#ifndef KUTIL_H #define KUTIL_H /**************************************** * Computer Algebra System SINGULAR * ****************************************/ /* * ABSTRACT: kernel: utils for kStd */ #include #include #include #include #include #include #if 1 #define setmax 16 #define setmaxL ((4096-12)/sizeof(LObject)) #define setmaxLinc ((4096)/sizeof(LObject)) #define setmaxT 64 #define setmaxTinc 32 #else #define setmax 16 #define setmaxL 16 #define setmaxLinc 16 #define setmaxT 16 #define setmaxTinc 16 #endif // if you want std computations as in Singular version < 2: // This disables RedThrough, tailReductions against T (bba), // sets posInT = posInT15 (bba, strat->honey), and enables redFirst with LDeg // NOTE: can be achieved with option(oldStd) #undef NO_KINLINE #if !defined(KDEBUG) && !defined(NO_INLINE) #define KINLINE inline #else #define KINLINE #define NO_KINLINE 1 #endif typedef int* intset; typedef int64 wlen_type; typedef wlen_type* wlen_set; typedef class sTObject TObject; typedef class sLObject LObject; typedef TObject * TSet; typedef LObject * LSet; typedef struct denominator_list_s denominator_list_s; typedef denominator_list_s *denominator_list; struct denominator_list_s{number n; denominator_list next;}; extern denominator_list DENOMINATOR_LIST; class sTObject { public: unsigned long sevSig; poly sig; // the signature of the element poly p; // Lm(p) \in currRing Tail(p) \in tailRing poly t_p; // t_p \in tailRing: as monomials Lm(t_p) == Lm(p) poly max; // p_GetMaxExpP(pNext(p)) ring tailRing; long FDeg; // pFDeg(p) int ecart, length, // as of pLDeg pLength, // either == 0, or == pLength(p) i_r; // index of TObject in R set, or -1 if not in T BOOLEAN is_normalized; // true, if pNorm was called on p, false otherwise // used in incremental sba() with F5C: // we know some of the redundant elements in // strat->T beforehand, so we can just discard // them and do not need to consider them in the // interreduction process BOOLEAN is_redundant; // used in sba's sig-safe reduction: // sometimes we already know that a reducer // is sig-safe, so no need for a real // sig-safeness check BOOLEAN is_sigsafe; #ifdef HAVE_PLURAL BOOLEAN is_special; // true, it is a new special S-poly (e.g. for SCA) #endif // initialization KINLINE void Init(ring r = currRing); KINLINE sTObject(ring tailRing = currRing); KINLINE sTObject(poly p, ring tailRing = currRing); KINLINE sTObject(poly p, ring c_r, ring tailRing); KINLINE sTObject(sTObject* T, int copy); KINLINE void Set(ring r=currRing); KINLINE void Set(poly p_in, ring r=currRing); KINLINE void Set(poly p_in, ring c_r, ring t_r); // Frees the polys of T KINLINE void Delete(); // Sets polys to NULL KINLINE void Clear(); // makes a copy of the poly of T KINLINE void Copy(); // ring-dependent Lm access: these might result in allocation of monomials KINLINE poly GetLmCurrRing(); KINLINE poly GetLmTailRing(); KINLINE poly GetLm(ring r); // this returns Lm and ring r (preferably from tailRing), but does not // allocate a new poly KINLINE void GetLm(poly &p, ring &r) const; #ifdef OLIVER_PRIVAT_LT // routines for calc. with rings KINLINE poly GetLtCurrRing(); KINLINE poly GetLtTailRing(); KINLINE poly GetLt(ring r); KINLINE void GetLt(poly &p, ring &r) const; #endif KINLINE BOOLEAN IsNull() const; KINLINE int GetpLength(); // makes sure that T.p exists KINLINE void SetLmCurrRing(); // Iterations // simply get the next monomial KINLINE poly Next(); KINLINE void LmDeleteAndIter(); // deg stuff // compute pTotalDegree KINLINE long pTotalDeg() const; // computes pFDeg KINLINE long pFDeg() const; // computes and sets FDeg KINLINE long SetpFDeg(); // gets stored FDeg KINLINE long GetpFDeg() const; // computes pLDeg KINLINE long pLDeg(); // sets length, FDeg, returns