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DESCRIPTION
Code Collection of the Aks algorithm
Citation preview
AKS testfor primesYou areencouragedto solve this
task according to thetask description, usingany language you mayknow.
AKS test for primesFrom Rosetta Code
The AKS algorithm (http://www.cse.iitk.ac.in/users/manindra/algebra/primality_v6.pdf) for testing whether a number is prime is apolynomial-time algorithm based on an elementary theorem aboutPascal triangles.
The theorem on which the test is based can be stated as follows:
a number p is prime if and only if all the coefficients of thepolynomial expansion of
(x − 1)p − (xp − 1)
are divisible by p.
For example, trying p = 3:
(x − 1)3 − (x3 − 1) = (x3 − 3x2 + 3x − 1) − (x3 − 1) = − 3x2 + 3xAnd all the coefficients are divisible by 3 so 3 is prime.
Note:This task is not the AKS primality test. It is an inefficient exponential timealgorithm discovered in the late 1600s and used as an introductory lemma
in the AKS derivation.
The task
Create a function/subroutine/method that given p generates the coefficients of the expandedpolynomial representation of (x − 1)p.
1.
Use the function to show here the polynomial expansions of (x − 1)p for p in the range 0 to atleast 7, inclusive.
2.
Use the previous function in creating another function that when given p returns whether pis prime using the theorem.
3.
Use your test to generate a list of all primes under 35.4. As a stretch goal, generate all primes under 50 (Needs greater than 31 bit integers).5.
References
Agrawal-Kayal-Saxena (AKS) primality test (https://en.wikipedia.org/wiki/AKS_primality_test)(Wikipedia)Fool-Proof Test for Primes (http://www.youtube.com/watch?v=HvMSRWTE2mI) -Numberphile (Video). The accuracy of this video is disputed -- at best it is anoversimplification.
Contents
1 ALGOL 682 AutoHotkey
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3 Bracmat4 C5 C#6 Clojure7 CoffeeScript8 Common Lisp9 D10 EchoLisp11 Erlang12 Fortran13 Go14 FreeBASIC15 Haskell16 J17 Java18 JavaScript19 jq20 Julia21 Maple22 Mathematica / Wolfram Language23 Oforth24 PARI/GP25 Pascal26 Perl
26.1 Real AKS27 Perl 628 Phix29 PicoLisp30 Prolog
30.1 Prolog(ue)30.2 Pascal Triangle Generator30.3 Solutions
31 PureBasic32 Python
32.1 Python: Output formatted for wiki33 R34 Racket35 REXX
35.1 version 135.2 version 2
36 Ruby37 Rust38 Scala39 Scilab40 Seed741 Sidef42 Swift43 Tcl44 uBasic/4tH45 zkl
ALGOL 68
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The code below uses Algol 68 Genie which provides arbitrary precision arithmetic for LONGLONG modes.
BEGINCOMMENT Mathematical preliminaries.
First note that the homogeneous polynomial (a+b)^n is symmetrical(to see this just swap the variables a and b). Therefore its
coefficients need be calculated only to that of (ab)^{n/2} for even n or (ab)^{(n-1)/2} for odd n.
Second, the coefficients are the binomial coefficients C(n,k) where the coefficient of a^k b^(n-k) is C(n,k) = n! / k! (k-1)!. This leads to an immediate and relatively efficient implementation for which we do not need to compute n! before dividing by k! and (k-1)! but, rather cancel common factors as we go along. Further, the well-known symmetry identity C(n,k) = C(n, n-k) allows a significant reduction in computational effort.
Third, (x-1)^n is the value of (a + b)^n when a=x and b = -1. The powers of -1 alternate between +1 and -1 so we may as well compute
(x+1)^n and negate every other coefficient when printing.COMMENT
PR precision=300 PRMODE LLI = LONG LONG INT; CO For brevity COPROC choose = (INT n, k) LLI :BEGIN
LLI result := 1;INT sym k := (k >= n%2 | n-k | k); CO Use symmetry COIF sym k > 0 THEN
FOR i FROM 0 TO sym k-1DO result TIMESAB (n-i); result OVERAB (i+1)OD
FI; result
END;PROC coefficients = (INT n) [] LLI :BEGIN
[0:n] LLI a;FOR i FROM 0 TO n%2DO a[i] := a[n-i] := choose (n, i) CO Use symmetry CO
OD; a
END;COMMENT First print the polynomials (x-1)^n, remembering to alternate signs and to tidy up the constant term, the x^1 term and the x^n term. This means we must treat (x-1)^0 and (x-1)^1 speciallyCOMMENT
FOR n FROM 0 TO 7DO
[0:n] LLI a := coefficients (n);printf (($"(x-1)^", g(0), " = "$, n));CASE n+1 IN
printf (($g(0)l$, a[0])),printf (($"x - ", g(0)l$, a[1]))
OUTprintf (($"x^", g(0)$, n));FOR i TO n-2DO printf (($xax, g(0), "x^", g(0)$, (ODD i | "-" | "+"), a[i], n-i))OD;printf (($xax, g(0), "x"$, (ODD (n-1) | "-" | "+"), a[n-1]));printf (($xaxg(0)l$, (ODD n | "-" | "+"), a[n]))
ESACOD;COMMENT Finally, for the "AKS" portion of the task, the sign of the coefficient has no effect on its divisibility by p so, once again, we may as well use the positive coefficients. Symmetry clearly
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reduces the necessary number of tests by a factor of two.COMMENT
PROC is prime = (INT n) BOOL :BEGIN
BOOL prime := TRUE;FOR i FROM 1 TO n%2 WHILE prime DO prime := choose (n, i) MOD n = 0 OD;
primeEND;print ("Primes < 50 are ");FOR n FROM 2 TO 50 DO (is prime (n) | printf (($g(0)x$, n)) ) OD;print (newline);print ("And just to show off, the primes between 900 and 1000 are ");FOR n FROM 900 TO 1000 DO IF is prime (n) THEN printf (($g(0)x$, n)) FI OD;print (newline)
END
Output:
(x-1)^0 = 1(x-1)^1 = x - 1(x-1)^2 = x^2 - 2x + 1(x-1)^3 = x^3 - 3x^2 + 3x - 1(x-1)^4 = x^4 - 4x^3 + 6x^2 - 4x + 1(x-1)^5 = x^5 - 5x^4 + 10x^3 - 10x^2 + 5x - 1(x-1)^6 = x^6 - 6x^5 + 15x^4 - 20x^3 + 15x^2 - 6x + 1(x-1)^7 = x^7 - 7x^6 + 21x^5 - 35x^4 + 35x^3 - 21x^2 + 7x - 1Primes < 50 are 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 And just to show off, the primes between 900 and 1000 are 907 911 919 929 937 941 947 953 967 971 977 983 991 997
AutoHotkey
Works with: AutoHotkey L
; 1. Create a function/subroutine/method that given p generates the coefficients of the expanded polynomial representation of (x-1)^p. ; Function modified from http://rosettacode.org/wiki/Pascal%27s_triangle#AutoHotkeypascalstriangle(n=8) ; n rows of Pascal's triangle{
p := Object(), z:=Object()Loop, % n
Loop, % row := A_Indexcol := A_Index, p[row, col] := row = 1 and col = 1
? 1: (p[row-1, col-1] = "" ; math operations on blanks return blanks; I want to assume zero
? 0: p[row-1, col-1])
- (p[row-1, col] = ""? 0: p[row-1, col])
Return p}
; 2. Use the function to show here the polynomial expansions of p for p in the range 0 to at least 7, inclusive.For k, v in pascalstriangle(){
s .= "`n(x-1)^" k-1 . "="For k, w in v
s .= "+" w "x^" k-1}s := RegExReplace(s, "\+-", "-")s := RegExReplace(s, "x\^0", "")s := RegExReplace(s, "x\^1", "x")Msgbox % clipboard := s
; 3. Use the previous function in creating another function that when given p returns whether p is prime using the AKS test.aks(n){
isnotprime := FalseFor k, v in pascalstriangle(n+1)[n+1]
(k != 1 and k != n+1) ? isnotprime |= !(v // n = v / n) ; if any is not divisible, returns true
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Return !isnotprime}
; 4. Use your AKS test to generate a list of all primes under 35. i := 49p := pascalstriangle(i+1)Loop, % i{
n := A_Indexisnotprime := FalseFor k, v in p[n+1]
(k != 1 and k != n+1) ? isnotprime |= !(v // n = v / n) ; if any is not divisible, returns truet .= isnotprime ? "" : A_Index " "
}Msgbox % tReturn
Output:
(x-1)^0=+1(x-1)^1=-1+1x(x-1)^2=+1-2x+1x^2(x-1)^3=-1+3x-3x^2+1x^3(x-1)^4=+1-4x+6x^2-4x^3+1x^4(x-1)^5=-1+5x-10x^2+10x^3-5x^4+1x^5(x-1)^6=+1-6x+15x^2-20x^3+15x^4-6x^5+1x^6(x-1)^7=-1+7x-21x^2+35x^3-35x^4+21x^5-7x^6+1x^7
1 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
Function maxes out at i = 61 as AutoHotkey supports up to 64-bit signed integers.
Bracmat
Bracmat automatically normalizes symbolic expressions with the algebraic binary operators +, *, ^and \L (logartithm). It can differentiate such expressions using the \D binary operator. (Theseoperators were implemented in Bracmat before all other operators!). Some algebraic values canexist in two evaluated forms. The equivalent x*(a+b) and x*a+x*b are both considered "normal", butx*(a+b)+-1 is not, and therefore expanded to -1+a*x+b*x. This is used in the forceExpansion function toconvert e.g. x*(a+b) to x*a+x*b.
The primality test uses a pattern that looks for a fractional factor. If such a factor is found, thetest fails. Otherwise it succeeds.
( (forceExpansion=.1+!arg+-1)& (expandx-1P=.forceExpansion$((x+-1)^!arg))& ( isPrime = . forceExpansion $ (!arg^-1*(expandx-1P$!arg+-1*(x^!arg+-1))) : ?+/*?+? & ~` | )& out$"Polynomial representations of (x-1)^p for p <= 7 :"& -1:?n& whl ' ( 1+!n:~>7:?n & out$(str$("n=" !n ":") expandx-1P$!n) )& 1:?n& :?primes& whl ' ( 1+!n:~>50:?n & ( isPrime$!n&!primes !n:?primes |
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) )& out$"2 <= Primes <= 50:"& out$!primes);
Output:
Polynomial representations of (x-1)^p for p <= 7 :n=0: 1n=1: -1+xn=2: 1+-2*x+x^2n=3: -1+3*x+-3*x^2+x^3n=4: 1+-4*x+6*x^2+-4*x^3+x^4n=5: -1+5*x+-10*x^2+10*x^3+-5*x^4+x^5n=6: 1+-6*x+15*x^2+-20*x^3+15*x^4+-6*x^5+x^6 n=7: -1 + 7*x + -21*x^2 + 35*x^3 + -35*x^4 + 21*x^5 + -7*x^6 + x^72 <= Primes <= 50:2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
The AKS test kan be written more concisely than the task describes. This prints the primesbetween 980 and 1000:
( out$"Primes between 980 and 1000, short version:"& 980:?n& whl ' ( !n+1:<1000:?n & ( 1+!n^-1*((x+-1)^!n+-1*(x^!n+-1))+-1:?+/*?+? | out$!n ) ));
Output:
Primes between 980 and 1000, short version:983991997
C
#include <stdio.h>#include <stdlib.h>
long long c[100];
void coef(int n){
int i, j;
if (n < 0 || n > 63) abort(); // gracefully deal with range issue
for (c[i=0] = 1; i < n; c[0] = -c[0], i++)for (c[1 + (j=i)] = 1; j > 0; j--)
c[j] = c[j-1] - c[j];}
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int is_prime(int n){
int i;
coef(n);c[0] += 1, c[i=n] -= 1;while (i-- && !(c[i] % n));
return i < 0;}
void show(int n){
do printf("%+lldx^%d", c[n], n); while (n--);}
int main(void){
int n;
for (n = 0; n < 10; n++) {coef(n);printf("(x-1)^%d = ", n);show(n);putchar('\n');
}
printf("\nprimes (never mind the 1):");for (n = 1; n <= 63; n++)
if (is_prime(n))printf(" %d", n);
putchar('\n');return 0;
}
The ugly output:
(x-1)^0 = +1x^0(x-1)^1 = +1x^1-1x^0(x-1)^2 = +1x^2-2x^1+1x^0(x-1)^3 = +1x^3-3x^2+3x^1-1x^0(x-1)^4 = +1x^4-4x^3+6x^2-4x^1+1x^0(x-1)^5 = +1x^5-5x^4+10x^3-10x^2+5x^1-1x^0(x-1)^6 = +1x^6-6x^5+15x^4-20x^3+15x^2-6x^1+1x^0(x-1)^7 = +1x^7-7x^6+21x^5-35x^4+35x^3-21x^2+7x^1-1x^0(x-1)^8 = +1x^8-8x^7+28x^6-56x^5+70x^4-56x^3+28x^2-8x^1+1x^0(x-1)^9 = +1x^9-9x^8+36x^7-84x^6+126x^5-126x^4+84x^3-36x^2+9x^1-1x^0
primes (never mind the 1): 1 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61
C#
Translation of: C
using System; public class AksTest { static long[] c = new long[100];
static void Main(string[] args) { for (int n = 0; n < 10; n++) {
coef(n);Console.Write("(x-1)^" + n + " = ");show(n);Console.WriteLine("");
} Console.Write("Primes:");
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for (int n = 1; n <= 63; n++) if (is_prime(n)) Console.Write(n + " ");
Console.WriteLine('\n'); Console.ReadLine(); }
static void coef(int n) { int i, j;
if (n < 0 || n > 63) System.Environment.Exit(0);// gracefully deal with range issue
for (c[i = 0] = 1L; i < n; c[0] = -c[0], i++) for (c[1 + (j = i)] = 1L; j > 0; j--) c[j] = c[j - 1] - c[j]; }
static bool is_prime(int n) { int i;
coef(n); c[0] += 1; c[i = n] -= 1;
while (i-- != 0 && (c[i] % n) == 0) ;
return i < 0; }
static void show(int n) {
do { Console.Write("+" + c[n] + "x^" + n);
}while (n-- != 0); }
}
Clojure
The *' function is an arbitrary precision multiplication.
