#include #include #include #include #include NTL_START_IMPL static void IterPower(ZZ_pE& c, const ZZ_pE& a, long n) { ZZ_pE res; long i; res = a; for (i = 0; i < n; i++) power(res, res, ZZ_p::modulus()); c = res; } void SquareFreeDecomp(vec_pair_ZZ_pEX_long& u, const ZZ_pEX& ff) { ZZ_pEX f = ff; if (!IsOne(LeadCoeff(f))) Error("SquareFreeDecomp: bad args"); ZZ_pEX r, t, v, tmp1; long m, j, finished, done; u.SetLength(0); if (deg(f) == 0) return; m = 1; finished = 0; do { j = 1; diff(tmp1, f); GCD(r, f, tmp1); div(t, f, r); if (deg(t) > 0) { done = 0; do { GCD(v, r, t); div(tmp1, t, v); if (deg(tmp1) > 0) append(u, cons(tmp1, j*m)); if (deg(v) > 0) { div(r, r, v); t = v; j++; } else done = 1; } while (!done); if (deg(r) == 0) finished = 1; } if (!finished) { /* r is a p-th power */ long k, d; long p = to_long(ZZ_p::modulus()); d = deg(r)/p; f.rep.SetLength(d+1); for (k = 0; k <= d; k++) IterPower(f.rep[k], r.rep[k*p], ZZ_pE::degree()-1); m = m*p; } } while (!finished); } static void AbsTraceMap(ZZ_pEX& h, const ZZ_pEX& a, const ZZ_pEXModulus& F) { ZZ_pEX res, tmp; long k = NumBits(ZZ_pE::cardinality())-1; res = a; tmp = a; long i; for (i = 0; i < k-1; i++) { SqrMod(tmp, tmp, F); add(res, res, tmp); } h = res; } void FrobeniusMap(ZZ_pEX& h, const ZZ_pEXModulus& F) { PowerXMod(h, ZZ_pE::cardinality(), F); } static void RecFindRoots(vec_ZZ_pE& x, const ZZ_pEX& f) { if (deg(f) == 0) return; if (deg(f) == 1) { long k = x.length(); x.SetLength(k+1); negate(x[k], ConstTerm(f)); return; } ZZ_pEX h; ZZ_pEX r; { ZZ_pEXModulus F; build(F, f); do { random(r, deg(F)); if (IsOdd(ZZ_pE::cardinality())) { PowerMod(h, r, RightShift(ZZ_pE::cardinality(), 1), F); sub(h, h, 1); } else { AbsTraceMap(h, r, F); } GCD(h, h, f); } while (deg(h) <= 0 || deg(h) == deg(f)); } RecFindRoots(x, h); div(h, f, h); RecFindRoots(x, h); } void FindRoots(vec_ZZ_pE& x, const ZZ_pEX& ff) { ZZ_pEX f = ff; if (!IsOne(LeadCoeff(f))) Error("FindRoots: bad args"); x.SetMaxLength(deg(f)); x.SetLength(0); RecFindRoots(x, f); } void split(ZZ_pEX& f1, ZZ_pEX& g1, ZZ_pEX& f2, ZZ_pEX& g2, const ZZ_pEX& f, const ZZ_pEX& g, const vec_ZZ_pE& roots, long lo, long mid) { long r = mid-lo+1; ZZ_pEXModulus F; build(F, f); vec_ZZ_pE lroots(INIT_SIZE, r); long i; for (i = 0; i < r; i++) lroots[i] = roots[lo+i]; ZZ_pEX h, a, d; BuildFromRoots(h, lroots); CompMod(a, h, g, F); GCD(f1, a, f); div(f2, f, f1); rem(g1, g, f1); rem(g2, g, f2); } void RecFindFactors(vec_ZZ_pEX& factors, const ZZ_pEX& f, const ZZ_pEX& g, const vec_ZZ_pE& roots, long lo, long hi) { long r = hi-lo+1; if (r == 0) return; if (r == 1) { append(factors, f); return; } ZZ_pEX f1, g1, f2, g2; long mid = (lo+hi)/2; split(f1, g1, f2, g2, f, g, roots, lo, mid); RecFindFactors(factors, f1, g1, roots, lo, mid); RecFindFactors(factors, f2, g2, roots, mid+1, hi); } void