13 #include "factory/factory.h"
88 #define NC_MASK (3+64)
95 #define ZERODIVISOR_MASK 8
98 #define ZERODIVISOR_MASK 0
100 #define ALLOW_PLURAL 1
102 #define COMM_PLURAL 2
105 #define NO_ZERODIVISOR 8
106 #define ALLOW_ZERODIVISOR 0
108 #define ALLOW_NC ALLOW_LP|ALLOW_PLURAL
110 #define ALLOW_ZZ (ALLOW_RING|NO_ZERODIVISOR)
116 #define NO_CONVERSION 32
203 extern int iiArithAddCmd(
const char *szName,
short nAlias,
short nTokval,
204 short nToktype,
short nPos=-1);
214 #define ii_div_by_0 "div. by 0"
223 if ((
long)
i==
l)
return l;
248 int bb = (int)(
long)(
v->Data());
253 case '+': cc=
bimAdd(aa,bb);
break;
254 case '-': cc=
bimSub(aa,bb);
break;
255 case '*': cc=
bimMult(aa,bb);
break;
257 res->data=(
char *)cc;
267 number bb = (number)(
v->Data());
274 res->data=(
char *)cc;
284 int bb = (int)(
long)(
v->Data());
288 case '+': (*aa) += bb;
break;
289 case '-': (*aa) -= bb;
break;
290 case '*': (*aa) *= bb;
break;
293 case '%': (*aa) %= bb;
break;
295 res->data=(
char *)aa;
305 int bb = (int)(
long)(
v->Data());
314 res->data=(
char *)aa;
323 int l=(int)(
long)
v->Data();
326 int d=(int)(
long)u->
Data();
329 for(
i=
l-1;
i>=0;
i--) { (*vv)[
i]=d; }
330 res->data=(
char *)vv;
336 res->data=(
char *)
new intvec((
int)(long)u->
Data(),(int)(
long)
v->Data());
348 res->data = (
char *) (r<0);
351 res->data = (
char *) (r>0);
354 res->data = (
char *) (r<=0);
357 res->data = (
char *) (r>=0);
361 res->data = (
char *) (r==0);
365 if(r==-2) {
WerrorS(
"size incompatible");
return TRUE; }
376 res->data = (
char *) (r<0);
379 res->data = (
char *) (r>0);
382 res->data = (
char *) (r<=0);
385 res->data = (
char *) (r>=0);
389 res->data = (
char *) (r==0);
393 if(r==-2) {
WerrorS(
"size incompatible");
return TRUE; }
399 int b = (int)(
long)(
v->Data());
404 res->data = (
char *) (r<0);
407 res->data = (
char *) (r>0);
410 res->data = (
char *) (r<=0);
413 res->data = (
char *) (r>=0);
417 res->data = (
char *) (r==0);
432 res->data = (
char *) (
long)(r < 0);
435 res->data = (
char *) (
long)(r > 0);
438 res->data = (
char *) (
long)(r <= 0);
441 res->data = (
char *) (
long)(r >= 0);
445 res->data = (
char *)(
long) (r == 0);
453 poly
p=(poly)u->
Data();
454 poly q=(poly)
v->Data();
459 res->data = (
char *) (r < 0);
462 res->data = (
char *) (r > 0);
465 res->data = (
char *) (r <= 0);
468 res->data = (
char *) (r >= 0);
480 char* a = (
char * )(u->
Data());
481 char*
b = (
char * )(
v->Data());
513 else if (
v->Next()!=
NULL)
523 int b=(int)(
long)u->
Data();
524 int e=(int)(
long)
v->Data();
533 else if ((e==0)||(
b==1))
551 if(rc/
b!=oldrc) overflow=
TRUE;
555 WarnS(
"int overflow(^), result may be wrong");
557 res->data = (
char *)((
long)rc);
563 WerrorS(
"exponent must be non-negative");
569 int e=(int)(
long)
v->Data();
570 number n=(number)u->
Data();
577 WerrorS(
"exponent must be non-negative");
585 int e=(int)(
long)
v->Data();
586 number n=(number)u->
Data();
603 int v_i=(int)(
long)
v->Data();
606 WerrorS(
"exponent must be non-negative");
617 Werror(
"OVERFLOW in power(d=%ld, e=%d, max=%ld)",
660 res->data =
v->CopyD();
661 res->rtyp =
v->Typ();
701 if(isupper(u->
name[0]))
703 const char *c=u->
name+1;
704 while((*c!=
'\0')&&(islower(*c)||(isdigit(*c))||(*c==
'_'))) c++;
709 Print(
"%s of type 'ANY'. Trying load.\n", u->
name);
725 package pa=(package)u->Data();
739 WerrorS(
"reserved name with ::");
751 WerrorS(
"<package>::<id> expected");
758 unsigned int a=(
unsigned int)(
unsigned long)u->
Data();
759 unsigned int b=(
unsigned int)(
unsigned long)
v->Data();
761 res->data = (
char *)((
long)c);
764 WarnS(
"int overflow(+), result may be wrong");
775 res->data = (
char *)(
nAdd((number)u->
Data(), (number)
v->Data()));
810 WerrorS(
"intmat size not compatible");
820 WerrorS(
"bigintmat/cmatrix not compatible");
831 Werror(
"matrix size not compatible(%dx%d, %dx%d)",
839 ideal
A=(ideal)u->
Data(); ideal
B=(ideal)
v->Data();
843 Werror(
"matrix size not compatible(%dx%d, %dx%d)",
866 char* a = (
char * )(u->
Data());
867 char*
b = (
char * )(
v->Data());
868 char* r = (
char * )
omAlloc(strlen(a) + strlen(
b) + 1);
876 res->data = (
char *)
idAdd((ideal)u->
Data(),(ideal)
v->Data());
881 void *
ap=u->
Data();
void *bp=
v->Data();
882 int aa=(int)(
long)
ap;
883 int bb=(int)(
long)bp;
885 unsigned int a=(
unsigned int)(
unsigned long)
ap;
886 unsigned int b=(
unsigned int)(
unsigned long)bp;
890 WarnS(
"int overflow(-), result may be wrong");
892 res->data = (
char *)((
long)cc);
902 res->data = (
char *)(
nSub((number)u->
Data(), (number)
v->Data()));
938 WerrorS(
"intmat size not compatible");
948 WerrorS(
"bigintmat/cmatrix not compatible");
959 Werror(
"matrix size not compatible(%dx%d, %dx%d)",
968 ideal
A=(ideal)u->
Data(); ideal
B=(ideal)
v->Data();
972 Werror(
"matrix size not compatible(%dx%d, %dx%d)",
981 int a=(int)(
long)u->
Data();
982 int b=(int)(
long)
v->Data();
984 if ((c>INT_MAX)||(c<INT_MIN))
985 WarnS(
"int overflow(*), result may be wrong");
986 res->data = (
char *)((
long)((int)c));
1000 res->data = (
char *)(
nMult( (number)u->
Data(), (number)
v->Data()));
1001 number n=(number)
res->data;
1003 res->data=(
char *)n;
1021 Warn(
"possible OVERFLOW in mult(d=%ld, d=%ld, max=%ld)",
1033 Warn(
"possible OVERFLOW in mult(d=%ld, d=%ld, max=%ld)",
1068 WerrorS(
"intmat size not compatible");
1080 WerrorS(
"bigintmat/cmatrix not compatible");
1094 res->data = (
char *)I;
1108 res->data = (
char *)I;
1118 res->data = (
char *)I;
1149 Werror(
"matrix size not compatible(%dx%d, %dx%d) in *",
1160 ideal
A=(ideal)u->
Data(); ideal
B=(ideal)
v->Data();
1164 Werror(
"matrix size not compatible(%dx%d, %dx%d) in *",
1182 res->data = (
char *)(
long)((int)((
long)u->
Data()) >= (
int)((long)
v->Data()));
1200 res->data = (
char *)(
long)((int)((
long)u->
Data()) > (
int)((long)
v->Data()));
1214 res->data = (
char *)(
long)((int)((
long)u->
Data()) <= (
int)((long)
v->Data()));
1227 res->data = (
char *)(
long)((int)((
long)u->
Data()) < (
int)((long)
v->Data()));
1237 int a= (int)(
long)u->
Data();
1238 int b= (int)(
long)
v->Data();
1252 r=((a-c) /
b);
break;
1254 res->data=(
void *)((
long)r);
1259 number q=(number)
v->Data();
1267 res->data = (
char *)q;
1272 number q=(number)
v->Data();
1280 res->data = (
char *)q;
1285 poly q=(poly)
v->CopyD();
1286 poly
p=(poly)(u->
CopyD());
1294 poly q=(poly)
v->Data();
1319 res->data=(
char *)mm;
1330 res->data = (
char *)((
int)((long)u->
Data()) == (
int)((long)
v->Data()));
1348 res->data = (
char *)(
long)(u->
Data()==
v->Data());
1354 res->data = (
char *)((
long)
nEqual((number)u->
Data(),(number)
v->Data()));
1360 poly
p=(poly)u->
Data();
1361 poly q=(poly)
v->Data();
1381 res->data = (
char *)((
long)u->
Data() && (long)
v->Data());
1386 res->data = (
char *)((
long)u->
Data() || (long)
v->Data());
1399 while (sh->next !=
NULL) sh=sh->next;
1415 WerrorS(
"indexed object must have a name");
1422 memset(&t,0,
sizeof(t));
1426 t.
data=(
char *)((
long)(*iv)[
i]);
1449 poly
p=(poly)u->
Data();
1450 int i=(int)(
long)
v->Data();
1470 int i=(int)(
long)
v->Data();
1489 poly
p=(poly)u->
Data();
1497 while ((
p!=
NULL) && (sum>0))
1513 res->data=(
char *)r;
1518 poly
p=(poly)u->
Data();
1519 int i=(int)(
long)
v->Data();
1554 res->data=(
char *)r;
1562 char * nn = (
char *)
omAlloc(strlen(u->
name) + 14);
1563 sprintf(nn,
"%s(%d)",u->
name,(
int)(
long)
v->Data());
1577 long slen = strlen(u->
name) + 14;
1578 char *n = (
char*)
omAlloc(slen);
1591 sprintf(n,
"%s(%d)",u->
name,(*iv)[
i]);
1603 memset(tmp,0,
sizeof(
sleftv));
1615 while (
h->next!=
NULL)
h=
h->next;
1629 tmp_proc->
id=
"_auto";
1633 d=u->
data; u->
data=(
void *)tmp_proc;
1650 if (sl)
return TRUE;
1687 number *
x=(number *)
omAlloc(rl*
sizeof(number));
1688 number *q=(number *)
omAlloc(rl*
sizeof(number));
1690 for(
i=rl-1;
i>=0;
i--)
1697 for(
i=rl-1;
i>=0;
i--)
1703 res->data=(
char *)n;
1713 number *
x=(number *)
omAlloc(rl*
sizeof(number));
1714 number *q=(number *)
omAlloc(rl*
sizeof(number));
1716 for(
i=rl-1;
i>=0;
i--)
1722 for(
i=rl-1;
i>=0;
i--)
1726 Werror(
"poly expected at pos %d",
i+1);
1727 for(
i=rl-1;
i>=0;
i--)
1739 for(
i=rl-1;
i>=0;
i--)
1751 number n=n_ChineseRemainder(
x,q,rl,
currRing->cf);
1752 for(
i=rl-1;
i>=0;
i--)
1760 for(
i=rl-1;
i>=0;
i--)
1772 int s=(int)(
long)
v->Data();
1781 ideal
M=(ideal)u->
CopyD();
1782 int s=(int)(
long)
v->Data();
1795 poly
p=(poly)
v->Data();
1802 poly
p=(poly)
v->Data();
1809 int i=
pVar((poly)
v->Data());
1828 (ideal)(
v->Data()),
p);
1840 ideal I=(ideal)u->
Data();
1845 res->data = (
char *)((
long)d);
1850 poly
p=(poly)u->
Data();
1856 res->data = (
char *)(d);
1859 res->data=(
char *)(
long)(-1);
1864 int pos=(int)(
long)
v->Data();
1871 int pos=(int)(
long)
v->Data();
1872 ideal I=(ideal)u->
Data();
1886 ideal
m=(ideal)u->
Data();
1892 int i=
pVar((poly)
v->Data());
1903 int i=
pVar((poly)
v->Data());
1922 Warn(
"dim(%s,...) may be wrong because the mixed monomial ordering",
v->Name());
1927 ideal vid = (ideal)
v->Data();
1931 res->data = (
char *)-1;
1940 res->data = (
char *)d;
1946 res->data = (
char *)((
long)
scDimInt((ideal)(
v->Data()),(ideal)
w->Data()));
1950 res->data = (
char *)((
long)
scDimInt((ideal)(
v->Data()),q));
1957 ideal vi=(ideal)
v->Data();
1959 ideal ui=(ideal)u->
Data();
1993 res->data=(
char *)L;
2030 number uu=(number)u->
Data();number vv=(number)
v->Data();
2039 res->data=(
char *)L;
2044 int uu=(int)(
long)u->
Data();
int vv=(int)(
long)
v->Data();
2045 int p0=
ABS(uu),p1=
ABS(vv);
2046 int f0 = 1, f1 = 0, g0 = 0, g1 = 1, q, r;
2068 res->data=(
char *)L;
2075 if (ret)
return TRUE;
2078 res->data=(
char *)L;
2079 L->
m[0].
