Cullen and Woodall numbers: Difference between revisions
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Cullen and Woodall numbers in various dialects BASIC (Gambas, Run BASIC and XBasic) |
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=={{header|BASIC}}== |
=={{header|BASIC}}== |
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==={{header|BASIC256}}=== |
==={{header|BASIC256}}=== |
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{{works with|Run BASIC}} |
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{{works with|Just BASIC}} |
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{{works with|Liberty BASIC}} |
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{{trans|FreeBASIC}} |
{{trans|FreeBASIC}} |
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<syntaxhighlight lang="basic256">print "First 20 Cullen numbers:" |
<syntaxhighlight lang="basic256">print "First 20 Cullen numbers:" |
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end</syntaxhighlight> |
end</syntaxhighlight> |
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{{out}} |
{{out}} |
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<pre> |
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</pre> |
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==={{header|FreeBASIC}}=== |
==={{header|FreeBASIC}}=== |
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<syntaxhighlight lang=" |
<syntaxhighlight lang="vb">Dim As Uinteger n, num |
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Print "First 20 Cullen numbers:" |
Print "First 20 Cullen numbers:" |
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First 20 Woodall numbers: |
First 20 Woodall numbers: |
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1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519</pre> |
1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519</pre> |
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==={{header|Gambas}}=== |
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<syntaxhighlight lang="vbnet">Public Sub Main() |
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Dim n, num As Integer |
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Print "First 20 Cullen numbers:" |
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For n = 1 To 20 |
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num = n * (2 ^ n) + 1 |
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Print num; " "; |
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Next |
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Print "\n\nFirst 20 Woodall numbers:" |
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For n = 1 To 20 |
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num = n * (2 ^ n) - 1 |
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Print num; " "; |
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Next |
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End </syntaxhighlight> |
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{{out}} |
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<pre>Same as FreeBASIC entry.</pre> |
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==={{header|PureBasic}}=== |
==={{header|PureBasic}}=== |
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CloseConsole()</syntaxhighlight> |
CloseConsole()</syntaxhighlight> |
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{{out}} |
{{out}} |
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<pre> |
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</pre> |
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==={{header|QBasic}}=== |
==={{header|QBasic}}=== |
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END</syntaxhighlight> |
END</syntaxhighlight> |
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{{out}} |
{{out}} |
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<pre> |
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==={{header|Run BASIC}}=== |
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</pre> |
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{{works with|BASIC256}} |
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{{works with|Just BASIC}} |
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{{works with|Liberty BASIC}} |
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<syntaxhighlight lang="vb">print "First 20 Cullen numbers:" |
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for n = 1 to 20 |
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num = n * (2^n)+1 |
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print int(num); " "; |
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next |
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print : print |
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print "First 20 Woodall numbers:" |
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for n = 1 to 20 |
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num = n * (2^n)-1 |
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print int(num); " "; |
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next n |
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end</syntaxhighlight> |
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{{out}} |
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<pre>Same as FreeBASIC entry.</pre> |
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==={{header|True BASIC}}=== |
==={{header|True BASIC}}=== |
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Igual que la entrada de FreeBASIC. |
Igual que la entrada de FreeBASIC. |
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</pre> |
</pre> |
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==={{header|XBasic}}=== |
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{{works with|Windows XBasic}} |
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<syntaxhighlight lang="qbasic">PROGRAM "progname" |
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VERSION "0.0000" |
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IMPORT "xma" |
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DECLARE FUNCTION Entry () |
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FUNCTION Entry () |
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PRINT "First 20 Cullen numbers:" |
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FOR n = 1 TO 20 |
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num! = n * POWER (2, n) + 1 |
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PRINT num!; |
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NEXT n |
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PRINT |
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PRINT |
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PRINT "First 20 Woodall numbers:" |
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FOR n = 1 TO 20 |
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num! = n * POWER (2, n) - 1 |
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PRINT num!; |
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NEXT n |
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END FUNCTION |
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END PROGRAM</syntaxhighlight> |
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==={{header|Yabasic}}=== |
==={{header|Yabasic}}=== |
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<syntaxhighlight lang=" |
<syntaxhighlight lang="basic">print "First 20 Cullen numbers:" |
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for n = 1 to 20 |
for n = 1 to 20 |
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end</syntaxhighlight> |
end</syntaxhighlight> |
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{{out}} |
{{out}} |
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<pre> |
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</pre> |
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Revision as of 01:35, 12 March 2023
You are encouraged to solve this task according to the task description, using any language you may know.
