit
end;
i := i + 2
end
end
end;
{ Test and display primes 0 .. 50 }
var
n: integer;
begin
for n := 0 to 50 do
if (prime(n)) then
write(n, ' ');
end.
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
improved using number wheel
program TestTrialDiv;
{$IFDEF FPC}
{$MODE DELPHI}{$Smartlink ON}
{$ELSE}
{$APPLICATION CONSOLE}// for Delphi
{$ENDIF}
uses
primtrial;
{ Test and display primes 0 .. 50 }
begin
repeat
write(actPrime,' ');
until nextPrime > 50;
end.
- Output
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
PascalABC.NET
function IsPrime(N: integer): boolean;
begin
if N = 1 then
Result := False
else Result := True;
for var i:=2 to N.Sqrt.Round do
if N.Divs(i) then
begin
Result := False;
exit
end;
end;
begin
for var i:=1 to 1000 do
if IsPrime(i) then
Print(i)
end.
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157 163 167 173 179 181 191 193 197 199 211 223 227 229 233 239 241 251 257 263 269 271 277 281 283 293 307 311 313 317 331 337 347 349 353 359 367 373 379 383 389 397 401 409 419 421 431 433 439 443 449 457 461 463 467 479 487 491 499 503 509 521 523 541 547 557 563 569 571 577 587 593 599 601 607 613 617 619 631 641 643 647 653 659 661 673 677 683 691 701 709 719 727 733 739 743 751 757 761 769 773 787 797 809 811 821 823 827 829 839 853 857 859 863 877 881 883 887 907 911 919 929 937 941 947 953 967 971 977 983 991 997
Perl
A simple idiomatic solution:
sub prime { my $n = shift || $_;
$n % $_ or return for 2 .. sqrt $n;
$n > 1
}
print join(', ' => grep prime, 1..100), "\n";
Excluding multiples of 2 and 3
One of many ways of writing trial division using a mod-6 wheel. Almost 2x faster than the simple method shown earlier.
sub isprime {
my $n = shift;
return ($n >= 2) if $n < 4;
return unless $n % 2 && $n % 3;
my $sqrtn = int(sqrt($n));
for (my $i = 5; $i <= $sqrtn; $i += 6) {
return unless $n % $i && $n % ($i+2);
}
1;
}
my $s = 0;
$s += !!isprime($_) for 1..100000;
print "Pi(100,000) = $s\n";
By Regular Expression
JAPH by Abigail 1999 [1] in conference slides 2000 [2].
While this is extremely clever and often used for Code golf, it should never be used for real work (it is extremely slow and uses lots of memory).
sub isprime {
('1' x shift) !~ /^1?$|^(11+?)\1+$/
}
print join(', ', grep(isprime($_), 0..39)), "\n";
Phix
function is_prime_by_trial_division(integer n) if n<2 then return 0 end if if n=2 then return 1 end if if remainder(n,2)=0 then return 0 end if for i=3 to floor(sqrt(n)) by 2 do if remainder(n,i)=0 then return 0 end if end for return 1 end function ?filter(tagset(32),is_prime_by_trial_division)
- Output:
{2,3,5,7,11,13,17,19,23,29,31}
PHP
<?php
function prime($a) {
if (($a % 2 == 0 && $a != 2) || $a < 2)
return false;
$limit = sqrt($a);
for ($i = 2; $i <= $limit; $i++)
if ($a % $i == 0)
return false;
return true;
}
foreach (range(1, 100) as $x)
if (prime($x)) echo "$x\n";
?>
By Regular Expression
<?php
function prime($a) {
return !preg_match('/^1?$|^(11+?)\1+$/', str_repeat('1', $a));
}
?>
Picat
Here are four different versions.
Iterative
is_prime1(N) =>
if N == 2 then
true
elseif N <= 1 ; N mod 2 == 0 then
false
else
foreach(I in 3..2..ceiling(sqrt(N)))
N mod I > 0
end
end.
Recursive
is_prime2(N) =>
(N == 2 ; is_prime2b(N,3)).
is_prime2b(N,_Div), N <= 1 => false.
is_prime2b(2,_Div) => true.
is_prime2b(N,_Div), N mod 2 == 0 => false.
is_prime2b(N,Div), Div > ceiling(sqrt(N)) => true.
is_prime2b(N,Div), Div > 2 =>
(N mod Div == 0 ->
false
;
is_prime2b(N,Div+2)
).
Functional
is_prime3(2) => true.
is_prime3(3) => true.
is_prime3(P) => P > 3, P mod 2 =\= 0, not has_factor3(P,3).
has_factor3(N,L), N mod L == 0 => true.
has_factor3(N,L) => L * L < N, L2 = L + 2, has_factor3(N,L2).
Generator approach
prime2(N)
can be used to generate primes until memory is exhausted.
Difference from Prolog implementation: Picat does not support between/3
with
"inf" as upper bound, so a high number (here 2**156+1) must be used.
prime2(2).
prime2(N) :-
between(3, 2**156+1, N),
N mod 2 = 1, % odd
M is floor(sqrt(N+1)), % round-off paranoia
Max is (M-1) // 2, % integer division
foreach(I in 1..Max) N mod (2*I+1) > 0 end.
Test
go =>
println([I : I in 1..100, is_prime1(I)]),
nl,
foreach(P in 1..6)
Primes = [ I : I in 1..10**P, is_prime1(I)],
println([10**P,Primes.len])
end,
nl.
- Output:
[2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97] [10,4] [100,25] [1000,168] [10000,1229] [100000,9592] [1000000,78498]
Benchmark
Times for calculating the number of primes below 10, 100,1_000,10_000, 100_000, and 1_000_000 respectively.