data=(
void *)r;
2091 int sw=(int)(
long)dummy->
Data();
2093 if ((sw<0)||(sw>2)) fac_sw=1;
2106 l->m[0].data=(
void *)
f;
2108 l->m[1].data=(
void *)
v;
2109 res->data=(
void *)
l;
2114 res->data=(
void *)
f;
2127 res->data=(
void *)
p;
2154 res->data=(
void *)L;
2161 number uu=(number)u->
Data();
2162 number vv=(number)
v->Data();
2170 ideal uu=(ideal)u->
Data();
2171 number vv=(number)
v->Data();
2185 ring r=(ring)u->
Data();
2194 int par_perm_size=0;
2203 par_perm_size=
rPar(r);
2212 perm=(
int *)
omAlloc0((r->N+1)*
sizeof(int));
2213 if (par_perm_size!=0)
2214 par_perm=(
int *)
omAlloc0(par_perm_size*
sizeof(
int));
2219 char ** r_par_names=
NULL;
2220 if (r->cf->extRing!=
NULL)
2222 r_par=r->cf->extRing->N;
2223 r_par_names=r->cf->extRing->names;
2226 char ** c_par_names=
NULL;
2230 c_par_names=
currRing->cf->extRing->names;
2234 maFindPerm(r->names, r->N, r_par_names, r_par,
2236 perm,par_perm,
currRing->cf->type);
2238 #ifdef HAVE_SHIFTBBA
2243 perm,par_perm,
currRing->cf->type,r->isLPring);
2250 if (par_perm_size!=0)
2264 Print(
"// par nr %d: %s -> %s\n",
2270 memset(&tmpW,0,
sizeof(
sleftv));
2274 perm,par_perm,par_perm_size,nMap)))
2292 Werror(
"no identity map from %s (%s -> %s)",u->
Fullname(),s1,s2);
2303 char *where=(
char *)u->
Data();
2304 char *what=(
char *)
v->Data();
2305 char *
found = strstr(where,what);
2308 res->data=(
char *)((
found-where)+1);
2317 ideal
id = (ideal)u->
Data();
2318 int max_length = (int)(
long)
v->Data();
2319 if (max_length < 0) {
2320 WerrorS(
"length for fres must not be negative");
2323 if (max_length == 0) {
2326 Warn(
"full resolution in a qring may be infinite, "
2327 "setting max length to %d", max_length);
2330 char *method = (
char *)
w->Data();
2334 if (strcmp(method,
"complete") != 0
2335 && strcmp(method,
"frame") != 0
2336 && strcmp(method,
"extended frame") != 0
2337 && strcmp(method,
"single module") != 0) {
2338 WerrorS(
"wrong optional argument for fres");
2342 res->data = (
void *)r;
2350 w->data = (
char *)
"complete";
2364 int uu=(int)(
long)u->
Data();
int vv=(int)(
long)
v->Data();
2365 int p0=
ABS(uu),p1=
ABS(vv);
2373 res->data=(
char *)(
long)p0;
2378 number n1 = (number) u->
Data();
2379 number n2 = (number)
v->Data();
2385 number a=(number) u->
Data();
2386 number
b=(number)
v->Data();
2411 PrintS(
"// NOTE: computation of Hilbert series etc. is being\n");
2412 PrintS(
"// performed for generic fibre, that is, over Q\n");
2420 switch((
int)(
long)
v->Data())
2423 res->data=(
void *)iv;
2436 int i=
pVar((poly)
v->Data());
2448 WerrorS(
"variable must have weight 1");
2453 int i=
pVar((poly)
v->Data());
2470 WerrorS(
"variable must have weight 1");
2477 ideal v_id=(ideal)
v->Data();
2486 currRing->pLexOrder=save_pLexOrder;
2509 const int n = L->
nr;
assume (n >= 0);
2510 std::vector<ideal> V(n + 1);
2512 for(
int i = n;
i >= 0;
i--) V[
i] = (ideal)(L->
m[
i].
Data());
2531 res->data = (
char *)
pJet((poly)u->
CopyD(), (int)(
long)
v->Data());
2565 h.data=(
void *)(
long)
IDELEMS((ideal)
v->Data());
2594 char *
s=(
char *)u->
Data();
2595 if(strcmp(
s,
"with")==0)
2597 if (strcmp(
s,
"try")==0)
2599 WerrorS(
"invalid second argument");
2600 WerrorS(
"load(\"libname\" [,option]);");
2622 ideal u_id=(ideal)u->
Data();
2623 ideal v_id=(ideal)
v->Data();
2626 if ((*w_u).compare((w_v))!=0)
2628 WarnS(
"incompatible weights");
2629 delete w_u; w_u=
NULL;
2637 WarnS(
"wrong weights");
2638 delete w_u; w_u=
NULL;
2643 res->data = (
char *)
idModulo(u_id,v_id ,hom,&w_u);
2654 number q=(number)
v->Data();
2665 number q=(number)
v->Data();
2676 poly q=(poly)
v->Data();
2682 poly
p=(poly)(u->
Data());
2700 char *opt=(
char *)
v->Data();
2712 if(strcmp(
l->m->type,
"ASCII")!=0)
2714 Werror(
"ASCII link required, not `%s`",
l->m->type);
2719 if (
l->name[0]!=
'\0')
2723 if (
v==
NULL) opt=(
const char*)
"i";
2724 else opt=(
const char *)
v->Data();
2766 const char *
s=(
const char *)u->
Data();
2767 newstruct_desc d=
NULL;
2773 else WerrorS(
"name of newstruct must be longer than 1 character");
2779 int i=(
int)(long)
v->Data();
2787 Werror(
"par number %d out of range 1..%d",
i,
p);
2797 WerrorS(
"basering must NOT be a qring!");
2817 WerrorS(
"basering must NOT be a qring!");
2837 WerrorS(
"basering must NOT be a qring!");
2857 WerrorS(
"basering must NOT be a qring!");
2879 const poly q = (poly)
b->Data();
2892 const poly
p = (poly)a->
Data();
2906 const poly q = (poly)
b->Data();
2911 const poly
p = (poly)a->
Data();
2912 int k=(int)(
long)c->
Data();
2916 for (
int i = 0;
i <
k;
i++)
2928 if (qq ==
NULL)
break;
2934 Werror(
"invalid number of iterations");
2944 ring r = (ring)a->
Data();
2947 res->data =
b->Data();
2948 res->rtyp =
b->rtyp;
2953 Werror(
"%s is not an opposite ring to current ring",a->
Fullname());
2966 res->rtyp = argtype;
2974 res->rtyp = argtype;
2982 res->rtyp = argtype;
2995 res->rtyp = argtype;
3000 WerrorS(
"unsupported type in oppose");
3024 int i=(int)(
long)u->
Data();
3025 int j=(int)(
long)
v->Data();
3026 if (
j-
i <0) {
WerrorS(
"invalid range for random");
return TRUE;}
3033 int isRowEchelon = (int)(
long)
v->Data();
3034 if (isRowEchelon != 1) isRowEchelon = 0;
3035 int rank =
luRank(
m, isRowEchelon);
3036 res->data =(
char *)(
long)rank;
3048 Werror(
"cannot read from `%s`",
s);
3057 ideal vi=(ideal)
v->Data();
3065 ideal ui=(ideal)u->
Data();
3066 ideal vi=(ideal)
v->Data();
3074 int maxl=(int)(
long)
v->Data();
3077 WerrorS(
"length for res must not be negative");
3083 ideal u_id=(ideal)u->
Data();
3092 "full resolution in a qring may be infinite, setting max length to %d",
3106 int add_row_shift=0;
3110 add_row_shift = ww->
min_in();
3111 (*ww) -= add_row_shift;
3127 (
"`lres` not implemented for inhomogeneous input or qring");
3131 WarnS(
"the current implementation of `lres` may not work in the case of a single variable");
3141 (
"`kres` not implemented for inhomogeneous input or qring");
3153 (
"`hres` not implemented for inhomogeneous input or qring");
3156 ideal u_id_copy=
idCopy(u_id);
3158 r=
syHilb(u_id_copy,&dummy);
3171 res->data=(
void *)r;
3172 if ((weights!=
NULL) && (ww!=
NULL)) {
delete ww; ww=
NULL; }
3176 if (weights!=
NULL) (*ww) += add_row_shift;
3205 n1 = (number)u->
CopyD();
3209 i = (int)(
long)u->
Data();
3217 i = (int)(
long)
v->Data();
3221 res->data = (
char*)
l;
3227 res->data = (
char *)r;
3240 res->data = (
char *)r;
3246 int i=
rSum((ring)u->
Data(),(ring)
v->Data(),r);
3247 res->data = (
char *)r;
3250 #define SIMPL_NORMALIZE 64
3251 #define SIMPL_LMDIV 32
3252 #define SIMPL_LMEQ 16
3253 #define SIMPL_MULT 8
3255 #define SIMPL_NULL 2
3256 #define SIMPL_NORM 1
3259 int sw = (int)(
long)
v->Data();
3290 res->data = (
char * )
id;
3297 int sw=(int)(
long)dummy->
Data();
3312 l->m[0].data=(
void *)
f;
3314 l->m[1].data=(
void *)
v;
3315 res->data=(
void *)
l;
3320 res->data=(
void *)
f;
3333 res->data=(
void *)
p;
3354 int sw = (int)(
long)
v->Data();
3365 res->data = (
char * )
p;
3373 ideal u_id=(ideal)(u->
Data());
3398 ideal i1=(ideal)(u->
Data());
3404 poly
p=(poly)
v->Data();
3408 memset(i0->m,0,
sizeof(poly)*
IDELEMS(i0));
3441 i0=(ideal)
v->CopyD();
3443 memset(i0->m,0,
sizeof(poly)*
IDELEMS(i0));
3482 ideal I=(ideal)u->
Data();
3491 ideal
A=(ideal)u->
Data();
3492 ideal
B=(ideal)
v->Data();
3498 sleftv tmp_u,tmp_v,tmp_res;
3518 int i=(
int)(long)
v->Data();
3539 int t = (int)(
long)
v->Data();
3549 res->data = (
void*)(
long)
i;
3564 int timeout = 1000*(int)(
long)
v->Data();
3572 for(
unsigned nfinished = 0; nfinished < ((unsigned)Lforks->
nr)+1; nfinished++)
3597 res->data = (
void*)(
long)ret;
3605 #define jjWRONG2 (proc2)jjWRONG
3606 #define jjWRONG3 (proc3)jjWRONG
3651 res->data = (
char *)n;
3656 res->data = (
char *)(-(
long)u->
Data());
3663 res->data = (
char *)n;
3681 res->data = (
char *)iv;
3688 res->data = (
char *)bim;
3697 ring r=(ring)u->
Data();
3701 char name_buffer[100];
3704 sprintf(name_buffer,
"PYTHON_RING_VAR%d",ending);
3728 l->m[0].data=(
void *)
m;
3729 l->m[1].data=(
void *)iv;
3730 res->data = (
char *)
l;
3750 number n=(number)u->
CopyD();
3774 number n=(number) tmp.
data;
3789 res->data = (
char *)(
long)
rChar((ring)
v->Data());
3799 res->data = (
char *)(
long)((
bigintmat*)(
v->Data()))->cols();
3804 res->data = (
char *)(
long)((
intvec*)(
v->Data()))->cols();
3812 res->data = (
char *)
p;
3823 res->data = (
char *)(
long)(aa->
rows()*aa->
cols());
3828 res->data = (
char *)(
long)
nSize((number)
v->Data());
3845 res->data = (
char *)(
long)((
intvec*)(
v->Data()))->length();
3850 ring r=(ring)
v->Data();
3856 extern int ipower (
int b,
int n );
3857 elems=
ipower(r->cf->ch,r->cf->extRing->pFDeg(r->cf->extRing->qideal->m[0],r->cf->extRing));
3859 res->data = (
char *)(
long)elems;
3865 poly
p=(poly)
v->Data();
3867 else res->data=(
char *)-1;
3872 ideal I=(ideal)u->
Data();
3878 res->data = (
char *)(
long)d;
3887 PrintS(
"// NOTE: computation of degree is being performed for\n");
3888 PrintS(
"// generic fibre, that is, over Q\n");
3907 else if (
v->rtyp!=0)
res->data=(
void *)(-1);
3915 number n =
reinterpret_cast<number
>(
v->Data());
3924 number n =
reinterpret_cast<number
>(
v->Data());
3939 i=
m->rows();
j=
m->cols();
3944 Werror(
"det of %d x %d bigintmat",
i,
j);
3953 number2 r=(number2)
omAlloc0(
sizeof(*r));
3955 i=
m->rows();
j=
m->cols();
3959 r->cf=
m->basecoeffs();
3964 Werror(
"det of %d x %d cmatrix",
i,
j);
3975 i=
m->rows();
j=
m->cols();
3980 Werror(
"det of %d x %d intmat",
i,
j);
3987 ideal I=(ideal)
v->Data();
3996 Warn(
"dim(%s) may be wrong because the mixed monomial ordering",
v->Name());
4001 ideal vid = (ideal)
v->Data();
4005 res->data = (
char *)-1L;
4027 for(
unsigned ii=0;ii<(unsigned)
IDELEMS(vv);ii++)
4036 for(
unsigned jj = 0;jj<(unsigned)
IDELEMS(vc)-1;jj++)
4038 if((vc->m[jj]!=
NULL)
4059 res->data = (
char *)d;
4075 Werror(
"cannot dump to `%s`",
s);
4084 int co=(int)(
long)
v->Data();
4090 else WerrorS(
"argument of gen must be positive");
4095 char * d = (
char *)
v->Data();
4096 char *
s = (
char *)
omAlloc(strlen(d) + 13);
4097 strcpy(
s, (
char *)d);
4098 strcat(
s,
"\n;RETURN();\n");
4135 WarnS(
"no factorization implemented");
4139 res->data=(
void *)L;
4152 l->m[0].data=(
void *)
f;
4154 l->m[1].data=(
void *)
v;
4155 res->data=(
void *)
l;
4166 Werror(
"cannot get dump from `%s`",
s);
4175 ideal I=(ideal)
v->Data();
4184 ideal I=(ideal)
v->Data();
4198 WerrorS(
"module must be zero-dimensional");
4199 if (delete_w)
delete w;
4222 if (delete_w)
delete w;
4223 res->data=(
void *)po;
4231 PrintS(
"// NOTE: computation of Hilbert series etc. is being\n");
4232 PrintS(
"// performed for generic fibre, that is, over Q\n");
4246 PrintS(
"// NOTE: computation of Hilbert series etc. is being\n");
4247 PrintS(
"// performed for generic fibre, that is, over Q\n");
4256 ideal v_id=(ideal)
v->Data();
4264 char *s_isHomog=
omStrDup(
"isHomog");
4270 else if (
w!=
NULL)
delete w;
4288 #ifdef HAVE_SHIFTBBA
4291 int deg = (int)(
long)
v->Data();
4293 WerrorS(
"degree bound of Letterplace ring is to small");
4317 res->data=(
char *)mat;
4327 res->data=(
char *)I;
4334 ring q=(ring)
v->Data();
4337 if (q->qideal==
NULL)
4344 WerrorS(
"can only get ideal from identical qring");
4370 WarnS(
"interred: this command is experimental over the integers");
4378 res->data = (
char *)(
long)
pVar((poly)
v->Data());
4389 res->data = (
char *)0;
4396 poly
p=(poly)(
v->Data());
4401 res->data = (
char *)
i;
4408 WerrorS(
"differentiation not defined in the coefficient ring");
4411 number n = (number) u->
Data();
4412 number
k = (number)
v->Data();
4425 ideal
id = (ideal)a->
Data();
4435 for(
int i = 0;
i < W;
i++,
p++, q++ )
4461 poly
p=(poly)
v->Data();
4474 poly
p=(poly)
v->Data();
4487 res->data=(
char *)iv;
4492 poly
p=(poly)
v->Data();
4501 res->data = (
char*) lm;
4513 if (mm==0) mm=0x7fff;
4514 int isLetterplace=(int)(
long)
atGet(
v,
"isLetterplaceRing",
INT_CMD);
4516 res->data=(
char *)r;
4524 memset(&tmp, 0,
sizeof(tmp));
4540 WerrorS(
"matrix must be constant");
4554 res->data=(
char*)ll;
4565 switch(((
int)(
long)
v->Data()))
4580 res->data = (
char *)0;
4584 res->data = (
char *)0;
4599 l->m[0].data=(
char *)r;
4602 l->m[1].data=(
char *)
m;
4603 res->data=(
char *)
l;
4619 res->data=(
char *)tmp;
4628 number n,
i;
i=(number)
v->Data();
4633 res->data=(
void *)n;
4663 res->data=(
char*)(
long)((long)
v->Data()==0 ? 1 : 0);
4668 res->data = (
char *)(
long)(((ring)(
v->Data()))->N);
4679 poly
p=(poly)
v->Data();
4685 int i=(int)(
long)
v->Data();
4688 if ((0<
i) && (
i<=
p))
4694 Werror(
"par number %d out of range 1..%d",
i,
p);
4701 number nn=(number)
v->Data();
4712 int i=(int)(
long)
v->Data();
4718 Werror(
"par number %d out of range 1..%d",
i,
p);
4725 poly
p=(poly)
v->Data();
4729 WerrorS(
"poly must be constant");
4738 res->data=(
void *)n;
4745 poly
p=(poly)
v->Data();
4749 WerrorS(
"poly must be constant");
4763 int i =
IsPrime((
int)(
long)(
v->Data()));
4764 res->data = (
char *)(
long)(
i > 1 ?
