Emirp primes: Difference between revisions
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The 10,000th Emirp prime is : 948349 |
The 10,000th Emirp prime is : 948349 |
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=={{header|Frink}}== |
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<lang frink> |
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isEmirp[x] := |
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{ |
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if isPrime[x] |
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{ |
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s = toString[x] |
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rev = reverse[s] |
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return s != rev and isPrime[parseInt[rev]] |
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} |
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return false |
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} |
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// Functions that return finite and infinite enumerating expressions of emirps |
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emirps[] := select[primes[], getFunction["isEmirp", 1]] |
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emirps[begin, end] := select[primes[begin, end], getFunction["isEmirp", 1]] |
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println["First 20: " + first[emirps[], 20]] |
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println["Range: " + emirps[7700, 8000]] |
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println["10000th: " + last[first[emirps[], 10000]]] |
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</lang> |
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{{out}} |
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<pre> |
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First 20: [13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389] |
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Range: [7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963] |
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10000th: 948349 |
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</pre> |
</pre> |
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Revision as of 21:44, 18 January 2020
You are encouraged to solve this task according to the task description, using any language you may know.
An emirp (prime spelled backwards) are primes that when reversed (in their decimal representation) are a different prime.
(This rules out palindromic primes.)
- Task
-
- show the first twenty emirps
- show all emirps between 7,700 and 8,000
- show the 10,000th emirp
In each list, the numbers should be in order.
Invoke the (same) program once per task requirement, this will show what limit is used as the upper bound for calculating surplus (regular) primes.
The specific method of how to determine if a range or if specific values are to be shown will be left to the programmer.
- See also
- Wikipedia, Emirp.
- The Prime Pages, emirp.
- Wolfram MathWorld™, Emirp.
- The On‑Line Encyclopedia of Integer Sequences, emirps (A6567).
Ada
he solution uses the package Miller_Rabin from the Miller-Rabin primality test.
<lang Ada>with Ada.Text_IO, Miller_Rabin;
procedure Emirp_Gen is
type Num is range 0 .. 2**63-1; -- maximum for the gnat Ada compiler MR_Iterations: constant Positive := 25; -- the probability Pr[Is_Prime(N, MR_Iterations) = Probably_Prime] -- is 1 for prime N and < 4**(-MR_Iterations) for composed N function Is_Emirp(E: Num) return Boolean is package MR is new Miller_Rabin(Num); use MR; function Rev(E: Num) return Num is
N: Num := E; R: Num := 0;
begin
while N > 0 loop R := 10*R + N mod 10; -- N mod 10 is least significant digit of N N := N / 10; -- delete least significant digit of N end loop; return R;
end Rev; R: Num := Rev(E); begin return E /= R and then
(Is_Prime(E, MR_Iterations) = Probably_Prime) and then (Is_Prime(R, MR_Iterations) = Probably_Prime);
end Is_Emirp;
function Next(P: Num) return Num is N: Num := P+1; begin while not (Is_Emirp(N)) Loop
N := N + 1;
end loop; return N; end Next; Current: Num; Count: Num := 0;
begin
-- show the first twenty emirps Ada.Text_IO.Put("First 20 emirps:"); Current := 1; for I in 1 .. 20 loop Current := Next(Current); Ada.Text_IO.Put(Num'Image(Current)); end loop; Ada.Text_IO.New_Line; -- show the emirps between 7700 and 8000 Ada.Text_IO.Put("Emirps between 7700 and 8000:"); Current := 7699; loop Current := Next(Current); exit when Current > 8000; Ada.Text_IO.Put(Num'Image(Current)); end loop; -- the 10_000th emirp Ada.Text_IO.Put("The 10_000'th emirp:"); for I in 1 .. 10_000 loop Current := Next(Current); end loop; Ada.Text_IO.Put_Line(Num'Image(Current));
end Emirp_Gen;</lang>
- Output:
First 20 emirps: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Emirps between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 The 10_000'th emirp: 948349
ALGOL 68
Uses Algol 68G specific argc and argv procedures to access to command line. Allows the user to specify the from and to range values or ordinals on the command line. The sieve size can also be specified. As suggested by the Fortran sample, from = to is treated as a special case for labeling the output. <lang algol68># sieve of Eratosthenes: sets s[i] to TRUE if i is prime, FALSE otherwise # PROC sieve = ( REF[]BOOL s )VOID:
BEGIN # start with everything flagged as prime # FOR i TO UPB s DO s[ i ] := TRUE OD; # sieve out the non-primes # s[ 1 ] := FALSE; FOR i FROM 2 TO ENTIER sqrt( UPB s ) DO IF s[ i ] THEN FOR p FROM i * i BY i TO UPB s DO s[ p ] := FALSE OD FI OD END # sieve # ;
- parse the command line - ignore errors #
INT emirp from := 1; # lowest emirp required # INT emirp to := 10; # highest emirp required # BOOL value range := FALSE; # TRUE if the range is the value of the emirps #
# FALSE if the range is the ordinal of the # # emirps #
INT max number := 1 000 000; # sieve size #
- returns s converted to an integer - does not check s is a valid integer #
PROC to int = ( STRING s )INT:
BEGIN INT result := 0; FOR ch pos FROM LWB s TO UPB s DO result *:= 10; result +:= ABS s[ ch pos ] - ABS "0" OD; result END # to int # ;
FOR arg pos TO argc DO
IF argv( arg pos ) = "FROM" THEN emirp from := to int( argv( arg pos + 1 ) ) ELIF argv( arg pos ) = "TO" THEN emirp to := to int( argv( arg pos + 1 ) ) ELIF argv( arg pos ) = "VALUE" THEN value range := TRUE ELIF argv( arg pos ) = "ORDINAL" THEN value range := FALSE ELIF argv( arg pos ) = "SIEVE" THEN max number := to int( argv( arg pos + 1 ) ) FI
OD;
- construct a sieve of primes up to the maximum number required for the task #
[ 1 : max number ]BOOL is prime; sieve( is prime );
- return TRUE if p is an emirp, FALSE otherwise #
PROC is emirp = ( INT p )BOOL:
IF NOT is prime[ p ] THEN FALSE ELSE # reverse the digits of p, if this is a prime different from p, # # p is an emirp # INT q := 0; INT rest := ABS p; WHILE rest > 0 DO q TIMESAB 10; q PLUSAB rest MOD 10; rest OVERAB 10 OD; is prime[ q ] AND q /= p FI # is emirp # ;
- generate the required emirp list #
IF value range THEN
# find emirps with values in the specified range # print( ( "emirps between ", whole( emirp from, 0 ), " and ", whole( emirp to, 0 ), ":" ) ); FOR p FROM emirp from TO emirp to DO IF is emirp( p ) THEN print( ( " ", whole( p, 0 ) ) ) FI OD
ELSE
# find emirps with ordinals in the specified range # INT emirp count := 0; IF emirp from = emirp to THEN print( ( "emirp ", whole( emirp from, 0 ), ":" ) ) ELSE print( ( "emirps ", whole( emirp from, 0 ), " to ", whole( emirp to, 0 ), ":" ) ) FI; FOR p TO max number WHILE emirp count < emirp to DO IF is emirp( p ) THEN # have another emirp # emirp count +:= 1; IF emirp count >= emirp from THEN print( ( " ", whole( p, 0 ) ) ) FI FI OD
FI; print( ( newline ) )</lang>
- Output:
a68g emirpPrimes.a68 - FROM 1 TO 20
emirps 1 to 20: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389
a68g emirpPrimes.a68 - FROM 7700 TO 8000 VALUE
emirps between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963
a68g emirpPrimes.a68 - FROM 10000 TO 10000
emirp 10000: 948349
AutoHotkey
<lang AutoHotkey>SetBatchLines, -1 p := 1 Loop, 20 { p := NextEmirp(p) a .= p " " } p := 7700 Loop { p := NextEmirp(p) if (p > 8000) break b .= p " " } p :=1 Loop, 10000 p := NextEmirp(p) MsgBox, % "First twenty emirps: " a . "`nEmirps between 7,700 and 8,000: " b . "`n10,000th emirp: " p
IsPrime(n) { if (n < 2) return, 0 else if (n < 4) return, 1 else if (!Mod(n, 2)) return, 0 else if (n < 9) return 1 else if (!Mod(n, 3)) return, 0 else { r := Floor(Sqrt(n)) f := 5 while (f <= r) { if (!Mod(n, f)) return, 0 if (!Mod(n, (f + 2))) return, 0 f += 6 } return, 1 } }
NextEmirp(n) { Loop if (IsPrime(++n)) { rev := Reverse(n) if (rev = n) continue if (IsPrime(rev)) return n } }
Reverse(s) { Loop, Parse, s r := A_LoopField r return r }</lang>
- Output:
First twenty emirps: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Emirps between 7,700 and 8,000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 10,000th emirp: 948349
AWK
Based on C example here :
cat emirp.awk <lang AWK> function is_prime(n, p) {
if (!(n%2) || !(n%3)) {
return 0 }
p = 1 while(p*p < n) if (n%(p += 4) == 0 || n%(p += 2) == 0) { return 0 } return 1
}
function reverse(n, r) { r = 0
for (r = 0; int(n) != 0; n /= 10) r = r*10 + int(n%10); return r
}
function is_emirp(n, r) {
r = reverse(n)
return ((r != n) && is_prime(n) && is_prime(r)) ? 1 : 0 }
BEGIN { c = 0 for (x = 11; c < 20; x += 2) { if (is_emirp(x)) { printf(" %i,", x); ++c } } printf("\n") for (x = 7701; x < 8000; x += 2) { if (is_emirp(x)) { printf(" %i,", x); ++c } } printf("\n") c = 0 for (x = 11; ; x += 2)
if (is_emirp(x) && ++c == 10000) { printf(" %i", x); break; }
printf("\n") } </lang>
- Output:
$ awk -f emirp.awk 13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389, 7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963, 948349
C
Note the unusual commandline argument parsing to sastisfy the "invoke three times" magic requirement. <lang c>#include <stdio.h>
typedef unsigned uint; int is_prime(uint n) {
if (!(n%2) || !(n%3)) return 0; uint p = 1; while(p*p < n) if (n%(p += 4) == 0 || n%(p += 2) == 0) return 0; return 1;
}
uint reverse(uint n) {
uint r; for (r = 0; n; n /= 10) r = r*10 + (n%10); return r;
}
int is_emirp(uint n) {
uint r = reverse(n); return r != n && is_prime(n) && is_prime(r);
}
int main(int argc, char **argv) {
uint x, c = 0; switch(argc) { // advanced args parsing case 1: for (x = 11; c < 20; x += 2) if (is_emirp(x)) printf(" %u", x), ++c; break;
case 2: for (x = 7701; x < 8000; x += 2) if (is_emirp(x)) printf(" %u", x); break;
default: for (x = 11; ; x += 2) if (is_emirp(x) && ++c == 10000) { printf("%u", x); break; } }
putchar('\n'); return 0;
}</lang>
- Output:
% ./a.out # no argument: task 1 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 % ./a.out a # one argument: task 2 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 % ./a.out a b # you get the idea 948349
C++
<lang Cpp>#include <vector>
- include <iostream>
- include <algorithm>
- include <sstream>
- include <string>
- include <cmath>
bool isPrime ( int number ) {
if ( number <= 1 ) return false ; if ( number == 2 ) return true ; for ( int i = 2 ; i <= std::sqrt( number ) ; i++ ) { if ( number % i == 0 )
return false ;
} return true ;
}
int reverseNumber ( int n ) {
std::ostringstream oss ; oss << n ; std::string numberstring ( oss.str( ) ) ; std::reverse ( numberstring.begin( ) , numberstring.end( ) ) ; return std::stoi ( numberstring ) ;
}
bool isEmirp ( int n ) {
return isPrime ( n ) && isPrime ( reverseNumber ( n ) ) && n != reverseNumber ( n ) ;
}
int main( ) {
std::vector<int> emirps ; int i = 1 ; while ( emirps.size( ) < 20 ) { if ( isEmirp( i ) ) { emirps.push_back( i ) ; } i++ ; } std::cout << "The first 20 emirps:\n" ; for ( int i : emirps ) std::cout << i << " " ; std::cout << '\n' ; int newstart = 7700 ; while ( newstart < 8001 ) { if ( isEmirp ( newstart ) )
std::cout << newstart << '\n' ;
newstart++ ; } while ( emirps.size( ) < 10000 ) { if ( isEmirp ( i ) ) {
emirps.push_back( i ) ;
} i++ ; } std::cout << "the 10000th emirp is " << emirps[9999] << " !\n" ;
return 0 ;
}</lang>
- Output:
13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 the 10000th emirp is 948349 !