FindFactors(vec_ZZ_pEX& factors, const ZZ_pEX& f, const ZZ_pEX& g, const vec_ZZ_pE& roots) { long r = roots.length(); factors.SetMaxLength(r); factors.SetLength(0); RecFindFactors(factors, f, g, roots, 0, r-1); } void IterFindFactors(vec_ZZ_pEX& factors, const ZZ_pEX& f, const ZZ_pEX& g, const vec_ZZ_pE& roots) { long r = roots.length(); long i; ZZ_pEX h; factors.SetLength(r); for (i = 0; i < r; i++) { sub(h, g, roots[i]); GCD(factors[i], f, h); } } void TraceMap(ZZ_pEX& w, const ZZ_pEX& a, long d, const ZZ_pEXModulus& F, const ZZ_pEX& b) { if (d < 0) Error("TraceMap: bad args"); ZZ_pEX y, z, t; z = b; y = a; clear(w); while (d) { if (d == 1) { if (IsZero(w)) w = y; else { CompMod(w, w, z, F); add(w, w, y); } } else if ((d & 1) == 0) { Comp2Mod(z, t, z, y, z, F); add(y, t, y); } else if (IsZero(w)) { w = y; Comp2Mod(z, t, z, y, z, F); add(y, t, y); } else { Comp3Mod(z, t, w, z, y, w, z, F); add(w, w, y); add(y, t, y); } d = d >> 1; } } void PowerCompose(ZZ_pEX& y, const ZZ_pEX& h, long q, const ZZ_pEXModulus& F) { if (q < 0) Error("PowerCompose: bad args"); ZZ_pEX z(INIT_SIZE, F.n); long sw; z = h; SetX(y); while (q) { sw = 0; if (q > 1) sw = 2; if (q & 1) { if (IsX(y)) y = z; else sw = sw | 1; } switch (sw) { case 0: break; case 1: CompMod(y, y, z, F); break; case 2: CompMod(z, z, z, F); break; case 3: Comp2Mod(y, z, y, z, z, F); break; } q = q >> 1; } } long ProbIrredTest(const ZZ_pEX& f, long iter) { long n = deg(f); if (n <= 0) return 0; if (n == 1) return 1; ZZ_pEXModulus F; build(F, f); ZZ_pEX b, r, s; FrobeniusMap(b, F); long all_zero = 1; long i; for (i = 0; i < iter; i++) { random(r, n); TraceMap(s, r, n, F, b); all_zero = all_zero && IsZero(s); if (deg(s) > 0) return 0; } if (!all_zero || (n & 1)) return 1; PowerCompose(s, b, n/2, F); return !IsX(s); } long ZZ_pEX_BlockingFactor = 10; void RootEDF(vec_ZZ_pEX& factors, const ZZ_pEX& f, long verbose) { vec_ZZ_pE roots; double t; if (verbose) { cerr << "finding roots..."; t = GetTime(); } FindRoots(roots, f); if (verbose) { cerr << (GetTime()-t) << "\n"; } long r = roots.length(); factors.SetLength(r); for (long j = 0; j < r; j++) { SetX(factors[j]); sub(factors[j], factors[j], roots[j]); } } void EDFSplit(vec_ZZ_pEX& v, const ZZ_pEX& f, const ZZ_pEX& b, long d) { ZZ_pEX a, g, h; ZZ_pEXModulus F; vec_ZZ_pE roots; build(F, f); long n = F.n; long r = n/d; random(a, n); TraceMap(g, a, d, F, b); MinPolyMod(h, g, F, r); FindRoots(roots, h); FindFactors(v, f, g, roots); } void RecEDF(vec_ZZ_pEX& factors, const ZZ_pEX& f, const ZZ_pEX& b, long d, long verbose) { vec_ZZ_pEX v; long i; ZZ_pEX bb; if (verbose) cerr << "+"; EDFSplit(v, f, b, d); for (i = 0; i < v.length(); i++) { if (deg(v[i]) == d) { append(factors, v[i]); } else { ZZ_pEX bb; rem(bb, b, v[i]); RecEDF(factors, v[i], bb, d, verbose); } } } void