Cipolla's algorithm
Cipolla's algorithm
Solve x² ≡ n (mod p)
In computational number theory, Cipolla's algorithm is a technique for solving an equation of the form x² ≡ n (mod p), where p is an odd prime and x ,n ∊ Fp = {0, 1, ... p-1}.
To apply the algorithm we need the Legendre symbol, and arithmetic in Fp².
Legendre symbol
- The Legendre symbol ( a | p) denotes the value of a ^ ((p-1)/2) (mod p)
- (a | p) ≡ 1 if a is a square (mod p)
- (a | p) ≡ -1 if a is not a square (mod p)
- (a | p) ≡ 0 is a ≡ 0
Arithmetic in Fp²
Let ω a symbol such as ω² is a member of Fp and not a square, x and y members of Fp. The set Fp² is defined as {x + ω y }. The subset { x + 0 ω} of Fp² is Fp. Fp² is somewhat equivalent to the field of complex number, with ω analoguous to i, and i² = -1 . Remembering that all operations are modulo p, addition, multiplication and exponentiation in Fp² are defined as :
- (x1 + ω y1) + (x2 + ω y2) := (x1 + x2 + ω (y1 + y2))
- (x1 + ω y1) * (x2 + ω y2) := (x1*x2 + y1*y2*ω²) + ω (x1*y2 + x2*y1)
- (0 + ω) * (0 + ω) := (ω² + 0 ω) ≡ ω² in Fp
- (x1 + ω y1) ^ n := (x + ω y) * (x + ω y) * ... ( n times) (1)
Algorithm pseudo-code
- Input : p an odd prime, and n ≠ 0 in Fp
- Step 0. Check that n is indeed a square : (n | p) must be ≡ 1
- Step 1. Find, by trial and error, an a > 0 such as (a² - n) is not a square : (a²-n | p) must be ≡ -1.
- Step 2. Let ω² = a² - n. Compute, in Fp2 : (a + ω) ^ ((p + 1)/2) (mod p)
To compute this step, use a pair of numbers, initially [a,1], and use repeated "multiplication" which is defined such that [c,d] times [e,f] is (mod p) [ c*c + ω²*f*f, d*e + c*f ].
- Step 3. Check that the result is ≡ x + 0 * ω in Fp2, that is x in Fp.
- Step 4. Output the two positive solutions, x and p - x (mod p).
- Step 5. Check that x * x ≡ n (mod p)
Example from Wikipedia
n := 10 , p := 13 Legendre(10,13) → 1 // 10 is indeed a square a := 2 // try ω² := a*a - 10 // ≡ 7 ≡ -6 Legendre (ω² , 13) → -1 // ok - not square (2 + ω) ^ 7 → 6 + 0 ω // by modular exponentiation (1) // 6 and (13 - 6) = 7 are solutions (6 * 6) % 13 → 10 // = n . Checked.
Task
Implement the above.
Find solutions (if any) for
- n = 10 p = 13
- n = 56 p = 101
- n = 8218 p = 10007
- n = 8219 p = 10007
- n = 331575 p = 1000003
Extra credit
- n 665165880 p 1000000007
- n 881398088036 p 1000000000039
- n = 34035243914635549601583369544560650254325084643201 p = 10^50 + 151
See also:
EchoLisp
<lang scheme> (lib 'struct) (lib 'types) (lib 'bigint)
- test equality mod p
(define-syntax-rule (mod= a b p) (zero? (% (- a b) p)))
(define (Legendre a p) (powmod a (/ (1- p) 2) p))
- Arithmetic in Fp²
(struct Fp² ( x y ))
- a + b
(define (Fp²-add Fp²:a Fp²:b p ω2) (Fp² (% (+ a.x b.x) p) (% (+ a.y b.y) p)))
- a * b
(define (Fp²-mul Fp²:a Fp²:b p ω2) (Fp² (% (+ (* a.x b.x) (* ω2 a.y b.y)) p) (% (+ (* a.x b.y) (* a.y b.x)) p)))
- a * a
(define (Fp²-square Fp²:a p ω2) (Fp² (% (+ (* a.x a.x) (* ω2 a.y a.y)) p) (% (* 2 a.x a.y) p)))
- a ^ n
(define (Fp²-pow Fp²:a n p ω2) (cond ((= 0 n) (Fp² 1 0)) ((= 1 n) (Fp² a.x a.y)) ((= 2 n) (Fp²-mul a a p ω2)) ((even? n) (Fp²-square (Fp²-pow a (/ n 2) p ω2) p ω2)) (else (Fp²-mul a (Fp²-pow a (1- n) p ω2) p ω2))))
- x^2 ≡ n (mod p) ?
