OpenXM_contrib2/asir2000/include/ca.h - diff

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Diff for /OpenXM_contrib2/asir2000/include/ca.h between version 1.81 and 1.103

version 1.81, 2011/06/16 08:17:15

version 1.103, 2017/09/14 01:34:54

Line 45

* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE,

* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE.

* $OpenXM: OpenXM_contrib2/asir2000/include/ca.h,v 1.80 2011/05/11 06:03:53 ohara Exp $

* $OpenXM: OpenXM_contrib2/asir2000/include/ca.h,v 1.102 2017/08/31 02:36:21 noro Exp $

#include <stdio.h>

#include <stdlib.h>

#include <gmp.h>

#include <mpc.h>

#include <limits.h>

/* from mpfr-impl.h */

#define MPFR_PREC(x) ((x)->_mpfr_prec)

#define MPFR_EXP(x) ((x)->_mpfr_exp)

#define MPFR_MANT(x) ((x)->_mpfr_d)

#define MPFR_LAST_LIMB(x) ((MPFR_PREC (x) - 1) / GMP_NUMB_BITS)

#define MPFR_LIMB_SIZE(x) (MPFR_LAST_LIMB (x) + 1)

#define RAT_CEIL(nm,dn) (((nm)+(dn)-1)/((dn)))

#define MPFR_LIMB_SIZE_REAL(x) (RAT_CEIL(MPFR_PREC((x)),sizeof(mp_limb_t)*CHAR_BIT) * (sizeof(mp_limb_t)/sizeof(int)) )

#define MPFR_LIMB_SIZE_BODY(x) (RAT_CEIL(MPFR_PREC((x)),sizeof(unsigned int)*CHAR_BIT))

#if defined(hpux)

#include <netinet/in.h>

# define setbuffer(FP,buf,siz) setvbuf(FP,buf,_IOFBF,siz)

#endif

#if !defined(VISUAL)

#if !defined(VISUAL) && !defined(__MINGW32__)

#include <unistd.h>

#include <sys/param.h>

#endif

Line 68

Line 82

#define alloca(x) __builtin_alloca(x)

#endif

#if defined(VISUAL)

#if defined(VISUAL) || defined(__MINGW32__)

#include <limits.h>

#include <malloc.h>

#endif

Line 77

Line 92

typedef caddr_t pointer;

#endif

typedef void * pointer;

#if defined(sun)

#include <strings.h>

#else

#include <string.h>

#if defined(VISUAL)

#if defined(VISUAL) || defined(__MINGW32__)

#define index(s,c) strchr(s,c)

#define bzero(s,len) memset(s,0,len)

#define bcopy(x,y,len) memcpy(y,x,len)

Line 130 typedef void * pointer;

Line 146 typedef void * pointer;

#define O_IMAT 24

/* IMAT */

#define O_NBP 25

#define O_DPM 26

#define N_Q 0

#define N_R 1

#define N_A 2

#define N_B 3

#define N_C 4

#define N_NEXT_B (N_B)

#define N_M 5

#if defined(INTERVAL)

#define N_LM 6

#define N_Quad (N_NEXT_B+1)

#define N_GF2N 7

#define N_IP (N_NEXT_B+2)

#define N_GFPN 8

#define N_IntervalDouble (N_NEXT_B+3)

#define N_GFS 9

#define N_IntervalQuad (N_NEXT_B+4)

#define N_GFSN 10

#define N_IntervalBigFloat (N_NEXT_B+5)

#define N_DA 11

#define N_PRE_C N_IntervalBigFloat

#define N_BASE (N_NEXT_B+5)

#else

#define N_BASE N_NEXT_B

#endif

#define N_C (N_BASE+1)

#define N_M (N_BASE+2)

#define N_LM (N_BASE+3)

#define N_GF2N (N_BASE+4)

#define N_GFPN (N_BASE+5)

#define N_GFS (N_BASE+6)

#define N_GFSN (N_BASE+7)

#define N_DA (N_BASE+8)

#define N_GZ (N_BASE+9)

#define N_GQ (N_BASE+10)

#define N_PARIB (N_BASE+11)

#define ORD_REVGRADLEX 0

#define ORD_GRADLEX 1

Line 163 typedef _int64 L;

Line 195 typedef _int64 L;

typedef unsigned _int64 UL;

#endif

#if defined(__GNUC__)

typedef __uint64_t U64;

typedef __uint128_t U128;

typedef __int64_t L64;

typedef __int128_t L128;

#endif

typedef struct oN {

int p;

unsigned int b[1];