LDeg KINLINE long SetDegStuffReturnLDeg(); // arithmetic KINLINE void Mult_nn(number n); KINLINE void ShallowCopyDelete(ring new_tailRing, omBin new_tailBin, pShallowCopyDeleteProc p_shallow_copy_delete, BOOLEAN set_max = TRUE); // manipulations KINLINE void pNorm(); KINLINE void pCleardenom(); #ifdef KDEBUG void wrp(); #endif }; #ifndef NDEBUG extern int strat_nr; extern int strat_fac_debug; #endif class sLObject : public sTObject { public: unsigned long sev; unsigned long from; // from which polynomial it comes from // this is important for signature-based // algorithms unsigned long checked; // this is the index of S up to which // the corresponding LObject was already checked in // critical pair creation => when entering the // reduction process it is enough to start a second // rewritten criterion check from checked+1 onwards // NOTE: If checked = 3 then the corresponding pair is // detected by Buchberger's Product Criterion and can be // deleted poly p1,p2; /*- the pair p comes from, lm(pi) in currRing, tail(pi) in tailring -*/ poly lcm; /*- the lcm of p1,p2 -*/ kBucket_pt bucket; int i_r1, i_r2; // initialization KINLINE void Init(ring tailRing = currRing); KINLINE sLObject(ring tailRing = currRing); KINLINE sLObject(poly p, ring tailRing = currRing); KINLINE sLObject(poly p, ring c_r, ring tailRing); // Frees the polys of L KINLINE void Delete(); KINLINE void Clear(); // Iterations KINLINE void LmDeleteAndIter(); KINLINE poly LmExtractAndIter(); // spoly related things // preparation for reduction if not spoly KINLINE void PrepareRed(BOOLEAN use_bucket); KINLINE void SetLmTail(poly lm, poly new_p, int length, int use_bucket, ring r); KINLINE void Tail_Minus_mm_Mult_qq(poly m, poly qq, int lq, poly spNoether); KINLINE void Tail_Mult_nn(number n); // deletes bucket, makes sure that p and t_p exists KINLINE poly GetP(omBin lmBin = NULL); // similar, except that only t_p exists KINLINE poly GetTP(); // does not delete bucket, just canonicalizes it // returned poly is such that Lm(p) \in currRing, Tail(p) \in tailRing KINLINE poly CanonicalizeP(); // makes a copy of the poly of L KINLINE void Copy(); // gets the poly and makes a copy of it KINLINE poly CopyGetP(); KINLINE int GetpLength(); KINLINE long pLDeg(BOOLEAN use_last); KINLINE long pLDeg(); KINLINE int SetLength(BOOLEAN lengt_pLength = FALSE); KINLINE long SetDegStuffReturnLDeg(); KINLINE long SetDegStuffReturnLDeg(BOOLEAN use_last); // returns minimal component of p KINLINE long MinComp(); // returns component of p KINLINE long Comp(); KINLINE void ShallowCopyDelete(ring new_tailRing, pShallowCopyDeleteProc p_shallow_copy_delete); // sets sev KINLINE void SetShortExpVector(); // enable assignment from TObject KINLINE sLObject& operator=(const sTObject&); // get T's corresponding to p1, p2: they might return NULL KINLINE TObject* T_1(const skStrategy* strat); KINLINE TObject* T_2(const skStrategy* strat); KINLINE void T_1_2(const skStrategy* strat, TObject* &T_1, TObject* &T_2); // simplify coefficients KINLINE void Normalize(); KINLINE void HeadNormalize(); }; extern int HCord; class skStrategy; typedef skStrategy * kStrategy; class skStrategy { public: kStrategy next; int (*red)(LObject * L,kStrategy strat); int (*red2)(LObject * L,kStrategy strat); void (*initEcart)(LObject * L); int (*posInT)(const TSet T,const int tl,LObject &h); int (*posInLSba)(const LSet set, const int length, LObject* L,const kStrategy strat); int (*posInL)(const LSet set, const int length, LObject* L,const kStrategy strat); void (*enterS)(LObject h, int pos,kStrategy strat, int atR/* =-1*/ ); void (*initEcartPair)(LObject * h, poly f, poly g, int ecartF, int ecartG); int (*posInLOld)(const LSet Ls,const int Ll, LObject* Lo,const kStrategy strat); void (*enterOnePair) (int i,poly p,int ecart, int isFromQ,kStrategy strat, int atR /*= -1*/); void (*chainCrit) (poly p,int ecart,kStrategy strat); BOOLEAN (*syzCrit) (poly sig, unsigned long not_sevSig, kStrategy strat); BOOLEAN (*rewCrit1) (poly sig, unsigned long not_sevSig, kStrategy strat, int start /*= 0*/); BOOLEAN (*rewCrit2) (poly sig, unsigned long not_sevSig, kStrategy strat, int start /*= 0*/); pFDegProc pOrigFDeg; pLDegProc pOrigLDeg; pFDegProc pOrigFDeg_TailRing; pLDegProc pOrigLDeg_TailRing; LObject P; ideal Shdl; ideal D; /*V(S) is in D(D)*/ ideal M; /*set of minimal generators*/ polyset S; polyset syz; polyset sig; intset ecartS; intset fromS; // from which S[i] S[j] comes from // this is important for signature-based // algorithms intset syzIdx;// index in the syz array at which the first // syzygy of component i comes up // important for signature-based algorithms BOOLEAN incremental; unsigned long currIdx; int max_lower_index; intset lenS; wlen_set lenSw; /* for tgb.ccc */ intset fromQ; unsigned long* sevS; unsigned long* sevSyz; unsigned long* sevSig; unsigned long* sevT; TSet T; LSet L; LSet B; poly kHEdge; poly kNoether; poly t_kHEdge; // same polys in tailring KINLINE poly kNoetherTail(); poly t_kNoether; BOOLEAN * NotUsedAxis; BOOLEAN * pairtest;/*used for enterOnePair*/ poly tail; intvec * kModW; intvec * kHomW; // procedure for ShalloCopy from tailRing to currRing pShallowCopyDeleteProc p_shallow_copy_delete; // pointers to Tobjects R[i] is ith Tobject which is generated TObject** R; // S_2_R[i] yields Tobject which corresponds to S[i] int* S_2_R; ring tailRing; omBin lmBin; omBin tailBin; #ifndef NDEBUG int nr; #endif int cp,c3; int cv; // in shift bases: counting V criterion int sl,mu; int syzl,syzmax,syzidxmax; int tl,tmax; int Ll,Lmax; int Bl,Bmax; int ak,LazyDegree,LazyPass; int syzComp; int HCord; int lastAxis; int newIdeal; int minim; #ifdef HAVE_SHIFTBBA int lV; #endif BOOLEAN interpt; BOOLEAN homog; #ifdef HAVE_PLURAL BOOLEAN z2homog; // Z_2 - homogeneous input allows product criterion in commutative and SCA cases! #endif BOOLEAN kHEdgeFound; BOOLEAN honey,sugarCrit; BOOLEAN Gebauer,noTailReduction; BOOLEAN fromT; BOOLEAN noetherSet; BOOLEAN update; BOOLEAN posInLOldFlag; BOOLEAN use_buckets; BOOLEAN interred_flag; // if set, pLDeg(p, l) == (pFDeg(pLast(p), pLength) BOOLEAN LDegLast; // if set, then L.length == L.pLength BOOLEAN length_pLength; // if set, then posInL does not depend on L.length BOOLEAN posInLDependsOnLength; /*FALSE, if posInL == posInL10*/ #ifdef HAVE_PLURAL // set this flag to 1 to stop the product criteria // use ALLOW_PROD_CRIT(strat) to test BOOLEAN no_prod_crit; #define ALLOW_PROD_CRIT(A) (!(A)->no_prod_crit) #else #define ALLOW_PROD_CRIT(A) (1) #endif char redTailChange; char news; char newt;/*used for messageSets*/ char noClearS; char completeReduce_retry; char overflow; skStrategy(); ~skStrategy(); // return TObject corresponding to S[i]: assume that it exists // i.e. no error checking is done KINLINE TObject* S_2_T(int i); // like S_2_T, except that NULL is returned if it can not be found KINLINE TObject* s_2_t(int i); }; void deleteHC(poly *p, int *e, int *l, kStrategy strat); void deleteHC(LObject* L, kStrategy strat, BOOLEAN fromNext = FALSE); void deleteInS (int i,kStrategy strat); void deleteInSSba (int i,kStrategy strat); void cleanT (kStrategy strat); static inline LSet initL (int nr=setmaxL) { return (LSet)omAlloc(nr*sizeof(LObject)); } void deleteInL(LSet set, int *length, int j,kStrategy strat); void enterL (LSet *set,int *length, int *LSetmax, LObject p,int at); void enterSBba (LObject p,int atS,kStrategy strat, int atR = -1); void enterSSba (LObject p,int atS,kStrategy strat, int atR = -1); void initEcartPairBba (LObject* Lp,poly