Truncatable primes: Difference between revisions
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=={{header|Perl 6}}== |
=={{header|Perl 6}}== |
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{{works with|Rakudo |
{{works with|Rakudo Star|2010.09}} |
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This uses a fairly naive isprime routine. It works but is slow. |
This uses a fairly naive isprime routine. It works but is slow. |
Revision as of 01:58, 12 October 2010
You are encouraged to solve this task according to the task description, using any language you may know.
A truncatable prime is prime number that when you successively remove digits from one end of the prime, you are left with a new prime number; for example, the number 997 is called a left-truncatable prime as the numbers 997, 97, and 7 are all prime. The number 7393 is a right-truncatable prime as the numbers 7393, 739, 73, and 7 formed by removing digits from its right are also prime. No zeroes are allowed in truncatable primes.
The task is to find the largest left-truncatable and right-truncatable primes less than one million.
C.f: Sieve of Eratosthenes; Truncatable Prime from Mathworld.
Ada
<lang Ada> with Ada.Text_IO; use Ada.Text_IO; with Ada.Containers.Ordered_Sets;
procedure Truncatable_Primes is
package Natural_Set is new Ada.Containers.Ordered_Sets (Natural); use Natural_Set;
Primes : Set; function Is_Prime (N : Natural) return Boolean is Position : Cursor := First (Primes); begin while Has_Element (Position) loop if N mod Element (Position) = 0 then return False; end if; Position := Next (Position); end loop; return True; end Is_Prime;
function Is_Left_Trucatable_Prime (N : Positive) return Boolean is M : Natural := 1; begin while Contains (Primes, N mod (M * 10)) and (N / M) mod 10 > 0 loop M := M * 10; if N <= M then return True; end if; end loop; return False; end Is_Left_Trucatable_Prime;
function Is_Right_Trucatable_Prime (N : Positive) return Boolean is M : Natural := N; begin while Contains (Primes, M) and M mod 10 > 0 loop M := M / 10; if M <= 1 then return True; end if; end loop; return False; end Is_Right_Trucatable_Prime;
Position : Cursor;
begin
for N in 2..1_000_000 loop if Is_Prime (N) then Insert (Primes, N); end if; end loop; Position := Last (Primes); while Has_Element (Position) loop if Is_Left_Trucatable_Prime (Element (Position)) then Put_Line ("Largest LTP from 1..1000000:" & Integer'Image (Element (Position))); exit; end if; Previous (Position); end loop; Position := Last (Primes); while Has_Element (Position) loop if Is_Right_Trucatable_Prime (Element (Position)) then Put_Line ("Largest RTP from 1..1000000:" & Integer'Image (Element (Position))); exit; end if; Previous (Position); end loop;
end Truncatable_Primes; </lang> Sample output:
Largest LTP from 1..1000000: 998443 Largest RTP from 1..1000000: 739399
D
<lang d>import std.stdio, std.math, std.string, std.conv;
bool isPrime(int n) {
if (n <= 1) return false; foreach (i; 2 .. cast(int)sqrt(cast(real)n) + 1) if (!(n % i)) return false; return true;
}
bool isLeftTruncatablePrime(int n) {
string s = to!string(n); if (indexOf(s, '0') != -1) return false; foreach (i; 0 .. s.length) if (!isPrime(to!int(s[i .. $]))) return false; return true;
}
bool isRightTruncatablePrime(int n) {
string s = to!string(n); if (indexOf(s, '0') != -1) return false; foreach (i; 0 .. s.length) if (!isPrime(to!int(s[0 .. i+1]))) return false; return true;
}
void main() {