Line 224 typedef struct oBF {

Line 263 typedef struct oBF {

short id;

char nid;

char pad;

long body[1];

mpfr_t body;

} *BF;

typedef struct oC {

Line 263 typedef struct oDAlg {

Line 302 typedef struct oDAlg {

struct oQ *dn;

} *DAlg;

typedef struct oGZ {

short id;

char nid;

char pad;

mpz_t body;

} *GZ;

typedef struct oGQ {

short id;

char nid;

char pad;

mpq_t body;

} *GQ;

typedef struct oNum {

short id;

char nid;

Line 380 typedef struct oDPV {

Line 432 typedef struct oDPV {

struct oDP **body;

} *DPV;

typedef struct oUSINT {

short id;

short pad;

Line 481 typedef struct oDCP {

Line 534 typedef struct oDCP {

typedef struct oMP {

struct oDL *dl;

P c;

Obj c;

struct oMP *next;

} *MP;

typedef struct oDPM {

short id;

short nv;

int sugar;

struct oDMM *body;

} *DPM;

typedef struct oDMM {

int pos;

struct oDL *dl;

Obj c;

struct oDMM *next;

} *DMM;

typedef struct oDL {

int td;

int d[1];

Line 624 struct order_spec {

Line 691 struct order_spec {

int nv;

int ispot; /* 1 means Position over Term (Pos then Term) */

int pot_nelim; /* size of positions for pot-elimination order */

int *top_weight;

int module_rank;

int *module_top_weight;

union {

int simple;

struct {

Line 726 typedef unsigned int ModNum;

Line 796 typedef unsigned int ModNum;

/* memory allocators (W_... : uses alloca) */

#if 0

#define MALLOC(d) Risa_GC_malloc(d)

#define MALLOC_ATOMIC(d) Risa_GC_malloc_atomic(d)

#define MALLOC_ATOMIC_IGNORE_OFF_PAGE(d) Risa_GC_malloc_atomic_ignore_off_page(d)

#define REALLOC(p,d) Risa_GC_realloc(p,d)

#else

#define GCFREE(p) Risa_GC_free(p)

#define MALLOC(d) GC_malloc(d)

#define MALLOC_ATOMIC(d) GC_malloc_atomic(d)

#define REALLOC(p,d) GC_realloc(p,d)

#endif

#define CALLOC(d,e) MALLOC((d)*(e))

#if !defined(__CYGWIN__) && (defined(__GNUC__) || defined(vax) || defined(apollo) || defined(alloca) || defined(VISUAL))

#if 0

#if !defined(__CYGWIN__) && (defined(__GNUC__) || defined(vax) || defined(apollo) || defined(alloca) || defined(VISUAL) || defined(__MINGW32__))

#define ALLOCA(d) alloca(d)

#else

#define ALLOCA(d) MALLOC(d)

#endif

#define ALLOCA(d) MALLOC(d)

/* for handling signals */

#if defined(HAVE_SIGACTION) /* POSIX */

void (*set_signal(int sig, void (*handler)(int)))(int);

#define set_signal_for_restart(x,y) (0)

#else

#define set_signal(x,y) (signal(x,y))

#define set_signal_for_restart(x,y) (signal(x,y))

#endif

/* for setjmp/longjmp compatibility */

#if defined(__CYGWIN__) || defined(__x86_64)

#if defined(__CYGWIN__) || defined(HAVE_SIGACTION) || (defined(__x86_64) && !defined(__MINGW32__))

#define JMP_BUF sigjmp_buf

#define SETJMP(x) sigsetjmp(x,~0)

#define LONGJMP(x,y) siglongjmp(x,y)

Line 806 bzero((char *)(q)->b,(w)*sizeof(unsigned int)))

Line 885 bzero((char *)(q)->b,(w)*sizeof(unsigned int)))

((q).b=(unsigned int *)ALLOCA((w)*sizeof(unsigned int)))

/* cell allocators */

#define NEWGZ(q) ((q)=(GZ)MALLOC(sizeof(struct oGZ)),OID(q)=O_N,NID(q)=N_GZ)

#define NEWGQ(q) ((q)=(GQ)MALLOC(sizeof(struct oGQ)),OID(q)=O_N,NID(q)=N_GQ)

#define NEWQ(q) ((q)=(Q)MALLOC(sizeof(struct oQ)),OID(q)=O_N,NID(q)=N_Q)

#define NEWMQ(q) ((q)=(MQ)MALLOC_ATOMIC(sizeof(struct oMQ)),OID(q)=O_N,NID(q)=N_M)