(define (Cipolla n p)
- check n is a square
(unless (= 1 (Legendre n p)) (error "not a square (mod p)" (list n p)))
- iterate until suitable 'a' found
(define a (for ((t (in-range 2 p))) ;; t = tentative a #:break (= (1- p) (Legendre (- (* t t) n) p)) => t )) (define ω2 (- (* a a) n)) ;; (writeln 'a-> a 'ω2-> ω2 'ω-> 'ω) ;; (Fp² a 1) = a + ω (define r (Fp²-pow (Fp² a 1) (/ (1+ p) 2) p ω2)) ;; (writeln 'r r) (define x (Fp²-x r)) (assert (zero? (Fp²-y r))) ;; hope that ω has vanished (assert (mod= n (* x x) p)) ;; checking the result (printf "Roots of %d are (%d,%d) (mod %d)" n x (% (- p x) p) p)) </lang>
- Output:
(Cipolla 10 13) Roots of 10 are (6,7) (mod 13) (% (* 6 6) 13) → 10 ;; checking (Cipolla 56 101) Roots of 56 are (37,64) (mod 101) (Cipolla 8218 10007) Roots of 8218 are (9872,135) (mod 10007) Cipolla 8219 10007) ❌ error: not a square (mod p) (8219 10007) (Cipolla 331575 1000003) Roots of 331575 are (855842,144161) (mod 1000003) (% ( * 855842 855842) 1000003) → 331575
FreeBASIC
LongInt version
Had a close look at the EchoLisp code for step 2. Used the FreeBASIC code from the Miller-Rabin task for prime testing. <lang freebasic>' version 08-04-2017 ' compile with: fbc -s console ' maximum for p is 17 digits to be on the save side
' TRUE/FALSE are built-in constants since FreeBASIC 1.04 ' But we have to define them for older versions.
- Ifndef TRUE
#Define FALSE 0 #Define TRUE Not FALSE
- EndIf
Type fp2
x As LongInt y As LongInt
End Type
Function mul_mod(a As ULongInt, b As ULongInt, modulus As ULongInt) As ULongInt
' returns a * b mod modulus Dim As ULongInt x, y = a mod modulus
While b > 0 If (b And 1) = 1 Then x = (x + y) Mod modulus End If y = (y Shl 1) Mod modulus b = b Shr 1 Wend
Return x
End Function
Function pow_mod(b As ULongInt, power As ULongInt, modulus As ULongInt) As ULongInt
' returns b ^ power mod modulus Dim As ULongInt x = 1
While power > 0 If (power And 1) = 1 Then ' x = (x * b) Mod modulus x = mul_mod(x, b, modulus) End If ' b = (b * b) Mod modulus b = mul_mod(b, b, modulus) power = power Shr 1 Wend
Return x
End Function
Function Isprime(n As ULongInt, k As Long) As Long
' miller-rabin prime test If n > 9223372036854775808ull Then ' limit 2^63, pow_mod/mul_mod can't handle bigger numbers Print "number is to big, program will end" Sleep End End If
' 2 is a prime, if n is smaller then 2 or n is even then n = composite If n = 2 Then Return TRUE If (n < 2) OrElse ((n And 1) = 0) Then Return FALSE
Dim As ULongInt a, x, n_one = n - 1, d = n_one Dim As UInteger s
While (d And 1) = 0 d = d Shr 1 s = s + 1 Wend
While k > 0 k = k - 1 a = Int(Rnd * (n -2)) +2 ' 2 <= a < n x = pow_mod(a, d, n) If (x = 1) Or (x = n_one) Then Continue While For r As Integer = 1 To s -1 x = pow_mod(x, 2, n) If x = 1 Then Return FALSE If x = n_one Then Continue While Next If x <> n_one Then Return FALSE Wend Return TRUE
End Function
Function legendre_symbol (a As LongInt, p As LongInt) As LongInt
Dim As LongInt x = pow_mod(a, ((p -1) \ 2), p) If p -1 = x Then Return x - p Else Return x End If
End Function
Function fp2mul(a As fp2, b As fp2, p As LongInt, w2 As LongInt) As fp2