EDF(vec_ZZ_pEX& factors, const ZZ_pEX& ff, const ZZ_pEX& bb, long d, long verbose) { ZZ_pEX f = ff; ZZ_pEX b = bb; if (!IsOne(LeadCoeff(f))) Error("EDF: bad args"); long n = deg(f); long r = n/d; if (r == 0) { factors.SetLength(0); return; } if (r == 1) { factors.SetLength(1); factors[0] = f; return; } if (d == 1) { RootEDF(factors, f, verbose); return; } double t; if (verbose) { cerr << "computing EDF(" << d << "," << r << ")..."; t = GetTime(); } factors.SetLength(0); RecEDF(factors, f, b, d, verbose); if (verbose) cerr << (GetTime()-t) << "\n"; } void SFCanZass(vec_ZZ_pEX& factors, const ZZ_pEX& ff, long verbose) { ZZ_pEX f = ff; if (!IsOne(LeadCoeff(f))) Error("SFCanZass: bad args"); if (deg(f) == 0) { factors.SetLength(0); return; } if (deg(f) == 1) { factors.SetLength(1); factors[0] = f; return; } factors.SetLength(0); double t; ZZ_pEXModulus F; build(F, f); ZZ_pEX h; if (verbose) { cerr << "computing X^p..."; t = GetTime(); } FrobeniusMap(h, F); if (verbose) { cerr << (GetTime()-t) << "\n"; } vec_pair_ZZ_pEX_long u; if (verbose) { cerr << "computing DDF..."; t = GetTime(); } NewDDF(u, f, h, verbose); if (verbose) { t = GetTime()-t; cerr << "DDF time: " << t << "\n"; } ZZ_pEX hh; vec_ZZ_pEX v; long i; for (i = 0; i < u.length(); i++) { const ZZ_pEX& g = u[i].a; long d = u[i].b; long r = deg(g)/d; if (r == 1) { // g is already irreducible append(factors, g); } else { // must perform EDF if (d == 1) { // root finding RootEDF(v, g, verbose); append(factors, v); } else { // general case rem(hh, h, g); EDF(v, g, hh, d, verbose); append(factors, v); } } } } void CanZass(vec_pair_ZZ_pEX_long& factors, const ZZ_pEX& f, long verbose) { if (!IsOne(LeadCoeff(f))) Error("CanZass: bad args"); double t; vec_pair_ZZ_pEX_long sfd; vec_ZZ_pEX x; if (verbose) { cerr << "square-free decomposition..."; t = GetTime(); } SquareFreeDecomp(sfd, f); if (verbose) cerr << (GetTime()-t) << "\n"; factors.SetLength(0); long i, j; for (i = 0; i < sfd.length(); i++) { if (verbose) { cerr << "factoring multiplicity " << sfd[i].b << ", deg = " << deg(sfd[i].a) << "\n"; } SFCanZass(x, sfd[i].a, verbose); for (j = 0; j < x.length(); j++) append(factors, cons(x[j], sfd[i].b)); } } void mul(ZZ_pEX& f, const vec_pair_ZZ_pEX_long& v) { long i, j, n; n = 0; for (i = 0; i < v.length(); i++) n += v[i].b*deg(v[i].a); ZZ_pEX g(INIT_SIZE, n+1); set(g); for (i = 0; i < v.length(); i++) for (j = 0; j < v[i].b; j++) { mul(g, g, v[i].a); } f = g; } long BaseCase(const ZZ_pEX& h, long q, long a, const ZZ_pEXModulus& F) { long b, e; ZZ_pEX lh(INIT_SIZE, F.n); lh = h; b = 1; e = 0; while (e < a-1 && !IsX(lh)) { e++; b *= q; PowerCompose(lh, lh, q, F); } if (!IsX(lh)) b *= q; return b; } void TandemPowerCompose(ZZ_pEX& y1, ZZ_pEX& y2, const ZZ_pEX& h, long q1, long q2, const ZZ_pEXModulus& F) { ZZ_pEX