Blum integer: Difference between revisions
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24.985% end with 9 |
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</pre> |
</pre> |
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=={{header|BASIC}}== |
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==={{header|BASIC256}}=== |
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{{trans|FreeBASIC}} |
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<syntaxhighlight lang="vb">global Prime1 |
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n = 3 |
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c = 0 |
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print "The first 50 Blum integers:" |
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while True |
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if isSemiprime(n) then |
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if Prime1 % 4 = 3 then |
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Prime2 = n / Prime1 |
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if (Prime2 <> Prime1) and (Prime2 % 4 = 3) then |
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c += 1 |
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if c <= 50 then |
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print rjust(string(n), 4); |
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if c % 10 = 0 then print |
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end if |
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if c >= 26828 then |
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print : print "The 26828th Blum integer is: "; n |
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exit while |
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end if |
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end if |
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end if |
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end if |
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n += 2 |
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end while |
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end |
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function isSemiprime(n) |
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d = 3 |
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c = 0 |
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while d*d <= n |
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while n % d = 0 |
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if c = 2 then return false |
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n /= d |
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c += 1 |
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end while |
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d += 2 |
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end while |
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Prime1 = n |
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return c = 1 |
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end function</syntaxhighlight> |
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==={{header|FreeBASIC}}=== |
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<syntaxhighlight lang="vb">Dim Shared As Uinteger Prime1 |
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Dim As Uinteger n = 3, c = 0, Prime2 |
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Function isSemiprime(n As Uinteger) As Boolean |
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Dim As Uinteger d = 3, c = 0 |
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While d*d <= n |
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While n Mod d = 0 |
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If c = 2 Then Return False |
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n /= d |
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c += 1 |
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Wend |
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d += 2 |
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Wend |
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Prime1 = n |
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Return c = 1 |
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End Function |
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Print "The first 50 Blum integers:" |
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Do |
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If isSemiprime(n) Then |
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If Prime1 Mod 4 = 3 Then |
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Prime2 = n / Prime1 |
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If (Prime2 <> Prime1) And (Prime2 Mod 4 = 3) Then |
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c += 1 |
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If c <= 50 Then |
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Print Using "####"; n; |
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If c Mod 10 = 0 Then Print |
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End If |
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If c >= 26828 Then |
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Print !"\nThe 26828th Blum integer is: " ; n |
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Exit Do |
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End If |
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End If |
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End If |
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End If |
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n += 2 |
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Loop |
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Sleep</syntaxhighlight> |
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{{out}} |
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<pre>The first 50 Blum integers: |
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21 33 57 69 77 93 129 133 141 161 |
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177 201 209 213 217 237 249 253 301 309 |
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321 329 341 381 393 413 417 437 453 469 |
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473 489 497 501 517 537 553 573 581 589 |
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597 633 649 669 681 713 717 721 737 749 |
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The 26828th Blum integer is: 524273</pre> |
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==={{header|Gambas}}=== |
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{{trans|FreeBASIC}} |
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<syntaxhighlight lang="vbnet">Public Prime1 As Integer |
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Public Sub Main() |
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Dim n As Integer = 3, c As Integer = 0, Prime2 As Integer |
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Print "The first 50 Blum integers:" |
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Do |
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If isSemiprime(n) Then |
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If Prime1 Mod 4 = 3 Then |
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Prime2 = n / Prime1 |
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If (Prime2 <> Prime1) And (Prime2 Mod 4 = 3) Then |
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c += 1 |
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If c <= 50 Then |
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Print Format$(n, "####"); |
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If c Mod 10 = 0 Then Print |
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End If |
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If c >= 26828 Then |
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Print "\nThe 26828th Blum integer is: "; n |
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Break |
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End If |
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End If |
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End If |
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End If |
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n += 2 |
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Loop |
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End |
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Function isSemiprime(n As Integer) As Boolean |
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Dim d As Integer = 3, c As Integer = 0 |
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While d * d <= n |
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While n Mod d = 0 |
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If c = 2 Then Return False |
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n /= d |
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c += 1 |
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Wend |
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d += 2 |
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Wend |
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Prime1 = n |
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Return c = 1 |
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End Function </syntaxhighlight> |
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=={{header|C}}== |
=={{header|C}}== |
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Line 218: | Line 359: | ||
Same as Wren example. |
Same as Wren example. |
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</pre> |
</pre> |
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=={{header|C#}}== |
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{{trans|Java}} |
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<syntaxhighlight lang="C#"> |
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using System; |
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using System.Collections.Generic; |
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public class BlumInteger |
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{ |
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public static void Main(string[] args) |
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{ |
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int[] blums = new int[50]; |
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int blumCount = 0; |
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Dictionary<int, int> lastDigitCounts = new Dictionary<int, int>(); |
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int number = 1; |
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while (blumCount < 400000) |
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{ |
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int prime = LeastPrimeFactor(number); |
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if (prime % 4 == 3) |
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{ |
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int quotient = number / prime; |
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if (quotient != prime && IsPrimeType3(quotient)) |
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{ |
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if (blumCount < 50) |
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{ |
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blums[blumCount] = number; |
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} |
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if (!lastDigitCounts.ContainsKey(number % 10)) |
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{ |
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lastDigitCounts[number % 10] = 0; |
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} |
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lastDigitCounts[number % 10]++; |
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blumCount++; |
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if (blumCount == 50) |
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{ |
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Console.WriteLine("The first 50 Blum integers:"); |
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for (int i = 0; i < 50; i++) |
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{ |
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Console.Write($"{blums[i],3}"); |
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Console.Write((i % 10 == 9) ? Environment.NewLine : " "); |
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} |
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Console.WriteLine(); |
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} |
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else if (blumCount == 26828 || blumCount % 100000 == 0) |
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{ |
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Console.WriteLine($"The {blumCount}th Blum integer is: {number}"); |
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if (blumCount == 400000) |
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{ |
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Console.WriteLine(); |
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Console.WriteLine("Percent distribution of the first 400000 Blum integers:"); |
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foreach (var key in lastDigitCounts.Keys) |
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{ |
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Console.WriteLine($" {((double)lastDigitCounts[key] / 4000):0.000}% end in {key}"); |
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} |
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} |
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} |
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} |
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} |
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number += (number % 5 == 3) ? 4 : 2; |
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} |
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} |
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private static bool IsPrimeType3(int number) |
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{ |
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if (number < 2) return false; |
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if (number % 2 == 0) return number == 2; |
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if (number % 3 == 0) return number == 3; |
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for (int divisor = 5; divisor * divisor <= number; divisor += 2) |
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{ |
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if (number % divisor == 0) return false; |
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} |
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return number % 4 == 3; |
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} |
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private static int LeastPrimeFactor(int number) |
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{ |
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if (number == 1) return 1; |
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if (number % 2 == 0) return 2; |
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if (number % 3 == 0) return 3; |
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if (number % 5 == 0) return 5; |
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for (int divisor = 7; divisor * divisor <= number; divisor += 2) |
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{ |
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if (number % divisor == 0) return divisor; |
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} |
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return number; |
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} |
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} |
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</syntaxhighlight> |
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{{out}} |
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<pre> |
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The first 50 Blum integers: |
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21 33 57 69 77 93 129 133 141 161 |
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177 201 209 213 217 237 249 253 301 309 |
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321 329 341 381 393 413 417 437 453 469 |
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473 489 497 501 517 537 553 573 581 589 |
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597 633 649 669 681 713 717 721 737 749 |
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The 26828th Blum integer is: 524273 |
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The 100000th Blum integer is: 2075217 |
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The 200000th Blum integer is: 4275533 |
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The 300000th Blum integer is: 6521629 |
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The 400000th Blum integer is: 8802377 |
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Percent distribution of the first 400000 Blum integers: |
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25.001% end in 1 |
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25.017% end in 3 |
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24.997% end in 7 |
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24.985% end in 9 |
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</pre> |
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=={{header|C++}}== |
=={{header|C++}}== |
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Line 313: | Line 571: | ||
</pre> |
</pre> |
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=={{header| |
=={{header|Common Lisp}}== |
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<syntaxhighlight lang="vb">Dim Shared As Uinteger Prime1 |
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Dim As Uinteger n = 3, c = 0, Prime2 |
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Simple implementation without any performance tuning; execute (main) from REPL. |
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Function isSemiprime(n As Uinteger) As Boolean |
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Dim As Uinteger d = 3, c = 0 |
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While d*d <= n |