(defn c "kth coefficient of (x - 1)^n"[n k](/ (apply *' (range n (- n k) -1))
(apply *' (range k 0 -1))(if (and (even? k) (< k n)) -1 1)))
(defn cs "coefficient series for (x - 1)^n, k=[0..n]"[n](map #(c n %) (range (inc n))))
(defn aks? [p] (->> (cs p) rest butlast (every? #(-> % (mod p) zero?))))
(println "coefficient series n (k[0] .. k[n])")(doseq [n (range 10)] (println n (cs n)))(println)(println "primes < 50 per AKS:" (filter aks? (range 2 50)))
Output:
coefficient series n (k[0] .. k[n])0 (1)1 (-1 1)2 (-1 2 1)
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3 (-1 3 -3 1)4 (-1 4 -6 4 1)5 (-1 5 -10 10 -5 1)6 (-1 6 -15 20 -15 6 1)7 (-1 7 -21 35 -35 21 -7 1)8 (-1 8 -28 56 -70 56 -28 8 1)9 (-1 9 -36 84 -126 126 -84 36 -9 1)
primes < 50 per AKS: (2 3 5 7 11 13 17 19 23 29 31 37 41 43 47)
CoffeeScript
pascal = () -> a = []
return () ->if a.length is 0 then a = [1]else
b = (a[i] + a[i+1] for i in [0 ... a.length - 1]) a = [1].concat(b).concat [1]
show = (a) -> show_x = (e) ->
switch ewhen 0 then ""when 1 then "x"else "x^#{e}"
degree = a.length - 1 str = "(x - 1)^#{degree} =" sgn = 1
for i in [0...a.length] str += ' ' + (if sgn > 0 then "+" else "-") + ' ' + a[i] + show_x(degree - i) sgn = -sgn
return str
primerow = (row) -> degree = row.length - 1 row[1 ... degree].every (x) -> x % degree is 0
p = pascal()console.log show p() for i in [0..7]
p = pascal()p(); p() # skip 0 and 1
primes = (i+1 for i in [1..49] when primerow p())
console.log ""console.log "The primes upto 50 are: #{primes}"
Output:
(x - 1)^0 = + 1(x - 1)^1 = + 1x - 1(x - 1)^2 = + 1x^2 - 2x + 1(x - 1)^3 = + 1x^3 - 3x^2 + 3x - 1(x - 1)^4 = + 1x^4 - 4x^3 + 6x^2 - 4x + 1(x - 1)^5 = + 1x^5 - 5x^4 + 10x^3 - 10x^2 + 5x - 1(x - 1)^6 = + 1x^6 - 6x^5 + 15x^4 - 20x^3 + 15x^2 - 6x + 1(x - 1)^7 = + 1x^7 - 7x^6 + 21x^5 - 35x^4 + 35x^3 - 21x^2 + 7x - 1
The primes upto 50 are: 2,3,5,7,11,13,17,19,23,29,31,37,41,43,47
Common Lisp
(defun coefficients (p)
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(cond((= p 0) #(1))
(t (loop for i from 1 upto p for result = #(1 -1) then (map 'vector #'-
(concatenate 'vector result #(0))(concatenate 'vector #(0) result))
finally (return result)))))
(defun primep (p)(cond((< p 2) nil)
(t (let ((c (coefficients p)))(decf (elt c 0))(loop for i from 0 upto (/ (length c) 2)
for x across c never (/= (mod x p) 0))))))
(defun main ()(format t "# p: (x-1)^p for small p:~%")(loop for p from 0 upto 7
do (format t "~D: " p)(loop for i from 0
for x across (reverse (coefficients p))do (when (>= x 0) (format t "+"))
(format t "~D" x)(if (> i 0)
(format t "X^~D " i)(format t " ")))
(format t "~%"))(loop for i from 0 to 50
do (when (primep i) (format t "~D " i)))(format t "~%"))
Output:
# p: (x-1)^p for small p:0: +1 1: -1 +1X^1 2: +1 -2X^1 +1X^2 3: -1 +3X^1 -3X^2 +1X^3 4: +1 -4X^1 +6X^2 -4X^3 +1X^4 5: -1 +5X^1 -10X^2 +10X^3 -5X^4 +1X^5 6: +1 -6X^1 +15X^2 -20X^3 +15X^4 -6X^5 +1X^6 7: -1 +7X^1 -21X^2 +35X^3 -35X^4 +21X^5 -7X^6 +1X^7 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
D
Translation of: Python
import std.stdio, std.range, std.algorithm, std.string, std.bigint;
BigInt[] expandX1(in uint p) pure /*nothrow*/ {if (p == 0) return [1.BigInt];typeof(return) r = [1.BigInt, BigInt(-1)];foreach (immutable _; 1 .. p)
r = zip(r~0.BigInt, 0.BigInt~r).map!(xy => xy[0]-xy[1]).array; r.reverse();
return r;}
bool aksTest(in uint p) pure /*nothrow*/ {if (p < 2) return false;auto ex = p.expandX1;
ex[0]++;return !ex[0 .. $ - 1].any!(mult => mult % p);
}
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void main() {"# p: (x-1)^p for small p:".writeln;foreach (immutable p; 0 .. 12)
writefln("%3d: %s", p, p.expandX1.zip(iota(p + 1)).retro .map!q{"%+dx^%d ".format(a[])}.join.replace("x^0", "") .replace("^1 ", " ").replace("+", "+ ") .replace("-", "- ").replace(" 1x", " x")[2 .. $]);
"\nSmall primes using the AKS test:".writeln;101.iota.filter!aksTest.writeln;
}
Output:
# p: (x-1)^p for small p: 0: 1 1: x - 1 2: x^2 - 2x + 1 3: x^3 - 3x^2 + 3x - 1 4: x^4 - 4x^3 + 6x^2 - 4x + 1 5: x^5 - 5x^4 + 10x^3 - 10x^2 + 5x - 1 6: x^6 - 6x^5 + 15x^4 - 20x^3 + 15x^2 - 6x + 1 7: x^7 - 7x^6 + 21x^5 - 35x^4 + 35x^3 - 21x^2 + 7x - 1 8: x^8 - 8x^7 + 28x^6 - 56x^5 + 70x^4 - 56x^3 + 28x^2 - 8x + 1 9: x^9 - 9x^8 + 36x^7 - 84x^6 + 126x^5 - 126x^4 + 84x^3 - 36x^2 + 9x - 1 10: x^10 - 10x^9 + 45x^8 - 120x^7 + 210x^6 - 252x^5 + 210x^4 - 120x^3 + 45x^2 - 10x + 1 11: x^11 - 11x^10 + 55x^9 - 165x^8 + 330x^7 - 462x^6 + 462x^5 - 330x^4 + 165x^3 - 55x^2 + 11x - 1
Small primes using the AKS test:[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97]
EchoLisp
We use the math.lib library and the poly functions to compute and display the requiredpolynomials. A polynomial P(x) = a0 +a1*x + .. an*x^n is a list of coefficients (a0 a1 .... an).
(lib 'math.lib);; 1 - x^p : P = (1 0 0 0 ... 0 -1)(define (mono p) (append (list 1) (make-list (1- p) 0) (list -1)))
;; compute (x-1)^p , p >= 1(define (aks-poly p)
(poly-pow (list -1 1) p))
;; (define (show-them n)
(for ((p (in-range 1 n)))(writeln 'p p (poly->string 'x (aks-poly p)))))
;; aks-test;; P = (x-1)^p + 1 - x^p(define (aks-test p)
(let ((P (poly-add (mono p) (aks-poly p))) (test (lambda(a) (zero? (modulo a p))))) ;; p divides a[i] ? (apply and (map test P)))) ;; returns #t if true for all a[i]
Output:
(show-them 13) →p 1 x -1p 2 x^2 -2x +1p 3 x^3 -3x^2 +3x -1p 4 x^4 -4x^3 +6x^2 -4x +1p 5 x^5 -5x^4 +10x^3 -10x^2 +5x -1
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p 6 x^6 -6x^5 +15x^4 -20x^3 +15x^2 -6x +1p 7 x^7 -7x^6 +21x^5 -35x^4 +35x^3 -21x^2 +7x -1p 8 x^8 -8x^7 +28x^6 -56x^5 +70x^4 -56x^3 +28x^2 -8x +1p 9 x^9 -9x^8 +36x^7 -84x^6 +126x^5 -126x^4 +84x^3 -36x^2 +9x -1p 10 x^10 -10x^9 +45x^8 -120x^7 +210x^6 -252x^5 +210x^4 -120x^3 +45x^2 -10x +1p 11 x^11 -11x^10 +55x^9 -165x^8 +330x^7 -462x^6 +462x^5 -330x^4 +165x^3 -55x^2 +11x -1p 12 x^12 -12x^11 +66x^10 -220x^9 +495x^8 -792x^7 +924x^6 -792x^5 +495x^4 -220x^3 +66x^2 -12x +1
(lib 'bigint)Lib: bigint.lib loaded.
(for ((p (in-range 2 100)))(when (aks-test p) (write p))) →
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
Erlang
Translation of: CoffeeScript
The Erlang io module can print out lists of characters with any level of nesting as a flat string.(e.g. ["Er", ["la", ["n"]], "g"] prints as "Erlang") which is useful when constructing the strings toprint out for the binomial expansions. The program also shows how lazy lists can be implementedin Erlang.
#! /usr/bin/escript
-import(lists, [all/2, seq/2, zip/2]).
iterate(F, X) -> fun() -> [X | iterate(F, F(X))] end.
take(0, _lazy) -> [];take(N, Lazy) ->
[Value | Next] = Lazy(),[Value | take(N-1, Next)].
pascal() -> iterate(fun (Row) -> [1 | sum_adj(Row)] end, [1]).
sum_adj([_] = L) -> L;sum_adj([A, B | _] = Row) -> [A+B | sum_adj(tl(Row))].
show_binomial(Row) ->Degree = length(Row) - 1,["(x - 1)^", integer_to_list(Degree), " =", binomial_rhs(Row, 1, Degree)].
show_x(0) -> "";show_x(1) -> "x";show_x(N) -> [$x, $^ | integer_to_list(N)].
binomial_rhs([], _, _) -> [];binomial_rhs([Coef | Coefs], Sgn, Exp) ->
SignChar = if Sgn > 0 -> $+; true -> $- end,[$ , SignChar, $ , integer_to_list(Coef), show_x(Exp) | binomial_rhs(Coefs, -Sgn, Exp-1)].
primerow(Row, N) -> all(fun (Coef) -> (Coef =:= 1) or (Coef rem N =:= 0) end, Row).
main(_) ->[io:format("~s~n", [show_binomial(Row)]) || Row <- take(8, pascal())],io:format("~nThe primes upto 50: ~p~n",
[[N || {Row, N} <- zip(tl(tl(take(51, pascal()))), seq(2, 50)),primerow(Row, N)]]).
Output:
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(x - 1)^0 = + 1(x - 1)^1 = + 1x - 1(x - 1)^2 = + 1x^2 - 2x + 1(x - 1)^3 = + 1x^3 - 3x^2 + 3x - 1(x - 1)^4 = + 1x^4 - 4x^3 + 6x^2 - 4x + 1(x - 1)^5 = + 1x^5 - 5x^4 + 10x^3 - 10x^2 + 5x - 1(x - 1)^6 = + 1x^6 - 6x^5 + 15x^4 - 20x^3 + 15x^2 - 6x + 1(x - 1)^7 = + 1x^7 - 7x^6 + 21x^5 - 35x^4 + 35x^3 - 21x^2 + 7x - 1
The primes upto 50: [2,3,5,7,11,13,17,19,23,29,31,37,41,43,47]
Fortran
program aksimplicit none
! Coefficients of polynomial expansioninteger(kind=16), dimension(:), allocatable :: coeffsinteger(kind=16) :: n! Character variable for I/Ocharacter(len=40) :: tmp
! Point #2do n = 0, 7
write(tmp, *) ncall polynomial_expansion(n, coeffs)
write(*, fmt='(A)', advance='no') '(x - 1)^'//trim(adjustl(tmp))//' ='call print_polynom(coeffs)
end do
! Point #4do n = 2, 35if (is_prime(n)) write(*, '(I4)', advance='no') n
end do write(*, *)
! Point #5do n = 2, 124if (is_prime(n)) write(*, '(I4)', advance='no') n
end do write(*, *)
if (allocated(coeffs)) deallocate(coeffs)contains! Calculate coefficients of (x - 1)^n using binomial theoremsubroutine polynomial_expansion(n, coeffs)integer(kind=16), intent(in) :: ninteger(kind=16), dimension(:), allocatable, intent(out) :: coeffsinteger(kind=16) :: i, j
if (allocated(coeffs)) deallocate(coeffs)
allocate(coeffs(n + 1))
do i = 1, n + 1 coeffs(i) = binomial(n, i - 1)*(-1)**(n - i - 1)
end doend subroutine
! Calculate binomial coefficient using recurrent relation, as calculation! using factorial overflows too quickly.function binomial(n, k) result (res)integer(kind=16), intent(in) :: n, kinteger(kind=16) :: resinteger(kind=16) :: i
if (k == 0) then res = 1
returnend if
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res = 1do i = 0, k - 1
res = res*(n - i)/(i + 1)end do
end function
! Outputs polynomial with given coefficientssubroutine print_polynom(coeffs)integer(kind=16), dimension(:), allocatable, intent(in) :: coeffsinteger(kind=4) :: i, pcharacter(len=40) :: cbuf, pbuflogical(kind=1) :: non_zero
if (.not. allocated(coeffs)) return
non_zero = .false.
