| # |
| # Copyright (c) 2008-2012 Stefan Krah. All rights reserved. |
| # |
| # Redistribution and use in source and binary forms, with or without |
| # modification, are permitted provided that the following conditions |
| # are met: |
| # |
| # 1. Redistributions of source code must retain the above copyright |
| # notice, this list of conditions and the following disclaimer. |
| # |
| # 2. Redistributions in binary form must reproduce the above copyright |
| # notice, this list of conditions and the following disclaimer in the |
| # documentation and/or other materials provided with the distribution. |
| # |
| # THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS "AS IS" AND |
| # ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE |
| # IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE |
| # ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE |
| # FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL |
| # DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS |
| # OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) |
| # HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT |
| # LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY |
| # OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF |
| # SUCH DAMAGE. |
| # |
| |
| |
| ###################################################################### |
| # This file lists and checks some of the constants and limits used # |
| # in libmpdec's Number Theoretic Transform. At the end of the file # |
| # there is an example function for the plain DFT transform. # |
| ###################################################################### |
| |
| |
| # |
| # Number theoretic transforms are done in subfields of F(p). P[i] |
| # are the primes, D[i] = P[i] - 1 are highly composite and w[i] |
| # are the respective primitive roots of F(p). |
| # |
| # The strategy is to convolute two coefficients modulo all three |
| # primes, then use the Chinese Remainder Theorem on the three |
| # result arrays to recover the result in the usual base RADIX |
| # form. |
| # |
| |
| # ====================================================================== |
| # Primitive roots |
| # ====================================================================== |
| |
| # |
| # Verify primitive roots: |
| # |
| # For a prime field, r is a primitive root if and only if for all prime |
| # factors f of p-1, r**((p-1)/f) =/= 1 (mod p). |
| # |
| def prod(F, E): |
| """Check that the factorization of P-1 is correct. F is the list of |
| factors of P-1, E lists the number of occurrences of each factor.""" |
| x = 1 |
| for y, z in zip(F, E): |
| x *= y**z |
| return x |
| |
| def is_primitive_root(r, p, factors, exponents): |
| """Check if r is a primitive root of F(p).""" |
| if p != prod(factors, exponents) + 1: |
| return False |
| for f in factors: |
| q, control = divmod(p-1, f) |
| if control != 0: |
| return False |
| if pow(r, q, p) == 1: |
| return False |
| return True |
| |
| |
| # ================================================================= |
| # Constants and limits for the 64-bit version |
| # ================================================================= |
| |
| RADIX = 10**19 |
| |
| # Primes P1, P2 and P3: |
| P = [2**64-2**32+1, 2**64-2**34+1, 2**64-2**40+1] |
| |
| # P-1, highly composite. The transform length d is variable and |
| # must divide D = P-1. Since all D are divisible by 3 * 2**32, |
| # transform lengths can be 2**n or 3 * 2**n (where n <= 32). |
| D = [2**32 * 3 * (5 * 17 * 257 * 65537), |
| 2**34 * 3**2 * (7 * 11 * 31 * 151 * 331), |