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While n Mod d = 0 |
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If c = 2 Then Return False |
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n /= d |
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c += 1 |
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Wend |
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d += 2 |
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Wend |
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Prime1 = n |
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Return c = 1 |
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End Function |
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<syntaxhighlight lang="lisp"> |
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Print "The first 50 Blum integers:" |
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(defun is-factor (x y) |
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Do |
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(zerop (mod x y))) |
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If isSemiprime(n) Then |
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If Prime1 Mod 4 = 3 Then |
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(defun is-congruent (num a n) |
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Prime2 = n / Prime1 |
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(= (mod num n) a)) |
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If (Prime2 <> Prime1) And (Prime2 Mod 4 = 3) Then |
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c += 1 |
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If c <= 50 Then |
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Print Using "####"; n; |
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If c Mod 10 = 0 Then Print |
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End If |
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If c >= 26828 Then |
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Print !"\nThe 26828th Blum integer is: " ; n |
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Exit Do |
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End If |
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End If |
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End If |
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End If |
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n += 2 |
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Loop |
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(defun is-prime (n) |
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Sleep</syntaxhighlight> |
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(cond ((< n 4) (or (= n 2) (= n 3))) |
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((or (zerop (mod n 2)) (zerop (mod n 3))) nil) |
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(t (loop for i from 5 to (floor (sqrt n)) by 6 |
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never (or (is-factor n i) |
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(is-factor n (+ i 2))))))) |
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(defun first-factor (n) |
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(loop for i from 2 to (floor (sqrt n)) |
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thereis (if (is-factor n i) i nil))) |
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(defun is-blum (n) |
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(let ((factor (first-factor n))) |
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(and factor |
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(is-congruent factor 3 4) |
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(/= factor (/ n factor)) |
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(is-congruent (/ n factor) 3 4) |
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(is-prime factor) |
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(is-prime (/ n factor))))) |
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(defun main () |
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(let ((n 0) |
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(i 1) |
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(blums '()) |
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(counts '())) |
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(dotimes (i 10) (push (cons i 0) counts)) |
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(loop while (<= n 400000) |
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do (setf i (+ i 2)) |
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(when (is-blum i) |
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(incf n) |
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(incf (cdr (assoc (mod i 10) counts))) |
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(when (<= n 50) |
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(push i blums) |
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(when (= n 50) |
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(format t "First 50 Blum integers:~%") |
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(format t "~{~5d~5d~5d~5d~5d~5d~5d~5d~5d~5d~%~}~%" (reverse blums)))) |
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(if (find n '(26828 100000 200000 300000 400000)) |
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(format t "The ~7:dth Blum integer is: ~9:d~%" n i)))) |
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(format t "~%% distribution of the first 400,000 Blum integers:~%") |
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(dolist (x '(1 3 7 9)) |
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(format t "~3$% end in ~a~%" (/ (cdr (assoc x counts)) 4000) x)))) |
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</syntaxhighlight> |
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{{out}} |
{{out}} |
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<pre> |
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<pre>The first 50 Blum integers: |
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First 50 Blum integers: |
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21 33 57 69 77 93 129 133 141 161 |
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21 33 57 69 77 93 129 133 141 161 |
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177 201 209 213 217 237 249 253 301 309 |
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177 201 209 213 217 237 249 253 301 309 |
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321 329 341 381 393 413 417 437 453 469 |
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321 329 341 381 393 413 417 437 453 469 |
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473 489 497 501 517 537 553 573 581 589 |
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473 489 497 501 517 537 553 573 581 589 |
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597 633 649 669 681 713 717 721 737 749 |
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597 633 649 669 681 713 717 721 737 749 |
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The |
The 26,828th Blum integer is: 524,273 |
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The 100,000th Blum integer is: 2,075,217 |
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The 200,000th Blum integer is: 4,275,533 |
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The 300,000th Blum integer is: 6,521,629 |
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The 400,000th Blum integer is: 8,802,377 |
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% distribution of the first 400,000 Blum integers: |
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25.001% end in 1 |
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25.017% end in 3 |
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24.997% end in 7 |
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24.985% end in 9 |
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</pre> |
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=={{header|EasyLang}}== |
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{{trans|FreeBASIC}} |
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<syntaxhighlight lang=easylang>fastfunc semiprim n . |
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d = 3 |
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while d * d <= n |
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while n mod d = 0 |
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if c = 2 |
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return 0 |
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. |
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n /= d |
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c += 1 |
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. |
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d += 2 |
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. |
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if c = 1 |
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return n |
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. |
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. |
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print "The first 50 Blum integers:" |
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n = 3 |
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numfmt 0 4 |
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repeat |
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prim1 = semiprim n |
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if prim1 <> 0 |
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if prim1 mod 4 = 3 |
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prim2 = n div prim1 |
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if prim2 <> prim1 and prim2 mod 4 = 3 |
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c += 1 |
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if c <= 50 |
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write n |
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if c mod 10 = 0 ; print "" ; . |
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. |
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. |
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. |
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. |
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until c >= 26828 |
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n += 2 |
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. |
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print "" |
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print "The 26828th Blum integer is: " & n</syntaxhighlight> |
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=={{header|Go}}== |
=={{header|Go}}== |
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Line 440: | Line 764: | ||
<pre> |
<pre> |
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Same as Wren example. |
Same as Wren example. |
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</pre> |
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=={{header|Haskell}}== |
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Works with <code>GHC 9.2.8</code> and [https://hackage.haskell.org/package/arithmoi-0.13.0.0 arithmoi-0.13.0.0]. |
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<syntaxhighlight lang="haskell"> |
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{-# LANGUAGE BangPatterns #-} |
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{-# LANGUAGE DeriveFunctor #-} |
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{-# LANGUAGE ScopedTypeVariables #-} |
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module Rosetta.BlumInteger |
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( Stream (..) |
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, Stats (..) |
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, toList |
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, blumIntegers |
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, countLastDigits |
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) where |
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import GHC.Natural (Natural) |
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import Math.NumberTheory.Primes (Prime (..), nextPrime) |
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-- | A stream is an infinite list. |
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data Stream a = a :> Stream a |
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deriving Functor |
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-- | Converts a stream to the corresponding infinite list. |
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toList :: Stream a -> [a] |
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toList (x :> xs) = x : toList xs |
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unsafeFromList :: [a] -> Stream a |
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unsafeFromList = foldr (:>) $ error "fromList: finite list" |
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primes3mod4 :: Stream (Prime Natural) |
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primes3mod4 = unsafeFromList [nextPrime 3, nextPrime 7 ..] |
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-- Assume: |
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-- * All numbers in all the streams are distinct. |
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-- * Each stream is sorted. |
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-- * In the stream of streams, the first element of each stream is less than the first element of the next stream. |
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sortStreams :: forall a. Ord a => Stream (Stream a) -> Stream a |
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sortStreams ((x :> xs) :> xss) = x :> sortStreams (insert xs xss) |
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where |
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insert :: Stream a -> Stream (Stream a) -> Stream (Stream a) |
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insert ys@(y :> _) zss@(zs@(z :> _) :> zss') |
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| y < z = ys :> zss |
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| otherwise = zs :> insert ys zss' |
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-- | The |
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blumIntegers :: Stream Natural |
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blumIntegers = sortStreams $ go $ unPrime <$> primes3mod4 |
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where |
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go :: Stream Natural -> Stream (Stream Natural) |
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go (p :> ps) = ((p *) <$> ps) :> go ps |
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data Stats a = Stats |
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{ s1 :: !a |
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, s3 :: !a |
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, s7 :: !a |
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, s9 :: !a |
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} deriving (Show, Eq, Ord, Functor) |
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lastDigit :: Natural -> Int |
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lastDigit n = fromIntegral $ n `mod` 10 |
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updateCount :: Stats Int -> Natural -> Stats Int |
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updateCount !dc n = case lastDigit n of |
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1 -> dc { s1 = s1 dc + 1 } |
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3 -> dc { s3 = s3 dc + 1 } |
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7 -> dc { s7 = s7 dc + 1 } |
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9 -> dc { s9 = s9 dc + 1 } |
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_ -> error "updateCount: impossible" |
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countLastDigits :: forall a. Fractional a => Int -> Stream Natural -> Stats a |
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countLastDigits n = fmap f . go Stats { s1 = 0, s3 = 0, s7 = 0, s9 = 0 } n |
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where |
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go :: Stats Int -> Int -> Stream Natural -> Stats Int |
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go !dc 0 _ = dc |
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go !dc m (x :> xs) = go (updateCount dc x) (m - 1) xs |
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f :: Int -> a |
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f m = fromIntegral m / fromIntegral n |
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{-# LANGUAGE NumericUnderscores #-} |
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{-# LANGUAGE TypeApplications #-} |
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module Main |
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( main |
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) where |
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import Control.Monad (forM_) |
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import Text.Printf (printf) |
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import Numeric.Natural (Natural) |
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import Rosetta.BlumInteger |
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main :: IO () |
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main = do |
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let xs = toList blumIntegers |
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printf "The first 50 Blum integers are:\n\n" |
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forM_ (take 50 xs) $ \x -> do |
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printf "%3d\n" x |
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printf "\n" |
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nth xs 26_828 |
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forM_ [100_000, 200_000 .. 400_000] $ nth xs |
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printf "\n" |
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printf "Distribution by final digit for the first 400000 Blum integers:\n\n" |
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let Stats r1 r3 r7 r9 = countLastDigits @Double 400_000 blumIntegers |
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forM_ [(1 :: Int, r1), (3, r3), (7, r7), (9, r9)] $ \(d, r) -> |