i : 2);
4770 ideal v_id=(ideal)
v->Data();
4775 WarnS(
"wrong weights");
4795 if (((
p=(poly)
v->Data())!=
NULL)
4804 res->data = (
char *)n;
4809 char *
s= (
char *)
v->Data();
4816 res->data = (
char *)1;
4825 res->data = (
char *)1;
4833 res->data =(
char *)(
long)rank;
4852 ring r=(ring)
v->Data();
4858 long mm=r->bitmask/2;
4875 ring r=(ring)
v->Data();
4882 ideal
i = (ideal)
v->Data();
4883 res->data = (
char *)
i->rank;
4888 res->data = (
char *)(
long)((
bigintmat*)(
v->Data()))->rows();
4893 res->data = (
char *)(
long)((
intvec*)(
v->Data()))->rows();
4898 res->data = (
char *)(
long)
rPar(((ring)
v->Data()));
4907 WerrorS(
"qring not supported by slimgb at the moment");
4912 WerrorS(
"ordering must be global for slimgb");
4916 WarnS(
"groebner base computations with inexact coefficients can not be trusted due to rounding errors");
4919 ideal u_id=(ideal)u->
Data();
4924 WarnS(
"wrong weights");
4946 ideal v_id=(ideal)
v->Data();
4953 WarnS(
"wrong weights");
4972 ideal v_id=(ideal)
v->Data();
4979 WarnS(
"wrong weights");
4998 ideal v_id=(ideal)
v->Data();
5005 WarnS(
"wrong weights");
5024 WarnS(
"groebner base computations with inexact coefficients can not be trusted due to rounding errors");
5026 ideal v_id=(ideal)
v->Data();
5033 WarnS(
"wrong weights");
5051 res->data = (
char *)
idSort((ideal)
v->Data());
5064 l->m[0].data=(
void *)
f;
5066 l->m[1].data=(
void *)
v;
5067 res->data=(
void *)
l;
5084 ideal v_id=(ideal)
v->Data();
5086 int add_row_shift=0;
5090 add_row_shift=
w->min_in();
5091 (*w)-=add_row_shift;
5116 res->data = (
char *)(((
bigintmat*)(
v->Data()))->transpose());
5127 ring r = (ring)a->
Data();
5135 WarnS(
"opposite only for global orderings");
5142 ring r = (ring)a->
Data();
5154 ideal v_id=(ideal)a->
Data();
5167 #if defined(HAVE_SHIFTBBA) || defined(HAVE_PLURAL)
5173 WarnS(
"groebner base computations with inexact coefficients can not be trusted due to rounding errors");
5175 ideal v_id=(ideal)
v->Data();
5201 ideal I=(ideal)
v->Data();
5216 res->data = (
char *)J;
5228 int t=(int)(
long)
v->data;
5278 int i=(int)(
long)
v->Data();
5284 res->data=(
char *)
p;
5300 int i=(int)(
long)
v->Data();
5328 res->data = (
void*)(
long)
i;
5341 for(
int nfinished = 0; nfinished < Lforks->
nr+1; nfinished++)
5357 res->data = (
void*)(
long)
j;
5367 #ifdef HAVE_DYNAMIC_LOADING
5374 Werror(
"%s: unknown type",
s);
5392 Werror(
"can not create package `%s`",plib);
5398 package pa=IDPACKAGE(pl);
5402 Werror(
"can not create package `%s` - binaries exists",plib);
5408 package savepack=currPack;
5424 #ifdef HAVE_DYNAMIC_LOADING
5427 WerrorS(
"Dynamic modules are not supported by this version of Singular");
5447 Print(
"loading of >%s< failed\n",
s);
5456 res->data = (
char *)strlen((
char *)
v->Data());
5461 res->data = (
char *)(
long)
pLength((poly)
v->Data());
5466 res->data = (
char *)(
long)
idElem((ideal)
v->Data());
5486 res->data = (
char *)
pHead((poly)
v->Data());
5554 number n=(number)u->
CopyD();
5561 number n=(number)u->
Data();
5570 char *
s= (
char *)u->
Data();
5571 int r = (int)(
long)
v->Data();
5572 int c = (int)(
long)
w->Data();
5575 if ( (r<1) || (r>
l) || (c<0) )
5581 sprintf((
char *)
res->data,
"%-*.*s",c,c,
s+r-1);
5587 int r = (int)(
long)
v->Data();
5588 int c = (int)(
long)
w->Data();
5589 if ((r<1)||(r>iv->
rows())||(c<1)||(c>iv->
cols()))
5591 Werror(
"wrong range[%d,%d] in intmat %s(%d x %d)",
5604 while (
h->next!=
NULL)
h=
h->next;
5614 int r = (int)(
long)
v->Data();
5615 int c = (int)(
long)
w->Data();
5616 if ((r<1)||(r>bim->
rows())||(c<1)||(c>bim->
cols()))
5618 Werror(
"wrong range[%d,%d] in bigintmat %s(%d x %d)",
5632 while (
h->next!=
NULL)
h=
h->next;
5642 int r = (int)(
long)
v->Data();
5643 int c = (int)(
long)
w->Data();
5647 Werror(
"wrong range[%d,%d] in matrix %s(%d x %d)",r,c,u->
Fullname(),
5661 while (
h->next!=
NULL)
h=
h->next;
5670 ideal
m= (ideal)u->
Data();
5671 int r = (int)(
long)
v->Data();
5672 int c = (int)(
long)
w->Data();
5674 if ((r<1)||(r>
m->rank)||(c<1)||(c>
IDELEMS(
m)))
5676 Werror(
"wrong range[%d,%d] in matrix %s(%d x %d)",r,c,u->
Fullname(),
5690 while (
h->next!=
NULL)
h=
h->next;
5708 WerrorS(
"cannot build expression lists from unnamed objects");
5711 memcpy(&ut,u,
sizeof(ut));
5712 memset(&t,0,
sizeof(t));
5716 t.
data=(
char *)(
long)((*iv)[
l]);
5726 memcpy(u,&ut,
sizeof(ut));
5758 WerrorS(
"cannot build expression lists from unnamed objects");
5761 memcpy(&ut,u,
sizeof(ut));
5762 memset(&t,0,
sizeof(t));
5766 t.
data=(
char *)(
long)((*iv)[
l]);
5776 memcpy(u,&ut,
sizeof(ut));
5809 WerrorS(
"cannot build expression lists from unnamed objects");
5812 memcpy(&ut,u,
sizeof(ut));
5813 memset(&t1,0,
sizeof(
sleftv));
5814 memset(&t2,0,
sizeof(
sleftv));
5817 for (vl=0;vl< vv->
length(); vl++)
5819 t1.
data=(
char *)(
long)((*vv)[vl]);
5820 for (wl=0;wl< wv->
length(); wl++)
5822 t2.
data=(
char *)(
long)((*wv)[wl]);
5832 memcpy(u,&ut,
sizeof(ut));
5872 int k=(int)(
long)
w->Data();
5879 l->m[0].data=(
void *)
m;
5880 l->m[1].data=(
void *)iv;
5887 l->m[0].data=(
void *)
m;
5889 res->data = (
char *)
l;
5896 WerrorS(
"3rd argument must be a name of a matrix");
5899 ideal
i=(ideal)u->
Data();
5900 int rank=(int)
i->rank;
5909 (ideal)(
v->Data()),(poly)(
w->Data()));
5916 WerrorS(
"3rd argument must be a name of a matrix");
5924 memset(&t,0,
sizeof(t));
5941 ideal I=(ideal)u->
Data();
5962 int n=(int)(
long)
w->Data();
5963 char *where=(
char *)u->
Data();
5964 char *what=(
char *)
v->Data();
5966 if ((1>n)||(n>(int)strlen(where)))
5968 Werror(
"start position %d out of range",n);
5971 found = strchr(where+n-1,*what);
5972 if (*(what+1)!=
'\0')
5974 while((
found !=
NULL) && (strncmp(
found+1,what+1,strlen(what+1))!=0))
5981 res->data=(
char *)((
found-where)+1);
5987 if ((
int)(
long)
w->Data()==0)
5999 Werror(
"weight vector must have size %d, not %d",
6006 PrintS(
"// NOTE: computation of Hilbert series etc. is being\n");
6007 PrintS(
"// performed for generic fibre, that is, over Q\n");
6015 switch((
int)(
long)
v->Data())
6018 res->data=(
void *)iv;
6032 int i=
pVar((poly)
v->Data());
6044 WerrorS(
"variable must have weight 1");
6050 int i=
pVar((poly)
v->Data());
6062 WerrorS(
"variable must have weight 1");
6067 intvec* im=
new intvec((
int)(
long)
v->Data(),(
int)(
long)
w->Data(), 0);
6073 (*im)[
i] = (*arg)[
i];
6076 res->data = (
char *)im;
6081 ideal I1=(ideal)u->
Data();
6082 ideal I2=(ideal)
v->Data();
6083 ideal I3=(ideal)
w->Data();
6094 ideal I=(ideal)u->
Data();
6096 res->data=(
char *)
idSect(I,(ideal)
v->Data(),alg);
6103 res->data = (
char *)
ppJetW((poly)u->
Data(),(int)(
long)
v->Data(),iw);
6111 WerrorS(
"2nd argument must be a unit");
6127 WerrorS(
"2nd argument must be a diagonal matrix of units");
6174 Werror(
"`%s` is undefined",
v->Fullname());
6190 const int mk = (
const int)(
long)u->
Data();
6191 bool noIdeal =
true;
bool noK =
true;
bool noAlgorithm =
true;
6192 bool noCacheMinors =
true;
bool noCacheMonomials =
true;
6193 ideal IasSB;
int k;
char* algorithm;
int cacheMinors;
int cacheMonomials;
6209 noAlgorithm =
false;
6214 noCacheMinors =
false;
6220 noCacheMonomials =
false;
6234 noAlgorithm =
false;
6239 noCacheMinors =
false;
6244 noCacheMonomials =
false;
6251 algorithm = (
char*)u->
next->
Data();
6252 noAlgorithm =
false;
6256 noCacheMinors =
false;
6261 noCacheMonomials =
false;
6269 if (strcmp(algorithm,
"bareiss") == 0)
6270 algorithm = (
char*)
"Bareiss";
6271 if (strcmp(algorithm,
"laplace") == 0)
6272 algorithm = (
char*)
"Laplace";
6273 if (strcmp(algorithm,
"cache") == 0)
6274 algorithm = (
char*)
"Cache";
6283 if ((!noK) && (
k == 0))
6285 WerrorS(
"Provided number of minors to be computed is zero.");
6288 if ((!noAlgorithm) && (strcmp(algorithm,
"Bareiss") != 0)
6289 && (strcmp(algorithm,
"Laplace") != 0)
6290 && (strcmp(algorithm,
"Cache") != 0))
6292 WerrorS(
"Expected as algorithm one of 'B/bareiss', 'L/laplace', or 'C/cache'.");
6295 if ((!noAlgorithm) && (strcmp(algorithm,
"Bareiss") == 0)
6298 Werror(
"Bareiss algorithm not defined over coefficient rings %s",
6299 "with zero divisors.");
6303 if ((mk < 1) || (mk >
m->rows()) || (mk >
m->cols()))
6312 if ((!noAlgorithm) && (strcmp(algorithm,
"Cache") == 0)
6313 && (noCacheMinors || noCacheMonomials))
6316 cacheMonomials = 100000;
6322 (noIdeal ? 0 : IasSB),
false);
6323 else if (strcmp(algorithm,
"Cache") == 0)
6325 (noIdeal ? 0 : IasSB), 3, cacheMinors,
6326 cacheMonomials,
false);
6329 (noIdeal ? 0 : IasSB),
false);
6339 (
const char *)
w->Data());
6353 WerrorS(
"2nd/3rd arguments must have names");
6357 const char *ring_name=u->
Name();
6364 if ((preim_ring==
NULL)
6367 Werror(
"preimage ring `%s` is not the basering",mapping->preimage);
6383 Werror(
"`%s` is not defined in `%s`",
v->
name,ring_name);
6387 if (kernel_cmd) image=
idInit(1,1);
6404 Werror(
"`%s` is not defined in `%s`",
w->name,ring_name);
6411 WarnS(
"preimage in local qring may be wrong: use Ring::preimageLoc instead");
6420 int i=(int)(
long)u->
Data();
6421 int r=(int)(
long)
v->Data();
6422 int c=(int)(
long)
w->Data();
6423 if ((r<=0) || (c<=0))
return TRUE;
6439 res->data = (
char *)iv;
6449 Werror(
"no random function defined for coeff %d",
cf->type);
6455 number2 nn=(number2)
omAlloc(
sizeof(*nn));
6465 int &ringvar, poly &monomexpr)
6467 monomexpr=(poly)
w->Data();
6468 poly
p=(poly)
v->Data();
6472 Werror(
"`%s` substitutes a ringvar only by a term",
6477 if ((ringvar=
pVar(
p))==0)
6486 WerrorS(
"ringvar/par expected");
6510 if (nok)
return TRUE;
6511 poly
p=(poly)u->
Data();
6536 if (nok)
return TRUE;
6537 ideal
id=(ideal)u->
Data();
6541 if (monomexpr!=
NULL)
6556 Warn(
"possible OVERFLOW in subst, max exponent is %ld",
currRing->bitmask/2);
6586 memset(&tmp,0,
sizeof(tmp));
6595 int mi=(int)(
long)
v->Data();
6596 int ni=(int)(
long)
w->Data();
6599 Werror(
"converting ideal to matrix: dimensions must be positive(%dx%d)",mi,ni);
6610 memcpy(
m->m,I->m,
i*
sizeof(poly));
6611 memset(I->m,0,
i*
sizeof(poly));
6613 res->data = (
char *)
m;
6618 int mi=(int)(
long)
v->Data();
6619 int ni=(int)(
long)
w->Data();
6622 Werror(
"converting module to matrix: dimensions must be positive(%dx%d)",mi,ni);
6631 int mi=(int)(
long)
v->Data();
6632 int ni=(int)(
long)
w->Data();
6635 Werror(
"converting matrix to matrix: dimensions must be positive(%dx%d)",mi,ni);
6652 res->data = (
char *)
m;
6657 int mi=(int)(
long)
v->Data();
6658 int ni=(int)(
long)
w->Data();
6661 Werror(
"converting to smatrix: dimensions must be positive(%dx%d)",mi,ni);
6689 &(hw->data.uideal));
6698 Werror(
"`%s` must be 0-dimensional",
v->Name());
6710 Werror(
"`%s` must be 0-dimensional",
v->Name());
6721 0,(int)(
long)
w->Data());
6728 0,(int)(
long)
w->Data());
6734 int maxl=(int)
v->Data();
6735 ideal u_id=(ideal)u->
Data();
6751 WarnS(
"wrong weights");
6779 yes = (strcmp((
char *)
res->data, (
char *)
w->Data()) == 0);
6781 res->data = (
void *)(
long)yes;
6795 ideal u_id=(ideal)(u->
Data());
6800 WarnS(
"wrong weights");
6841 lineno=(int)(
long)
v->
next->Data();
6905 WarnS(
"<module>,<module>,<int>[,<intvec>] expected!");
6912 ideal P=(ideal)w1.