z(INIT_SIZE, F.n); long sw; z = h; SetX(y1); SetX(y2); while (q1 || q2) { sw = 0; if (q1 > 1 || q2 > 1) sw = 4; if (q1 & 1) { if (IsX(y1)) y1 = z; else sw = sw | 2; } if (q2 & 1) { if (IsX(y2)) y2 = z; else sw = sw | 1; } switch (sw) { case 0: break; case 1: CompMod(y2, y2, z, F); break; case 2: CompMod(y1, y1, z, F); break; case 3: Comp2Mod(y1, y2, y1, y2, z, F); break; case 4: CompMod(z, z, z, F); break; case 5: Comp2Mod(z, y2, z, y2, z, F); break; case 6: Comp2Mod(z, y1, z, y1, z, F); break; case 7: Comp3Mod(z, y1, y2, z, y1, y2, z, F); break; } q1 = q1 >> 1; q2 = q2 >> 1; } } long RecComputeDegree(long u, const ZZ_pEX& h, const ZZ_pEXModulus& F, FacVec& fvec) { if (IsX(h)) return 1; if (fvec[u].link == -1) return BaseCase(h, fvec[u].q, fvec[u].a, F); ZZ_pEX h1, h2; long q1, q2, r1, r2; q1 = fvec[fvec[u].link].val; q2 = fvec[fvec[u].link+1].val; TandemPowerCompose(h1, h2, h, q1, q2, F); r1 = RecComputeDegree(fvec[u].link, h2, F, fvec); r2 = RecComputeDegree(fvec[u].link+1, h1, F, fvec); return r1*r2; } long RecComputeDegree(const ZZ_pEX& h, const ZZ_pEXModulus& F) // f = F.f is assumed to be an "equal degree" polynomial // h = X^p mod f // the common degree of the irreducible factors of f is computed { if (F.n == 1 || IsX(h)) return 1; FacVec fvec; FactorInt(fvec, F.n); return RecComputeDegree(fvec.length()-1, h, F, fvec); } void FindRoot(ZZ_pE& root, const ZZ_pEX& ff) // finds a root of ff. // assumes that ff is monic and splits into distinct linear factors { ZZ_pEXModulus F; ZZ_pEX h, h1, f; ZZ_pEX r; f = ff; if (!IsOne(LeadCoeff(f))) Error("FindRoot: bad args"); if (deg(f) == 0) Error("FindRoot: bad args"); while (deg(f) > 1) { build(F, f); random(r, deg(F)); if (IsOdd(ZZ_pE::cardinality())) { PowerMod(h, r, RightShift(ZZ_pE::cardinality(), 1), F); sub(h, h, 1); } else { AbsTraceMap(h, r, F); } GCD(h, h, f); if (deg(h) > 0 && deg(h) < deg(f)) { if (deg(h) > deg(f)/2) div(f, f, h); else f = h; } } negate(root, ConstTerm(f)); } static long power(long a, long e) { long i, res; res = 1; for (i = 1; i <= e; i++) res = res * a; return res; } static long IrredBaseCase(const ZZ_pEX& h, long q, long a, const ZZ_pEXModulus& F) { long e; ZZ_pEX X, s, d; e = power(q, a-1); PowerCompose(s, h, e, F); SetX(X); sub(s, s, X); GCD(d, F.f, s); return IsOne(d); } static long RecIrredTest(long u, const ZZ_pEX& h, const ZZ_pEXModulus& F, const FacVec& fvec) { long q1, q2; ZZ_pEX h1, h2; if (IsX(h)) return 0; if (fvec[u].link == -1) { return IrredBaseCase(h, fvec[u].q, fvec[u].a, F); } q1 = fvec[fvec[u].link].val; q2 = fvec[fvec[u].link+1].val; TandemPowerCompose(h1, h2, h, q1, q2, F); return RecIrredTest(fvec[u].link, h2, F, fvec) && RecIrredTest(fvec[u].link+1, h1, F, fvec); } long DetIrredTest(const ZZ_pEX& f) { if (deg(f) <= 0) return 0; if (deg(f) == 