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printf "%d: %6.3f%%\n" d $ r * 100 |
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printf "\n" |
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where |
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nth :: [Natural] -> Int -> IO () |
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nth xs n = printf "The %6dth Blum integer is %8d.\n" n $ xs !! (n - 1) |
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</syntaxhighlight> |
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{{out}} |
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<pre> |
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The first 50 Blum integers are: |
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21 |
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33 |
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57 |
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69 |
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77 |
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93 |
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129 |
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133 |
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141 |
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161 |
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177 |
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201 |
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209 |
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213 |
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217 |
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237 |
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249 |
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253 |
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301 |
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309 |
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321 |
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329 |
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341 |
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381 |
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393 |
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413 |
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417 |
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437 |
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453 |
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469 |
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473 |
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489 |
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497 |
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501 |
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517 |
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537 |
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553 |
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573 |
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581 |
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589 |
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597 |
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633 |
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649 |
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669 |
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681 |
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713 |
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717 |
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721 |
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737 |
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749 |
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The 26828th Blum integer is 524273. |
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The 100000th Blum integer is 2075217. |
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The 200000th Blum integer is 4275533. |
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The 300000th Blum integer is 6521629. |
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The 400000th Blum integer is 8802377. |
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Distribution by final digit for the first 400000 Blum integers: |
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1: 25.001% |
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3: 25.017% |
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7: 24.997% |
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9: 24.985% |
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</pre> |
</pre> |
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Line 744: | Line 1,256: | ||
end |
end |
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</syntaxhighlight>{{out}} Same as Wren, Go, etc |
</syntaxhighlight>{{out}} Same as Wren, Go, etc |
||
=={{header|Mathematica}} / {{header|Wolfram Language}}== |
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<syntaxhighlight lang="mathematica"> |
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ClearAll[BlumIntegerQ, BlumIntegersInRange, PrimePi2, BlumCount, binarySearch, BlumInts, timing, upperLimitEstimate, lastDigit, lastDigitDistributionPercents]; |
|||
BlumIntegerQ[n_Integer] := With[{factors = FactorInteger[n]}, |
|||
n ~ Mod ~ 4 == 1 && |
|||
Length[factors] == 2 && |
|||
factors[[1, 1]] ~ Mod ~ 4 == 3 && |
|||
Last@Total@factors == 2 |
|||
]; |
|||
SetAttributes[BlumIntegerQ, Listable]; |
|||
BlumIntegersInRange[n_Integer] := BlumIntegersInRange[1, n]; |
|||
BlumIntegersInRange[start_Integer, end_Integer] := |
|||
Select[Range[start + (4 - start) ~ Mod ~ 4, end, 4] + 1, BlumIntegerQ]; |
|||
(* Counts semiprimes. See https://people.maths.ox.ac.uk/erban/papers/paperDCRE.pdf *) |
|||
PrimePi2[x_] := (PrimePi[Sqrt[x]] - PrimePi[Sqrt[x]]^2)/2 + Sum[PrimePi[x/Prime[p]], {p, 1, PrimePi[Sqrt[x]]}]; |
|||
SetAttributes[PrimePi2, Listable]; |
|||
(* Blum integers are semiprimes that are 1 mod 4, with two distinct factors where both factors are 3 mod 4. The following function gives an approximation of the number of Blum integers <= x. |
|||
According to my tests, this function tends to overestimate by approximately 5% in the range we're interested in. |
|||
*) |
|||
BlumCount[x_] := Ceiling[(PrimePi2[x] - PrimePi[Sqrt[x]]) / 4]; |
|||
SetAttributes[BlumCount, Listable]; |
|||
binarySearch[f_, targetValue_] := |
|||
Module[{lo = 1, mid, hi = 1, currentValue}, |
|||
While[f[hi] < targetValue, |
|||
hi *= 2;]; |
|||
While[lo <= hi, |
|||
mid = Ceiling[(lo + hi) / 2]; |
|||
currentValue = f[mid]; |
|||
If[currentValue < targetValue, |
|||
lo = mid + 1;]; |
|||
If[currentValue > targetValue, |
|||
hi = mid - 1;]; |
|||
If[currentValue == targetValue, |
|||
While[f[mid] == targetValue, |
|||
mid++; |
|||
]; |
|||
Return[mid - 1]; |
|||
]; |
|||
]; |
|||
]; |
|||
lastDigit[n_Integer] := n ~ Mod ~ 10; |
|||
SetAttributes[lastDigit, Listable]; |
|||
upperLimitEstimate = Ceiling[binarySearch[BlumCount, 400000]* 1.1]; |
|||
timing = First@AbsoluteTiming[BlumInts = BlumIntegersInRange[upperLimitEstimate];]; |
|||
lastDigitDistributionPercents = N[Counts@lastDigit@BlumInts[[;; 400000]] / 4000, 5]; |
|||
Print["Calculated the first ", Length[BlumInts], |
|||
" Blum integers in ", timing, " seconds."]; |
|||
Print[]; |
|||
Print["First 50 Blum integers:"]; |
|||
Print[TableForm[Partition[BlumInts[[;; 50]], 10], |
|||
TableAlignments -> Right]]; |
|||
Print[]; |
|||
Print[Grid[ |
|||
Table[{"The ", n , "th Blum integer is: ", |
|||
BlumInts[[n]]}, {n, {26828, 100000, 200000, 300000, 400000}}] , |
|||
Alignment -> Right]] |
|||
Print[]; |
|||
Print["% distribution of the first 400,000 Blum integers:"]; |
|||
Print[Grid[ |
|||
Table[{lastDigitDistributionPercents[n], "% end in ", |
|||
n}, {n, {1, 3, 7, 9}} ], Alignment -> Right]]; |
|||
</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
Calculated the first 416420 Blum integers in 15.1913 seconds. |
|||
First 50 Blum integers: |
|||
21 33 57 69 77 93 129 133 141 161 |
|||
177 201 209 213 217 237 249 253 301 309 |
|||
321 329 341 381 393 413 417 437 453 469 |
|||
473 489 497 501 517 537 553 573 581 589 |
|||
597 633 649 669 681 713 717 721 737 749 |
|||
The 26828 th Blum integer is: 524273 |
|||
The 100000 th Blum integer is: 2075217 |
|||
The 200000 th Blum integer is: 4275533 |
|||
The 300000 th Blum integer is: 6521629 |
|||
The 400000 th Blum integer is: 8802377 |
|||
% distribution of the first 400,000 Blum integers: |
|||
25.001% end in 1 |
|||
25.017% end in 3 |
|||
24.997% end in 7 |
|||
24.985% end in 9 |
|||
</pre> |
|||
=={{header|Maxima}}== |
=={{header|Maxima}}== |
||
Line 1,047: | Line 1,660: | ||
{{trans|Raku}} |
{{trans|Raku}} |
||
{{libheader|ntheory}} |
{{libheader|ntheory}} |
||
<syntaxhighlight lang="perl" line> |
<syntaxhighlight lang="perl" line>use v5.36; |
||
use ntheory qw(is_square is_semiprime factor vecall); |
|||
use v5.36; |
|||
use enum <false true>; |
|||
use ntheory <is_prime gcd>; |
|||
sub comma { reverse |
sub comma { reverse((reverse shift) =~ s/.{3}\K/,/gr) =~ s/^,//r } |
||
sub table ($c, @V) { my $t = $c * (my $w = 5); ( |
sub table ($c, @V) { my $t = $c * (my $w = 5); (sprintf(('%' . $w . 'd') x @V, @V)) =~ s/.{1,$t}\K/\n/gr } |
||
sub is_blum ($n) { |
sub is_blum ($n) { |
||
($n % 4) == 1 && is_semiprime($n) && !is_square($n) && vecall { ($_ % 4) == 3 } factor($n); |
|||
return false if $n < 2 or is_prime $n; |
|||
my $factor = find_factor($n); |
|||
my $div = int($n / $factor); |
|||
return true if is_prime($factor) && is_prime($div) && ($div != $factor) && ($factor%4 == 3) && ($div%4 == 3); |
|||
false; |
|||
} |
} |
||
sub find_factor ($n, $constant = 1) { |
|||
my($x, $rho, $factor) = (2, 1, 1); |
|||
while ($factor == 1) { |
|||
$rho *= 2; |
|||
my $fixed = $x; |
|||
for (0..$rho) { |
|||
$x = ( $x * $x + $constant ) % $n; |
|||
$factor = gcd(($x-$fixed), $n); |
|||
last if 1 < $factor; |
|||
} |
|||
} |
|||
$factor = find_factor($n, $constant+1) if $n == $factor; |
|||
$factor; |
|||
} |
|||
my($i, @blum, %C); |
|||
my @nth = (26828, 1e5, 2e5, 3e5, 4e5); |
my @nth = (26828, 1e5, 2e5, 3e5, 4e5); |
||
my (@blum, %C); |
|||
while (++$i) { |
|||
for (my $i = 1 ; ; ++$i) { |
|||
push @blum, $i if is_blum $i; |
push @blum, $i if is_blum $i; |
||
last if $nth[-1] == |
last if $nth[-1] == @blum; |
||
} |
} |
||
$C{ |
$C{$_ % 10}++ for @blum; |
||
say "The first fifty Blum integers:\n" . table 10, @blum[0..49]; |
say "The first fifty Blum integers:\n" . table 10, @blum[0 .. 49]; |
||
printf "The %7sth Blum integer: %9s\n", comma($_), comma $blum[$_-1] for @nth; |
printf "The %7sth Blum integer: %9s\n", comma($_), comma $blum[$_ - 1] for @nth; |
||
say ''; |
say ''; |
||
printf "$_: %6d (%.3f%%)\n", $C{$_}, 100*$C{$_}/scalar @blum for <1 3 7 9>; |
printf "$_: %6d (%.3f%%)\n", $C{$_}, 100 * $C{$_} / scalar @blum for <1 3 7 9>;</syntaxhighlight> |
||
</syntaxhighlight> |
|||
{{out}} |
{{out}} |
||
<pre> |
<pre> |
||
Line 1,117: | Line 1,707: | ||
{{trans|Pascal}} |
{{trans|Pascal}} |
||
You can run this online [http://phix.x10.mx/p2js/Blum.htm here]. |
You can run this online [http://phix.x10.mx/p2js/Blum.htm here]. |
||
<!-- |
<!--(phixonline)--> |
||
<syntaxhighlight lang="phix"> |
|||
<span style="color: #008080;">with</span> <span style="color: #008080;">javascript_semantics</span> |
|||
with javascript_semantics |
|||
<span style="color: #008080;">constant</span> <span style="color: #000000;">LIMIT</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">1e7</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">N</span> <span style="color: #0000FF;">=</span> <span style="color: #7060A8;">floor</span><span style="color: #0000FF;">((</span><span style="color: #7060A8;">floor</span><span style="color: #0000FF;">(</span><span style="color: #000000;">LIMIT</span><span style="color: #0000FF;">/</span><span style="color: #000000;">3</span><span style="color: #0000FF;">)-</span><span style="color: #000000;">1</span><span style="color: #0000FF;">)/</span><span style="color: #000000;">4</span><span style="color: #0000FF;">)+</span><span style="color: #000000;">1</span> |
|||
constant LIMIT = 1e7, N = floor((floor(LIMIT/3)-1)/4)+1 |
|||
<span style="color: #008080;">function</span> <span style="color: #000000;">Sieve4n_3_Primes</span><span style="color: #0000FF;">()</span> |
|||
function Sieve4n_3_Primes() |
|||
<span style="color: #004080;">sequence</span> <span style="color: #000000;">sieve</span> <span style="color: #0000FF;">=</span> <span style="color: #7060A8;">repeat</span><span style="color: #0000FF;">(</span><span style="color: #000000;">0</span><span style="color: #0000FF;">,</span><span style="color: #000000;">N</span><span style="color: #0000FF;">),</span> <span style="color: #000000;">p4n3</span> <span style="color: #0000FF;">=</span> <span style="color: #0000FF;">{}</span> |
|||
sequence sieve = repeat(0,N), p4n3 = {} |
|||
<span style="color: #008080;">for</span> <span style="color: #000000;">idx</span><span style="color: #0000FF;">=</span><span style="color: #000000;">1</span> <span style="color: #008080;">to</span> <span style="color: #000000;">N</span> <span style="color: #008080;">do</span> |
|||
for idx=1 to N do |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">sieve</span><span style="color: #0000FF;">[</span><span style="color: #000000;">idx</span><span style="color: #0000FF;">]=</span><span style="color: #000000;">0</span> <span style="color: #008080;">then</span> |
|||
if sieve[idx]=0 then |
|||
<span style="color: #004080;">integer</span> <span style="color: #000000;">n</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">idx</span><span style="color: #0000FF;">*</span><span style="color: #000000;">4</span><span style="color: #0000FF;">-</span><span style="color: #000000;">1</span> |
|||
integer n = idx*4-1 |
|||
<span style="color: #000000;">p4n3</span> <span style="color: #0000FF;">&=</span> <span style="color: #000000;">n</span> |
|||
p4n3 &= n |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">idx</span><span style="color: #0000FF;">+</span><span style="color: #000000;">n</span><span style="color: #0000FF;">></span><span style="color: #000000;">N</span> <span style="color: #008080;">then</span> |
|||
if idx+n>N then |
|||
<span style="color: #000080;font-style:italic;">// collect the rest</span> |
|||
// collect the rest |
|||
<span style="color: #008080;">for</span> <span style="color: #000000;">j</span><span style="color: #0000FF;">=</span><span style="color: #000000;">idx</span><span style="color: #0000FF;">+</span><span style="color: #000000;">1</span> <span style="color: #008080;">to</span> <span style="color: #000000;">N</span> <span style="color: #008080;">do</span> |
|||
for j=idx+1 to N do |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">sieve</span><span style="color: #0000FF;">[</span><span style="color: #000000;">j</span><span style="color: #0000FF;">]=</span><span style="color: #000000;">0</span> <span style="color: #008080;">then</span> |
|||
if sieve[j]=0 then |
|||
<span style="color: #000000;">p4n3</span> <span style="color: #0000FF;">&=</span> <span style="color: #000000;">4</span><span style="color: #0000FF;">*</span><span style="color: #000000;">j</span><span style="color: #0000FF;">-</span><span style="color: #000000;">1</span> |
|||
p4n3 &= 4*j-1 |
|||
end if |
|||
end for |
|||
exit |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
end if |
|||
<span style="color: #008080;">for</span> <span style="color: #000000;">j</span><span style="color: #0000FF;">=</span><span style="color: #000000;">idx</span><span style="color: #0000FF;">+</span><span style="color: #000000;">n</span> <span style="color: #008080;">to</span> <span style="color: #000000;">N</span> <span style="color: #008080;">by</span> <span style="color: #000000;">n</span> <span style="color: #008080;">do</span> |
|||
for j=idx+n to N by n do |
|||
<span style="color: #000000;">sieve</span><span style="color: #0000FF;">[</span><span style="color: #000000;">j</span><span style="color: #0000FF;">]</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">1</span> |
|||
sieve[j] = 1 |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">for</span> |
|||
end for |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
end if |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">for</span> |
|||
end for |
|||
<span style="color: #008080;">return</span> <span style="color: #000000;">p4n3</span> |
|||
return p4n3 |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">function</span> |
|||
end function |
|||
<span style="color: #004080;">sequence</span> <span style="color: #000000;">p4n3</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">Sieve4n_3_Primes</span><span style="color: #0000FF;">(),</span> |
|||
sequence p4n3 = Sieve4n_3_Primes(), |
|||
<span style="color: #000000;">BlumField</span> <span style="color: #0000FF;">=</span> <span style="color: #7060A8;">repeat</span><span style="color: #0000FF;">(</span><span style="color: #004600;">false</span><span style="color: #0000FF;">,</span><span style="color: #000000;">LIMIT</span><span style="color: #0000FF;">),</span> |
|||
BlumField = repeat(false,LIMIT), |
|||
<span style="color: #000000;">Blum50</span> <span style="color: #0000FF;">=</span> <span style="color: #0000FF;">{},</span> <span style="color: #000000;">counts</span> <span style="color: #0000FF;">=</span> <span style="color: #7060A8;">repeat</span><span style="color: #0000FF;">(</span><span style="color: #000000;">0</span><span style="color: #0000FF;">,</span><span style="color: #000000;">10</span><span style="color: #0000FF;">)</span> |
|||
Blum50 = {}, counts = repeat(0,10) |
|||
<span style="color: #008080;">for</span> <span style="color: #000000;">idx</span><span style="color: #0000FF;">,</span><span style="color: #000000;">n</span> <span style="color: #008080;">in</span> <span style="color: #000000;">p4n3</span> <span style="color: #008080;">do</span> |
|||
for idx,n in p4n3 do |
|||
<span style="color: #008080;">for</span> <span style="color: #000000;">bj</span> <span style="color: #008080;">in</span> <span style="color: #000000;">p4n3</span> <span style="color: #008080;">from</span> <span style="color: #000000;">idx</span><span style="color: #0000FF;">+</span><span style="color: #000000;">1</span> <span style="color: #008080;">do</span> |
|||
for bj in p4n3 from idx+1 do |
|||
<span style="color: #004080;">atom</span> <span style="color: #000000;">k</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">n</span><span style="color: #0000FF;">*</span><span style="color: #000000;">bj</span> |
|||
atom k = n*bj |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">k</span><span style="color: #0000FF;">></span><span style="color: #000000;">LIMIT</span> <span style="color: #008080;">then</span> <span style="color: #008080;">exit</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