- imperative:
is_prime1/1
(0.971) - recursive:
is_prime2/1
(3.258s) - functional:
is_prime3/1
(0.938s) - test/generate
prime2/1
(2.129s)
PicoLisp
(de prime? (N)
(or
(= N 2)
(and
(> N 1)
(bit? 1 N)
(let S (sqrt N)
(for (D 3 T (+ D 2))
(T (> D S) T)
(T (=0 (% N D)) NIL) ) ) ) ) )
PL/0
The program waits for a number. Then it displays 1 if the number is prime, 0 otherwise.
var p, isprime;
procedure checkprimality;
var i, isichecked;
begin
isprime := 0;
if p = 2 then isprime := 1;
if p >= 3 then
begin
i := 2; isichecked := 0;
while isichecked = 0 do
begin
if (p / i) * i = p then isichecked := 1;
if isichecked <> 1 then
if i * i >= p then
begin
isprime := 1; isichecked := 1
end;
i := i + 1
end
end
end;
begin
? p;
call checkprimality;
! isprime
end.
4 runs:
- Input:
1
- Output:
0
- Input:
25
- Output:
0
- Input:
43
- Output:
1
- Input:
101
- Output:
1
PL/I
is_prime: procedure (n) returns (bit(1));
declare n fixed (15);
declare i fixed (10);
if n < 2 then return ('0'b);
if n = 2 then return ('1'b);
if mod(n, 2) = 0 then return ('0'b);
do i = 3 to sqrt(n) by 2;
if mod(n, i) = 0 then return ('0'b);
end;
return ('1'b);
end is_prime;
PL/M
This can be compiled with the original 8080 PL/M compiler and run under CP/M or an emulator or clone.
Note that all integers in 8080 PL/M are unsigned.
100H: /* TEST FOR PRIMALITY BY TRIAL DIVISION */
DECLARE FALSE LITERALLY '0', TRUE LITERALLY '0FFH';
/* CP/M BDOS SYSTEM CALL */
BDOS: PROCEDURE( FN, ARG ); DECLARE FN BYTE, ARG ADDRESS; GOTO 5; END;
PR$CHAR: PROCEDURE( C ); DECLARE C BYTE; CALL BDOS( 2, C ); END;
PR$STRING: PROCEDURE( S ); DECLARE S ADDRESS; CALL BDOS( 9, S ); END;
PR$NL: PROCEDURE; CALL PR$STRING( .( 0DH, 0AH, '$' ) ); END;
PR$NUMBER: PROCEDURE( N );
DECLARE N ADDRESS;
DECLARE V ADDRESS, N$STR( 6 ) BYTE, W BYTE;
N$STR( W := LAST( N$STR ) ) = '$';
N$STR( W := W - 1 ) = '0' + ( ( V := N ) MOD 10 );
DO WHILE( ( V := V / 10 ) > 0 );
N$STR( W := W - 1 ) = '0' + ( V MOD 10 );
END;
CALL PR$STRING( .N$STR( W ) );
END PR$NUMBER;
/* INTEGER SUARE ROOT: BASED ON THE ONE IN THE PL/M FOR FROBENIUS NUMBERS */
SQRT: PROCEDURE( N )ADDRESS;
DECLARE ( N, X0, X1 ) ADDRESS;
IF N <= 3 THEN DO;
IF N = 0 THEN X0 = 0; ELSE X0 = 1;
END;
ELSE DO;
X0 = SHR( N, 1 );
DO WHILE( ( X1 := SHR( X0 + ( N / X0 ), 1 ) ) < X0 );
X0 = X1;
END;
END;
RETURN X0;
END SQRT;
IS$PRIME: PROCEDURE( N )BYTE; /* RETURNS TRUE IF N IS PRIME, FALSE IF NOT */
DECLARE N ADDRESS;
IF N < 2 THEN RETURN FALSE;
ELSE IF ( N AND 1 ) = 0 THEN RETURN N = 2;
ELSE DO;
/* ODD NUMBER > 2 */
DECLARE I ADDRESS;
DO I = 3 TO SQRT( N ) BY 2;
IF N MOD I = 0 THEN RETURN FALSE;
END;
RETURN TRUE;
END;
END IS$PRIME;
/* TEST THE IS$PRIME PROCEDURE */
DECLARE I ADDRESS;
DO I = 0 TO 100;
IF IS$PRIME( I ) THEN DO;
CALL PR$CHAR( ' ' );
CALL PR$NUMBER( I );
END;
END;
CALL PR$NL;
EOF
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
PowerShell
function isPrime ($n) {
if ($n -eq 1) {$false}
elseif ($n -eq 2) {$true}
elseif ($n -eq 3) {$true}
else{
$m = [Math]::Floor([Math]::Sqrt($n))
(@(2..$m | where {($_ -lt $n) -and ($n % $_ -eq 0) }).Count -eq 0)
}
}
1..15 | foreach{"isPrime $_ : $(isPrime $_)"}
Output:
isPrime 1 : False isPrime 2 : True isPrime 3 : True isPrime 4 : False isPrime 5 : True isPrime 6 : False isPrime 7 : True isPrime 8 : False isPrime 9 : False isPrime 10 : False isPrime 11 : True isPrime 12 : False isPrime 13 : True isPrime 14 : False isPrime 15 : False
Prolog
The following predicate showcases Prolog's support for writing predicates suitable for both testing and generating. In this case, assuming the Prolog implemenation supports indefinitely large integers, prime(N) can be used to generate primes until memory is exhausted.
prime(2).
prime(N) :-
between(3, inf, N),
1 is N mod 2, % odd
M is floor(sqrt(N+1)), % round-off paranoia
Max is (M-1) // 2, % integer division
forall( between(1, Max, I), N mod (2*I+1) > 0 ).