A Cullen number is a number of the form n × 2n + 1 where n is a natural number.
A Woodall number is very similar. It is a number of the form n × 2n - 1 where n is a natural number.
So for each n the associated Cullen number and Woodall number differ by 2.
Woodall numbers are sometimes referred to as Riesel numbers or Cullen numbers of the second kind.
Cullen primes are Cullen numbers that are prime. Similarly, Woodall primes are Woodall numbers that are prime.
It is common to list the Cullen and Woodall primes by the value of n rather than the full evaluated expression. They tend to get very large very quickly. For example, the third Cullen prime, n == 4713, has 1423 digits when evaluated.
- Task
- Write procedures to find Cullen numbers and Woodall numbers.
- Use those procedures to find and show here, on this page the first 20 of each.
- Stretch
- Find and show the first 5 Cullen primes in terms of n.
- Find and show the first 12 Woodall primes in terms of n.
- See also
11l
F cullen(n)
R (n << n) + 1
F woodall(n)
R (n << n) - 1
print(‘First 20 Cullen numbers:’)
L(i) 1..20
print(cullen(i), end' ‘ ’)
print()
print()
print(‘First 20 Woodall numbers:’)
L(i) 1..20
print(woodall(i), end' ‘ ’)
print()
- Output:
First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519
ALGOL 68
Uses Algol 68Gs LONG LONG INT for long integers. The number of digits must be specified and appears to affect the run time as larger sies are specified. This sample only shows the first two Cullen primes as the time taken to find the third is rather long.
BEGIN # find Cullen and Woodall numbers and determine which are prime #
# a Cullen number n is n2^2 + 1, Woodall number is n2^n - 1 #
PR read "primes.incl.a68" PR # include prime utilities #
PR precision 800 PR # set number of digits for Algol 68G LONG LONG INT #
# returns the nth Cullen number #
OP CULLEN = ( INT n )LONG LONG INT: n * LONG LONG INT(2)^n + 1;
# returns the nth Woodall number #
OP WOODALL = ( INT n )LONG LONG INT: CULLEN n - 2;
# show the first 20 Cullen numbers #
print( ( "1st 20 Cullen numbers:" ) );
FOR n TO 20 DO
print( ( " ", whole( CULLEN n, 0 ) ) )
OD;
print( ( newline ) );
# show the first 20 Woodall numbers #
print( ( "1st 20 Woodall numbers:" ) );
FOR n TO 20 DO
print( ( " ", whole( WOODALL n, 0 ) ) )
OD;
print( ( newline ) );
BEGIN # first 2 Cullen primes #
print( ( "Index of the 1st 2 Cullen primes:" ) );
LONG LONG INT power of 2 := 1;
INT prime count := 0;
FOR n WHILE prime count < 2 DO
power of 2 *:= 2;
LONG LONG INT c n = ( n * power of 2 ) + 1;
IF is probably prime( c n ) THEN
prime count +:= 1;
print( ( " ", whole( n, 0 ) ) )
FI
OD;
print( ( newline ) )
END;
BEGIN # first 12 Woodall primes #
print( ( "Index of the 1st 12 Woodall primes:" ) );
LONG LONG INT power of 2 := 1;
INT prime count := 0;
FOR n WHILE prime count < 12 DO
power of 2 *:= 2;
LONG LONG INT w n = ( n * power of 2 ) - 1;
IF is probably prime( w n ) THEN
prime count +:= 1;
print( ( " ", whole( n, 0 ) ) )
FI
OD;
print( ( newline ) )
END
END
- Output:
1st 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 1st 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 Index of the 1st 2 Cullen primes: 1 141 Index of the 1st 12 Woodall primes: 2 3 6 30 75 81 115 123 249 362 384 462
Arturo
cullen: function [n]->
inc n * 2^n
woodall: function [n]->
dec n * 2^n
print ["First 20 cullen numbers:" join.with:" " to [:string] map 1..20 => cullen]
print ["First 20 woodall numbers:" join.with:" " to [:string] map 1..20 => woodall]
- Output:
First 20 cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519
AWK
# syntax: GAWK -f CULLEN_AND_WOODALL_NUMBERS.AWK
BEGIN {
start = 1
stop = 20
printf("Cullen %d-%d:",start,stop)
for (n=start; n<=stop; n++) {
printf(" %d",n*(2^n)+1)
}
printf("\n")
printf("Woodall %d-%d:",start,stop)
for (n=start; n<=stop; n++) {
printf(" %d",n*(2^n)-1)
}
printf("\n")
exit(0)
}
- Output:
Cullen 1-20: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 Woodall 1-20: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519
BASIC
BASIC256
print "First 20 Cullen numbers:"
for n = 1 to 20
num = n * (2^n)+1
print int(num); " ";
next
print : print
print "First 20 Woodall numbers:"
for n = 1 to 20
num = n * (2^n)-1
print int(num); " ";
next n
end
- Output:
Igual que la entrada de FreeBASIC.