C#
<lang csharp>using static System.Console; using System; using System.Linq; using System.Collections.Generic;
public class Program {
public static void Main() { const int limit = 1_000_000; WriteLine("First 20:"); WriteLine(FindEmirpPrimes(limit).Take(20).Delimit()); WriteLine();
WriteLine("Between 7700 and 8000:"); WriteLine(FindEmirpPrimes(limit).SkipWhile(p => p < 7700).TakeWhile(p => p < 8000).Delimit()); WriteLine();
WriteLine("10000th:"); WriteLine(FindEmirpPrimes(limit).ElementAt(9999)); }
private static IEnumerable<int> FindEmirpPrimes(int limit) { var primes = Primes(limit).ToHashSet();
foreach (int prime in primes) { int reverse = prime.Reverse(); if (reverse != prime && primes.Contains(reverse)) yield return prime;
}
}
private static IEnumerable<int> Primes(int bound) { if (bound < 2) yield break; yield return 2;
BitArray composite = new BitArray((bound - 1) / 2); int limit = ((int)(Math.Sqrt(bound)) - 1) / 2; for (int i = 0; i < limit; i++) { if (composite[i]) continue;
int prime = 2 * i + 3; yield return prime;
for (int j = (prime * prime - 2) / 2; j < composite.Count; j += prime) composite[j] = true;
}
for (int i = limit; i < composite.Count; i++) if (!composite[i]) yield return 2 * i + 3;
}
}
public static class Extensions {
public static HashSet<T> ToHashSet<T>(this IEnumerable<T> source) => new HashSet<T>(source);
private const string defaultSeparator = " "; public static string Delimit<T>(this IEnumerable<T> source, string separator = defaultSeparator) => string.Join(separator ?? defaultSeparator, source);
public static int Reverse(this int number) {
if (number < 0) return -Reverse(-number); if (number < 10) return number; int reverse = 0; while (number > 0) { reverse = reverse * 10 + number % 10; number /= 10; } return reverse;
}
}</lang>
- Output:
First 20: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 10000th: 948349
Clojure
Using biginteger's isProbablePrime()
The isProbablePrime() method performs a Miller-Rabin primality test to within a given certainty. <lang clojure>(defn emirp? [v]
(let [a (biginteger v) b (biginteger (clojure.string/reverse (str v)))] (and (not= a b) (.isProbablePrime a 16) (.isProbablePrime b 16))))
- Generate the output
(println "first20: " (clojure.string/join " " (take 20 (filter emirp? (iterate inc 0))))) (println "7700-8000: " (clojure.string/join " " (filter emirp? (range 7700 8000)))) (println "10,000: " (nth (filter emirp? (iterate inc 0)) 9999))
</lang>
- Output:
first20: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 7700-8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 10,000: 948349
Common Lisp
It uses a primitive prime function found in http://www.rosettacode.org/wiki/Primality_by_trial_division, not optimized at all. <lang 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)))))
(defun reverse-digits (n)
(labels ((next (n v) (if (zerop n) v (multiple-value-bind (q r) (truncate n 10) (next q (+ (* v 10) r)))))) (next n 0)))
(defun emirp (&key (count nil) (start 10) (end nil) (print-all nil))
(do* ((n start (1+ n)) (c count) ) ((or (and count (<= c 0)) (and end (>= n end)))) (when (and (primep n) (not (= n (reverse-digits n))) (primep (reverse-digits n))) (when print-all (format t "~a " n)) (when count (decf c)) )))
(progn
(format t "First 20 emirps: ") (emirp :count 20 :print-all t) (format t "~%Emirps between 7700 and 8000: ") (emirp :start 7700 :end 8000 :print-all t) (format t "~%The 10,000'th emirp: ") (emirp :count 10000 :print-all nil) )
</lang>
- Output:
First 20 emirps: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Emirps between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 The 10,000'th emirp: 948349
D
<lang d>bool isEmirp(uint n) pure nothrow @nogc {
bool isPrime(in uint n) pure nothrow @nogc { if (n == 2 || n == 3) return true; else if (n < 2 || n % 2 == 0 || n % 3 == 0) return false; for (uint div = 5, inc = 2; div ^^ 2 <= n; div += inc, inc = 6 - inc) if (n % div == 0) return false;
return true; }
uint reverse(uint n) pure nothrow @nogc { uint r; for (r = 0; n; n /= 10) r = r * 10 + (n % 10); return r; }
immutable r = reverse(n); return r != n && isPrime(n) && isPrime(r);
}
void main() {
import std.stdio, std.algorithm, std.range;
auto uints = uint.max.iota; writeln("First 20:\n", uints.filter!isEmirp.take(20)); writeln("Between 7700 and 8000:\n", iota(7_700, 8_001).filter!isEmirp); writeln("10000th: ", uints.filter!isEmirp.drop(9_999).front);
}</lang>
- Output:
First 20: [13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389] Between 7700 and 8000: [7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963] 10000th: 948349
This code is not efficient, but the run-time is acceptable, about 0.33 seconds with the ldc2 compiler.
Sieve-Based Version
<lang d>import std.stdio, std.algorithm, std.range, std.bitmanip;
/// Not extendible Sieve of Eratosthenes. BitArray sieve(in uint n) pure nothrow /*@safe*/ {
BitArray composites; composites.init([true, true]); composites.length = n; if (n < 2) return composites;
foreach (immutable uint i; 2 .. cast(uint)(n ^^ 0.5) + 1) if (!composites[i]) for (uint k = i * i; k < n; k += i) composites[k] = true;
return composites;
}
__gshared BitArray composites;
bool isEmirp(uint n) nothrow @nogc {
uint reverse(uint n) pure nothrow @safe @nogc { uint r; for (r = 0; n; n /= 10) r = r * 10 + (n % 10); return r; }
immutable r = reverse(n); // BitArray doesn't perform bound tests yet. assert(n < composites.length && r < composites.length); return r != n && !composites[n] && !composites[r];
}
void main() {
composites = 1_000_000.sieve;
auto uints = uint.max.iota; writeln("First 20:\n", uints.filter!isEmirp.take(20)); writeln("Between 7700 and 8000:\n", iota(7_700, 8_001).filter!isEmirp); writeln("10000th: ", uints.filter!isEmirp.drop(9_999).front);
}</lang> The output is the same. With ldc2 compiler the run-time is about 0.06 seconds.
Elixir
<lang elixir>defmodule Emirp do
defp prime?(2), do: true defp prime?(n) when n<2 or rem(n,2)==0, do: false defp prime?(n), do: prime?(n,3) defp prime?(n,k) when n<k*k, do: true defp prime?(n,k) when rem(n,k)==0, do: false defp prime?(n,k), do: prime?(n,k+2) def emirp?(n) do if prime?(n) do reverse = to_string(n) |> String.reverse |> String.to_integer n != reverse and prime?(reverse) end end def task do emirps = Stream.iterate(1, &(&1+1)) |> Stream.filter(&emirp?/1) first = Enum.take(emirps,20) |> Enum.join(" ") IO.puts "First 20 emirps: #{first}" between = Enum.reduce_while(emirps, [], fn x,acc -> cond do x < 7700 -> {:cont, acc} x in 7700..8000 -> {:cont, [x | acc]} true -> {:halt, Enum.reverse(acc)} end end) |> Enum.join(" ") IO.puts "Emirps between 7,700 and 8,000: #{between}" IO.puts "10,000th emirp: #{Enum.at(emirps, 9999)}" end
end
Emirp.task</lang>
- Output:
First 20 emirps: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Emirps between 7,700 and 8,000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 10,000th emirp: 948349
F#
The function
This task uses Extensible Prime Generator (F#) <lang fsharp> // Generate emirps. Nigel Galloway: November 19th., 2017 let emirp =
let rec fN n g = match n with |0->g |_->fN (n/10) (g*10+n%10) let fG n g = n<>g && isPrime g primes |> Seq.filter (fun n -> fG n (fN n 0))
</lang>
The Task
<lang fsharp> emirps |> (Seq.take 20) |> Seq.iter (printf "%d ") </lang>
- Output:
13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389
<lang fsharp> emirps |> Seq.skipWhile (fun n->n<7700) |> Seq.takeWhile (fun n->n<=8000) |> Seq.iter (printf "%d ") </lang>
- Output:
7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963
<lang fsharp> printfn "%d" (Seq.item 9999 emirps) </lang>
- Output:
948349
<lang fsharp> // count # of emirps with n = 2 to 7 digits. Nigel Galloway: August 8th., 2018 let n=emirp |> Seq.takeWhile(fun n->n<10000000) |> Seq.countBy(fun n->match n with |n when n>999999->7
|n when n> 99999->6 |n when n> 9999->5 |n when n> 999->4 |n when n> 99->3 |_ ->2)
for n,g in n do printfn "%d -> %d" n g </lang>
- Output:
2 -> 8 3 -> 28 4 -> 204 5 -> 1406 6 -> 9538 7 -> 70474 Real: 00:07:19.408, CPU: 00:07:23.250, GC gen0: 59744, gen1: 3
Factor
<lang factor>USING: io kernel lists lists.lazy math.extras math.parser
math.primes sequences ;
FROM: prettyprint => . pprint ; IN: rosetta-code.emirp
- rev ( n -- n' )
number>string reverse string>number ;
- emirp? ( n -- ? )
dup rev [ = not ] [ [ prime? ] bi@ ] 2bi and and ;
- nemirps ( n -- seq )
0 lfrom [ emirp? ] lfilter ltake list>array ;
- print-seq ( seq -- )
[ pprint bl ] each nl ;
- part1 ( -- )
"First 20 emirps:" print 20 nemirps print-seq ;
- part2 ( -- )
"Emirps between 7700 and 8000:" print 7700 ... 8000 [ emirp? ] filter print-seq ;
- part3 ( -- )
"10,000th emirp:" print 10,000 nemirps last . ;
- main ( -- )
part1 nl part2 nl part3 ;
MAIN: main</lang>
- Output:
First 20 emirps: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Emirps between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 10,000th emirp: 948349
Fortran
Fortran has no standard interface arrangements whereby a run can be supplied with parameters from a command line. Some implementations do provide a routine, possibly called something like GETARG and with a variety of parameters and usages. One can of course read a disc file containing suitable parameters, but this is not as specified. So, to meet the three invocations, a subroutine is devised with parameters that allow it to perform the three different tasks. To handle "the first twenty", the parameters are easy 1,20. For "the 10,000'th", they are 10000,10000. Meeting the requirement for an invocation that lists all emirPs between 7,700 and 8,000 involved further bending, with the result that the subroutine has four parameters. Then I thought: why not specify the base for the numerology? So, five.
Now arise such questions as well-based emirPs. For instance, 17 is a base ten emirP, and in (say) base thirteen, 17 is 14 (and not an even number); 41 in base thirteen is 53 and that is a prime also. So, 17 (the number) is an emirP in both base ten and base thirteen. Is there a maximally-based emirP? But, for now, onwards in base ten.
The source would be F77, except for the idea of having the assistant routines GETPRIME(i), NEXTPRIME(n), and ISPRIME(n) all share the responsibility for the updating of a stash of prime numbers as they find the need rather than pre-emptively calculating a table of primes that is large enough for any expected usage, possibly by some high-speed trickery. Since the routines invoke each other back and forth, the dreaded attribute of RECURSIVE must be declared to encourage the compiler and so F90 is required. Otherwise, each routine would have to be careful over its own usage. Each would separately have to be able to proceed past the end of the current stash of prime numbers should its need arise, and augment the table as possible. For use in factoring numbers, the table need not be large as P(4792) = 46337, and the square of this exceeds the capacity of a signed thirty-two bit integer. But in this task, actual prime numbers are required well beyond that. Each run announces the table size, thereby showing the limit of its table of primes; there seemed no point in clearing the table each time to more closely follow the notion of separate runs.
For factoring numbers up to the 32-bit two's complement integer limit, the table need not be large, and it can easily enough be stored as a collection of sixteen and thirty-two bit numbers to save some space. Accessing an array PRIME(i) can be made a function GETPRIME(i) without a change in syntax (as needed in pascal: Prime[i] for an array, GetPrime(i) for a function), at least for reading. So, instead of 4792x4 = 19168 bytes, 12144 are needed, to set against the additional code complexity. These days, this is a difference of small importance. Actually, a further value is needed to hold Prime(4793) = 46349. Function ISPRIME does not determine its stepping point via the near universal usage of SQRT(n). If calculated in double precision this will give acceptable results for a 32-bit integer, but I have been burnt by an ad-hoc calculation nDgits = LOG10(x) + 1 failing for x = 10 because Log10(10) = 0·9999etc. which may well round to one, but truncates to zero. So, a SQRT-free demonstration, needed if the MOD function were unavailable. Actually, if P(i) is the last factor to be checked, this suffices up to the square of P(i + 1), not P(i). But this bound is only useful when successive numbers are being tested; for an individual factorisation it is too messy.
The initial version ran very slowly once past the first run, and this prompted some instrumentation, the addition of counters for the invocations. It transpired that GETPRIME(i) was being invoked thousands of millions of times... Once again, a N2 process is to be avoided, here when NEXTPRIME(n) was stepping linearly along the array of primes (in the hope of knowing the next prime along without having to recalculate it) and being invoked many times to do so. This was fixed by introducing a binary search, the list of primes being of course in order. The early version of NEXTPRIME(n) also did not attempt to save new primes, as it might be invoked with a value well beyond the end of the table and the next value on from n might be past many lesser primes. But by working on from PRIME(NP) up to n they can be found and saved along the way. Saving new primes in NEXTPRIME meant that GETPRIME should no longer itself attempt saving, as it is invoking NEXTPRIME. Mutual recursion is all very well, but organisation is important also. <lang Fortran> MODULE BAG !A mixed assortment.
INTEGER MSG !I/O unit number to share about. INTEGER PF16LIMIT,PF32LIMIT,NP !Know that P(3512) = 32749, the last within two's complement 16-bit integers. PARAMETER (PF16LIMIT = 3512, PF32LIMIT = 4793) !32749² = 1,072,497,001; the integer limit is 2,147,483,647 in 32-bit integers. INTEGER*2 PRIME16(PF16LIMIT) !P(4792) = 46337, next is 46349 and 46337² = 2,147,117,569. INTEGER*4 PRIME32(PF16LIMIT + 1:PF32LIMIT) !Let the compiler track the offsets. DATA NP,PRIME16(1),PRIME16(2)/2,2,3/ !But, start off with this. Note that Prime(NP) is odd... INTEGER NGP,NNP,NIP !Invocation counts. DATA NGP,NNP,NIP/3*0/ !Starting at zero. CONTAINS !Some co-operating routines. RECURSIVE INTEGER FUNCTION GETPRIME(I) !They are numbered. As if in an array Prime(i).
Chooses from amongst two arrays, of sizes known from previous work.
INTEGER I !The desired index. INTEGER P !A potential prime. INTEGER MP !Counts beyond NP. NGP = NGP + 1 !Another try. IF (I.LE.0) THEN !A silly question? GETPRIME = -666 !This should cause trouble! ELSE IF (I.LE.NP) THEN !I have a little list. IF (I.LE.PF16LIMIT) THEN !Well actually, two little lists. GETPRIME = PRIME16(I) !So, direct access from this. ELSE !Or, for the larger numbers, GETPRIME = PRIME32(I) !This. END IF !So much for previous effort. ELSE IF (I.LE.PF32LIMIT) THEN !My list may not yet be completely filled. MP = NP !This is the last stashed so far. P = GETPRIME(NP) !I'll ask me to figure out where this is stashed. 10 P = NEXTPRIME(P) !Go for the next one along. MP = MP + 1 !Advance my count. IF (MP.LT.I) GO TO 10 !Are we there yet? GETPRIME = P !Yep. ELSE !But, my list may be too short. WRITE (MSG,*) "Hic!",I !So, give an indication. STOP "Too far..." !And quit. END IF !For factoring 32-bit, need only 4792 elements. END FUNCTION GETPRIME !This is probably faster than reading from a monster disc file.
SUBROUTINE STASHPRIME(P) !Saves a value in the stash. INTEGER P !The prime to be stashed. NP = NP + 1 !Count another in. IF (NP.LE.PF16LIMIT) THEN !But, where to? PRIME16(NP) = P !The short list. ELSE IF (NP.LE.PF32LIMIT) THEN!Or, PRIME32(NP) = P !The long list (which is shorter) ELSE !Or, STOP "Stash overflow!" !Oh dear. END IF !It is stashed. END SUBROUTINE STASHPRIME !The checking should be redundant.