if k>LIMIT then exit end if |
|||
<span style="color: #000000;">BlumField</span><span style="color: #0000FF;">[</span><span style="color: #000000;">k</span><span style="color: #0000FF;">]</span> <span style="color: #0000FF;">=</span> <span style="color: #004600;">true</span> |
|||
BlumField[k] = true |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">for</span> |
|||
end for |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">for</span> |
|||
end for |
|||
<span style="color: #004080;">integer</span> <span style="color: #000000;">count</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">0</span> |
|||
integer count = 0 |
|||
<span style="color: #008080;">for</span> <span style="color: #000000;">n</span><span style="color: #0000FF;">,</span><span style="color: #000000;">k</span> <span style="color: #008080;">in</span> <span style="color: #000000;">BlumField</span> <span style="color: #008080;">do</span> |
|||
for n,k in BlumField do |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">k</span> <span style="color: #008080;">then</span> |
|||
if k then |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">count</span><span style="color: #0000FF;"><</span><span style="color: #000000;">50</span> <span style="color: #008080;">then</span> <span style="color: #000000;">Blum50</span> <span style="color: #0000FF;">&=</span> <span style="color: #000000;">n</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
if count<50 then Blum50 &= n end if |
|||
<span style="color: #000000;">counts</span><span style="color: #0000FF;">[</span><span style="color: #7060A8;">remainder</span><span style="color: #0000FF;">(</span><span style="color: #000000;">n</span><span style="color: #0000FF;">,</span><span style="color: #000000;">10</span><span style="color: #0000FF;">)]</span> <span style="color: #0000FF;">+=</span> <span style="color: #000000;">1</span> |
|||
counts[remainder(n,10)] += 1 |
|||
<span style="color: #000000;">count</span> <span style="color: #0000FF;">+=</span> <span style="color: #000000;">1</span> |
|||
count += 1 |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">count</span><span style="color: #0000FF;">=</span><span style="color: #000000;">50</span> <span style="color: #008080;">then</span> |
|||
if count=50 then |
|||
<span style="color: #7060A8;">printf</span><span style="color: #0000FF;">(</span><span style="color: #000000;">1</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"First 50 Blum integers:\n%s\n"</span><span style="color: #0000FF;">,{</span><span style="color: #7060A8;">join_by</span><span style="color: #0000FF;">(</span><span style="color: #000000;">Blum50</span><span style="color: #0000FF;">,</span><span style="color: #000000;">1</span><span style="color: #0000FF;">,</span><span style="color: #000000;">10</span><span style="color: #0000FF;">,</span><span style="color: #008000;">" "</span><span style="color: #0000FF;">,</span><span style="color: #000000;">fmt</span><span style="color: #0000FF;">:=</span><span style="color: #008000;">"%3d"</span><span style="color: #0000FF;">)})</span> |
|||
printf(1,"First 50 Blum integers:\n%s\n",{join_by(Blum50,1,10," ",fmt:="%3d")}) |
|||
<span style="color: #008080;">elsif</span> <span style="color: #000000;">count</span><span style="color: #0000FF;">=</span><span style="color: #000000;">26828</span> <span style="color: #008080;">or</span> <span style="color: #7060A8;">remainder</span><span style="color: #0000FF;">(</span><span style="color: #000000;">count</span><span style="color: #0000FF;">,</span><span style="color: #000000;">1e5</span><span style="color: #0000FF;">)=</span><span style="color: #000000;">0</span> <span style="color: #008080;">then</span> |
|||
elsif count=26828 or remainder(count,1e5)=0 then |
|||
<span style="color: #7060A8;">printf</span><span style="color: #0000FF;">(</span><span style="color: #000000;">1</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"The %,7d%s Blum integer is: %,9d\n"</span><span style="color: #0000FF;">,</span> <span style="color: #0000FF;">{</span><span style="color: #000000;">count</span><span style="color: #0000FF;">,</span><span style="color: #7060A8;">ord</span><span style="color: #0000FF;">(</span><span style="color: #000000;">count</span><span style="color: #0000FF;">),</span><span style="color: #000000;">n</span><span style="color: #0000FF;">})</span> |
|||
printf(1,"The %,7d%s Blum integer is: %,9d\n", {count,ord(count),n}) |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">count</span><span style="color: #0000FF;">=</span><span style="color: #000000;">4e5</span> <span style="color: #008080;">then</span> <span style="color: #008080;">exit</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
if count=4e5 then exit end if |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
end if |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
end if |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">for</span> |
|||
end for |
|||
<span style="color: #7060A8;">printf</span><span style="color: #0000FF;">(</span><span style="color: #000000;">1</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"\nPercentage distribution of the first 400,000 Blum integers:\n"</span><span style="color: #0000FF;">)</span> |
|||
printf(1,"\nPercentage distribution of the first 400,000 Blum integers:\n") |
|||
<span style="color: #008080;">for</span> <span style="color: #000000;">i</span><span style="color: #0000FF;">,</span><span style="color: #000000;">n</span> <span style="color: #008080;">in</span> <span style="color: #000000;">counts</span> <span style="color: #008080;">do</span> |
|||
for i,n in counts do |
|||
<span style="color: #008080;">if</span> <span style="color: #000000;">n</span> <span style="color: #008080;">then</span> |
|||
if n then |
|||
<span style="color: #7060A8;">printf</span><span style="color: #0000FF;">(</span><span style="color: #000000;">1</span><span style="color: #0000FF;">,</span><span style="color: #008000;">" %6.3f%% end in %d\n"</span><span style="color: #0000FF;">,</span> <span style="color: #0000FF;">{</span><span style="color: #000000;">n</span><span style="color: #0000FF;">/</span><span style="color: #000000;">4000</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">i</span><span style="color: #0000FF;">})</span> |
|||
printf(1," %6.3f%% end in %d\n", {n/4000, i}) |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">if</span> |
|||
end if |
|||
<span style="color: #008080;">end</span> <span style="color: #008080;">for</span> |
|||
end for |
|||
<!--</syntaxhighlight>--> |
|||
</syntaxhighlight> |
|||
{{out}} |
{{out}} |
||
<pre> |
<pre> |
||
Line 1,467: | Line 2,058: | ||
26828th Blum number: 524273 |
26828th Blum number: 524273 |
||
</pre> |
|||
=={{header|Scala}}== |
|||
{{trans|Java}} |
|||
<syntaxhighlight lang="Scala"> |
|||
import scala.collection.mutable |
|||
object BlumInteger extends App { |
|||
var blums = new Array[Int](50) |
|||
var blumCount = 0 |
|||
val lastDigitCounts = mutable.Map[Int, Int]() |
|||
var number = 1 |
|||
while (blumCount < 400_000) { |
|||
val prime = leastPrimeFactor(number) |
|||
if (prime % 4 == 3) { |
|||
val quotient = number / prime |
|||
if (quotient != prime && isPrimeType3(quotient)) { |
|||
if (blumCount < 50) { |
|||
blums(blumCount) = number |
|||
} |
|||
lastDigitCounts(number % 10) = lastDigitCounts.getOrElse(number % 10, 0) + 1 |
|||
blumCount += 1 |
|||
if (blumCount == 50) { |
|||
println("The first 50 Blum integers:") |
|||
blums.grouped(10).foreach(group => println(group.map(i => f"$i%3d").mkString(" "))) |
|||
println("") |
|||
} else if (blumCount == 26828 || blumCount % 100_000 == 0) { |
|||
println(f"The ${blumCount}th Blum integer is: $number%7d") |
|||
if (blumCount == 400_000) { |
|||
println("\nPercent distribution of the first 400000 Blum integers:") |
|||
lastDigitCounts.foreach { case (key, count) => |
|||
println(f" ${count.toDouble / 4000}%6.3f%% end in $key") |
|||
} |
|||
} |
|||
} |
|||
} |
|||
} |
|||
number += (if (number % 5 == 3) 4 else 2) |
|||
} |
|||
def isPrimeType3(aNumber: Int): Boolean = { |
|||
if (aNumber < 2) return false |
|||
if (aNumber % 2 == 0) return aNumber == 2 |
|||
if (aNumber % 3 == 0) return aNumber == 3 |
|||
var divisor = 5 |
|||
while (divisor * divisor <= aNumber) { |
|||
if (aNumber % divisor == 0) return false |
|||
divisor += 2 |
|||
} |
|||
aNumber % 4 == 3 |
|||
} |
|||
def leastPrimeFactor(aNumber: Int): Int = { |
|||
if (aNumber == 1) return 1 |
|||
if (aNumber % 2 == 0) return 2 |
|||
if (aNumber % 3 == 0) return 3 |
|||
var divisor = 5 |
|||
while (divisor * divisor <= aNumber) { |
|||
if (aNumber % divisor == 0) return divisor |
|||
divisor += 2 |
|||
} |
|||
aNumber |
|||
} |
|||
} |
|||
</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
The first 50 Blum integers: |
|||
21 33 57 69 77 93 129 133 141 161 |
|||
177 201 209 213 217 237 249 253 301 309 |
|||
321 329 341 381 393 413 417 437 453 469 |
|||
473 489 497 501 517 537 553 573 581 589 |
|||
597 633 649 669 681 713 717 721 737 749 |
|||
The 26828th Blum integer is: 524273 |
|||
The 100000th Blum integer is: 2075217 |
|||
The 200000th Blum integer is: 4275533 |
|||
The 300000th Blum integer is: 6521629 |
|||
The 400000th Blum integer is: 8802377 |
|||
Percent distribution of the first 400000 Blum integers: |
|||
25.001% end in 1 |
|||
25.017% end in 3 |
|||
24.997% end in 7 |
|||
24.985% end in 9 |
|||
</pre> |
|||
=={{header|Sidef}}== |
|||
Takes about 30 seconds: |
|||
<syntaxhighlight lang="ruby">func blum_integers(upto) { |
|||
var L = [] |
|||
var P = idiv(upto, 3).primes.grep{ .is_congruent(3, 4) } |
|||
for i in (1..P.end) { |
|||
var p = P[i] |
|||
for j in (^i) { |
|||
var t = p*P[j] |
|||
break if (t > upto) |
|||
L << t |
|||
} |
|||
} |
|||
L.sort |
|||
} |
|||
func blum_first(n) { |
|||
var upto = int(4.5*n*log(n) / log(log(n))) |
|||
loop { |
|||
var B = blum_integers(upto) |
|||
if (B.len >= n) { |
|||
return B.first(n) |
|||
} |
|||
upto *= 2 |
|||
} |
|||
} |
|||
with (50) {|n| |
|||
say "The first #{n} Blum integers:" |
|||
blum_first(n).slices(10).each { .map{ "%4s" % _ }.join.say } |
|||
} |
|||
say '' |
|||
for n in (26828, 1e5, 2e5, 3e5, 4e5) { |
|||
var B = blum_first(n) |
|||
say "#{n.commify}th Blum integer: #{B.last}" |
|||
if (n == 4e5) { |
|||
say '' |
|||
for k in (1,3,7,9) { |
|||
var T = B.grep { .is_congruent(k, 10) } |
|||
say "#{k}: #{'%6s' % T.len} (#{T.len / B.len * 100}%)" |
|||
} |
|||
} |
|||
}</syntaxhighlight> |
|||
{{out}} |
|||
<pre> |
|||
The first 50 Blum integers: |
|||
21 33 57 69 77 93 129 133 141 161 |
|||
177 201 209 213 217 237 249 253 301 309 |
|||
321 329 341 381 393 413 417 437 453 469 |
|||
473 489 497 501 517 537 553 573 581 589 |
|||
597 633 649 669 681 713 717 721 737 749 |
|||
26,828th Blum integer: 524273 |
|||
100,000th Blum integer: 2075217 |
|||
200,000th Blum integer: 4275533 |
|||
300,000th Blum integer: 6521629 |
|||
400,000th Blum integer: 8802377 |
|||
1: 100005 (25.00125%) |
|||
3: 100067 (25.01675%) |
|||
7: 99989 (24.99725%) |
|||
9: 99939 (24.98475%) |
|||
</pre> |
</pre> |
||
Line 1,472: | Line 2,223: | ||
{{libheader|Wren-math}} |
{{libheader|Wren-math}} |
||
{{libheader|Wren-fmt}} |
{{libheader|Wren-fmt}} |
||
<syntaxhighlight lang=" |
<syntaxhighlight lang="wren">import "./math" for Int |
||
import "./fmt" for Fmt |
import "./fmt" for Fmt |
||
Latest revision as of 14:52, 19 May 2024
You are encouraged to solve this task according to the task description, using any language you may know.
- Definition
A positive integer n is a Blum integer if n = p x q is a semi-prime for which p and q are distinct primes congruent to 3 mod 4. In other words, p and q must be of the form 4t + 3 where t is some non-negative integer.
- Example
21 is a Blum integer because it has two prime factors: 3 (= 4 x 0 + 3) and 7 (= 4 x 1 + 3).
- Task
Find and show on this page the first 50 Blum integers.
Also show the 26,828th.
- Stretch
Find and show the 100,000th, 200,000th, 300,000th and 400,000th Blum integers.
For the first 400,000 Blum integers, show the percentage distribution by final decimal digit (to 3 decimal places). Clearly, such integers can only end in 1, 3, 7 or 9.
- Related task
- References
- Wikipedia article Blum integer
- OEIS sequence A016105: Blum integers
ALGOL 68
If running this with ALGOL 68G, you will need to specify a larger heap size with -heap 256M
on the command line.
Builds tables of the unique prime factor counts and the last prime factor to handle the stretch goal, uses prime factorisation to find the first 50 Blum integers.
Note that Blum integers must be 1 modulo 4 and if one prime factor is 3 modulo 4, the other must also be.
BEGIN # find Blum integers, semi-primes where both factors are 3 mod 4 #
# and the factors are distinct #
INT max number = 10 000 000; # maximum possible Blum we will consider #
[ 1 : max number ]INT upfc; # table of unique prime factor counts #
[ 1 : max number ]INT lpf; # table of last prime factors #
FOR i TO UPB upfc DO upfc[ i ] := 0; lpf[ i ] := 1 OD;
FOR i FROM 2 TO UPB upfc OVER 2 DO
IF upfc[ i ] = 0 THEN
FOR j FROM i + i BY i TO UPB upfc DO
upfc[ j ] +:= 1;
lpf[ j ] := i
OD
FI
OD;
# returns TRUE if n is a Blum integer, FALSE otherwise #
PROC is blum = ( INT n )BOOL:
IF n < 21 THEN FALSE # the lowest primes modulo 4 that are 3 are #
# 3 & 7, so 21 is the lowest possible number #
ELIF NOT ODD n THEN FALSE
ELSE
INT v := n;
INT f count := 0;
INT f := 3;
WHILE f <= v AND f count < 3 DO
IF v MOD f = 0 THEN
IF f MOD 4 /= 3 THEN
f count := 9 # the prime factor mod 4 isn't 3 #
ELSE
v OVERAB f;
f count +:= 1
FI;
IF v MOD f = 0 THEN
f count := 9 # f is not a distinct factor of n #
FI
FI;
f +:= 2
OD;
f count = 2
FI # is blum # ;
# show various Blum integers #
print( ( "The first 50 Blum integers:", newline ) );
INT b count := 0;
[ 0 : 9 ]INT last count := []INT( 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 )[ AT 0 ];
FOR i FROM 21 BY 4 WHILE b count < 400 000 DO
# Blum integers must be 1 modulo 4 #
IF b count < 50 THEN
IF is blum( i ) THEN
b count +:= 1;
last count[ i MOD 10 ] +:= 1;
print( ( whole( i, -4 ) ) );
IF b count MOD 10 = 0 THEN print( ( newline ) ) FI
FI
ELIF upfc[ i ] = 2 THEN
# two prime factors - could be a Blum integer #
IF lpf[ i ] MOD 4 = 3 THEN
# the last prime factor mod 4 is three #
IF upfc[ i OVER lpf[ i ] ] = 0 THEN
# and the other prime factor is unique (e.g. not 3^3) #
b count +:= 1;
last count[ i MOD 10 ] +:= 1;
IF b count = 26 828
OR b count = 100 000
OR b count = 200 000
OR b count = 300 000
OR b count = 400 000
THEN
print( ( "The ", whole( b count, -6 )
, "th Blum integer is ", whole( i, -11 )
, newline
)
)
FI
FI
FI
FI
OD;
# show some statistics of the last digits #
print( ( "For Blum integers up to ", whole( b count, 0 ), ":", newline ) );
FOR i FROM LWB last count TO UPB last count DO
IF last count[ i ] /= 0 THEN
print( ( " ", fixed( ( last count[ i ] * 100 ) / b count, -8, 3 )
, "% end with ", whole( i, 0 )
, newline
)
)
FI
OD
END
- Output:
The first 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828th Blum integer is 524273 The 100000th Blum integer is 2075217 The 200000th Blum integer is 4275533 The 300000th Blum integer is 6521629 The 400000th Blum integer is 8802377 For Blum integers up to 400000: 25.001% end with 1 25.017% end with 3 24.997% end with 7 24.985% end with 9
BASIC
BASIC256
global Prime1
n = 3
c = 0
print "The first 50 Blum integers:"
while True
if isSemiprime(n) then
if Prime1 % 4 = 3 then
Prime2 = n / Prime1
if (Prime2 <> Prime1) and (Prime2 % 4 = 3) then
c += 1
if c <= 50 then
print rjust(string(n), 4);
if c % 10 = 0 then print
end if
if c >= 26828 then
print : print "The 26828th Blum integer is: "; n
exit while
end if
end if
end if
end if
n += 2
end while
end
function isSemiprime(n)
d = 3
c = 0
while d*d <= n
while n % d = 0
if c = 2 then return false
n /= d
c += 1
end while
d += 2
end while
Prime1 = n
return c = 1
end function
FreeBASIC
Dim Shared As Uinteger Prime1
Dim As Uinteger n = 3, c = 0, Prime2
Function isSemiprime(n As Uinteger) As Boolean
Dim As Uinteger d = 3, c = 0
While d*d <= n
While n Mod d = 0
If c = 2 Then Return False
n /= d
c += 1
Wend
d += 2
Wend
Prime1 = n
Return c = 1
End Function
Print "The first 50 Blum integers:"
Do
If isSemiprime(n) Then
If Prime1 Mod 4 = 3 Then
Prime2 = n / Prime1
If (Prime2 <> Prime1) And (Prime2 Mod 4 = 3) Then
c += 1
If c <= 50 Then
Print Using "####"; n;
If c Mod 10 = 0 Then Print
End If
If c >= 26828 Then
Print !"\nThe 26828th Blum integer is: " ; n
Exit Do
End If
End If
End If
End If
n += 2
Loop
Sleep
- Output:
The first 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828th Blum integer is: 524273
Gambas
Public Prime1 As Integer
Public Sub Main()
Dim n As Integer = 3, c As Integer = 0, Prime2 As Integer
Print "The first 50 Blum integers:"
Do
If isSemiprime(n) Then
If Prime1 Mod 4 = 3 Then
Prime2 = n / Prime1
If (Prime2 <> Prime1) And (Prime2 Mod 4 = 3) Then
c += 1
If c <= 50 Then
Print Format$(n, "####");
If c Mod 10 = 0 Then Print
End If
If c >= 26828 Then
Print "\nThe 26828th Blum integer is: "; n
Break
End If
End If
End If
End If
n += 2
Loop
End
Function isSemiprime(n As Integer) As Boolean
Dim d As Integer = 3, c As Integer = 0
While d * d <= n
While n Mod d = 0
If c = 2 Then Return False
n /= d
c += 1
Wend
d += 2
Wend
Prime1 = n
Return c = 1
End Function
C
#include <stdio.h>
#include <stdbool.h>
#include <locale.h>
int inc[8] = {4, 2, 4, 2, 4, 6, 2, 6};
bool isPrime(int n) {
if (n < 2) return false;
if (n%2 == 0) return n == 2;
if (n%3 == 0) return n == 3;
int d = 5;
while (d*d <= n) {
if (n%d == 0) return false;
d += 2;
if (n%d == 0) return false;
d += 4;
}
return true;
}
// Assumes n is odd.
int firstPrimeFactor(int n) {
if (n == 1) return 1;
if (!(n%3)) return 3;
if (!(n%5)) return 5;
for (int k = 7, i = 0; k*k <= n; ) {
if (!(n%k)) {
return k;
} else {
k += inc[i];
i = (i + 1) % 8;
}
}
return n;
}
int main() {
int i = 1, j, bc = 0, p, q;
int blum[50], counts[4] = {0}, digits[4] = {1, 3, 5, 7};
setlocale(LC_NUMERIC, "");
while (true) {
p = firstPrimeFactor(i);
if (p % 4 == 3) {
q = i / p;
if (q != p && q % 4 == 3 && isPrime(q)) {
if (bc < 50) blum[bc] = i;
++counts[i % 10 / 3];
++bc;
if (bc == 50) {
printf("First 50 Blum integers:\n");
for (j = 0; j < 50; ++j) {
printf("%3d ", blum[j]);
if (!((j+1) % 10)) printf("\n");
}
printf("\n");
} else if (bc == 26828 || !(bc % 100000)) {
printf("The %'7dth Blum integer is: %'9d\n", bc, i);
if (bc == 400000) {
printf("\n%% distribution of the first 400,000 Blum integers:\n");
for (j = 0; j < 4; ++j) {
printf(" %6.3f%% end in %d\n", counts[j]/4000.0, digits[j]);
}
break;
}
}
}
}
i += (i % 5 == 3) ? 4 : 2;
}
return 0;
}
- Output:
Same as Wren example.