#define NEWGFS(q) ((q)=(GFS)MALLOC_ATOMIC(sizeof(struct oGFS)),OID(q)=O_N,NID(q)=N_GFS)

Line 818 bzero((char *)(q)->b,(w)*sizeof(unsigned int)))

Line 899 bzero((char *)(q)->b,(w)*sizeof(unsigned int)))

#define NEWCOMP(c,n) ((c)=(COMP)MALLOC(sizeof(struct oCOMP)+((n)-1)*sizeof(Obj)),OID(c)=O_COMP)

#define NEWDP(d) ((d)=(DP)MALLOC(sizeof(struct oDP)),OID(d)=O_DP)

#define NEWDPV(d) ((d)=(DPV)MALLOC(sizeof(struct oDPV)),OID(d)=O_DPV)

#define NEWDPM(d) ((d)=(DPM)MALLOC(sizeof(struct oDPM)),OID(d)=O_DPM)

#define NEWUSINT(u) ((u)=(USINT)MALLOC_ATOMIC(sizeof(struct oUSINT)),OID(u)=O_USINT)

#define NEWERR(e) ((e)=(ERR)MALLOC(sizeof(struct oERR)),OID(e)=O_ERR)

#define NEWMATHCAP(e) ((e)=(MATHCAP)MALLOC(sizeof(struct oMATHCAP)),OID(e)=O_MATHCAP)

Line 834 bzero((char *)(q)->b,(w)*sizeof(unsigned int)))

Line 916 bzero((char *)(q)->b,(w)*sizeof(unsigned int)))

#define NEWV(v) ((v)=(V)MALLOC(sizeof(struct oV)))

#define NEWVL(vl) ((vl)=(VL)MALLOC(sizeof(struct oVL)))

#define NEWMP(m) ((m)=(MP)MALLOC(sizeof(struct oMP)))

#define NEWDMM(m) ((m)=(DMM)MALLOC(sizeof(struct oDMM)))

#define NEWDLBUCKET(a) ((a)=(DLBUCKET)MALLOC(sizeof(struct oDLBUCKET)))

#define NEWDPP(a) ((a)=(DP_pairs)MALLOC(sizeof(struct dp_pairs)))

Line 847 bzero((char *)(q)->b,(w)*sizeof(unsigned int)))

Line 930 bzero((char *)(q)->b,(w)*sizeof(unsigned int)))

#define NEWReal(q) ((q)=(Real)MALLOC_ATOMIC(sizeof(struct oReal)),OID(q)=O_N,NID(q)=N_R)

#define NEWAlg(r) ((r)=(Alg)MALLOC(sizeof(struct oAlg)),OID(r)=O_N,NID(r)=N_A)

#define NEWDAlg(r) ((r)=(DAlg)MALLOC(sizeof(struct oDAlg)),OID(r)=O_N,NID(r)=N_DA)

#define NEWBF(q,l) ((q)=(BF)MALLOC_ATOMIC(TRUESIZE(oBF,(l)-1,long)),OID(q)=O_N,NID(q)=N_B)

#define NEWBF(q) ((q)=(BF)MALLOC(sizeof(struct oBF)),OID(q)=O_N,NID(q)=N_B)

#define NEWPARIBF(q,l) ((q)=(BF)MALLOC_ATOMIC(TRUESIZE(oBF,(l)-1,long)),OID(q)=O_N,NID(q)=N_PARIB)

#define NEWC(r) ((r)=(C)MALLOC(sizeof(struct oC)),OID(r)=O_N,NID(r)=N_C)

#define NEWLM(r) ((r)=(LM)MALLOC(sizeof(struct oLM)),OID(r)=O_N,NID(r)=N_LM)

#define NEWGF2N(r) ((r)=(GF2N)MALLOC(sizeof(struct oGF2N)),OID(r)=O_N,NID(r)=N_GF2N)

Line 879 DEG(DC(p))=ONE,COEF(DC(p))=(P)ONEM,NEXT(DC(p))=0)

Line 963 DEG(DC(p))=ONE,COEF(DC(p))=(P)ONEM,NEXT(DC(p))=0)

#define MKSTR(a,b) (NEWSTR(a),(a)->body=(char *)(b))

#define MKDP(n,m,d) (NEWDP(d),(d)->nv=(n),BDY(d)=(m))

#define MKDPV(len,m,d) (NEWDPV(d),(d)->len=(len),BDY(d)=(m))

#define MKDPM(n,m,d) (NEWDPM(d),(d)->nv=(n),BDY(d)=(m))