INTEGER FUNCTION FINDPRIME(IT) !Via binary search. INTEGER IT !The value to be found. INTEGER L,R,P !Assistants. L = 0 !This is the *exclusive bounds* version. R = NP + 1 !Thus, L = first - 1; R = Last + 1. 1 P = (R - L)/2 !Probe offset. IF (P.LE.0) THEN !No span? FINDPRIME = -L !Not found. IT follows Prime(L). RETURN !Escape. END IF !But otherwise, P = P + L !Convert to an index into array PRIME, manifested via GETPRIME. IF (IT - GETPRIME(P)) 2,4,3 !Compare... Three way result. 2 R = P; GO TO 1 !IT < PRIME(P): move R back. 3 L = P; GO TO 1 !PRIME(P) < IT: move L forward. 4 FINDPRIME = P !PRIME(P) = IT: Found here! END FUNCTION FINDPRIME !Simple and fast.
RECURSIVE INTEGER FUNCTION NEXTPRIME(P) !Some effort may ensue.
Checks the stash in PRIME in the hope of finding the next prime directly, otherwise advances from P. Collates a stash of primes in PRIME16 and PRIME32, advancing NP from 2 to PF32LIMIT as it goes.
INTEGER P !Not necessarily itself a prime number. INTEGER PI !A possibly prime increment. INTEGER IT !A finger. NNP = NNP + 1 !Another try IF (P.LE.1) THEN !Dodge annoying effects. Otherwise, FINDPRIME(P) would be zero. PI = 2 !The first prime is known. Because P precedes Prime(1). ELSE !The first stashed value is two. IT = (ABS(FINDPRIME(P))) !The stash is ordered, and P = 2 will be found at 1. IF (IT.LT.NP) THEN !Before my last-known prime? FINDPRIME(4) = -2 as it follows Prime(NP=2). PI = GETPRIME(IT + 1) !Yes, so I know the next along already. ELSE !Otherwise, it is past Prime(NP). and IT = NP thanks to the ABS. IF (NP.LT.PF32LIMIT) THEN !If my stash is not yet filled, PI = GETPRIME(IT) !I want to start with its last entry, known to be an odd number. ELSE !So that I can stash each next prime along the way. PI = P !Otherwise, start with P. IF (MOD(PI,2).EQ.0) PI = PI - 1 !And some suspicion. END IF !So much for a starting position. DO WHILE (PI.LE.P) !Perhaps I must go further. 11 PI = PI + 2 !Advance to a possibility. IF (.NOT.ISPRIME(PI)) GO TO 11 !Discard it? IF (IT.EQ.NP .AND. IT.LT.PF32LIMIT) THEN !Am I one further on from NP? CALL STASHPRIME(PI) !Yes, and there is space to stash it. IT = IT + 1 !Ready for the next one along, if it comes. END IF !All are candidates for my stash. END DO !Perhaps this prime will be big enough. END IF !It may be a long way past PRIME(NP). END IF !And I may have filled my stash along the way. NEXTPRIME = PI !Take that. END FUNCTION NEXTPRIME !Messy.
RECURSIVE LOGICAL FUNCTION ISPRIME(N) !Checks an arbitrary number, though limited by INTEGER size.
Crunches up to SQRT(N), and at worst needs to be able to reach Prime(4793) = 46349; greater than SQRT(2147483647) = 46340·95...
INTEGER N !The number. INTEGER I,F,Q !Assistants. NIP = NIP + 1 !Another try. IF (N.LT.2) THEN !Dodge annoyances. ISPRIME = .FALSE. !Such as N = 1, and the first F being 2. ELSE !Otherwise, some effort. ISPRIME = .FALSE. !The usual result. I = 1 !Start at the start with PRIME(1). 10 F = GETPRIME(I) !Thus, no special case with F = 2. Q = N/F !So, how many times? (Truncation, remember) IF (Q .GE. F) THEN !Q < F means F² > N. IF (Q*F .EQ. N) RETURN !A factor is found! I = I + 1 !Very well. GO TO 10 !Try the next possible factor. END IF !And if we get through all that, ISPRIME = .TRUE. !It is a prime number. END IF !And we're done. END FUNCTION ISPRIME !After a lot of divisions.
INTEGER FUNCTION ESREVER(IT,BASE) !Reversed digits. INTEGER IT !The number to be reversed. Presumably positive. INTEGER BASE !For the numerology. INTEGER N,R !Assistants. IF (BASE.LE.1) STOP "Base 2 at least!" !Ah, distrust. N = IT !A copy I can damage. R = 0 !Here we go. DO WHILE(N.GT.0) !A digit remains? R = R*BASE + MOD(N,BASE) !Yes. Grab the low-order digit of N. N = N/BASE !And reduce N by another power of BASE. END DO !Test afresh. ESREVER = R !That's it. END FUNCTION ESREVER !Easy enough.
SUBROUTINE EMIRP(BASE,N1,N2,I1,I2) !Two-part interface. INTEGER BASE !Avoid decimalist chauvinism. INTEGER N1,N2 !Count span to show those found. INTEGER I1,I2 !Search span. INTEGER N !Counter. INTEGER P,R !Assistants. WRITE (MSG,1) N1,N2,BASE,I1,I2 !Declare the purpose. 1 FORMAT ("Show the first ",I0," to ",I0, !So as to encompass & " emirP numbers (base ",I0,") between ",I0," and ",I0) !The specified options. N = 0 !None found so far. P = I1 - 1 !Syncopation. The starting position might itself be a prime number.
Chase another emirP.
10 P = NEXTPRIME(P) !I want the next prime. IF (P.LT.I1) GO TO 10 !Up to the starting mark yet? IF (P.GT.I2) GO TO 900 !Past the finishing mark? R = ESREVER(P,BASE) !Righto, a candidate. IF (P .EQ. R) GO TO 10 !Palindromes are rejected. IF (.NOT.ISPRIME(R)) GO TO 10 !As are non-primes. N = N + 1 !Aha, a success!
c if (mod(n,100) .eq. 0) then c write (6,66) N,P,R,NP,NGP,NNP,NIP c 66 format ("N=",I5,",p=",I6,",R=",I6,",NP=",I6,3I12) c end if
IF (N.GE.N1) WRITE (6,*) P,R !Are we within the count span? IF (N.LT.N2) GO TO 10 !Past the end?
Closedown.
900 WRITE (MSG,901) NP,GETPRIME(NP) !Might be of interest. 901 FORMAT ("Stashed up to Prime(",I0,") = ",I0,/) END SUBROUTINE EMIRP !Well, that was odd. END MODULE BAG !Mixed.
PROGRAM POKE !Now put it all to the test. USE BAG !With ease. MSG = 6 !Standard output.
CALL EMIRP(10, 1, 20, 1, 1000) !These parameters CALL EMIRP(10, 1, 28,7700, 8000) !Meet the specifiction CALL EMIRP(10,10000,10000, 1,1000000) !Of three separate invocations.
END !Whee!</lang>
Output:
Show the first 1 to 20 emirP numbers (base 10) between 1 and 1000 13 31 17 71 31 13 37 73 71 17 73 37 79 97 97 79 107 701 113 311 149 941 157 751 167 761 179 971 199 991 311 113 337 733 347 743 359 953 389 983 Stashed up to Prime(77) = 389 Show the first 1 to 28 emirP numbers (base 10) between 7700 and 8000 7717 7177 7757 7577 7817 7187 7841 1487 7867 7687 7879 9787 7901 1097 7927 7297 7949 9497 7951 1597 7963 3697 Stashed up to Prime(1008) = 8009 Show the first 10000 to 10000 emirP numbers (base 10) between 1 and 1000000 948349 943849 Stashed up to Prime(4793) = 46349
And the invocation counts: GETPRIME 15,200,926; NEXTPRIME 74,799; ISPRIME 548,944. The execution time is small: the run completes even as the new output window stabilises on the screen.
An earlier version used a larger table of primes (size 123,456) as EMIRP advanced via I = I + 1; P = GETPRIME(I)
thereby only considering successive primes as candidates without having to check factors to find them. By converting to P = NEXTPRIME(P)
the table could be made smaller, but this meant being clear within NEXTPRIME that if P was greater than the last stashed prime, and the table was filled, then the table no longer offered an advantage and the search should start from P. With larger P, starting from Prime(NP) meant more and more catching up.
Function ISPRIME uses GETPRIME(i) for its successive factor trials, and thus works only up to the table limit unless GETPRIME were to be extended. If NEXTPRIME were used instead the table would be accessed where possible, otherwise a march would begin. If ISPRIME were to be changed to accept say a 64-bit integer the table size limit could be increased, but alas a complete table would require around 139,094,144 entries, and all those trial divisions would take a while. Still, the possible factors go no further than F = SQRT(N), approximately calculated now, and to check that F has no factors requires only tests up to SQRT(F)...
Project Extensible_prime_generator#Fortran offers a scheme supporting such routines as PRIME(i) instead of GETPRIME(i), NEXTPRIME(N), and ISPRIME(N), using a disc file in place of a large array in memory - whose values would be lost when the run finishes. But instead of about a hundred lines of Fortran to provide primes for EMIRP, module PRIMEBAG requires 311 lines.
FreeBASIC
<lang freebasic>' FB 1.05.0 Win64
Function isPrime(n As UInteger) As Boolean
If n < 2 Then Return False If n Mod 2 = 0 Then Return n = 2 If n Mod 3 = 0 Then Return n = 3 Dim d As Integer = 5 While d * d <= n If n Mod d = 0 Then Return False d += 2 If n Mod d = 0 Then Return False d += 4 Wend Return True
End Function
Function reverseNumber(n As UInteger) As UInteger
If n < 10 Then Return n Dim As Integer sum = 0 While n > 0 sum = 10 * sum + (n Mod 10) n \= 10 Wend Return sum
End Function
Function isEmirp(n As UInteger) As Boolean
If Not isPrime(n) Then Return False Dim As UInteger reversed = reverseNumber(n) Return reversed <> n AndAlso CInt(isPrime(reversed))
End Function
' We can immediately rule out all primes from 2 to 11 as these are palindromic ' and not therefore Emirp primes Print "The first 20 Emirp primes are :" Dim As UInteger count = 0, i = 13 Do
If isEmirp(i) Then Print Using "####"; i; count + = 1 End If i += 2
Loop Until count = 20 Print : Print Print "The Emirp primes between 7700 and 8000 are:" i = 7701 Do
If isEmirp(i) Then Print Using "#####"; i; i += 2
Loop While i < 8000 Print : Print Print "The 10,000th Emirp prime is : "; i = 13 : count = 0 Do
If isEmirp(i) Then count += 1 If count = 10000 Then Exit Do i += 2
Loop Print i Print Print "Press any key to quit" Sleep</lang>
- Output:
The first 20 Emirp primes are : 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 The Emirp primes between 7700 and 8000 are: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 The 10,000th Emirp prime is : 948349
Frink
<lang frink> isEmirp[x] := {
if isPrime[x] { s = toString[x] rev = reverse[s] return s != rev and isPrime[parseInt[rev]] } return false
}
// Functions that return finite and infinite enumerating expressions of emirps emirps[] := select[primes[], getFunction["isEmirp", 1]] emirps[begin, end] := select[primes[begin, end], getFunction["isEmirp", 1]]
println["First 20: " + first[emirps[], 20]] println["Range: " + emirps[7700, 8000]] println["10000th: " + last[first[emirps[], 10000]]] </lang>
- Output:
First 20: [13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389] Range: [7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963] 10000th: 948349
Go
This has a bit more to it than required but little optimization, other than using a fast Sieve of Atkin implementation for the prime numbers and skipping some tests on ranges of impossible Emirps (thanks to a comment on the discussion page).
As a side note, by using the same API as the prime number generator this also demonstrates how Go interfaces can be used (and note it doesn't require the existing code/package to know anything about the interface being defined). <lang go>package main
import ( "flag" "fmt" "github.com/jbarham/primegen.go" // Sieve of Atkin implementation "math" )
// primeCache is a simple cache of small prime numbers, it very // well might be faster to just regenerate them as needed. type primeCache struct { gen *primegen.Primegen primes []uint64 }
func NewPrimeCache() primeCache { g := primegen.New() return primeCache{gen: g, primes: []uint64{g.Next()}} }
// upto returns a slice of primes <= n. // The returned slice is shared with all callers, do not modify it! func (pc *primeCache) upto(n uint64) []uint64 { if p := pc.primes[len(pc.primes)-1]; p <= n { for p <= n { p = pc.gen.Next() pc.primes = append(pc.primes, p) } return pc.primes[:len(pc.primes)-1] } for i, p := range pc.primes { if p > n { return pc.primes[:i] } } panic("not reached") }
var cache = NewPrimeCache()
func sqrt(x uint64) uint64 { return uint64(math.Sqrt(float64(x))) }
// isprime does a simple test if n is prime. // See also math/big.ProbablyPrime(). func isprime(n uint64) bool { for _, p := range cache.upto(sqrt(n)) { if n%p == 0 { return false } } return true }
func reverse(n uint64) (r uint64) { for n > 0 { r = 10*r + n%10 n /= 10 } return }
// isEmirp does a simple test if n is Emirp, n must be prime func isEmirp(n uint64) bool { r := reverse(n) return r != n && isprime(r) }
// EmirpGen is a sequence generator for Emirp primes type EmirpGen struct { pgen *primegen.Primegen nextn uint64 r1l, r1h uint64 r2l, r2h uint64 r3l, r3h uint64 }
func NewEmirpGen() *EmirpGen { e := &EmirpGen{pgen: primegen.New()} e.Reset() return e }
func (e *EmirpGen) Reset() { e.pgen.Reset() e.nextn = 0 // Primes >7 cannot end in 2,4,5,6,8 (leaving 1,3,7) e.r1l, e.r1h = 20, 30 e.r2l, e.r2h = 40, 70 e.r3l, e.r3h = 80, 90 }
func (e *EmirpGen) next() (n uint64) { for n = e.pgen.Next(); !isEmirp(n); n = e.pgen.Next() { // Skip over inpossible ranges // Benchmarks show this saves ~20% when generating n upto 1e6 switch { case e.r1l <= n && n < e.r1h: e.pgen.SkipTo(e.r1h) case e.r2l <= n && n < e.r2h: e.pgen.SkipTo(e.r2h) case e.r3l <= n && n < e.r3h: e.pgen.SkipTo(e.r3h) case n > e.r3h: e.r1l *= 10 e.r1h *= 10 e.r2l *= 10 e.r2h *= 10 e.r3l *= 10 e.r3h *= 10 } } return }
func (e *EmirpGen) Next() (n uint64) { if n = e.nextn; n != 0 { e.nextn = 0 return } return e.next() }
func (e *EmirpGen) Peek() uint64 { if e.nextn == 0 { e.nextn = e.next() } return e.nextn }
func (e *EmirpGen) SkipTo(nn uint64) { e.pgen.SkipTo(nn) e.nextn = 0 return }
// SequenceGen defines an arbitrary sequence generator. // Both *primegen.Primegen and *EmirpGen implement this. type SequenceGen interface { Next() uint64 Peek() uint64 Reset() SkipTo(uint64) //Count(uint64) uint64 // not implemented for *EmirpGen }
func main() { var start, end uint64 var n, skip uint var oneline, primes bool flag.UintVar(&n, "n", math.MaxUint64, "number of emirps to print") flag.UintVar(&skip, "skip", 0, "number of emirps to skip") flag.Uint64Var(&start, "start", 0, "start at x>=start") flag.Uint64Var(&end, "end", math.MaxUint64, "stop at x<=end") flag.BoolVar(&oneline, "oneline", false, "output on a single line") flag.BoolVar(&primes, "primes", false, "generate primes rather than emirps") flag.Parse()
sep := "\n" if oneline { sep = " " }
// Here's where making SequenceGen an interface comes in handy: var seq SequenceGen if primes { seq = primegen.New() } else { seq = NewEmirpGen() }
for seq.Peek() < start { seq.Next() } for ; skip > 0; skip-- { seq.Next() } for ; n > 0 && seq.Peek() <= end; n-- { fmt.Print(seq.Next(), sep) } if oneline { fmt.Println() } }</lang>
- Output:
$ ./emirp -h Usage of ./emirp: -end=18446744073709551615: stop at x<=end -n=18446744073709551615: number of emirps to print -oneline=false: output on a single line -primes=false: generate primes rather than emirps -skip=0: number of emirps to skip -start=0: start at x>=start $ ./emirp -oneline -n 20 -primes # not asked for, just demonstrating SequenceGen interface 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 $ ./emirp -oneline -n 20 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 $ ./emirp -oneline -start 7800 -end 8000 7817 7841 7867 7879 7901 7927 7949 7951 7963 $ ./emirp -skip 9999 -n 1 948349
Haskell
<lang haskell>#!/usr/bin/env runghc
import Data.HashSet (HashSet, fromList, member) import Data.List import Data.Numbers.Primes import System.Environment import System.Exit import System.IO
-- optimization mentioned on the talk page startDigOK :: Integer -> Bool startDigOK n = head (show n) `elem` "1379"
-- infinite list of primes that have an acceptable first digit filtPrimes :: [Integer] filtPrimes = filter startDigOK primes
-- finite list of primes that have an acceptable first digit and -- are the specified number of digits in length nDigsFPr :: Integer -> [Integer] nDigsFPr n =
takeWhile (< hi) $ dropWhile (< lo) filtPrimes where lo = 10 ^ (n - 1) hi = 10 ^ n
-- hash set of the filtered primes of the specified number of digits nDigsFPrHS :: Integer -> HashSet Integer nDigsFPrHS n = fromList $ nDigsFPr n
-- infinite list of hash sets, where each hash set contains primes of -- a specific number of digits, i. e. index 2 contains 2 digit primes, -- index 3 contains 3 digit primes, etc. -- Don't access index 0, because it will return an error fPrByDigs :: [HashSet Integer] fPrByDigs = map nDigsFPrHS [0 ..]