C#
using System;
using System.Collections.Generic;
public class BlumInteger
{
public static void Main(string[] args)
{
int[] blums = new int[50];
int blumCount = 0;
Dictionary<int, int> lastDigitCounts = new Dictionary<int, int>();
int number = 1;
while (blumCount < 400000)
{
int prime = LeastPrimeFactor(number);
if (prime % 4 == 3)
{
int quotient = number / prime;
if (quotient != prime && IsPrimeType3(quotient))
{
if (blumCount < 50)
{
blums[blumCount] = number;
}
if (!lastDigitCounts.ContainsKey(number % 10))
{
lastDigitCounts[number % 10] = 0;
}
lastDigitCounts[number % 10]++;
blumCount++;
if (blumCount == 50)
{
Console.WriteLine("The first 50 Blum integers:");
for (int i = 0; i < 50; i++)
{
Console.Write($"{blums[i],3}");
Console.Write((i % 10 == 9) ? Environment.NewLine : " ");
}
Console.WriteLine();
}
else if (blumCount == 26828 || blumCount % 100000 == 0)
{
Console.WriteLine($"The {blumCount}th Blum integer is: {number}");
if (blumCount == 400000)
{
Console.WriteLine();
Console.WriteLine("Percent distribution of the first 400000 Blum integers:");
foreach (var key in lastDigitCounts.Keys)
{
Console.WriteLine($" {((double)lastDigitCounts[key] / 4000):0.000}% end in {key}");
}
}
}
}
}
number += (number % 5 == 3) ? 4 : 2;
}
}
private static bool IsPrimeType3(int number)
{
if (number < 2) return false;
if (number % 2 == 0) return number == 2;
if (number % 3 == 0) return number == 3;
for (int divisor = 5; divisor * divisor <= number; divisor += 2)
{
if (number % divisor == 0) return false;
}
return number % 4 == 3;
}
private static int LeastPrimeFactor(int number)
{
if (number == 1) return 1;
if (number % 2 == 0) return 2;
if (number % 3 == 0) return 3;
if (number % 5 == 0) return 5;
for (int divisor = 7; divisor * divisor <= number; divisor += 2)
{
if (number % divisor == 0) return divisor;
}
return number;
}
}
- Output:
The first 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828th Blum integer is: 524273 The 100000th Blum integer is: 2075217 The 200000th Blum integer is: 4275533 The 300000th Blum integer is: 6521629 The 400000th Blum integer is: 8802377 Percent distribution of the first 400000 Blum integers: 25.001% end in 1 25.017% end in 3 24.997% end in 7 24.985% end in 9
C++
#include <algorithm>
#include <cstdint>
#include <iomanip>
#include <iostream>
#include <vector>
bool is_prime_type_3(const int32_t number) {
if ( number < 2 ) return false;
if ( number % 2 == 0 ) return false;
if ( number % 3 == 0 ) return number == 3;
for ( int divisor = 5; divisor * divisor <= number; divisor += 2 ) {
if ( number % divisor == 0 ) { return false; }
}
return number % 4 == 3;
}
int32_t least_prime_factor(const int32_t number) {
if ( number == 1 ) { return 1; }
if ( number % 3 == 0 ) { return 3; }
if ( number % 5 == 0 ) { return 5; }
for ( int divisor = 7; divisor * divisor <= number; divisor += 2 ) {
if ( number % divisor == 0 ) { return divisor; }
}
return number;
}
int main() {
int32_t blums[50];
int32_t blum_count = 0;
int32_t last_digit_counts[10] = {};
int32_t number = 1;
while ( blum_count < 400'000 ) {
const int32_t prime = least_prime_factor(number);
if ( prime % 4 == 3 ) {
const int32_t quotient = number / prime;
if ( quotient != prime && is_prime_type_3(quotient) ) {
if ( blum_count < 50 ) {
blums[blum_count] = number;
}
last_digit_counts[number % 10] += 1;
blum_count += 1;
if ( blum_count == 50 ) {
std::cout << "The first 50 Blum integers:" << std::endl;
for ( int32_t i = 0; i < 50; ++i ) {
std::cout << std::setw(3) << blums[i] << ( ( i % 10 == 9 ) ? "\n" : " " );
}
std::cout << std::endl;
} else if ( blum_count == 26'828 || blum_count % 100'000 == 0 ) {
std::cout << "The " << std::setw(6) << blum_count << "th Blum integer is: "
<< std::setw(7) << number << std::endl;
if ( blum_count == 400'000 ) {
std::cout << "\nPercent distribution of the first 400000 Blum integers:" << std::endl;
for ( const int32_t& i : { 1, 3, 7, 9 } ) {
std::cout << " " << std::setw(6) << std::setprecision(5)
<< (double) last_digit_counts[i] / 4'000 << "% end in " << i << std::endl;
}
}
}
}
}
number += ( number % 5 == 3 ) ? 4 : 2;
}
}
- Output:
The first 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828th Blum integer is: 524273 The 100000th Blum integer is: 2075217 The 200000th Blum integer is: 4275533 The 300000th Blum integer is: 6521629 The 400000th Blum integer is: 8802377 Percent distribution of the first 400000 Blum integers: 25.001% end in 1 25.017% end in 3 24.997% end in 7 24.985% end in 9
Common Lisp
Simple implementation without any performance tuning; execute (main) from REPL.
(defun is-factor (x y)
(zerop (mod x y)))
(defun is-congruent (num a n)
(= (mod num n) a))
(defun is-prime (n)
(cond ((< n 4) (or (= n 2) (= n 3)))
((or (zerop (mod n 2)) (zerop (mod n 3))) nil)
(t (loop for i from 5 to (floor (sqrt n)) by 6
never (or (is-factor n i)
(is-factor n (+ i 2)))))))
(defun first-factor (n)
(loop for i from 2 to (floor (sqrt n))
thereis (if (is-factor n i) i nil)))
(defun is-blum (n)
(let ((factor (first-factor n)))
(and factor
(is-congruent factor 3 4)
(/= factor (/ n factor))
(is-congruent (/ n factor) 3 4)
(is-prime factor)
(is-prime (/ n factor)))))
(defun main ()
(let ((n 0)
(i 1)
(blums '())
(counts '()))
(dotimes (i 10) (push (cons i 0) counts))
(loop while (<= n 400000)
do (setf i (+ i 2))
(when (is-blum i)
(incf n)
(incf (cdr (assoc (mod i 10) counts)))
(when (<= n 50)
(push i blums)
(when (= n 50)
(format t "First 50 Blum integers:~%")
(format t "~{~5d~5d~5d~5d~5d~5d~5d~5d~5d~5d~%~}~%" (reverse blums))))
(if (find n '(26828 100000 200000 300000 400000))
(format t "The ~7:dth Blum integer is: ~9:d~%" n i))))
(format t "~%% distribution of the first 400,000 Blum integers:~%")
(dolist (x '(1 3 7 9))
(format t "~3$% end in ~a~%" (/ (cdr (assoc x counts)) 4000) x))))
- Output:
First 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26,828th Blum integer is: 524,273 The 100,000th Blum integer is: 2,075,217 The 200,000th Blum integer is: 4,275,533 The 300,000th Blum integer is: 6,521,629 The 400,000th Blum integer is: 8,802,377 % distribution of the first 400,000 Blum integers: 25.001% end in 1 25.017% end in 3 24.997% end in 7 24.985% end in 9
EasyLang
fastfunc semiprim n .
d = 3
while d * d <= n
while n mod d = 0
if c = 2
return 0
.
n /= d
c += 1
.
d += 2
.
if c = 1
return n
.
.
print "The first 50 Blum integers:"
n = 3
numfmt 0 4
repeat
prim1 = semiprim n
if prim1 <> 0
if prim1 mod 4 = 3
prim2 = n div prim1
if prim2 <> prim1 and prim2 mod 4 = 3
c += 1
if c <= 50
write n
if c mod 10 = 0 ; print "" ; .
.
.
.
.
until c >= 26828
n += 2
.
print ""
print "The 26828th Blum integer is: " & n
Go
package main
import (
"fmt"
"rcu"
)
var inc = []int{4, 2, 4, 2, 4, 6, 2, 6}
// Assumes n is odd.
func firstPrimeFactor(n int) int {
if n == 1 {
return 1
}
if n%3 == 0 {
return 3
}
if n%5 == 0 {
return 5
}
for k, i := 7, 0; k*k <= n; {
if n%k == 0 {
return k
} else {
k += inc[i]
i = (i + 1) % 8
}
}
return n
}
func main() {
blum := make([]int, 50)
bc := 0
counts := make([]int, 4)
i := 1
for {
p := firstPrimeFactor(i)
if p%4 == 3 {
q := i / p
if q != p && q%4 == 3 && rcu.IsPrime(q) {
if bc < 50 {
blum[bc] = i
}
counts[i%10/3]++
bc++
if bc == 50 {
fmt.Println("First 50 Blum integers:")
rcu.PrintTable(blum, 10, 3, false)
fmt.Println()
} else if bc == 26828 || bc%100000 == 0 {
fmt.Printf("The %7sth Blum integer is: %9s\n", rcu.Commatize(bc), rcu.Commatize(i))
if bc == 400000 {
fmt.Println("\n% distribution of the first 400,000 Blum integers:")
digits := []int{1, 3, 7, 9}
for j := 0; j < 4; j++ {
fmt.Printf(" %6.3f%% end in %d\n", float64(counts[j])/4000, digits[j])
}
return
}
}
}
}
if i%5 == 3 {
i += 4
} else {
i += 2
}
}
}
- Output:
Same as Wren example.
Haskell
Works with GHC 9.2.8
and arithmoi-0.13.0.0.
{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE DeriveFunctor #-}
{-# LANGUAGE ScopedTypeVariables #-}
module Rosetta.BlumInteger
( Stream (..)
, Stats (..)
, toList
, blumIntegers
, countLastDigits
) where
import GHC.Natural (Natural)
import Math.NumberTheory.Primes (Prime (..), nextPrime)
-- | A stream is an infinite list.
data Stream a = a :> Stream a
deriving Functor
-- | Converts a stream to the corresponding infinite list.
toList :: Stream a -> [a]
toList (x :> xs) = x : toList xs
unsafeFromList :: [a] -> Stream a
unsafeFromList = foldr (:>) $ error "fromList: finite list"
primes3mod4 :: Stream (Prime Natural)
primes3mod4 = unsafeFromList [nextPrime 3, nextPrime 7 ..]
-- Assume:
-- * All numbers in all the streams are distinct.
-- * Each stream is sorted.
-- * In the stream of streams, the first element of each stream is less than the first element of the next stream.
sortStreams :: forall a. Ord a => Stream (Stream a) -> Stream a
sortStreams ((x :> xs) :> xss) = x :> sortStreams (insert xs xss)
where
insert :: Stream a -> Stream (Stream a) -> Stream (Stream a)
insert ys@(y :> _) zss@(zs@(z :> _) :> zss')
| y < z = ys :> zss
| otherwise = zs :> insert ys zss'
-- | The
blumIntegers :: Stream Natural
blumIntegers = sortStreams $ go $ unPrime <$> primes3mod4
where
go :: Stream Natural -> Stream (Stream Natural)
go (p :> ps) = ((p *) <$> ps) :> go ps
data Stats a = Stats
{ s1 :: !a
, s3 :: !a
, s7 :: !a
, s9 :: !a
} deriving (Show, Eq, Ord, Functor)
lastDigit :: Natural -> Int
lastDigit n = fromIntegral $ n `mod` 10
updateCount :: Stats Int -> Natural -> Stats Int
updateCount !dc n = case lastDigit n of
1 -> dc { s1 = s1 dc + 1 }
3 -> dc { s3 = s3 dc + 1 }
7 -> dc { s7 = s7 dc + 1 }
9 -> dc { s9 = s9 dc + 1 }
_ -> error "updateCount: impossible"
countLastDigits :: forall a. Fractional a => Int -> Stream Natural -> Stats a
countLastDigits n = fmap f . go Stats { s1 = 0, s3 = 0, s7 = 0, s9 = 0 } n
where
go :: Stats Int -> Int -> Stream Natural -> Stats Int
go !dc 0 _ = dc
go !dc m (x :> xs) = go (updateCount dc x) (m - 1) xs
f :: Int -> a
f m = fromIntegral m / fromIntegral n
{-# LANGUAGE NumericUnderscores #-}
{-# LANGUAGE TypeApplications #-}
module Main
( main
) where
import Control.Monad (forM_)
import Text.Printf (printf)
import Numeric.Natural (Natural)
import Rosetta.BlumInteger
main :: IO ()
main = do
let xs = toList blumIntegers
printf "The first 50 Blum integers are:\n\n"
forM_ (take 50 xs) $ \x -> do
printf "%3d\n" x
printf "\n"
nth xs 26_828
forM_ [100_000, 200_000 .. 400_000] $ nth xs
printf "\n"
printf "Distribution by final digit for the first 400000 Blum integers:\n\n"
let Stats r1 r3 r7 r9 = countLastDigits @Double 400_000 blumIntegers
forM_ [(1 :: Int, r1), (3, r3), (7, r7), (9, r9)] $ \(d, r) ->
printf "%d: %6.3f%%\n" d $ r * 100
printf "\n"
where
nth :: [Natural] -> Int -> IO ()
nth xs n = printf "The %6dth Blum integer is %8d.\n" n $ xs !! (n - 1)
- Output:
The first 50 Blum integers are: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828th Blum integer is 524273. The 100000th Blum integer is 2075217. The 200000th Blum integer is 4275533. The 300000th Blum integer is 6521629. The 400000th Blum integer is 8802377. Distribution by final digit for the first 400000 Blum integers: 1: 25.001% 3: 25.017% 7: 24.997% 9: 24.985%
J
Implementation:
isblum=: {{
ab=. q: y
if. 2= #ab do.
if. </ab do.