FreeBASIC
Dim As Uinteger n, num
Print "First 20 Cullen numbers:"
For n = 1 To 20
num = n * (2^n)+1
Print num; " ";
Next
Print !"\n\nFirst 20 Woodall numbers:"
For n = 1 To 20
num = n * (2^n)-1
Print num; " ";
Next n
Sleep
- Output:
First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519
Gambas
Public Sub Main()
Dim n, num As Integer
Print "First 20 Cullen numbers:"
For n = 1 To 20
num = n * (2 ^ n) + 1
Print num; " ";
Next
Print "\n\nFirst 20 Woodall numbers:"
For n = 1 To 20
num = n * (2 ^ n) - 1
Print num; " ";
Next
End
- Output:
Same as FreeBASIC entry.
PureBasic
OpenConsole()
PrintN("First 20 Cullen numbers:")
For n.i = 1 To 20
num = n * Pow(2, n)+1
Print(Str(num) + " ")
Next
PrintN(#CRLF$ + "First 20 Woodall numbers:")
For n.i = 1 To 20
num = n * Pow(2, n)-1
Print(Str(num) + " ")
Next n
PrintN(#CRLF$ + "--- terminado, pulsa RETURN---"): Input()
CloseConsole()
- Output:
Igual que la entrada de FreeBASIC.
QBasic
DIM num AS LONG ''comment this line for True BASIC
PRINT "First 20 Cullen numbers:"
FOR n = 1 TO 20
LET num = n * (2 ^ n) + 1
PRINT num;
NEXT n
PRINT
PRINT
PRINT "First 20 Woodall numbers:"
FOR n = 1 TO 20
LET num = n * (2 ^ n) - 1
PRINT num;
NEXT n
END
- Output:
Igual que la entrada de FreeBASIC.
Run BASIC
print "First 20 Cullen numbers:"
for n = 1 to 20
num = n * (2^n)+1
print int(num); " ";
next
print : print
print "First 20 Woodall numbers:"
for n = 1 to 20
num = n * (2^n)-1
print int(num); " ";
next n
end
- Output:
Same as FreeBASIC entry.
True BASIC
REM DIM num AS LONG !uncomment this line for QBasic
PRINT "First 20 Cullen numbers:"
FOR n = 1 TO 20
LET num = n * (2 ^ n) + 1
PRINT num;
NEXT n
PRINT
PRINT
PRINT "First 20 Woodall numbers:"
FOR n = 1 TO 20
LET num = n * (2 ^ n) - 1
PRINT num;
NEXT n
END
- Output:
Igual que la entrada de FreeBASIC.
XBasic
PROGRAM "progname"
VERSION "0.0000"
IMPORT "xma"
DECLARE FUNCTION Entry ()
FUNCTION Entry ()
PRINT "First 20 Cullen numbers:"
FOR n = 1 TO 20
num! = n * POWER (2, n) + 1
PRINT num!;
NEXT n
PRINT
PRINT
PRINT "First 20 Woodall numbers:"
FOR n = 1 TO 20
num! = n * POWER (2, n) - 1
PRINT num!;
NEXT n
END FUNCTION
END PROGRAM
Yabasic
print "First 20 Cullen numbers:"
for n = 1 to 20
num = n * (2^n)+1
print num, " ";
next
print "\n\nFirst 20 Woodall numbers:"
for n = 1 to 20
num = n * (2^n)-1
print num, " ";
next n
print
end
- Output:
Igual que la entrada de FreeBASIC.