isEmirp :: Integer -> Bool isEmirp n =
let revStr = reverse $ show n reversed = read revStr hs = fPrByDigs !! length revStr in (startDigOK n) && (reversed /= n) && (reversed `member` hs)
emirps :: [Integer] emirps = filter isEmirp primes
emirpSlice :: Integer -> Integer -> [Integer] emirpSlice from to =
genericTake numToTake $ genericDrop numToDrop emirps where numToDrop = from - 1 numToTake = 1 + to - from
emirpValues :: Integer -> Integer -> [Integer] emirpValues lo hi =
dropWhile (< lo) $ takeWhile (<= hi) emirps
usage = do
name <- getProgName putStrLn $ "usage: " ++ name ++ " lo hi [slice | values]" exitFailure
main = do
hSetBuffering stdout NoBuffering args <- getArgs fixedArgs <- case length args of 1 -> return $ args ++ args ++ ["slice"] 2 -> return $ args ++ ["slice"] 3 -> return args _ -> usage let lo = read $ fixedArgs !! 0 hi = read $ fixedArgs !! 1 case fixedArgs !! 2 of "slice" -> print $ emirpSlice lo hi "values" -> print $ emirpValues lo hi _ -> usage</lang>
- Output:
This program uses the same format for command line arguments as the Perl 6 example.
$ ./Emirp.hs 1 20 [13,17,31,37,71,73,79,97,107,113,149,157,167,179,199,311,337,347,359,389] $ ./Emirp.hs 7700 8000 values [7717,7757,7817,7841,7867,7879,7901,7927,7949,7951,7963] $ ./Emirp.hs 10000 [948349]
List-based
Using list-based incremental sieve from here and trial division from here, <lang haskell> λ> let emirp p = let q=(read.reverse.show) p in q /= p && noDivsBy primesW q
λ> take 20 . filter emirp $ primesW
[13,17,31,37,71,73,79,97,107,113,149,157,167,179,199,311,337,347,359,389]
λ> filter emirp . takeWhile (< 8000) . dropWhile (< 7700) $ primesW
[7717,7757,7817,7841,7867,7879,7901,7927,7949,7951,7963] -- 0.02 secs
λ> (!! (10000-1)) . filter emirp $ primesW
948349 -- 0.69 secs</lang>
J
Solution:<lang j> emirp =: (] #~ ~: *. 1 p: ]) |.&.:":"0 NB. Input is array of primes</lang>
In other words: select numbers from the argument list whose decimal reverse is both different and prime and return those decimal reversed values as numbers. (For simplicity, we require that our argument be a list of prime numbers.)
Examples<lang j> /:~ emirp p: 2+i.75 13 17 31 37 71 73 79 97 113 311 701 733 743 751 761 941 953 971 983 991
(#~ 7700&< * 8000&>) /:~ emirp i.&.(_1&p:) 9999
7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963
# emirp p: i.74791 NB. 10,000th emirp is 74,790th prime
10000
p: 74790
948349
NB. alternative approach (first emirp value would be at index 0): 9999 { /:~ emirp p:i.1e5
943849</lang>
Java
This implementation uses a slight optimization discussed in the talk page. It will not actually check the primality (forwards or backwards) for a number that starts or ends with the digits 2, 4, 5, 6, or 8 since no primes greater than 7 end with those digits. <lang java>public class Emirp{
//trivial prime algorithm, sub in whatever algorithm you want public static boolean isPrime(long x){ if(x < 2) return false; if(x == 2) return true; if((x & 1) == 0) return false;
for(long i = 3; i <= Math.sqrt(x);i+=2){ if(x % i == 0) return false; }
return true; }
public static boolean isEmirp(long x){ String xString = Long.toString(x); if(xString.length() == 1) return false; if(xString.matches("[24568].*") || xString.matches(".*[24568]")) return false; //eliminate some easy rejects long xR = Long.parseLong(new StringBuilder(xString).reverse().toString()); if(xR == x) return false; return isPrime(x) && isPrime(xR); }
public static void main(String[] args){ int count = 0; long x = 1;
System.out.println("First 20 emirps:"); while(count < 20){ if(isEmirp(x)){ count++; System.out.print(x + " "); } x++; }
System.out.println("\nEmirps between 7700 and 8000:"); for(x = 7700; x <= 8000; x++){ if(isEmirp(x)){ System.out.print(x +" "); } }
System.out.println("\n10,000th emirp:"); for(x = 1, count = 0;count < 10000; x++){ if(isEmirp(x)){ count++; } } //--x to fix the last increment from the loop System.out.println(--x); } }</lang>
- Output:
First 20 emirps: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Emirps between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 10,000th emirp: 948349
JavaScript
Script source <lang javascript>function isPrime(n) {
if (!(n % 2) || !(n % 3)) return 0;
var p = 1; while (p * p < n) { if (n % (p += 4) == 0 || n % (p += 2) == 0) { return false } } return true
}
function isEmirp(n) {
var s = n.toString(); var r = s.split("").reverse().join(""); return r != n && isPrime(n) && isPrime(r);
}
function main() {
var out = document.getElementById("content");
var c = 0; var x = 11; var last; var str;
while (c < 10000) { if (isEmirp(x)) { c += 1;
// first twenty emirps if (c == 1) {
str = "
" + x; } else if (c < 20) { str += " " + x; } else if (c == 20) { out.innerHTML = str + " " + x + "
";
}
// all emirps between 7,700 and 8,000 else if (7700 <= x && x <= 8001) { if (last < 7700) {
str = "
" + x; } else { str += " " + x; } } else if (x > 7700 && last < 8001) { out.innerHTML += str + "
";
}
// the 10,000th emirp else if (c == 10000) {
out.innerHTML += "
" + x + "
";
}
last = x; } x += 2; }
} </lang>
Solution page <lang html><!DOCTYPE html> <html>
<head> <title>Emirp primes</title> <script src="emirp.js"></script> </head> <body onload="main()">
</body>
</html></lang>
- Output:
13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 948349
jq
The given tasks are simple to implement in jq if unbounded streams can be harnessed, which is possible in versions of jq that support "foreach" and "break". This article accordingly showcases the use of these builtins, which have been available since July 7, 2014.
Infrastructure: prime numbers <lang jq>def is_prime:
if . == 2 then true else 2 < . and . % 2 == 1 and (. as $in | (($in + 1) | sqrt) as $m | [false, 3] | until( .[0] or .[1] > $m; [$in % .[1] == 0, .[1] + 2]) | .[0] | not) end ;
def relatively_prime:
.[0] as $n | .[1] as $primes | ($n | sqrt) as $s | (.[1] | length) as $length | [0, true] | until( .[0] > $length or ($primes[.[0]] > $s) or .[1] == false; [.[0] + 1, ($n % $primes[.[0]] != 0)] ) | .[1] ;
def primes:
# The helper function, next, has arity 0 for tail recursion optimization; # its input must be an array of primes of length at least 2, # the last also being the greatest. def next: . as $previous | .[length-1] as $last | [(2 + $last), $previous] | until( relatively_prime ; .[0] += 2) as $nextp | ( $previous + [$nextp[0]] ); 2, ([2,3] | recurse( next ) | .[-1]) ;</lang>
Emirps <lang jq>def is_emirp:
. as $n | tostring | explode | reverse | implode | tonumber | (. != $n) and is_prime ;
- emirps(n) emits [i, p] where p is the i-th emirp, up to and including i == n
def emirps(n):
label $start | # state: [count, $emirp] foreach primes as $p ([0, null]; if .[0] >= n then break $start else if ($p | is_emirp) then [.[0] + 1, $p] else .[1] = null end end; if .[1] then . else empty end ) ;</lang>
The tasks
(0) The three separate subtasks can be accomplished in one step as follows: <lang jq>emirps(10000) | select( .[0] <= 20 or (7700 <= .[1] and .[1] <= 8000) or .[0] == 10000)</lang>
The output of the above is shown below.
To accomplish the three subtasks separately:
(1) First twenty: <lang jq>emirps(20)</lang>
(2) Selection by value <lang>label $top | primes | if (7700 <= .) and (. <= 8000) and is_emirp then .
elif . > 8000 then break $top else empty end</lang>
(3) 10,000th <lang>last(emirps(10000)) | .[1]</lang>
- Output:
<lang sh>$ jq -c -n -f Emirp_primes.jq [1,13] [2,17] [3,31] [4,37] [5,71] [6,73] [7,79] [8,97] [9,107] [10,113] [11,149] [12,157] [13,167] [14,179] [15,199] [16,311] [17,337] [18,347] [19,359] [20,389] [180,7717] [181,7757] [182,7817] [183,7841] [184,7867] [185,7879] [186,7901] [187,7927] [188,7949] [189,7951] [190,7963] [10000,948349]</lang>
Julia
<lang julia>using Primes
function collapse(n::Array{<:Integer})
sum = 0 for (p, d) in enumerate(n) sum += d * 10 ^ (p - 1) end return sum
end
Base.reverse(n::Integer) = collapse(reverse(digits(n))) isemirp(n::Integer) = (if isprime(n) m = reverse(n); return m != n && isprime(m) end; false)
function firstnemirps(m::Integer)
rst = zeros(typeof(m), m) i, n = 1, 2 while i ≤ m if isemirp(n) rst[i] = n i += 1 end n += 1 end return rst
end
emirps = firstnemirps(10000) println("First 20:\n", emirps[1:20]) println("Between 7700 and 8000:\n", filter(x -> 7700 ≤ x ≤ 8000, emirps)) println("10000th:\n", emirps[10000])
</lang>
- Output:
First 20: [13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389] Between 7700 and 8000: [7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963] 10000th: 948349
Kotlin
<lang scala>// version 1.1.4
fun isPrime(n: Int) : Boolean {
if (n < 2) return false if (n % 2 == 0) return n == 2 if (n % 3 == 0) return n == 3 var d = 5 while (d * d <= n) { if (n % d == 0) return false d += 2 if (n % d == 0) return false d += 4 } return true
}
fun reverseNumber(n: Int) : Int {
if (n < 10) return n var sum = 0 var nn = n while (nn > 0) { sum = 10 * sum + nn % 10 nn /= 10 } return sum
}
fun isEmirp(n: Int) : Boolean {
if (!isPrime(n)) return false val reversed = reverseNumber(n) return reversed != n && isPrime(reversed)
}
fun main(args: Array<String>) {
println("The first 20 Emirp primes are :") var count = 0 var i = 13 do { if (isEmirp(i)) { print(i.toString() + " ") count++ } i += 2 } while (count < 20) println() println() println("The Emirp primes between 7700 and 8000 are :") i = 7701 do { if (isEmirp(i)) print(i.toString() + " ") i += 2 } while (i < 8000) println() println() print("The 10,000th Emirp prime is : ") i = 13 count = 0 do { if (isEmirp(i)) count++ if (count == 10000) break i += 2 } while(true) print(i)
}</lang>
- Output:
The first 20 Emirp primes are : 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 The Emirp primes between 7700 and 8000 are : 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 The 10,000th Emirp prime is : 948349
Lua
<lang Lua> function isPrime (n)
if n < 2 then return false end if n < 4 then return true end if n % 2 == 0 then return false end for d = 3, math.sqrt(n), 2 do if n % d == 0 then return false end end return true
end
function isEmirp (n)
if not isPrime(n) then return false end local rev = tonumber(string.reverse(n)) if rev == n then return false end return isPrime(rev)
end
function emirpGen (mode, a, b)
local count, n, eString = 0, 0, "" if mode == "between" then for n = a, b do if isEmirp(n) then eString = eString .. n .. " " end end return eString end while count < a do n = n + 1 if isEmirp(n) then eString = eString .. n .. " " count = count + 1 end end if mode == "first" then return eString end if mode == "Nth" then return n end
end
if #arg > 1 and #arg < 4 then
print(emirpGen(arg[1], tonumber(arg[2]), tonumber(arg[3])))
else
print("Wrong number of arguments")
end </lang> Command prompt session:
>lua emirp.lua first 20 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 >lua emirp.lua between 7700 8000 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 >lua emirp.lua Nth 10000 948349
Maple
<lang Maple>EmirpPrime := proc(n)
local eprime; eprime := parse(StringTools:-Reverse(convert(n,string))); if n <> eprime and isprime(n) and isprime(eprime) then return n; end if;
end proc: EmirpsList := proc( n )
local i, values; values := Array([]): i := 0: do i := i + 1; if EmirpPrime(i) <> NULL then ArrayTools:-Append(values, i); end if; until numelems(values) = n; return convert(values,list);
end proc: EmirpsList(20); EmirpPrime~([seq(7700..8000)]); EmirpsList(10000)[-1]; </lang>
- Output:
[13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389] [7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963] 948349
Mathematica
First a simple helper function <lang Mathematica>reverseDigits[n_Integer] := FromDigits@Reverse@IntegerDigits@n</lang> A function to test whether n is an emirp prime <lang Mathematica>emirpQ[n_Integer] :=
Block[{rev = reverseDigits@n}, And[n != rev, PrimeQ[rev]]]</lang>
Note, this test function assumes n is prime. Adding a check to verify n is prime will have an impact on execution time for finding the mth emirp prime particularly when m is large.