#define MKLM(b,l) (!(b)?(l)=0:(NEWLM(l),(l)->body=(b),(l)))

#define MKGF2N(b,l) (!(b)?(l)=0:(NEWGF2N(l),(l)->body=(b),(l)))

#define MKGFPN(b,l) (!(b)?(l)=0:(NEWGFPN(l),(l)->body=(b),(l)))

Line 904 if(!(r)){NEWDLBUCKET(r);(c)=(r);}else{NEWDLBUCKET(NEXT

Line 989 if(!(r)){NEWDLBUCKET(r);(c)=(r);}else{NEWDLBUCKET(NEXT

if(!(r)){NEWVL(r);(c)=(r);}else{NEWVL(NEXT(c));(c)=NEXT(c);}

#define NEXTDPP(r,c) \

if(!(r)){NEWDPP(r);(c)=(r);}else{NEWDPP(NEXT(c));(c)=NEXT(c);}

#define NEXTDMM(r,c) \

if(!(r)){NEWDMM(r);(c)=(r);}else{NEWDMM(NEXT(c));(c)=NEXT(c);}

/* convertors */

#define NTOQ(n,s,q) \

Line 947 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q)

Line 1034 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q)

#define SL(n) ((n)->p)

#define ZALLOC(d) ((Z)MALLOC_ATOMIC(TRUESIZE(oZ,(d)-1,int)))

#if defined(PARI)

#define ToReal(a) (!(a)?(double)0.0:REAL(a)?BDY((Real)a):RATN(a)?RatnToReal((Q)a):BIGFLOAT(a)?mpfrtodbl(BDY((BF)a)):0)

#define ToReal(a) (!(a)?(double)0.0:REAL(a)?BDY((Real)a):RATN(a)?RatnToReal((Q)a):BIGFLOAT(a)?rtodbl(BDY((BF)a)):0)

#else

#define ToReal(a) (!(a)?(double)0.0:REAL(a)?BDY((Real)a):RATN(a)?RatnToReal((Q)a):0.0)

#endif

/* predicates */

#define NUM(p) (OID(p)==O_N)

Line 966 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q)

Line 1049 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q)

#define UNIMQ(q) ((q)&&NUM(q)&&SFF(q)&&(CONT((MQ)q)==1))

#define MUNIQ(q) ((q)&&NUM(q)&&RATN(q)&&(SGN((Q)q)==-1)&&UNIN(NM((Q)q))&&(!DN((Q)q)))

#define MUNIMQ(q) ((q)&&NUM(q)&&SFF(q)&&(CONT((MQ)q)==-1))

#define UNILM(n) ((n)&&UNIN(BDY(n)))

#define UNIN(n) ((n)&&(PL(n)==1)&&(BD(n)[0]==1))

#define EVENN(n) ((!(n))||(!(BD(n)[0]%2)))

Line 987 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q)

Line 1071 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q)

#define FTOIF(i) ((int)(((unsigned int)(i)|0x80000000)))

struct cdl {

P c;

Obj c;

DL d;

};

Line 1095 void hybrid_mulup(int,UP,UP,UP *);

Line 1179 void hybrid_mulup(int,UP,UP,UP *);

void getmod_lm(N *);

int maxblenup(UP);

void monicup(UP,UP *);

void simpup(UP,UP *);

void simpnum(Num,Num *);

void decompp(P,Q,P *,P *);

void truncp(P,Q,P *);

void uremp(P,P,P *);

void ugcdp(P,P,P *);

void reversep(P,Q,P *);

void invmodp(P,Q,P *);

void addup(UP,UP,UP *);

void subup(UP,UP,UP *);

void chsgnup(UP,UP *);

void mulup(UP,UP,UP *);

void tmulup(UP,UP,int,UP *);

void squareup(UP,UP *);

void remup(UP,UP,UP *);

void remup_destructive(UP,UP);

void qrup(UP,UP,UP *,UP *);

void qrup_destructive(UP,UP);

void gcdup(UP,UP,UP *);

void reverseup(UP,int,UP *);

void invmodup(UP,int,UP *);

void pwrup(UP,Q,UP *);

void squarep_gf2n(VL,P,P *);

void kmulp(VL,P,P,P *);

void ksquarep(VL,P,P *);

void kmulup(UP,UP,UP *);

void ksquareup(UP,UP *);

void extractup(UP,int,int,UP *);

void copyup(UP,UP);

void c_copyup(UP,int,pointer *);

void kmulupmain(UP,UP,UP *);

