Category:PrimTrial: Difference between revisions
(Created page with "Unit at http://rosettacode.org/wiki/Primality_by_trial_division#improved_using_number_wheel") |
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unit primTrial
{{works with|Free Pascal}} {{works with|Delphi}}
Maybe NativeUint must be typed in older versions to LongWord aka cardinal
<lang pascal>
unit primTrial;
//NativeUInt: LongWord 32-Bit-OS/ Uint64 64-Bit-OS
{$IFDEF FPC}
{$MODE DELPHI}
{$Smartlink ON}
{$OPTIMIZATION ON,Regvar,PEEPHOLE,CSE,ASMCSE}
{$CODEALIGN proc=32}
{$ENDIF}
interface
procedure InitPrime;
function actPrime :NativeUint;
function isPrime(pr: NativeUint):boolean;
function isAlmostPrime(n: NativeUint;cnt: NativeUint): boolean;
function SmallFactor(pr: NativeUint):NativeUint;
//next prime
function NextPrime: NativeUint;
//next possible prime of number wheel
function NextPosPrim: NativeUint;
//next prime greater equal limit
function PrimeGELimit(Limit:NativeUint):NativeUint;
implementation
uses
sysutils;
const
cntsmallPrimes = 6;
smallPrimes : array[0..cntsmallPrimes-1] of NativeUint = (2,3,5,7,11,13);
wheelSize = (2-1)*(3-1)*(5-1)*(7-1)*(11-1)*(13-1);
wheelCircumfence = 2*3*5*7*11*13;
var
deltaWheel : array[0..wheelSize-1] of byte;
WheelIdx : nativeUint;
p,pw : nativeUint;
procedure InitPrime;
//initialies wheel and prime to startposition
Begin
p := 2;
pw := 1;
WheelIdx := 0;
end;
function actPrime :NativeUint;inline;
Begin
result := p;
end;
procedure InitWheel;
//search for numbers that are no multiples of smallprimes
//saving only the distance, to keep size small
var
p0,p1,i,d,res : NativeUint;
Begin
p0 := 1;d := 0;p1 := p0;
repeat
Repeat
p1 := p1+2;// only odd
i := 1;
repeat
res := p1 mod smallPrimes[i];
inc(i)
until (res =0)OR(i >= cntSmallPrimes);
if res <> 0 then
Begin
deltaWheel[d] := p1-p0;
inc(d);
break;
end;
until false;
p0 := p1;
until d >= wheelSize;
end;
function biggerFactor(p: NativeUint):NativeUint;
//trial division by wheel numbers
//reduces count of divisions from 1/2 = 0.5( only odd numbers )
//to 5760/30030 = 0.1918
var
sp : NativeUint;
d : NativeUint;
r : NativeUint;
Begin
sp := 1;d := 0;
repeat
sp := sp+deltaWheel[d];
r := p mod sp;
d := d+1;
//IF d = WheelSize then d := 0;
d := d AND NativeUint(-ord(d<>WheelSize));
IF r = 0 then
BREAK;
until p < sp*sp;
IF r = 0 then
result := sp
else
result := p;
end;
function SmallFactor(pr: NativeUint):NativeUint;
//checking numbers omitted by biggerFactor
var
k : NativeUint;
Begin
result := pr;
IF pr in [2,3,5,7,11,13] then
EXIT;
IF NOT(ODD(pr))then Begin result := 2; EXIT end;
For k := 1 to cntSmallPrimes-1 do
Begin
IF pr Mod smallPrimes[k] = 0 then
Begin
result := smallPrimes[k];
EXIT
end;
end;
k := smallPrimes[cntsmallPrimes-1];
IF pr>k*k then
result := biggerFactor(pr);
end;
function isPrime(pr: NativeUint):boolean;
Begin
IF pr > 1 then
isPrime := smallFactor(pr) = pr
else
isPrime := false;
end;
function isAlmostPrime(n: NativeUint;cnt: NativeUint): boolean;
var
fac1,c : NativeUint;
begin
c := 0;
repeat
fac1 := SmallFactor(n);
n := n div fac1;
inc(c);
until (n = 1) OR (c > cnt);
isAlmostPrime := (n = 1) AND (c = cnt);
end;
function isSemiprime(n: NativeUint): boolean;
begin
result := isAlmostPrime(n,2);
end;
function NextPosPrim: NativeUint;inline;
var
WI : NativeUint;
Begin
result := pw+deltaWheel[WheelIdx];
WI := (WheelIdx+1);
WheelIdx := WI AND NativeUint(-ORD(WI<>WheelSize));
pw := result;
end;
function NextPrime: NativeUint;
Begin
IF p >= smallPrimes[High(smallPrimes)]then
Begin
repeat
until isPrime(NextPosPrim);
result := pw;
p := result;
end
else
Begin
result := 0;
while p >= smallPrimes[result] do
inc(result);
result := smallPrimes[result];
p:= result;
end;
end;
function PrimeGELimit(Limit:NativeUint):NativeUint;
//prime greater or equal limit
Begin
IF Limit > wheelCircumfence then
Begin
WheelIdx:= wheelSize-1;
result := (Limit DIV wheelCircumfence)*wheelCircumfence-1;
pw := result;
//the easy way, no prime test
while pw <= Limit do
NextPosPrim;
result := pw;
p := result;
if Not(isPrime(result)) then
result := NextPrime;
end
else
Begin
InitPrime;
repeat
until (NextPosPrim >= limit) AND isPrime(pw);
result := pw;
p := result;