Data();
6913 ideal
Q=(ideal)w2.
Data();
6915 int n=(int)(
long)v3->
Data();
6922 while( (
i > 0) && ((*w0) > 0) )
6928 WarnS(
"not all weights are positive!");
6947 L->
m[1].
data=(
void *)
R->m[0];
7032 res->data=(
char *)
id;
7037 ring r=(ring)u->
Data();
7045 WerrorS(
"fetch(<ring>,<name>[,<intvec>[,<intvec>])");
7050 if (perm_par_l!=
NULL)
7059 int par_perm_size=0;
7068 par_perm_size=
rPar(r);
7076 par_perm_size=
rPar(r);
7078 if (par_perm_size!=0)
7079 par_perm=(
int *)
omAlloc0(par_perm_size*
sizeof(
int));
7081 if (perm_par_l==
NULL)
7083 if (par_perm_size!=0)
7088 if (par_perm_size==0)
WarnS(
"source ring has no parameters");
7093 if (i<perm_par_v->
length()) par_perm[
i]=(*perm_par_v)[
i];
7097 Warn(
"invalid entry for par %d: %d\n",
i,par_perm[
i]);
7105 if (i<perm_var_v->
length()) perm[
i+1]=(*perm_var_v)[
i];
7109 Warn(
"invalid entry for var %d: %d\n",
i,perm[
i]);
7118 Print(
"// var nr %d: %s -> var %s\n",
i,r->names[
i-1],
currRing->names[perm[
i]-1]);
7124 if (par_perm[
i-1]<0)
7125 Print(
"// par nr %d: %s -> par %s\n",
7127 else if (par_perm[
i-1]>0)
7128 Print(
"// par nr %d: %s -> var %s\n",
7134 memset(&tmpW,0,
sizeof(
sleftv));
7138 perm,par_perm,par_perm_size,nMap)))
7156 Werror(
"no identity map from %s (%s -> %s)",u->
Fullname(),s1,s2);
7163 int l=
v->listLength();
7194 WerrorS(
"cannot convert to ideal or module");
7205 r[
i]=(ideal)
h->Data();
7217 r[
i]=(ideal)tmp.
Data();
7249 matrix iMat;
int invertible;
7255 int rr = aMat->
rows();
7256 int cc = aMat->
cols();
7259 Werror(
"given matrix (%d x %d) is not quadratic, hence not invertible", rr, cc);
7264 WerrorS(
"matrix must be constant");
7274 int rr = uMat->
rows();
7275 int cc = uMat->
cols();
7278 Werror(
"third matrix (%d x %d) is not quadratic, hence not invertible",
7287 WerrorS(
"matricesx must be constant");
7294 Werror(
"expected either one or three matrices");
7312 res->data=(
char*)ll;
7336 WerrorS(
"expected exactly three matrices and one vector as input");
7346 Werror(
"first matrix (%d x %d) is not quadratic",
7352 Werror(
"second matrix (%d x %d) is not quadratic",
7358 Werror(
"second matrix (%d x %d) and third matrix (%d x %d) do not fit",
7364 Werror(
"third matrix (%d x %d) and vector (%d x 1) do not fit",
7373 WerrorS(
"matrices must be constant");
7393 res->data=(
char*)ll;
7407 (*iv)[
i]=(int)(
long)
h->Data();
7426 res->data=(
char *)iv;
7443 WerrorS(
"2nd argument must be a unit");
7456 WerrorS(
"2nd argument must be a diagonal matrix of units");
7461 (
int)(long)u3->
Data(),
7470 Werror(
"%s(`poly`,`poly`,`int`,`intvec`) exppected",
7488 else if (
w->next==
NULL)
7515 && ((strcmp(u->
Name(),
"real")==0) || (strcmp(u->
Name(),
"complex")==0)))
7518 memset(u,0,
sizeof(
sleftv));
7536 Werror(
"`int` expected while building `%s(`",u->
name);
7541 sprintf(nn,
"%s(%d",u->
name,(
int)(
long)
v->Data());
7545 while (*
s!=
'\0')
s++;
7549 Werror(
"`int` expected while building `%s`",nn);
7553 sprintf(
s,
",%d",(
int)(
long)
v->Data());
7555 while (*
s!=
'\0')
s++;
7576 ideal I=(ideal)u->
Data();
7589 Werror(
"%s(`ideal`,`ideal`,`matrix`,`string`)\n"
7590 "or (`module`,`module`,`matrix`,`string`)expected",
7608 ideal I=(ideal)u->
Data();
7615 &(hw->data.uideal),alg);
7621 Werror(
"%s(`ideal`,`ideal`,`matrix`,`string`)\n"
7622 "or (`module`,`module`,`matrix`,`string`)expected",
7630 if (
v!=
NULL) sl =
v->listLength();
7634 int add_row_shift = 0;
7636 if (weights!=
NULL) add_row_shift=weights->
min_in();
7663 Werror(
"`%s` is undefined",
h->Fullname());
7669 ((ring)L->
m[
i].
data)->ref++;
7675 res->data=(
char *)L;
7724 WerrorS(
"2nd argument must be a diagonal matrix of units");
7732 (int)(
long)u4->
Data()
7742 else u1p=(poly)u1->
Data();
7745 else u2p=(poly)u2->
Data();
7749 WerrorS(
"2nd argument must be a unit");
7778 WerrorS(
"2nd argument must be a diagonal matrix of units");
7786 (int)(
long)u4->
Data(),
7798 WerrorS(
"2nd argument must be a unit");
7809 Werror(
"%s(`ideal`,`ideal`,`matrix`,`int`,`intvec`) exppected",
7821 for(
i=0;
i<nCount;
i++)
7842 int n =
v->listLength();
7845 res->data =
v->String();
7849 char** slist = (
char**)
omAlloc(n*
sizeof(
char*));
7854 slist[
i] =
v->String();
7856 j+=strlen(slist[
i]);
7858 char*
s = (
char*)
omAlloc((
j+1)*
sizeof(char));
7862 strcat(
s, slist[
i]);
7882 #if defined(__alpha) && !defined(linux)
7885 void usleep(
unsigned long usec);
7914 leftv u =
v;
int factorsGiven = 0;
7917 WerrorS(
"expected arguments (poly, int [, poly, poly] [, int, int])");
7920 else h = (poly)u->
Data();
7924 WerrorS(
"expected arguments (poly, int [, poly, poly] [, int, int])");
7927 else d = (int)(
long)u->
Data();
7933 WerrorS(
"expected arguments (poly, int [, poly, poly] [, int, int])");
7938 f0 = (poly)u->
Data();
7948 WerrorS(
"expected arguments (poly, int [, poly, poly] [, int, int])");
7953 xIndex = (int)(
long)u->
Data();
7954 yIndex = (int)(
long)u->
next->
Data();
7960 WerrorS(
"expected arguments (poly, int [, poly, poly] [, int, int])");
7967 WerrorS(
"expected non-constant polynomial argument(s)");
7971 if ((xIndex < 1) || (n < xIndex))
7973 Werror(
"index for variable x (%d) out of range [1..%d]", xIndex, n);
7976 if ((yIndex < 1) || (n < yIndex))
7978 Werror(
"index for variable y (%d) out of range [1..%d]", yIndex, n);
7981 if (xIndex == yIndex)
7983 WerrorS(
"expected distinct indices for variables x and y");
7988 if (factorsGiven == 0)
8002 WerrorS(
"expected h(0,y) to have exactly two distinct monic factors");
8017 res->data = (
char*)L;
8028 #if defined(HAVE_USLEEP)
8029 if (((
long)
res->data) == 0L)
8038 #elif defined(HAVE_SLEEP)
8039 if (((
int)
res->data) == 0)
8044 si_sleep((is - 1)/1000000 + 1);
8063 if ((rest!=
NULL) && (!
b))
8068 memset(&tmp_res,0,
sizeof(tmp_res));
8070 memcpy(
res,&tmp_res,
sizeof(tmp_res));
8085 WerrorS(
"expected (matrix, number, number, number) as arguments");
8090 (number)(
v->Data()),
8091 (number)(
w->Data()),
8092 (number)(
x->Data()));
8102 ideal i1=(ideal)(u->
Data());
8108 WerrorS(
"expected `std(`ideal/module`,`poly/vector`,`intvec`,`intvec`)");
8123 i0->m[0]=(poly)
v->Data();
8128 i0=(ideal)
v->Data();
8132 WerrorS(
"expected `std(`ideal/module`,`poly/vector`,`intvec`,`intvec`)");
8139 memset(i0->m,0,
sizeof(poly)*
IDELEMS(i0));
8149 WarnS(
"wrong weights");
8183 WerrorS(
"expected `cring` [ `id` ... ]");
8189 char **n=(
char**)
omAlloc0(
N*
sizeof(
char*));
8190 for(
int i=0;
i<
N;
i++,names=names->
next)
8192 n[
i]=(
char *)names->
Name();
8204 r->start =(int)(
long)e->
Data();
8209 int c=(int)(
long)u->
Data();
8213 PrintS(
"delete all variables\n");
8218 default:
WerrorS(
"not implemented");
8223 #define NULL_VAL NULL
8227 #include "iparith.inc"
8246 while (dA2[
i].cmd==op)
8248 if ((at==dA2[
i].arg1)
8249 && (bt==dA2[
i].arg2))
8266 if ((call_failed=dA2[
i].
p(
res,a,
b)))
8286 while (dA2[
i].cmd==op)
8313 || (call_failed=dA2[
i].
p(
res,an,bn)));
8352 Werror(
"`%s` is not defined",
s);
8359 Werror(
"%s(`%s`,`%s`) failed"
8364 Werror(
"`%s` %s `%s` failed"
8369 while (dA2[
i].cmd==op)
8371 if(((at==dA2[
i].arg1)||(bt==dA2[
i].arg2))
8376 Werror(
"expected %s(`%s`,`%s`)"
8379 Werror(
"expected `%s` %s `%s`"
8417 memcpy(&d->arg1,a,
sizeof(
sleftv));
8419 memcpy(&d->arg2,
b,
sizeof(
sleftv));
8423 res->data=(
char *)d;
8436 if (!bb->blackbox_Op2(op,
res,a,
b))
return FALSE;
8442 else if ((bt>
MAX_TOK)&&(op!=
'('))
8447 if(!bb->blackbox_Op2(op,
res,a,
b))
return FALSE;
8475 while (dA1[
i].cmd==op)
8494 if ((call_failed=dA1[
i].
p(
res,a)))
8514 while (dA1[
i].cmd==op)
8538 || (call_failed=dA1[
i].
p(
res,an)));
8579 while (dA1[
i].cmd==op)
8583 Werror(
"expected %s(`%s`)"
8606 memcpy(&d->arg1,a,
sizeof(
sleftv));
8610 res->data=(
char *)d;
8623 res->data=bb->blackbox_Init(bb);
8624 if(!bb->blackbox_Assign(
res,a))
return FALSE;
8634 if(!bb->blackbox_Op1(op,
res,a))
return FALSE;
8655 const struct sValCmd3* dA3,
int at,
int bt,
int ct,
8667 while (dA3[
i].cmd==op)
8669 if ((at==dA3[
i].arg1)
8670 && (bt==dA3[
i].arg2)
8671 && (ct==dA3[
i].arg3))
8679 Print(
"call %s(%s,%s,%s)\n",
8681 if ((call_failed=dA3[
i].
p(
res,a,
b,c)))
8702 while (dA3[
i].cmd==op)
8718 Print(
"call %s(%s,%s,%s)\n",
8724 || (call_failed=dA3[
i].