void ksquareupmain(UP,UP *);

void rembymulup(UP,UP,UP *);

void rembymulup_special(UP,UP,UP,UP *);

void tkmulup(UP,UP,int,UP *);

void shiftup(UP,int,UP *);

void set_degreeup(UP,int);

void decompup(UP,int,UP *,UP *);

void truncup(UP,int,UP *);

void uptofmarray(int,UP,ModNum *);

void fmarraytoup(ModNum *,int,UP *);

void uiarraytoup(unsigned int **,int,int,UP *);

void adj_coefup(UP,N,N,UP *);

void uptolmup(UP,UP *);

void remcup(UP,N,UP *);

void fft_mulup(UP,UP,UP *);

void fft_squareup(UP,UP *);

void trunc_fft_mulup(UP,UP,int,UP *);

void shoup_fft_mulup(UP,UP,UP *);

void shoup_fft_squareup(UP,UP *);

void shoup_trunc_fft_mulup(UP,UP,int,UP *);

void crup(ModNum **,int,int *,int,N,UP *);

void shoup_crup(ModNum **,int,int *,int,N,N,UP *);

void squareup_gf2n(UP,UP *);

void powermodup_gf2n(UP,UP *);

void generic_powermodup_gf2n(UP,UP,Q,UP *);

void tracemodup_gf2n(UP,UP,Q,UP *);

void tracemodup_gf2n_slow(UP,UP,Q,UP *);

void tracemodup_gf2n_tab(UP,UP,Q,UP *);

void square_rem_tab_up_gf2n(UP,UP *,UP *);

void powertabup_gf2n(UP,UP,UP *);

void find_root_gf2n(UP,GF2N *);

int cmpdl_composite(int,DL,DL);

int cmpdl_matrix(int,DL,DL);

int cmpdl_order_pair(int,DL,DL);

Line 1174 int cmpdl_revgradlex(int,DL,DL);

Line 1193 int cmpdl_revgradlex(int,DL,DL);

int cmpdl_gradlex(int,DL,DL);

int cmpdl_revlex(int,DL,DL);

int cmpdl_lex(int,DL,DL);

int compd(VL,DP,DP);

void adddl(int,DL,DL,DL *);

void divsdc(VL,DP,P,DP *);

void muldc(VL,DP,P,DP *);

void muldm(VL,DP,MP,DP *);

void muld(VL,DP,DP,DP *);

void chsgnd(DP,DP *);

void subd(VL,DP,DP,DP *);

void addd(VL,DP,DP,DP *);

int sugard(MP);

void nodetod(NODE,DP *);

void dtop(VL,VL,DP,P *);

void ptod(VL,VL,P,DP *);

void initd(struct order_spec *);

void adddv(VL,DPV,DPV,DPV *);

void subdv(VL,DPV,DPV,DPV *);

Line 1195 void muldv(VL,DP,DPV,DPV *);

Line 1200 void muldv(VL,DP,DPV,DPV *);

void chsgndv(DPV,DPV *);

int compdv(VL,DPV,DPV);

void adddpm(VL,DPM,DPM,DPM *);

void subdpm(VL,DPM,DPM,DPM *);

void mulobjdpm(VL,Obj,DPM,DPM *);

void chsgndpm(DPM,DPM *);

int compdpm(VL,DPM,DPM);

void _printdp(DP);

void _dp_sp_mod(DP,DP,int,DP *);

void _dp_mod(DP,int,NODE,DP *);

Line 1223 void rtime_init(void);

Line 1234 void rtime_init(void);

void setmod_gf2n(P);

void mt_sgenrand(unsigned long);

unsigned long mt_genrand(void);

#if defined(VISUAL)

#if defined(VISUAL) || defined(__MINGW32__)

void srandom(unsigned int);

unsigned int random(void);

#endif

Line 1430 void Risa_GC_get_adj(int *,int *);

Line 1441 void Risa_GC_get_adj(int *,int *);

void *Risa_GC_malloc(size_t);

void *Risa_GC_malloc_atomic(size_t);

void *Risa_GC_realloc(void *,size_t);

void Risa_GC_free(void *);

void *Risa_GC_malloc_atomic_ignore_off_page(size_t);

void *GC_malloc(size_t);

void *GC_malloc_atomic(size_t);

void *GC_realloc(void *,size_t);

Line 1437 double NatToReal(N,int *);

Line 1450 double NatToReal(N,int *);

double RatnToReal(Q);

double pwrreal0(double,int);

double rtodbl(); /* XXX */

double mpfrtodbl(mpfr_t a);

int **almat(int,int);

pointer **almat_pointer(int,int);

int berlecnt(register int,UM);