F#
// Cullen and Woodall numbers. Nigel Galloway: January 14th., 2022
let Cullen,Woodall=let fG n (g:int)=(bigint g)*2I**g+n in fG 1I, fG -1I
Seq.initInfinite((+)1>>Cullen)|>Seq.take 20|>Seq.iter(printf "%A "); printfn ""
Seq.initInfinite((+)1>>Woodall)|>Seq.take 20|>Seq.iter(printf "%A "); printfn ""
Seq.initInfinite((+)1)|>Seq.filter(fun n->let mutable n=Woodall n in Open.Numeric.Primes.MillerRabin.IsProbablePrime &n)|>Seq.take 12|>Seq.iter(printf "%A "); printfn ""
Seq.initInfinite((+)1)|>Seq.filter(fun n->let mutable n=Cullen n in Open.Numeric.Primes.MillerRabin.IsProbablePrime &n)|>Seq.take 5|>Seq.iter(printf "%A "); printfn ""
- Output:
3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 2 3 6 30 75 81 115 123 249 362 384 462 1 141 4713 5795 6611
Factor
USING: arrays kernel math math.vectors prettyprint ranges
sequences ;
20 [1..b] [ dup 2^ * 1 + ] map dup 2 v-n 2array simple-table.
- Output:
3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519
Go
package main
import (
"fmt"
big "github.com/ncw/gmp"
)
func cullen(n uint) *big.Int {
one := big.NewInt(1)
bn := big.NewInt(int64(n))
res := new(big.Int).Lsh(one, n)
res.Mul(res, bn)
return res.Add(res, one)
}
func woodall(n uint) *big.Int {
res := cullen(n)
return res.Sub(res, big.NewInt(2))
}
func main() {
fmt.Println("First 20 Cullen numbers (n * 2^n + 1):")
for n := uint(1); n <= 20; n++ {
fmt.Printf("%d ", cullen(n))
}
fmt.Println("\n\nFirst 20 Woodall numbers (n * 2^n - 1):")
for n := uint(1); n <= 20; n++ {
fmt.Printf("%d ", woodall(n))
}
fmt.Println("\n\nFirst 5 Cullen primes (in terms of n):")
count := 0
for n := uint(1); count < 5; n++ {
cn := cullen(n)
if cn.ProbablyPrime(15) {
fmt.Printf("%d ", n)
count++
}
}
fmt.Println("\n\nFirst 12 Woodall primes (in terms of n):")
count = 0
for n := uint(1); count < 12; n++ {
cn := woodall(n)
if cn.ProbablyPrime(15) {
fmt.Printf("%d ", n)
count++
}
}
fmt.Println()
}
- Output:
First 20 Cullen numbers (n * 2^n + 1): 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers (n * 2^n - 1): 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 First 5 Cullen primes (in terms of n): 1 141 4713 5795 6611 First 12 Woodall primes (in terms of n): 2 3 6 30 75 81 115 123 249 362 384 462
Haskell
findCullen :: Int -> Integer
findCullen n = toInteger ( n * 2 ^ n + 1 )
cullens :: [Integer]
cullens = map findCullen [1 .. 20]
woodalls :: [Integer]
woodalls = map (\i -> i - 2 ) cullens
main :: IO ( )
main = do
putStrLn "First 20 Cullen numbers:"
print cullens
putStrLn "First 20 Woodall numbers:"
print woodalls
- Output:
First 20 Cullen numbers: [3,9,25,65,161,385,897,2049,4609,10241,22529,49153,106497,229377,491521,1048577,2228225,4718593,9961473,20971521] First 20 Woodall numbers: [1,7,23,63,159,383,895,2047,4607,10239,22527,49151,106495,229375,491519,1048575,2228223,4718591,9961471,20971519]
J
cullen=: {{ y* 1+2x^y }}
woodall=: {{ y*_1+2x^y }}
Task example:
cullen 1+i.20
3 10 27 68 165 390 903 2056 4617 10250 22539 49164 106509 229390 491535 1048592 2228241 4718610 9961491 20971540
woodall 1+i.20
1 6 21 60 155 378 889 2040 4599 10230 22517 49140 106483 229362 491505 1048560 2228207 4718574 9961453 20971500
Julia
using Lazy
using Primes
cullen(n, two = BigInt(2)) = n * two^n + 1
woodall(n, two = BigInt(2)) = n * two^n - 1
primecullens = @>> Lazy.range() filter(n -> isprime(cullen(n)))
primewoodalls = @>> Lazy.range() filter(n -> isprime(woodall(n)))
println("First 20 Cullen numbers: ( n × 2**n + 1)\n", [cullen(n, 2) for n in 1:20]) # A002064