p(
res,an,bn,cn)));
8773 Werror(
"`%s` is not defined",
s);
8779 Werror(
"%s(`%s`,`%s`,`%s`) failed"
8783 while (dA3[
i].cmd==op)
8785 if(((at==dA3[
i].arg1)
8787 ||(ct==dA3[
i].arg3))
8790 Werror(
"expected %s(`%s`,`%s`,`%s`)"
8819 memcpy(&d->arg1,a,
sizeof(
sleftv));
8821 memcpy(&d->arg2,
b,
sizeof(
sleftv));
8823 memcpy(&d->arg3,c,
sizeof(
sleftv));
8827 res->data=(
char *)d;
8839 if(!bb->blackbox_Op3(op,
res,a,
b,c))
return FALSE;
8888 if(
v==
NULL)
return failed;
8910 res->data=(
char *)d;
8915 memcpy(&d->arg1,a,
sizeof(
sleftv));
8950 if(!bb->blackbox_OpM(op,
res,a))
return FALSE;
8965 if ((args==
dArithM[
i].number_of_args)
8967 || ((
dArithM[
i].number_of_args==-2)&&(args>0)))
9065 Warn(
"outdated identifier `%s` used - please change your code",
9116 if (op==dArithTab[
p].cmd)
return dArithTab[
p].start;
9117 if (op<dArithTab[
p].cmd) e=
p-1;
9137 if (tok==
ANY_TYPE)
return "any_type";
9138 if (tok==
COMMAND)
return "command";
9139 if (tok==
NONE)
return "nothing";
9151 if (tok==
IDHDL)
return "identifier";
9187 cmdnames *pCmdL = (cmdnames*)a;
9188 cmdnames *pCmdR = (cmdnames*)
b;
9193 if(pCmdL->name==
NULL)
return 1;
9194 if(pCmdR->name==
NULL)
return -1;
9197 if(strcmp(pCmdL->name,
"$INVALID$")==0)
return -1;
9198 if(strcmp(pCmdR->name,
"$INVALID$")==0)
return 1;
9201 if (pCmdL->tokval==-1)
9203 if (pCmdR->tokval==-1)
9204 return strcmp(pCmdL->name, pCmdR->name);
9209 if(pCmdR->tokval==-1)
return -1;
9211 return strcmp(pCmdL->name, pCmdR->name);
9319 if(nPos<0)
return NULL;
9328 if(szName==
NULL)
return -1;
9333 Print(
"'%s' not found (%d)\n", szName, nIndex);
9376 if(szName==
NULL)
return -1;
9380 Print(
"'%s' already exists at %d\n", szName, nIndex);
9418 WerrorS(
"not implemented for non-commutative rings");
9428 #ifdef HAVE_SHIFTBBA
9444 WerrorS(
"not implemented for rings with rings as coeffients");
9451 WerrorS(
"domain required as coeffients");
9457 WarnS(
"considering the image in Q[...]");
9470 WerrorS(
"not implemented for rings with rings as coeffients (except ZZ)");
9476 int return_type=c->
m[0].
Typ();
9492 for (
unsigned i=0;
i<=(unsigned)c->
nr;
i++)
9497 if (bo) {
Werror(
"chinrem failed for list entry %d",
i+1);
break;}
9507 WerrorS(
"poly/ideal/module/matrix/list expected");
9524 ideal *
x=(ideal *)
omAlloc(rl*
sizeof(ideal));
9530 for(
i=rl-1;
i>=0;
i--)
9532 if (c->
m[
i].
Typ()!=return_type)
9557 xx=(number *)
omAlloc(rl*
sizeof(number));
9558 for(
i=rl-1;
i>=0;
i--)
9570 Werror(
"bigint expected at pos %d",
i+1);
9577 number *q=(number *)
omAlloc(rl*
sizeof(number));
9580 for(
i=rl-1;
i>=0;
i--)
9587 for(
i=rl-1;
i>=0;
i--)
9599 Werror(
"bigint expected at pos %d",
i+1);
9615 res->data=(
char *)n;
9630 for(
i=rl-1;
i>=0;
i--)
9635 res->rtyp=return_type;
9645 for (
unsigned i=0;
i<=(unsigned)c->
nr;
i++)
9650 if (bo) {
Werror(
"farey failed for list entry %d",
i+1);
break;}
9663 if (at < bt)
return -1;
9664 if (at > bt)
return 1;
9665 int tab_pos=
iiTabIndex(dArithTab2,JJTAB2LEN,
'<');
9667 memset(&tmp,0,
sizeof(
sleftv));
9673 unsigned long ad=(
unsigned long)a->
Data();
9674 unsigned long bd=(
unsigned long)
b->Data();
9675 if (ad<bd)
return -1;
9676 else if (ad==bd)
return 0;
9687 unsigned long ad=(
unsigned long)a->
Data();
9688 unsigned long bd=(
unsigned long)
b->Data();
9689 if (ad<bd)
return -1;
9690 else if (ad==bd)
return 0;
9721 for(
j=
i;
j<len;
j++)
l->m[
j]=
l->m[
j+1];
9722 memset(&(
l->m[len]),0,
sizeof(
sleftv));
ideal getMinorIdealCache(const matrix mat, const int minorSize, const int k, const ideal iSB, const int cacheStrategy, const int cacheN, const int cacheW, const bool allDifferent)
Returns the specified set of minors (= subdeterminantes) of the given matrix.
ideal getMinorIdeal(const matrix mat, const int minorSize, const int k, const char *algorithm, const ideal iSB, const bool allDifferent)
Returns the specified set of minors (= subdeterminantes) of the given matrix.
ideal getMinorIdealHeuristic(const matrix mat, const int minorSize, const int k, const ideal iSB, const bool allDifferent)
Returns the specified set of minors (= subdeterminantes) of the given matrix.
void * atGet(idhdl root, const char *name, int t, void *defaultReturnValue)
void atSet(idhdl root, char *name, void *data, int typ)
static int si_max(const int a, const int b)
static int si_min(const int a, const int b)
bigintmat * bimSub(bigintmat *a, bigintmat *b)
bigintmat * bimMult(bigintmat *a, bigintmat *b)
intvec * bim2iv(bigintmat *b)
bigintmat * bimAdd(bigintmat *a, bigintmat *b)
Matrix-Add/-Sub/-Mult so oder mit operator+/-/* ? @Note: NULL as a result means an error (non-compati...
blackbox * getBlackboxStuff(const int t)
return the structure to the type given by t
const char * getBlackboxName(const int t)
return the name to the type given by t (r/o)
int blackboxIsCmd(const char *n, int &tok)
used by scanner: returns ROOT_DECL for known types (and the type number in tok)
void printBlackboxTypes()
list all defined type (for debugging)
const CanonicalForm CFMap CFMap & N
CanonicalForm map(const CanonicalForm &primElem, const Variable &alpha, const CanonicalForm &F, const Variable &beta)
map from to such that is mapped onto
int ipower(int b, int m)
int ipower ( int b, int m )
poly singclap_pmod(poly f, poly g, const ring r)
ideal singclap_factorize(poly f, intvec **v, int with_exps, const ring r)
poly singclap_pdivide(poly f, poly g, const ring r)
BOOLEAN singclap_extgcd(poly f, poly g, poly &res, poly &pa, poly &pb, const ring r)
number singclap_det_bi(bigintmat *m, const coeffs cf)
int singclap_det_i(intvec *m, const ring)
ideal singclap_sqrfree(poly f, intvec **v, int with_exps, const ring r)
int compare(const bigintmat *op) const
intvec * delete_pos(int p)
void show(int mat=0, int spaces=0) const
int compare(const intvec *o) const
Class used for (list of) interpreter objects.
void CleanUp(ring r=currRing)
void Clean(ring r=currRing)
INLINE_THIS void Init(int l=0)
Coefficient rings, fields and other domains suitable for Singular polynomials.
static FORCE_INLINE int n_ParDeg(number n, const coeffs r)
static FORCE_INLINE number n_Mult(number a, number b, const coeffs r)
return the product of 'a' and 'b', i.e., a*b
static FORCE_INLINE number n_Param(const int iParameter, const coeffs r)
return the (iParameter^th) parameter as a NEW number NOTE: parameter numbering: 1....
static FORCE_INLINE long n_Int(number &n, const coeffs r)
conversion of n to an int; 0 if not possible in Z/pZ: the representing int lying in (-p/2 ....
static FORCE_INLINE char * nCoeffString(const coeffs cf)
TODO: make it a virtual method of coeffs, together with: Decompose & Compose, rParameter & rPar.
static FORCE_INLINE number n_Add(number a, number b, const coeffs r)
return the sum of 'a' and 'b', i.e., a+b
static FORCE_INLINE number n_GetDenom(number &n, const coeffs r)
return the denominator of n (if elements of r are by nature not fractional, result is 1)
static FORCE_INLINE BOOLEAN nCoeff_is_Extension(const coeffs r)
static FORCE_INLINE number n_Random(siRandProc p, number p1, number p2, const coeffs cf)
static FORCE_INLINE char * nCoeffName(const coeffs cf)
@ n_algExt
used for all algebraic extensions, i.e., the top-most extension in an extension tower is algebraic
static FORCE_INLINE number n_Gcd(number a, number b, const coeffs r)
in Z: return the gcd of 'a' and 'b' in Z/nZ, Z/2^kZ: computed as in the case Z in Z/pZ,...
static FORCE_INLINE BOOLEAN n_IsUnit(number n, const coeffs r)
TRUE iff n has a multiplicative inverse in the given coeff field/ring r.
static FORCE_INLINE BOOLEAN n_GreaterZero(number n, const coeffs r)
ordered fields: TRUE iff 'n' is positive; in Z/pZ: TRUE iff 0 < m <= roundedBelow(p/2),...
static FORCE_INLINE nMapFunc n_SetMap(const coeffs src, const coeffs dst)
set the mapping function pointers for translating numbers from src to dst
static FORCE_INLINE number n_InpNeg(number n, const coeffs r)
in-place negation of n MUST BE USED: n = n_InpNeg(n) (no copy is returned)
static FORCE_INLINE void n_Power(number a, int b, number *res, const coeffs r)
fill res with the power a^b
static FORCE_INLINE number n_Farey(number a, number b, const coeffs r)
static FORCE_INLINE number n_Div(number a, number b, const coeffs r)
return the quotient of 'a' and 'b', i.e., a/b; raises an error if 'b' is not invertible in r exceptio...
static FORCE_INLINE number n_RePart(number i, const coeffs cf)
static FORCE_INLINE BOOLEAN n_IsZero(number n, const coeffs r)
TRUE iff 'n' represents the zero element.
static FORCE_INLINE int n_Size(number n, const coeffs r)
return a non-negative measure for the complexity of n; return 0 only when n represents zero; (used fo...
static FORCE_INLINE number n_Sub(number a, number b, const coeffs r)
return the difference of 'a' and 'b', i.e., a-b
static FORCE_INLINE number n_ChineseRemainderSym(number *a, number *b, int rl, BOOLEAN sym, CFArray &inv_cache, const coeffs r)
static FORCE_INLINE void n_Delete(number *p, const coeffs r)
delete 'p'
static FORCE_INLINE number n_ExtGcd(number a, number b, number *s, number *t, const coeffs r)
beware that ExtGCD is only relevant for a few chosen coeff. domains and may perform something unexpec...
static FORCE_INLINE number n_Init(long i, const coeffs r)
a number representing i in the given coeff field/ring r
static FORCE_INLINE number n_IntMod(number a, number b, const coeffs r)
for r a field, return n_Init(0,r) always: n_Div(a,b,r)*b+n_IntMod(a,b,r)==a n_IntMod(a,...
static FORCE_INLINE BOOLEAN n_DivBy(number a, number b, const coeffs r)
test whether 'a' is divisible 'b'; for r encoding a field: TRUE iff 'b' does not represent zero in Z:...
static FORCE_INLINE BOOLEAN n_Equal(number a, number b, const coeffs r)
TRUE iff 'a' and 'b' represent the same number; they may have different representations.
static FORCE_INLINE number n_GetNumerator(number &n, const coeffs r)
return the numerator of n (if elements of r are by nature not fractional, result is n)
static FORCE_INLINE number n_SubringGcd(number a, number b, const coeffs r)
static FORCE_INLINE number n_ImPart(number i, const coeffs cf)
number(* nMapFunc)(number a, const coeffs src, const coeffs dst)
maps "a", which lives in src, into dst
static FORCE_INLINE void n_Normalize(number &n, const coeffs r)
inplace-normalization of n; produces some canonical representation of n;
static FORCE_INLINE BOOLEAN nCoeff_is_transExt(const coeffs r)
TRUE iff r represents a transcendental extension field.