Line 1776 void pwrreal(Num,Num,Real *);

Line 1790 void pwrreal(Num,Num,Real *);

void pwrmi(MQ,Q,MQ *);

void pwrlm(LM,Q,LM *);

void pwrum(int,UM,int,UM);

void reallocarray(char **,int *,int *,int);

void asir_reallocarray(char **,int *,int *,int);

void reductr(VL,Obj,Obj *);

void reimtocplx(Num,Num,Num *);

void rem2q(Q,Q,Q,Q *);

Line 2134 int has_fcoef(DP f);

Line 2148 int has_fcoef(DP f);

int has_fcoef_p(P f);

void initd(struct order_spec *spec);

void ptod(VL vl,VL dvl,P p,DP *pr);

void dtop(VL vl,VL dvl,DP p,P *pr);

void dtop(VL vl,VL dvl,DP p,Obj *pr);

void nodetod(NODE node,DP *dp);

int sugard(MP m);

void addd(VL vl,DP p1,DP p2,DP *pr);

Line 2150 void weyl_muld(VL vl,DP p1,DP p2,DP *pr);

Line 2164 void weyl_muld(VL vl,DP p1,DP p2,DP *pr);

void weyl_muldm(VL vl,MP m0,DP p,DP *pr);

void weyl_mulmm(VL vl,MP m0,MP m1,int n,struct cdl *rtab,int rtablen);

void comm_muld_tab(VL vl,int nv,struct cdl *t,int n,struct cdl *t1,int n1,struct cdl *rt);

void muldc(VL vl,DP p,P c,DP *pr);

void muldc(VL vl,DP p,Obj c,DP *pr);

void divsdc(VL vl,DP p,P c,DP *pr);

void divdc(VL vl,DP p,Obj c,DP *pr);

void adddl(int n,DL d1,DL d2,DL *dr);

void adddl_destructive(int n,DL d1,DL d2);

int compd(VL vl,DP p1,DP p2);

Line 2631 void mkwcz(int k,int l,Z *t);

Line 2646 void mkwcz(int k,int l,Z *t);

int remzi(Z n,int m);

#if 0 && !defined(VISUAL)

#if 0 && !defined(VISUAL) && !defined(__MINGW32__)

void bzero(const void *,int);

void bcopy(const void *,void *,int);

char *index(char *,int);

Line 2643 void addnbp(VL vl,NBP p1,NBP p2, NBP *rp);

Line 2658 void addnbp(VL vl,NBP p1,NBP p2, NBP *rp);

void mulnbp(VL vl,NBP p1,NBP p2, NBP *rp);

void pwrnbp(VL vl,NBP p1,Q n, NBP *rp);

int compnbp(VL vl,NBP p1,NBP p2);

#define WORDSIZE_IN_N(a) (ABS((a)->_mp_size)*GMP_LIMB_BITS/32)

#define MPZTOGZ(g,q) \

(!mpz_sgn(g)?((q)=0):(NEWGZ(q),BDY(q)[0]=(g)[0],(q)))

#define MPQTOGQ(g,q) \

(!mpq_sgn(g)?((q)=0):(NEWGQ(q),BDY(q)[0]=(g)[0],(q)))

#define INTMPQ(a) (!mpz_cmp_ui(mpq_numref(a),1))

#define UNIGZ(a) ((a)&&NID(a)==N_GZ&&!mpz_cmp_ui(BDY(a),1))

#define MUNIGZ(a) ((a)&&NID(a)==N_GZ&&!mpz_cmp_si(BDY(a),-1))

#define INTGQ(a) ((a)&&NID(a)==N_GQ&&!mpz_cmp_ui(mpq_denref(BDY(a)),1))

#define UNIGQ(a) \

((a)&&NID(a)==N_GQ&&!mpz_cmp_ui(mpq_numref(BDY(a)),1)&&!mpz_cmp_ui(mpq_denref(BDY(a)),1))

#define MUNIGQ(a) \

((a)&&NID(a)==N_GQ&&!mpz_cmp_si(mpq_numref(BDY(a)),-1)&&!mpz_cmp_ui(mpq_denref(BDY(a)),1))

#define MPZTOMPQ(z,q) \

(mpq_init(q),mpq_numref(q)[0] = (z)[0],mpz_set_ui(mpq_denref(q),1))