println("First 20 Woodall numbers: ( n × 2**n - 1)\n", [woodall(n, 2) for n in 1:20]) # A003261
println("\nFirst 5 Cullen primes: (in terms of n)\n", take(5, primecullens)) # A005849
println("\nFirst 12 Woodall primes: (in terms of n)\n", Int.(collect(take(12, primewoodalls)))) # A002234
- Output:
First 20 Cullen numbers: ( n × 2**n + 1) [3, 9, 25, 65, 161, 385, 897, 2049, 4609, 10241, 22529, 49153, 106497, 229377, 491521, 1048577, 2228225, 4718593, 9961473, 20971521] First 20 Woodall numbers: ( n × 2**n - 1) [1, 7, 23, 63, 159, 383, 895, 2047, 4607, 10239, 22527, 49151, 106495, 229375, 491519, 1048575, 2228223, 4718591, 9961471, 20971519] First 5 Cullen primes: (in terms of n) List: (1 141 4713 5795 6611) First 12 Woodall primes: (in terms of n) [2, 3, 6, 30, 75, 81, 115, 123, 249, 362, 384, 462]
Lua
function T(t) return setmetatable(t, {__index=table}) end
table.range = function(t,n) local s=T{} for i=1,n do s[i]=i end return s end
table.map = function(t,f) local s=T{} for i=1,#t do s[i]=f(t[i]) end return s end
function cullen(n) return (n<<n)+1 end
print("First 20 Cullen numbers:")
print(T{}:range(20):map(cullen):concat(" "))
function woodall(n) return (n<<n)-1 end
print("First 20 Woodall numbers:")
print(T{}:range(20):map(woodall):concat(" "))
- Output:
First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519
Mathematica /Wolfram Language
ClearAll[CullenNumber, WoodallNumber]
SetAttributes[{CullenNumber, WoodallNumber}, Listable]
CullenNumber[n_Integer] := n 2^n + 1
WoodallNumber[n_Integer] := n 2^n - 1
CullenNumber[Range[20]]
WoodallNumber[Range[20]]
cps = {};
Do[
If[PrimeQ[CullenNumber[i]],
AppendTo[cps, i];
If[Length[cps] >= 5, Break[]]
]
,
{i, 1, \[Infinity]}
]
cps
wps = {};
Do[
If[PrimeQ[WoodallNumber[i]],
AppendTo[wps, i];
If[Length[wps] >= 12, Break[]]
]
,
{i, 1, \[Infinity]}
];
wps
- Output:
{3, 9, 25, 65, 161, 385, 897, 2049, 4609, 10241, 22529, 49153, 106497, 229377, 491521, 1048577, 2228225, 4718593, 9961473, 20971521} {1, 7, 23, 63, 159, 383, 895, 2047, 4607, 10239, 22527, 49151, 106495, 229375, 491519, 1048575, 2228223, 4718591, 9961471, 20971519} {1, 141, 4713, 5795, 6611} {2, 3, 6, 30, 75, 81, 115, 123, 249, 362, 384, 462}
Perl
use strict;
use warnings;
use bigint;
use ntheory 'is_prime';
use constant Inf => 1e10;
sub cullen {
my($n,$c) = @_;
($n * 2**$n) + $c;
}
my($m,$n);
($m,$n) = (20,0);
print "First $m Cullen numbers:\n";
print do { $n < $m ? (++$n and cullen($_,1) . ' ') : last } for 1 .. Inf;
($m,$n) = (20,0);
print "\n\nFirst $m Woodall numbers:\n";
print do { $n < $m ? (++$n and cullen($_,-1) . ' ') : last } for 1 .. Inf;
($m,$n) = (5,0);
print "\n\nFirst $m Cullen primes: (in terms of n)\n";
print do { $n < $m ? (!!is_prime(cullen $_,1) and ++$n and "$_ ") : last } for 1 .. Inf;
($m,$n) = (12,0);
print "\n\nFirst $m Woodall primes: (in terms of n)\n";
print do { $n < $m ? (!!is_prime(cullen $_,-1) and ++$n and "$_ ") : last } for 1 .. Inf;
- Output:
First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 First 5 Cullen primes: (in terms of n) 1 141 4713 5795 6611 First 12 Woodall primes: (in terms of n) 2 3 6 30 75 81 115 123 249 362 384 462
Phix