Dim As fp2 answer Dim As ULongInt tmp1, tmp2 ' needs to be broken down in smaller steps to avoid overflow ' answer.x = (a.x * b.x + a.y * b.y * w2) Mod p ' answer.y = (a.x * b.y + a.y * b.x) Mod p tmp1 = mul_mod(a.x, b.x, p) tmp2 = mul_mod(a.y, b.y, p) tmp2 = mul_mod(tmp2, w2, p) answer.x = (tmp1 + tmp2) Mod p tmp1 = mul_mod(a.x, b.y, p) tmp2 = mul_mod(a.y, b.x, p) answer.y = (tmp1 + tmp2) Mod p
Return answer
End Function
Function fp2square(a As fp2, p As LongInt, w2 As LongInt) As fp2
Return fp2mul(a, a, p, w2)
End Function
Function fp2pow(a As fp2, n As LongInt, p As LongInt, w2 As LongInt) As fp2
If n = 0 Then Return Type (1, 0) If n = 1 Then Return a If n = 2 Then Return fp2square(a, p, w2) If (n And 1) = 0 Then Return fp2square(fp2pow(a, n \ 2, p, w2), p , w2) Else Return fp2mul(a, fp2pow(a, n -1, p, w2), p, w2) End If
End Function
' ------=< MAIN >=------
Data 10, 13, 56, 101, 8218, 10007,8219, 10007 Data 331575, 1000003, 665165880, 1000000007 Data 881398088036, 1000000000039
Randomize Timer Dim As LongInt n, p, a, w2 Dim As LongInt i, x1, x2 Dim As fp2 answer
For i = 1 To 7
Read n, p Print Print "Find solution for n =";n ; " and p =";p
If p = 2 OrElse Isprime(p,15) = FALSE Then Print "No solution, p is not a odd prime" Continue For End If
' p is checked and is a odd prime If legendre_symbol(n, p) <> 1 Then Print n; " is not a square in F";Str(p) Continue For End If
Do Do a = Rnd * (p -2) +2 w2 = a * a - n Loop Until legendre_symbol(w2, p) = -1
answer = Type(a, 1) answer = fp2pow(answer, (p +1) \ 2, p, w2) If answer.y <> 0 Then Continue Do
x1 = answer.x : x2 = p - x1 If mul_mod(x1, x1, p) = n AndAlso mul_mod(x2, x2, p) = n Then Print "Solution found: x1 ="; x1; ", "; "x2 ="; x2 Exit Do End If Loop ' loop until solution is found
Next
' empty keyboard buffer While Inkey <> "" : Wend Print : Print "hit any key to end program" Sleep End</lang>
- Output:
Find solution for n = 10 and p = 13 Solution found: x1 = 7, x2 = 6 Find solution for n = 56 and p = 101 Solution found: x1 = 37, x2 = 64 Find solution for n = 8218 and p = 10007 Solution found: x1 = 9872, x2 = 135 Find solution for n = 8219 and p = 10007 8219 is not a square in F10007 Find solution for n = 331575 and p = 1000003 Solution found: x1 = 144161, x2 = 855842 Find solution for n = 665165880 and p = 1000000007 Solution found: x1 = 475131702, x2 = 524868305 Find solution for n = 881398088036 and p = 1000000000039 Solution found: x1 = 791399408049, x2 = 208600591990
GMP version
<lang freebasic>' version 12-04-2017 ' compile with: fbc -s console
- Include Once "gmp.bi"
Type fp2
x As Mpz_ptr y As Mpz_ptr
End Type
Data "10", "13" Data "56", "101" Data "8218", "10007" Data "8219", "10007" Data "331575", "1000003" Data "665165880", "1000000007" Data "881398088036", "1000000000039" Data "34035243914635549601583369544560650254325084643201" ', 10^50 + 151
Function fp2mul(a As fp2, b As fp2, p As Mpz_ptr, w2 As Mpz_ptr) As fp2
Dim As fp2 r r.x = Allocate(Len(__Mpz_struct)) : Mpz_init(r.x) r.y = Allocate(Len(__Mpz_struct)) : Mpz_init(r.y)
Mpz_mul (r.x, a.y, b.y) Mpz_mul (r.x, r.x, w2) Mpz_addmul(r.x, a.x, b.x) Mpz_mod (r.x, r.x, p) Mpz_mul (r.y, a.x, b.y) Mpz_addmul(r.y, a.y, b.x) Mpz_mod (r.y, r.y, p)
Return r
End Function
Function fp2square(a As fp2, p As Mpz_ptr, w2 As Mpz_ptr) As fp2
Return fp2mul(a, a, p, w2)
End Function
Function fp2pow(a As fp2, n As Mpz_ptr, p As Mpz_ptr, w2 As Mpz_ptr) As fp2