enum int n = 1_000_000; foreach_reverse (i; 2 .. n) if (isLeftTruncatablePrime(i)) { writeln("Largest left-truncatable prime in 2 .. ", n, ": ", i); break; } foreach_reverse (i; 2 .. n) if (isRightTruncatablePrime(i)) { writeln("Largest right-truncatable prime in 2 .. ", n, ": ", i); break; }
}</lang> Output:
Largest left-truncatable prime in 2 .. 1000000: 998443 Largest right-truncatable prime in 2 .. 1000000: 739399
Haskell
Using
from HackageDB
<lang haskell>import Data.Numbers.Primes(primes, isPrime) import Data.List import Control.Arrow
primes1e6 = reverse. filter (notElem '0'. show) $ takeWhile(<=1000000) primes
rightT, leftT :: Int -> Bool rightT = all isPrime. takeWhile(>0). drop 1. iterate (`div`10) leftT x = all isPrime. takeWhile(<x).map (x`mod`) $ iterate (*10) 10
main = do
let (ltp, rtp) = (head. filter leftT &&& head. filter rightT) primes1e6 putStrLn $ "Left truncatable " ++ show ltp putStrLn $ "Right truncatable " ++ show rtp</lang>
Output: <lang haskell>*Main> main Left truncatable 998443 Right truncatable 739399</lang>
Interpretation of the J contribution: <lang haskell>digits = [1..9] :: [Integer] smallPrimes = filter isPrime digits pow10 = iterate (*10) 1 mul10 = (pow10!!). length. show righT = (+) . (10 *) lefT = liftM2 (.) (+) ((*) . mul10)
primesTruncatable f = iterate (concatMap (filter isPrime.flip map digits. f)) smallPrimes</lang> Output: <lang haskell>*Main> maximum $ primesTruncatable righT !! 5 739399
- Main> maximum $ primesTruncatable lefT !! 5
998443</lang>
Icon and Unicon
Icon
<lang Icon>procedure main(arglist)
N := 0 < integer(\arglist[1]) | 1000000 # primes to generator 1 to ... (1M or 1st arglist) D := (0 < integer(\arglist[2]) | 10) / 2 # primes to display (10 or 2nd arglist) P := sieve(N) # from sieve task (modified) write("There are ",*P," prime numbers in the range 1 to ",N) if *P <= 2*D then every writes( "Primes: "|!sort(P)||" "|"\n" ) else every writes( "Primes: "|(L := sort(P))[1 to D]||" "|"... "|L[*L-D+1 to *L]||" "|"\n" ) largesttruncateable(P)
end
procedure largesttruncateable(P) #: find the largest left and right trucatable numbers in P local ltp,rtp
every x := sort(P)[*P to 1 by -1] do # largest to smallest if not find('0',x) then { /ltp := islefttrunc(P,x) /rtp := isrighttrunc(P,x) if \ltp & \rtp then break # until both found } write("Largest left truncatable prime = ", ltp) write("Largest right truncatable prime = ", rtp) return
end
procedure isrighttrunc(P,x) #: return integer x if x and all right truncations of x are in P or fails if x = 0 | (member(P,x) & isrighttrunc(P,x / 10)) then return x end
procedure islefttrunc(P,x) #: return integer x if x and all left truncations of x are in P or fails if *x = 0 | ( (x := integer(x)) & member(P,x) & islefttrunc(P,x[2:0]) ) then return x end</lang>
Sample output:
There are 78498 prime numbers in the range 1 to 1000000 Primes: 2 3 5 7 11 ... 999953 999959 999961 999979 999983 Largest left truncatable prime = 998443 Largest right truncatable prime = 739399
Unicon
The Icon solution works in Unicon.
J
Truncatable primes may be constructed by starting with a set of one digit prime numbers and then repeatedly adding a non-zero digit (using the cartesian product of digit sequences) and, at each step, selecting the prime numbers which result.
In other words, given:
<lang j>selPrime=: #~ 1&p: seed=: selPrime digits=: 1+i.9 step=: selPrime@,@:(,&.":/&>)@{@;</lang>
The largest truncatable primes less than a million can be obtained by adding five digits to the prime seeds, then finding the largest value from the result:
<lang j> >./ digits&step^:5 seed NB. left truncatable 998443
>./ step&digits^:5 seed NB. right truncatable
739399</lang>
Perl 6
This uses a fairly naive isprime routine. It works but is slow.