Example using SWI-Prolog:
?- time( (bagof( P, (prime(P), ((P > 100000, !, fail); true)), Bag), length(Bag,N), last(Bag,Last), writeln( (N,Last) ) )). % 1,724,404 inferences, 1.072 CPU in 1.151 seconds (93% CPU, 1607873 Lips) Bag = [2, 3, 5, 7, 11, 13, 17, 19, 23|...], N = 9592, Last = 99991. ?- time( prime(99991) ). % 165 inferences, 0.000 CPU in 0.000 seconds (92% CPU, 1213235 Lips) true. ?-
Python
The simplest primality test, using trial division:
def prime(a):
return not (a < 2 or any(a % x == 0 for x in xrange(2, int(a**0.5) + 1)))
Another test. Exclude even numbers first:
def prime2(a):
if a == 2: return True
if a < 2 or a % 2 == 0: return False
return not any(a % x == 0 for x in xrange(3, int(a**0.5) + 1, 2))
Yet another test. Exclude multiples of 2 and 3, see http://www.devx.com/vb2themax/Tip/19051:
def prime3(a):
if a < 2: return False
if a == 2 or a == 3: return True # manually test 2 and 3
if a % 2 == 0 or a % 3 == 0: return False # exclude multiples of 2 and 3
maxDivisor = a**0.5
d, i = 5, 2
while d <= maxDivisor:
if a % d == 0: return False
d += i
i = 6 - i # this modifies 2 into 4 and viceversa
return True
By Regular Expression
Regular expression by "Abigail".
(An explanation is given in "The Story of the Regexp and the Primes").
>>> import re
>>> def isprime(n):
return not re.match(r'^1?$|^(11+?)\1+$', '1' * n)
>>> # A quick test
>>> [i for i in range(40) if isprime(i)]
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37]
Qi
(define prime?-0
K N -> true where (> (* K K) N)
K N -> false where (= 0 (MOD N K))
K N -> (prime?-0 (+ K 2) N))
(define prime?
1 -> false
2 -> true
N -> false where (= 0 (MOD N 2))
N -> (prime?-0 3 N))
Quackery
sqrt+
is defined at Isqrt (integer square root) of X#Quackery.
[ dup 4 < iff [ 1 > ] done
dup 1 & not iff [ drop false ] done
true swap dup sqrt+
0 = iff [ 2drop not ] done
1 >> times
[ dup i^ 1 << 3 + mod 0 = if
[ dip not conclude ] ]
drop ] is isprime ( n --> b )
R
is.prime <- function(n) n == 2 || n > 2 && n %% 2 == 1 && (n < 9 || all(n %% seq(3, floor(sqrt(n)), 2) > 0))
which(sapply(1:100, is.prime))
# [1] 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
Racket
#lang racket
(define (prime? number)
(cond ((not (positive? number)) #f)
((= 1 number) #f)
((even? number) (= 2 number))
(else (for/and ((i (in-range 3 (ceiling (sqrt number)))))
(not (zero? (remainder number i)))))))
Raku
(formerly Perl 6) Here we use a "none" junction which will autothread through the %% "is divisible by" operator to assert that $i is not divisible by 2 or any of the numbers up to its square root. Read it just as you would English: "Integer $i is prime if it is greater than one and is divisible by none of 2, 3, up to the square root of $i."
sub prime (Int $i --> Bool) {
$i > 1 and so $i %% none 2..$i.sqrt;
}
This can easily be improved in two ways. First, we generate the primes so we only divide by those, instead of all odd numbers. Second, we memoize the result using the //= idiom of Perl, which does the right-hand calculation and assigns it only if the left side is undefined. We avoid recalculating the square root each time. Note the mutual recursion that depends on the implicit laziness of list evaluation:
my @primes = 2, 3, 5, -> $p { ($p+2, $p+4 ... &prime)[*-1] } ... *;
my @isprime = False,False; # 0 and 1 are not prime by definition
sub prime($i) {
my \limit = $i.sqrt.floor;
@isprime[$i] //= so ($i %% none @primes ...^ { $_ > limit })
}
say "$_ is{ "n't" x !prime($_) } prime." for 1 .. 100;
REBOL
prime?: func [n] [
case [
n = 2 [ true ]
n <= 1 or (n // 2 = 0) [ false ]
true [
for i 3 round square-root n 2 [
if n // i = 0 [ return false ]
]
true
]
]
]
repeat i 100 [ print [i prime? i]]
REXX
compact version
This version uses a technique which increments by six for testing primality (up to the √ n ).
Programming note: all the REXX programs below show all primes up and including the number specified.
- If the number is negative, the absolute value of it is used for the upper limit, but no primes are shown.
- The number of primes found is always shown.
Also, it was determined that computing the (integer) square root of the number to be tested in the isPrime
function slowed up the function (for all three REXX versions), however, for larger numbers of N, it would
be faster.
/*REXX program tests for primality by using (kinda smartish) trial division. */
parse arg n .; if n=='' then n=10000 /*let the user choose the upper limit. */
tell=(n>0); n=abs(n) /*display the primes only if N > 0. */
p=0 /*a count of the primes found (so far).*/
do j=-57 to n /*start in the cellar and work up. */
if \isPrime(j) then iterate /*if not prime, then keep looking. */
p=p+1 /*bump the jelly bean counter. */
if tell then say right(j,20) 'is prime.' /*maybe display prime to the terminal. */
end /*j*/
say
say "There are " p " primes up to " n ' (inclusive).'