1) return 1; ZZ_pEXModulus F; build(F, f); ZZ_pEX h; FrobeniusMap(h, F); ZZ_pEX s; PowerCompose(s, h, F.n, F); if (!IsX(s)) return 0; FacVec fvec; FactorInt(fvec, F.n); return RecIrredTest(fvec.length()-1, h, F, fvec); } long IterIrredTest(const ZZ_pEX& f) { if (deg(f) <= 0) return 0; if (deg(f) == 1) return 1; ZZ_pEXModulus F; build(F, f); ZZ_pEX h; FrobeniusMap(h, F); long CompTableSize = 2*SqrRoot(deg(f)); ZZ_pEXArgument H; build(H, h, F, CompTableSize); long i, d, limit, limit_sqr; ZZ_pEX g, X, t, prod; SetX(X); i = 0; g = h; d = 1; limit = 2; limit_sqr = limit*limit; set(prod); while (2*d <= deg(f)) { sub(t, g, X); MulMod(prod, prod, t, F); i++; if (i == limit_sqr) { GCD(t, f, prod); if (!IsOne(t)) return 0; set(prod); limit++; limit_sqr = limit*limit; i = 0; } d = d + 1; if (2*d <= deg(f)) { CompMod(g, g, H, F); } } if (i > 0) { GCD(t, f, prod); if (!IsOne(t)) return 0; } return 1; } static void MulByXPlusY(vec_ZZ_pEX& h, const ZZ_pEX& f, const ZZ_pEX& g) // h represents the bivariate polynomial h[0] + h[1]*Y + ... + h[n-1]*Y^k, // where the h[i]'s are polynomials in X, each of degree < deg(f), // and k < deg(g). // h is replaced by the bivariate polynomial h*(X+Y) (mod f(X), g(Y)). { long n = deg(g); long k = h.length()-1; if (k < 0) return; if (k < n-1) { h.SetLength(k+2); h[k+1] = h[k]; for (long i = k; i >= 1; i--) { MulByXMod(h[i], h[i], f); add(h[i], h[i], h[i-1]); } MulByXMod(h[0], h[0], f); } else { ZZ_pEX b, t; b = h[n-1]; for (long i = n-1; i >= 1; i--) { mul(t, b, g.rep[i]); MulByXMod(h[i], h[i], f); add(h[i], h[i], h[i-1]); sub(h[i], h[i], t); } mul(t, b, g.rep[0]); MulByXMod(h[0], h[0], f); sub(h[0], h[0], t); } // normalize k = h.length()-1; while (k >= 0 && IsZero(h[k])) k--; h.SetLength(k+1); } static void IrredCombine(ZZ_pEX& x, const ZZ_pEX& f, const ZZ_pEX& g) { if (deg(f) < deg(g)) { IrredCombine(x, g, f); return; } // deg(f) >= deg(g)...not necessary, but maybe a little more // time & space efficient long df = deg(f); long dg = deg(g); long m = df*dg; vec_ZZ_pEX h(INIT_SIZE, dg); long i; for (i = 0; i < dg; i++) h[i].SetMaxLength(df); h.SetLength(1); set(h[0]); vec_ZZ_pE a; a.SetLength(2*m); for (i = 0; i < 2*m; i++) { a[i] = ConstTerm(h[0]); if (i < 2*m-1) MulByXPlusY(h, f, g); } MinPolySeq(x, a, m); } static void BuildPrimePowerIrred(ZZ_pEX& f, long q, long e) { long n = power(q, e); do { random(f, n); SetCoeff(f, n); } while (!IterIrredTest(f)); } static void RecBuildIrred(ZZ_pEX& f, long u, const FacVec& fvec) { if (fvec[u].link == -1) BuildPrimePowerIrred(f, fvec[u].q, fvec[u].a); else { ZZ_pEX g, h; RecBuildIrred(g, fvec[u].link, fvec); RecBuildIrred(h, fvec[u].link+1, fvec); IrredCombine(f, g, h); } } void BuildIrred(ZZ_pEX& f, long n) { if (n <= 0) Error("BuildIrred: n must be positive"); if (NTL_OVERFLOW(n, 1, 0)) Error("overflow