<lang perl6> use v6; my %cache = <2 3 5 7 11 13 17 19 23> >>=>>> 1;
sub isprime ($test) {
return %cache{$test} if defined %cache{$test}; return (%cache{$test} = 0) if $test <= 25; my $r = floor($test ** .5); return (%cache{$test} = 0) unless $test % $_ for (2, 3, * + 2 ... * >= $r); return (%cache{$test} = 1);
}
sub trunc_prime ($type, $limit is copy) {
$limit += ($limit % 2 ?? 0 !! 1); for ($limit, * - 2 ... * < 2 ) -> $loop { next if $loop ~~ /0/; # No zeros allowed my $this = $loop; while $this.&isprime { $this.=subst($type, ); return $loop unless $this; } }
}
say "Largest Left Truncatable Prime < 1000000: ",trunc_prime(rx/^\d/, 1000000); say "Largest Right Truncatable Prime < 1000000: ",trunc_prime(rx/\d$/, 1000000); </lang> Output:
Largest Left Truncatable Prime < 1000000: 998443 Largest Right Truncatable Prime < 1000000: 739339
PicoLisp
<lang PicoLisp>(load "@lib/rsa.l") # Use the 'prime?' function from RSA package
(de truncatablePrime? (N Fun)
(for (L (chop N) L (Fun L)) (T (= "0" (car L))) (NIL (prime? (format L))) T ) )
(let (Left 1000000 Right 1000000)
(until (truncatablePrime? (dec 'Left) cdr)) (until (truncatablePrime? (dec 'Right) '((L) (cdr (rot L))))) (cons Left Right) )</lang>
Output:
-> (998443 . 739399)
PowerShell
<lang PowerShell>function IsPrime ( [int] $num ) {
$isprime = @{} 2..[math]::sqrt($num) | Where-Object { $isprime[$_] -eq $null } | ForEach-Object { $_ $isprime[$_] = $true for ( $i=$_*$_ ; $i -le $num; $i += $_ ) { $isprime[$i] = $false } } 2..$num | Where-Object { $isprime[$_] -eq $null }
}
function Truncatable ( [int] $num ) {
$declen = [math]::abs($num).ToString().Length $primes = @() $ltprimes = @{} $rtprimes = @{} 1..$declen | ForEach-Object { $ltprimes[$_]=@{}; $rtprimes[$_]=@{} } IsPrime $num | ForEach-Object { $lastltprime = 2 $lastrtprime = 2 } { $curprim = $_ $curdeclen = $curprim.ToString().Length $primes += $curprim if( $curdeclen -eq 1 ) { $ltprimes[1][$curprim] = $true $rtprimes[1][$curprim] = $true $lastltprime = $curprim $lastrtprime = $curprim } else { $curmod = $curprim % [math]::pow(10,$curdeclen - 1) $curdiv = [math]::floor($curprim / 10) if( $ltprimes[$curdeclen - 1][[int]$curmod] ) { $ltprimes[$curdeclen][$curprim] = $true $lastltprime = $curprim } if( $rtprimes[$curdeclen - 1][[int]$curdiv] ) { $rtprimes[$curdeclen][$curprim] = $true $lastrtprime = $curprim } } if( ( $ltprimes[$curdeclen - 2].Keys.count -gt 0 ) -and ( $ltprimes[$curdeclen - 1].Keys.count -gt 0 ) ) { $ltprimes[$curdeclen -2] = @{} } if( ( $rtprimes[$curdeclen - 2].Keys.count -gt 0 ) -and ( $rtprimes[$curdeclen - 1].Keys.count -gt 0 ) ) { $rtprimes[$curdeclen -2] = @{} } } { "Largest Left Truncatable Prime: $lastltprime" "Largest Right Truncatable Prime: $lastrtprime" }
}</lang>
PureBasic
<lang PureBasic>#MaxLim = 999999
Procedure is_Prime(n)
If n<=1 : ProcedureReturn #False ElseIf n<4 : ProcedureReturn #True ElseIf n%2=0: ProcedureReturn #False ElseIf n<9 : ProcedureReturn #True ElseIf n%3=0: ProcedureReturn #False Else Protected r=Round(Sqr(n),#PB_Round_Down) Protected f=5 While f<=r If n%f=0 Or n%(f+2)=0 ProcedureReturn #False EndIf f+6 Wend EndIf ProcedureReturn #True
