/usr/include/NTL/GF2EXFactoring.h is in libntl-dev 6.2.1-1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 | #ifndef NTL_GF2EXFactoring__H
#define NTL_GF2EXFactoring__H
#include <NTL/GF2EX.h>
#include <NTL/pair_GF2EX_long.h>
NTL_OPEN_NNS
/************************************************************
factorization routines
************************************************************/
void SquareFreeDecomp(vec_pair_GF2EX_long& u, const GF2EX& f);
inline vec_pair_GF2EX_long SquareFreeDecomp(const GF2EX& f)
{ vec_pair_GF2EX_long x; SquareFreeDecomp(x, f); return x; }
// Performs square-free decomposition.
// f must be monic.
// If f = prod_i g_i^i, then u is set to a lest of pairs (g_i, i).
// The list is is increasing order of i, with trivial terms
// (i.e., g_i = 1) deleted.
void FindRoots(vec_GF2E& x, const GF2EX& f);
inline vec_GF2E FindRoots(const GF2EX& f)
{ vec_GF2E x; FindRoots(x, f); return x; }
// f is monic, and has deg(f) distinct roots.
// returns the list of roots
void FindRoot(GF2E& root, const GF2EX& f);
inline GF2E FindRoot(const GF2EX& f)
{ GF2E x; FindRoot(x, f); return x; }
// finds a single root of f.
// assumes that f is monic and splits into distinct linear factors
void SFBerlekamp(vec_GF2EX& factors, const GF2EX& f, long verbose=0);
inline vec_GF2EX SFBerlekamp(const GF2EX& f, long verbose=0)
{ vec_GF2EX x; SFBerlekamp(x, f, verbose); return x; }
// Assumes f is square-free and monic.
// returns list of factors of f.
// Uses "Berlekamp" appraoch.
void berlekamp(vec_pair_GF2EX_long& factors, const GF2EX& f, long verbose=0);
inline vec_pair_GF2EX_long
berlekamp(const GF2EX& f, long verbose=0)
{ vec_pair_GF2EX_long x; berlekamp(x, f, verbose); return x; }
// returns a list of factors, with multiplicities.
// f must be monic.
// Uses "Berlekamp" appraoch.
NTL_THREAD_LOCAL
extern long GF2EX_BlockingFactor;
// Controls GCD blocking for DDF.
void DDF(vec_pair_GF2EX_long& factors, const GF2EX& f, const GF2EX& h,
long verbose=0);
inline vec_pair_GF2EX_long DDF(const GF2EX& f, const GF2EX& h,
long verbose=0)
{ vec_pair_GF2EX_long x; DDF(x, f, h, verbose); return x; }
// Performs distinct-degree factorization.
// Assumes f is monic and square-free, and h = X^p mod f
// Obsolete: see NewDDF, below.
NTL_THREAD_LOCAL
extern long GF2EX_GCDTableSize; /* = 4 */
// Controls GCD blocking for NewDDF
NTL_THREAD_LOCAL
extern char GF2EX_stem[];
// Determines filename stem for external storage in NewDDF.
NTL_THREAD_LOCAL
extern double GF2EXFileThresh;
// external files are used for baby/giant steps if size
// of these tables exceeds GF2EXFileThresh KB.
void NewDDF(vec_pair_GF2EX_long& factors, const GF2EX& f, const GF2EX& h,
long verbose=0);
inline vec_pair_GF2EX_long NewDDF(const GF2EX& f, const GF2EX& h,
long verbose=0)
{ vec_pair_GF2EX_long x; NewDDF(x, f, h, verbose); return x; }
// same as above, but uses baby-step/giant-step method
void EDF(vec_GF2EX& factors, const GF2EX& f, const GF2EX& b,
long d, long verbose=0);
inline vec_GF2EX EDF(const GF2EX& f, const GF2EX& b,
long d, long verbose=0)
{ vec_GF2EX x; EDF(x, f, b, d, verbose); return x; }
// Performs equal-degree factorization.
// f is monic, square-free, and all irreducible factors have same degree.
// b = X^p mod f.