If Mpz_cmp_ui(n, 0) = 0 Then Mpz_set_ui(a.x, 1) Mpz_set_ui(a.y, 0) Return a End If If Mpz_cmp_ui(n, 1) = 0 Then Return a If Mpz_cmp_ui(n, 2) = 0 Then Return fp2square(a, p, w2) If Mpz_tstbit(n, 0) = 0 Then Mpz_fdiv_q_2exp(n, n, 1) ' even Return fp2square(fp2pow(a, n, p, w2), p, w2) Else Mpz_sub_ui(n, n, 1) ' odd Return fp2mul(a, fp2pow(a, n, p, w2), p, w2) End If
End Function
' ------=< MAIN >=------
Dim As Long i Dim As ZString Ptr zstr Dim As String n_str, p_str
Dim As Mpz_ptr a, n, p, p2, w2, x1, x2 a = Allocate(Len(__Mpz_struct)) : Mpz_init(a) n = Allocate(Len(__Mpz_struct)) : Mpz_init(n) p = Allocate(Len(__Mpz_struct)) : Mpz_init(p) p2 = Allocate(Len(__Mpz_struct)) : Mpz_init(p2) w2 = Allocate(Len(__Mpz_struct)) : Mpz_init(w2) x1 = Allocate(Len(__Mpz_struct)) : Mpz_init(x1) x2 = Allocate(Len(__Mpz_struct)) : Mpz_init(x2)
Dim As fp2 answer answer.x = Allocate(Len(__Mpz_struct)) : Mpz_init(answer.x) answer.y = Allocate(Len(__Mpz_struct)) : Mpz_init(answer.y)
For i = 1 To 8
Read n_str Mpz_set_str(n, n_str, 10) If i < 8 Then Read p_str Mpz_set_str(p, p_str, 10) Else p_str = "10^50 + 151" ' set up last n Mpz_set_str(p, "1" + String(50, "0"), 10) Mpz_add_ui(p, p, 151) End If
Print "Find solution for n = "; n_str; " and p = "; p_str
If Mpz_tstbit(p, 0) = 0 OrElse Mpz_probab_prime_p(p, 20) = 0 Then Print p_str; "is not a odd prime" Print Continue For End If
' p is checked and is a odd prime ' legendre symbol needs to be 1 If Mpz_legendre(n, p) <> 1 Then Print n_str; " is not a square in F"; p_str Print Continue For End If
Mpz_set_ui(a, 1) Do Do Do Mpz_add_ui(a, a, 1) Mpz_mul(w2, a, a) Mpz_sub(w2, w2, n) Loop Until Mpz_legendre(w2, p) = -1
Mpz_set(answer.x, a) Mpz_set_ui(answer.y, 1) Mpz_add_ui(p2, p, 1) ' p2 = p + 1 Mpz_fdiv_q_2exp(p2, p2, 1) ' p2 = p2 \ 2 (p2 shr 1)
answer = fp2pow(answer, p2, p, w2)
Loop Until Mpz_cmp_ui(answer.y, 0) = 0 Mpz_set(x1, answer.x) Mpz_sub(x2, p, x1) Mpz_powm_ui(a, x1, 2, p) Mpz_powm_ui(p2, x2, 2, p) If Mpz_cmp(a, n) = 0 AndAlso Mpz_cmp(p2, n) = 0 Then Exit Do Loop
zstr = Mpz_get_str(0, 10, x1) Print "Solution found: x1 = "; *zstr; zstr = Mpz_get_str(0, 10, x2) Print ", x2 = "; *zstr Print
Next
Mpz_clear(x1) : Mpz_clear(p2) : Mpz_clear(p) : Mpz_clear(a) : Mpz_clear(n) Mpz_clear(x2) : Mpz_clear(w2) : Mpz_clear(answer.x) : Mpz_clear(answer.y)
' empty keyboard buffer While Inkey <> "" : Wend Print : Print "hit any key to end program" Sleep End</lang>
- Output:
Find solution for n = 10 and p = 13 Solution found: x1 = 6, x2 = 7 Find solution for n = 56 and p = 101 Solution found: x1 = 37, x2 = 64 Find solution for n = 8218 and p = 10007 Solution found: x1 = 9872, x2 = 135 Find solution for n = 8219 and p = 10007 8219 is not a square in F10007 Find solution for n = 331575 and p = 1000003 Solution found: x1 = 855842, x2 = 144161 Find solution for n = 665165880 and p = 1000000007 Solution found: x1 = 524868305, x2 = 475131702 Find solution for n = 881398088036 and p = 1000000000039 Solution found: x1 = 208600591990, x2 = 791399408049 Find solution for n = 34035243914635549601583369544560650254325084643201 and p = 10^50 + 151 Solution found: x1 = 17436881171909637738621006042549786426312886309400, x2 = 82563118828090362261378993957450213573687113690751
Go
int
Implementation following the pseudocode in the task description. <lang go>package main