*./3=4|ab
else. 0 end.
else. 0 end.
}}"0
blumseq=: {{
r=. (#~ isblum) }.i.b=. 1e4
while. y>#r do.
r=. r, (#~ isblum) b+i.1e4
b=. b+1e4
end.
y{.r
}}
Task examples:
5 10$blumseq 50
21 33 57 69 77 93 129 133 141 161
177 201 209 213 217 237 249 253 301 309
321 329 341 381 393 413 417 437 453 469
473 489 497 501 517 537 553 573 581 589
597 633 649 669 681 713 717 721 737 749
{: blumseq 26828
524273
Stretch:
B=: blumseq 4e5
{:1e5{.B
2075217
{:2e5{.B
4275533
{:3e5{.B
6521629
{:4e5{.B
8802377
{:B
8802377
(~.,. 4e3 %~ #/.~) 10|B
1 25.0012
3 25.0167
7 24.9973
9 24.9847
Java
import java.util.HashMap;
import java.util.Map;
public final class BlumInteger {
public static void main(String[] aArgs) {
int[] blums = new int[50];
int blumCount = 0;
Map<Integer, Integer> lastDigitCounts = new HashMap<Integer, Integer>();
int number = 1;
while ( blumCount < 400_000 ) {
final int prime = leastPrimeFactor(number);
if ( prime % 4 == 3 ) {
final int quotient = number / prime;
if ( quotient != prime && isPrimeType3(quotient) ) {
if ( blumCount < 50 ) {
blums[blumCount] = number;
}
lastDigitCounts.merge(number % 10, 1, Integer::sum);
blumCount += 1;
if ( blumCount == 50 ) {
System.out.println("The first 50 Blum integers:");
for ( int i = 0; i < 50; i++ ) {
System.out.print(String.format("%3d", blums[i]));
System.out.print(( i % 10 == 9 ) ? System.lineSeparator() : " ");
}
System.out.println();
} else if ( blumCount == 26_828 || blumCount % 100_000 == 0 ) {
System.out.println(String.format("%s%6d%s%7d",
"The ", blumCount, "th Blum integer is: ", number));
if ( blumCount == 400_000 ) {
System.out.println();
System.out.println("Percent distribution of the first 400000 Blum integers:");
for ( int key : lastDigitCounts.keySet() ) {
System.out.println(String.format("%s%6.3f%s%d",
" ", (double) lastDigitCounts.get(key) / 4_000, "% end in ", key));
}
}
}
}
}
number += ( number % 5 == 3 ) ? 4 : 2;
}
}
private static boolean isPrimeType3(int aNumber) {
if ( aNumber < 2 ) { return false; }
if ( aNumber % 2 == 0 ) { return false; }
if ( aNumber % 3 == 0 ) { return aNumber == 3; }
for ( int divisor = 5; divisor * divisor <= aNumber; divisor += 2 ) {
if ( aNumber % divisor == 0 ) { return false; }
}
return aNumber % 4 == 3;
}
private static int leastPrimeFactor(int aNumber) {
if ( aNumber == 1 ) { return 1; }
if ( aNumber % 3 == 0 ) { return 3; }
if ( aNumber % 5 == 0 ) { return 5; }
for ( int divisor = 7; divisor * divisor <= aNumber; divisor += 2 ) {
if ( aNumber % divisor == 0 ) { return divisor; }
}
return aNumber;
}
}
The first 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828th Blum integer is: 524273 The 100000th Blum integer is: 2075217 The 200000th Blum integer is: 4275533 The 300000th Blum integer is: 6521629 The 400000th Blum integer is: 8802377 Percent distribution of the first 400000 Blum integers: 25.001% end in 1 25.017% end in 3 24.997% end in 7 24.985% end in 9
jq
Adapted from Wren
### Generic utilities
def lpad($len): tostring | ($len - length) as $l | (" " * $l) + .;
# tabular print
def tprint(columns; wide):
reduce _nwise(columns) as $row ("";
. + ($row|map(lpad(wide)) | join(" ")) + "\n" );
### Primes
def is_prime:
. as $n
| if ($n < 2) then false
elif ($n % 2 == 0) then $n == 2
elif ($n % 3 == 0) then $n == 3
elif ($n % 5 == 0) then $n == 5
elif ($n % 7 == 0) then $n == 7
elif ($n % 11 == 0) then $n == 11
elif ($n % 13 == 0) then $n == 13
elif ($n % 17 == 0) then $n == 17
elif ($n % 19 == 0) then $n == 19
else sqrt as $s
| 23
| until( . > $s or ($n % . == 0); . + 2)
| . > $s
end;
def primes: 2, (range(3;infinite;2) | select(is_prime));
# input: the number to be tested
def isprime($smalls):
if . < 2 then false
else sqrt as $s
| (first( $smalls[] as $p
| if . == $p then 1
elif . % $p == 0 then 0
elif $p > $s then 1
else empty
end) // null) as $result
| if $result then $result == 1
else ($smalls[-1] + 2)
| until( . > $s or ($n % . == 0); . + 2)
| . > $s
end
end;
# Assumes n is odd.
def firstPrimeFactor:
if (. == 1) then 1
elif (. % 3 == 0) then 3
elif (. % 5 == 0) then 5
else . as $n
| [4, 2, 4, 2, 4, 6, 2, 6] as $inc
| { k: 7,
i: 0 }
| ($n | sqrt) as $s
| until (.k > $s or .done;
if $n % .k == 0
then .done = true
else .k += $inc[.i]
| .i = (.i + 1) % 8
end )
| if .done then .k else $n end
end ;
### Blum integers
# Number of small primes to pre-compute
def task($numberOfSmallPrimes):
[limit($numberOfSmallPrimes; primes)] as $smalls
| { blum: [],
bc:0,
counts: { "1": 0, "3": 0, "7": 0, "9": 0 },
i: 1 }
| label $out
| foreach range(0; infinite) as $_ (.;
(.i|firstPrimeFactor) as $p
| .j = null
| if ($p % 4 == 3)
then (.i / $p) as $q
| if $q != $p and ($q % 4 == 3) and ($q | isprime($smalls))
then if (.bc < 50) then .blum[.bc] = .i else . end
| .counts[(.i % 10) | tostring] += 1
| .bc += 1
| .j = .i
else .
end
else .
end
| .i |= if (. % 5 == 3) then . + 4 else . + 2 end;
select(.j)
| if (.bc == 50)
then "First 50 Blum integers:",
(.blum | tprint(10; 3) )
elif .bc == 26828 or .bc % 1e5 == 0
then "The \(.bc) Blum integer is: \(.j)",
if .bc == 400000
then "\n% distribution of the first 400,000 Blum integers:",
((.counts|keys_unsorted[]) as $k
| " \( .counts[$k] / 4000 )% end in \($k)"),
break $out
else empty
end
else empty
end);
task(10000)
- Output:
First 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828 Blum integer is: 524273 The 100000 Blum integer is: 2075217 The 200000 Blum integer is: 4275533 The 300000 Blum integer is: 6521629 The 400000 Blum integer is: 8802377 % distribution of the first 400,000 Blum integers: 25.00125% end in 1 25.01675% end in 3 24.99725% end in 7 24.98475% end in 9
Julia
using Formatting, Primes
function isblum(n)
pe = factor(n).pe
return length(pe) == 2 && all(p -> p[2] == 1 && p[1] % 4 == 3, pe)
end
const blum400k = @view (filter(isblum, 1:9_000_000))[1:400_000]
println("First 50 Blum integers:")
foreach(p -> print(rpad(p[2], 4), p[1] % 10 == 0 ? "\n" : ""), enumerate(blum400k[1:50]))
for idx in [26_828, 100_000, 200_000, 300_000, 400_000]
println("\nThe $(format(idx, commas = true))th Blum number is ",
format(blum400k[idx], commas = true), ".")
end
println("\n% distribution of the first 400,000 Blum integers is:")
for d in [1, 3, 7, 9]
println(lpad(round(count(x -> x % 10 == d, blum400k) / 4000, digits=3), 8), "% end in $d")
end
- Output:
Same as Wren, Go, etc
Mathematica / Wolfram Language
ClearAll[BlumIntegerQ, BlumIntegersInRange, PrimePi2, BlumCount, binarySearch, BlumInts, timing, upperLimitEstimate, lastDigit, lastDigitDistributionPercents];
BlumIntegerQ[n_Integer] := With[{factors = FactorInteger[n]},
n ~ Mod ~ 4 == 1 &&
Length[factors] == 2 &&
factors[[1, 1]] ~ Mod ~ 4 == 3 &&
Last@Total@factors == 2
];
SetAttributes[BlumIntegerQ, Listable];
BlumIntegersInRange[n_Integer] := BlumIntegersInRange[1, n];
BlumIntegersInRange[start_Integer, end_Integer] :=
Select[Range[start + (4 - start) ~ Mod ~ 4, end, 4] + 1, BlumIntegerQ];
(* Counts semiprimes. See https://people.maths.ox.ac.uk/erban/papers/paperDCRE.pdf *)
PrimePi2[x_] := (PrimePi[Sqrt[x]] - PrimePi[Sqrt[x]]^2)/2 + Sum[PrimePi[x/Prime[p]], {p, 1, PrimePi[Sqrt[x]]}];
SetAttributes[PrimePi2, Listable];
(* Blum integers are semiprimes that are 1 mod 4, with two distinct factors where both factors are 3 mod 4. The following function gives an approximation of the number of Blum integers <= x.
According to my tests, this function tends to overestimate by approximately 5% in the range we're interested in.
*)
BlumCount[x_] := Ceiling[(PrimePi2[x] - PrimePi[Sqrt[x]]) / 4];
SetAttributes[BlumCount, Listable];
binarySearch[f_, targetValue_] :=
Module[{lo = 1, mid, hi = 1, currentValue},
While[f[hi] < targetValue,
hi *= 2;];
While[lo <= hi,
mid = Ceiling[(lo + hi) / 2];
currentValue = f[mid];
If[currentValue < targetValue,
lo = mid + 1;];
If[currentValue > targetValue,
hi = mid - 1;];
If[currentValue == targetValue,
While[f[mid] == targetValue,
mid++;
];
Return[mid - 1];
];
];
];
lastDigit[n_Integer] := n ~ Mod ~ 10;
SetAttributes[lastDigit, Listable];
upperLimitEstimate = Ceiling[binarySearch[BlumCount, 400000]* 1.1];
timing = First@AbsoluteTiming[BlumInts = BlumIntegersInRange[upperLimitEstimate];];
lastDigitDistributionPercents = N[Counts@lastDigit@BlumInts[[;; 400000]] / 4000, 5];
Print["Calculated the first ", Length[BlumInts],
" Blum integers in ", timing, " seconds."];
Print[];
Print["First 50 Blum integers:"];
Print[TableForm[Partition[BlumInts[[;; 50]], 10],
TableAlignments -> Right]];
Print[];
Print[Grid[
Table[{"The ", n , "th Blum integer is: ",
BlumInts[[n]]}, {n, {26828, 100000, 200000, 300000, 400000}}] ,
Alignment -> Right]]
Print[];
Print["% distribution of the first 400,000 Blum integers:"];
Print[Grid[
Table[{lastDigitDistributionPercents[n], "% end in ",
n}, {n, {1, 3, 7, 9}} ], Alignment -> Right]];
- Output:
Calculated the first 416420 Blum integers in 15.1913 seconds. First 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828 th Blum integer is: 524273 The 100000 th Blum integer is: 2075217 The 200000 th Blum integer is: 4275533 The 300000 th Blum integer is: 6521629 The 400000 th Blum integer is: 8802377 % distribution of the first 400,000 Blum integers: 25.001% end in 1 25.017% end in 3 24.997% end in 7 24.985% end in 9
Maxima
/* Predicate functions that checks wether an integer is a Blum integer or not */
blum_p(n):=lambda([x],length(ifactors(x))=2 and unique(map(second,ifactors(x)))=[1] and mod(ifactors(x)[1][1],4)=3 and mod(ifactors(x)[2][1],4)=3)(n)$
/* Function that returns a list of the first len Blum integers */
blum_count(len):=block(
[i:1,count:0,result:[]],
while count<len do (if blum_p(i) then (result:endcons(i,result),count:count+1),i:i+1),
result)$
/* Test cases */
/* First 50 Blum integers */
blum_count(50);
/* Blum integer number 26828 */
last(blum_count(26828));
- Output:
[21,33,57,69,77,93,129,133,141,161,177,201,209,213,217,237,249,253,301,309,321,329,341,381,393,413,417,437,453,469,473,489,497,501,517,537,553,573,581,589,597,633,649,669,681,713,717,721,737,749] 524273
Nim
import std/[strformat, tables]
func isPrime(n: Natural): bool =
## Return "true" is "n" is prime.
if n < 2: return false
if (n and 1) == 0: return n == 2
if n mod 3 == 0: return n == 3
var d = 5
var step = 2
while d * d <= n:
if n mod d == 0:
return false
inc d, step
step = 6 - step
return true
const Inc = [4, 2, 4, 2, 4, 6, 2, 6]