BOOLEAN pa(leftv res, leftv args)
BOOLEAN pb(leftv res, leftv args)
const CanonicalForm int s
const Variable & v
< [in] a sqrfree bivariate poly
VAR void(* WerrorS_callback)(const char *s)
void WerrorS(const char *s)
FILE * feFopen(const char *path, const char *mode, char *where, short useWerror, short path_only)
VAR char my_yylinebuf[80]
void monitor(void *F, int mode)
void newBuffer(char *s, feBufferTypes t, procinfo *pi, int lineno)
int iiTestConvert(int inputType, int outputType)
const char * iiTwoOps(int t)
VAR BOOLEAN yyInRingConstruction
int scMult0Int(ideal S, ideal Q, const ring tailRing)
ideal scKBase(int deg, ideal s, ideal Q, intvec *mv)
intvec * scIndIntvec(ideal S, ideal Q)
int scMultInt(ideal S, ideal Q)
void scDegree(ideal S, intvec *modulweight, ideal Q)
int scDimInt(ideal S, ideal Q)
void hLookSeries(ideal S, intvec *modulweight, ideal Q, intvec *wdegree, ring tailRing)
intvec * hSecondSeries(intvec *hseries1)
intvec * hFirstSeries(ideal S, intvec *modulweight, ideal Q, intvec *wdegree, ring tailRing)
GbVariant syGetAlgorithm(char *n, const ring r, const ideal)
matrix idCoeffOfKBase(ideal arg, ideal kbase, poly how)
ideal idSyzygies(ideal h1, tHomog h, intvec **w, BOOLEAN setSyzComp, BOOLEAN setRegularity, int *deg, GbVariant alg)
matrix idDiff(matrix i, int k)
ideal idLiftStd(ideal h1, matrix *ma, tHomog hi, ideal *syz, GbVariant alg)
BOOLEAN idTestHomModule(ideal m, ideal Q, intvec *w)
ideal idQuot(ideal h1, ideal h2, BOOLEAN h1IsStb, BOOLEAN resultIsIdeal)
ideal idSeries(int n, ideal M, matrix U, intvec *w)
matrix idDiffOp(ideal I, ideal J, BOOLEAN multiply)
ideal idElimination(ideal h1, poly delVar, intvec *hilb, GbVariant alg)
ideal idMinBase(ideal h1)
ideal idSect(ideal h1, ideal h2, GbVariant alg)
ideal idMultSect(resolvente arg, int length, GbVariant alg)
ideal idLift(ideal mod, ideal submod, ideal *rest, BOOLEAN goodShape, BOOLEAN isSB, BOOLEAN divide, matrix *unit, GbVariant alg)
ideal id_Farey(ideal x, number N, const ring r)
void idLiftW(ideal P, ideal Q, int n, matrix &T, ideal &R, short *w)
ideal idMinEmbedding(ideal arg, BOOLEAN inPlace, intvec **w)
ideal idModulo(ideal h2, ideal h1, tHomog hom, intvec **w)
#define idDelete(H)
delete an ideal
#define idSimpleAdd(A, B)
BOOLEAN idInsertPoly(ideal h1, poly h2)
insert h2 into h1 (if h2 is not the zero polynomial) return TRUE iff h2 was indeed inserted
ideal id_Copy(ideal h1, const ring r)
copy an ideal
static BOOLEAN idIsZeroDim(ideal i)
static BOOLEAN idHomModule(ideal m, ideal Q, intvec **w)
static intvec * idSort(ideal id, BOOLEAN nolex=TRUE)
static BOOLEAN idHomIdeal(ideal id, ideal Q=NULL)
static ideal idMult(ideal h1, ideal h2)
hh := h1 * h2
ideal idAdd(ideal h1, ideal h2)
h1 + h2
#define idMaxIdeal(D)
initialise the maximal ideal (at 0)
#define idPosConstant(I)
index of generator with leading term in ground ring (if any); otherwise -1
ideal interpolation(const std::vector< ideal > &L, intvec *v)
static BOOLEAN length(leftv result, leftv arg)
intvec * ivSub(intvec *a, intvec *b)
intvec * ivTranp(intvec *o)
intvec * ivMult(intvec *a, intvec *b)
intvec * ivAdd(intvec *a, intvec *b)
#define IMATELEM(M, I, J)
intvec * ivCopy(const intvec *o)
static BOOLEAN jjUMINUS_MA(leftv res, leftv u)
static BOOLEAN jjOP_BIM_I(leftv res, leftv u, leftv v)
static BOOLEAN jjRANK1(leftv res, leftv v)
static BOOLEAN jjINDEX_V_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjIMPART(leftv res, leftv v)
static BOOLEAN jjIm2Iv(leftv res, leftv v)
static BOOLEAN jjQUOT(leftv res, leftv u, leftv v)
static BOOLEAN jjUMINUS_IV(leftv res, leftv u)
static BOOLEAN jjOPPOSITE(leftv res, leftv a)
static int _gentable_sort_cmds(const void *a, const void *b)
compares to entry of cmdsname-list
BOOLEAN jjWAITALL1(leftv res, leftv u)
static BOOLEAN jjRESTART(leftv, leftv u)
static BOOLEAN jjidHead(leftv res, leftv v)
static BOOLEAN jjHILBERT(leftv, leftv v)
static BOOLEAN jjTIMES_MA_P1(leftv res, leftv u, leftv v)
static BOOLEAN jjLEADMONOM(leftv res, leftv v)
static BOOLEAN jjOP_IV_I(leftv res, leftv u, leftv v)
static BOOLEAN jjstrlen(leftv res, leftv v)
static BOOLEAN jjBRACK_Bim(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjEXTGCD_P(leftv res, leftv u, leftv v)
static BOOLEAN jjDET_BI(leftv res, leftv v)
BOOLEAN jjWAIT1ST1(leftv res, leftv u)
BOOLEAN jjLOAD(const char *s, BOOLEAN autoexport)
load lib/module given in v
static BOOLEAN jjMATRIX_Mo(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjP2I(leftv res, leftv v)
static BOOLEAN jjIS_RINGVAR_P(leftv res, leftv v)
static BOOLEAN jjDOTDOT(leftv res, leftv u, leftv v)
static BOOLEAN jjFWALK3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjREPART(leftv res, leftv v)
static BOOLEAN jjTIMES_MA_BI2(leftv res, leftv u, leftv v)
static BOOLEAN jjMAP(leftv res, leftv u, leftv v)
static BOOLEAN jjGT_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjN2BI(leftv res, leftv v)
static BOOLEAN jjCHAR(leftv res, leftv v)
static BOOLEAN jjOP_I_IM(leftv res, leftv u, leftv v)
static BOOLEAN jjBRACK_Ma_IV_I(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjROWS_IV(leftv res, leftv v)
static BOOLEAN jjLIFTSTD(leftv res, leftv u, leftv v)
static BOOLEAN jjNULL(leftv, leftv)
static BOOLEAN jjNEWSTRUCT2(leftv, leftv u, leftv v)
static BOOLEAN jjMONITOR2(leftv res, leftv u, leftv v)
static BOOLEAN jjDIM(leftv res, leftv v)
static BOOLEAN jjCOUNT_BIM(leftv res, leftv v)
static BOOLEAN jjBRACKET(leftv res, leftv a, leftv b)
static BOOLEAN jjCOLS_IV(leftv res, leftv v)
static BOOLEAN jjNAMES_I(leftv res, leftv v)
static BOOLEAN jjMULT(leftv res, leftv v)
static BOOLEAN jjPARDEG(leftv res, leftv v)
static BOOLEAN jjDENOMINATOR(leftv res, leftv v)
Return the denominator of the input number NOTE: the input number is normalized as a side effect.
static BOOLEAN jjRANDOM(leftv res, leftv u, leftv v)
static BOOLEAN jjIDEAL_Ma(leftv res, leftv v)
static BOOLEAN jjDIVISION(leftv res, leftv u, leftv v)
static BOOLEAN jjOP_I_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjmpTransp(leftv res, leftv v)
static BOOLEAN jjOPTION_PL(leftv res, leftv v)
static BOOLEAN jjEQUAL_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjDET_S(leftv res, leftv v)
static BOOLEAN jjL2R(leftv res, leftv v)
static BOOLEAN jjREDUCE5(leftv res, leftv u)
static BOOLEAN jjrCharStr(leftv res, leftv v)
static BOOLEAN jjSUBST_Id_I(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjMINUS_B_P(leftv res, leftv u, leftv v)
static BOOLEAN jjHILBERT_IV(leftv res, leftv v)
int iiArithFindCmd(const char *szName)
static BOOLEAN jjIDEAL_R(leftv res, leftv v)
static BOOLEAN jjINDEPSET(leftv res, leftv v)
static BOOLEAN jjTYPEOF(leftv res, leftv v)
static BOOLEAN jjLU_SOLVE(leftv res, leftv v)
static BOOLEAN jjFACSTD(leftv res, leftv v)
static BOOLEAN jjMEMORY(leftv res, leftv v)
static BOOLEAN jjidTransp(leftv res, leftv v)
static BOOLEAN jjLIFT(leftv res, leftv u, leftv v)
static BOOLEAN jjUMINUS_BIM(leftv res, leftv u)
static BOOLEAN jjSUBST_Bu(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjTIMES_MA_N2(leftv res, leftv u, leftv v)
static BOOLEAN jjDIM_R(leftv res, leftv v)
BOOLEAN jjSORTLIST(leftv, leftv arg)
static BOOLEAN jjDUMP(leftv, leftv v)
static BOOLEAN jjpMaxComp(leftv res, leftv v)
static BOOLEAN jjREDUCE3_ID(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjELIMIN_HILB(leftv res, leftv u, leftv v, leftv w)
static int jjCOMPARE_ALL(const void *aa, const void *bb)
static BOOLEAN jjNAMEOF(leftv res, leftv v)
static BOOLEAN jjPlural_mat_poly(leftv res, leftv a, leftv b)
static BOOLEAN jjTIMES_SM(leftv res, leftv u, leftv v)
static BOOLEAN jjMOD_BI(leftv res, leftv u, leftv v)
BOOLEAN jjUNIQLIST(leftv, leftv arg)
static BOOLEAN jjTIMES_MA_I2(leftv res, leftv u, leftv v)
static BOOLEAN jjSTATUS2L(leftv res, leftv u, leftv v)
BOOLEAN(* proc3)(leftv, leftv, leftv, leftv)
static BOOLEAN jjGT_I(leftv res, leftv u, leftv v)
static BOOLEAN jjPRIME(leftv res, leftv v)
static BOOLEAN jjPFAC2(leftv res, leftv u, leftv v)
static BOOLEAN jjidVec2Ideal(leftv res, leftv v)
static BOOLEAN jjJACOB_P(leftv res, leftv v)
static BOOLEAN jjSQR_FREE(leftv res, leftv u)
static BOOLEAN jjSTD_HILB_W(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjEQUAL_I(leftv res, leftv u, leftv v)
static BOOLEAN jjTIMES_MA_P2(leftv res, leftv u, leftv v)
static BOOLEAN jjSBA_1(leftv res, leftv v, leftv u)
static BOOLEAN jjCOEFFS3_P(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjCALL1MANY(leftv res, leftv u)
static BOOLEAN jjPLUS_MA(leftv res, leftv u, leftv v)
static BOOLEAN jjWRONG(leftv, leftv)
static BOOLEAN jjMINUS_V(leftv res, leftv u, leftv v)
static BOOLEAN jjINTERRED(leftv res, leftv v)
static BOOLEAN jjJACOB_M(leftv res, leftv a)
static BOOLEAN jjJET_ID_IV(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjTIMES_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjBAREISS(leftv res, leftv v)
static BOOLEAN jjREAD(leftv res, leftv v)
static BOOLEAN jjLT_N(leftv res, leftv u, leftv v)
static BOOLEAN jjMINUS_MA(leftv res, leftv u, leftv v)
static BOOLEAN jjFactModD_M(leftv res, leftv v)
static BOOLEAN jjMATRIX_Id(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjEXTGCD_I(leftv res, leftv u, leftv v)
static BOOLEAN jjIS_RINGVAR_S(leftv res, leftv v)
static BOOLEAN jjDelete_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjLE_N(leftv res, leftv u, leftv v)
static BOOLEAN jjSUBST_P(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjROWS_BIM(leftv res, leftv v)
static BOOLEAN jjCOMPARE_S(leftv res, leftv u, leftv v)
int iiInitArithmetic()
initialisation of arithmetic structured data
static BOOLEAN jjOR_I(leftv res, leftv u, leftv v)
static BOOLEAN jjTIMES_MA_I1(leftv res, leftv u, leftv v)
static BOOLEAN jjBAREISS3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjRESERVED0(leftv, leftv)
static BOOLEAN jjTIMES_MA_N1(leftv res, leftv u, leftv v)
static BOOLEAN jjLIFT_4(leftv res, leftv U)
static BOOLEAN jjSLIM_GB(leftv res, leftv u)
static BOOLEAN jjMSTD(leftv res, leftv v)
static BOOLEAN jjBREAK1(leftv, leftv v)
const char * Tok2Cmdname(int tok)
static BOOLEAN jjJET_ID_M(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjMINUS_BIM(leftv res, leftv u, leftv v)
static BOOLEAN jjnInt(leftv res, leftv u)
static BOOLEAN jjSQR_FREE2(leftv res, leftv u, leftv dummy)
static BOOLEAN jjCOEFFS3_Id(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjREGULARITY(leftv res, leftv v)
static BOOLEAN jjMINUS_N(leftv res, leftv u, leftv v)
static BOOLEAN jjBREAK0(leftv, leftv)
static BOOLEAN jjTRACE_IV(leftv res, leftv v)
BOOLEAN iiExprArith2(leftv res, leftv a, int op, leftv b, BOOLEAN proccall)
static BOOLEAN jjMONOM(leftv res, leftv v)
static BOOLEAN jjSort_Id(leftv res, leftv v)
static BOOLEAN jjCOEF_M(leftv, leftv v)
static BOOLEAN jjidMinBase(leftv res, leftv v)
static BOOLEAN jjDEG_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjRING_2(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjMINUS_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjPREIMAGE_R(leftv res, leftv v)
static BOOLEAN jjHOMOG_P(leftv res, leftv u, leftv v)
static BOOLEAN jjBRACK_Im(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjMATRIX_Ma(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjidMaxIdeal(leftv res, leftv v)
char * iiArithGetCmd(int nPos)
static BOOLEAN jjMINOR_M(leftv res, leftv v)
static BOOLEAN jjCOUNT_BI(leftv res, leftv v)
static BOOLEAN jjPROC3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjCOLS_BIM(leftv res, leftv v)
static BOOLEAN jjREDUCE3_CP(leftv res, leftv u, leftv v, leftv w)
struct sValCmd3 * psValCmd3
static BOOLEAN jjBRACK_Ma_I_IV(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjLE_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjPLUS_B_P(leftv res, leftv u, leftv v)
static BOOLEAN jjPlural_mat_mat(leftv res, leftv a, leftv b)
static BOOLEAN jjIDEAL_Map(leftv res, leftv v)
static BOOLEAN jjPARSTR2(leftv res, leftv u, leftv v)
BOOLEAN(* proc2)(leftv, leftv, leftv)