exit /*stick a fork in it, we're all done. */
/*──────────────────────────────────────────────────────────────────────────────────────*/
isPrime: procedure; parse arg x /*get the number to be tested. */
if wordpos(x, '2 3 5 7')\==0 then return 1 /*is number a teacher's pet? */
if x<2 | x//2==0 | x//3==0 then return 0 /*weed out the riff-raff. */
do k=5 by 6 until k*k>x /*skips odd multiples of 3. */
if x//k==0 | x//(k+2)==0 then return 0 /*a pair of divides. ___ */
end /*k*/ /*divide up through the √ x */
/*Note: // is ÷ remainder.*/
return 1 /*done dividing, it's prime. */
- output when using the default input of: 100
2 is prime. 3 is prime. 5 is prime. 7 is prime. 11 is prime. 13 is prime. 17 is prime. 19 is prime. 23 is prime. 29 is prime. 31 is prime. 37 is prime. 41 is prime. 43 is prime. 47 is prime. 53 is prime. 59 is prime. 61 is prime. 67 is prime. 71 is prime. 73 is prime. 79 is prime. 83 is prime. 89 is prime. 97 is prime. There are 25 primes up to 100 (inclusive).
optimized version
This version separates multiple-clause if statements, and also tests for low primes,
making it about 8% faster.
/*REXX program tests for primality by using (kinda smartish) trial division. */
parse arg n .; if n=='' then n=10000 /*let the user choose the upper limit. */
tell=(n>0); n=abs(n) /*display the primes only if N > 0. */
p=0 /*a count of the primes found (so far).*/
do j=-57 to n /*start in the cellar and work up. */
if \isPrime(j) then iterate /*if not prime, then keep looking. */
p=p+1 /*bump the jelly bean counter. */
if tell then say right(j,20) 'is prime.' /*maybe display prime to the terminal. */
end /*j*/
say
say "There are " p " primes up to " n ' (inclusive).'
exit /*stick a fork in it, we're all done. */
/*──────────────────────────────────────────────────────────────────────────────────────*/
isPrime: procedure; parse arg x /*get integer to be investigated.*/
if x<11 then return wordpos(x, '2 3 5 7')\==0 /*is it a wee prime? */
if x//2==0 then return 0 /*eliminate all the even numbers.*/
if x//3==0 then return 0 /* ··· and eliminate the triples.*/
do k=5 by 6 until k*k>x /*this skips odd multiples of 3. */
if x//k ==0 then return 0 /*perform a divide (modulus), */
if x//(k+2)==0 then return 0 /* ··· and the next umpty one. */
end /*k*/ /*Note: REXX // is ÷ remainder.*/
return 1 /*did all divisions, it's prime. */
- output is identical to the first version when the same input is used.
unrolled version
This version uses an unrolled version (of the 2nd version) of some multiple-clause if statements, and
also an optimized version of the testing of low primes is used, making it about 22% faster.
Note that the do ... until ... was changed to do ... while ....
/*REXX program tests for primality by using (kinda smartish) trial division. */
parse arg n .; if n=='' then n=10000 /*let the user choose the upper limit. */
tell=(n>0); n=abs(n) /*display the primes only if N > 0. */
p=0 /*a count of the primes found (so far).*/
do j=-57 to n /*start in the cellar and work up. */
if \isPrime(j) then iterate /*if not prime, then keep looking. */
p=p+1 /*bump the jelly bean counter. */
if tell then say right(j,20) 'is prime.' /*maybe display prime to the terminal. */
end /*j*/
say
say "There are " p " primes up to " n ' (inclusive).'
exit /*stick a fork in it, we're all done. */
/*──────────────────────────────────────────────────────────────────────────────────────*/
isPrime: procedure; parse arg x /*get the integer to be investigated. */
if x<107 then return wordpos(x, '2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53',
'59 61 67 71 73 79 83 89 97 101 103')\==0 /*some low primes.*/
if x// 2 ==0 then return 0 /*eliminate all the even numbers. */
if x// 3 ==0 then return 0 /* ··· and eliminate the triples. */
parse var x '' -1 _ /* obtain the rightmost digit.*/
if _ ==5 then return 0 /* ··· and eliminate the nickels. */
if x// 7 ==0 then return 0 /* ··· and eliminate the luckies. */
if x//11 ==0 then return 0
if x//13 ==0 then return 0
if x//17 ==0 then return 0
if x//19 ==0 then return 0
if x//23 ==0 then return 0
if x//29 ==0 then return 0
if x//31 ==0 then return 0
if x//37 ==0 then return 0
if x//41 ==0 then return 0
if x//43 ==0 then return 0
if x//47 ==0 then return 0
if x//53 ==0 then return 0
if x//59 ==0 then return 0
if x//61 ==0 then return 0
if x//67 ==0 then return 0
if x//71 ==0 then return 0
if x//73 ==0 then return 0
if x//79 ==0 then return 0
if x//83 ==0 then return 0
if x//89 ==0 then return 0
if x//97 ==0 then return 0
if x//101==0 then return 0
if x//103==0 then return 0 /*Note: REXX // is ÷ remainder. */
do k=107 by 6 while k*k<=x /*this skips odd multiples of three. */
if x//k ==0 then return 0 /*perform a divide (modulus), */
if x//(k+2)==0 then return 0 /* ··· and the next also. ___ */
end /*k*/ /*divide up through the √ x */
return 1 /*after all that, ··· it's a prime. */
- output is identical to the first version when the same input is used.