do i = 1, size(coeffs)if (coeffs(i) .eq. 0) cycle
p = i - 1 write(cbuf, '(I40)') abs(coeffs(i)) write(pbuf, '(I40)') p
if (non_zero) thenif (coeffs(i) .gt. 0) then
write(*, fmt='(A)', advance='no') ' + 'else
write(*, fmt='(A)', advance='no') ' - 'endif
elseif (coeffs(i) .gt. 0) then
write(*, fmt='(A)', advance='no') ' 'else
write(*, fmt='(A)', advance='no') ' - 'endif
endif
if (p .eq. 0) then write(*, fmt='(A)', advance='no') trim(adjustl(cbuf))
elseif (p .eq. 1) thenif (coeffs(i) .eq. 1) then
write(*, fmt='(A)', advance='no') 'x'else
write(*, fmt='(A)', advance='no') trim(adjustl(cbuf))//'x'end if
elseif (coeffs(i) .eq. 1) then
write(*, fmt='(A)', advance='no') 'x^'//trim(adjustl(pbuf))else
write(*, fmt='(A)', advance='no') &trim(adjustl(cbuf))//'x^'//trim(adjustl(pbuf))
end ifend if
non_zero = .true.end do
write(*, *)end subroutine
! Test if n is prime using AKS test. Point #3.function is_prime(n) result (res)integer(kind=16), intent (in) :: nlogical(kind=1) :: resinteger(kind=16), dimension(:), allocatable :: coeffsinteger(kind=16) :: i
call polynomial_expansion(n, coeffs) coeffs(1) = coeffs(1) + 1 coeffs(n + 1) = coeffs(n + 1) - 1
res = .true.
do i = 1, n + 1 res = res .and. (mod(coeffs(i), n) == 0)
end do
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if (allocated(coeffs)) deallocate(coeffs)end function
end program aks
Output:
(x - 1)^0 = 1(x - 1)^1 = - 1 + x(x - 1)^2 = 1 - 2x + x^2(x - 1)^3 = - 1 + 3x - 3x^2 + x^3(x - 1)^4 = 1 - 4x + 6x^2 - 4x^3 + x^4(x - 1)^5 = - 1 + 5x - 10x^2 + 10x^3 - 5x^4 + x^5(x - 1)^6 = 1 - 6x + 15x^2 - 20x^3 + 15x^4 - 6x^5 + x^6(x - 1)^7 = - 1 + 7x - 21x^2 + 35x^3 - 35x^4 + 21x^5 - 7x^6 + x^7 2 3 5 7 11 13 17 19 23 29 31 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113
Go
package main
import "fmt"
func bc(p int) []int64 { c := make([]int64, p+1) r := int64(1)
for i, half := 0, p/2; i <= half; i++ { c[i] = r c[p-i] = r r = r * int64(p-i) / int64(i+1)
}for i := p - 1; i >= 0; i -= 2 {
c[i] = -c[i]}return c
}
func main() {for p := 0; p <= 7; p++ {
fmt.Printf("%d: %s\n", p, pp(bc(p)))}for p := 2; p < 50; p++ {
if aks(p) { fmt.Print(p, " ")
}}
fmt.Println()}
var e = []rune("²³⁴⁵⁶⁷")
func pp(c []int64) (s string) {if len(c) == 1 {
return fmt.Sprint(c[0])}
p := len(c) - 1if c[p] != 1 {
s = fmt.Sprint(c[p])}for i := p; i > 0; i-- {
s += "x"if i != 1 {
s += string(e[i-2])}if d := c[i-1]; d < 0 {
s += fmt.Sprintf(" - %d", -d)} else {
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s += fmt.Sprintf(" + %d", d)}
}return
}
func aks(p int) bool { c := bc(p) c[p]-- c[0]++
for _, d := range c {if d%int64(p) != 0 {
return false}
}return true
}
Output:
0: 11: x - 12: x² - 2x + 13: x³ - 3x² + 3x - 14: x⁴ - 4x³ + 6x² - 4x + 15: x⁵ - 5x⁴ + 10x³ - 10x² + 5x - 16: x⁶ - 6x⁵ + 15x⁴ - 20x³ + 15x² - 6x + 17: x⁷ - 7x⁶ + 21x⁵ - 35x⁴ + 35x³ - 21x² + 7x - 12 3 5 7 11 13 17 19 23 29 31 37 41 43 47
FreeBASIC
'METHOD -- Use the Pascal triangle to retrieve the coefficients'UPPER LIMIT OF FREEBASIC ULONGINT GETS PRIMES UP TO 70Sub string_split(s_in As String,char As String,result() As String)
Dim As String s=s_in,var1,var2Dim As Integer n,pst#macro split(stri,char,var1,var2)
pst=Instr(stri,char) var1="":var2=""
If pst<>0 Then var1=Mid(stri,1,pst-1) var2=Mid(stri,pst+1)
Else var1=stri
End IfRedim Preserve result(1 To 1+n-((Len(var1)>0)+(Len(var2)>0)))
result(n+1)=var1#endmacroDo
split(s,char,var1,var2):n=n+1:s=var2Loop Until var2=""Redim Preserve result(1 To Ubound(result)-1)
End Sub
'Get Pascal triangle componentsFunction pasc(n As Integer,flag As Integer=0) As String n+=1
Dim As Ulongint V(n):V(1)=1ulDim As String s,signFor r As Integer= 2 To n
s=""For i As Integer = r To 1 Step -1
V(i) += V(i-1)If i Mod 2=1 Then sign="" Else sign="-"
s+=sign+Str(V(i))+","Next i
Next rIf flag Then 'formatted output
Dim As String i,i2,i3,gRedim As String a(0)
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string_split(s,",",a())For n1 As Integer=1 To Ubound(a)
If Left(a(n1),1)="-" Then sign="" Else sign="+"If n1=Ubound(a) Then i2="" Else i2=a(n1)If n1=2 Then i3="x" Else i3="x^"+Str(n1-1)If n1=1 Then i="":sign=" " Else i=i3
g+=sign+i2+i+" "Next n1
g="(x-1)^"+Str(n-1)+" = "+gReturn g
End IfReturn s
End Function
Function isprime(num As Integer) As IntegerRedim As String a(0)
string_split(pasc(num),",",a())For n As Integer=Lbound(a)+1 To Ubound(a)-1
If (Valulng(Ltrim(a(n),"-"))) Mod num<>0 Then Return 0Next nReturn -1
End Function'==================================== 'Formatted outputFor n As Integer=1 To 9
Print pasc(n,1)Next n
Print'Limit of Freebasic Ulongint sets about 70 maxPrint "Primes up to 70:"For n As Integer=2 To 70
If isprime(n) Then Print n;Next n
Sleep
Output:
(x-1)^1 = -1 +x(x-1)^2 = 1 -2x +x^2(x-1)^3 = -1 +3x -3x^2 +x^3(x-1)^4 = 1 -4x +6x^2 -4x^3 +x^4(x-1)^5 = -1 +5x -10x^2 +10x^3 -5x^4 +x^5(x-1)^6 = 1 -6x +15x^2 -20x^3 +15x^4 -6x^5 +x^6(x-1)^7 = -1 +7x -21x^2 +35x^3 -35x^4 +21x^5 -7x^6 +x^7(x-1)^8 = 1 -8x +28x^2 -56x^3 +70x^4 -56x^5 +28x^6 -8x^7 +x^8(x-1)^9 = -1 +9x -36x^2 +84x^3 -126x^4 +126x^5 -84x^6 +36x^7 -9x^8 +x^9
Primes up to 70: 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67
Haskell
expand p = scanl (\z i -> z * (p-i+1) `div` i) 1 [1..p]
test p | p < 2 = False| otherwise = and [mod n p == 0 | n <- init . tail $ expand p]
printPoly [1] = "1"printPoly p = concat [ unwords [pow i, sgn (l-i), show (p!!(i-1))]
| i <- [l-1,l-2..1] ] where l = length p sgn i = if even i then "+" else "-" pow i = take i "x^" ++ if i > 1 then show i else ""
main = doputStrLn "-- p: (x-1)^p for small p"
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putStrLn $ unlines [show i ++ ": " ++ printPoly (expand i) | i <- [0..10]]putStrLn "-- Primes up to 100:"print (filter test [1..100])
Output:
-- p: (x-1)^p for small p0: 11: x - 12: x^2 - 2x + 13: x^3 - 3x^2 + 3x - 14: x^4 - 4x^3 + 6x^2 - 4x + 15: x^5 - 5x^4 + 10x^3 - 10x^2 + 5x - 16: x^6 - 6x^5 + 15x^4 - 20x^3 + 15x^2 - 6x + 17: x^7 - 7x^6 + 21x^5 - 35x^4 + 35x^3 - 21x^2 + 7x - 18: x^8 - 8x^7 + 28x^6 - 56x^5 + 70x^4 - 56x^3 + 28x^2 - 8x + 19: x^9 - 9x^8 + 36x^7 - 84x^6 + 126x^5 - 126x^4 + 84x^3 - 36x^2 + 9x - 110: x^10 - 10x^9 + 45x^8 - 120x^7 + 210x^6 - 252x^5 + 210x^4 - 120x^3 + 45x^2 - 10x + 1
-- Primes up to 100:[2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97]
J
Solution:
binomialExpansion =: (!~ * _1 ^ 2 | ]) i.&.:<: NB. 1) Create a function that gives the coefficients of (x-1)^p. testAKS =: 0 *./ .= ] | binomialExpansion NB. 3) Use that function to create another which determines whether p is prime usin
Examples:
binomialExpansion&.> i. 8 NB. 2) show the polynomial expansions p in the range 0 to at 7 inclusive.+-++--+----+-------+-----------+---------------+------------------+|0||_2|_3 3|_4 6 _4|_5 10 _10 5|_6 15 _20 15 _6|_7 21 _35 35 _21 7|+-++--+----+-------+-----------+---------------+------------------+
(#~ testAKS&> ) 2+i. 35 NB. 4) Generate a list of all primes under 35.2 3 5 7 11 13 17 19 23 29 31
(#~ testAKS&> ) 2+i. 50 NB. 5) [stretch] Generate all primes under 502 3 5 7 11 13 17 19 23 29 31 37 41 43 47 i.&.:(_1&p:) 50 NB. Double-check our results using built-in prime filter.2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
Java
Translation of: CSolution:
public class AksTest {
static Long[] c = new Long[100];
public static void main(String[] args){
for (int n = 0; n < 10; n++) {coef(n);System.out.print("(x-1)^" + n + " = ");show(n);System.out.println("");
}
System.out.print("Primes:");for (int n = 1; n <= 63; n++)
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if (is_prime(n))System.out.printf(" %d", n);
System.out.println('\n');}
static void coef(int n){
int i, j;
if (n < 0 || n > 63) System.exit(0); // gracefully deal with range issue
for (c[i=0] = 1l; i < n; c[0] = -c[0], i++)for (c[1 + (j=i)] = 1l; j > 0; j--)
c[j] = c[j-1] - c[j];}
static boolean is_prime(int n){
int i;
coef(n);c[0] += 1;c[i=n] -= 1;
while (i-- != 0 && (c[i] % n) == 0);
return i < 0;}
static void show(int n){
do {System.out.print("+" + c[n] + "x^"+ n);
}while (n-- != 0);}
}
Output:
(x-1)^0 = +1x^0(x-1)^1 = +1x^1+-1x^0(x-1)^2 = +1x^2+-2x^1+1x^0(x-1)^3 = +1x^3+-3x^2+3x^1+-1x^0(x-1)^4 = +1x^4+-4x^3+6x^2+-4x^1+1x^0(x-1)^5 = +1x^5+-5x^4+10x^3+-10x^2+5x^1+-1x^0(x-1)^6 = +1x^6+-6x^5+15x^4+-20x^3+15x^2+-6x^1+1x^0(x-1)^7 = +1x^7+-7x^6+21x^5+-35x^4+35x^3+-21x^2+7x^1+-1x^0(x-1)^8 = +1x^8+-8x^7+28x^6+-56x^5+70x^4+-56x^3+28x^2+-8x^1+1x^0(x-1)^9 = +1x^9+-9x^8+36x^7+-84x^6+126x^5+-126x^4+84x^3+-36x^2+9x^1+-1x^0Primes: 1 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61
JavaScript
Translation of: CoffeeScript
var i, p, pascal, primerow, primes, show, _i;
pascal = function() {var a;
a = [];return function() {var b, i;if (a.length === 0) {return a = [1];
} else { b = (function() {
var _i, _ref, _results; _results = [];
for (i = _i = 0, _ref = a.length - 1; 0 <= _ref ? _i < _ref : _i > _ref; i = 0 <= _ref ? ++_i : --_i) {
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_results.push(a[i] + a[i + 1]);}return _results;
})();return a = [1].concat(b).concat([1]);
}};
};
show = function(a) {var degree, i, sgn, show_x, str, _i, _ref;
show_x = function(e) {switch (e) {case 0:return "";
case 1:return "x";
default:return "x^" + e;
}};
degree = a.length - 1; str = "(x - 1)^" + degree + " ="; sgn = 1;for (i = _i = 0, _ref = a.length; 0 <= _ref ? _i < _ref : _i > _ref; i = 0 <= _ref ? ++_i : --_i) {
str += ' ' + (sgn > 0 ? "+" : "-") + ' ' + a[i] + show_x(degree - i); sgn = -sgn;}return str;
};
primerow = function(row) {var degree;
degree = row.length - 1;return row.slice(1, degree).every(function(x) {return x % degree === 0;
});};
p = pascal();
for (i = _i = 0; _i <= 7; i = ++_i) { console.log(show(p()));}
p = pascal();
p();
p();
primes = (function() {var _j, _results;
_results = [];for (i = _j = 1; _j <= 49; i = ++_j) {if (primerow(p())) {
_results.push(i + 1);}
}return _results;
})();
console.log("");
console.log("The primes upto 50 are: " + primes);
Output:
(x - 1)^0 = + 1(x - 1)^1 = + 1x - 1(x - 1)^2 = + 1x^2 - 2x + 1(x - 1)^3 = + 1x^3 - 3x^2 + 3x - 1(x - 1)^4 = + 1x^4 - 4x^3 + 6x^2 - 4x + 1(x - 1)^5 = + 1x^5 - 5x^4 + 10x^3 - 10x^2 + 5x - 1(x - 1)^6 = + 1x^6 - 6x^5 + 15x^4 - 20x^3 + 15x^2 - 6x + 1
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(x - 1)^7 = + 1x^7 - 7x^6 + 21x^5 - 35x^4 + 35x^3 - 21x^2 + 7x - 1
The primes upto 50 are: 2,3,5,7,11,13,17,19,23,29,31,37,41,43,47
Reviewed (ES6):
function pascal(n) {var cs = []; if (n) while (n--) coef(); return coeffunction coef() {
if (cs.length === 0) return cs = [1];for (var t=[1,1], i=cs.length-1; i; i-=1) t.splice( 1, 0, cs[i-1]+cs[i] ); return cs = t
}}
function show(cs) {for (var s='', sgn=true, i=0, deg=cs.length-1; i<=deg; sgn=!sgn, i+=1) {
s += ' ' + (sgn ? '+' : '-') + cs[i] + (e => e==0 ? '' : e==1 ? 'x' : 'x<sup>' + e + '</sup>')(deg-i)}return '(x-1)<sup>' + deg + '</sup> =' + s;
}
function isPrime(cs) {var deg=cs.length-1; return cs.slice(1, deg).every( function(c) { return c % deg === 0 } )
}
var coef=pascal(); for (var i=0; i<=7; i+=1) document.write(show(coef()), '<br>')
document.write('<br>Primes: ');for (var coef=pascal(2), n=2; n<=50; n+=1) if (isPrime(coef())) document.write(' ', n)
Output:
(x-1)0 = +1
(x-1)1 = +1x -1
(x-1)2 = +1x2 -2x +1
(x-1)3 = +1x3 -3x2 +3x -1
(x-1)4 = +1x4 -4x3 +6x2 -4x +1
(x-1)5 = +1x5 -5x4 +10x3 -10x2 +5x -1
(x-1)6 = +1x6 -6x5 +15x4 -20x3 +15x2 -6x +1
(x-1)7 = +1x7 -7x6 +21x5 -35x4 +35x3 -21x2 +7x -1
Primes: 2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47
Translation of: C
function coef(n) {for (var c=[1], i=0; i<n; c[0]=-c[0], i+=1) {
c[i+1]=1; for (var j=i; j; j-=1) c[j] = c[j-1]-c[j]}return c
}
function show(cs) {var s='', n=cs.length-1do s += (cs[n]>0 ? ' +' : ' ') + cs[n] + (n==0 ? '' : n==1 ? 'x' :'x<sup>'+n+'</sup>'); while (n--)return s
}
function isPrime(n) {var cs=coef(n), i=n-1; while (i-- && cs[i]%n == 0);return i < 1
}
for (var n=0; n<=7; n++) document.write('(x-1)<sup>',n,'</sup> = ', show(coef(n)), '<br>')
document.write('<br>Primes: ');for (var n=2; n<=50; n++) if (isPrime(n)) document.write(' ', n)
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Output:
(x-1)0 = +1
(x-1)1 = +1x -1
(x-1)2 = +1x2 -2x +1
(x-1)3 = +1x3 -3x2 +3x -1
(x-1)4 = +1x4 -4x3 +6x2 -4x +1
(x-1)5 = +1x5 -5x4 +10x3 -10x2 +5x -1
(x-1)6 = +1x6 -6x5 +15x4 -20x3 +15x2 -6x +1
(x-1)7 = +1x7 -7x6 +21x5 -35x4 +35x3 -21x2 +7x -1
Primes: 2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47
jq
Works with: jq version 1.5rc1
In the #Prolog section of this page, it is shown how the symmetry of rows in a Pascal triangle canbe used to yield a more efficient test of primality than is apparently envisioned by the problemstatement. The key concept is the "OptPascal row", which is just the longest non-decreasingsequence of the corresponding Pascal row. In this article, the focus will therefore be on OptPascalrows.