end;
end;
//initialization
Begin
InitWheel;
InitPrime;
end.</lang>
|
Revision as of 08:05, 14 February 2015
unit primTrial
Maybe NativeUint must be typed in older versions to LongWord aka cardinal
<lang pascal> unit primTrial; //NativeUInt: LongWord 32-Bit-OS/ Uint64 64-Bit-OS {$IFDEF FPC}
{$MODE DELPHI} {$Smartlink ON} {$OPTIMIZATION ON,Regvar,PEEPHOLE,CSE,ASMCSE} {$CODEALIGN proc=32}
{$ENDIF}
interface
procedure InitPrime; function actPrime :NativeUint; function isPrime(pr: NativeUint):boolean; function isAlmostPrime(n: NativeUint;cnt: NativeUint): boolean; function SmallFactor(pr: NativeUint):NativeUint; //next prime function NextPrime: NativeUint; //next possible prime of number wheel function NextPosPrim: NativeUint; //next prime greater equal limit function PrimeGELimit(Limit:NativeUint):NativeUint;
implementation
uses
sysutils;
const
cntsmallPrimes = 6; smallPrimes : array[0..cntsmallPrimes-1] of NativeUint = (2,3,5,7,11,13); wheelSize = (2-1)*(3-1)*(5-1)*(7-1)*(11-1)*(13-1); wheelCircumfence = 2*3*5*7*11*13;
var
deltaWheel : array[0..wheelSize-1] of byte; WheelIdx : nativeUint; p,pw : nativeUint;
procedure InitPrime; //initialies wheel and prime to startposition Begin
p := 2; pw := 1; WheelIdx := 0;
end;
function actPrime :NativeUint;inline; Begin
result := p;
end;
procedure InitWheel; //search for numbers that are no multiples of smallprimes //saving only the distance, to keep size small var
p0,p1,i,d,res : NativeUint;
Begin
p0 := 1;d := 0;p1 := p0; repeat Repeat p1 := p1+2;// only odd i := 1; repeat res := p1 mod smallPrimes[i]; inc(i) until (res =0)OR(i >= cntSmallPrimes); if res <> 0 then Begin deltaWheel[d] := p1-p0; inc(d); break; end; until false; p0 := p1; until d >= wheelSize;
end;
function biggerFactor(p: NativeUint):NativeUint; //trial division by wheel numbers //reduces count of divisions from 1/2 = 0.5( only odd numbers ) //to 5760/30030 = 0.1918 var
sp : NativeUint; d : NativeUint; r : NativeUint;
Begin
sp := 1;d := 0; repeat sp := sp+deltaWheel[d]; r := p mod sp; d := d+1; //IF d = WheelSize then d := 0; d := d AND NativeUint(-ord(d<>WheelSize)); IF r = 0 then BREAK; until p < sp*sp; IF r = 0 then result := sp else result := p;
end;
function SmallFactor(pr: NativeUint):NativeUint; //checking numbers omitted by biggerFactor var
k : NativeUint;
Begin
result := pr; IF pr in [2,3,5,7,11,13] then EXIT; IF NOT(ODD(pr))then Begin result := 2; EXIT end; For k := 1 to cntSmallPrimes-1 do Begin IF pr Mod smallPrimes[k] = 0 then Begin result := smallPrimes[k]; EXIT end; end; k := smallPrimes[cntsmallPrimes-1]; IF pr>k*k then result := biggerFactor(pr);
end;
function isPrime(pr: NativeUint):boolean; Begin
IF pr > 1 then isPrime := smallFactor(pr) = pr else isPrime := false;
end;
function isAlmostPrime(n: NativeUint;cnt: NativeUint): boolean; var
fac1,c : NativeUint;
begin
c := 0; repeat fac1 := SmallFactor(n); n := n div fac1; inc(c); until (n = 1) OR (c > cnt); isAlmostPrime := (n = 1) AND (c = cnt);
end;
function isSemiprime(n: NativeUint): boolean; begin
result := isAlmostPrime(n,2);
end;
function NextPosPrim: NativeUint;inline;
var
WI : NativeUint;
Begin
result := pw+deltaWheel[WheelIdx]; WI := (WheelIdx+1); WheelIdx := WI AND NativeUint(-ORD(WI<>WheelSize)); pw := result;
end;
function NextPrime: NativeUint; Begin
IF p >= smallPrimes[High(smallPrimes)]then Begin repeat until isPrime(NextPosPrim); result := pw; p := result; end else Begin result := 0; while p >= smallPrimes[result] do inc(result); result := smallPrimes[result]; p:= result; end;
end;
function PrimeGELimit(Limit:NativeUint):NativeUint; //prime greater or equal limit Begin
IF Limit > wheelCircumfence then Begin WheelIdx:= wheelSize-1; result := (Limit DIV wheelCircumfence)*wheelCircumfence-1; pw := result; //the easy way, no prime test while pw <= Limit do NextPosPrim; result := pw; p := result; if Not(isPrime(result)) then result := NextPrime; end else Begin InitPrime; repeat until (NextPosPrim >= limit) AND isPrime(pw); result := pw; p := result; end;
end; //initialization Begin
InitWheel; InitPrime;
end.</lang>
Pages in category "PrimTrial"
The following 11 pages are in this category, out of 11 total.