with javascript_semantics atom t0 = time() include mpfr.e procedure cullen(mpz r, integer n) mpz_ui_pow_ui(r,2,n) mpz_mul_si(r,r,n) mpz_add_si(r,r,1) end procedure procedure woodall(mpz r, integer n) cullen(r,n) mpz_sub_si(r,r,2) end procedure sequence c = {}, w = {} mpz z = mpz_init() for i=1 to 20 do cullen(z,i) c = append(c,mpz_get_str(z)) mpz_sub_si(z,z,2) w = append(w,mpz_get_str(z)) end for printf(1," Cullen[1..20]:%s\nWoodall[1..20]:%s\n",{join(c),join(w)}) atom t1 = time()+1 c = {} integer n = 1 while length(c)<iff(platform()=JS?2:5) do cullen(z,n) if mpz_prime(z) then c = append(c,sprint(n)) end if n += 1 if time()>t1 and platform()!=JS then progress("c(%d) [needs to get to 6611], %d found\r",{n,length(c)}) t1 = time()+2 end if end while if platform()!=JS then progress("") end if printf(1,"First 5 Cullen primes (in terms of n):%s\n",{join(c)}) w = {} n = 1 while length(w)<12 do woodall(z,n) if mpz_prime(z) then w = append(w,sprint(n)) end if n += 1 end while printf(1,"First 12 Woodall primes (in terms of n):%s\n",{join(w)}) ?elapsed(time()-t0)
- Output:
Cullen[1..20]:3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 Woodall[1..20]:1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 First 5 Cullen primes (in terms of n):1 141 4713 5795 6611 First 12 Woodall primes (in terms of n):2 3 6 30 75 81 115 123 249 362 384 462 "34.4s"
Note the time given is for desktop/Phix 64bit, for comparison the Julia entry took about 20s on the same box. On 32-bit it is nearly 5 times slower (2 minutes and 38s) and hence under pwa/p2js in a browser (which is inherently 32bit) it is limited to the first 2 cullen primes only, but manages that in 0.4s.
Python
print("working...")
print("First 20 Cullen numbers:")
for n in range(1,21):
num = n*pow(2,n)+1
print(str(num),end= " ")
print()
print("First 20 Woodall numbers:")
for n in range(1,21):
num = n*pow(2,n)-1
print(str(num),end=" ")
print()
print("done...")
- Output:
working... First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 done...
Bit Shift
def cullen(n): return((n<<n)+1)
def woodall(n): return((n<<n)-1)
print("First 20 Cullen numbers:")
for i in range(1,21):
print(cullen(i),end=" ")
print()
print()
print("First 20 Woodall numbers:")
for i in range(1,21):
print(woodall(i),end=" ")
print()
- Output:
Same as Quackery.
Quackery
[ dup << 1+ ] is cullen ( n --> n )
[ dup << 1 - ] is woodall ( n --> n )
say "First 20 Cullen numbers:" cr
20 times [ i^ 1+ cullen echo sp ] cr
cr
say "First 20 Woodall numbers:" cr
20 times [ i^ 1+ woodall echo sp ] cr
- Output:
First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519
Raku
my @cullen = ^∞ .map: { $_ × 1 +< $_ + 1 };
my @woodall = ^∞ .map: { $_ × 1 +< $_ - 1 };
put "First 20 Cullen numbers: ( n × 2**n + 1)\n", @cullen[1..20]; # A002064
put "\nFirst 20 Woodall numbers: ( n × 2**n - 1)\n", @woodall[1..20]; # A003261
put "\nFirst 5 Cullen primes: (in terms of n)\n", @cullen.grep( &is-prime, :k )[^5]; # A005849
put "\nFirst 12 Woodall primes: (in terms of n)\n", @woodall.grep( &is-prime, :k )[^12]; # A002234
- Output:
First 20 Cullen numbers: ( n × 2**n + 1) 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: ( n × 2**n - 1) 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 First 5 Cullen primes: (in terms of n) 1 141 4713 5795 6611 First 12 Woodall primes: (in terms of n) 2 3 6 30 75 81 115 123 249 362 384 462
Ring
load "stdlib.ring"
see "working..." + nl
see "First 20 Cullen numbers:" + nl
for n = 1 to 20
num = n*pow(2,n)+1
see "" + num + " "
next
see nl + nl + "First 20 Woodall numbers:" + nl
for n = 1 to 20
num = n*pow(2,n)-1
see "" + num + " "
next
see nl + "done..." + nl
- Output:
working... First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 done...