Finally, a function which returns the first emirp prime larger than the supplied argument <lang Mathematica>nextEmirp[n_Integer] :=
NestWhile[NextPrime, NextPrime[n], ! emirpQ[#] &]</lang>
With these the first 20 emirp primes are computed as: <lang Mathematica>Rest@NestList[nextEmirp, 1, 20]</lang>
- Output:
{13,17,31,37,71,73,79,97,107,113,149,157,167,179,199,311,337,347,359,389}
The emirp primes betweewn 7700 and 8000 are: <lang Mathematica>Rest@NestWhileList[nextEmirp, 7700, # < 8000 &]</lang>
- Output:
{7717,7757,7817,7841,7867,7879,7901,7927,7949,7951,7963,9001}
The 10,000th emirp prime is: <lang Mathematica>Nest[nextEmirp, 1, 10000]</lang>
- Output:
948349
MATLAB
<lang Matlab> NN=(1:1:1e6); %Natural numbers between 1 and t pns=NN(isprime(NN)); %prime numbers p=fliplr(str2num(fliplr(num2str(pns)))); a=pns(isprime(p)); b=p(isprime(p)); c=a-b; emirps=NN(a(c~=0)); </lang>
- Output:
the first twenty emirps are: emirps(1:20) ans = Columns 1 through 14 13 17 31 37 71 73 79 97 107 113 149 157 167 179 Columns 15 through 20 199 311 337 347 359 389
The emirp primes betweewn 7700 and 8000 are: emirps(emirps>=7700 & emirps<=8000) ans = Columns 1 through 7 7717 7757 7817 7841 7867 7879 7901 Columns 8 through 11 7927 7949 7951 7963
The 10,000th emirp prime is: emirps(10000) ans = 948349
Modula-2
<lang modula2>MODULE Emirp; FROM Conversions IMPORT StrToLong; FROM FormatString IMPORT FormatString; FROM LongMath IMPORT sqrt; FROM Terminal IMPORT WriteString,WriteLn,ReadChar;
PROCEDURE IsPrime(x : LONGINT) : BOOLEAN; VAR
i : LONGINT; u : LONGREAL; v : LONGINT;
BEGIN
IF x<2 THEN RETURN FALSE END; IF x=2 THEN RETURN TRUE END; IF x MOD 2 = 0 THEN RETURN FALSE END;
u := sqrt(FLOAT(x)); v := TRUNC(u);
FOR i:=3 TO v BY 2 DO IF x MOD i = 0 THEN RETURN FALSE END END;
RETURN TRUE
END IsPrime;
PROCEDURE IsEmirp(x : LONGINT) : BOOLEAN; VAR
buf,rev : ARRAY[0..9] OF CHAR; i,j : INTEGER; y : LONGINT;
BEGIN
(* Terminate early if the number is even *) IF x MOD 2 = 0 THEN RETURN FALSE END;
(* First convert the input to a string *) FormatString("%l", buf, x);
(* Create a copy of the string revered *) j := 0; WHILE buf[j] # 0C DO INC(j) END; DEC(j); i := 0; WHILE buf[i] # 0C DO rev[i] := buf[j]; INC(i); DEC(j) END; rev[i] := 0C;
(* Convert the reversed copy to a number *) StrToLong(rev,y);
(* Terminate early if the number is even *) IF y MOD 2 = 0 THEN RETURN FALSE END;
(* Discard palindromes *) IF x=y THEN RETURN FALSE END;
RETURN IsPrime(x) AND IsPrime(y)
END IsEmirp;
VAR
buf : ARRAY[0..63] OF CHAR; x,count : LONGINT;
BEGIN
count := 0; x := 1;
WriteString("First 20 emirps:"); WriteLn; WHILE count<20 DO IF IsEmirp(x) THEN INC(count); FormatString("%l ", buf, x); WriteString(buf) END; INC(x) END; WriteLn;
WriteString("Emirps between 7700 and 8000:"); WriteLn; FOR x:=7700 TO 8000 DO IF IsEmirp(x) THEN FormatString("%l ", buf, x); WriteString(buf) END END; WriteLn;
WriteString("10,000th emirp:"); WriteLn; count := 0; x := 1; WHILE count<10000 DO IF IsEmirp(x) THEN INC(count); END; INC(x) END; FormatString("%l ", buf, x-1); WriteString(buf); WriteLn;
ReadChar
END Emirp.</lang>
Oforth
Using isPrime function of Primality by trial division task :
<lang Oforth>: isEmirp(n)
n isPrime ifFalse: [ false return ] n asString reverse asInteger dup n == ifTrue: [ drop false ] else: [ isPrime ] ;
- main(min, max, length)
| l |
ListBuffer new ->l min while(l size length < ) [ dup max > ifTrue: [ break ] dup isEmirp ifTrue: [ dup l add ] 1 + ] drop l ;</lang>
- Output:
>main(2, 9999999, 20) println [13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389] >main(7700, 8000, 300) println [7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963] >main(2, 9999999999, 10000) last println 948349
PARI/GP
<lang parigp>rev(n)=subst(Polrev(digits(n)),'x,10); emirp(n)=my(r=rev(n)); isprime(r) && isprime(n) && n!=r select(emirp, primes(100))[1..20] select(emirp, primes([7700,8000])) s=10000; forprime(p=2,,if(emirp(p) && s--==0, return(p)))</lang>
- Output:
%1 = [13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389] %2 = [7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963] %3 = 948349
Pascal
using trial division unit , but jumping over number ranges, where the reversed numbers can't be a prime. Compiles with Delphi and Free Pascal. <lang pascal>program Emirp; //palindrome prime 13 <-> 31 {$IFDEF FPC}
{$MODE DELPHI} {$OPTIMIZATION ON} {$OPTIMIZATION REGVAR} {$OPTIMIZATION PEEPHOLE} {$OPTIMIZATION CSE} {$OPTIMIZATION ASMCSE} {$Smartlink ON} {$CODEALIGN proc=32}
{$ELSE}
{$APPLICATION CONSOLE}
{$ENDIF} uses
primtrial,sysutils; //IntToStr
const
helptext : array[0..5] of string = (' usage ', ' t -> test of functions', ' b l u -> Emirps betwenn l,u b 7700 8000', ' c n -> count of Emirps up to n c 99999', ' f n -> output n first Emirp f 20', ' n -> output the n.th Emirps 10000');
StepToNextPrimeEnd : Array[0..9] of byte = (1,0,3,0,7,7,7,0,9,0);
base = 10;
var
s: AnsiString; pow, powLen : NativeUint;
procedure OutputHelp; var
i : NativeUint;
Begin
For i := Low(helptext) to High(helptext) do writeln(helptext[i]); writeln;
end;
function GetNumber(const s: string;var n:NativeUint):boolean; var
ErrCode: Word;
Begin
val(s,n,Errcode); result := ErrCode = 0;
end;
procedure RvsStr(var s: AnsiString); var
i, j: NativeUint; swapChar : Ansichar;
Begin
i := 1; j := Length(s); While j>i do Begin swapChar:= s[i];s[i] := s[j];s[j] := swapChar; inc(i);dec(j) end;
end;
function RvsNumL(var n: NativeUint):NativeUint; //reverse and last digit var
q, c: NativeUint;
Begin
result := n; q := 0; repeat c:= result div Base; q := q*Base+(result-c*Base); result := c; until result < Base; n := q*Base+result;
end;
procedure InitP(var p: NativeUint); Begin
powLen := 2; pow := Base; InitPrime; repeat p :=NextPrime until p >= 11;
end;
function isEmirp(p: NativeUint):boolean; var
rvsp: NativeUint;
Begin
s := IntToStr(p); result := StepToNextPrimeEnd[Ord(s[1])-48] = 0; IF result then Begin RvsStr(s); rvsp := StrToInt(s); result := false; IF rvsp<>p then result := isPrime(rvsp); end;
end;
function NextEmirp:NativeUint; var
r,Ldgt: NativeUint;
Begin
result:= NextPrime; repeat r := result; //reverse Ldgt := RvsNumL(r); Ldgt := StepToNextPrimeEnd[Ldgt]; IF Ldgt = 0 then Begin IF r<>result then IF isPrime(r) then EXIT; result:= NextPrime; end else Begin while actPrime > pow*Base do Begin inc(PowLen); pow := pow*base; end; result := Ldgt*pow; result := PrimeGELimit(result); end; until false;
end;
function GetIthEmirp(i: NativeUint):NativeUint; var
p : NativeUint;
Begin
InitP(p); Repeat dec(i); p:= NextEmirp; until i = 0; result := p;
end;
procedure nFirstEmirp(n: NativeUint); var
p : NativeUint;
Begin
InitP(p); Writeln('the first ',n,' Emirp primE: '); Repeat dec(n); p:= NextEmirp; write(p,' '); until n = 0; Writeln;
end;
function CntToLimit(n: NativeUint):NativeUint; var
p,cnt : NativeUint;
Begin
cnt := 0; InitP(p); p:= NextEmirp; While p <= n do Begin inc(cnt); p:= NextEmirp; end; result := cnt;
end;
procedure InRange(l,u:NativeUint); var
p : NativeUint; b : boolean;
Begin
InitP(p); IF l > u then Begin p:=l;l:=u;u:=p end; Writeln('Emirp primes between ',l,' and ',u,' : '); p := PrimeGELimit(l);
b := IsEmirp(p); if b then write(p,' '); p:= NextEmirp; IF (p> u) AND NOT b then Writeln('none') else Begin while p < u do Begin write(p,' '); p:= NextEmirp; end; Writeln; end;
end;
var
i,u: NativeUint; select : char;
Begin
IF paramcount >= 1 then select := Lowercase(paramstr(1)[1]); case paramcount of 1: Begin if select='t' then Begin nFirstEmirp(20); InRange(7700,8000); Writeln('the ',10000,'.th Emirp prime: ',GetIthEmirp(10000)); writeln(CntToLimit(9999),' Emirp primes up to ',9999); // as a gag InRange(400000000,700000000); end else IF GetNumber(paramstr(1),i) then Writeln('the ',i,'.th Emirp prime: ',GetIthEmirp(i)) else OutPutHelp; end; 2: Begin case select of 'c': If GetNumber(paramstr(2),i) then writeln(CntToLimit(i),' Eemirp primes up to ',i) else OutPutHelp; 'f': If GetNumber(paramstr(2),i) then nFirstEmirp(i) else OutPutHelp; else OutPutHelp; end; end; 3: IF (select ='b') AND GetNumber(paramstr(2),i) AND GetNumber(paramstr(3),u) Then InRange(i,u) else OutPutHelp; else OutPutHelp; end;
End.</lang>
- output
./Emirp t the first 20 Emirp primE: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Emirp primes between 7700 and 8000 : 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 the 10000.th Emirp prime: 948349 240 Emirp primes up to 9999 Emirp primes between 400000000 and 700000000 : none real 0m0.033s ... a little "stress test" Emirp primes between 300000000 and 400000000 : 1058667 rumtime for this: 2m 3 secs
Using static sieve
is much faster. Only Counting Emirps. http://rosettacode.org/wiki/Extensible_prime_generator#Pascal It would be nice, if someone could check the results.Like F# today did
- output
Count Emirps Emirp Total Decimals Count Count 2 8 8 3 28 36 4 204 240 5 1406 1646 6 9538 11184 7 70474 81658 8 535578 617236 9 4192024 4809260 10 33619380 38428640 11 274890232 313318872
Perl
<lang perl>use feature 'say'; use ntheory qw(forprimes is_prime);
- Return the first $count emirps using expanding segments.
- Can efficiently generate millions of emirps.
sub emirp_list {
my $count = shift; my($i, $inc, @n) = (13, 100+10*$count); while (@n < $count) { forprimes { push @n, $_ if is_prime(reverse $_) && $_ ne reverse($_); } $i, $i+$inc-1; ($i, $inc) = ($i+$inc, int($inc * 1.03) + 1000); } splice @n, $count; # Trim off excess emirps @n;
}
say "First 20: ", join " ", emirp_list(20); print "Between 7700 and 8000:"; forprimes { print " $_" if is_prime(reverse $_) && $_ ne reverse($_) } 7700,8000; print "\n"; say "The 10_000'th emirp: ", (emirp_list(10000))[-1];</lang>
- Output:
First 20: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 The 10_000'th emirp: 948349
Perl 6
For better performance, build the lazy list using module Math::Primesieve
, not the built-in, then display results based on parameters passed in. The default is to display an array slice starting and stopping at the given indices. Alternately, ask for all values between two endpoints.
<lang perl6>use Math::Primesieve;
sub prime-hash (Int $max) {
my $sieve = Math::Primesieve.new; my @primes = $sieve.primes($max); @primes.Set;
}
sub MAIN ($start, $stop = Nil, $display = <slice>) {
my $end = $stop // $start; my %primes = prime-hash(100*$end); my @emirps = lazy gather for 1 .. * -> $n { take $n if %primes{$n} and %primes{$n.flip} and $n != $n.flip }
given $display { when 'slice' { return @emirps[$start-1 .. $end-1] }; when 'values' { my @values = gather for @emirps { .take if $start < $_ < $end; last if $_> $end } return @values } }
}</lang>
- Output:
Run with passed parameters: 1 20
('slice' is the default. you could pass it in, but it isn't necessary.)
13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389
Run with passed parameters: 7700 8000 values
7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963
Run with passed parameter: 10000
948349
Phix
Using Extensible_prime_generator#Phix, not that this task makes trial division onerous.
Does not assume anywhere that some pre-guessed value will be enough.