// d = degree of irreducible factors of f
// Space for the trace-map computation can be controlled via ComposeBound.
void RootEDF(vec_GF2EX& factors, const GF2EX& f, long verbose=0);
inline vec_GF2EX RootEDF(const GF2EX& f, long verbose=0)
{ vec_GF2EX x; RootEDF(x, f, verbose); return x; }
// EDF for d==1
void SFCanZass(vec_GF2EX& factors, const GF2EX& f, long verbose=0);
inline vec_GF2EX SFCanZass(const GF2EX& f, long verbose=0)
{ vec_GF2EX x; SFCanZass(x, f, verbose); return x; }
// Assumes f is monic and square-free.
// returns list of factors of f.
// Uses "Cantor/Zassenhaus" approach.
void CanZass(vec_pair_GF2EX_long& factors, const GF2EX& f, long verbose=0);
inline vec_pair_GF2EX_long CanZass(const GF2EX& f, long verbose=0)
{ vec_pair_GF2EX_long x; CanZass(x, f, verbose); return x; }
// returns a list of factors, with multiplicities.
// f must be monic.
// Uses "Cantor/Zassenhaus" approach.
void mul(GF2EX& f, const vec_pair_GF2EX_long& v);
inline GF2EX mul(const vec_pair_GF2EX_long& v)
{ GF2EX x; mul(x, v); return x; }
// multiplies polynomials, with multiplicities
/*************************************************************
irreducible poly's: tests and constructions
**************************************************************/
long ProbIrredTest(const GF2EX& f, long iter=1);
// performs a fast, probabilistic irreduciblity test
// the test can err only if f is reducible, and the
// error probability is bounded by p^{-iter}.
long DetIrredTest(const GF2EX& f);
// performs a recursive deterministic irreducibility test
// fast in the worst-case (when input is irreducible).
long IterIrredTest(const GF2EX& f);
// performs an iterative deterministic irreducibility test,
// based on DDF. Fast on average (when f has a small factor).
void BuildIrred(GF2EX& f, long n);
inline GF2EX BuildIrred_GF2EX(long n)
{ GF2EX x; BuildIrred(x, n); NTL_OPT_RETURN(GF2EX, x); }
// Build a monic irreducible poly of degree n.
void BuildRandomIrred(GF2EX& f, const GF2EX& g);
inline GF2EX BuildRandomIrred(const GF2EX& g)
{ GF2EX x; BuildRandomIrred(x, g); NTL_OPT_RETURN(GF2EX, x); }
// g is a monic irreducible polynomial.
// constructs a random monic irreducible polynomial f of the same degree.
long RecComputeDegree(const GF2EX& h, const GF2EXModulus& 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
// This routine is useful in counting points on elliptic curves
long IterComputeDegree(const GF2EX& h, const GF2EXModulus& F);
void TraceMap(GF2EX& w, const GF2EX& a, long d, const GF2EXModulus& F,
const GF2EX& b);
inline GF2EX TraceMap(const GF2EX& a, long d, const GF2EXModulus& F,
const GF2EX& b)
{ GF2EX x; TraceMap(x, a, d, F, b); return x; }
// w = a+a^q+...+^{q^{d-1}} mod f;
// it is assumed that d >= 0, and b = X^q mod f, q a power of p
// Space allocation can be controlled via ComposeBound (see <NTL/GF2EX.h>)
void PowerCompose(GF2EX& w, const GF2EX& a, long d, const GF2EXModulus& F);
inline GF2EX PowerCompose(const GF2EX& a, long d, const GF2EXModulus& F)
{ GF2EX x; PowerCompose(x, a, d, F); return x; }
// w = X^{q^d} mod f;
// it is assumed that d >= 0, and b = X^q mod f, q a power of p
// Space allocation can be controlled via ComposeBound (see <NTL/GF2EX.h>)
void PlainFrobeniusMap(GF2EX& h, const GF2EXModulus& F);
void ComposeFrobeniusMap(GF2EX& y, const GF2EXModulus& F);
void FrobeniusMap(GF2EX& h, const GF2EXModulus& F);
inline GF2EX FrobeniusMap(const GF2EXModulus& F)
{ GF2EX x; FrobeniusMap(x, F); return x; }
long UseComposeFrobenius(long d, long n);
NTL_CLOSE_NNS
#endif
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