Ruby
The OpenSSL prime? methods is faster than the standard one. It still takes 1-2 minutes to calculate the first 5 Cullen primes.
require 'openssl'
cullen = Enumerator.new{|y| (1..).each{|n| y << (n*(1<<n) + 1)} }
woodall = Enumerator.new{|y| (1..).each{|n| y << (n*(1<<n) - 1)} }
cullen_primes = Enumerator.new{|y| (1..).each {|i|y << i if OpenSSL::BN.new(cullen.next).prime?}}
woodall_primes = Enumerator.new{|y| (1..).each{|i|y << i if OpenSSL::BN.new(woodall.next).prime?}}
num = 20
puts "First #{num} Cullen numbers:\n#{cullen.first(num).join(" ")}"
puts "First #{num} Woodal numbers:\n#{woodall.first(num).join(" ")}"
puts "First 5 Cullen primes:\n#{cullen_primes.first(5).join(", ")}"
puts "First 12 Woodall primes:\n#{woodall_primes.first(12).join(", ")}"
- Output:
First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodal numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 First 5 Cullen primes: 1, 141, 4713, 5795, 6611 First 12 Woodall primes: 2, 3, 6, 30, 75, 81, 115, 123, 249, 362, 384, 462
Rust
// [dependencies]
// rug = "1.15.0"
use rug::integer::IsPrime;
use rug::Integer;
fn cullen_number(n: u32) -> Integer {
let num = Integer::from(n);
(num << n) + 1
}
fn woodall_number(n: u32) -> Integer {
let num = Integer::from(n);
(num << n) - 1
}
fn main() {
println!("First 20 Cullen numbers:");
let cullen: Vec<String> = (1..21).map(|x| cullen_number(x).to_string()).collect();
println!("{}", cullen.join(" "));
println!("\nFirst 20 Woodall numbers:");
let woodall: Vec<String> = (1..21).map(|x| woodall_number(x).to_string()).collect();
println!("{}", woodall.join(" "));
println!("\nFirst 5 Cullen primes in terms of n:");
let cullen_primes: Vec<String> = (1..)
.filter_map(|x| match cullen_number(x).is_probably_prime(25) {
IsPrime::No => None,
_ => Some(x.to_string()),
})
.take(5)
.collect();
println!("{}", cullen_primes.join(" "));
println!("\nFirst 12 Woodall primes in terms of n:");
let woodall_primes: Vec<String> = (1..)
.filter_map(|x| match woodall_number(x).is_probably_prime(25) {
IsPrime::No => None,
_ => Some(x.to_string()),
})
.take(12)
.collect();
println!("{}", woodall_primes.join(" "));
}
- Output:
First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 First 5 Cullen primes in terms of n: 1 141 4713 5795 6611 First 12 Woodall primes in terms of n: 2 3 6 30 75 81 115 123 249 362 384 462
Sidef
func cullen(n) { n * (1 << n) + 1 }
func woodall(n) { n * (1 << n) - 1 }
say "First 20 Cullen numbers:"
say cullen.map(1..20).join(' ')
say "\nFirst 20 Woodall numbers:"
say woodall.map(1..20).join(' ')
say "\nFirst 5 Cullen primes: (in terms of n)"
say 5.by { cullen(_).is_prime }.join(' ')
say "\nFirst 12 Woodall primes: (in terms of n)"
say 12.by { woodall(_).is_prime }.join(' ')
- Output:
First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 First 5 Cullen primes: (in terms of n) 1 141 4713 5795 6611 First 12 Woodall primes: (in terms of n) 2 3 6 30 75 81 115 123 249 362 384 462
Verilog
module main;
integer n, num;
initial begin
$display("First 20 Cullen numbers:");
for(n = 1; n <= 20; n=n+1)
begin
num = n * (2 ** n) + 1;
$write(num, " ");
end
$display("");
$display("First 20 Woodall numbers:");
for(n = 1; n <= 20; n=n+1)
begin
num = n * (2 ** n) - 1;
$write(num, " ");
end
$finish ;
end
endmodule
Wren
CLI
Cullen primes limited to first 2 as very slow after that.