Ring
give n
flag = isPrime(n)
if flag = 1 see n + " is a prime number"
else see n + " is not a prime number" ok
func isPrime num
if (num <= 1) return 0 ok
if (num % 2 = 0 and num != 2) return 0 ok
for i = 3 to floor(num / 2) -1 step 2
if (num % i = 0) return 0 ok
next
return 1
RPL
This version use binary integers
RPL code | Comment |
---|---|
≪ / LAST ROT * - #0 == ≫ 'BDIV?' STO ≪ IF DUP #3 ≤ THEN #2 / B→R ELSE IF DUP #2 BDIV? OVER #3 BDIV? OR THEN DROP 0 ELSE DUP B→R √ R→B → a maxd ≪ a #2 #5 1 SF WHILE 1 FS? OVER maxd ≤ AND REPEAT IF a OVER BDIV? THEN 1 CF END OVER + #6 ROT - SWAP END ≫ SWAP DROP BDIV? NOT END END ≫ 'BPRIM?' STO |
BDIV? ( #a #b -- boolean ) BPRIM? ( #a -- boolean ) return 1 if a is 2 or 3 if 2 or 3 divides a return 0 else store a and root(a) initialize stack with a i d and set flag 1 to control loop exit while d <= root(a) prepare loop exit if d divides a i = 6 - i which modifies 2 into 4 and viceversa empty stack and return result |
Floating point version
Faster but limited to 1E12.
≪ IF DUP 5 ≤ THEN { 2 3 5 } SWAP POS
ELSE
IF DUP 2 MOD NOT THEN 2
ELSE
DUP √ CEIL → lim
≪ 3 WHILE DUP2 MOD OVER lim ≤ AND REPEAT 2 + END
≫
END MOD
END SIGN
≫ 'PRIM?' STO
Ruby
def prime(a)
if a == 2
true
elsif a <= 1 || a % 2 == 0
false
else
divisors = (3..Math.sqrt(a)).step(2)
divisors.none? { |d| a % d == 0 }
end
end
p (1..50).select{|i| prime(i)}
The prime package in the stdlib for Ruby contains this compact Prime#prime?
method:
require "prime"
def prime?(value, generator = Prime::Generator23.new)
return false if value < 2
for num in generator
q,r = value.divmod num
return true if q < num
return false if r == 0
end
end
p (1..50).select{|i| prime?(i)}
Without any fancy stuff:
def primes(limit)
(enclose = lambda { |primes|
primes.last.succ.upto(limit) do |trial_pri|
if primes.none? { |pri| (trial_pri % pri).zero? }
return enclose.call(primes << trial_pri)
end
end
primes
}).call([2])
end
p primes(50)
- Output:
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47]
By Regular Expression
def isprime(n)
'1'*n !~ /^1?$|^(11+?)\1+$/
end
Prime Generators Tests
Mathematicaly basis of Prime Generators https://www.academia.edu/19786419/PRIMES-UTILS_HANDBOOK https://www.academia.edu/42734410/Improved_Primality_Testing_and_Factorization_in_Ruby_revised
require "benchmark/ips"
# the simplest PG primality test using the P3 prime generator
# reduces the number space for primes to 2/6 (33.33%) of all integers
def primep3?(n) # P3 Prime Generator primality test
# P3 = 6*k + {5, 7} # P3 primes candidates (pc) sequence
return n | 1 == 3 if n < 5 # n: 0,1,4|false, 2,3|true
return false if n.gcd(6) != 1 # 1/3 (2/6) of integers are P3 pc
p, sqrtn = 5, Integer.sqrt(n) # first P3 sequence value
until p > sqrtn
return false if n % p == 0 || n % (p + 2) == 0 # if n is composite
p += 6 # first prime candidate for next kth residues group
end
true
end
# PG primality test using the P5 prime generator
# reduces the number space for primes to 8/30 (26.67%) of all integers
def primep5?(n) # P5 Prime Generator primality test
# P5 = 30*k + {7,11,13,17,19,23,29,31} # P5 primes candidates sequence
return [2, 3, 5].include?(n) if n < 7 # for small and negative values
return false if n.gcd(30) != 1 # 4/15 (8/30) of integers are P5 pc
p, sqrtn = 7, Integer.sqrt(n) # first P5 sequence value
until p > sqrtn
return false if # if n is composite
n % (p) == 0 || n % (p+4) == 0 || n % (p+6) == 0 || n % (p+10) == 0 ||
n % (p+12) == 0 || n % (p+16) == 0 || n % (p+22) == 0 || n % (p+24) == 0
p += 30 # first prime candidate for next kth residues group
end
true
end
# PG primality test using the P7 prime generator
# reduces the number space for primes to 48/210 (22.86%) of all integers
def primep7?(n)
# P7 = 210*k + {11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,
# 89,97,101,103,107,109,113,121,127,131,137,139,143,149,151,157,163,
# 167,169,173,179,181,187,191,193,197,199,209,211}
return [2, 3, 5, 7].include?(n) if n < 11
return false if n.gcd(210) != 1 # 8/35 (48/210) of integers are P7 pc
p, sqrtn = 11, Integer.sqrt(n) # first P7 sequence value
until p > sqrtn
return false if
n % (p) == 0 || n % (p+2) == 0 || n % (p+6) == 0 || n % (p+8) == 0 ||
n % (p+12) == 0 || n % (p+18) == 0 || n % (p+20) == 0 || n % (p+26) == 0 ||
n % (p+30) == 0 || n % (p+32) == 0 || n % (p+36) == 0 || n % (p+42) == 0 ||
n % (p+48) == 0 || n % (p+50) == 0 || n % (p+56) == 0 || n % (p+60) == 0 ||
n % (p+62) == 0 || n % (p+68) == 0 || n % (p+72) == 0 || n % (p+78) == 0 ||
n % (p+86) == 0 || n % (p+90) == 0 || n % (p+92) == 0 || n % (p+96) == 0 ||
n % (p+98) == 0 || n % (p+102) == 0 || n % (p+110) == 0 || n % (p+116) == 0 ||
n % (p+120) == 0 || n % (p+126) == 0 || n % (p+128) == 0 || n % (p+132) == 0 ||
n % (p+138) == 0 || n % (p+140) == 0 || n % (p+146) == 0 || n % (p+152) == 0 ||
n % (p+156) == 0 || n % (p+158) == 0 || n % (p+162) == 0 || n % (p+168) == 0 ||
n % (p+170) == 0 || n % (p+176) == 0 || n % (p+180) == 0 || n % (p+182) == 0 ||
n % (p+186) == 0 || n % (p+188) == 0 || n % (p+198) == 0 || n % (p+200) == 0
p += 210 # first prime candidate for next kth residues group
end
true
end
# Benchmarks to test for various size primes
p = 541
Benchmark.ips do |b|
print "\np = #{p}"
b.report("primep3?") { primep3?(p) }
b.report("primep5?") { primep5?(p) }
b.report("primep7?") { primep7?(p) }
b.compare!