<lang Phix>sequence primes = {2,3,5,7}
atom sieved = 10
procedure add_block() integer N = min((sieved-1)*sieved,400000) sequence sieve = repeat(1,N) -- sieve[i] is really i+sieved
for i=2 to length(primes) do -- (evens filtered on output) atom p = primes[i], p2 = p*p if p2>sieved+N then exit end if if p2<sieved+1 then p2 += ceil((sieved+1-p2)/p)*p end if p2 -= sieved if and_bits(p2,1)=0 then p2 += p end if for k=p2 to N by p*2 do sieve[k] = 0 end for end for for i=1 to N by 2 do if sieve[i] then primes &= i+sieved end if end for sieved += N
end procedure
function is_prime(integer n)
while sieved<n do add_block() end while return binary_search(n,primes)>0
end function
sequence emirps = {}
function rev(integer n) integer res = 0
while n do res = res*10+remainder(n,10) n = floor(n/10) end while return res
end function
function emirp(integer n)
if is_prime(n) then integer r = rev(n) if r!=n and is_prime(r) then return 1 end if end if return 0
end function
procedure usage()
printf(1,"use a single command line argument, with no spaces, eg \"1-20\" (first 20), \n") printf(1,"\"7700..8000\" (between 7700 and 8000), or \"10000\" (the 10,000th).\n") {} = wait_key() abort(0)
end procedure
procedure main(string arg3) sequence args integer n,m
if find('-',arg3) then -- nth to mth emirp range args = scanf(arg3,"%d-%d") if length(args)!=1 then usage() end if Template:N,m = args integer k = 1 while length(emirps)<m do if emirp(k) then emirps &= k end if k += 1 end while printf(1,"emirps %d to %d: ",{n,m}) ?emirps[n..m] elsif match("..",arg3) then -- emirps between n amd m args = scanf(arg3,"%d..%d") if length(args)!=1 then usage() end if Template:N,m = args integer k = 1 while length(emirps)=0 or emirps[$]<m do if emirp(k) then emirps &= k end if k += 1 end while sequence s = {} for i=1 to length(emirps) do if emirps[i]>n then for j=i to length(emirps) do if emirps[j]>m then printf(1,"emirps between %d and %d: ",{n,m}) ?emirps[i..j-1] exit end if end for exit end if end for else -- nth emirp args = scanf(arg3,"%d") if length(args)!=1 then usage() end if Template:N = args integer k = 1 while length(emirps)<n do if emirp(k) then emirps &= k end if k += 1 end while printf(1,"emirp %d: ",{n}) ?emirps[n] end if
end procedure
sequence cl = command_line()
if length(cl)=2 then main("1-20") main("7700..8000") main("10000") elsif length(cl)!=3 then usage() else main(cl[3]) end if {} = wait_key()</lang>
- Output:
emirps 1 to 20: {13,17,31,37,71,73,79,97,107,113,149,157,167,179,199,311,337,347,359,389} emirps between 7700 and 8000: {7717,7757,7817,7841,7867,7879,7901,7927,7949,7951,7963} emirp 10000: 938033
PHP
<lang PHP><?php
function is_prime($n) {
if ($n <= 3) { return $n > 1; } elseif (($n % 2 == 0) or ($n % 3 == 0)) { return false; } $i = 5; while ($i * $i <= $n) { if ($n % $i == 0) { return false; } $i += 2; if ($n % $i == 0) { return false; } $i += 4; } return true;
}
function is_emirp($n) {
$r = (int) strrev((string) $n); return (($r != $n) and is_prime($r) and is_prime($n));
}
$c = $x = 0; $first20 = $between = ; do {
$x++; if (is_emirp($x)) { $c++; if ($c <= 20) { $first20 .= $x . ' '; } if (7700 <= $x and $x <= 8000) { $between .= $x . ' '; } }
} while ($c < 10000);
echo
'First twenty emirps :', PHP_EOL, $first20, PHP_EOL, 'Emirps between 7,700 and 8,000 :', PHP_EOL, $between, PHP_EOL, 'The 10,000th emirp :', PHP_EOL, $x, PHP_EOL;</lang>
- Output:
First twenty emirps : 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Emirps between 7,700 and 8,000 : 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 The 10,000th emirp : 948349
PicoLisp
<lang PicoLisp>(de prime? (N)
(and (bit? 1 N) (let S (sqrt N) (for (D 3 T (+ D 2)) (T (> D S) N) (T (=0 (% N D)) NIL) ) ) ) )
(de palindr? (A)
(and (<> (setq A (chop A)) (setq @@ (reverse A)) ) (format @@) ) )
(de emirp? (N)
(and (palindr? N) (prime? @) (prime? N)) )
(de take1 (N)
(let I 11 (make (for (X 1 (>= 20 X)) (and (emirp? (inc 'I 2)) (link @) (inc 'X) ) ) ) ) )
(de take2 (NIL)
(make (for (I 7701 (> 8000 I) (+ I 2)) (and (emirp? I) (link @)) ) ) )
(de take3 (NIL)
(let I 11 (for (X 1 (>= 10000 X)) (and (emirp? (inc 'I 2)) (inc 'X)) ) I ) )
(println (take1 20)) (println (take2)) (println (take3))</lang>
- Output:
(13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389) (7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963) 948349
PL/I
<lang pli>*process or(!);
pt1: Proc(run) Options(main); /********************************************************************* * 25.03.2014 Walter Pachl * Note: Prime number computations are extended as needed *********************************************************************/ Dcl debug Bit(1) Init('0'b); Dcl run Char(100) Var; Dcl primes(200000) Bin Fixed(31) Init(2,3,5,7,11,13,17,(200000-7)0); Dcl nn Bin Fixed(31) Init(0); Dcl np Bin Fixed(31) Init(7); Dcl hp Bin Fixed(31) Init(17); Dcl ip Bin Fixed(31); Dcl (p,r) Bin Fixed(31); Put Edit('run=',run,'<')(Skip,a,a,a); np=7; call cprimes(20,1,'A');
main_loop: Do ip=1 To 100000; /* loop over all primes */ p=primes(ip); /* candidate */ If p=0 Then call cprimes(20,hp+1,'.'); p=primes(ip); /* candidate */ r=rev(p); /* reversed candidate */ If p=r Then; /* skip palindromic prime */ Else Do; /* p is eligible */ If is_prime(r) Then Do; /* reversed p is a prime */ nn=nn+1; /* increment number of hits */ Select; When(run<='1') Do; If nn<21 Then Call show_1; /* call appropriate output */ If nn=20 Then Leave main_loop; End; When(run='2') Do; If hp<8000 Then Call cprimes(1,8000,'B'); If 7700<p & p<8000 Then Call show_2; If p>8000 Then Leave main_loop; End; When(run='3') Do; If np<10000 Then Call cprimes(10000,1,'C'); If nn=10000 Then Do; Call show_3; Leave main_loop; End; End; Otherwise Do; Put skip list('Invoke as pt1 1/2/3'); Return; End; End; End; End; End;
show_1: Proc; Dcl first Bit(1) Static Init('1'b); If first Then Do; Put Edit('the first 20 emirps:')(Skip,a); first='0'b; Put Skip; End; If nn=11 Then Put Skip; Put Edit(p)(F(4)); End;
show_2: Proc; Dcl first Bit(1) Static Init('1'b); If first Then Do; Put Edit('emirps between 7700 and 8000:')(Skip,a); first='0'b; Put Skip; End; Put Edit(p)(F(5)); End;
show_3: Proc; Dcl first Bit(1) Static Init('1'b); If first Then Do; Put Edit('the 10000th emirp:')(Skip,a); first='0'b; Put Skip; End; Put Edit(p)(F(6)); End;
cprimes: Proc(num,mp,s); /********************************************************************* * Fill the array primes with prime numbers * so that it contains at least num primes and all primes<=mp *********************************************************************/ dcl o Char(60) Var; If debug Then Put String(o) Edit('cprimes: ',s,np,hp)(a,a,2(f(6))); Dcl num Bin Fixed(31); /* number of primes needed */ Dcl mp Bin Fixed(31); /* max prime must be > mp */ Dcl p Bin Fixed(31); /* candidate for next prime */ Dcl s Char(1); /* place of invocation */ loop: Do p=hp+2 By 2 Until(np>=num & hp>mp); /* only odd numbers are elig.*/ If mod(p, 3)=0 Then Iterate; If mod(p, 5)=0 Then Iterate; If mod(p, 7)=0 Then Iterate; If mod(p,11)=0 Then Iterate; If mod(p,13)=0 Then Iterate; Do k=7 By 1 While(primes(k)**2<=p); If mod(p,primes(k))=0 Then Iterate loop; End; np=np+1; primes(np)=p; hp=p; End; If debug Then Put Edit(o,' -> ',np,hp)(Skip,a,a,2(f(6))); End;
rev: Proc(x) Returns(Bin Fixed(31)); /********************************************************************* * reverse the given number *********************************************************************/ Dcl x Bin Fixed(31); Dcl p Pic'ZZZZZZ9'; Dcl qq Char(7) Init(); Dcl q Pic'ZZZZZZ9' based(addr(qq)); Dcl v Char(8) Var; p=x; v=trim(p); v=reverse(v); substr(qq,8-length(v))=v; Return(q); End;
is_prime: Proc(x) Returns(Bit(1)); /********************************************************************* * check if x is a prime number (binary search in primes) *********************************************************************/ Dcl x Bin Fixed(31); Dcl lo Bin Fixed(31) Init(1); Dcl hi Bin Fixed(31); Dcl m Bin Fixed(31); If x>hp Then Do; /* x is outside of range in primes */ If debug Then Put Edit('is_prime x=',x,'hp=',hp)(Skip,2(a,f(8),x(1))); Call cprimes(1,x,'D'); /* extend range of primes */ End; hi=np; Do While(lo<=hi); /* lookup */ m=(lo+hi)/2; Select; When (x=primes(m)) Return('1'b); /* x is a prime number*/ When (x<primes(m)) hi=m-1; Otherwise /* x>primes(m) */ lo=m+1; End; End; Return('0'b); /* x is not a prime number */ End;
End;</lang>
- Output:
run=1 < the first 20 emirps: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 run=2 < emirps between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 run=3 < the 10000th emirp: 948349
Python
This uses Prime_decomposition#Python:_Using_Croft_Spiral_sieve and so the prime number generator self-extends to generate ever larger primes automatically.
There is no explicit hard-coded ceiling added to the code for the prime generator, which is the reason given for the need to invoke a program three times in the task description. <lang python>from __future__ import print_function from prime_decomposition import primes, is_prime from heapq import * from itertools import islice
def emirp():
largest = set() emirps = [] heapify(emirps) for pr in primes(): while emirps and pr > emirps[0]: yield heappop(emirps) if pr in largest: yield pr else: rp = int(str(pr)[::-1]) if rp > pr and is_prime(rp): heappush(emirps, pr) largest.add(rp)
print('First 20:\n ', list(islice(emirp(), 20))) print('Between 7700 and 8000:\n [', end=) for pr in emirp():
if pr >= 8000: break if pr >= 7700: print(pr, end=', ')
print(']') print('10000th:\n ', list(islice(emirp(), 10000-1, 10000)))</lang>
- Output:
First 20: [13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389] Between 7700 and 8000: [7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963, ] 10000th: [948349]
Racket
This implementation seems to have exploded somewhat due to
- the need to "account" for the greatest tested prime
- the need to reset memory between runs
- the need for a main (to support the above)
- and a (possibly misguided) thought that performance might be a consideration
(my naive version finds the 10,0000th in ... ms)
So there are two versions presented below. The first is minimalist, providing basic functions, unburdened by accounting or (too many) performance considerations (please don't mark this as needing attention... I know it falls short of <lang racket>#lang racket (require math/number-theory)
(define (stigid n)
(define (inr n a) (if (= 0 n) a (inr (quotient n 10) (+ (* 10 a) (modulo n 10))))) (inr n 0))
(define (emirp-prime? n)
(define u (stigid n)) (and (not (= u n)) (prime? n) (prime? u)))
(printf "\"show the first twenty emirps.\"~%") (for/list ((n (sequence-filter emirp-prime? (in-range 11 +Inf.0 2))) (_ (in-range 20))) n)
(printf "\"show all emirps between 7,700 and 8,000\"~%") (for/list ((n (sequence-filter emirp-prime? (in-range 7701 8000 2)))) n)
(printf "\"show the 10,000th emirp\"~%") (let loop ((i 10000) (p 9))
(define p+2 (+ p 2)) (cond [(not (emirp-prime? p+2)) (loop i p+2)] [(= i 1) p+2] [else (loop (- i 1) p+2)]))</lang>
The second is somewhat larger and seems to be a playground for all sorts of code. <lang racket>#lang racket
- ---------------------------------------------------------------------------------------------------
- There are two distinct requirements here...
- 1. to test for emirp-primality - this can be done as easily as testing for primality.
- We use math/number-theory's "prime?" for this, which has no bounds
- 2. to find the nth emirp-prime. Even when were doing this with normal primes, we wouldn't test
- each number; rather sieve them. Prime sieves by their very nature are at least memory bound...
- so I'm happy in this case that they are kept within the bounds of "fixnum" integers. Once we
- accept that, we can use the unsafe-ops on fixnums which allow for a performance boost. The
- fixnum / sieve code is after this simpler stuff.
- ---------------------------------------------------------------------------------------------------
(require math/number-theory)
- this slows things down, having to unbox, test and rebox the m.p.g -- but the task asks for some
- accounting to be performed, so account we do!
(define max-prime-tested (box 0))
(define (report-mpg)
(printf "Max prime tested (using math/number-theory): ~a~%" (unbox max-prime-tested)))
(define (prime?/remember-max n)
(define rv (prime? n)) (when (and rv (> n (unbox max-prime-tested))) (set-box! max-prime-tested n)) rv)
(define (stigid n)
(define (inner-stigid n a) (if (= 0 n) a (inner-stigid (quotient n 10) (+ (* 10 a) (modulo n 10))))) (inner-stigid n 0))
(define (emirp-prime? n)
(define u (stigid n)) (and (not (= u n)) (prime?/remember-max n) (prime?/remember-max u)))
- ---------------------------------------------------------------------------------------------------
(require
racket/require (except-in (filtered-in (lambda (n) (regexp-replace #rx"unsafe-" n "")) racket/unsafe/ops) unbox set-box!))