func firstPrimeFactor(n: Positive): int =
## Return the first prime factor.
## Assuming "n" is odd.
if n == 1: return 1
if n mod 3 == 0: return 3
if n mod 5 == 0: return 5
var k = 7
var i = 0
while k * k <= n:
if n mod k == 0:
return k
k += Inc[i]
i = (i + 1) and 7
return n
var blum: array[50, int]
var bc = 0
var counts: CountTable[int]
var n = 1
while true:
var p = n.firstPrimeFactor
if (p and 3) == 3:
let q = n div p
if q != p and (q and 3) == 3 and q.isPrime:
if bc < 50: blum[bc] = n
counts.inc(n mod 10)
inc bc
if bc == 50:
echo "First 50 Blum integers:"
for i, val in blum:
stdout.write &"{val:3}"
stdout.write if i mod 10 == 9: '\n' else: ' '
echo()
elif bc == 26828 or bc mod 100000 == 0:
echo &"The {bc:>6}th Blum integer is: {n:>7}"
if bc == 400000:
echo "\n% distribution of the first 400_000 Blum integers:"
for i in [1, 3, 7, 9]:
echo &" {counts[i]/4000:6.3f} % end in {i}"
break
n = if n mod 5 == 3: n + 4 else: n + 2
- Output:
First 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828th Blum integer is: 524273 The 100000th Blum integer is: 2075217 The 200000th Blum integer is: 4275533 The 300000th Blum integer is: 6521629 The 400000th Blum integer is: 8802377 % distribution of the first 400_000 Blum integers: 25.001 % end in 1 25.017 % end in 3 24.997 % end in 7 24.985 % end in 9
Pascal
Free Pascal
Generating Blum integer by multiplying primes of form 4*n+3.
Tried to sieve numbers of form 4*n+3.
Could not start at square of prime, since 5,13 are not getting sieved, but 35 =5*7 == 4*8 +3.
Using a simple prime sieve and check for 4*n+3 would be easier and faster.
program BlumInteger;
{$IFDEF FPC} {$MODE DELPHI}{$Optimization ON,ALL} {$ENDIF}
{$IFDEF WINDOWS}{$APPTYPE CONSOLE}{$ENDIF}
{
// for commatize = Numb2USA(IntToStr(n))
uses
sysutils, //IntToStr
strutils; //Numb2USA
}
const
LIMIT = 10*1000*1000;// >750
type
tP4n3 = array of Uint32;
function CommaUint(n : Uint64):AnsiString;
//commatize only positive Integers
var
fromIdx,toIdx :Int32;
pRes : pChar;
Begin
str(n,result);
fromIdx := length(result);
toIdx := fromIdx-1;
if toIdx < 3 then
exit;
toIdx := 4*(toIdx DIV 3)+toIdx MOD 3 +1 ;
setlength(result,toIdx);
pRes := @result[1];
dec(pRes);
repeat
pRes[toIdx] := pRes[FromIdx];
pRes[toIdx-1] := pRes[FromIdx-1];
pRes[toIdx-2] := pRes[FromIdx-2];
pRes[toIdx-3] := ',';
dec(toIdx,4);
dec(FromIdx,3);
until FromIdx<=3;
while fromIdx>=1 do
Begin
pRes[toIdx] := pRes[FromIdx];
dec(toIdx);
dec(fromIdx);
end;
end;
procedure Sieve4n_3_Primes(Limit:Uint32;var P4n3:tP4n3);
var
sieve : array of byte;
BlPrCnt,idx,n,j: Uint32;
begin
//DIV 3 -> smallest factor of Blum Integer
n := (LIMIT DIV 3 -3) DIV 4+ 1;
setlength(sieve,n);
setlength(P4n3,n);
BlPrCnt:= 0;
idx := 0;
repeat
if sieve[idx]= 0 then
begin
n := idx*4+3;
P4n3[BlPrCnt] := n;
inc(BlPrCnt);
j := idx+n;
if j > High(sieve) then
break;
while j <= High(sieve) do
begin
sieve[j] := 1;
inc(j,n);
end;
end;
inc(idx);
until idx>High(sieve);
//collect the rest
for idx := idx+1 to High(sieve) do
if sieve[idx]=0 then
Begin
P4n3[BlPrCnt] := idx*4+3;
inc(BlPrCnt);
end;
setlength(P4n3,BlPrCnt);
setlength(sieve,0);
end;
var
BlumField : array[0..LIMIT] of boolean;
BlumPrimes : tP4n3;
EndDigit : array[0..9] of Uint32;
k : Uint64;
n,idx,j,P4n3Cnt : Uint32;
begin
Sieve4n_3_Primes(Limit,BlumPrimes);
P4n3Cnt := length(BlumPrimes);
writeln('There are ',CommaUint(P4n3Cnt),' needed primes 4*n+3 to Limit ',CommaUint(LIMIT));
dec(P4n3Cnt);
writeln;
//generate Blum-Integers
For idx := 0 to P4n3Cnt do
Begin
n := BlumPrimes[idx];
For j := idx+1 to P4n3Cnt do
Begin
k := n*BlumPrimes[j];
if k>LIMIT then
BREAK;
BlumField[k] := true;
end;
end;
writeln('First 50 Blum-Integers ');
idx :=0;
j := 0 ;
repeat
while (idx<LIMIT) AND Not(BlumField[idx]) do
inc(idx);
if idx = LIMIT then
BREAK;
if j mod 10 = 0 then
writeln;
write(idx:5);
inc(j);
inc(idx);
until j >= 50;
Writeln(#13,#10);
//count and calc and summate decimal digit
writeln(' relative occurence of digit');
writeln(' n.th |Blum-Integer|Digit: 1 3 7 9');
idx :=0;
j := 0 ;
n := 0;
k := 26828;
repeat
while (idx<LIMIT) AND Not(BlumField[idx]) do
inc(idx);
if idx = LIMIT then
BREAK;
//count last decimal digit
inc(EndDigit[idx MOD 10]);
inc(j);
if j = k then
begin
write(CommaUint(j):10,' | ',CommaUint(idx):11,'| ');
write(EndDigit[1]/j*100:7:3,'% |');
write(EndDigit[3]/j*100:7:3,'% |');
write(EndDigit[7]/j*100:7:3,'% |');
writeln(EndDigit[9]/j*100:7:3,'%');
if k < 100000 then
k := 100000
else
k += 100000;
end;
inc(idx);
until j >= 400000;
Writeln;
end.
- @TIO.RUN:
There are 119,644 needed primes 4*n+3 to Limit 10,000,000 First 50 Blum-Integers 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 relative occurence of digit n.th |Blum-Integer| 1 3 7 9 26,828 | 524,273| 24.933% | 25.071% | 25.030% | 24.966% 100,000 | 2,075,217| 24.973% | 25.026% | 25.005% | 24.996% 200,000 | 4,275,533| 24.990% | 24.986% | 25.033% | 24.992% 300,000 | 6,521,629| 24.982% | 25.014% | 25.033% | 24.970% 400,000 | 8,802,377| 25.001% | 25.017% | 24.997% | 24.985% Real time: 0.097 s User time: 0.068 s Sys. time: 0.028 s CPU share: 99.08 % C-Version //-O3 -marchive=native Real time: 1.658 s User time: 1.612 s Sys. time: 0.033 s CPU share: 99.18 %
Perl
use v5.36;
use ntheory qw(is_square is_semiprime factor vecall);
sub comma { reverse((reverse shift) =~ s/.{3}\K/,/gr) =~ s/^,//r }
sub table ($c, @V) { my $t = $c * (my $w = 5); (sprintf(('%' . $w . 'd') x @V, @V)) =~ s/.{1,$t}\K/\n/gr }
sub is_blum ($n) {
($n % 4) == 1 && is_semiprime($n) && !is_square($n) && vecall { ($_ % 4) == 3 } factor($n);
}
my @nth = (26828, 1e5, 2e5, 3e5, 4e5);
my (@blum, %C);
for (my $i = 1 ; ; ++$i) {
push @blum, $i if is_blum $i;
last if $nth[-1] == @blum;
}
$C{$_ % 10}++ for @blum;
say "The first fifty Blum integers:\n" . table 10, @blum[0 .. 49];
printf "The %7sth Blum integer: %9s\n", comma($_), comma $blum[$_ - 1] for @nth;
say '';
printf "$_: %6d (%.3f%%)\n", $C{$_}, 100 * $C{$_} / scalar @blum for <1 3 7 9>;
- Output:
The first fifty Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26,828th Blum integer: 524,273 The 100,000th Blum integer: 2,075,217 The 200,000th Blum integer: 4,275,533 The 300,000th Blum integer: 6,521,629 The 400,000th Blum integer: 8,802,377 1: 100005 (25.001%) 3: 100067 (25.017%) 7: 99989 (24.997%) 9: 99939 (24.985%)
Phix
You can run this online here.
with javascript_semantics
constant LIMIT = 1e7, N = floor((floor(LIMIT/3)-1)/4)+1
function Sieve4n_3_Primes()
sequence sieve = repeat(0,N), p4n3 = {}
for idx=1 to N do
if sieve[idx]=0 then
integer n = idx*4-1
p4n3 &= n
if idx+n>N then
// collect the rest
for j=idx+1 to N do
if sieve[j]=0 then
p4n3 &= 4*j-1
end if
end for
exit
end if
for j=idx+n to N by n do
sieve[j] = 1
end for
end if
end for
return p4n3
end function
sequence p4n3 = Sieve4n_3_Primes(),
BlumField = repeat(false,LIMIT),
Blum50 = {}, counts = repeat(0,10)
for idx,n in p4n3 do
for bj in p4n3 from idx+1 do
atom k = n*bj
if k>LIMIT then exit end if
BlumField[k] = true
end for
end for
integer count = 0
for n,k in BlumField do
if k then
if count<50 then Blum50 &= n end if
counts[remainder(n,10)] += 1
count += 1
if count=50 then
printf(1,"First 50 Blum integers:\n%s\n",{join_by(Blum50,1,10," ",fmt:="%3d")})
elsif count=26828 or remainder(count,1e5)=0 then
printf(1,"The %,7d%s Blum integer is: %,9d\n", {count,ord(count),n})
if count=4e5 then exit end if
end if
end if
end for
printf(1,"\nPercentage distribution of the first 400,000 Blum integers:\n")
for i,n in counts do
if n then
printf(1," %6.3f%% end in %d\n", {n/4000, i})
end if
end for
- Output:
First 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26,828th Blum integer is: 524,273 The 100,000th Blum integer is: 2,075,217 The 200,000th Blum integer is: 4,275,533 The 300,000th Blum integer is: 6,521,629 The 400,000th Blum integer is: 8,802,377 Percentage distribution of the first 400,000 Blum integers: 25.001% end in 1 25.017% end in 3 24.997% end in 7 24.985% end in 9
Python
''' python example for task rosettacode.org/wiki/Blum_integer '''
from sympy import factorint
def generate_blum():
''' Generate the Blum integers in series '''
for candidate in range(1, 10_000_000_000):
fexp = factorint(candidate).items()
if len(fexp) == 2 and sum(p[1] == 1 and p[0] % 4 == 3 for p in fexp) == 2:
yield candidate
print('First 50 Blum integers:')
lastdigitsums = [0, 0, 0, 0]
for idx, blum in enumerate(generate_blum()):
if idx < 50:
print(f'{blum: 4}', end='\n' if (idx + 1) % 10 == 0 else '')
elif idx + 1 in [26_828, 100_000, 200_000, 300_000, 400_000]:
print(f'\nThe {idx+1:,}th Blum number is {blum:,}.')
j = blum % 10
lastdigitsums[0] += j == 1
lastdigitsums[1] += j == 3
lastdigitsums[2] += j == 7
lastdigitsums[3] += j == 9
if idx + 1 == 400_000:
print('\n% distribution of the first 400,000 Blum integers is:')
for k, dig in enumerate([1, 3, 7, 9]):
print(f'{lastdigitsums[k]/4000:>8.5}% end in {dig}')
break
- Output:
Same as Wren example.
Quackery
sqrt
, isprime
, and eratosthenes
are defined at Sieve of Eratosthenes#Quackery.
from
, index
, incr
, and end
are defined at Loops/Increment loop index within loop body#Quackery.
In the line 600000 eratosthenes
, 600000
suggests foreknowledge of the value of the 26828th Blum integer, and while I was not the first person to complete this task, so knew that 524273
would suffice, I reasoned that if I had determined the generally linear relationship between n
and Blum(n)
from computing the first fifty Blum integers with a slower but unbounded primality test I would have felt confident that 600000
would suffice. See the graphs at https://oeis.org/A016105/graph for confirmation.
Precomputing the primes takes a hot minute, but the overhead is worth it for the overall speed gain.
blum
returns 0
(i.e. false
) if the number passed to it, and the value of the smaller divisor (non-zero is taken as true
) rather than false
and true
(i.e. 1
) as the divisor is available without extra calculation. So as well as listing the Blum integers, their factors are shown in the output.