f,poly g,int ecartF,int ecartG); void initEcartPairMora (LObject* Lp,poly f,poly g,int ecartF,int ecartG); int posInS (const kStrategy strat, const int length, const poly p, const int ecart_p); int posInT0 (const TSet set,const int length,LObject &p); int posInT1 (const TSet set,const int length,LObject &p); int posInT2 (const TSet set,const int length,LObject &p); int posInT11 (const TSet set,const int length,LObject &p); int posInTSig (const TSet set,const int length,LObject &p); int posInT110 (const TSet set,const int length,LObject &p); int posInT13 (const TSet set,const int length,LObject &p); int posInT15 (const TSet set,const int length,LObject &p); int posInT17 (const TSet set,const int length,LObject &p); int posInT19 (const TSet set,const int length,LObject &p); int posInT_EcartpLength(const TSet set,const int length,LObject &p); #ifdef HAVE_MORE_POS_IN_T int posInT_EcartFDegpLength(const TSet set,const int length,LObject &p); int posInT_FDegpLength(const TSet set,const int length,LObject &p); int posInT_pLength(const TSet set,const int length,LObject &p); #endif void reorderS (int* suc,kStrategy strat); int posInLF5C (const LSet set, const int length, LObject* L,const kStrategy strat); int posInLSig (const LSet set, const int length, LObject* L,const kStrategy strat); int posInL0 (const LSet set, const int length, LObject* L,const kStrategy strat); int posInL11 (const LSet set, const int length, LObject* L,const kStrategy strat); int posInL13 (const LSet set, const int length, LObject* L,const kStrategy strat); int posInL15 (const LSet set, const int length, LObject* L,const kStrategy strat); int posInL17 (const LSet set, const int length, LObject* L,const kStrategy strat); int posInL10 (const LSet set, const int length, LObject* L,const kStrategy strat); int posInL110 (const LSet set, const int length, LObject* L,const kStrategy strat); KINLINE poly redtailBba (poly p,int pos,kStrategy strat,BOOLEAN normalize=FALSE); #ifdef HAVE_RINGS KINLINE poly redtailBba_Z (poly p,int pos,kStrategy strat); poly redtailBba_Z (LObject* L, int pos, kStrategy strat ); #endif poly redtailBba (LObject *L, int pos,kStrategy strat, BOOLEAN withT = FALSE,BOOLEAN normalize=FALSE); poly redtailSba (LObject *L, int pos,kStrategy strat, BOOLEAN withT = FALSE,BOOLEAN normalize=FALSE); poly redtailBba (TObject *T, int pos,kStrategy strat); poly redtail (poly p,int pos,kStrategy strat); poly redtail (LObject *L,int pos,kStrategy strat); poly redNF (poly h,int & max_ind,int nonorm,kStrategy strat); int redNF0 (LObject *P,kStrategy strat); poly redNFTail (poly h,const int sl,kStrategy strat); int redHoney (LObject* h, kStrategy strat); #ifdef HAVE_RINGS int redRing (LObject* h,kStrategy strat); int redRiloc (LObject* h,kStrategy strat); void enterExtendedSpoly(poly h,kStrategy strat); void superenterpairs (poly h,int k,int ecart,int pos,kStrategy strat, int atR = -1); poly kCreateZeroPoly(long exp[], long cabsind, poly* t_p, ring leadRing, ring tailRing); long ind2(long arg); long ind_fact_2(long arg); long twoPow(long arg); ideal createG0(); #endif int redLazy (LObject* h,kStrategy strat); int redHomog (LObject* h,kStrategy strat); int redSig (LObject* h,kStrategy strat); //adds hSig to be able to check with F5's criteria when entering pairs! void enterpairsSig (poly h, poly hSig, int from, int k, int ec, int pos,kStrategy strat, int atR = -1); void enterpairs (poly h, int k, int ec, int pos,kStrategy strat, int atR = -1); void entersets (LObject h); void pairs (); void message (int i,int* reduc,int* olddeg,kStrategy strat,int red_result); void messageStat (int hilbcount,kStrategy strat); #ifdef KDEBUG void messageSets (kStrategy strat); #else #define messageSets(s) do {} while (0) #endif void initEcartNormal (LObject* h); void initEcartBBA (LObject* h); void initS (ideal F, ideal Q,kStrategy strat); void initSL (ideal F, ideal Q,kStrategy strat); void initSLSba (ideal F, ideal Q,kStrategy strat); /************************************************* * when initializing a new bunch of principal * syzygies at the beginning of a new iteration * step in a signature-based algorithm we * compute ONLY the leading elements of those * syzygies, NOT the whole syzygy * NOTE: this needs to be adjusted for a more * general approach on signature-based algorithms ***********************************************/ void initSyzRules (kStrategy strat); void updateS(BOOLEAN toT,kStrategy strat); void enterSyz (LObject p,kStrategy strat); void enterT (LObject p,kStrategy strat, int atT = -1); void cancelunit (LObject* p,BOOLEAN inNF=FALSE); void HEckeTest (poly pp,kStrategy strat); void initBuchMoraCrit(kStrategy strat); void initSbaCrit(kStrategy strat); void initHilbCrit(ideal F, ideal Q, intvec **hilb,kStrategy strat); void initBuchMoraPos(kStrategy strat); void initSbaPos(kStrategy strat); void initBuchMora (ideal F, ideal Q,kStrategy strat); void initSbaBuchMora (ideal F, ideal Q,kStrategy strat); void exitBuchMora (kStrategy strat); void exitSba (kStrategy strat); void updateResult(ideal r,ideal Q,kStrategy strat); void completeReduce (kStrategy strat, BOOLEAN withT=FALSE); void kFreeStrat(kStrategy strat); void enterOnePairNormal (int i,poly p,int ecart, int isFromQ,kStrategy strat, int atR); void enterOnePairSig (int i,poly p,poly pSig,int ecart, int isFromQ,kStrategy strat, int atR); void chainCritNormal (poly p,int ecart,kStrategy strat); void chainCritSig (poly p,int ecart,kStrategy strat); BOOLEAN homogTest(polyset F, int Fmax); BOOLEAN newHEdge(kStrategy strat); BOOLEAN syzCriterion(poly sig, unsigned long not_sevSig, kStrategy strat); BOOLEAN syzCriterionInc(poly sig, unsigned long not_sevSig, kStrategy strat); KINLINE BOOLEAN arriRewDummy(poly sig, unsigned long not_sevSig, kStrategy strat, int start); BOOLEAN arriRewCriterion(poly sig, unsigned long not_sevSig, kStrategy strat, int start); BOOLEAN faugereRewCriterion(poly sig, unsigned long not_sevSig, kStrategy strat, int start); BOOLEAN findMinLMPair(poly sig, unsigned long not_sevSig, kStrategy strat, int start); // returns index of p in TSet, or -1 if not found int kFindInT(poly p, TSet T, int tlength); // return -1 if no divisor is found // number of first divisor, otherwise int kFindDivisibleByInT(const TSet &T, const unsigned long* sevT, const int tl, const LObject* L, const int start=0); // same with S int kFindDivisibleByInS(const kStrategy strat, int *max_ind, LObject* L); int kFindNextDivisibleByInS(const kStrategy strat, int start,int max_ind, LObject* L); TObject* kFindDivisibleByInS(kStrategy strat, int pos, LObject* L, TObject *T, long ecart = LONG_MAX); /*************************************************************** * * stuff to be inlined * ***************************************************************/ KINLINE TSet initT (); KINLINE TObject** initR(); KINLINE unsigned long* initsevT(); KINLINE poly k_LmInit_currRing_2_tailRing(poly p, ring tailRing, omBin bin); KINLINE poly k_LmInit_tailRing_2_currRing(poly p, ring tailRing, omBin bin); KINLINE poly k_LmShallowCopyDelete_currRing_2_tailRing(poly p, ring tailRing, omBin bin); KINLINE poly k_LmShallowCopyDelete_tailRing_2_currRing(poly p, ring tailRing, omBin bin); KINLINE poly k_LmInit_currRing_2_tailRing(poly p, ring tailRing); KINLINE poly k_LmInit_tailRing_2_currRing(poly p, ring tailRing); KINLINE poly k_LmShallowCopyDelete_currRing_2_tailRing(poly p, ring tailRing); KINLINE poly k_LmShallowCopyDelete_tailRing_2_currRing(poly p, ring tailRing); // if exp bound is not violated, return