in BuildIrred"); if (n == 1) { SetX(f); return; } FacVec fvec; FactorInt(fvec, n); RecBuildIrred(f, fvec.length()-1, fvec); } #if 0 void BuildIrred(ZZ_pEX& f, long n) { if (n <= 0) Error("BuildIrred: n must be positive"); if (n == 1) { SetX(f); return; } ZZ_pEX g; do { random(g, n); SetCoeff(g, n); } while (!IterIrredTest(g)); f = g; } #endif void BuildRandomIrred(ZZ_pEX& f, const ZZ_pEX& g) { ZZ_pEXModulus G; ZZ_pEX h, ff; build(G, g); do { random(h, deg(g)); IrredPolyMod(ff, h, G); } while (deg(ff) < deg(g)); f = ff; } /************* NEW DDF ****************/ long ZZ_pEX_GCDTableSize = 4; char ZZ_pEX_stem[256] = ""; double ZZ_pEXFileThresh = 256; static vec_ZZ_pEX BabyStepFile; static vec_ZZ_pEX GiantStepFile; static long use_files; static double CalcTableSize(long n, long k) { double sz = ZZ_p::storage(); sz = sz*ZZ_pE::degree(); sz = sz + NTL_VECTOR_HEADER_SIZE + sizeof(vec_ZZ_p); sz = sz*n; sz = sz + NTL_VECTOR_HEADER_SIZE + sizeof(vec_ZZ_pE); sz = sz * k; sz = sz/1024; return sz; } static void GenerateBabySteps(ZZ_pEX& h1, const ZZ_pEX& f, const ZZ_pEX& h, long k, long verbose) { double t; if (verbose) { cerr << "generating baby steps..."; t = GetTime(); } ZZ_pEXModulus F; build(F, f); ZZ_pEXArgument H; #if 0 double n2 = sqrt(double(F.n)); double n4 = sqrt(n2); double n34 = n2*n4; long sz = long(ceil(n34/sqrt(sqrt(2.0)))); #else long sz = 2*SqrRoot(F.n); #endif build(H, h, F, sz); h1 = h; long i; if (!use_files) { BabyStepFile.kill(); BabyStepFile.SetLength(k-1); } for (i = 1; i <= k-1; i++) { if (use_files) { ofstream s; OpenWrite(s, FileName(ZZ_pEX_stem, "baby", i)); s << h1 << "\n"; s.close(); } else BabyStepFile(i) = h1; CompMod(h1, h1, H, F); if (verbose) cerr << "+"; } if (verbose) cerr << (GetTime()-t) << "\n"; } static void GenerateGiantSteps(const ZZ_pEX& f, const ZZ_pEX& h, long l, long verbose) { double t; if (verbose) { cerr << "generating giant steps..."; t = GetTime(); } ZZ_pEXModulus F; build(F, f); ZZ_pEXArgument H; #if 0 double n2 = sqrt(double(F.n)); double n4 = sqrt(n2); double n34 = n2*n4; long sz = long(ceil(n34/sqrt(sqrt(2.0)))); #else long sz = 2*SqrRoot(F.n); #endif build(H, h, F, sz); ZZ_pEX h1; h1 = h; long i; if (!use_files) { GiantStepFile.kill(); GiantStepFile.SetLength(l); } for (i = 1; i <= l-1; i++) { if (use_files) { ofstream s; OpenWrite(s, FileName(ZZ_pEX_stem, "giant", i)); s << h1 << "\n"; s.close(); } else GiantStepFile(i) = h1; CompMod(h1, h1, H, F); if (verbose) cerr << "+"; } if (use_files) { ofstream s; OpenWrite(s, FileName(ZZ_pEX_stem, "giant", i)); s << h1 << "\n"; s.close(); } else GiantStepFile(i) = h1; if (verbose) cerr << (GetTime()-t) << "\n"; } static void FileCleanup(long k, long l) { if (use_files) { long i; for (i = 1; i <= k-1; i++) remove(FileName(ZZ_pEX_stem, "baby", i)); for (i = 1; i <= l; i++) remove(FileName(ZZ_pEX_stem, "giant", i)); } else { BabyStepFile.kill(); GiantStepFile.kill(); } } static void NewAddFactor(vec_pair_ZZ_pEX_long& u, const ZZ_pEX& g, long m, long verbose) { long len = u.length(); u.SetLength(len+1); u[len].a = g; u[len].b = m; if (verbose) { cerr << "split " << m << " " << deg(g) << "\n"; } } static void NewProcessTable(vec_pair_ZZ_pEX_long& u, ZZ_pEX& f, const ZZ_pEXModulus& F, vec_ZZ_pEX& buf, long size, long StartInterval, long IntervalLength, long verbose) { if (size == 0) return; ZZ_pEX& g = buf[size-1]; long i; for (i = 0; i < size-1; i++) MulMod(g, g, buf[i], F); GCD(g, f, g); if (deg(g) == 0) return; div(f, f, g); long d = (StartInterval-1)*IntervalLength + 1; i = 0; long interval = StartInterval; while (i < size-1 && 2*d <= deg(g)) { GCD(buf[i], buf[i], g); if (deg(buf[i]) > 0) { NewAddFactor(u, buf[i], interval, verbose); div(g, g, buf[i]); } i++; interval++; d += IntervalLength; } if (deg(g) > 0) { if (i == size-1) NewAddFactor(u, g, interval, verbose); else NewAddFactor(u, g, (deg(g)+IntervalLength-1)/IntervalLength, verbose); } } static void FetchGiantStep(ZZ_pEX& g, long gs, const ZZ_pEXModulus& F) { if (use_files) { ifstream s; OpenRead(s, FileName(ZZ_pEX_stem, "giant", gs)); s >> g; s.close(); } else g = GiantStepFile(gs); rem(g, g, F); } static void FetchBabySteps(vec_ZZ_pEX& v, long k) { v.SetLength(k); SetX(v[0]); long i; for (i = 1; i <= k-1; i++) { if (use_files) { ifstream s; OpenRead(s, FileName(ZZ_pEX_stem, "baby", i)); s >> v[i]; s.close(); } else v[i] = BabyStepFile(i); } } static void GiantRefine(vec_pair_ZZ_pEX_long& u, const ZZ_pEX& ff, long k, long l, long verbose) { double t; if (verbose) { cerr << "giant refine..."; t = GetTime(); } u.SetLength(0); vec_ZZ_pEX BabyStep; FetchBabySteps(BabyStep, k); vec_ZZ_pEX buf(INIT_SIZE, ZZ_pEX_GCDTableSize); ZZ_pEX f; f = ff; ZZ_pEXModulus F; build(F, f); ZZ_pEX g; ZZ_pEX h; long size = 0; long first_gs; long d = 1; while (2*d <= deg(f)) { long old_n = deg(f); long gs = (d+k-1)/k; long bs = gs*k - d; if (bs == k-1) { size++; if (size == 1) first_gs = gs; FetchGiantStep(g, gs, F); sub(buf[size-1], g, BabyStep[bs]); } else { sub(h, g, BabyStep[bs]); MulMod(buf[size-1], buf[size-1], h, F); } if (verbose && bs == 0) cerr << "+"; if (size == ZZ_pEX_GCDTableSize && bs == 0) { NewProcessTable(u, f, F, buf, size, first_gs, k, verbose); if (verbose) cerr << "*"; size = 0; } d++; if (2*d <= deg(f) && deg(f) < old_n) { build(F, f); long i; for (i = 1; i <= k-1; i++) rem(BabyStep[i], BabyStep[i], F); } } if (size > 0) { NewProcessTable(u, f, F, buf, size, first_gs, k, verbose); if (verbose) cerr << "*"; } if (deg(f) > 0) NewAddFactor(u, f, 0, verbose); if (verbose) { t = GetTime()-t; cerr << "giant refine time: " << t << "\n"; } } static void