NOTE: jq uses IEEE 754 64-bit numbers and thus if builtin arithmetic is used, is_prime will onlybe accurate up to 96 by this method because of loss of precision. The program below, however,can easily be adapted to use a BigInt library such as the one at https://github.com/joelpurra/jq-bigint
# add_pairs is a helper function for optpascal/0# Input: an OptPascal array# Output: the next OptPascal array (obtained by adding adjacent items, # but if the last two items are unequal, then their sum is repeated)def add_pairs: if length <= 1 then . elif length == 2 then (.[0] + .[1]) as $S | if (.[0] == .[1]) then [$S] else [$S,$S] end else [.[0] + .[1]] + (.[1:]|add_pairs) end;
# Input: an OptPascal row# Output: the next OptPascalRowdef next_optpascal: [1] + add_pairs;
# generate a stream of OptPascal arrays, beginning with []def optpascals: [] | recurse(next_optpascal);
# generate a stream of Pascal arraysdef pascals: # pascalize takes as input an OptPascal array and produces # the corresponding Pascal array; # if the input ends in a pair, then peel it off before reversing it. def pascalize: . + ((if .[-2] == .[-1] then .[0:-2] else .[0:-1] end) | reverse);
optpascals | pascalize;
# Input: integer n# Output: the n-th Pascal rowdef pascal: nth(.; pascals);
def optpascal: nth(.; optpascals);
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Task 1: "A method to generate the coefficients of (x-1)^p"
def coefficients: def alternate_signs: . as $in | reduce range(0; length) as $i ([]; . + [$in[$i] * (if $i % 2 == 0 then 1 else -1 end )]); (.+1) | pascal | alternate_signs;
Task 2: "Show here the polynomial expansions of (x − 1)^p for p in the range 0 to at least 7,inclusive."
range(0;8) | "Coefficient for (x - 1)^\(.): \(coefficients)"
Output:
Coefficients for (x - 1)^0: [1]Coefficients for (x - 1)^1: [1,-1]Coefficients for (x - 1)^2: [1,-2,1]Coefficients for (x - 1)^3: [1,-3,3,-1]Coefficients for (x - 1)^4: [1,-4,6,-4,1]Coefficients for (x - 1)^5: [1,-5,10,-10,5,-1]Coefficients for (x - 1)^6: [1,-6,15,-20,15,-6,1]Coefficients for (x - 1)^7: [1,-7,21,-35,35,-21,7,-1]
Task 3: Prime Number Test
For brevity, we show here only the relatively efficient solution based on optpascal/0:
def is_prime: . as $N | if . < 2 then false else (1+.) | optpascal | all( .[2:][]; . % $N == 0 ) end;
Task 4: "Use your AKS test to generate a list of all primes under 35."
range(0;36) | select(is_prime)
Output:
235711131719232931
Task 5: "As a stretch goal, generate all primes under 50."
[range(0;50) | select(is_prime)]
Output:
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[2,3,5,7,11,13,17,19,23,29,31,37,41,43,47]
Julia
Task 1
function polycoefs(n::Int64) pc = typeof(n)[] if n < 0 return pc end sgn = one(n) for k in n:-1:0 push!(pc, sgn*binomial(n, k)) sgn = -sgn end return pcend
Perhaps this should be done with a comprehension, but properly accounting for the sign is trickyin that case.
Task 2
function stringpoly(n::Int64) if n < 0 return "" end st = @sprintf "(x - 1)^{%d} & = & " n for (i, c) in enumerate(polycoefs(n)) if i == 1 op = "" ac = c elseif c < 0 op = "-" ac = abs(c) else op = "+" ac = abs(c) end p = n + 1 - i if p == 0 st *= @sprintf " %s %d\\\\" op ac elseif ac == 1 st *= @sprintf " %s x^{%d}" op p else st *= @sprintf " %s %dx^{%d}" op ac p end end return stend
Of course this could be simpler, but this produces a nice payoff in typeset equations that do oninclude extraneous characters (leading pluses and coefficients of 1).
Task 3
function isaksprime(n::Int64) if n < 2
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return false end for c in polycoefs(n)[2:(end-1)] if c%n != 0 return false end end return trueend
Task 4
println("<math>")println("\\begin{array}{lcl}")for i in 0:10 println(stringpoly(i))endprintln("\\end{array}")println("</math>\n")
L = 50print("AKS primes less than ", L, ": ")sep = ""for i in 1:L if isaksprime(i) print(sep, i) sep = ", " endendprintln()
Output:
AKS primes less than 50: 2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47
Maple
Maple handles algebraic manipulation of polynomials natively.
> for xpr in seq( expand( (x-1)^p ), p = 0 .. 7 ) do print( xpr ) end: 1
x - 1
2
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x - 2 x + 1
3 2 x - 3 x + 3 x - 1
4 3 2 x - 4 x + 6 x - 4 x + 1
5 4 3 2 x - 5 x + 10 x - 10 x + 5 x - 1
6 5 4 3 2 x - 6 x + 15 x - 20 x + 15 x - 6 x + 1
7 6 5 4 3 2 x - 7 x + 21 x - 35 x + 35 x - 21 x + 7 x - 1
To implement the primality test, we write the following procedure that uses the (built-in)polynomial expansion to generate a list of coefficients of the expanded polynomial.
polc := p -> [coeffs]( expand( (x-1)^p - (x^p-1) ) ):
Use polc to implement prime? which does the primality test.
prime? := n -> n > 1 and {op}( map( modp, polc( n ), n ) ) = {0}
Of course, rather than calling polc, we can inline it, just for the sake of making the whole thing aone-liner (while adding argument type-checking for good measure):
prime? := (n::posint) -> n > 1 and {op}( map( modp, [coeffs]( expand( (x-1)^n - (x^n-1) ) ), n ) ) = {0}
This agrees with the built-in primality test isprime:
> evalb( seq( prime?(i), i = 1 .. 1000 ) = seq( isprime( i ), i = 1 .. 1000 ) ); true
Use prime? with the built-in Maple select procedure to pick off the primes up to 50:
> select( prime?, [seq](1..50) ); [2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47]
Mathematica / Wolfram Language
Algebraic manipulation is built into Mathematica, so there's no need to create a function to do(x-1)^p
Print["powers of (x-1)"](x - 1)^( Range[0, 7]) // Expand // TableForm Print["primes under 50"]poly[p_] := (x - 1)^p - (x^p - 1) // Expand;coefflist[p_Integer] := Coefficient[poly[p], x, #] & /@ Range[0, p - 1];AKSPrimeQ[p_Integer] := (Mod[coefflist[p] , p] // Union) == {0};
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Select[Range[1, 50], AKSPrimeQ]
Output:
powers of (x-1)1-1+x1-2 x+x^2-1+3 x-3 x^2+x^31-4 x+6 x^2-4 x^3+x^4-1+5 x-10 x^2+10 x^3-5 x^4+x^51-6 x+15 x^2-20 x^3+15 x^4-6 x^5+x^6-1+7 x-21 x^2+35 x^3-35 x^4+21 x^5-7 x^6+x^7
primes under 50{1, 2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47}
Oforth
func: nextCoef(prev) { | i | ListBuffer new dup add(0) prev size 1 - loop: i [ dup add(prev at(i) prev at(i 1 +) - ) ] dup add(0)}func: coefs(n) { [ 0, 1, 0 ] #nextCoef times(n) extract(2, n 2 + ) }func: isPrime(n) { coefs(n) extract(2, n) conform(#[n mod 0 == ]) }
func: aks{| i | 0 10 for: i [ System.Out "(x-1)^" << i << " = " << coefs(i) << cr ] 50 seq filter(#isPrime) apply(#[ print " " print ]) printcr}
Output:
(x-1)^0 = [1](x-1)^1 = [-1, 1](x-1)^2 = [1, -2, 1](x-1)^3 = [-1, 3, -3, 1](x-1)^4 = [1, -4, 6, -4, 1](x-1)^5 = [-1, 5, -10, 10, -5, 1](x-1)^6 = [1, -6, 15, -20, 15, -6, 1](x-1)^7 = [-1, 7, -21, 35, -35, 21, -7, 1](x-1)^8 = [1, -8, 28, -56, 70, -56, 28, -8, 1](x-1)^9 = [-1, 9, -36, 84, -126, 126, -84, 36, -9, 1](x-1)^10 = [1, -10, 45, -120, 210, -252, 210, -120, 45, -10, 1]2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
PARI/GP
getPoly(n)=('x-1)^n;vector(8,n,getPoly(n-1))AKS_slow(n)=my(P=getPoly(n));for(i=1,n-1,if(polcoeff(P,i)%n,return(0))); 1;AKS(n)=my(X=('x-1)*Mod(1,n));X^n=='x^n-1;select(AKS, [1..50])
Output:
[1, x - 1, x^2 - 2*x + 1, x^3 - 3*x^2 + 3*x - 1, x^4 - 4*x^3 + 6*x^2 - 4*x + 1, x^5 - 5*x^4 + 10*x^3 - 10*x^2 + 5*x - 1, x^6 - 6*x^5 + 15*x^4
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[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47]
Pascal
tested wth freepascal
const pasTriMax = 61;type tpasTri =array[0..pasTriMax] of UInt64;
var pasTri : tpasTri;
procedure pastriangle(n:longInt);//calculate the n'th line 0.. middlevar j,k: longWord;begin pasTri[0] := 1; j := 1;while (j<=n) dobegin
inc(j); k := j SHR 1; pasTri[k] :=pasTri[k-1];
For k := k downto 1 do inc(pasTri[k],pasTri[k-1]);end;
end;
function CheckPrime(n:longWord):boolean;var i : integer; res: boolean;Begin
IF n > pasTriMax thenbeginwriteln(n,' is out of range ');
EXIT;end;
pastriangle(n); res := true; i := n shr 1;while res AND (i >1) doBegin
res := res AND(pasTri[i] mod n = 0); dec(i);end;
CheckPrime := res;end;
procedure ExpandPoly(n:longWord);const Vz :array[boolean] of char = ('+','-');var j,k: longWord; bVz: Boolean;BeginIF n < 2 thenBeginIF n = 0 thenwriteln('(x-1)^0 = 1')
elsewriteln('(x-1)^1 = x-1');
EXIT;end;
IF n > pasTriMax thenbegin
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writeln(n,' is out of range '); EXIT;end;
pastriangle(n);write('(x-1)^',n,' = ');
k := 0; j := n; bVz := false;repeatIF j=n thenwrite('x^',j)
elsewrite(Vz[bVz],pasTri[k],'*x^',j);
bVz := Not(bVz); inc(k); dec(j);until k>= j;
k := j;while k > 0 doBeginIF j <> 1 thenwrite(Vz[bVz],pasTri[k],'*x^',j)
elsewrite(Vz[bVz],pasTri[k],'*x');
bVz := Not(bVz); dec(k); dec(j);end;write(Vz[bVz],pasTri[0]);writeln;
end;
var n: LongWord;BeginFor n := 0 to 9 do
ExpandPoly(n);For n := 2 to pasTriMax doIF CheckPrime(n) thenwrite(n:3);
end.