import "fmt"
func c(n, p int) (R1, R2 int, ok bool) {
// a^e mod p powModP := func(a, e int) int { s := 1 for ; e > 0; e-- { s = s * a % p } return s } // Legendre symbol, returns 1, 0, or -1 mod p -- that's 1, 0, or p-1. ls := func(a int) int { return powModP(a, (p-1)/2) } // Step 0, validate arguments if ls(n) != 1 { return } // Step 1, find a, ω2 var a, ω2 int for a = 0; ; a++ { // integer % in Go uses T-division, add p to keep the result positive ω2 = (a*a + p - n) % p if ls(ω2) == p-1 { break } } // muliplication in fp2 type point struct{ x, y int } mul := func(a, b point) point { return point{(a.x*b.x + a.y*b.y*ω2) % p, (a.x*b.y + b.x*a.y) % p} } // Step2, compute power r := point{1, 0} s := point{a, 1} for n := (p + 1) >> 1 % p; n > 0; n >>= 1 { if n&1 == 1 { r = mul(r, s) } s = mul(s, s) } // Step3, check x in Fp if r.y != 0 { return } // Step5, check x*x=n if r.x*r.x%p != n { return } // Step4, solutions return r.x, p - r.x, true
}
func main() {
fmt.Println(c(10, 13)) fmt.Println(c(56, 101)) fmt.Println(c(8218, 10007)) fmt.Println(c(8219, 10007)) fmt.Println(c(331575, 1000003))
}</lang>
- Output:
6 7 true 37 64 true 9872 135 true 0 0 false 855842 144161 true
big.Int
Extra credit: <lang go>package main
import (
"fmt" "math/big"
)
func c(n, p big.Int) (R1, R2 big.Int, ok bool) {
if big.Jacobi(&n, &p) != 1 { return } var one, a, ω2 big.Int one.SetInt64(1) for ; ; a.Add(&a, &one) { // big.Int Mod uses Euclidean division, result is always >= 0 ω2.Mod(ω2.Sub(ω2.Mul(&a, &a), &n), &p) if big.Jacobi(&ω2, &p) == -1 { break } } type point struct{ x, y big.Int } mul := func(a, b point) (z point) { var w big.Int z.x.Mod(z.x.Add(z.x.Mul(&a.x, &b.x), w.Mul(w.Mul(&a.y, &a.y), &ω2)), &p) z.y.Mod(z.y.Add(z.y.Mul(&a.x, &b.y), w.Mul(&b.x, &a.y)), &p) return } var r, s point r.x.SetInt64(1) s.x.Set(&a) s.y.SetInt64(1) var e big.Int for e.Rsh(e.Add(&p, &one), 1); len(e.Bits()) > 0; e.Rsh(&e, 1) { if e.Bit(0) == 1 { r = mul(r, s) } s = mul(s, s) } R2.Sub(&p, &r.x) return r.x, R2, true
}
func main() {
var n, p big.Int n.SetInt64(665165880) p.SetInt64(1000000007) R1, R2, ok := c(n, p) fmt.Println(&R1, &R2, ok)
n.SetInt64(881398088036) p.SetInt64(1000000000039) R1, R2, ok = c(n, p) fmt.Println(&R1, &R2, ok)
n.SetString("34035243914635549601583369544560650254325084643201", 10) p.SetString("100000000000000000000000000000000000000000000000151", 10) R1, R2, ok = c(n, p) fmt.Println(&R1) fmt.Println(&R2)
}</lang>
- Output:
475131702 524868305 true 791399408049 208600591990 true 82563118828090362261378993957450213573687113690751 17436881171909637738621006042549786426312886309400
J
Based on the echolisp implementation:
<lang J>leg=: dyad define
x (y&|)@^ (y-1)%2
)
mul2=: conjunction define
m| (*&{. + n**&{:), (+/ .* |.)
)
pow2=: conjunction define
if. 0=y do. 1 0 elseif. 1=y do. x elseif. 2=y do. x (m mul2 n) x elseif. 0=2|y do. (m mul2 n)~ x (m pow2 n) y%2 elseif. do. x (m mul2 n) x (m pow2 n) y-1 end.
)
cipolla=: dyad define
assert. 1=1 p: y [ 'y must be prime' assert. 1= x leg y [ 'x must be square mod y' a=.1 whilst. (0 ~:{: r) do. a=. a+1 while. 1>: leg&y@(x -~ *:) a do. a=.a+1 end. w2=. y|(*:a) - x r=. (a,1) (y pow2 w2) (y+1)%2 end. if. x =&(y&|) *:{.r do. y|(,-){.r else. smoutput 'got ',":~.y|(,-){.r assert. 'not a valid square root' end.