600000 eratosthenes
[ dup sqrt
tuck dup * = ] is exactsqrt ( n --> n b )
[ dup isprime iff
[ drop false ] done
dup 4 mod 1 != iff
[ drop false ] done
dup exactsqrt iff
[ 2drop false ] done
temp put
3 from
[ 4 incr
index temp share > iff
[ drop false end ]
done
index isprime not if done
dup index /mod 0 != iff
drop done
isprime not if done
drop index end ]
temp release ] is blum ( n --> n )
[ dup blum
over echo
say " = "
dup echo
say " * "
/ echo cr ] is echoblum ( n --> )
say "The First 50 Blum integers:"
cr cr
[] 1 from
[ 4 incr
index blum if
[ index join ]
dup size 50 = if end ]
witheach echoblum
cr
say "The 26828th Blum integer:"
cr cr
0 1 from
[ 4 incr
index blum if 1+
dup 26828 = if
[ drop index end ] ]
echoblum
- Output:
The First 50 Blum integers: 21 = 3 * 7 33 = 3 * 11 57 = 3 * 19 69 = 3 * 23 77 = 7 * 11 93 = 3 * 31 129 = 3 * 43 133 = 7 * 19 141 = 3 * 47 161 = 7 * 23 177 = 3 * 59 201 = 3 * 67 209 = 11 * 19 213 = 3 * 71 217 = 7 * 31 237 = 3 * 79 249 = 3 * 83 253 = 11 * 23 301 = 7 * 43 309 = 3 * 103 321 = 3 * 107 329 = 7 * 47 341 = 11 * 31 381 = 3 * 127 393 = 3 * 131 413 = 7 * 59 417 = 3 * 139 437 = 19 * 23 453 = 3 * 151 469 = 7 * 67 473 = 11 * 43 489 = 3 * 163 497 = 7 * 71 501 = 3 * 167 517 = 11 * 47 537 = 3 * 179 553 = 7 * 79 573 = 3 * 191 581 = 7 * 83 589 = 19 * 31 597 = 3 * 199 633 = 3 * 211 649 = 11 * 59 669 = 3 * 223 681 = 3 * 227 713 = 23 * 31 717 = 3 * 239 721 = 7 * 103 737 = 11 * 67 749 = 7 * 107 The 26828th Blum integer: 524273 = 223 * 2351
Raku
use List::Divvy;
use Lingua::EN::Numbers;
sub is-blum(Int $n ) {
return False if $n.is-prime;
my $factor = find-factor($n);
return True if ($factor.is-prime && ( my $div = $n div $factor ).is-prime && ($div != $factor)
&& ($factor % 4 == 3) && ($div % 4 == 3));
False;
}
sub find-factor ( Int $n, $constant = 1 ) {
my $x = 2;
my $rho = 1;
my $factor = 1;
while $factor == 1 {
$rho *= 2;
my $fixed = $x;
for ^$rho {
$x = ( $x * $x + $constant ) % $n;
$factor = ( $x - $fixed ) gcd $n;
last if 1 < $factor;
}
}
$factor = find-factor( $n, $constant + 1 ) if $n == $factor;
$factor;
}
my @blum = lazy (2..Inf).hyper(:1000batch).grep: &is-blum;
say "The first fifty Blum integers:\n" ~
@blum[^50].batch(10)».fmt("%3d").join: "\n";
say '';
printf "The %9s Blum integer: %9s\n", .&ordinal-digit(:c), comma @blum[$_-1] for 26828, 1e5, 2e5, 3e5, 4e5;
say "\nBreakdown by last digit:";
printf "%d => %%%7.4f:\n", .key, +.value / 4e3 for sort @blum[^4e5].categorize: {.substr(*-1)}
- Output:
The first fifty Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26,828th Blum integer: 524,273 The 100,000th Blum integer: 2,075,217 The 200,000th Blum integer: 4,275,533 The 300,000th Blum integer: 6,521,629 The 400,000th Blum integer: 8,802,377 Breakdown by last digit: 1 => %25.0013: 3 => %25.0168: 7 => %24.9973: 9 => %24.9848:
RPL
Blum integers are necessarily of the form 4k + 21, which allows to speed up the quest.
≪ FACTORS @ n FACTORS returns { p1 n1 p2 n2 .. } for n = p1n1 * p2n2 * .. CASE DUP SIZE 4 ≠ THEN DROP 0 END LIST→ DROP ROT * 1 ≠ THEN DROP2 0 END 4 MOD SWAP 4 MOD * 9 == END ≫ 'BLUM?' STO ≪ { } 17 DO 4 + IF DUP BLUM? THEN SWAP OVER + SWAP END UNTIL OVER SIZE 50 == END 50 SWAP DO 4 + IF DUP BLUM? THEN SWAP 1 + SWAP END UNTIL OVER 26828 == END NIP ≫ 'TASK' STO
- Output:
2: { 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 } 1: 524273
Runs in 10 minutes 55 on the iHP48 emulator.
Ruby
require 'prime'
BLUM_EXP = [1, 1]
blums = (1..).step(2).lazy.select do |c|
next if c % 5 == 0
primes, exps = c.prime_division.transpose
exps == BLUM_EXP && primes.all?{|pr| (pr-3) % 4 == 0}
end
n, m = 50, 26828
res = blums.first(m)
puts "First #{n} Blum numbers:"
res.first(n).each_slice(10){|s| puts "%4d"*s.size % s}
puts "\n#{m}th Blum number: #{res.last}"
- Output:
First 50 Blum numbers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 26828th Blum number: 524273
Scala
import scala.collection.mutable
object BlumInteger extends App {
var blums = new Array[Int](50)
var blumCount = 0
val lastDigitCounts = mutable.Map[Int, Int]()
var number = 1
while (blumCount < 400_000) {
val prime = leastPrimeFactor(number)
if (prime % 4 == 3) {
val quotient = number / prime
if (quotient != prime && isPrimeType3(quotient)) {
if (blumCount < 50) {
blums(blumCount) = number
}
lastDigitCounts(number % 10) = lastDigitCounts.getOrElse(number % 10, 0) + 1
blumCount += 1
if (blumCount == 50) {
println("The first 50 Blum integers:")
blums.grouped(10).foreach(group => println(group.map(i => f"$i%3d").mkString(" ")))
println("")
} else if (blumCount == 26828 || blumCount % 100_000 == 0) {
println(f"The ${blumCount}th Blum integer is: $number%7d")
if (blumCount == 400_000) {
println("\nPercent distribution of the first 400000 Blum integers:")
lastDigitCounts.foreach { case (key, count) =>
println(f" ${count.toDouble / 4000}%6.3f%% end in $key")
}
}
}
}
}
number += (if (number % 5 == 3) 4 else 2)
}
def isPrimeType3(aNumber: Int): Boolean = {
if (aNumber < 2) return false
if (aNumber % 2 == 0) return aNumber == 2
if (aNumber % 3 == 0) return aNumber == 3
var divisor = 5
while (divisor * divisor <= aNumber) {
if (aNumber % divisor == 0) return false
divisor += 2
}
aNumber % 4 == 3
}
def leastPrimeFactor(aNumber: Int): Int = {
if (aNumber == 1) return 1
if (aNumber % 2 == 0) return 2
if (aNumber % 3 == 0) return 3
var divisor = 5
while (divisor * divisor <= aNumber) {
if (aNumber % divisor == 0) return divisor
divisor += 2
}
aNumber
}
}
- Output:
The first 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26828th Blum integer is: 524273 The 100000th Blum integer is: 2075217 The 200000th Blum integer is: 4275533 The 300000th Blum integer is: 6521629 The 400000th Blum integer is: 8802377 Percent distribution of the first 400000 Blum integers: 25.001% end in 1 25.017% end in 3 24.997% end in 7 24.985% end in 9
Sidef
Takes about 30 seconds:
func blum_integers(upto) {
var L = []
var P = idiv(upto, 3).primes.grep{ .is_congruent(3, 4) }
for i in (1..P.end) {
var p = P[i]
for j in (^i) {
var t = p*P[j]
break if (t > upto)
L << t
}
}
L.sort
}
func blum_first(n) {
var upto = int(4.5*n*log(n) / log(log(n)))
loop {
var B = blum_integers(upto)
if (B.len >= n) {
return B.first(n)
}
upto *= 2
}
}
with (50) {|n|
say "The first #{n} Blum integers:"
blum_first(n).slices(10).each { .map{ "%4s" % _ }.join.say }
}
say ''
for n in (26828, 1e5, 2e5, 3e5, 4e5) {
var B = blum_first(n)
say "#{n.commify}th Blum integer: #{B.last}"
if (n == 4e5) {
say ''
for k in (1,3,7,9) {
var T = B.grep { .is_congruent(k, 10) }
say "#{k}: #{'%6s' % T.len} (#{T.len / B.len * 100}%)"
}
}
}
- Output:
The first 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 26,828th Blum integer: 524273 100,000th Blum integer: 2075217 200,000th Blum integer: 4275533 300,000th Blum integer: 6521629 400,000th Blum integer: 8802377 1: 100005 (25.00125%) 3: 100067 (25.01675%) 7: 99989 (24.99725%) 9: 99939 (24.98475%)
Wren
import "./math" for Int
import "./fmt" for Fmt
var inc = [4, 2, 4, 2, 4, 6, 2, 6]
// Assumes n is odd.
var firstPrimeFactor = Fn.new { |n|
if (n == 1) return 1
if (n%3 == 0) return 3
if (n%5 == 0) return 5
var k = 7
var i = 0
while (k * k <= n) {
if (n%k == 0) {
return k
} else {
k = k + inc[i]
i = (i + 1) % 8
}
}
return n
}
var blum = List.filled(50, 0)
var bc = 0
var counts = { 1: 0, 3: 0, 7: 0, 9: 0 }
var i = 1
while (true) {
var p = firstPrimeFactor.call(i)
if (p % 4 == 3) {
var q = i / p
if (q != p && q % 4 == 3 && Int.isPrime(q)) {
if (bc < 50) blum[bc] = i
counts[i % 10] = counts[i % 10] + 1
bc = bc + 1
if (bc == 50) {
System.print("First 50 Blum integers:")
Fmt.tprint("$3d ", blum, 10)
System.print()
} else if (bc == 26828 || bc % 1e5 == 0) {
Fmt.print("The $,9r Blum integer is: $,9d", bc, i)
if (bc == 400000) {
System.print("\n\% distribution of the first 400,000 Blum integers:")
for (i in [1, 3, 7, 9]) {
Fmt.print(" $6.3f\% end in $d", counts[i]/4000, i)
}
return
}
}
}
}
i = (i % 5 == 3) ? i + 4 : i + 2
}
- Output:
First 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26,828th Blum integer is: 524,273 The 100,000th Blum integer is: 2,075,217 The 200,000th Blum integer is: 4,275,533 The 300,000th Blum integer is: 6,521,629 The 400,000th Blum integer is: 8,802,377 % distribution of the first 400,000 Blum integers: 25.001% end in 1 25.017% end in 3 24.997% end in 7 24.985% end in 9
XPL0
Simple minded brute force takes 93 seconds on Pi4.
int Prime1;
func Semiprime(N); \Return 'true' if N is semiprime
int N, F, C;
[C:= 0; F:= 2;
repeat if rem(N/F) = 0 then
[C:= C+1;
Prime1:= N;
N:= N/F;
]
else F:= F+1;
until F > N;
return C = 2;
];
int N, C, Prime2;
[Format(4,0);
N:= 3; C:= 0;
loop [if Semiprime(N) then
[if rem(Prime1/4) = 3 then
[Prime2:= N/Prime1;
if Prime2 # Prime1 and rem(Prime2/4) = 3 then
[C:= C+1;
if C <= 50 then
[RlOut(0, float(N));
if rem(C/10) = 0 then CrLf(0);
];
if rem(C/1000)=0 then ChOut(0, ^.);
if C >= 26828 then
[Text(0, "^m^jThe 26828th Blum integer is: ");
IntOut(0, N); CrLf(0);
quit;
];
];
];
];
N:= N+2;
];
]
- Output:
21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 .......................... The 26828th Blum integer is: 524273
Faster factoring. Does stretch. Takes 9.2 seconds.
include xpllib; \for Print
int Prime1;
func Semiprime(N); \Returns 'true' if odd N >= 3 is semiprime
int N, D, C;
[C:= 0; D:= 3;
while D*D <= N do
[while rem(N/D) = 0 do
[if C = 2 then return false;
C:= C+1;
N:= N/D;
];
D:= D+2;
];
Prime1:= N;
return C = 1;
];
int N, C, I, Goal, Prime2;
int FD, DC(10); \final digit and digit counters
[Text(0, "First 50 Blum integers:^m^j");
N:= 3; C:= 0; Goal:= 100_000;
for I:= 0 to 9 do DC(I):= 0;
loop [if Semiprime(N) then
[if rem(Prime1/4) = 3 then
[Prime2:= N/Prime1;
if rem(Prime2/4) = 3 and Prime2 # Prime1 then
[C:= C+1;
if C <= 50 then
[Print("%5d", N);
if rem(C/10) = 0 then Print("\n");
];
if C = 26_828 then
Print("\nThe 26,828th Blum integer is: %7,d\n", N);
if C = Goal then
[Print("The %6,dth Blum integer is: %7,d\n", Goal, N);
if Goal = 400_000 then quit;
Goal:= Goal + 100_000;
];
FD:= rem(N/10);
DC(FD):= DC(FD)+1;
];
];
];
N:= N+2;
];
Print("\n% distribution of the first 400,000 Blum integers:\n");
for I:= 0 to 9 do
if DC(I) > 0 then
Print("%4.3f\% end in %d\n", float(DC(I)) / 4_000., I);
]
- Output:
First 50 Blum integers: 21 33 57 69 77 93 129 133 141 161 177 201 209 213 217 237 249 253 301 309 321 329 341 381 393 413 417 437 453 469 473 489 497 501 517 537 553 573 581 589 597 633 649 669 681 713 717 721 737 749 The 26,828th Blum integer is: 524,273 The 100,000th Blum integer is: 2,075,217 The 200,000th Blum integer is: 4,275,533 The 300,000th Blum integer is: 6,521,629 The 400,000th Blum integer is: 8,802,377 % distribution of the first 400,000 Blum integers: 25.001% end in 1 25.017% end in 3 24.997% end in 7 24.985% end in 9