output
(x-1)^0 = 1
(x-1)^1 = x-1
(x-1)^2 = x^2-2*x+1
(x-1)^3 = x^3-3*x^2+3*x-1
(x-1)^4 = x^4-4*x^3+6*x^2-4*x+1
(x-1)^5 = x^5-5*x^4+10*x^3-10*x^2+5*x-1
(x-1)^6 = x^6-6*x^5+15*x^4-20*x^3+15*x^2-6*x+1
(x-1)^7 = x^7-7*x^6+21*x^5-35*x^4+35*x^3-21*x^2+7*x-1
(x-1)^8 = x^8-8*x^7+28*x^6-56*x^5+70*x^4-56*x^3+28*x^2-8*x+1
(x-1)^9 = x^9-9*x^8+36*x^7-84*x^6+126*x^5-126*x^4+84*x^3-36*x^2+9*x-1
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61
Perl
use strict;
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use warnings;# Select one of these lines. Math::BigInt is in core, but quite slow.use Math::BigInt; sub binomial { Math::BigInt->new(shift)->bnok(shift) }# use Math::Pari "binomial";# use ntheory "binomial";
sub binprime {my $p = shift;return 0 unless $p >= 2;# binomial is symmetric, so only test half the termsfor (1 .. ($p>>1)) { return 0 if binomial($p,$_) % $p }1;
}sub coef { # For prettier printingmy($n,$e) = @_;return $n unless $e;$n = "" if $n==1;$e==1 ? "${n}x" : "${n}x^$e";
}sub binpoly {my $p = shift;join(" ", coef(1,$p),
map { join("",("+","-")[($p-$_)&1]," ",coef(binomial($p,$_),$_)) }reverse 0..$p-1 );
}print "expansions of (x-1)^p:\n";print binpoly($_),"\n" for 0..9;print "Primes to 80: [", join(",", grep { binprime($_) } 2..80), "]\n";
Output:
expansions of (x-1)^p:1x - 1x^2 - 2x + 1x^3 - 3x^2 + 3x - 1x^4 - 4x^3 + 6x^2 - 4x + 1x^5 - 5x^4 + 10x^3 - 10x^2 + 5x - 1x^6 - 6x^5 + 15x^4 - 20x^3 + 15x^2 - 6x + 1x^7 - 7x^6 + 21x^5 - 35x^4 + 35x^3 - 21x^2 + 7x - 1x^8 - 8x^7 + 28x^6 - 56x^5 + 70x^4 - 56x^3 + 28x^2 - 8x + 1x^9 - 9x^8 + 36x^7 - 84x^6 + 126x^5 - 126x^4 + 84x^3 - 36x^2 + 9x - 1Primes to 80: [2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79]
Real AKS
The ntheory module has implementations of the full AKS algorithm in Perl, C, and C+GMP. This isvastly faster than the method used in this task and is polynomial time, but like all current AKSimplementations is still much slower than other methods such as BPSW, APR-CL, and ECPP.
Library: ntheory
use ntheory ":all";# Uncomment next line to see the r and s values used. Set to 2 for more detail.# prime_set_config(verbose => 1);say join(" ", grep { is_aks_prime($_) } 1_000_000_000 .. 1_000_000_100);
Output:
1000000007 1000000009 1000000021 1000000033 1000000087 1000000093 1000000097
Perl 6
constant expansions = [1], [1,-1], -> @prior { [@prior,0 Z- 0,@prior] } ... *;
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sub polyprime($p where 2..*) { so expansions[$p].[1 ..^ */2].all %% $p }
The expansions are generated similarly to how most FP languages generate sequences thatresemble Pascal's triangle, using a zipwith meta-operator (Z) with subtraction, applied betweentwo lists that add a 0 on either end to the prior list. Here we define a constant infinite sequenceusing the ... sequence operator with a "whatever" endpoint. In fact, the second term [1,-1] couldhave been generated from the first term, but we put it in there for documentation so the readercan see what direction things are going.
The polyprime function pretty much reads like the original description. Is it "so" that the p'thexpansion's coefficients are all divisible by p? The .[1 ..^ */2] slice is done simply to weed outdivisions by 1 or by factors we've already tested (since the coefficients are symmetrical in termsof divisibility). If we wanted to write polyprime even more idiomatically, we could have made itanother infinite constant list that is just a mapping of the first list, but we decided that would justbe showing off. :-)
Showing the expansions:
say ' p: (x-1)ᵖ';say '-----------';
sub super ($n) {$n.trans: '0123456789'
=> '⁰¹²³⁴⁵⁶⁷⁸⁹';}
for ^13 -> $d {say $d.fmt('%2i: '), (
expansions[$d].kv.map: -> $i, $n {my $p = $d - $i;[~] gather {
take < + - >[$n < 0] ~ ' ' unless $p == $d; take $n.abs unless $p == $d > 0; take 'x' if $p > 0; take super $p - $i if $p > 1;
}}
)}
Output:
p: (x-1)ᵖ----------- 0: 1 1: x - 1 2: x² - 2x + 1 3: x³ - 3x² + 3x - 1 4: x⁴ - 4x³ + 6x² - 4x + 1 5: x⁵ - 5x⁴ + 10x³ - 10x² + 5x - 1 6: x⁶ - 6x⁵ + 15x⁴ - 20x³ + 15x² - 6x + 1 7: x⁷ - 7x⁶ + 21x⁵ - 35x⁴ + 35x³ - 21x² + 7x - 1 8: x⁸ - 8x⁷ + 28x⁶ - 56x⁵ + 70x⁴ - 56x³ + 28x² - 8x + 1 9: x⁹ - 9x⁸ + 36x⁷ - 84x⁶ + 126x⁵ - 126x⁴ + 84x³ - 36x² + 9x - 110: x¹⁰ - 10x⁹ + 45x⁸ - 120x⁷ + 210x⁶ - 252x⁵ + 210x⁴ - 120x³ + 45x² - 10x + 111: x¹¹ - 11x¹⁰ + 55x⁹ - 165x⁸ + 330x⁷ - 462x⁶ + 462x⁵ - 330x⁴ + 165x³ - 55x² + 11x - 112: x¹² - 12x¹¹ + 66x¹⁰ - 220x⁹ + 495x⁸ - 792x⁷ + 924x⁶ - 792x⁵ + 495x⁴ - 220x³ + 66x² - 12x + 1
And testing the function:
print "\nPrimes up to 100:\n { grep &polyprime, 2..100 }\n";
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Output:
Primes up to 100: 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97
Phix
-- Does not work for primes above 53, which is actually beyond the original task anyway.-- Translated from the C version, just about everything is (working) out-by-1, what fun.
sequence c = repeat(0,100)
procedure coef(integer n)-- out-by-1, ie coef(1)==^0, coef(2)==^1, coef(3)==^2 etc. c[n] = 1 for i=n-1 to 2 by -1 do c[i] = c[i]+c[i-1] end forend procedure
function is_prime(integer n) coef(n+1); -- (I said it was out-by-1) for i=2 to n-1 do -- (technically "to n" is more correct) if remainder(c[i],n)!=0 then return 0 end if end for return 1end function
procedure show(integer n)-- (As per coef, this is (working) out-by-1)object ci for i=n to 1 by -1 do ci = c[i] if ci=1 then if remainder(n-i,2)=0 then if i=1 then if n=1 then ci = "1" else ci = "+1" end if else ci = "" end if else ci = "-1" end if else if remainder(n-i,2)=0 then ci = sprintf("+%d",ci) else ci = sprintf("-%d",ci) end if end if if i=1 then -- ie ^0 printf(1,"%s",{ci}) elsif i=2 then -- ie ^1 printf(1,"%sx",{ci}) else printf(1,"%sx^%d",{ci,i-1}) end if end forend procedure
procedure AKS_test_for_primes() for n=1 to 10 do -- (0 to 9 really) coef(n); printf(1,"(x-1)^%d = ", n-1); show(n);
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puts(1,'\n'); end for
puts(1,"\nprimes (<=53):");-- coef(2); -- (needed to reset c, if we want to avoid saying 1 is prime...) c[2] = 1 -- (this manages "", which is all that call did anyway...) for n = 2 to 53 do if is_prime(n) then printf(1," %d", n); end if end for puts(1,'\n'); if getc(0) then end ifend procedure
AKS_test_for_primes()
Output:
(x-1)^0 = 1(x-1)^1 = x-1(x-1)^2 = x^2-2x+1(x-1)^3 = x^3-3x^2+3x-1(x-1)^4 = x^4-4x^3+6x^2-4x+1(x-1)^5 = x^5-5x^4+10x^3-10x^2+5x-1(x-1)^6 = x^6-6x^5+15x^4-20x^3+15x^2-6x+1(x-1)^7 = x^7-7x^6+21x^5-35x^4+35x^3-21x^2+7x-1(x-1)^8 = x^8-8x^7+28x^6-56x^5+70x^4-56x^3+28x^2-8x+1(x-1)^9 = x^9-9x^8+36x^7-84x^6+126x^5-126x^4+84x^3-36x^2+9x-1
primes (<=53): 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53
PicoLisp
(de pascal (N) (let D 1 (make (for X (inc N) (link D) (setq D (*/ D (- (inc N) X) (- X)) ) ) ) ) )
(for (X 0 (> 10 X) (inc X)) (println X '-> (pascal X) ) )
(println (filter '((X) (fully '((Y) (=0 (% Y X))) (cdr (head -1 (pascal X))) ) ) (range 2 50) ) )
(bye)
Output:
0 -> (1)1 -> (1 -1)2 -> (1 -2 1)3 -> (1 -3 3 -1)4 -> (1 -4 6 -4 1)5 -> (1 -5 10 -10 5 -1)6 -> (1 -6 15 -20 15 -6 1)7 -> (1 -7 21 -35 35 -21 7 -1)8 -> (1 -8 28 -56 70 -56 28 -8 1)
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9 -> (1 -9 36 -84 126 -126 84 -36 9 -1)(2 3 5 7 11 13 17 19 23 29 31 37 41 43 47)
Prolog
Prolog(ue)
The theorem as stated ties together two elementary concepts in mathematics: prime numbers andthe Pascal triangle. The simplicity of the connection can be expressed directly in Prolog by thefollowing prime number generator:
prime(P) :- pascal([1,P|Xs]), append(Xs, [1], Rest), forall( member(X,Xs), 0 is X mod P).
where pascal/1 is a generator of rows of the Pascal triangle, for example as defined below; theother predicates used above are standard.
This solution to the Rosetta Code problems will accordingly focus on the Pascal triangle, but toillustrate a number of points, we shall exploit its symmetry by representing each of its rows bythe longest initial non-decreasing segment of that row, as illustrated in the third column of thefollowing table:
Row Pascal Row optpascal1 1 [1]2 1 1 [1, 1]3 1 2 1 [1, 2]4 1 3 3 1 [1, 3, 3]
We shall refer to this condensed representation of a row as an "optpascal list". Using it, we cansimplify and improve the above prime number generator by defining it as follows:
prime(N) :- optpascal([1,N|Xs]), forall( member(X,Xs), 0 is X mod N).
Using SWI-Prolog without modifying any of the memory management parameters, this primenumber generator was used to generate all primes up to and including 75,659.
Since Pascal triangles are the foundation of our approach to addressing the specific Rosetta Codeproblems, we begin by defining the generator pascal/2 that is required by the first problem, butwe do so by defining it in terms of an efficient generator, optpascal/1.
Pascal Triangle Generator
% To generate the n-th row of a Pascal triangle% pascal(+N, Row)pascal(0, [1]).pascal(N, Row) :- N > 0, optpascal( [1, N|Xs] ),!,
pascalize( [1, N|Xs], Row ).
pascalize( Opt, Row ) :-% if Opt ends in a pair, then peel off the pair:
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( append(X, [R,R], Opt) -> true ; append(X, [R], Opt) ), reverse(X, Rs), append( Opt, Rs, Row ).
% optpascal(-X) generates optpascal lines:optpascal(X) :- optpascal_successor( [], X).
% optpascal_successor(+P, -Q) is true if Q is an optpascal list beneath the optpascal list P:optpascal_successor(P, Q) :- optpascal(P, NextP),(Q = NextP ; optpascal_successor(NextP, Q)).
% optpascal(+Row, NextRow) is true if Row and NextRow are adjacent rows in the Pascal triangle.% optpascal(+Row, NextRow) where the optpascal representation is usedoptpascal(X, [1|Y]) :- add_pairs(X, Y).
% add_pairs(+OptPascal, NextOptPascal) is a helper function for optpascal/2.% Given one OptPascal list, it generates the next by adding adjacent% items, but if the last two items are unequal, then their sum is% repeated. This is intended to be a deterministic predicate, and to% avoid a probable compiler limitation, we therefore use one cut.add_pairs([], []).add_pairs([X], [X]).add_pairs([X,Y], Ans) :- S is X + Y,(X = Y -> Ans=[S] ; Ans=[S,S]),!. % To overcome potential limitation of compiler
add_pairs( [X1, X2, X3|Xs], [S|Ys]) :- S is X1 + X2, add_pairs( [X2, X3|Xs], Ys).
Solutions
Solutions with output from SWI-Prolog:
%%% Task 1: "A method to generate the coefficients of (1-X)^p"
coefficients(N, Coefficients) :- pascal(N, X), alternate_signs(X, Coefficients).
alternate_signs( [], [] ).alternate_signs( [A], [A] ).alternate_signs( [A,B | X], [A, MB | Y] ) :- MB is -B, alternate_signs(X,Y).
%%% Task 2. "Show here the polynomial expansions of (x − 1)p for p in the range 0 to at least 7, inclusive."
coefficients(Coefficients) :- optpascal( Opt), pascalize( Opt, Row ), alternate_signs(Row, Coefficients).