- NB using fixnum below limits stigid to "fixnum" (about 2^60) range of numbers
- but, unleashed, unsafe-fx... are fast
(define (fxstigid n)
(define (inner-fxstigid n a) (if (fx= 0 n) a (inner-fxstigid (fxquotient n 10) (fx+ (fx* 10 a) (fxmodulo n 10))))) (inner-fxstigid n 0))
- Grows the sieve to n (so n is included in the sieve)
- Values in the sieve are
- = 0 - known non-prime
- > 0 - known prime
- The new sieve does not alter non-zero values in the old sieve; to preserve cachceing of e.g. emirps
- Always returns a copy (so it is caller responsibility to determine the necessity of this function)
(define (extend-prime-sieve sieve n)
(define sieve-size (bytes-length sieve)) (define sieve-size+ (fx+ 1 n)) (define new-sieve (make-bytes sieve-size+ 1)) (bytes-copy! new-sieve 0 sieve 0 (fxmin sieve-size+ sieve-size)) (for* ((f (in-range 2 (add1 (integer-sqrt sieve-size+)))) #:unless (fx= (bytes-ref new-sieve f) 0) ; the only case of non-prime (f+ (in-range (fx* f (fxmax 2 (fxquotient sieve-size f))) sieve-size+ f))) (bytes-set! new-sieve f+ 0)) (values sieve-size+ new-sieve))
- task three *needs* a sieve to operate sub-second
- values in sieve are
- 0 - known non-prime
- 1 - known prime, unknown emirp-ality (freshly generated from extend-prime-sieve)
- 2 - known prime, known non-emirp -- needed for sieve extension
- 3 - known emirp (and .
- known prime)
(define-values
(emirp-prime?/sieve reset-sieve! report-mpg/sieved extend-sieve!) (let [(sieve-size 2) (the-sieve (bytes 0 0))] (define (extend-sieve! n) (when (fx>= n sieve-size) (define-values (sieve-size+ new-sieve) (extend-prime-sieve the-sieve n)) (set! the-sieve new-sieve) (set! sieve-size sieve-size+))) (values (lambda (n) (extend-sieve! n) (case (bytes-ref the-sieve n) [(0) #f] ; it's not even prime [(1) ; it's a prime... but is is emirp? (define u (fxstigid n)) (define new-sieve-n (cond [(fx= u n) 2] [(fx> u n) (if (emirp-prime?/sieve u) 3 2)] [(fx= (bytes-ref the-sieve u) 1) 3] [else 2])) (bytes-set! the-sieve n new-sieve-n) (fx= new-sieve-n 3)] [(2) #f] ; we know it's not emirp [(3) #t])) ; we already knew it's an emirp (lambda () (set! sieve-size 2) (set! the-sieve (bytes 0 0))) (lambda () (printf "Sieve size: ~a~%Max prime generated (sieve): ~a~%" sieve-size (for/last ((n the-sieve) (p (in-naturals)) #:unless (fx= 0 n)) p))) extend-sieve!)))
- ---------------------------------------------------------------------------------------------------
- testing *-primality is a lot cheaper than generating, and we'll use math/number-theory to do
- this... it's fast enough. Because they cannot be palindromic and because 2 is the only even prime
- (and is palindromic), all emirps are odd - hence our sequences starting with an odd (>= 11),
- stepping by 2.
(define (task1 (emirp?-test emirp-prime?))
(printf "\"show the first twenty emirps.\" [~s]~%" emirp?-test) (for/list ((n (sequence-filter emirp?-test (in-range 11 +Inf.0 2))) (_ (in-range 20))) n))
(define (task2 (emirp?-test emirp-prime?))
(printf "\"show all emirps between 7,700 and 8,000\" [~s]~%" emirp?-test) (for/list ((n (sequence-filter emirp?-test (in-range 7701 8000 2)))) n))
(define (task3 (emirp?-test emirp-prime?) (extend-sieve-fn #f))
(printf "\"show the 10,000th emirp\" [~s]~%" emirp?-test) (when extend-sieve-fn (extend-sieve-fn (nth-prime 10000))) ; at a guess, the 10000th emirp will be > the 10000th prime (let loop ((i 10000) (p 9)) (define p+2 (fx+ p 2)) (cond [(not (emirp?-test p+2)) (loop i p+2)] [(fx= i 1) p+2] [else (loop (fx- i 1) p+2)])))
- -| MAIN |------------------------------------------------------------------------------------------
(provide main) (define (main task)
;; to avoid the *necessity* of calling from the command line multiple times, we reset the sieve on ;; each invocation of main (reset-sieve!) (set-box! max-prime-tested 0) (match task ["1" (displayln (task1)) (report-mpg)] ["2" (displayln (task2)) (report-mpg)] ["3" (displayln (task3 emirp-prime?/sieve extend-sieve!)) (report-mpg/sieved)]))
- -| TESTS |-----------------------------------------------------------------------------------------
(module+ test
(require rackunit) (check-false (emirp-prime?/sieve 12)) (check-false (emirp-prime?/sieve 23)) (check-true (emirp-prime?/sieve 13)) (check-equal? (for/list ((n (sequence-filter emirp-prime?/sieve (in-range 11 100000 2))) (_ (in-range 3))) n) '(13 17 31)) (check-equal? (time (task1 emirp-prime?/sieve)) (time (task1))) (check-equal? (time (task2 emirp-prime?/sieve)) (time (task2))) (check-equal? (time (task3 emirp-prime?/sieve extend-sieve!)) (time (task3))))
</lang>
- Output:
"show the first twenty emirps." '(13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389) "show all emirps between 7,700 and 8,000" '(7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963) "show the 10,000th emirp" 948349
Second program, run from Linux bash shell:
$ for i in 1 2 3; do racket -t Emirp-primes.rkt -m $i; echo; done "show the first twenty emirps." [#<procedure:emirp-prime?>] (13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389) Max prime tested (using math/number-theory): 991 "show all emirps between 7,700 and 8,000" [#<procedure:emirp-prime?>] (7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963) Max prime tested (using math/number-theory): 9787 "show the 10,000th emirp" [#<procedure:...Emirp-primes.rkt:77:5>] 948349 Sieve size: 999998
REXX
version 1
Specifications of arguments note: The following REXX program accepts:
- a single number N, indicates to display the Nth emirp prime
- two numbers N M, indicates to display the Nth ──► Mth emirp primes.
- two numbers N -M, indicates to display the emirp primes between N and │M│ (inclusive).
Programming note: the trial division method of generating (regular) primes is a bit on the slow side, so some
memoization was added (assisting with the √ j ), and some of the trial divisions were hard-coded to minimize
the CPU time a bit.
<lang rexx>/*REXX program finds emirp primes (base 10): when a prime reversed, is another prime.*/
parse arg x y . /*obtain optional arguments from the CL*/
if x== | x=="," then do; x=1; y=20; end /*Not specified? Then use the default.*/
if y== then y=x /* " " " " " " */
r=y<0; y=abs(y) /*display a range of emirp primes ? */
rly=length(y) + \r /*adjusted length of the Y value. */
!.=0; c=0; _=2 3 5 7 11 13 17; $= /*isP; emirp count; low primes; emirps.*/
do #=1 for words(_); p=word(_,#); @.#=p; !.p=1; end /*#*/
- =#-1; ip=#; s.#=@.#**2 /*adjust # (for the DO loop); last P².*/
/*▒▒▒▒▒▒▒▒▒▒▒▒▒▒ [↓] generate more primes within range. */ do j=@.#+2 by 2 /*only find odd primes from here on. */ if length(#)>rly then leave /*have we enough primes for emirps? */ if j//3 ==0 then iterate /*is J divisible by three? */ if right(j,1)==5 then iterate /*is the right-most digit a "5" ? */ if j//7 ==0 then iterate /*is J divisible by seven? */ if j//11 ==0 then iterate /*is J divisible by eleven? */ if j//13 ==0 then iterate /*is J divisible by thirteen? */ /*[↑] the above five lines saves time.*/ do k=ip while s.k<=j /*divide by the known odd primes. */ if j//@.k==0 then iterate j /*J divisible by X? Then ¬prime. ___*/ end /*k*/ /* [↑] divide by odd primes up to √ j */ #=#+1 /*bump the number of primes found. */ @.#=j; s.#=j*j; !.j=1 /*assign to sparse array; prime²; prime*/ end /*j*/ /* [↑] keep generating until enough. */ /*▒▒▒▒▒▒▒▒▒▒▒▒▒▒ [↓] filter emirps for the display. */ do j=6 to @.#; _=@.j /*traipse through the regular primes. */ if (r&_>y) | (\r&c==y) then leave /*is the prime not within the range? */ __=reverse(_) /*reverse (digits) of the regular prime*/ if \!.__ | _==__ then iterate /*is the reverse a different prime ? */ c=c+1 /*bump the emirp prime counter. */ if (r&_<x) | (\r&c<x) then iterate /*is emirp not within allowed range? */ $=$ _ /*append prime to the emirpPrime list. */ end /*j*/ /* [↑] list: by value or by range. */ /* [↓] display the emirp list. */
say strip($); say; n=words($); ?=(n\==1) /*display the emirp primes wanted. */ if ? then say n 'emirp primes shown.' /*stick a fork in it, we're all done. */</lang> output when using the following for input: 1 20
13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 20 emirp primes shown.
output when using the following for input: 7700 -8000
7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 11 emirp primes shown.
output when using the following for input: 10000
948349
version 2
<lang rexx> /*********************************************************************
* 27.03.2014 Walter Pachl *********************************************************************/ Parse Arg run first.=1 nn=0 ol= lb='00'x If run= Then run=1 call cprimes 20,20,'A' main_loop: Do ip=1 To 1000000 /* loop over all primes */ p=primes.ip /* candidate */ If p=0 Then call cprimes 20,hp+1,'B' p=primes.ip /* candidate */ r=reverse(p) /* reversed candidate */ If p<>r Then Do /* not a palindromic prime */ If is_prime(r) Then Do /* reversed p is a prime */ nn=nn+1 /* increment number of hits */ Select When run<='1' Then Do If nn<21 Then Call show 1,'the first 20 emirps:',4 If nn=20 Then Leave End When(run='2') Then Do If hp<8000 Then Call cprimes 1,8000,'C' If 7700<p & p<8000 Then Call show 2,'emirps between 7700 and 8000:',5 If p>8000 Then Leave End When(run='3') Then Do If nn=10000 Then Do Call show 3,'the 10.000th emirp:',6 Leave End End When(run='4') Then Do Call cprimes 1,999999 /* dirty trick to speed thins up */ If nn=10000 Then Do Call show 4,'the 10.000th emirp (alternate version):',6 Leave End End Otherwise Do Say 'Invoke as ptx 1/2/3' Exit End End End End End Call oo Say 'largest prime:' hp Exit
show: Parse Arg task,header,nl If first.task Then Do Call o header||lb first.task=0 End Call o right(p,nl) If nn=10 Then Call o lb Return
cprimes: Procedure Expose primes. psquare. is_prime. nprimes hp /*********************************************************************
- adapted for my needs from REXX's Extensible prime generation
- Fill the array primes with prime numbers
- so that it contains at least num primes and all primes<=mp
- /
Parse Arg num,mp If symbol('primes.0')=='LIT' Then Do /* 1st time here? Initialize */ primes.=0 /* prime numbers */ is_prime.=0 /* is_prime.x -> x is prime */ psquare.=0 /* psquare.x = square of */ plist='2 3 5 7 11 13 17 19 23' /* knows low primes. */ Do i=1 For words(plist) p=word(plist,i) primes.i=p is_prime.p=1 End nprimes=i-1 primes.0=nprimes+1 psquare.nprimes=primes.nprimes**2 /* square of this prime */ End /* [?] done with building low Ps */ Do j=primes.nprimes+2 By 2 While nprimes<num | primes.nprimes<mp If j//3==0 Then Iterate If right(j,1)==5 Then Iterate If j//7==0 Then Iterate If j//11==0 Then Iterate If j//13==0 Then Iterate If j//17==0 Then Iterate If j//19==0 Then Iterate If j//23==0 Then Iterate Do k=primes.0-1 While psquare.k<=j /* check for other known primes */ If j//primes.k==0 Then /* J is divisible by k-th prime */ Iterate j /* j is not prime */ End nprimes=nprimes+1 /* bump number of primes found. */ primes.nprimes=j psquare.nprimes=j*j is_prime.j=1 hp=j End Return
is_prime: Procedure Expose primes. psquare. is_prime. nprimes hp /********************************************************************* * check if x is a prime number *********************************************************************/ Parse Arg x If x>hp Then Call cprimes 1,x Return is_prime.x
o: ol=ol||arg(1)
Return
oo: Do While ol<>
Parse Var ol l (lb) ol Say l End Return</lang>
output
rexx ptz 1 the first 20 emirps: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 largest prime: 991 rexx ptz 2 emirps between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 largest prime: 10007 rexx ptz 3 the 10.000th emirp: 948349 largest prime: 1000003 rexx ptz 4 (slightly faster that rexx ptz 3) the 10.000th emirp (alternate version): 948349 largest prime: 1000003
Ring
<lang ring> nr = 1 m = 2 see "first 20 :" + nl while nr < 21
emirp = isEmirp(m) if emirp = 1 see m see " " nr++ ok m++
end see nl + nl
nr = 1 m = 7701 see "between 7700 8000 :" + nl while m > 7700 and m < 8000
emirp = isEmirp(m) if emirp = 1 see m see " " nr++ ok m++
end see nl + nl
nr = 1 m = 2 see "Nth 10000 :" + nl while nr > 0 and nr < 101
emirp = isEmirp(m) if emirp = 1 nr++ ok m++
end see m + nl
func isEmirp n
if not isPrime(n) return false ok cStr = string(n) cstr2 = "" for x = len(cStr) to 1 step -1 cStr2 += cStr[x] next rev = number(cstr2) if rev = n return false ok return isPrime(rev)
func isPrime n
if n < 2 return false ok if n < 4 return true ok if n % 2 = 0 return false ok for d = 3 to sqrt(n) step 2 if n % d = 0 return false ok next return true
</lang>
Ruby
<lang ruby>require 'prime'
emirp = Enumerator.new do |y|
Prime.each do |prime| rev = prime.to_s.reverse.to_i y << prime if rev.prime? and rev != prime end
end
puts "First 20 emirps:", emirp.first(20).join(" ") puts "Emirps between 7,700 and 8,000:" emirp.with_index(1) do |prime,i|
print "#{prime} " if (7700..8000).cover?(prime) if i==10000 puts "", "10,000th emirp:", prime break end
end</lang>
- Output:
First 20 emirps: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Emirps between 7,700 and 8,000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 10,000th emirp: 948349
Rust
<lang>#![feature(iterator_step_by)]
extern crate primal;
fn is_prime(n: u64) -> bool {
if n == 2 || n == 3 || n == 5 || n == 7 || n == 11 || n == 13 { return true; } if n % 2 == 0 || n % 3 == 0 || n % 5 == 0 || n % 7 == 0 || n % 11 == 0 || n % 13 == 0 { return false; } let root = (n as f64).sqrt() as u64 + 1; (17..root).step_by(2).all(|i| n % i != 0)
}
fn is_emirp(n: u64) -> bool {
let mut aux = n; let mut rev_prime = 0; while aux > 0 { rev_prime = rev_prime * 10 + aux % 10; aux /= 10; } if n == rev_prime { return false; } is_prime(rev_prime)
}
fn calculate() -> (Vec<usize>, Vec<usize>, usize) {
let mut count = 1; let mut vec1 = Vec::new(); let mut vec2 = Vec::new(); let mut emirp_10_000 = 0;
for i in primal::Primes::all() { if is_emirp(i as u64) { if count < 21 { vec1.push(i) } if i > 7_700 && i < 8_000 { vec2.push(i) } if count == 10_000 { emirp_10_000 = i; break; } count += 1; } }
(vec1, vec2, emirp_10_000)
}
fn main() {
let (vec1, vec2, emirp_10_000) = calculate();
println!("First 20 emirp-s : {:?}", vec1); println!("Emirps-s between 7700 and 8000 : {:?}", vec2); println!("10.000-th emirp : {}", emirp_10_000);
}</lang>
- Output:
First 20 primes : [13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389] Emirps-s between 7700 and 8000 : [7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963] 10.000-th emirp : 948349 real 0m0.040s user 0m0.036s sys 0m0.003s
Scala
Using BigInt's isProbablePrime()
The isProbablePrime() method performs a Miller-Rabin primality test to within a given certainty. <lang scala>def isEmirp( v:Long ) : Boolean = {
val b = BigInt(v.toLong) val r = BigInt(v.toString.reverse.toLong) b != r && b.isProbablePrime(16) && r.isProbablePrime(16)
}
// Generate the output {
val (a,b1,b2,c) = (20,7700,8000,10000) println( "%32s".format( "First %d emirps: ".format( a )) + Stream.from(2).filter( isEmirp(_) ).take(a).toList.mkString(",") ) println( "%32s".format( "Emirps between %d and %d: ".format( b1, b2 )) + {for( i <- b1 to b2 if( isEmirp(i) ) ) yield i}.mkString(",") ) println( "%32s".format( "%,d emirp: ".format( c )) + Iterator.from(2).filter( isEmirp(_) ).drop(c-1).next )
}</lang>
- Output:
First 20 emirps: 13,17,31,37,71,73,79,97,107,113,149,157,167,179,199,311,337,347,359,389 Emirps between 7700 and 8000: 7717,7757,7817,7841,7867,7879,7901,7927,7949,7951,7963 10,000 emirp: 948349
Sidef
<lang ruby>func forprimes(a, b, callback) {
for (var p = a.dec.next_prime; p <= b; p.next_prime!) { callback(p) }
}
func is_emirp(p) {
var str = Str(p) var rev = str.reverse (str != rev) && is_prime(Num(rev))
}
func emirp_list(count) {
var i = 13 var inc = (100 + 10*count) var n = [] while (n.len < count) { forprimes(i, i+inc - 1, {|p| is_emirp(p) && (n << p) }) (i, inc) = (i+inc, int(inc * 1.03) + 1000) } n.splice(count) return n
}
say ("First 20: ", emirp_list(20).join(' ')) say ("Between 7700 and 8000: ", gather {
forprimes(7700, 8000, {|p| is_emirp(p) && take(p) }) }.join(' '))
say ("The 10,000'th emirp: ", emirp_list(10000)[-1])</lang>
- Output:
First 20: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 The 10,000'th emirp: 948349
Smalltalk
Works with Smalltalk/X
This uses a builtin class called LazyCons, which is useful to implement infinite lists. The code is functional, looking somewhat Scheme'isch (that's what blocks are for).