puts
end
p = 1000003
Benchmark.ips do |b|
print "\np = #{p}"
b.report("primep3?") { primep3?(p) }
b.report("primep5?") { primep5?(p) }
b.report("primep7?") { primep7?(p) }
b.compare!
puts
end
p = 4294967291 # largest prime < 2**32
Benchmark.ips do |b|
print "\np = #{p}"
b.report("primep3?") { primep3?(p) }
b.report("primep5?") { primep5?(p) }
b.report("primep7?") { primep7?(p) }
b.compare!
puts
end
p = (10 ** 16) * 2 + 3
Benchmark.ips do |b|
print "\np = #{p}"
b.report("primep3?") { primep3?(p) }
b.report("primep5?") { primep5?(p) }
b.report("primep7?") { primep7?(p) }
b.compare!
puts
end
- Output:
p = 541 Warming up -------------------------------------- primep3? 109.893k i/100ms primep5? 123.949k i/100ms primep7? 44.216k i/100ms Calculating ------------------------------------- primep3? 1.598M (± 3.4%) i/s - 8.022M in 5.025036s primep5? 1.872M (± 6.3%) i/s - 9.420M in 5.059896s primep7? 502.040k (± 1.2%) i/s - 2.520M in 5.020919s Comparison: primep5?: 1871959.0 i/s primep3?: 1598489.8 i/s - 1.17x slower primep7?: 502039.8 i/s - 3.73x slower p = 1000003 Warming up -------------------------------------- primep3? 5.850k i/100ms primep5? 9.013k i/100ms primep7? 10.889k i/100ms Calculating ------------------------------------- primep3? 59.965k (± 1.1%) i/s - 304.200k in 5.073641s primep5? 92.561k (± 2.1%) i/s - 468.676k in 5.065709s primep7? 109.335k (± 0.8%) i/s - 555.339k in 5.079549s Comparison: primep7?: 109334.7 i/s primep5?: 92561.4 i/s - 1.18x slower primep3?: 59964.5 i/s - 1.82x slower p = 4294967291 Warming up -------------------------------------- primep3? 92.000 i/100ms primep5? 148.000 i/100ms primep7? 184.000 i/100ms Calculating ------------------------------------- primep3? 926.647 (± 1.1%) i/s - 4.692k in 5.064067s primep5? 1.480k (± 1.7%) i/s - 7.400k in 5.001399s primep7? 1.804k (± 1.0%) i/s - 9.200k in 5.099110s Comparison: primep7?: 1804.4 i/s primep5?: 1480.0 i/s - 1.22x slower primep3?: 926.6 i/s - 1.95x slower p = 20000000000000003 Warming up -------------------------------------- primep3? 1.000 i/100ms primep5? 1.000 i/100ms primep7? 1.000 i/100ms Calculating ------------------------------------- primep3? 0.422 (± 0.0%) i/s - 3.000 in 7.115929s primep5? 0.671 (± 0.0%) i/s - 4.000 in 5.957077s primep7? 0.832 (± 0.0%) i/s - 5.000 in 6.007834s Comparison: primep7?: 0.8 i/s primep5?: 0.7 i/s - 1.24x slower primep3?: 0.4 i/s - 1.97x slower
Rust
fn is_prime(n: u64) -> bool {
match n {
0 | 1 => false,
2 => true,
_even if n % 2 == 0 => false,
_ => {
let sqrt_limit = (n as f64).sqrt() as u64;
(3..=sqrt_limit).step_by(2).find(|i| n % i == 0).is_none()
}
}
}
fn main() {
for i in (1..30).filter(|i| is_prime(*i)) {
println!("{} ", i);
}
}
- Output:
2 3 5 7 11 13 17 19 23 29
S-lang
define is_prime(n)
{
if (n == 2) return(1);
if (n <= 1) return(0);
if ((n & 1) == 0) return(0);
variable mx = int(sqrt(n)), i;
_for i (3, mx, 1) {
if ((n mod i) == 0)
return(0);
}
return(1);
}
define ptest()
{
variable lst = {};
_for $1 (1, 64, 1)
if (is_prime($1))
list_append(lst, string($1));
print(strjoin(list_to_array(lst), ", "));
}
ptest();
- Output:
"2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61"
SAS
data primes;
do n=1 to 1000;
link primep;
if primep then output;
end;
stop;
primep:
if n < 4 then do;
primep=n=2 or n=3;
return;
end;
primep=0;
if mod(n,2)=0 then return;
do k=3 to sqrt(n) by 2;
if mod(n,k)=0 then return;
end;
primep=1;
return;
keep n;
run;
Scala
Simple version
def isPrime(n: Int) =
n > 1 && (Iterator.from(2) takeWhile (d => d * d <= n) forall (n % _ != 0))
Accelerated version FP and parallel runabled
//
- Output:
Best seen running in your browser Scastie (remote JVM).