% As required by the problem statement, but necessarily very inefficient::- between(0, 7, N), coefficients(N, Coefficients), writeln(Coefficients), fail ; true.
[1][1,-1][1,-2,1][1,-3,3,-1][1,-4,6,-4,1][1,-5,10,-10,5,-1][1,-6,15,-20,15,-6,1][1,-7,21,-35,35,-21,7,-1]
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The following would be more efficient because backtracking saves recomputation:
:- coefficients(Coefficients), writeln(Coefficients), Coefficients = [_,N|_], N = -7.
%%% Task 3. Use the previous function in creating [sic]%%% another function that when given p returns whether p is prime%%% using the AKS test.
% Even for testing whether a given number, N, is prime, % this approach is inefficient, but here is a Prolog implementation:
prime_test_per_requirements(N) :- coefficients(N, [1|Coefficients]), append(Cs, [_], Coefficients), forall( member(C, Cs), 0 is C mod N).
The following is more efficient (because it relies on optpascal lists rather than the full array ofcoefficients), and more flexible (because it can be used to generate primes without requiringrecomputation):
prime(N) :- optpascal([1,N|Xs]), forall( member(X,Xs), 0 is X mod N).
%%% Task 4. Use your AKS test to generate a list of all primes under 35.
:- prime(N), (N < 35 -> write(N), write(' '), fail ; nl).
% Output: 1 2 3 5 7 11 13 17 19 23 29 31
%%% Task 5. As a stretch goal, generate all primes under 50.
:- prime(N), (N < 50 -> write(N), write(' '), fail ; nl).
% Output: 1 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
PureBasic
EnableExplicitDefine vzr.b = -1, vzc.b = ~vzr, nMAX.i = 10, n , k
Procedure coeff(nRow.i, Array pd.i(2))Define.i n, kFor n=1 To nRowFor k=0 To nIf k=0 Or k=n : pd(n,k)=1 : Continue : EndIf
pd(n,k)=pd(n-1,k-1)+pd(n-1,k)Next
NextEndProcedure
Procedure.b isPrime(n.i, Array pd.i(2))Define.i mFor m=1 To n-1If Not pd(n,m) % n = 0 : ProcedureReturn #False : EndIf
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NextProcedureReturn #True
EndProcedure
Dim pd.i(nMAX,nMAX)pd(0,0)=1 : coeff(nMAX, pd())OpenConsole()
For n=0 To nMAXPrint(RSet(Str(n),3,Chr(32))+": ")If vzr : Print("+") : Else : Print("-") : EndIfFor k=0 To n If k>0 : If vzc : Print("+") : Else : Print("-") : EndIf : vzc = ~vzc : EndIfPrint(RSet(Str(pd(n,k)),3,Chr(32))+Space(3))
NextPrintN("")
vzr = ~vzr : vzc = ~vzr NextPrintN("")
nMAX=50 : Dim pd.i(nMAX,nMAX)Print("Primes n<=50 : ") : coeff(nMAX, pd())For n=2 To 50If isPrime(n,pd()) : Print(Str(n)+Space(2)) : EndIf
NextInput()
Output:
0: + 1 1: - 1 + 1 2: + 1 - 2 + 1 3: - 1 + 3 - 3 + 1 4: + 1 - 4 + 6 - 4 + 1 5: - 1 + 5 - 10 + 10 - 5 + 1 6: + 1 - 6 + 15 - 20 + 15 - 6 + 1 7: - 1 + 7 - 21 + 35 - 35 + 21 - 7 + 1 8: + 1 - 8 + 28 - 56 + 70 - 56 + 28 - 8 + 1 9: - 1 + 9 - 36 + 84 -126 +126 - 84 + 36 - 9 + 1 10: + 1 - 10 + 45 -120 +210 -252 +210 -120 + 45 - 10 + 1
Primes n<=50 : 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
Python
def expand_x_1(n): # This version uses a generator and thus less computations c =1
for i in range(n/2+1): c = c*(n-i)/(i+1)
yield c
def aks(p):if p==2:
return True
for i in expand_x_1(p):if i % p:
# we stop without computing all possible solutionsreturn False
return True
def expand_x_1(p): ex = [1]
for i in range(p): ex.append(ex[-1] * -(p-i) / (i+1))
return ex[::-1]
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def aks_test(p):if p < 2: return False
ex = expand_x_1(p) ex[0] += 1
return not any(mult % p for mult in ex[0:-1])
print('# p: (x-1)^p for small p')for p in range(12):
print('%3i: %s' % (p, ' '.join('%+i%s' % (e, ('x^%i' % n) if n else '')for n,e in enumerate(expand_x_1(p)))))
print('\n# small primes using the aks test')print([p for p in range(101) if aks_test(p)])
Output:
# p: (x-1)^p for small p 0: +1 1: -1 +1x^1 2: +1 -2x^1 +1x^2 3: -1 +3x^1 -3x^2 +1x^3 4: +1 -4x^1 +6x^2 -4x^3 +1x^4 5: -1 +5x^1 -10x^2 +10x^3 -5x^4 +1x^5 6: +1 -6x^1 +15x^2 -20x^3 +15x^4 -6x^5 +1x^6 7: -1 +7x^1 -21x^2 +35x^3 -35x^4 +21x^5 -7x^6 +1x^7 8: +1 -8x^1 +28x^2 -56x^3 +70x^4 -56x^5 +28x^6 -8x^7 +1x^8 9: -1 +9x^1 -36x^2 +84x^3 -126x^4 +126x^5 -84x^6 +36x^7 -9x^8 +1x^9 10: +1 -10x^1 +45x^2 -120x^3 +210x^4 -252x^5 +210x^6 -120x^7 +45x^8 -10x^9 +1x^10 11: -1 +11x^1 -55x^2 +165x^3 -330x^4 +462x^5 -462x^6 +330x^7 -165x^8 +55x^9 -11x^10 +1x^11
# small primes using the aks test[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97]
Python: Output formatted for wiki
Using a wikitable and math features with the following additional code produces better formattedpolynomial output:
print('''{| class="wikitable" style="text-align:left;"|+ Polynomial Expansions and AKS prime test|-! <math>p</math>! <math>(x-1)^p</math>|-''')for p in range(12):
print('! <math>%i</math>\n| <math>%s</math>\n| %r\n|-' % (p,
' '.join('%s%s' % (('%+i' % e) if (e != 1 or not p or (p and not n) ) else '+',(('x^{%i}' % n) if n > 1 else 'x') if n else '')
for n,e in enumerate(expand_x_1(p))), aks_test(p)))print('|}')
Output:
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Polynomial Expansions and AKS prime test
p (x − 1)p Prime(p)?
0 + 1 False
1 − 1 + x False
2 + 1 − 2x + x2 True
3 − 1 + 3x − 3x2 + x3 True
4 + 1 − 4x + 6x2 − 4x3 + x4 False
5 − 1 + 5x − 10x2 + 10x3 − 5x4 + x5 True
6 + 1 − 6x + 15x2 − 20x3 + 15x4 − 6x5 + x6 False
7 − 1 + 7x − 21x2 + 35x3 − 35x4 + 21x5 − 7x6 + x7 True
8 + 1 − 8x + 28x2 − 56x3 + 70x4 − 56x5 + 28x6 − 8x7 + x8 False
9 − 1 + 9x − 36x2 + 84x3 − 126x4 + 126x5 − 84x6 + 36x7 − 9x8 + x9 False
10 + 1 − 10x + 45x2 − 120x3 + 210x4 − 252x5 + 210x6 − 120x7 + 45x8 − 10x9 +x10 False
11 − 1 + 11x − 55x2 + 165x3 − 330x4 + 462x5 − 462x6 + 330x7 − 165x8 + 55x9
− 11x10 + x11 True
R
Borrowing heavily from Python listing. Optimized for the fact that the vector of the coefficients isa palindrome.
Is.Prime<-function(x){ expand<-function(p){ ex = 1 for (i in 0:(p/2-1)){ ex<-c(ex[1]*(p-i)/(i+1),ex) } return(rev(ex)[-1]) } return(as.logical(min(expand(x)%%x==0))) }
Racket
With copious use of the math/number-theory library...
#lang racket(require math/number-theory)
;; 1. coefficients of expanded polynomial (x-1)^p;; produces a vector because in-vector can provide a start;; and stop (of 1 and p) which allow us to drop the (-1)^p;; and the x^p terms, respectively.;;;; (vector-ref (coefficients p) e) is the coefficient for p^e(define (coefficients p) (for/vector ((e (in-range 0 (add1 p)))) (define sign (expt -1 (- p e))) (* sign (binomial p e))))
;; 2. Show the polynomial expansions from p=0 .. 7 (inclusive)
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;; (it's possible some of these can be merged...)(define (format-coefficient c e leftmost?) (define (format-c.x^e c e) (define +c (abs c)) (match* (+c e) [(_ 0) (format "~a" +c)] [(1 _) (format "x^~a" e)] [(_ _) (format "~ax^~a" +c e)])) (define +/- (if (negative? c) "-" "+")) (define +c.x^e (format-c.x^e c e)) (match* (c e leftmost?) [(0 _ _) ""] [((? negative?) _ #t) (format "-~a" +c.x^e)] [(_ _ #t) +c.x^e] [(_ _ _) (format " ~a ~a" +/- +c.x^e)]))
(define (format-polynomial cs) (define cs-length (sequence-length cs)) (apply string-append (reverse ; convention is to display highest exponent first (for/list ((c cs) (e (in-naturals))) (format-coefficient c e (= e (sub1 cs-length)))))))
(for ((p (in-range 0 (add1 11)))) (printf "p=~a: ~a~%" p (format-polynomial (coefficients p))))
;; 3. AKS primeality test(define (prime?/AKS p) (define cs (coefficients p)) (and (or (= (vector-ref cs 0) -1) ; c_0 = -1 -> c_0 - (-1) = 0 (divides? p 2)) ; c_0 = 1 -> c_0 - (-1) = 2 -> divides? (for/and ((c (in-vector cs 1 p))) (divides? p c))))
;; there is some discussion (see Discussion) about what to do with the perennial "1";; case. This is my way of saying that I'm ignoring it(define lowest-tested-number 2)
;; 4. list of numbers < 35 that are prime (note that 1 is prime;; by the definition of the AKS test for primes):(displayln (for/list ((i (in-range lowest-tested-number 35)) #:when (prime?/AKS i)) i))
;; 5. stretch goal: all prime numbers under 50(displayln (for/list ((i (in-range lowest-tested-number 50)) #:when (prime?/AKS i)) i))(displayln (for/list ((i (in-range lowest-tested-number 100)) #:when (prime?/AKS i)) i))
Output:
p=0: 1p=1: x^1 - 1p=2: x^2 - 2x^1 + 1p=3: x^3 - 3x^2 + 3x^1 - 1p=4: x^4 - 4x^3 + 6x^2 - 4x^1 + 1p=5: x^5 - 5x^4 + 10x^3 - 10x^2 + 5x^1 - 1p=6: x^6 - 6x^5 + 15x^4 - 20x^3 + 15x^2 - 6x^1 + 1p=7: x^7 - 7x^6 + 21x^5 - 35x^4 + 35x^3 - 21x^2 + 7x^1 - 1p=8: x^8 - 8x^7 + 28x^6 - 56x^5 + 70x^4 - 56x^3 + 28x^2 - 8x^1 + 1p=9: x^9 - 9x^8 + 36x^7 - 84x^6 + 126x^5 - 126x^4 + 84x^3 - 36x^2 + 9x^1 - 1p=10: x^10 - 10x^9 + 45x^8 - 120x^7 + 210x^6 - 252x^5 + 210x^4 - 120x^3 + 45x^2 - 10x^1 + 1p=11: x^11 - 11x^10 + 55x^9 - 165x^8 + 330x^7 - 462x^6 + 462x^5 - 330x^4 + 165x^3 - 55x^2 + 11x^1 - 1(2 3 5 7 11 13 17 19 23 29 31)(2 3 5 7 11 13 17 19 23 29 31 37 41 43 47)(2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97)
REXX
version 1
/* REXX ---------------------------------------------------------------
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* 09.02.2014 Walter Pachl* 22.02.2014 WP fix 'accounting' problem (courtesy GS)*--------------------------------------------------------------------*/c.=1Numeric Digits 100limit=200pl=''mmm=0Do p=3 To limit pm1=p-1 c.p.1=1 c.p.p=1Do j=2 To p-1
jm1=j-1 c.p.j=c.pm1.jm1+c.pm1.j mmm=max(mmm,c.p.j)
EndEnd
Say '(x-1)**0 = 1'do i=2 To limit im1=i-1sign='+'
ol='(x-1)^'im1 '='Do j=i to 2 by -1If j=2 Then
term='x 'Else
term='x^'||(j-1)If j=i Then
ol=ol termElse
ol=ol sign c.i.j'*'termsign=translate(sign,'+-','-+')End
If i<10 thenSay ol sign 1
Do j=2 To i-1If c.i.j//(i-1)>0 ThenLeave
EndIf j>i-1 Then
pl=pl (i-1)End
Say ' 'Say 'Primes:' subword(pl,2,27)Say ' ' subword(pl,29)Say 'Largest coefficient:' mmmSay 'This has' length(mmm) 'digits'
Output:
(x-1)**0 = 1(x-1)^1 = x - 1(x-1)^2 = x^2 - 2*x + 1(x-1)^3 = x^3 - 3*x^2 + 3*x - 1(x-1)^4 = x^4 - 4*x^3 + 6*x^2 - 4*x + 1(x-1)^5 = x^5 - 5*x^4 + 10*x^3 - 10*x^2 + 5*x - 1(x-1)^6 = x^6 - 6*x^5 + 15*x^4 - 20*x^3 + 15*x^2 - 6*x + 1(x-1)^7 = x^7 - 7*x^6 + 21*x^5 - 35*x^4 + 35*x^3 - 21*x^2 + 7*x - 1(x-1)^8 = x^8 - 8*x^7 + 28*x^6 - 56*x^5 + 70*x^4 - 56*x^3 + 28*x^2 - 8*x + 1
Primes: 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157 163 167 173 179 181 191 193 197 199Largest coefficient: 45274257328051640582702088538742081937252294837706668420660This has 59 digits
version 2
This REXX version is an optimized version (of version 1) and modified to address each of therequirements.The program determines programmatically the required number of digits (precision) for the large
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coefficients.
