/**************************************************************************\ MODULE: ZZ_pEXFactoring SUMMARY: Routines are provided for factorization of polynomials over ZZ_pE, as well as routines for related problems such as testing irreducibility and constructing irreducible polynomials of given degree. \**************************************************************************/ #include #include void SquareFreeDecomp(vec_pair_ZZ_pEX_long& u, const ZZ_pEX& f); vec_pair_ZZ_pEX_long SquareFreeDecomp(const ZZ_pEX& f); // Performs square-free decomposition. f must be monic. If f = // prod_i g_i^i, then u is set to a list 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_ZZ_pE& x, const ZZ_pEX& f); vec_ZZ_pE FindRoots(const ZZ_pEX& f); // f is monic, and has deg(f) distinct roots. returns the list of // roots void FindRoot(ZZ_pE& root, const ZZ_pEX& f); ZZ_pE FindRoot(const ZZ_pEX& f); // finds a single root of f. assumes that f is monic and splits into // distinct linear factors void NewDDF(vec_pair_ZZ_pEX_long& factors, const ZZ_pEX& f, const ZZ_pEX& h, long verbose=0); vec_pair_ZZ_pEX_long NewDDF(const ZZ_pEX& f, const ZZ_pEX& h, long verbose=0); // This computes a distinct-degree factorization. The input must be // monic and square-free. factors is set to a list of pairs (g, d), // where g is the product of all irreducible factors of f of degree d. // Only nontrivial pairs (i.e., g != 1) are included. The polynomial // h is assumed to be equal to X^{ZZ_pE::cardinality()} mod f. // This routine implements the baby step/giant step algorithm // of [Kaltofen and Shoup, STOC 1995]. // further described in [Shoup, J. Symbolic Comp. 20:363-397, 1995]. // NOTE: When factoring "large" polynomials, // this routine uses external files to store some intermediate // results, which are removed if the routine terminates normally. // These files are stored in the current directory under names of the // form ddf-*-baby-* and ddf-*-giant-*. // The definition of "large" is controlled by the variable extern double ZZ_pEXFileThresh // which can be set by the user. If the sizes of the tables // exceeds ZZ_pEXFileThresh KB, external files are used. // Initial value is 256. void EDF(vec_ZZ_pEX& factors, const ZZ_pEX& f, const ZZ_pEX& h, long d, long verbose=0); vec_ZZ_pEX EDF(const ZZ_pEX& f, const ZZ_pEX& h, long d, long verbose=0); // Performs equal-degree factorization. f is monic, square-free, and // all irreducible factors have same degree. h = X^{ZZ_pE::cardinality()} mod // f. d = degree of irreducible factors of f. This routine // implements the algorithm of [von zur Gathen and Shoup, // Computational Complexity 2:187-224, 1992] void RootEDF(vec_ZZ_pEX& factors, const ZZ_pEX& f, long verbose=0); vec_ZZ_pEX RootEDF(const ZZ_pEX& f, long verbose=0); // EDF for d==1 void SFCanZass(vec_ZZ_pEX& factors, const ZZ_pEX& f, long verbose=0); vec_ZZ_pEX SFCanZass(const ZZ_pEX& f, long verbose=0); // Assumes f is monic and square-free. returns list of factors of f. // Uses "Cantor/Zassenhaus" approach, using the routines NewDDF and // EDF above. void CanZass(vec_pair_ZZ_pEX_long& factors, const ZZ_pEX& f, long verbose=0); vec_pair_ZZ_pEX_long CanZass(const ZZ_pEX& f, long verbose=0); // returns a list of factors, with multiplicities. f must be monic. // Calls SquareFreeDecomp and SFCanZass. // NOTE: these routines use modular composition. The space // used for the required tables can be controlled by the variable // ZZ_pEXArgBound (see ZZ_pEX.txt). void mul(ZZ_pEX& f, const vec_pair_ZZ_pEX_long& v); ZZ_pEX mul(const vec_pair_ZZ_pEX_long& v); // multiplies polynomials, with multiplicities /**************************************************************************\ Irreducible Polynomials \**************************************************************************/ long ProbIrredTest(const ZZ_pEX& 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 // ZZ_pE::cardinality()^{-iter}. This implements an algorithm from [Shoup, // J. Symbolic Comp. 17:371-391, 1994]. long DetIrredTest(const ZZ_pEX& f); // performs a recursive deterministic irreducibility test. Fast in // the worst-case (when input is irreducible). This implements an // algorithm from [Shoup, J. Symbolic Comp. 17:371-391, 1994]. long IterIrredTest(const ZZ_pEX& f); // performs an iterative deterministic irreducibility test, based on // DDF. Fast on average (when f has a small factor). void BuildIrred(ZZ_pEX& f, long n); ZZ_pEX BuildIrred_ZZ_pEX(long n); // Build a monic irreducible poly of degree n. void BuildRandomIrred(ZZ_pEX& f, const ZZ_pEX& g); ZZ_pEX BuildRandomIrred(const ZZ_pEX& g); // g is a monic irreducible polynomial. Constructs a random monic // irreducible polynomial f of the same degree. long IterComputeDegree(const ZZ_pEX& h, const ZZ_pEXModulus& F); // f is assumed to be an "equal degree" polynomial, and h = // X^{ZZ_pE::cardinality()} mod f. The common degree of the irreducible // factors of f is computed. Uses a "baby step/giant step" algorithm, similar // to NewDDF. Although asymptotocally slower than RecComputeDegree // (below), it is faster for reasonably sized inputs. long RecComputeDegree(const ZZ_pEX& h, const ZZ_pEXModulus& F); // f is assumed to be an "equal degree" polynomial, // h = X^{ZZ_pE::cardinality()} mod f. // The common degree of the irreducible factors of f is // computed Uses a recursive algorithm similar to DetIrredTest. void TraceMap(ZZ_pEX& w, const ZZ_pEX& a, long d, const ZZ_pEXModulus& F, const ZZ_pEX& h); ZZ_pEX TraceMap(const ZZ_pEX& a, long d, const ZZ_pEXModulus& F, const ZZ_pEX& h); // Computes w = a+a^q+...+^{q^{d-1}} mod f; it is assumed that d >= 0, // and h = X^q mod f, q a power of ZZ_pE::cardinality(). This routine // implements an algorithm from [von zur Gathen and Shoup, // Computational Complexity 2:187-224, 1992] void PowerCompose(ZZ_pEX& w, const ZZ_pEX& h, long d, const ZZ_pEXModulus& F); ZZ_pEX PowerCompose(const ZZ_pEX& h, long d, const ZZ_pEXModulus& F); // Computes w = X^{q^d} mod f; it is assumed that d >= 0, and h = X^q // mod f, q a power of ZZ_pE::cardinality(). This routine implements an // algorithm from [von zur Gathen and Shoup, Computational Complexity // 2:187-224, 1992]