)</lang>
Task examples:
<lang J> 10 cipolla 13 6 7
56 cipolla 101
37 64
8218 cipolla 10007
9872 135
8219 cipolla 10007
|assertion failure: cipolla | 1=x leg y['x must be square mod y'
331575 cipolla 1000003
855842 144161
665165880x cipolla 1000000007x
524868305 475131702
881398088036x cipolla 1000000000039x
208600591990 791399408049
34035243914635549601583369544560650254325084643201x cipolla (10^50x) + 151
17436881171909637738621006042549786426312886309400 82563118828090362261378993957450213573687113690751</lang>
Perl 6
<lang perl6># Legendre operator (𝑛│𝑝) sub infix:<│> (Int \𝑛, Int \𝑝 where 𝑝.is-prime && (𝑝 != 2)) {
given 𝑛.expmod( (𝑝-1) div 2, 𝑝 ) { when 0 { 0 } when 1 { 1 } default { -1 } }
}
- a coordinate in a Field of p elements
class Fp {
has Int $.x; has Int $.y;
}
sub cipolla ( Int \𝑛, Int \𝑝 ) {
note "Invalid parameters ({𝑛}, {𝑝})" and return Nil if (𝑛│𝑝) != 1; my $ω2; my $a = 0; loop { last if ($ω2 = ($a² - 𝑛) % 𝑝)│𝑝 < 0; $a++; }
# define a local multiply operator for Field coordinates multi sub infix:<*> ( Fp $a, Fp $b ){ Fp.new: :x(($a.x * $b.x + $a.y * $b.y * $ω2) % 𝑝), :y(($a.x * $b.y + $b.x * $a.y) % 𝑝) }
my $r = Fp.new: :x(1), :y(0); my $s = Fp.new: :x($a), :y(1);
for (𝑝+1) +> 1, * +> 1 ... 1 { $r *= $s if $_ % 2; $s *= $s; } return Nil if $r.y; $r.x;
}
my @tests = (
(10, 13), (56, 101), (8218, 10007), (8219, 10007), (331575, 1000003), (665165880, 1000000007), (881398088036, 1000000000039), (34035243914635549601583369544560650254325084643201, 100000000000000000000000000000000000000000000000151)
);
for @tests -> ($n, $p) {
my $r = cipolla($n, $p); say $r ?? "Roots of $n are ($r, {$p-$r}) mod $p" !! "No solution for ($n, $p)"
} </lang>
- Output:
Roots of 10 are (6, 7) mod 13 Roots of 56 are (37, 64) mod 101 Roots of 8218 are (9872, 135) mod 10007 Invalid parameters (8219, 10007) No solution for (8219, 10007) Roots of 331575 are (855842, 144161) mod 1000003 Roots of 665165880 are (475131702, 524868305) mod 1000000007 Roots of 881398088036 are (791399408049, 208600591990) mod 1000000000039 Roots of 34035243914635549601583369544560650254325084643201 are (82563118828090362261378993957450213573687113690751, 17436881171909637738621006042549786426312886309400) mod 100000000000000000000000000000000000000000000000151
PicoLisp
<lang PicoLisp># from @lib/rsa.l (de **Mod (X Y N)
(let M 1 (loop (when (bit? 1 Y) (setq M (% (* M X) N)) ) (T (=0 (setq Y (>> 1 Y))) M ) (setq X (% (* X X) N)) ) ) )
(de legendre (N P)
(**Mod N (/ (dec P) 2) P) )
(de mul ("A" B P W2)
(let (A (copy "A") B (copy B)) (set "A" (% (+ (* (car A) (car B)) (* (cadr A) (cadr B) W2) ) P ) (cdr "A") (% (+ (* (car A) (cadr B)) (* (car B) (cadr A)) ) P ) ) ) )
(de ci (N P)
(and (=1 (legendre N P)) (let (A 0 W2 0 R NIL S NIL ) (loop (setq W2 (% (- (+ (* A A) P) N) P) ) (T (= (dec P) (legendre W2 P))) (inc 'A) ) (setq R (list 1 0) S (list A 1)) (for (N (% (>> 1 (inc P)) P) (> N 0) (>> 1 N) ) (and (bit? 1 N) (mul R S P W2)) (mul S S P W2) ) (=0 (cadr R)) (= N (% (* (car R) (car R)) P) ) (list (car R) (- P (car R))) ) ) )
(println (ci 10 13)) (println (ci 56 101)) (println (ci 8218 10007)) (println (ci 8219 10007)) (println (ci 331575 1000003)) (println (ci 665165880 1000000007)) (println (ci 881398088036 1000000000039)) (println (ci 34035243914635549601583369544560650254325084643201 (+ (** 10 50) 151)))</lang>
- Output:
(6 7) (37 64) (9872 135) NIL (855842 144161) (475131702 524868305) (791399408049 208600591990) (82563118828090362261378993957450213573687113690751 17436881171909637738621006042549786426312886309400)
Racket
<lang racket>#lang racket
(require math/number-theory)
- math/number-theory allows us to parameterize a "current-modulus"
- which obviates the need for p to be passed around constantly
(define (Cipolla n p) (with-modulus p (mod-Cipolla n)))
(define (mod-Legendre a)
(modexpt a (/ (sub1 (current-modulus)) 2)))
- Arithmetic in Fp²
(struct Fp² (x y))
(define-syntax-rule (Fp²-destruct* (a a.x a.y) ...)