object IsPrimeTrialDivision extends App {
def isPrime(n: Long) =
n > 1 && ((n & 1) != 0 || n == 2) && (n % 3 != 0 || n == 3) &&
(5 to math.sqrt(n).toInt by 6).par.forall(d => n % d != 0 && n % (d + 2) != 0)
assert(!isPrime(-1))
assert(!isPrime(1))
assert(isPrime(2))
assert(isPrime(100000000003L))
assert(isPrime(100000000019L))
assert(isPrime(100000000057L))
assert(isPrime(100000000063L))
assert(isPrime(100000000069L))
assert(isPrime(100000000073L))
assert(isPrime(100000000091L))
println("10 Numbers tested. A moment please …\nNumber crunching biggest 63-bit prime …")
assert(isPrime(9223372036854775783L)) // Biggest 63-bit prime
println("All done")
}
Accelerated version FP, tail recursion
Tests 1.3 M numbers against OEIS prime numbers.
import scala.annotation.tailrec
import scala.io.Source
object PrimesTestery extends App {
val rawText = Source.fromURL("https://oeis.org/A000040/a000040.txt")
val oeisPrimes = rawText.getLines().take(100000).map(_.split(" ")(1)).toVector
def isPrime(n: Long) = {
@tailrec
def inner(d: Int, end: Int): Boolean = {
if (d > end) true
else if (n % d != 0 && n % (d + 2) != 0) inner(d + 6, end) else false
}
n > 1 && ((n & 1) != 0 || n == 2) &&
(n % 3 != 0 || n == 3) && inner(5, math.sqrt(n).toInt)
}
println(oeisPrimes.size)
for (i <- 0 to 1299709) assert(isPrime(i) == oeisPrimes.contains(i.toString), s"Wrong $i")
}
Scheme
(define (prime? number)
(define (*prime? divisor)
(or (> (* divisor divisor) number)
(and (> (modulo number divisor) 0)
(*prime? (+ divisor 1)))))
(and (> number 1)
(*prime? 2)))
; twice faster, testing only odd divisors
(define (prime? n)
(if (< n 4) (> n 1)
(and (odd? n)
(let loop ((k 3))
(or (> (* k k) n)
(and (positive? (remainder n k))
(loop (+ k 2))))))))
Seed7
const func boolean: isPrime (in integer: number) is func
result
var boolean: prime is FALSE;
local
var integer: upTo is 0;
var integer: testNum is 3;
begin
if number = 2 then
prime := TRUE;
elsif odd(number) and number > 2 then
upTo := sqrt(number);
while number rem testNum <> 0 and testNum <= upTo do
testNum +:= 2;
end while;
prime := testNum > upTo;
end if;
end func;
Original source: [3]
SETL
program trial_division;
print({n : n in {1..100} | prime n});
op prime(n);
return n>=2 and not exists d in {2..floor sqrt n} | n mod d = 0;
end op;
end program;
- Output:
{2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97}
Sidef
func is_prime(a) {
given (a) {
when (2) { true }
case (a <= 1 || a.is_even) { false }
default { 3 .. a.isqrt -> any { .divides(a) } -> not }
}
}
Alternative version, excluding multiples of 2 and 3:
func is_prime(n) {
return (n >= 2) if (n < 4)
return false if (n%%2 || n%%3)
for k in (5 .. n.isqrt -> by(6)) {
return false if (n%%k || n%%(k+2))
}
return true
}
Smalltalk
| isPrime |
isPrime := [:n |
n even ifTrue: [ ^n=2 ]
ifFalse: [
3 to: n sqrt do: [:i |
(n \\ i = 0) ifTrue: [ ^false ]
].
^true
]
]
SNOBOL4
define('isprime(n)i,max') :(isprime_end)
isprime isprime = n
le(n,1) :s(freturn)
eq(n,2) :s(return)
eq(remdr(n,2),0) :s(freturn)
max = sqrt(n); i = 1
isp1 i = le(i + 2,max) i + 2 :f(return)
eq(remdr(n,i),0) :s(freturn)f(isp1)
isprime_end
By Patterns
Using the Abigail regex transated to Snobol patterns.
define('rprime(n)str,pat1,pat2,m1') :(end_rprime)
rprime str = dupl('1',n); rprime = n
pat1 = ('1' | '')
pat2 = ('11' arbno('1')) $ m1 (*m1 arbno(*m1))
str pos(0) (pat1 | pat2) rpos(0) :s(freturn)f(return)
end_rprime
* # Test and display primes 0 .. 50
loop rprimes = rprimes rprime(n) ' '
n = lt(n,50) n + 1 :s(loop)
output = rprimes
end
- Output:
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
SparForte
As a structured script.