TRUE and // get m1 = LCM(LM(p1), LM(p2))/LM(p1) // m2 = LCM(LM(p1), LM(p2))/LM(p2) // return FALSE and m1 == NULL, m2 == NULL , otherwise KINLINE BOOLEAN k_GetLeadTerms(const poly p1, const poly p2, const ring p_r, poly &m1, poly &m2, const ring m_r); #ifdef HAVE_RINGS KINLINE void k_GetStrongLeadTerms(const poly p1, const poly p2, const ring leadRing, poly &m1, poly &m2, poly &lcm, const ring taiRing); #endif #ifdef KDEBUG // test strat BOOLEAN kTest(kStrategy strat); // test strat, and test that S is contained in T BOOLEAN kTest_TS(kStrategy strat); // test LObject BOOLEAN kTest_L(LObject* L, ring tailRing = NULL, BOOLEAN testp = FALSE, int lpos = -1, TSet T = NULL, int tlength = -1); // test TObject BOOLEAN kTest_T(TObject* T, ring tailRing = NULL, int tpos = -1, char TN = '?'); // test set strat->SevS BOOLEAN kTest_S(kStrategy strat); #else #define kTest(A) (TRUE) #define kTest_TS(A) (TRUE) #define kTest_T(T) (TRUE) #define kTest_S(T) (TRUE) #define kTest_L(T) (TRUE) #endif /*************************************************************** * * From kstd2.cc * ***************************************************************/ poly kFindZeroPoly(poly input_p, ring leadRing, ring tailRing); ideal bba (ideal F, ideal Q,intvec *w,intvec *hilb,kStrategy strat); ideal sba (ideal F, ideal Q,intvec *w,intvec *hilb,kStrategy strat); poly kNF2 (ideal F, ideal Q, poly q, kStrategy strat, int lazyReduce); ideal kNF2 (ideal F,ideal Q,ideal q, kStrategy strat, int lazyReduce); void initBba(ideal F,kStrategy strat); void initSba(ideal F,kStrategy strat); void f5c (kStrategy strat, int& olddeg, int& minimcnt, int& hilbeledeg, int& hilbcount, int& srmax, int& lrmax, int& reduc, ideal Q, intvec *w,intvec *hilb ); /*************************************************************** * * From kspoly.cc * ***************************************************************/ // Reduces PR with PW // Assumes PR != NULL, PW != NULL, Lm(PW) divides Lm(PR) // Changes: PR // Const: PW // If coef != NULL, then *coef is a/gcd(a,b), where a = LC(PR), b = LC(PW) // If strat != NULL, tailRing is changed if reduction would violate exp bound // of tailRing // Returns: 0 everything ok, no tailRing change // 1 tailRing has successfully changed (strat != NULL) // 2 no reduction performed, tailRing needs to be changed first // (strat == NULL) // -1 tailRing change could not be performed due to exceeding exp // bound of currRing int ksReducePoly(LObject* PR, TObject* PW, poly spNoether = NULL, number *coef = NULL, kStrategy strat = NULL); // Reduces PR with PW // Assumes PR != NULL, PW != NULL, Lm(PW) divides Lm(PR) // Changes: PR // Const: PW // If coef != NULL, then *coef is a/gcd(a,b), where a = LC(PR), b = LC(PW) // If strat != NULL, tailRing is changed if reduction would violate exp bound // of tailRing // Returns: 0 everything ok, no tailRing change // 1 tailRing has successfully changed (strat != NULL) // 2 no reduction performed, tailRing needs to be changed first // (strat == NULL) // 3 no reduction performed, not sig-safe!!! // -1 tailRing change could not be performed due to exceeding exp // bound of currRing int ksReducePolySig(LObject* PR, TObject* PW, long idx, poly spNoether = NULL, number *coef = NULL, kStrategy strat = NULL); // Reduces PR at Current->next with PW // Assumes PR != NULL, Current contained in PR // Current->next != NULL, LM(PW) devides LM(Current->next) // Changes: PR // Const: PW // Return: see ksReducePoly int ksReducePolyTail(LObject* PR, TObject* PW, poly Current, poly spNoether = NULL); KINLINE int ksReducePolyTail(LObject* PR, TObject* PW, LObject* Red); // Creates S-Poly of Pair // Const: Pair->p1, Pair->p2 // Changes: Pair->p == S-Poly of p1, p2 // Assume: Pair->p1 != NULL && Pair->p2 void