static BOOLEAN jjKoszul(leftv res, leftv u, leftv v)
static BOOLEAN jjTIMES_N(leftv res, leftv u, leftv v)
static BOOLEAN jjINTERSECT_PL(leftv res, leftv v)
static BOOLEAN jjTIMES_MA(leftv res, leftv u, leftv v)
static BOOLEAN jjTIMES_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjPLUS_I(leftv res, leftv u, leftv v)
static BOOLEAN jjINTERSEC3S(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjRES3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjJET_P_IV(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjREDUCE_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjCOEF(leftv res, leftv u, leftv v)
BOOLEAN iiExprArith3Tab(leftv res, leftv a, int op, const struct sValCmd3 *dA3, int at, const struct sConvertTypes *dConvertTypes)
apply an operation 'op' to arguments a, a->next and a->next->next return TRUE on failure
static BOOLEAN jjOP_REST(leftv res, leftv u, leftv v)
static BOOLEAN jjEXECUTE(leftv, leftv v)
static BOOLEAN jjDEG_M_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjSTATUS3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjLEADEXP(leftv res, leftv v)
static BOOLEAN jjDEG_M(leftv res, leftv u)
static BOOLEAN jjPLUS_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjDIFF_COEF(leftv res, leftv u, leftv v)
int iiArithRemoveCmd(char *szName)
static BOOLEAN jjGE_N(leftv res, leftv u, leftv v)
static BOOLEAN jjEQUAL_SM(leftv res, leftv u, leftv v)
static BOOLEAN jjINTERPOLATION(leftv res, leftv l, leftv v)
static BOOLEAN jjSIMPL_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjRING3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjREDUCE_P(leftv res, leftv u, leftv v)
static BOOLEAN jjDIV_Ma(leftv res, leftv u, leftv v)
static BOOLEAN jjFRES3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjMODULO(leftv res, leftv u, leftv v)
static BOOLEAN jjCOMPARE_IV(leftv res, leftv u, leftv v)
STATIC_VAR int WerrorS_dummy_cnt
static BOOLEAN jjREAD2(leftv res, leftv u, leftv v)
static BOOLEAN jjREDUCE3_P(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjPAR1(leftv res, leftv v)
static BOOLEAN jjnlInt(leftv res, leftv u)
cmdnames * sCmds
array of existing commands
static BOOLEAN jjFAREY_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjPLUS_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjGCD_N(leftv res, leftv u, leftv v)
static BOOLEAN jjELIMIN(leftv res, leftv u, leftv v)
static BOOLEAN jjPLUSPLUS(leftv, leftv u)
static Subexpr jjMakeSub(leftv e)
static BOOLEAN jjCHINREM_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjROWS(leftv res, leftv v)
static BOOLEAN jjJET_ID(leftv res, leftv u, leftv v)
static BOOLEAN iiExprArith2TabIntern(leftv res, leftv a, int op, leftv b, BOOLEAN proccall, const struct sValCmd2 *dA2, int at, int bt, const struct sConvertTypes *dConvertTypes)
int IsCmd(const char *n, int &tok)
static BOOLEAN jjSBA(leftv res, leftv v)
static BOOLEAN jjOP_IM_I(leftv res, leftv u, leftv v)
static BOOLEAN jjJanetBasis(leftv res, leftv v)
static BOOLEAN jjKBASE(leftv res, leftv v)
static BOOLEAN jjTENSOR(leftv res, leftv u, leftv v)
static BOOLEAN jjmpTrace(leftv res, leftv v)
static BOOLEAN jjRING_PL(leftv res, leftv a)
static BOOLEAN jjREDUCE4(leftv res, leftv u)
static BOOLEAN jjFWALK(leftv res, leftv u, leftv v)
static BOOLEAN jjTEST(leftv, leftv v)
static BOOLEAN jjDIFF_ID_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjSYZ_2(leftv res, leftv u, leftv v)
static BOOLEAN jjPRUNE(leftv res, leftv v)
EXTERN_VAR int singclap_factorize_retry
static BOOLEAN jjDIVISION4(leftv res, leftv v)
unsigned nLastIdentifier
valid indentifieres are slot 1..nLastIdentifier
static BOOLEAN jjDEFINED(leftv res, leftv v)
static BOOLEAN jjRING_1(leftv res, leftv u, leftv v)
static BOOLEAN jjVDIM(leftv res, leftv v)
static BOOLEAN jjOP_I_BIM(leftv res, leftv u, leftv v)
static BOOLEAN jjCOUNT_N(leftv res, leftv v)
static BOOLEAN jjHILBERT2(leftv res, leftv u, leftv v)
static BOOLEAN jjFIND2(leftv res, leftv u, leftv v)
static BOOLEAN jjCOEF_Id(leftv res, leftv u, leftv v)
static BOOLEAN jjP2N(leftv res, leftv v)
static BOOLEAN jjE(leftv res, leftv v)
static BOOLEAN jjPOWER_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjTIMES_MA_BI1(leftv res, leftv u, leftv v)
BOOLEAN iiExprArith1(leftv res, leftv a, int op)
static BOOLEAN jjSTD_HILB_WP(leftv res, leftv INPUT)
static BOOLEAN jjLISTRING(leftv res, leftv v)
static BOOLEAN jjCOEFFS2_KB(leftv res, leftv u, leftv v)
static BOOLEAN jjELIMIN_ALG(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjVAR1(leftv res, leftv v)
static BOOLEAN jjLEADCOEF(leftv res, leftv v)
static BOOLEAN jjVARSTR2(leftv res, leftv u, leftv v)
static BOOLEAN jjPLUS_N(leftv res, leftv u, leftv v)
static BOOLEAN jjSUBST_Id_X(leftv res, leftv u, leftv v, leftv w, int input_type)
static BOOLEAN jjUMINUS_BI(leftv res, leftv u)
int iiArithAddCmd(const char *szName, short nAlias, short nTokval, short nToktype, short nPos=-1)
static BOOLEAN jjpLength(leftv res, leftv v)
static BOOLEAN jjJET_P_P(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjLT_I(leftv res, leftv u, leftv v)
static BOOLEAN jjIS_RINGVAR0(leftv res, leftv)
static BOOLEAN jjEXTGCD_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjBI2P(leftv res, leftv u)
static BOOLEAN jjTWOSTD(leftv res, leftv a)
static BOOLEAN jjGCD_I(leftv res, leftv u, leftv v)
static BOOLEAN jjCONTRACT(leftv res, leftv u, leftv v)
static BOOLEAN jjFAC_P(leftv res, leftv u)
static BOOLEAN jjREDUCE3_CID(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjFAREY_LI(leftv res, leftv u, leftv v)
static BOOLEAN jjTRANSP_BIM(leftv res, leftv v)
static BOOLEAN jjCOUNT_RES(leftv res, leftv v)
static BOOLEAN jjDelete_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjGE_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjrOrdStr(leftv res, leftv v)
static BOOLEAN jjKERNEL(leftv res, leftv u, leftv v)
static BOOLEAN jjINTERSECT3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjBRACK_Ma(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjMOD_N(leftv res, leftv u, leftv v)
static BOOLEAN jjLOAD_E(leftv, leftv v, leftv u)
static BOOLEAN jjNEWSTRUCT3(leftv, leftv u, leftv v, leftv w)
static BOOLEAN jjHOMOG_P_W(leftv res, leftv u, leftv v, leftv)
static BOOLEAN jjpHead(leftv res, leftv v)
static BOOLEAN jjSUBST_Id(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjEQUAL_R(leftv res, leftv u, leftv v)
static BOOLEAN jjCOUNT_L(leftv res, leftv v)
struct sValCmdM * psValCmdM
static BOOLEAN jjDET_I(leftv res, leftv v)
static BOOLEAN jjCOUNT_RG(leftv res, leftv v)
static BOOLEAN jjSMATRIX_Mo(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjINTERSECT(leftv res, leftv u, leftv v)
static BOOLEAN jjrVarStr(leftv res, leftv v)
static BOOLEAN jjOP_BI_BIM(leftv res, leftv u, leftv v)
static BOOLEAN jjDIFF_P(leftv res, leftv u, leftv v)
static BOOLEAN check_valid(const int p, const int op)
static BOOLEAN jjSTRING_PL(leftv res, leftv v)
static BOOLEAN jjMINUS_B(leftv res, leftv u, leftv v)
static BOOLEAN jjLIFTSTD_4(leftv res, leftv U)
static BOOLEAN jjRSUM(leftv res, leftv u, leftv v)
static BOOLEAN jjINDEX_I(leftv res, leftv u, leftv v)
static BOOLEAN jjPOWER_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjMONITOR1(leftv res, leftv v)
static BOOLEAN jjKLAMMER_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjFETCH(leftv res, leftv u, leftv v)
static BOOLEAN jjCALL3ARG(leftv res, leftv u)
static BOOLEAN jjSTD_1(leftv res, leftv u, leftv v)
static BOOLEAN jjUMINUS_N(leftv res, leftv u)
static BOOLEAN jjNUMERATOR(leftv res, leftv v)
Return the numerator of the input number NOTE: the input number is normalized as a side effect.
static BOOLEAN jjORD(leftv res, leftv v)
static BOOLEAN jjTIMES_P(leftv res, leftv u, leftv v)
static BOOLEAN jjUMINUS_I(leftv res, leftv u)
static BOOLEAN jjPREIMAGE(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjBRACK_Ma_IV_IV(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjPLUS_SM(leftv res, leftv u, leftv v)
BOOLEAN jjLOAD_TRY(const char *s)
static BOOLEAN jjLIFT3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjENVELOPE(leftv res, leftv a)
static BOOLEAN jjSetRing(leftv, leftv u)
static BOOLEAN jjMINUS_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjTIMES_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjFACSTD2(leftv res, leftv v, leftv w)
static BOOLEAN jjINTVEC_PL(leftv res, leftv v)
STATIC_VAR SArithBase sArithBase
Base entry for arithmetic.
static BOOLEAN jjEXPORTTO(leftv, leftv u, leftv v)
static BOOLEAN jjPlural_num_poly(leftv res, leftv a, leftv b)
static BOOLEAN jjDIV_P(leftv res, leftv u, leftv v)
static BOOLEAN jjKBASE2(leftv res, leftv u, leftv v)
static BOOLEAN jjPOWER_I(leftv res, leftv u, leftv v)
static BOOLEAN jjRES(leftv res, leftv u, leftv v)
static int iin_Int(number &n, coeffs cf)
static BOOLEAN jjPLUS_P_MA(leftv res, leftv u, leftv v)
static BOOLEAN jjMINRES_R(leftv res, leftv v)
static BOOLEAN jjCOLS(leftv res, leftv v)
static BOOLEAN jjPLUS_BIM(leftv res, leftv u, leftv v)
static BOOLEAN jjP2BI(leftv res, leftv v)
static void WerrorS_dummy(const char *)
static BOOLEAN jjGE_I(leftv res, leftv u, leftv v)
static BOOLEAN jjTRANSP_IV(leftv res, leftv v)
static BOOLEAN jjGT_N(leftv res, leftv u, leftv v)
static BOOLEAN jjUNIVARIATE(leftv res, leftv v)
static BOOLEAN jjHOMOG_ID_W(leftv res, leftv u, leftv v, leftv)
static BOOLEAN jjWEDGE(leftv res, leftv u, leftv v)
EXTERN_VAR BOOLEAN expected_parms
static BOOLEAN jjCOMPARE_P(leftv res, leftv u, leftv v)
static BOOLEAN jjFIND3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjLU_INVERSE(leftv res, leftv v)
static BOOLEAN jjBAREISS_BIM(leftv res, leftv v)
static BOOLEAN jjPLUS_MA_P(leftv res, leftv u, leftv v)
static BOOLEAN jjSIMPL_P(leftv res, leftv u, leftv v)
static BOOLEAN jjPFAC1(leftv res, leftv v)
static BOOLEAN jjQRDS(leftv res, leftv INPUT)
static BOOLEAN jjELIMIN_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjCONTENT(leftv res, leftv v)
static BOOLEAN jjDIFF_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjSTD(leftv res, leftv v)
static BOOLEAN jjTIMES_BIM(leftv res, leftv u, leftv v)
static BOOLEAN jjLIFTSTD3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjTIMES_I(leftv res, leftv u, leftv v)
static BOOLEAN jjDIV_N(leftv res, leftv u, leftv v)
static BOOLEAN jjINTMAT3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjCOUNT_IV(leftv res, leftv v)
static BOOLEAN jjFRES(leftv res, leftv u, leftv v)
unsigned nCmdAllocated
number of commands-slots allocated
static BOOLEAN jjDUMMY(leftv res, leftv u)
static BOOLEAN jjKLAMMER(leftv res, leftv u, leftv v)
BOOLEAN iiExprArith2Tab(leftv res, leftv a, int op, const struct sValCmd2 *dA2, int at, const struct sConvertTypes *dConvertTypes)
apply an operation 'op' to arguments a and a->next return TRUE on failure
static BOOLEAN jjBI2N(leftv res, leftv u)
static BOOLEAN jjRIGHTSTD(leftv res, leftv v)
BOOLEAN iiExprArithM(leftv res, leftv a, int op)
static BOOLEAN jjCOMPARE_MA(leftv res, leftv u, leftv v)
BOOLEAN iiExprArith3(leftv res, int op, leftv a, leftv b, leftv c)
static BOOLEAN jjGETDUMP(leftv, leftv v)
static BOOLEAN jjidFreeModule(leftv res, leftv v)
static BOOLEAN jjFAREY_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjBRACKET_REC(leftv res, leftv a, leftv b, leftv c)
static BOOLEAN jjCOMPARE_IV_I(leftv res, leftv u, leftv v)
static BOOLEAN jjRANDOM_Im(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjRESERVEDNAME(leftv res, leftv v)
struct sValCmd1 * psValCmd1
static BOOLEAN jjDIVMOD_I(leftv res, leftv u, leftv v)
static BOOLEAN jjLE_I(leftv res, leftv u, leftv v)
static BOOLEAN jjTENSOR_Ma(leftv res, leftv u, leftv v)
static BOOLEAN jjCOEFFS3_KB(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN iiExprArith3TabIntern(leftv res, int op, leftv a, leftv b, leftv c, const struct sValCmd3 *dA3, int at, int bt, int ct, const struct sConvertTypes *dConvertTypes)
static BOOLEAN jjRMINUS(leftv res, leftv u, leftv v)
BOOLEAN jjPROC(leftv res, leftv u, leftv v)