First an emirp checker: <lang smalltalk>isEmirp :=
[:p | |e| (e := p asString reversed asNumber) isPrime and:[ e ~= p ] ].</lang>
an infinite list of primes: <lang smalltalk>primeGen :=
[:n | LazyCons car:n cdr:[primeGen value:(n nextPrime)] ].</lang>
an infinite list of emirps, taking an infinite list of primes as arg: <lang smalltalk>emirpGen :=
[:l | |rest el| rest := l. [ el := rest car. rest := rest cdr. isEmirp value:el ] whileFalse. LazyCons car:el cdr:[emirpGen value:rest] ].</lang>
two infinite lists: <lang smalltalk>listOfPrimes := primeGen value:2. listOfEmirps := emirpGen value:listOfPrimes.</lang> generating output: <lang smalltalk>Transcript
show:'first 20 emirps: '; showCR:(listOfEmirps take:20) asArray.
Transcript
show:'emirps between 7700 and 8000 are: '; showCR:((7700 to:8000) select:[:n | n isPrime and:[isEmirp value:n]]).
Transcript
show:'10000th emirp: '; showCR:(listOfEmirps nth:10000).</lang>
Generates:
first 20 emirps: #(13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389) emirps between 7700 and 8000 are: OrderedCollection(7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963) 10000'th emirp: 948349
LazyCons is easily defined as: <lang smalltalk>Object subclass: #Cons
instancevariableNames:'car cdr'.
car:newCar cdr:newCdr
car := newCar. cdr := newCdr
car
^car
cdr
^cdr
Cons subclass:#LazyCons
cdr
cdr := cdr value. self changeClassTo:Cons. ^cdr</lang>
Stata
<lang stata>emirp 1000 list in 1/20, noobs noh
+-----+ | 13 | | 17 | | 31 | | 37 | | 71 | |-----| | 73 | | 79 | | 97 | | 107 | | 113 | |-----| | 149 | | 157 | | 167 | | 179 | | 199 | |-----| | 311 | | 337 | | 347 | | 359 | | 389 | +-----+
emirp 10000 list if 7700<p & p<8000, noobs noh
+------+ | 7717 | | 7757 | | 7817 | | 7841 | | 7867 | |------| | 7879 | | 7901 | | 7927 | | 7949 | | 7951 | |------| | 7963 | +------+
emirp 1000000 list if _n==10000, noobs noh
+--------+ | 948349 | +--------+</lang>
Now the definition of emirp.ado:
<lang stata>program emirp args n qui clear qui mata: build(`n') qui save temp, replace qui replace p=real(strreverse(strofreal(p))) qui merge 1:1 p using temp, keep(3) nogen qui drop if real(strreverse(strofreal(p)))==p end
mata real colvector sieve(real scalar n) { real colvector a real scalar i,j if (n<2) return(J(0,1,.)) a=J(n,1,1) a[1]=0 for (i=1; i<=n; i++) { if (a[i]) { j=i*i if (j>n) return(select(1::n,a)) for (; j<=n; j=j+i) a[j]=0 } } }
function build(n) { a=sieve(n) st_addobs(rows(a)) st_addvar("long","p") st_store(.,1,a) } end</lang>
Tcl
<lang tcl>package require math::numtheory
- Import only to keep line lengths down
namespace import math::numtheory::isprime proc emirp? {n} {
set r [string reverse $n] expr {$n != $r && [isprime $n] && [isprime $r]}
}
- Generate the various emirps
for {set n 2;set emirps {}} {[llength $emirps] < 20} {incr n} {
if {[emirp? $n]} {lappend emirps $n}
} puts "first20: $emirps"
for {set n 7700;set emirps {}} {$n <= 8000} {incr n} {
if {[emirp? $n]} {lappend emirps $n}
} puts "7700-8000: $emirps"
for {set n 2;set ne 0} true {incr n} {
if {[emirp? $n] && [incr ne] == 10000} break
} puts "10,000: $n"</lang>
- Output:
first20: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 7700-8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 10,000: 948349
VBA
<lang vb>Option Explicit
Private Const MAX As Long = 5000000 Private Emirps As New Collection Private CollTemp As New Collection
Sub Main() Dim t t = Timer
FillCollectionOfEmirps Debug.Print "At this point : Execution time = " & Timer - t & " seconds." Debug.Print "We have a Collection of the " & Emirps.Count & " first Emirps." Debug.Print "---------------------------" 'show the first twenty emirps Debug.Print "the first 20 emirps: "; ExtractEmirps(1, 20) 'show all emirps between 7,700 and 8,000 Debug.Print "all emirps between 7,700 and 8,000: "; ExtractEmirps(7700, 8000, True) 'show the 10,000th emirp Debug.Print "the 10,000th emirp: "; ExtractEmirps(10000, 10000) End Sub
Private Function ExtractEmirps(First As Long, Last As Long, Optional Value = False) As String Dim temp$, i As Long, e
If First = Last Then ExtractEmirps = Emirps(First) Else If Not Value Then For i = First To Last temp = temp & ", " & Emirps(i) Next Else For Each e In Emirps If e > First And e < Last Then temp = temp & ", " & e End If If e = Last Then Exit For Next e End If ExtractEmirps = Mid(temp, 3) End If
End Function
Private Sub FillCollectionOfEmirps() Dim Primes() As Long, e, i As Long
Primes = Atkin For i = LBound(Primes) To UBound(Primes) CollTemp.Add Primes(i), CStr(Primes(i)) Next i For Each e In CollTemp If IsEmirp(e) Then Emirps.Add e Next
End Sub
Private Function Atkin() As Long() Dim MyBool() As Boolean Dim SQRT_MAX As Long, i&, j&, N&, cpt&, MAX_TEMP As Long, temp() As Long
ReDim MyBool(MAX) SQRT_MAX = Sqr(MAX) + 1 MAX_TEMP = Sqr(MAX / 4) + 1 For i = 1 To MAX_TEMP For j = 1 To SQRT_MAX N = 4 * i * i + j * j If N <= MAX And (N Mod 12 = 1 Or N Mod 12 = 5) Then MyBool(N) = True End If Next j Next i MAX_TEMP = Sqr(MAX / 3) + 1 For i = 1 To MAX_TEMP For j = 1 To SQRT_MAX N = 3 * i * i + j * j If N <= MAX And N Mod 12 = 7 Then MyBool(N) = True End If Next j Next i For i = 1 To SQRT_MAX For j = 1 To SQRT_MAX N = 3 * i * i - j * j If i > j And N <= MAX And N Mod 12 = 11 Then MyBool(N) = True End If Next j Next i For i = 5 To SQRT_MAX Step 2 If MyBool(i) Then For j = i * i To MAX Step i MyBool(j) = False Next End If Next ReDim temp(MAX / 2) temp(0) = 2: temp(1) = 3: cpt = 2 For i = 5 To MAX Step 2 If MyBool(i) Then temp(cpt) = i: cpt = cpt + 1 Next ReDim Preserve temp(cpt - 1) Atkin = temp
End Function
Private Function IsEmirp(N) As Boolean Dim a As String, b As String
a = StrReverse(CStr(N)): b = CStr(N) If a <> b Then On Error Resume Next CollTemp.Add a, a If Err.Number > 0 Then IsEmirp = True Else CollTemp.Remove a End If On Error GoTo 0 End If
End Function</lang>
- Output:
At this point : Execution time = 13,23047 seconds. We have a Collection of the 29952 first Emirps. --------------------------- the first 20 emirps: 13, 17, 31, 37, 71, 73, 79, 97, 107, 113, 149, 157, 167, 179, 199, 311, 337, 347, 359, 389 all emirps between 7,700 and 8,000: 7717, 7757, 7817, 7841, 7867, 7879, 7901, 7927, 7949, 7951, 7963 the 10,000th emirp: 948349
Visual Basic .NET
<lang vbnet>Imports System.Runtime.CompilerServices
Module Module1
<Extension()> Function ToHashSet(Of T)(source As IEnumerable(Of T)) As HashSet(Of T) Return New HashSet(Of T)(source) End Function
<Extension()> Function Reverse(number As Integer) As Integer If number < 0 Then Return -Reverse(-number) End If If number < 10 Then Return number End If
Dim rev = 0 While number > 0 rev = rev * 10 + number Mod 10 number = number \ 10 End While
Return rev End Function
<Extension()> Function Delimit(Of T)(source As IEnumerable(Of T), Optional seperator As String = " ") As String Return String.Join(If(seperator, " "), source) End Function
Iterator Function Primes(bound As Integer) As IEnumerable(Of Integer) If bound < 2 Then Return End If Yield 2
Dim composite As New BitArray((bound - 1) / 2) Dim limit As Integer = Int((Int(Math.Sqrt(bound)) - 1) / 2) For i = 0 To limit - 1 If composite(i) Then Continue For End If Dim prime = 2 * i + 3 Yield prime
For j As Integer = Int((prime * prime - 2) / 2) To composite.Count - 1 Step prime composite(j) = True Next Next For i = limit To composite.Count - 1 If Not composite(i) Then Yield 2 * i + 3 End If Next End Function
Iterator Function FindEmirpPrimes(limit As Integer) As IEnumerable(Of Integer) Dim ps = Primes(limit).ToHashSet()
For Each p In ps Dim rev = p.Reverse() If rev <> p AndAlso ps.Contains(rev) Then Yield p End If Next End Function
Sub Main() Dim limit = 1_000_000 Console.WriteLine("First 20:") Console.WriteLine(FindEmirpPrimes(limit).Take(20).Delimit()) Console.WriteLine()
Console.WriteLine("Between 7700 and 8000:") Console.WriteLine(FindEmirpPrimes(limit).SkipWhile(Function(p) p < 7700).TakeWhile(Function(p) p < 8000).Delimit()) Console.WriteLine()
Console.WriteLine("10000th:") Console.WriteLine(FindEmirpPrimes(limit).ElementAt(9999)) End Sub
End Module</lang>
- Output:
First 20: 13 17 31 37 71 73 79 97 107 113 149 157 167 179 199 311 337 347 359 389 Between 7700 and 8000: 7717 7757 7817 7841 7867 7879 7901 7927 7949 7951 7963 10000th: 948349
zkl
Uses the solution from task Extensible prime generator#zkl. Saves the primes to a list, which gets pretty big. <lang zkl>var PS=Import("Src/ZenKinetic/sieve").postponed_sieve; var ps=Utils.Generator(PS), plist=ps.walk(10).copy();
fcn isEmirp(p){ rp:=p.toString().reverse().toInt();
if(p==rp) return(False); if(plist.holds(rp)) return(True); tp:=p; mp:=p.max(rp); while(tp<mp) { plist.append(tp=ps.next()) } return(tp==rp);
}
Utils.Generator(PS).filter(20,isEmirp);
Utils.Generator(PS).filter(fcn(p){if(p>8000)return(Void.Stop); p>7700 and isEmirp(p)});
Utils.Generator(PS).reduce(fcn(N,p){N+=isEmirp(p); (N==10000) and T(Void.Stop,p) or N },0);</lang>
- Output:
L(13,17,31,37,71,73,79,97,107,113,149,157,167,179,199,311,337,347,359,389) L(7817,7841,7867,7879,7901,7927,7949,7951,7963) 948349
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