IntervalRefine(vec_pair_ZZ_pEX_long& factors, const ZZ_pEX& ff, long k, long gs, const vec_ZZ_pEX& BabyStep, long verbose) { vec_ZZ_pEX buf(INIT_SIZE, ZZ_pEX_GCDTableSize); ZZ_pEX f; f = ff; ZZ_pEXModulus F; build(F, f); ZZ_pEX g; FetchGiantStep(g, gs, F); long size = 0; long first_d; long d = (gs-1)*k + 1; long bs = k-1; while (bs >= 0 && 2*d <= deg(f)) { long old_n = deg(f); if (size == 0) first_d = d; rem(buf[size], BabyStep[bs], F); sub(buf[size], buf[size], g); size++; if (size == ZZ_pEX_GCDTableSize) { NewProcessTable(factors, f, F, buf, size, first_d, 1, verbose); size = 0; } d++; bs--; if (bs >= 0 && 2*d <= deg(f) && deg(f) < old_n) { build(F, f); rem(g, g, F); } } NewProcessTable(factors, f, F, buf, size, first_d, 1, verbose); if (deg(f) > 0) NewAddFactor(factors, f, deg(f), verbose); } static void BabyRefine(vec_pair_ZZ_pEX_long& factors, const vec_pair_ZZ_pEX_long& u, long k, long l, long verbose) { double t; if (verbose) { cerr << "baby refine..."; t = GetTime(); } factors.SetLength(0); vec_ZZ_pEX BabyStep; long i; for (i = 0; i < u.length(); i++) { const ZZ_pEX& g = u[i].a; long gs = u[i].b; if (gs == 0 || 2*((gs-1)*k+1) > deg(g)) NewAddFactor(factors, g, deg(g), verbose); else { if (BabyStep.length() == 0) FetchBabySteps(BabyStep, k); IntervalRefine(factors, g, k, gs, BabyStep, verbose); } } if (verbose) { t = GetTime()-t; cerr << "baby refine time: " << t << "\n"; } } void NewDDF(vec_pair_ZZ_pEX_long& factors, const ZZ_pEX& f, const ZZ_pEX& h, long verbose) { if (!IsOne(LeadCoeff(f))) Error("NewDDF: bad args"); if (deg(f) == 0) { factors.SetLength(0); return; } if (deg(f) == 1) { factors.SetLength(0); append(factors, cons(f, 1)); return; } if (!ZZ_pEX_stem[0]) sprintf(ZZ_pEX_stem, "ddf-%ld", RandomBnd(10000)); long B = deg(f)/2; long k = SqrRoot(B); long l = (B+k-1)/k; ZZ_pEX h1; if (CalcTableSize(deg(f), k + l - 1) > ZZ_pEXFileThresh) use_files = 1; else use_files = 0; GenerateBabySteps(h1, f, h, k, verbose); GenerateGiantSteps(f, h1, l, verbose); vec_pair_ZZ_pEX_long u; GiantRefine(u, f, k, l, verbose); BabyRefine(factors, u, k, l, verbose); FileCleanup(k, l); } long IterComputeDegree(const ZZ_pEX& h, const ZZ_pEXModulus& F) { long n = deg(F); if (n == 1 || IsX(h)) return 1; long B = n/2; long k = SqrRoot(B); long l = (B+k-1)/k; ZZ_pEXArgument H; #if 0 double n2 = sqrt(double(n)); double n4 = sqrt(n2); double n34 = n2*n4; long sz = long(ceil(n34/sqrt(sqrt(2.0)))); #else long sz = 2*SqrRoot(F.n); #endif build(H, h, F, sz); ZZ_pEX h1; h1 = h; vec_ZZ_pEX baby; baby.SetLength(k); SetX(baby[0]); long i; for (i = 1; i <= k-1; i++) { baby[i] = h1; CompMod(h1, h1, H, F); if (IsX(h1)) return i+1; } build(H, h1, F, sz); long j; for (j = 2; j <= l; j++) { CompMod(h1, h1, H, F); for (i = k-1; i >= 0; i--) { if (h1 == baby[i]) return j*k-i; } } return n; } NTL_END_IMPL