(begin (match-define (Fp² a.x a.y) a) ...) )
- a + b
(define (Fp²-add a b ω2)
(Fp²-destruct* (a a.x a.y) (b b.x b.y)) (Fp² (mod+ a.x b.x) (mod+ a.y b.y)))
- a * b
(define (Fp²-mul a b ω2)
(Fp²-destruct* (a a.x a.y) (b b.x b.y)) (Fp² (mod+ (* a.x b.x) (* ω2 a.y b.y)) (mod+ (* a.x b.y) (* a.y b.x))))
- a * a
(define (Fp²-square a ω2)
(Fp²-destruct* (a a.x a.y)) (Fp² (mod+ (sqr a.x) (* ω2 (sqr a.y))) (mod* 2 a.x a.y)))
- a ^ n
(define (Fp²-pow a n ω2)
(Fp²-destruct* (a a.x a.y)) (cond ((= 0 n) (Fp² 1 0)) ((= 1 n) a) ((= 2 n) (Fp²-mul a a ω2)) ((even? n) (Fp²-square (Fp²-pow a (/ n 2) ω2) ω2)) (else (Fp²-mul a (Fp²-pow a (sub1 n) ω2) ω2))))
- x^2 ≡ n (mod p) ?
(define (mod-Cipolla n)
;; check n is a square (unless (= 1 (mod-Legendre n)) (error 'Cipolla "~a not a square (mod ~a)" n (current-modulus))) ;; iterate until suitable 'a' found (define a (for/first ((t (in-range 2 (current-modulus))) ;; t = tentative a #:when (= (sub1 (current-modulus)) (mod-Legendre (- (* t t) n)))) t)) (define ω2 (- (* a a) n)) ;; (Fp² a 1) = a + ω (define r (Fp²-pow (Fp² a 1) (/ (add1 (current-modulus)) 2) ω2)) (define x (Fp²-x r)) (unless (zero? (Fp²-y r)) (error 'Cipolla "ω has not vanished")) ;; hope that ω has vanished (unless (mod= n (* x x)) (error 'Cipolla "result check failed")) ;; checking the result (values x (mod- (current-modulus) x)))
(define (report-Cipolla n p)
(with-handlers ((exn:fail? (λ (x) (eprintf "Caught error: ~s~%" (exn-message x))))) (define-values (r1 r2) (Cipolla n p)) (printf "Roots of ~a are (~a,~a) (mod ~a)~%" n r1 r2 p)))
(module+ test
(report-Cipolla 10 13) (report-Cipolla 56 101) (report-Cipolla 8218 10007) (report-Cipolla 8219 10007) (report-Cipolla 331575 1000003) (report-Cipolla 665165880 1000000007) (report-Cipolla 881398088036 1000000000039) (report-Cipolla 34035243914635549601583369544560650254325084643201 100000000000000000000000000000000000000000000000151))</lang>
- Output:
Roots of 10 are (6,7) (mod 13) Roots of 56 are (37,64) (mod 101) Roots of 8218 are (9872,135) (mod 10007) Caught error: "Cipolla: 8219 not a square (mod 10007)" Roots of 331575 are (855842,144161) (mod 1000003) Roots of 665165880 are (524868305,475131702) (mod 1000000007) Roots of 881398088036 are (208600591990,791399408049) (mod 1000000000039) Roots of 34035243914635549601583369544560650254325084643201 are (17436881171909637738621006042549786426312886309400,82563118828090362261378993957450213573687113690751) (mod 100000000000000000000000000000000000000000000000151)
Sage
<lang sage> def eulerCriterion(a, p):
return -1 if pow(a, int((p-1)/2), p) == p-1 else 1
def cipollaMult(x1, y1, x2, y2, u, p):
return ((x1*x2 + y1*y2*u) % p), ((x1*y2 + x2*y1) % p)
def cipollaAlgorithm(n, p):
a = Mod(n, p) out = []
if eulerCriterion(a, p) == -1: print "❌ " + str(a) + " is not a quadratic residue modulo " + str(p) return False
if not is_prime(p): conglst = [] #congruence list crtlst = [] factors = []
for k in list(factor(p)): factors.append(int(k[0]))
for f in factors: conglst.append(cipollaAlgorithm(a, f))
for i in Permutations([0, 1] * len(factors), len(factors)).list(): for j in range(len(factors)): crtlst.append(int(conglst[ j ][ i[j] ]))
out.append(crt(crtlst, factors)) crtlst = []
return sorted(out)
if pow(p, 1, 4) == 3: temp = pow(a, int((p+1)/4), p) return [temp, p - temp]
t = randrange(2, p) u = pow(t**2 - a, 1, p) while (eulerCriterion(u, p) == 1): t = randrange(2, p) u = pow(t**2 - a, 1, p)
x0, y0 = t, 1 x, y = t, 1 for i in range(int((p + 1) / 2) - 1): x, y = cipollaMult(x, y, x0, y0, u, p)
out.extend([x, p - x])
return sorted(out)
</lang>
- Output:
sage: cipollaAlgorithm(10, 13) [6, 7] sage: cipollaAlgorithm(56, 101) [37, 64] sage: cipollaAlgorithm(8218, 10007) [135, 9872] sage: cipollaAlgorithm(331575, 1000003) [144161, 855842] sage: cipollaAlgorithm(8219, 10007) ❌ 8219 is not a quadratic residue modulo 10007 False
Sidef
<lang ruby>func cipolla(n, p) {
legendre(n, p) == 1 || return nil
var (a = 0, ω2 = 0) loop { ω2 = ((a*a - n) % p) if (legendre(ω2, p) == -1) { break } ++a }
struct point { x, y }
func mul(a, b) { point((a.x*b.x + a.y*b.y*ω2) % p, (a.x*b.y + b.x*a.y) % p) }
var r = point(1, 0) var s = point(a, 1)
for (var n = ((p+1) >> 1); n > 0; n >>= 1) { r = mul(r, s) if n.is_odd s = mul(s, s) }
r.y == 0 ? r.x : nil
}
var tests = [
[10, 13], [56, 101], [8218, 10007], [8219, 10007], [331575, 1000003], [665165880, 1000000007], [881398088036 1000000000039], [34035243914635549601583369544560650254325084643201, 10**50 + 151],
]
for n,p in tests {
var r = cipolla(n, p) if (defined(r)) { say "Roots of #{n} are (#{r} #{p-r}) mod #{p}" } else { say "No solution for (#{n}, #{p})" }
}</lang>
- Output:
Roots of 10 are (6 7) mod 13 Roots of 56 are (37 64) mod 101 Roots of 8218 are (9872 135) mod 10007 No solution for (8219, 10007) Roots of 331575 are (855842 144161) mod 1000003 Roots of 665165880 are (475131702 524868305) mod 1000000007 Roots of 881398088036 are (791399408049 208600591990) mod 1000000000039 Roots of 34035243914635549601583369544560650254325084643201 are (82563118828090362261378993957450213573687113690751 17436881171909637738621006042549786426312886309400) mod 100000000000000000000000000000000000000000000000151
zkl
Uses lib GMP (GNU MP Bignum Library). <lang zkl>var [const] BN=Import("zklBigNum"); //libGMP fcn modEq(a,b,p) { (a-b)%p==0 } fcn Legendre(a,p){ a.powm((p - 1)/2,p) }
class Fp2{ // Arithmetic in Fp^2
fcn init(_x,_y){ var [const] x=BN(_x), y=BN(_y) } // two big ints //fcn add(b,p){ self((x + b.x)%p,(y + b.y)%p) } // a + b fcn mul(b,p,w2){ self(( x*b.x + y*b.y*w2 )%p, (x*b.y + y*b.x) %p) } // a * b fcn square(p,w2){ mul(self,p,w2) } // a * a == self.mul(self,p,w2) fcn pow(n,p,w2){ // a ^ n if (n==0) self(1,0); else if(n==1) self; else if(n==2) square(p,w2); else if(n.isEven) pow(n/2,p,w2).square(p,w2); else mul(pow(n-1,p,w2),p,w2) }
}
fcn Cipolla(n,p){ n=BN(n); // x^2 == n (mod p) ?
if(Legendre(n,p)!=1) // check n is a square throw(Exception.AssertionError("not a square (mod p)"+vm.arglist)); // iterate until suitable 'a' found (the first one found) a:=[BN(2)..p].filter1('wrap(a){ Legendre(a*a-n,p)==(p-1) }); w2:=a*a - n; r:=Fp2(a,1).pow((p + 1)/2,p,w2); // (Fp2 a 1) = a + w2 x:=r.x; _assert_(r.y==0,"r.y==0 : "+r.y); // hope that w has vanished _assert_(modEq(n,x*x,p),"modEq(n,x*x,p)"); // checking the result println("Roots of %d are (%d,%d) (mod %d)".fmt(n,x,(p-x)%p,p)); return(x,(p-x)%p);
}</lang> <lang zkl>foreach n,p in (T( T(10,13),T(56,101),T(8218,10007),T(8219,10007),T(331575,1000003), T(665165880,1000000007),T(881398088036,1000000000039), T("34035243914635549601583369544560650254325084643201", BN(10).pow(50) + 151) )){
try{ Cipolla(n,p) }catch{ println(__exception) }
}</lang>
- Output:
Roots of 10 are (6,7) (mod 13) Roots of 56 are (37,64) (mod 101) Roots of 8218 are (9872,135) (mod 10007) AssertionError(not a square (mod p)L(8219,10007)) Roots of 331575 are (855842,144161) (mod 1000003) Roots of 665165880 are (524868305,475131702) (mod 1000000007) Roots of 881398088036 are (208600591990,791399408049) (mod 1000000000039) Roots of 34035243914635549601583369544560650254325084643201 are (17436881171909637738621006042549786426312886309400,82563118828090362261378993957450213573687113690751) (mod 100000000000000000000000000000000000000000000000151)