/*REXX pgm calculates primes via the Agrawal-Kayal-Saxena (AKS) primality test*/parse arg Z .; if Z=='' then Z=200 /*Z not specified? Then use default.*/OZ=Z; tell=Z<0; Z=abs(Z) /*Is Z negative? Then show expression.*/numeric digits max(9,Z%3) /*define a dynamic # of decimal digits.*/$.0='-'; $.1="+"; @.=1 /*$.x: sign char; default coefficients.*/#= /*define list of prime numbers (so far)*/do p=3 for Z; pm=p-1; pp=p+1 /*PM & PP: used as a coding convenience*/
do m=2 for pp%2-1; mm=m-1 /*calculate coefficients for a power. */ @[email protected] + @.pm.m; h=pp-m /*calculate left side of coefficients*/ @[email protected] /* " right " " " */
end /*m*/ /* [↑] The M DO loop creates both */end /*p*/ /* sides in the same loop, saving */
/* a bunch of execution time. */if tell then say '(x-1)^0: 1' /*possibly display the first expression*/
/* [↓] test for primality by division.*/do n=2 for Z; nh=n%2; d=n-1 /*create expressions; find the primes.*/
do k=3 to nh while @.n.k//d==0 /*are coefficients divisible by N-1 ? */end /*k*/ /* [↑] skip the 1st & 2nd coefficients*/
/* [↓] multiple THEN─IF faster than &s*/if d\==1 then if d\==4 then if k>nh then #=# d /*add number to prime list.*/if \tell then iterate /*Don't tell? Don't show expressions.*/
y='(x-1)^'d": " /*define first part of the expression. */ s=1 /*S: is the sign indicator (-1│+1).*/
do j=n to 2 by -1 /*create the higher powers first. */if j==2 then xp='x' /*if power=1, then don't show the power*/
else xp='x^' || (j-1) /* ··· else show power with ^ */if j==n then y=y xp /*no sign (+│-) for the 1st expression.*/
else y=y $.s @.n.j'∙'xp /*build the expression with sign (+|-).*/ s=\s /*flip the sign for the next expression*/
end /*j*/ /* [↑] the sign (now) is either 0 │ 1,*//* and is displayed either - │ + */
say y $.s 1 /*just show the first N expressions, */end /*n*/ /* [↑] ··· but only for negative Z. */
say /* [↓] Has Z a leading + ? Then show.*/is="isn't"; if Z==word(. #,words(#)+1) then is='is' /*is or isn't a prime.*/if left(OZ,1)=='+' then say Z is 'prime.' /*tell if OZ has a +. */
else say 'primes:' # /*display prime # list. */say /* [↓] size of big 'un.*/say 'Found ' words(#) ' primes and the largest coefficient has' ,
length(@.pm.h) "decimal digits." /*stick a fork in it, we're all done. */
output for requirement #2, showing twenty expressions using as input: -20
(x-1)^0: 1(x-1)^1: x - 1(x-1)^2: x^2 - 2∙x + 1(x-1)^3: x^3 - 3∙x^2 + 3∙x - 1(x-1)^4: x^4 - 4∙x^3 + 6∙x^2 - 4∙x + 1(x-1)^5: x^5 - 5∙x^4 + 10∙x^3 - 10∙x^2 + 5∙x - 1(x-1)^6: x^6 - 6∙x^5 + 15∙x^4 - 20∙x^3 + 15∙x^2 - 6∙x + 1(x-1)^7: x^7 - 7∙x^6 + 21∙x^5 - 35∙x^4 + 35∙x^3 - 21∙x^2 + 7∙x - 1(x-1)^8: x^8 - 8∙x^7 + 28∙x^6 - 56∙x^5 + 70∙x^4 - 56∙x^3 + 28∙x^2 - 8∙x + 1(x-1)^9: x^9 - 9∙x^8 + 36∙x^7 - 84∙x^6 + 126∙x^5 - 126∙x^4 + 84∙x^3 - 36∙x^2 + 9∙x - 1(x-1)^10: x^10 - 10∙x^9 + 45∙x^8 - 120∙x^7 + 210∙x^6 - 252∙x^5 + 210∙x^4 - 120∙x^3 + 45∙x^2 - 10∙x + 1(x-1)^11: x^11 - 11∙x^10 + 55∙x^9 - 165∙x^8 + 330∙x^7 - 462∙x^6 + 462∙x^5 - 330∙x^4 + 165∙x^3 - 55∙x^2 + 11∙x - 1(x-1)^12: x^12 - 12∙x^11 + 66∙x^10 - 220∙x^9 + 495∙x^8 - 792∙x^7 + 924∙x^6 - 792∙x^5 + 495∙x^4 - 220∙x^3 + 66∙x^2 - 12∙x + 1(x-1)^13: x^13 - 13∙x^12 + 78∙x^11 - 286∙x^10 + 715∙x^9 - 1287∙x^8 + 1716∙x^7 - 1716∙x^6 + 1287∙x^5 - 715∙x^4 + 286∙x^3 - 78∙x^2 + 13∙x - 1(x-1)^14: x^14 - 14∙x^13 + 91∙x^12 - 364∙x^11 + 1001∙x^10 - 2002∙x^9 + 3003∙x^8 - 3432∙x^7 + 3003∙x^6 - 2002∙x^5 + 1001∙x^4 - 364∙x^3 + 91∙x^(x-1)^15: x^15 - 15∙x^14 + 105∙x^13 - 455∙x^12 + 1365∙x^11 - 3003∙x^10 + 5005∙x^9 - 6435∙x^8 + 6435∙x^7 - 5005∙x^6 + 3003∙x^5 - 1365∙x^4 + 45(x-1)^16: x^16 - 16∙x^15 + 120∙x^14 - 560∙x^13 + 1820∙x^12 - 4368∙x^11 + 8008∙x^10 - 11440∙x^9 + 12870∙x^8 - 11440∙x^7 + 8008∙x^6 - 4368∙x^5 (x-1)^17: x^17 - 17∙x^16 + 136∙x^15 - 680∙x^14 + 2380∙x^13 - 6188∙x^12 + 12376∙x^11 - 19448∙x^10 + 24310∙x^9 - 24310∙x^8 + 19448∙x^7 - 12376∙(x-1)^18: x^18 - 18∙x^17 + 153∙x^16 - 816∙x^15 + 3060∙x^14 - 8568∙x^13 + 18564∙x^12 - 31824∙x^11 + 43758∙x^10 - 48620∙x^9 + 43758∙x^8 - 31824(x-1)^19: x^19 - 19∙x^18 + 171∙x^17 - 969∙x^16 + 3876∙x^15 - 11628∙x^14 + 27132∙x^13 - 50388∙x^12 + 75582∙x^11 - 92378∙x^10 + 92378∙x^9 - 755(x-1)^20: x^20 - 20∙x^19 + 190∙x^18 - 1140∙x^17 + 4845∙x^16 - 15504∙x^15 + 38760∙x^14 - 77520∙x^13 + 125970∙x^12 - 167960∙x^11 + 184756∙x^10
primes: 2 3 5 7 11 13 17 19
Found 8 primes and the largest coefficient has 6 decimal digits.
output for requirement #3, showing if 2221 is prime (or not) using for input: +2221
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(Output note: this number is really pushing at the limits of REXX's use of virtual memory; theversion ofRegina REXX used herein has a limit of around 2 Gbytes.)
2221 is prime.
Found 331 primes and the largest coefficient has 668 decimal digits.
output for requirement #4, showing all primes under 35 using the input: 35
primes: 2 3 5 7 11 13 17 19 23 29 31
Found 11 primes and the largest coefficient has 10 decimal digits.
output for requirement #5 (stretch goal), showing all primes under 50 using the input: 50
primes: 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
Found 15 primes and the largest coefficient has 15 decimal digits.
output when using the input: 500
primes: 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157 163 167 173 17
Found 95 primes and the largest coefficient has 150 decimal digits.
Ruby
Using the `polynomial` Rubygem, this can be written directly from the definition in thedescription:
require 'polynomial'
def x_minus_1_to_the(p)return Polynomial.new(-1,1)**p
end
def prime?(p)return false if p < 2(x_minus_1_to_the(p) - Polynomial.from_string("x**#{p}-1")).coefs.all?{|n| n%p==0}
end
8.times do |n|# the default Polynomial#to_s would be OK here; the substitutions just make the# output match the other version below.puts "(x-1)^#{n} = #{x_minus_1_to_the(n).to_s.gsub(/\*\*/,'^').gsub(/\*/,'')}"
end
puts "\nPrimes below 50:", 50.times.select {|n| prime? n}.join(',')
Or without the dependency:
def x_minus_1_to_the(p)p.times.inject([1]) do |ex, _|([0] + ex).zip(ex + [0]).map { |x,y| x - y }
endend
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def prime?(p)return false if p < 2
coeff = x_minus_1_to_the(p) coeff[0] += coeff.pop coeff.all?{|n| n%p==0}end
8.times do |n|puts "(x-1)^#{n} = " +
x_minus_1_to_the(n).each_with_index.map { |c, p|if p.zero? then c.to_selse(c<0 ? " - " : " + ") + (c.abs==1 ? "x" : "#{c.abs}x") + (p==1 ? "" : "^#{p}")
end}.join
end
puts "\nPrimes below 50:", 50.times.select {|n| prime? n}.join(',')
Output:
(x-1)^0 = 1(x-1)^1 = -1 + x(x-1)^2 = 1 - 2x + x^2(x-1)^3 = -1 + 3x - 3x^2 + x^3(x-1)^4 = 1 - 4x + 6x^2 - 4x^3 + x^4(x-1)^5 = -1 + 5x - 10x^2 + 10x^3 - 5x^4 + x^5(x-1)^6 = 1 - 6x + 15x^2 - 20x^3 + 15x^4 - 6x^5 + x^6(x-1)^7 = -1 + 7x - 21x^2 + 35x^3 - 35x^4 + 21x^5 - 7x^6 + x^7
Primes below 50:2,3,5,7,11,13,17,19,23,29,31,37,41,43,47
Rust
#![feature(core)]
use std::iter::{range_inclusive, repeat};
fn aks_coefficients(k: usize) -> Vec<i64> {let mut coefficients = repeat(0i64).take(k + 1).collect::<Vec<_>>();coefficients[0] = 1;for i in 1..(k + 1) {
coefficients[i] = -(1..i).fold(coefficients[0], |prev, j|{let old = coefficients[j];coefficients[j] = old - prev;old
});}coefficients
}
fn is_prime(p: usize) -> bool {if p < 2 {
false} else {
let c = aks_coefficients(p);range_inclusive(1, (c.len() - 1) / 2).all(|i| (c[i] % (p as i64)) == 0)
}}
fn main() { for i in 0..8 { println!("{}: {:?}", i, aks_coefficients(i)); }
for i in (1..51).filter(|&i| is_prime(i)) {print!("{} ", i);
}}
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Output:
0: [1]1: [1, -1]2: [1, -2, 1]3: [1, -3, 3, -1]4: [1, -4, 6, -4, 1]5: [1, -5, 10, -10, 5, -1]6: [1, -6, 15, -20, 15, -6, 1]7: [1, -7, 21, -35, 35, -21, 7, -1]2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
An alternative version which computes the coefficients in a more functional but less efficient way.