import "./big" for BigInt
var cullen = Fn.new { |n| (BigInt.one << n) * n + 1 }
var woodall = Fn.new { |n| cullen.call(n) - 2 }
System.print("First 20 Cullen numbers (n * 2^n + 1):")
for (n in 1..20) System.write("%(cullen.call(n)) ")
System.print("\n\nFirst 20 Woodall numbers (n * 2^n - 1):")
for (n in 1..20) System.write("%(woodall.call(n)) ")
System.print("\n\nFirst 2 Cullen primes (in terms of n):")
var count = 0
var n = 1
while (count < 2) {
var cn = cullen.call(n)
if (cn.isProbablePrime(5)){
System.write("%(n) ")
count = count + 1
}
n = n + 1
}
System.print("\n\nFirst 12 Woodall primes (in terms of n):")
count = 0
n = 1
while (count < 12) {
var wn = woodall.call(n)
if (wn.isProbablePrime(5)){
System.write("%(n) ")
count = count + 1
}
n = n + 1
}
System.print()
- Output:
First 20 Cullen numbers (n * 2^n + 1): 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers (n * 2^n - 1): 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 First 2 Cullen primes (in terms of n): 1 141 First 12 Woodall primes (in terms of n): 2 3 6 30 75 81 115 123 249 362 384 462
Embedded
Cullen primes still slow to emerge, just over 10 seconds overall.
/* cullen_and_woodall_numbers2.wren */
import "./gmp" for Mpz
var cullen = Fn.new { |n| (Mpz.one << n) * n + 1 }
var woodall = Fn.new { |n| cullen.call(n) - 2 }
System.print("First 20 Cullen numbers (n * 2^n + 1):")
for (n in 1..20) System.write("%(cullen.call(n)) ")
System.print("\n\nFirst 20 Woodall numbers (n * 2^n - 1):")
for (n in 1..20) System.write("%(woodall.call(n)) ")
System.print("\n\nFirst 5 Cullen primes (in terms of n):")
var count = 0
var n = 1
while (count < 5) {
var cn = cullen.call(n)
if (cn.probPrime(15) > 0){
System.write("%(n) ")
count = count + 1
}
n = n + 1
}
System.print("\n\nFirst 12 Woodall primes (in terms of n):")
count = 0
n = 1
while (count < 12) {
var wn = woodall.call(n)
if (wn.probPrime(15) > 0){
System.write("%(n) ")
count = count + 1
}
n = n + 1
}
System.print()
- Output:
First 20 Cullen numbers (n * 2^n + 1): 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers (n * 2^n - 1): 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519 First 5 Cullen primes (in terms of n): 1 141 4713 5795 6611 First 12 Woodall primes (in terms of n): 2 3 6 30 75 81 115 123 249 362 384 462
XPL0
func Cullen(N);
int N;
return N<<N + 1;
func Woodall(N);
int N;
return N<<N - 1;
int I;
[Text(0, "First 20 Cullen numbers:^m^j");
for I:= 1 to 20 do
[IntOut(0, Cullen(I)); ChOut(0, ^ )];
CrLf(0);
CrLf(0);
Text(0, "First 20 Woodall numbers:^m^j");
for I:= 1 to 20 do
[IntOut(0, Woodall(I)); ChOut(0, ^ )];
CrLf(0);
]
- Output:
First 20 Cullen numbers: 3 9 25 65 161 385 897 2049 4609 10241 22529 49153 106497 229377 491521 1048577 2228225 4718593 9961473 20971521 First 20 Woodall numbers: 1 7 23 63 159 383 895 2047 4607 10239 22527 49151 106495 229375 491519 1048575 2228223 4718591 9961471 20971519
- Programming Tasks
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