EndProcedure
Procedure TruncateLeft(n)
Protected s.s=Str(n), l=Len(s)-1 If Not FindString(s,"0",1) While l>0 s=Right(s,l) If Not is_Prime(Val(s)) ProcedureReturn #False EndIf l-1 Wend ProcedureReturn #True EndIf
EndProcedure
Procedure TruncateRight(a)
Repeat a/10 If Not a Break ElseIf Not is_Prime(a) Or a%10=0 ProcedureReturn #False EndIf ForEver ProcedureReturn #True
EndProcedure
i=#MaxLim Repeat
If is_Prime(i) If Not truncateleft And TruncateLeft(i) truncateleft=i EndIf If Not truncateright And TruncateRight(i) truncateright=i EndIf EndIf If truncateleft And truncateright Break Else i-2 EndIf
Until i<=0
x.s="Largest TruncateLeft= "+Str(truncateleft) y.s="Largest TruncateRight= "+Str(truncateright)
MessageRequester("Truncatable primes",x+#CRLF$+y)</lang>
Python
<lang python>maxprime = 1000000
def primes(n):
multiples = set() prime = [] for i in range(2, n+1): if i not in multiples: prime.append(i) multiples.update(set(range(i*i, n+1, i))) return prime
def truncatableprime(n):
'Return a longest left and right truncatable primes below n' primelist = [str(x) for x in primes(n)[::-1]] primeset = set(primelist) for n in primelist: # n = 'abc'; [n[i:] for i in range(len(n))] -> ['abc', 'bc', 'c'] alltruncs = set(n[i:] for i in range(len(n))) if alltruncs.issubset(primeset): truncateleft = int(n) break for n in primelist: # n = 'abc'; [n[:i+1] for i in range(len(n))] -> ['a', 'ab', 'abc'] alltruncs = set([n[:i+1] for i in range(len(n))]) if alltruncs.issubset(primeset): truncateright = int(n) break return truncateleft, truncateright
print(truncatableprime(maxprime))</lang>
Sample Output
(998443, 739399)
Tcl
<lang tcl>package require Tcl 8.5
- Optimized version of the Sieve-of-Eratosthenes task solution
proc sieve n {
set primes [list] if {$n < 2} {return $primes} set nums [dict create] for {set i 2} {$i <= $n} {incr i} { dict set nums $i "" } set next 2 set limit [expr {sqrt($n)}] while {$next <= $limit} { for {set i $next} {$i <= $n} {incr i $next} {dict unset nums $i} lappend primes $next
dict for {next -} $nums break
} return [concat $primes [dict keys $nums]]
}
proc isLeftTruncatable n {
global isPrime while {[string length $n] > 0} {
if {![info exist isPrime($n)]} { return false } set n [string range $n 1 end]
} return true
} proc isRightTruncatable n {
global isPrime while {[string length $n] > 0} {
if {![info exist isPrime($n)]} { return false } set n [string range $n 0 end-1]
} return true
}
- Demo code
set limit 1000000 puts "calculating primes up to $limit" set primes [sieve $limit] puts "search space contains [llength $primes] members" foreach p $primes {
set isPrime($p) "yes"
} set primes [lreverse $primes]
puts "searching for largest left-truncatable prime" foreach p $primes {
if {[isLeftTruncatable $p]} {
puts FOUND:$p break
}
}
puts "searching for largest right-truncatable prime" foreach p $primes {
if {[isRightTruncatable $p]} {
puts FOUND:$p break
}
}</lang> Output:
calculating primes up to 1000000 search space contains 78498 members searching for largest left-truncatable prime FOUND:998443 searching for largest right-truncatable prime FOUND:739399