fn aks_coefficients(k: usize) -> Vec<i64> {if k == 0 {
vec![1i64]} else {
let zero = Some(0i64);range(1, k).fold(vec![1i64, -1], |r, _| {
let a = r.iter().chain(zero.iter());let b = zero.iter().chain(r.iter());a.zip(b).map(|(x, &y)| x-y).collect()
})}
}
Scala
def powerMin1(n: BigInt) = if (n % 2 == 0) BigInt(1) else BigInt(-1)
val pascal = (( Vector(Vector(BigInt(1))) /: (1 to 50)) { (rows, i) =>val v = rows.headval newVector = ((1 until v.length) map (j =>
powerMin1(j+i) * (v(j-1).abs + v(j).abs))).toVector(powerMin1(i) +: newVector :+ powerMin1(i+v.length)) +: rows
}).reverse
def poly2String(poly: Vector[BigInt]) = ((0 until poly.length) map { i =>(i, poly(i)) match {
case (0, c) => c.toStringcase (_, c) =>
(if (c >= 0) "+" else "-") +(if (c == 1) "x" else c.abs + "x") +(if (i == 1) "" else "^" + i)
}}) mkString ""
def isPrime(n: Int) = {val poly = pascal(n)
poly.slice(1, poly.length - 1).forall(i => i % n == 0)}
for(i <- 0 to 7) { println( f"(x-1)^$i = ${poly2String( pascal(i) )}" ) }
val primes = (2 to 50).filter(isPrime)printlnprintln(primes mkString " ")
Output:
(x-1)^0 = 1(x-1)^1 = -1+x(x-1)^2 = 1-2x+x^2
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(x-1)^3 = -1+3x-3x^2+x^3(x-1)^4 = 1-4x+6x^2-4x^3+x^4(x-1)^5 = -1+5x-10x^2+10x^3-5x^4+x^5(x-1)^6 = 1-6x+15x^2-20x^3+15x^4-6x^5+x^6(x-1)^7 = -1+7x-21x^2+35x^3-35x^4+21x^5-7x^6+x^7
2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
Scilab
clearxdel(winsid())
stacksize('max')sz=stacksize();
n=7; //For the expansion up to power of ng=50; //For test of primes up to g
function X = pascal(g) //Pascal´s triangle X(1,1)=1; //Zeroth power X(2,1)=1; //First power X(2,2)=1; for q=3:1:g+1 //From second power use this loop X(q,1)=1; X(q,q)=1; for p=2:1:q-1 X(q,p)=X(q-1,p-1)+X(q-1,p); end endendfunction
Z=pascal(g); //Generate Pascal's triangle up to g
Q(0+1)="(x-1)^0 = 1"; //For nicer displayQ(1+1)="(x-1)^1 = x^1-1"; //For nicer display
disp(Q(1))disp(Q(2))
function cf=coef(Z,q,p) //Return coeffiecents for nicer display of expansion without "ones" if Z(q,p)==1 then cf=""; else cf=string(Z(q,p)); endendfunction
for q=3:n+1 //Generate and display the expansions Q(q)=strcat(["(x-1)^",string(q-1)," = "]); sing=""; //Sign of coeff. for p=1:q-1 //Number of coefficients equals power minus 1 Q(q)=strcat([Q(q),sing,coef(Z,q,p),"x^",string(q-p)]); if sing=="-" then sing="+"; else sing="-"; end end Q(q)=strcat([Q(q),sing,string(1)]); disp(Q(q)) clear Qend
function prime=prime(Z,g) prime="true"; for p=2:g if abs(floor(Z(g+1,p)/g)-Z(g+1,p)/g)>0 then prime="false"; break; end endendfunction
R="2"; //For nicer displayfor r=3:g
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if prime(Z,r)=="true" then R=strcat([R, ", ",string(r)]); endenddisp(R)
Output:
(x-1)^0 = 1
(x-1)^1 = x^1-1
(x-1)^2 = x^2-2x^1+1
(x-1)^3 = x^3-3x^2+3x^1-1
(x-1)^4 = x^4-4x^3+6x^2-4x^1+1
(x-1)^5 = x^5-5x^4+10x^3-10x^2+5x^1-1
(x-1)^6 = x^6-6x^5+15x^4-20x^3+15x^2-6x^1+1
(x-1)^7 = x^7-7x^6+21x^5-35x^4+35x^3-21x^2+7x^1-1
2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47
Seed7
$ include "seed7_05.s7i";
const func array integer: expand_x_1 (in integer: p) is func result var array integer: ex is [] (1); local var integer: i is 0; begin for i range 0 to p - 1 do ex := [] (ex[1] * -(p - i) div (i + 1)) & ex; end for; end func;
const func boolean: aks_test (in integer: p) is func result var boolean: aks_test is FALSE; local var array integer: ex is 0 times 0; var integer: idx is 0; begin if p >= 2 then ex := expand_x_1(p); ex[1] +:= 1; for idx range 1 to pred(length(ex)) until ex[idx] rem p <> 0 do noop; end for; aks_test := idx = length(ex); end if; end func;
const proc: main is func local var integer: p is 0; var integer: n is 0; var integer: e is 0; begin writeln("# p: (x-1)^p for small p"); for p range 0 to 11 do write(p lpad 3 <& ": "); for n key e range expand_x_1(p) do write(" "); if n >= 0 then
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write("+"); end if; write(n); if e > 1 then write("x^" <& pred(e)); end if; end for; writeln; end for; writeln; writeln("# small primes using the aks test"); for p range 0 to 61 do if aks_test(p) then write(p <& " "); end if; end for; writeln; end func;
Output:
# p: (x-1)^p for small p 0: +1 1: -1 +1x^1 2: +1 -2x^1 +1x^2 3: -1 +3x^1 -3x^2 +1x^3 4: +1 -4x^1 +6x^2 -4x^3 +1x^4 5: -1 +5x^1 -10x^2 +10x^3 -5x^4 +1x^5 6: +1 -6x^1 +15x^2 -20x^3 +15x^4 -6x^5 +1x^6 7: -1 +7x^1 -21x^2 +35x^3 -35x^4 +21x^5 -7x^6 +1x^7 8: +1 -8x^1 +28x^2 -56x^3 +70x^4 -56x^5 +28x^6 -8x^7 +1x^8 9: -1 +9x^1 -36x^2 +84x^3 -126x^4 +126x^5 -84x^6 +36x^7 -9x^8 +1x^9 10: +1 -10x^1 +45x^2 -120x^3 +210x^4 -252x^5 +210x^6 -120x^7 +45x^8 -10x^9 +1x^10 11: -1 +11x^1 -55x^2 +165x^3 -330x^4 +462x^5 -462x^6 +330x^7 -165x^8 +55x^9 -11x^10 +1x^11
# small primes using the aks test2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61
Sidef
Translation of: Perl
func binprime(p) {p >= 2 || return false;
range(1, p>>1).each { |i|(binomial(p, i) % p) && return false;
};return true;
}
func coef(n, e) {(e == 0) && return "#{n}";(n == 1) && (n = "");(e == 1) ? "#{n}x" : "#{n}x^#{e}";
}
func binpoly(p) { join(" ", coef(1, p), range(p-1).reverse.map {|i| join(" ", %w(+ -)[(p-i)&1], coef(binomial(p, i), i));
}...);}
say "expansions of (x-1)^p:";range(9).each { |i| say binpoly(i) };say "Primes to 80: [#{(2..80).grep { binprime(_) }}]";
Output:
expansions of (x-1)^p:
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1x - 1x^2 - 2x + 1x^3 - 3x^2 + 3x - 1x^4 - 4x^3 + 6x^2 - 4x + 1x^5 - 5x^4 + 10x^3 - 10x^2 + 5x - 1x^6 - 6x^5 + 15x^4 - 20x^3 + 15x^2 - 6x + 1x^7 - 7x^6 + 21x^5 - 35x^4 + 35x^3 - 21x^2 + 7x - 1x^8 - 8x^7 + 28x^6 - 56x^5 + 70x^4 - 56x^3 + 28x^2 - 8x + 1x^9 - 9x^8 + 36x^7 - 84x^6 + 126x^5 - 126x^4 + 84x^3 - 36x^2 + 9x - 1Primes to 80: [2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79]
Swift
func polynomialCoeffs(n: Int) -> [Int] { var result = [Int](count : n+1, repeatedValue : 0)
result[0]=1 for i in 1 ..< n/2+1 { //Progress up, until reaching the middle value result[i] = result[i-1] * (n-i+1)/i; } for i in n/2+1 ..< n+1 { //Copy the inverse of the first part result[i] = result[n-i]; } // Take into account the sign for i in stride(from: 1, through: n, by: 2) { result[i] = -result[i] }
return result}
func isPrime(n: Int) -> Bool {
var coeffs = polynomialCoeffs(n)
coeffs[0]-- coeffs[n]++
for i in 1 ... n { if coeffs[i]%n != 0 { return false } }
return true}
for i in 0...10 {
let coeffs = polynomialCoeffs(i)
print("(x-1)^\(i) = ") if i == 0 { print("1") } else { if i == 1 { print("x") } else { print("x^\(i)") if i == 2 { print("\(coeffs[i-1])x") } else { for j in 1...(i - 2) { if j%2 == 0 { print("+\(coeffs[j])x^\(i-j)") } else { print("\(coeffs[j])x^\(i-j)") } } if (i-1)%2 == 0 { print("+\(coeffs[i-1])x") } else {
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print("\(coeffs[i-1])x") } } } if i%2 == 0 { print("+\(coeffs[i])") } else { print("\(coeffs[i])") } } println()}
println()print("Primes under 50 : ")
for i in 1...50 { if isPrime(i) { print("\(i) ") }}
Output:
(x-1)^0 = 1(x-1)^1 = x-1(x-1)^2 = x^2-2x+1(x-1)^3 = x^3-3x^2+3x-1(x-1)^4 = x^4-4x^3+6x^2-4x+1(x-1)^5 = x^5-5x^4+10x^3-10x^2+5x-1(x-1)^6 = x^6-6x^5+15x^4-20x^3+15x^2-6x+1(x-1)^7 = x^7-7x^6+21x^5-35x^4+35x^3-21x^2+7x-1(x-1)^8 = x^8-8x^7+28x^6-56x^5+70x^4-56x^3+28x^2-8x+1(x-1)^9 = x^9-9x^8+36x^7-84x^6+126x^5-126x^4+84x^3-36x^2+9x-1(x-1)^10 = x^10-10x^9+45x^8-120x^7+210x^6-252x^5+210x^4-120x^3+45x^2-10x+1
Primes under 50 : 1 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47
Tcl
A recursive method with memorization would be more efficient, but this is sufficient forsmall-scale work.
proc coeffs {p {signs 1}} {set clist 1for {set i 0} {$i < $p} {incr i} {
set clist [lmap x [list 0 {*}$clist] y [list {*}$clist 0] { expr {$x + $y}}]
}if {$signs} {
set s -1set clist [lmap c $clist {expr {[set s [expr {-$s}]] * $c}}]
}return $clist
}proc aksprime {p} {
if {$p < 2} {return false
}foreach c [coeffs $p 0] {
if {$c == 1} continueif {$c % $p} { return false}
}return true
}
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for {set i 0} {$i <= 7} {incr i} {puts -nonewline "(x-1)^$i ="set j $iforeach c [coeffs $i] {
puts -nonewline [format " %+dx^%d" $c $j]incr j -1
}puts ""
}
set sub35primes {}for {set i 1} {$i < 35} {incr i} {
if {[aksprime $i]} {lappend sub35primes $i
}}puts "primes under 35: [join $sub35primes ,]"
set sub50primes {}for {set i 1} {$i < 50} {incr i} {
if {[aksprime $i]} {lappend sub50primes $i
}}puts "primes under 50: [join $sub50primes ,]"
Output:
(x-1)^0 = +1x^0(x-1)^1 = +1x^1 -1x^0(x-1)^2 = +1x^2 -2x^1 +1x^0(x-1)^3 = +1x^3 -3x^2 +3x^1 -1x^0(x-1)^4 = +1x^4 -4x^3 +6x^2 -4x^1 +1x^0(x-1)^5 = +1x^5 -5x^4 +10x^3 -10x^2 +5x^1 -1x^0(x-1)^6 = +1x^6 -6x^5 +15x^4 -20x^3 +15x^2 -6x^1 +1x^0(x-1)^7 = +1x^7 -7x^6 +21x^5 -35x^4 +35x^3 -21x^2 +7x^1 -1x^0primes under 35: 2,3,5,7,11,13,17,19,23,29,31primes under 50: 2,3,5,7,11,13,17,19,23,29,31,37,41,43,47
uBasic/4tH
For n = 0 To 9 Push n : Gosub _coef : Gosub _drop Print "(x-1)^";n;" = "; Push n : Gosub _show PrintNext
PrintPrint "primes (never mind the 1):";
For n = 1 To 34 Push n : Gosub _isprime If Pop() Then Print " ";n;Next
PrintEnd
' show polynomial expansions_show ' ( n --) Do If @(Tos()) > -1 Then Print "+"; Print @(Tos());"x^";Tos(); While (Tos()) Push Pop() - 1 Loop
Gosub _dropReturn
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' test whether number is a prime_isprime ' ( n --) Gosub _coef
i = Tos() @(0) = @(0) + 1 @(i) = @(i) - 1
Do While (i) * ((@(i) % Tos()) = 0) i = i - 1 Loop
Gosub _drop Push (i = 0)Return
' generate coefficients_coef ' ( n -- n) If (Tos() < 0) + (Tos() > 34) Then End ' gracefully deal with range issue i = 0 @(i) = 1
Do While i < Tos() j = i @(j+1) = 1
Do While j > 0 @(j) = @(j-1) - @(j) j = j - 1 Loop
@(0) = -@(0) i = i + 1 LoopReturn
' drop a value from the stack_drop ' ( n --) If Pop() EndifReturn
Output:
(x-1)^0 = +1x^0(x-1)^1 = +1x^1-1x^0(x-1)^2 = +1x^2-2x^1+1x^0(x-1)^3 = +1x^3-3x^2+3x^1-1x^0(x-1)^4 = +1x^4-4x^3+6x^2-4x^1+1x^0(x-1)^5 = +1x^5-5x^4+10x^3-10x^2+5x^1-1x^0(x-1)^6 = +1x^6-6x^5+15x^4-20x^3+15x^2-6x^1+1x^0(x-1)^7 = +1x^7-7x^6+21x^5-35x^4+35x^3-21x^2+7x^1-1x^0(x-1)^8 = +1x^8-8x^7+28x^6-56x^5+70x^4-56x^3+28x^2-8x^1+1x^0(x-1)^9 = +1x^9-9x^8+36x^7-84x^6+126x^5-126x^4+84x^3-36x^2+9x^1-1x^0
primes (never mind the 1): 1 2 3 5 7 11 13 17 19 23 29 31
zkl
Translation of: Python
var BN=Import("zklBigNum");fcn expand_x_1(p){ ex := L(BN(1)); foreach i in (p){ ex.append(ex[-1] * -(p-i) / (i+1)) } return(ex.reverse()) }fcn aks_test(p){ if (p < 2) return(False); ex := expand_x_1(p);
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ex[0] = ex[0] + 1; return(not ex[0,-1].filter('%.fp1(p)));}println("# p: (x-1)^p for small p");foreach p in (12){ println("%3d: ".fmt(p),expand_x_1(p).enumerate() .pump(String,fcn([(n,e)]){"%+d%s ".fmt(e,n and "x^%d".fmt(n) or "")}));}
println("\n# small primes using the aks test");println([0..110].filter(aks_test).toString(*));
Output:
# p: (x-1)^p for small p 0: +1 1: -1 +1x^1 2: +1 -2x^1 +1x^2 3: -1 +3x^1 -3x^2 +1x^3 4: +1 -4x^1 +6x^2 -4x^3 +1x^4 5: -1 +5x^1 -10x^2 +10x^3 -5x^4 +1x^5 6: +1 -6x^1 +15x^2 -20x^3 +15x^4 -6x^5 +1x^6 7: -1 +7x^1 -21x^2 +35x^3 -35x^4 +21x^5 -7x^6 +1x^7 8: +1 -8x^1 +28x^2 -56x^3 +70x^4 -56x^5 +28x^6 -8x^7 +1x^8 9: -1 +9x^1 -36x^2 +84x^3 -126x^4 +126x^5 -84x^6 +36x^7 -9x^8 +1x^9 10: +1 -10x^1 +45x^2 -120x^3 +210x^4 -252x^5 +210x^6 -120x^7 +45x^8 -10x^9 +1x^10 11: -1 +11x^1 -55x^2 +165x^3 -330x^4 +462x^5 -462x^6 +330x^7 -165x^8 +55x^9 -11x^10 +1x^11
# small primes using the aks testL(2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97,101,103,107,109)
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