#!/usr/local/bin/spar
pragma annotate( summary, "prime" );
pragma annotate( description, "Write a boolean function that tells whether a given" );
pragma annotate( description, "integer is prime. Remember that 1 and all" );
pragma annotate( description, "non-positive numbers are not prime. " );
pragma annotate( see_also, "http://rosettacode.org/wiki/Primality_by_trial_division" );
pragma annotate( author, "Ken O. Burtch" );
pragma license( unrestricted );
pragma restriction( no_external_commands );
procedure prime is
function is_prime(item : positive) return boolean is
result : boolean := true;
test : natural;
begin
if item /= 2 and item mod 2 = 0 then
result := false;
else
test := 3;
while test < natural( numerics.sqrt( item ) ) loop
if natural(item) mod test = 0 then
result := false;
exit;
end if;
test := @ + 2;
end loop;
end if;
return result;
end is_prime;
number : positive;
result : boolean;
begin
number := 6;
result := is_prime( number );
put( number ) @ ( " : " ) @ ( result );
new_line;
number := 7;
result := is_prime( number );
put( number ) @ ( " : " ) @ ( result );
new_line;
number := 8;
result := is_prime( number );
put( number ) @ ( " : " ) @ ( result );
new_line;
end prime;
SQL
declare @number int
set @number = 514229 -- number to check
;with cte(number) as
(
select 2
union all
select number+1
from cte
where number+1 < @number
)
select
cast(@number as varchar(100)) +
case
when exists
(
select *
from
(
select number, @number % number modNumber
from cte
) tmp
where tmp.modNumber = 0
)
then ' is composite'
else
' is prime'
end primalityTest
option (maxrecursion 0)
Standard ML
fun is_prime n =
if n = 2 then true
else if n < 2 orelse n mod 2 = 0 then false
else let
fun loop k =
if k * k > n then true
else if n mod k = 0 then false
else loop (k+2)
in loop 3
end
Swift
import Foundation
extension Int {
func isPrime() -> Bool {
switch self {
case let x where x < 2:
return false
case 2:
return true
default:
return
self % 2 != 0 &&
!stride(from: 3, through: Int(sqrt(Double(self))), by: 2).contains {self % $0 == 0}
}
}
}
A version that works with Swift 5.x and probably later. Does not need to import Foundation
extension Int
{
func isPrime() -> Bool
{
if self < 3
{
return self == 2
}
else
{
let upperLimit = Int(Double(self).squareRoot())
return !self.isMultiple(of: 2) && !stride(from: 3, through: upperLimit, by: 2)
.contains(where: { factor in self.isMultiple(of: factor) })
}
}
}
Tcl
proc is_prime n {
if {$n <= 1} {return false}
if {$n == 2} {return true}
if {$n % 2 == 0} {return false}
for {set i 3} {$i <= sqrt($n)} {incr i 2} {
if {$n % $i == 0} {return false}
}
return true
}
UNIX Shell
function primep {
typeset n=$1 p=3
(( n == 2 )) && return 0 # 2 is prime.
(( n & 1 )) || return 1 # Other evens are not prime.
(( n >= 3 )) || return 1
# Loop for odd p from 3 to sqrt(n).
# Comparing p * p <= n can overflow.
while (( p <= n / p )); do
# If p divides n, then n is not prime.
(( n % p )) || return 1
(( p += 2 ))
done
return 0 # Yes, n is prime.
}
primep() {
set -- "$1" 3
test "$1" -eq 2 && return 0 # 2 is prime.
expr "$1" \% 2 >/dev/null || return 1 # Other evens are not prime.
test "$1" -ge 3 || return 1
# Loop for odd p from 3 to sqrt(n).
# Comparing p * p <= n can overflow. We use p <= n / p.
while expr $2 \<= "$1" / $2 >/dev/null; do
# If p divides n, then n is not prime.
expr "$1" % $2 >/dev/null || return 1
set -- "$1" `expr $2 + 2`
done
return 0 # Yes, n is prime.
}
Ursala
Excludes even numbers, and loops only up to the approximate square root or until a factor is found.
#import std
#import nat
prime = ~<{0,1}&& -={2,3}!| ~&h&& (all remainder)^Dtt/~& iota@K31
Test program to try it on a few numbers:
#cast %bL
test = prime* <5,6,7>
- Output:
<true,false,true>
V
[prime?
2
[[dup * >] [true] [false] ifte [% 0 >] dip and]
[succ]
while
dup * <].
- Using it:
|11 prime?
=true
|4 prime?
=false
Verilog
module main;
integer i, k;
initial begin
$display("Prime numbers between 0 and 100:");
for(i = 2; i <= 99; i=i+1) begin
k=i;
if(i[0] != 1'b0) begin
if(k==3 | k==5 | k==7 | k==11 | k==13 | k==17 | k==19) $write(i);
else if(k%3==0 | k%5==0 | k%7==0 | k%11==0 | k%13==0 | k%17==0 | k%19==0) $write("");
else $write(i);
end
if(i==10'b00 | i==10'b010) $write(i);
end
$finish;
end
endmodule
V (Vlang)
import math
const numbers = [5, 3, 14, 19, 25, 59, 88]
fn main() {
for num in numbers {
println("${num} is a prime number? " + if is_prime(num) == true {'yes'} else {'no'})
}
}
fn is_prime(num int) bool {
if num <= 1 {return false}
if num % 2 == 0 && num != 2 {return false}
for idx := 3; idx <= math.floor(num / 2) - 1; idx += 2 {
if num % idx == 0 {return false}
}
return true
}
- Output:
5 is a prime number? yes 3 is a prime number? yes 14 is a prime number? no 19 is a prime number? yes 25 is a prime number? no 59 is a prime number? yes 88 is a prime number? no
Wren
import "./fmt" for Fmt
var isPrime = Fn.new { |n|
if (n < 2) return false
if (n%2 == 0) return n == 2
var p = 3
while (p * p <= n) {
if (n%p == 0) return false
p = p + 2
}
return true
}
var tests = [2, 5, 12, 19, 57, 61, 97]
System.print("Are the following prime?")
for (test in tests) {
Fmt.print("$2d -> $y", test, isPrime.call(test))
}
- Output:
Are the following prime? 2 -> yes 5 -> yes 12 -> no 19 -> yes 57 -> no 61 -> yes 97 -> yes
XPL0
func Prime(N); \Return 'true' if N is a prime number
int N;
int I;
[if N <= 1 then return false;
for I:= 2 to sqrt(N) do
if rem(N/I) = 0 then return false;
return true;
];
int Num;
repeat Num:= IntIn(0);
Text(0, if Prime(Num) then "is " else "not ");
Text(0, "prime^M^J");
until Num = 0
- Output:
777777777 not prime 777777773 is prime 0 not prime
zkl
The Method filter1 stops at the first non False result, which, if there is one, is the first found diviser, thus short cutting the rest of the test
fcn isPrime(n){
if(n.isEven or n<2) return(n==2);
(not [3..n.toFloat().sqrt().toInt(),2].filter1('wrap(m){n%m==0}))
}
- Output:
zkl: [1..].filter(20,isPrime) L(2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71) zkl: isPrime(777777773) True zkl: isPrime(777777777) False
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