| 2**40 * 3**2 * (5 * 7 * 13 * 17 * 241)] |
| |
| # Prime factors of P-1 and their exponents: |
| F = [(2,3,5,17,257,65537), (2,3,7,11,31,151,331), (2,3,5,7,13,17,241)] |
| E = [(32,1,1,1,1,1), (34,2,1,1,1,1,1), (40,2,1,1,1,1,1)] |
| |
| # Maximum transform length for 2**n. Above that only 3 * 2**31 |
| # or 3 * 2**32 are possible. |
| MPD_MAXTRANSFORM_2N = 2**32 |
| |
| |
| # Limits in the terminology of Pollard's paper: |
| m2 = (MPD_MAXTRANSFORM_2N * 3) // 2 # Maximum length of the smaller array. |
| M1 = M2 = RADIX-1 # Maximum value per single word. |
| L = m2 * M1 * M2 |
| P[0] * P[1] * P[2] > 2 * L |
| |
| |
| # Primitive roots of F(P1), F(P2) and F(P3): |
| w = [7, 10, 19] |
| |
| # The primitive roots are correct: |
| for i in range(3): |
| if not is_primitive_root(w[i], P[i], F[i], E[i]): |
| print("FAIL") |
| |
| |
| # ================================================================= |
| # Constants and limits for the 32-bit version |
| # ================================================================= |
| |
| RADIX = 10**9 |
| |
| # Primes P1, P2 and P3: |
| P = [2113929217, 2013265921, 1811939329] |
| |
| # P-1, highly composite. All D = P-1 are divisible by 3 * 2**25, |
| # allowing for transform lengths up to 3 * 2**25 words. |
| D = [2**25 * 3**2 * 7, |
| 2**27 * 3 * 5, |
| 2**26 * 3**3] |
| |
| # Prime factors of P-1 and their exponents: |
| F = [(2,3,7), (2,3,5), (2,3)] |
| E = [(25,2,1), (27,1,1), (26,3)] |
| |
| # Maximum transform length for 2**n. Above that only 3 * 2**24 or |
| # 3 * 2**25 are possible. |
| MPD_MAXTRANSFORM_2N = 2**25 |
| |
| |
| # Limits in the terminology of Pollard's paper: |
| m2 = (MPD_MAXTRANSFORM_2N * 3) // 2 # Maximum length of the smaller array. |
| M1 = M2 = RADIX-1 # Maximum value per single word. |
| L = m2 * M1 * M2 |
| P[0] * P[1] * P[2] > 2 * L |
| |
| |
| # Primitive roots of F(P1), F(P2) and F(P3): |
| w = [5, 31, 13] |
| |
| # The primitive roots are correct: |
| for i in range(3): |
| if not is_primitive_root(w[i], P[i], F[i], E[i]): |
| print("FAIL") |
| |
| |
| # ====================================================================== |
| # Example transform using a single prime |
| # ====================================================================== |
| |
| def ntt(lst, dir): |
| """Perform a transform on the elements of lst. len(lst) must |
| be 2**n or 3 * 2**n, where n <= 25. This is the slow DFT.""" |
| p = 2113929217 # prime |
| d = len(lst) # transform length |
| d_prime = pow(d, (p-2), p) # inverse of d |
| xi = (p-1)//d |
| w = 5 # primitive root of F(p) |
| r = pow(w, xi, p) # primitive root of the subfield |
| r_prime = pow(w, (p-1-xi), p) # inverse of r |
| if dir == 1: # forward transform |
| a = lst # input array |
| A = [0] * d # transformed values |
| for i in range(d): |
| s = 0 |
| for j in range(d): |
| s += a[j] * pow(r, i*j, p) |
| A[i] = s % p |
| return A |
| elif dir == -1: # backward transform |
| A = lst # input array |
| a = [0] * d # transformed values |
| for j in range(d): |
| s = 0 |
| for i in range(d): |
| s += A[i] * pow(r_prime, i*j, p) |
| a[j] = (d_prime * s) % p |
| return a |
| |
| def ntt_convolute(a, b): |
| """convolute arrays a and b.""" |
| assert(len(a) == len(b)) |
| x = ntt(a, 1) |
| y = ntt(b, 1) |
| for i in range(len(a)): |
| y[i] = y[i] * x[i] |
| r = ntt(y, -1) |
| return r |
| |
| |
| # Example: Two arrays representing 21 and 81 in little-endian: |
| a = [1, 2, 0, 0] |
| b = [1, 8, 0, 0] |
| |
| assert(ntt_convolute(a, b) == [1, 10, 16, 0]) |
| assert(21 * 81 == (1*10**0 + 10*10**1 + 16*10**2 + 0*10**3)) |