#define MPFRTOBF(g,q) \

(NEWBF(q),BDY(q)[0]=(g)[0],(q))

extern mpz_t ONEMPZ;

extern GZ ONEGZ;

void *gc_realloc(void *p,size_t osize,size_t nsize);

void gc_free(void *p,size_t size);

void init_gmpq();

GQ mpqtogzq(mpq_t a);

GQ qtogq(Q a);

Q gqtoq(GQ a);

GZ ztogz(Q a);

Q gztoz(GZ a);

P ptogp(P a);

P gptop(P a);

void addgz(GZ n1,GZ n2,GZ *nr);

void subgz(GZ n1,GZ n2,GZ *nr);

void mulgz(GZ n1,GZ n2,GZ *nr);

void mul1gz(GZ n1,int n2,GZ *nr);

void divgz(GZ n1,GZ n2,GZ *nq);

void chsgngz(GZ n,GZ *nr);

void pwrgz(GZ n1,Q n,GZ *nr);

int cmpgz(GZ q1,GZ q2);

void gcdgz(GZ n1,GZ n2,GZ *nq);

void gcdvgz(VECT v,GZ *q);

void addgq(GQ n1,GQ n2,GQ *nr);

void subgq(GQ n1,GQ n2,GQ *nr);

void mulgq(GQ n1,GQ n2,GQ *nr);

void divgq(GQ n1,GQ n2,GQ *nq);

void chsgngq(GQ n,GQ *nr);

void pwrgq(GQ n1,Q n,GQ *nr);

int cmpgq(GQ n1,GQ n2);

void mkgwc(int k,int l,GZ *t);

void gz_ptozp(P p,int sgn,GQ *c,P *pr);

void gz_lgp(P p,GZ *g,GZ *l);

void gz_qltozl(GQ *w,int n,GZ *dvr);

void _mdtodp(DP p,DP *pr);

void add_denomlist(P f);

void algobjtorat(Obj f,Obj *r);

void algtodalg(Alg a,DAlg *r);

void appenduflist(NODE n);

void arf_add(VL,Obj,Obj,Obj *);

void arf_chsgn(Obj,Obj *);

void arf_div(VL,Obj,Obj,Obj *);

void arf_mul(VL,Obj,Obj,Obj *);

void arf_sub(VL,Obj,Obj,Obj *);

void asir_terminate(int);

void check_intr();

void clctalg(P,VL *);

void comm_muld_trunc(VL vl,DP p1,DP p2,DL dl,DP *pr);

void comm_quod(VL vl,DP p1,DP p2,DP *pr);

void create_modorder_spec(int id,LIST shift,struct modorder_spec **s);

void dalgtoalg(DAlg da,Alg *r);

void divsgz(GZ n1,GZ n2,GZ *nq);

void dp_ht(DP p,DP *rp);

void dp_interreduce(LIST f,LIST v,int field,struct order_spec *ord,LIST *rp);

void dp_mbase(NODE,NODE *);

void dp_nf_tab_f(DP p,LIST *tab,DP *rp);

void dp_ptozp(DP,DP *);

void dp_sort(DP p,DP *rp);

void dp_subd(DP,DP,DP *);

void dp_true_nf(NODE,DP,DP *,int,DP *,P *);

void dp_true_nf_marked(NODE b,DP g,DP *ps,DP *hps,DP *rp,P *nmp,P *dnp);

void dp_true_nf_marked_mod(NODE b,DP g,DP *ps,DP *hps,int mod,DP *rp,P *dnp);

void gbcheck_list(NODE f,int n,VECT *gp,LIST *pp);

void gcdsf(VL vl,P *pa,int k,P *r);

void get_algtree(Obj f,VL *r);

void get_vars(Obj,VL *);

void gfstopgfs(GFS a,V v,P *c);

void henmain_incremental(LUM f,LUM *bqlist,ML cqlist, int np, int mod, int start, int bound);

void iftogfs(int n,GFS *c);

void indextogfs(int index,GFS *c);

void init_denomlist();

void inva_chrem(P p0,P p,NODE *pr);

void itogfs(int n,GFS *c);

void lcmn(N n1,N n2,N *nr);

void makevar(char *,P *);

void mdtodp(DP p,DP *pr);

void mfctrsf(VL vl,P f,DCP *dcp);

void mulp_trunc(VL vl,P p1,P p2,VN vn,P *pr);

void nd_det(int mod,MAT f,P *rp);

void nd_gr(LIST f,LIST v,int m,int homo,int retdp,int f4,struct order_spec *ord,LIST *rp);

