ref: f11139d4c918802a87730bc14d094670ee4ce572
dir: /libmp/mpmul.c/
#include "os.h" #include <mp.h> #include "dat.h" // // from knuth's 1969 seminumberical algorithms, pp 233-235 and pp 258-260 // // mpvecmul is an assembly language routine that performs the inner // loop. // // the karatsuba trade off is set empiricly by measuring the algs on // a 400 MHz Pentium II. // // karatsuba like (see knuth pg 258) // prereq: p is already zeroed static void mpkaratsuba(mpdigit *a, int alen, mpdigit *b, int blen, mpdigit *p) { mpdigit *t, *u0, *u1, *v0, *v1, *u0v0, *u1v1, *res, *diffprod; int u0len, u1len, v0len, v1len, reslen; int sign, n; // divide each piece in half n = alen/2; if(alen&1) n++; u0len = n; u1len = alen-n; if(blen > n){ v0len = n; v1len = blen-n; } else { v0len = blen; v1len = 0; } u0 = a; u1 = a + u0len; v0 = b; v1 = b + v0len; // room for the partial products t = mallocz(Dbytes*5*(2*n+1), 1); if(t == nil) sysfatal("mpkaratsuba: %r"); u0v0 = t; u1v1 = t + (2*n+1); diffprod = t + 2*(2*n+1); res = t + 3*(2*n+1); reslen = 4*n+1; // t[0] = (u1-u0) sign = 1; if(mpveccmp(u1, u1len, u0, u0len) < 0){ sign = -1; mpvecsub(u0, u0len, u1, u1len, u0v0); } else mpvecsub(u1, u1len, u0, u1len, u0v0); // t[1] = (v0-v1) if(mpveccmp(v0, v0len, v1, v1len) < 0){ sign *= -1; mpvecsub(v1, v1len, v0, v1len, u1v1); } else mpvecsub(v0, v0len, v1, v1len, u1v1); // t[4:5] = (u1-u0)*(v0-v1) mpvecmul(u0v0, u0len, u1v1, v0len, diffprod); // t[0:1] = u1*v1 memset(t, 0, 2*(2*n+1)*Dbytes); if(v1len > 0) mpvecmul(u1, u1len, v1, v1len, u1v1); // t[2:3] = u0v0 mpvecmul(u0, u0len, v0, v0len, u0v0); // res = u0*v0<<n + u0*v0 mpvecadd(res, reslen, u0v0, u0len+v0len, res); mpvecadd(res+n, reslen-n, u0v0, u0len+v0len, res+n); // res += u1*v1<<n + u1*v1<<2*n if(v1len > 0){ mpvecadd(res+n, reslen-n, u1v1, u1len+v1len, res+n); mpvecadd(res+2*n, reslen-2*n, u1v1, u1len+v1len, res+2*n); } // res += (u1-u0)*(v0-v1)<<n if(sign < 0) mpvecsub(res+n, reslen-n, diffprod, u0len+v0len, res+n); else mpvecadd(res+n, reslen-n, diffprod, u0len+v0len, res+n); memmove(p, res, (alen+blen)*Dbytes); free(t); } #define KARATSUBAMIN 32 void mpvecmul(mpdigit *a, int alen, mpdigit *b, int blen, mpdigit *p) { int i; mpdigit d; mpdigit *t; // both mpvecdigmuladd and karatsuba are fastest when a is the longer vector if(alen < blen){ i = alen; alen = blen; blen = i; t = a; a = b; b = t; } if(alen >= KARATSUBAMIN && blen > 1){ // O(n^1.585) mpkaratsuba(a, alen, b, blen, p); } else { // O(n^2) for(i = 0; i < blen; i++){ d = b[i]; if(d != 0) mpvecdigmuladd(a, alen, d, &p[i]); } } } void mpvectsmul(mpdigit *a, int alen, mpdigit *b, int blen, mpdigit *p) { int i; mpdigit *t; if(alen < blen){ i = alen; alen = blen; blen = i; t = a; a = b; b = t; } if(blen == 0) return; for(i = 0; i < blen; i++) mpvecdigmuladd(a, alen, b[i], &p[i]); } void mpmul(mpint *b1, mpint *b2, mpint *prod) { mpint *oprod; oprod = prod; if(prod == b1 || prod == b2){ prod = mpnew(0); prod->flags = oprod->flags; } prod->flags |= (b1->flags | b2->flags) & MPtimesafe; prod->top = 0; mpbits(prod, (b1->top+b2->top+1)*Dbits); if(prod->flags & MPtimesafe) mpvectsmul(b1->p, b1->top, b2->p, b2->top, prod->p); else mpvecmul(b1->p, b1->top, b2->p, b2->top, prod->p); prod->top = b1->top+b2->top+1; prod->sign = b1->sign*b2->sign; mpnorm(prod); if(oprod != prod){ mpassign(prod, oprod); mpfree(prod); } }