ksCreateSpoly(LObject* Pair, poly spNoether = NULL, int use_buckets=0, ring tailRing=currRing, poly m1 = NULL, poly m2 = NULL, TObject** R = NULL); /*2 * creates the leading term of the S-polynomial of p1 and p2 * do not destroy p1 and p2 * remarks: * 1. the coefficient is 0 (nNew) * 2. pNext is undefined */ poly ksCreateShortSpoly(poly p1, poly p2, ring tailRing); // old stuff KINLINE poly ksOldSpolyRed(poly p1, poly p2, poly spNoether = NULL); KINLINE poly ksOldSpolyRedNew(poly p1, poly p2, poly spNoether = NULL); KINLINE poly ksOldCreateSpoly(poly p1, poly p2, poly spNoether = NULL, ring r = currRing); KINLINE void ksOldSpolyTail(poly p1, poly q, poly q2, poly spNoether, ring r = currRing); /*************************************************************** * * Routines related for ring changes during std computations * ***************************************************************/ // return TRUE and set m1, m2 to k_GetLcmTerms, // if spoly creation of strat->P does not violate // exponent bound of strat->tailRing // FALSE, otherwise BOOLEAN kCheckSpolyCreation(LObject* L, kStrategy strat, poly &m1, poly &m2); #ifdef HAVE_RINGS // return TRUE if gcdpoly creation of R[atR] and S[atS] does not violate // exponent bound of strat->tailRing // FALSE, otherwise BOOLEAN kCheckStrongCreation(int atR, poly m1, int atS, poly m2, kStrategy strat); #endif // change strat->tailRing and adjust all data in strat, L, and T: // new tailRing has larger exponent bound // do nothing and return FALSE if exponent bound increase would result in // larger exponent bound that that of currRing BOOLEAN kStratChangeTailRing(kStrategy strat, LObject* L = NULL, TObject* T = NULL, // take this as new_expbound: if 0 // new expbound is 2*expbound of tailRing unsigned long new_expbound = 0); // initiate a change of the tailRing of strat -- should be called // right before main loop in bba void kStratInitChangeTailRing(kStrategy strat); /// Output some debug info about a given strategy void kDebugPrint(kStrategy strat); // getting sb order for sba computations ring sbaRing(kStrategy strat, const ring r=currRing, BOOLEAN complete=TRUE, int sgn=1); KINLINE void clearS (poly p, unsigned long p_sev, int* at, int* k, kStrategy strat); #include /* shiftgb stuff */ #include poly pMove2CurrTail(poly p, kStrategy strat); poly pMoveCurrTail2poly(poly p, kStrategy strat); poly pCopyL2p(LObject h, kStrategy strat); void enterTShift(LObject p, kStrategy strat, int atT, int uptodeg, int lV); void initBuchMoraShift (ideal F,ideal Q,kStrategy strat); void enterOnePairManyShifts (int i, poly p, int ecart, int isFromQ, kStrategy strat, int atR, int uptodeg, int lV); // ok void enterOnePairSelfShifts (poly qq, poly p, int ecart, int isFromQ, kStrategy strat, int atR, int uptodeg, int lV); void enterOnePairShift (poly q, poly p, int ecart, int isFromQ, kStrategy strat, int atR, int ecartq, int qisFromQ, int shiftcount, int ifromS, int uptodeg, int lV); // ok void enterpairsShift (poly h,int k,int ecart,int pos,kStrategy strat, int atR,int uptodeg, int lV); void initenterpairsShift (poly h,int k,int ecart,int isFromQ,kStrategy strat, int atR,int uptodeg, int lV); void updateSShift(kStrategy strat,int uptodeg,int lV); void initBbaShift(ideal F,kStrategy strat); poly redtailBbaShift (LObject* L, int pos, kStrategy strat, BOOLEAN withT, BOOLEAN normalize); int redFirstShift (LObject* h,kStrategy strat); // ok ideal freegb(ideal I, int uptodeg, int lVblock); ideal bbaShift(ideal F, ideal Q,intvec *w,intvec *hilb,kStrategy strat, int uptodeg, int lV); // test syz strategy: // will be removed soon extern int (*test_PosInT)(const TSet T,const int tl,LObject &h); extern int (*test_PosInL)(const LSet set, const int length, LObject* L,const kStrategy strat); #endif