void nd_gr_postproc(LIST f,LIST v,int m,struct order_spec *ord,int do_check,LIST *rp);

void nd_gr_recompute_trace(LIST f,LIST v,int m,struct order_spec *ord,LIST tlist,LIST *rp);

void nd_gr_trace(LIST f,LIST v,int trace,int homo,int f4,struct order_spec *ord,LIST *rp);

void nd_nf_p(Obj f,LIST g,LIST v,int m,struct order_spec *ord,Obj *rp);

void obj_algtodalg(Obj obj,Obj *r);

void obj_dalgtoalg(Obj obj,Obj *r);

void ox_bcast_102(int root);

void ox_reduce_102(int root,void (*func)());

void print_to_wfep(Obj obj);

void printn(N);

void printz(Z n);

void pthrootgfs(GFS a,GFS *b);

void quop_trunc(VL vl,P p1,P p2,VN vn,P *pr);

void red_by_vect_sf(int m,unsigned int *p,unsigned int *r,unsigned int hc,int len);

void removecont_array(P *c,int n,int full);

void reset_top_weight();

void setfield_dalg(NODE alist);

void setfield_gb(NODE gb,VL vl,struct order_spec *spec);

void setsecuremode(int value);

void sfbfctr_shift(P f,V x,V y,int degbound,GFS *evp,P *sfp,DCP *dcp);

void sfexgcd_by_hensel(BM g,BM h,int dy,BM *ap,BM *bp);

void sfptopsfp(P f,V v,P *gp);

void simpdalg(DAlg da,DAlg *r);

void simple_derivr(VL vl,Obj a,V v,Obj *b);

void substpp(VL vl,P p,V *vvect,P *svect,int nv,P *pr);

void ufctrsf(P p,DCP *dcp);

void vltopl(VL vl,LIST *l);

int arf_comp(VL, Obj, Obj);

int available_mcindex(int ind);

int compare_zero(int n,int *u,int row,int **w);

int create_composite_order_spec(VL vl,LIST order,struct order_spec **specp);

int create_order_spec(VL,Obj,struct order_spec **);

int dalgtoup(DAlg da,P *up,Q *dn);

int dl_equal(int nv,DL dl1,DL dl2);

int dp_redble(DP,DP);

int dpv_hp(DPV p);

int generic_gauss_elim_hensel(MAT mat,MAT *nmmat,Q *dn,int **rindp,int **cindp);

int generic_gauss_elim_hensel_dalg(MAT mat,DP *mb,MAT *nmmat,Q *dn,int **rindp,int **cindp);

int generic_gauss_elim_mod(int **mat0,int row,int col,int md,int *colstat);

int generic_gauss_elim_mod2(int **mat0,int row,int col,int md,int *colstat,int *rowstat);

int get_field_type(P p);

int get_ox_server_id(int index);

int getsecuremode();

int gz_generic_gauss_elim(MAT mat,MAT *nm,GZ *dn,int **rindp,int **cindp);

int gz_generic_gauss_elim_full(MAT mat,MAT *nm,GZ *dn,int **rindp,int **cindp);

int gz_gensolve_check(MAT mat,MAT nm,GZ dn,int *rind,int *cind);

int gz_gensolve_check2(MAT mat,MAT nm,GZ *dn,int *rind,int *cind);

int gz_intmtoratm(MAT mat,GZ md,MAT nm,GZ *dn);

int gz_intmtoratm2(MAT mat,GZ md,MAT nm,GZ *dn,int *stat);

int gz_inttorat(GZ c,GZ m,GZ b,int *sgnp,GZ *nmp,GZ *dnp);

int gz_intvtoratv(GZ *v,int n,GZ md,GZ b,GZ *nm,GZ *dn);

int invdalg(DAlg a,DAlg *c);

int is_eq(Obj a0,Obj a1);

int length(NODE);

int lu_mod(unsigned int **a,int n,unsigned int md,int **rinfo);

int n_bits_gz(GZ a);

int nd_gauss_elim_gz(GZ **mat0,int *sugar,int row,int col,int *colstat);

int poly_is_dependent(P p,V v);

int setsecureflag(char *name,int value);

int sfdegtest(int dy,int bound,UM *d1c,int k,int *in);

int sgnz(Z n);

#if defined(VISUAL) || defined(__MINGW32__)

void check_intr();

void enter_signal_cs();

void leave_signal_cs();

void leave_signal_cs_all();

#define LEAVE_SIGNAL_CS_ALL leave_signal_cs_all()

#else

#define LEAVE_SIGNAL_CS_ALL

#endif

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