static BOOLEAN jjPLUS_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjHILBERT3(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjDET2(leftv res, leftv u, leftv v)
static BOOLEAN jjSTD_HILB(leftv res, leftv u, leftv v)
static BOOLEAN jjAND_I(leftv res, leftv u, leftv v)
static BOOLEAN jjINDEX_P_IV(leftv res, leftv u, leftv v)
static BOOLEAN jjRPAR(leftv res, leftv v)
static BOOLEAN jjJanetBasis2(leftv res, leftv u, leftv v)
static BOOLEAN jjLOAD1(leftv, leftv v)
static BOOLEAN jjCOLON(leftv res, leftv u, leftv v)
static BOOLEAN jjRPLUS(leftv res, leftv u, leftv v)
static BOOLEAN jjCOLCOL(leftv res, leftv u, leftv v)
static BOOLEAN jjFAC_P2(leftv res, leftv u, leftv dummy)
static BOOLEAN jjHOMOG_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjrParStr(leftv res, leftv v)
struct sValCmd2 * psValCmd2
static BOOLEAN jjDEG(leftv res, leftv v)
static BOOLEAN jjFETCH_M(leftv res, leftv u)
static BOOLEAN jjINDEX_V(leftv res, leftv u, leftv v)
static BOOLEAN jjRINGLIST(leftv res, leftv v)
static BOOLEAN jjidElem(leftv res, leftv v)
static BOOLEAN jjDIM2(leftv res, leftv v, leftv w)
static BOOLEAN jjOP_BIM_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjGCD_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjBI2IM(leftv res, leftv u)
static BOOLEAN jjRANK2(leftv res, leftv u, leftv v)
static BOOLEAN jjDEGREE(leftv res, leftv v)
static BOOLEAN jjINDEPSET2(leftv res, leftv u, leftv v)
static BOOLEAN jjWAITALL2(leftv res, leftv u, leftv v)
static BOOLEAN jjOpenClose(leftv, leftv v)
static BOOLEAN jjBRACK_S(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjUMINUS_P(leftv res, leftv u)
static BOOLEAN jjMINUS_SM(leftv res, leftv u, leftv v)
static BOOLEAN jjHIGHCORNER_M(leftv res, leftv v)
static BOOLEAN jjNAMES(leftv res, leftv v)
static BOOLEAN jjINDEX_P(leftv res, leftv u, leftv v)
static BOOLEAN jjHIGHCORNER(leftv res, leftv v)
static BOOLEAN jjEQUAL_Ma(leftv res, leftv u, leftv v)
static BOOLEAN jjNAMES0(leftv res, leftv)
static BOOLEAN jjLOAD2(leftv, leftv, leftv v)
static BOOLEAN jjALIGN_M(leftv res, leftv u, leftv v)
static BOOLEAN jjWAIT1ST2(leftv res, leftv u, leftv v)
static BOOLEAN jjDIV_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjCOMPARE_BIM(leftv res, leftv u, leftv v)
static BOOLEAN jjEQUAL_N(leftv res, leftv u, leftv v)
static BOOLEAN jjDET2_S(leftv res, leftv u, leftv v)
static BOOLEAN jjCOEFFS_Id(leftv res, leftv u, leftv v)
STATIC_VAR si_char_2 Tok2Cmdname_buf
static BOOLEAN jjPROC1(leftv res, leftv u)
static BOOLEAN jjNOT(leftv res, leftv v)
static BOOLEAN jjPARSTR1(leftv res, leftv v)
static BOOLEAN jjSUBST_Id_N(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjJET4(leftv res, leftv u)
static BOOLEAN jjOPPOSE(leftv res, leftv a, leftv b)
static BOOLEAN jjMOD_P(leftv res, leftv u, leftv v)
BOOLEAN iiExprArith1Tab(leftv res, leftv a, int op, const struct sValCmd1 *dA1, int at, const struct sConvertTypes *dConvertTypes)
apply an operation 'op' to an argument a return TRUE on failure
static BOOLEAN jjPLUS_B(leftv res, leftv u, leftv v)
static BOOLEAN jjGCD_P(leftv res, leftv u, leftv v)
static BOOLEAN jjHOMOG1(leftv res, leftv v)
static BOOLEAN jjDET(leftv res, leftv v)
static void jjEQUAL_REST(leftv res, leftv u, leftv v)
static BOOLEAN jjCOUNT_M(leftv res, leftv v)
static BOOLEAN jjPLUS_V(leftv res, leftv u, leftv v)
static BOOLEAN jjKoszul_Id(leftv res, leftv u, leftv v)
static BOOLEAN jjKLAMMER_rest(leftv res, leftv u, leftv v)
static BOOLEAN jjCHINREM_ID(leftv res, leftv u, leftv v)
static BOOLEAN jjPLUS_S(leftv res, leftv u, leftv v)
static BOOLEAN jjHOMOG1_W(leftv res, leftv v, leftv u)
static BOOLEAN jjSBA_2(leftv res, leftv v, leftv u, leftv t)
static BOOLEAN jjINDEX_IV(leftv res, leftv u, leftv v)
unsigned nCmdUsed
number of commands used
static BOOLEAN jjRING_LIST(leftv res, leftv v)
static BOOLEAN jjBRACK_SM(leftv res, leftv u, leftv v, leftv w)
static BOOLEAN jjSUBST_Test(leftv v, leftv w, int &ringvar, poly &monomexpr)
static BOOLEAN jjMINUS_I(leftv res, leftv u, leftv v)
static BOOLEAN jjJET_P(leftv res, leftv u, leftv v)
static BOOLEAN jjVARSTR1(leftv res, leftv v)
static BOOLEAN jjSTATUS_M(leftv res, leftv v)
static BOOLEAN jjCALL1ARG(leftv res, leftv v)
static BOOLEAN jjLT_BI(leftv res, leftv u, leftv v)
static BOOLEAN jjPOWER_P(leftv res, leftv u, leftv v)
BOOLEAN jjLIST_PL(leftv res, leftv v)
static BOOLEAN jjPLUSMINUS_Gen(leftv res, leftv u, leftv v)
static BOOLEAN jjCALL2ARG(leftv res, leftv u)
static BOOLEAN jjINDEX_PBu(leftv res, leftv u, leftv v)
static int iiTabIndex(const jjValCmdTab dArithTab, const int len, const int op)
static BOOLEAN jjSYZYGY(leftv res, leftv v)
static BOOLEAN jjPOWER_N(leftv res, leftv u, leftv v)
static BOOLEAN jjKLAMMER_PL(leftv res, leftv u)
static BOOLEAN jjSUBST_M(leftv res, leftv u)
static BOOLEAN jjEQUAL_P(leftv res, leftv u, leftv v)
static BOOLEAN jjLU_DECOMP(leftv res, leftv v)
static BOOLEAN jjPlural_num_mat(leftv res, leftv a, leftv b)
static BOOLEAN jjIDEAL_PL(leftv res, leftv v)
static BOOLEAN jjNVARS(leftv res, leftv v)
static BOOLEAN jjERROR(leftv, leftv u)
static BOOLEAN jjSTATUS2(leftv res, leftv u, leftv v)
static BOOLEAN jjALIGN_V(leftv res, leftv u, leftv v)
static BOOLEAN jjRINGLIST_C(leftv res, leftv v)
BOOLEAN iiConvert(int inputType, int outputType, int index, leftv input, leftv output, const struct sConvertTypes *dConvertTypes)
const struct sConvertTypes dConvertTypes[]
VAR omBin sip_command_bin
lists ipNameListLev(idhdl root, int lev)
idhdl enterid(const char *s, int lev, int t, idhdl *root, BOOLEAN init, BOOLEAN search)
lists ipNameList(idhdl root)
EXTERN_VAR omBin sleftv_bin
BOOLEAN load_builtin(const char *newlib, BOOLEAN autoexport, SModulFunc_t init)
int(* SModulFunc_t)(SModulFunctions *)
BOOLEAN iiLoadLIB(FILE *fp, const char *libnamebuf, const char *newlib, idhdl pl, BOOLEAN autoexport, BOOLEAN tellerror)
char * iiConvName(const char *libname)
BOOLEAN iiGetLibStatus(const char *lib)
BOOLEAN iiTryLoadLib(leftv v, const char *id)
BOOLEAN load_modules(const char *newlib, char *fullname, BOOLEAN autoexport)
INST_VAR sleftv iiRETURNEXPR
BOOLEAN iiMake_proc(idhdl pn, package pack, leftv sl)
SModulFunc_t iiGetBuiltinModInit(const char *libname)
lists rDecompose(const ring r)
lists rDecompose_list_cf(const ring r)
BOOLEAN iiCheckTypes(leftv args, const short *type_list, int report)
check a list of arguemys against a given field of types return TRUE if the types match return FALSE (...
ring rInit(leftv pn, leftv rv, leftv ord)
leftv iiMap(map theMap, const char *what)
int iiRegularity(lists L)
BOOLEAN rDecompose_CF(leftv res, const coeffs C)
void iiMakeResolv(resolvente r, int length, int rlen, char *name, int typ0, intvec **weights)
int exprlist_length(leftv v)
BOOLEAN mpKoszul(leftv res, leftv c, leftv b, leftv id)
poly iiHighCorner(ideal I, int ak)
lists scIndIndset(ideal S, BOOLEAN all, ideal Q)
idhdl rFindHdl(ring r, idhdl n)
syStrategy syConvList(lists li)
ring rCompose(const lists L, const BOOLEAN check_comp, const long bitmask, const int isLetterplace)
const char * lastreserved
lists syConvRes(syStrategy syzstr, BOOLEAN toDel, int add_row_shift)
BOOLEAN iiExport(leftv v, int toLev)
const struct sValCmd1 dArith1[]
const struct sValCmd2 dArith2[]
BOOLEAN setOption(leftv res, leftv v)
BOOLEAN(* proc1)(leftv, leftv)
const struct sValCmdM dArithM[]
const struct sValCmd3 dArith3[]
ideal kMin_std(ideal F, ideal Q, tHomog h, intvec **w, ideal &M, intvec *hilb, int syzComp, int reduced)
ideal kInterRed(ideal F, ideal Q)
long kHomModDeg(poly p, ring r)
poly kNF(ideal F, ideal Q, poly p, int syzComp, int lazyReduce)
ideal kSba(ideal F, ideal Q, tHomog h, intvec **w, int sbaOrder, int arri, intvec *hilb, int syzComp, int newIdeal, intvec *vw)
ideal kStd(ideal F, ideal Q, tHomog h, intvec **w, intvec *hilb, int syzComp, int newIdeal, intvec *vw, s_poly_proc_t sp)
ideal rightgb(ideal F, ideal Q)
poly redNF(poly h, int &max_ind, int nonorm, kStrategy strat)
ideal_list kStdfac(ideal F, ideal Q, tHomog h, intvec **w, ideal D)
VAR char libnamebuf[1024]
static bool rIsSCA(const ring r)
ideal idOppose(ring Rop_src, ideal I, const ring Rop_dst)
opposes a module I from Rop to currRing(dst)
poly pOppose(ring Rop_src, poly p, const ring Rop_dst)
opposes a vector p from Rop to currRing (dst!)
BOOLEAN rIsLikeOpposite(ring rBase, ring rCandidate)
checks whether rings rBase and rCandidate could be opposite to each other returns TRUE if it is so
BOOLEAN nc_CallPlural(matrix cc, matrix dd, poly cn, poly dn, ring r, bool bSetupQuotient, bool bCopyInput, bool bBeQuiet, ring curr, bool dummy_ring=false)
returns TRUE if there were errors analyze inputs, check them for consistency detects nc_type,...
poly nc_p_Bracket_qq(poly p, const poly q, const ring r)
returns [p,q], destroys p
int luRank(const matrix aMat, const bool isRowEchelon, const ring R)
Computes the rank of a given (m x n)-matrix.
bool luInverseFromLUDecomp(const matrix pMat, const matrix lMat, const matrix uMat, matrix &iMat, const ring R)
This code computes the inverse by inverting lMat and uMat, and then performing two matrix multiplicat...
void henselFactors(const int xIndex, const int yIndex, const poly h, const poly f0, const poly g0, const int d, poly &f, poly &g)
Computes a factorization of a polynomial h(x, y) in K[[x]][y] up to a certain degree in x,...
bool luInverse(const matrix aMat, matrix &iMat, const ring R)
This code first computes the LU-decomposition of aMat, and then calls the method for inverting a matr...
void luDecomp(const matrix aMat, matrix &pMat, matrix &lMat, matrix &uMat, const ring R)
LU-decomposition of a given (m x n)-matrix.
bool luSolveViaLUDecomp(const matrix pMat, const matrix lMat, const matrix uMat, const matrix bVec, matrix &xVec, matrix &H)
Solves the linear system A * x = b, where A is an (m x n)-matrix which is given by its LU-decompositi...
lists qrDoubleShift(const matrix A, const number tol1, const number tol2, const number tol3, const ring r=currRing)
Computes all eigenvalues of a given real quadratic matrix with multiplicites.
BOOLEAN jjANY2LIST(leftv res, leftv v, int cnt)
LINLINE void nlDelete(number *a, const coeffs r)
LINLINE number nlInit(long i, const coeffs r)
void maFindPerm(char const *const *const preim_names, int preim_n, char const *const *const preim_par, int preim_p, char const *const *const names, int n, char const *const *const par, int nop, int *perm, int *par_perm, n_coeffType ch)
void maFindPermLP(char const *const *const preim_names, int preim_n, char const *const *const preim_par, int preim_p, char const *const *const names, int n, char const *const *const par, int nop, int *perm, int *par_perm, n_coeffType ch, int lV)
poly pSubstPoly(poly p, int var, poly image)
ideal idSubstPoly(ideal id, int n, poly e)
BOOLEAN maApplyFetch(int what, map theMap, leftv res, leftv w, ring preimage_r, int *perm, int *par_perm, int P, nMapFunc nMap)
ideal idSubstPar(ideal id, int n, poly e)
poly pSubstPar(poly p, int par, poly image)
BOOLEAN mp_IsDiagUnit(matrix U, const ring R)
matrix mp_Wedge(matrix a, int ar, const ring R)
matrix mp_Transp(matrix a, const ring R)
ideal sm_Tensor(ideal A, ideal B, const ring r)
ideal sm_Add(ideal a, ideal b, const ring R)
matrix mp_CoeffProc(poly f, poly vars, const ring R)
matrix pMultMp(poly p, matrix a, const ring R)
void mp_Monomials(matrix c, int r, int var, matrix m, const ring R)
DetVariant mp_GetAlgorithmDet(matrix m, const ring r)
matrix mp_CoeffProcId(ideal I, poly vars, const ring R)
poly sm_Det(ideal a, const ring r, DetVariant d)
ideal sm_Sub(ideal a, ideal b, const ring R)
ideal sm_Mult(ideal a, ideal b, const ring R)
matrix mp_Sub(matrix a, matrix b, const ring R)
poly mp_Det(matrix a, const ring r, DetVariant d)
matrix mpNew(int r, int c)
create a r x c zero-matrix
int mp_Compare(matrix a, matrix b, const ring R)
BOOLEAN sm_Equal(ideal a, ideal b, const ring R)
matrix mp_Mult(matrix a, matrix b, const ring R)
BOOLEAN mp_Equal(matrix a, matrix b, const ring R)
matrix mp_MultI(matrix a, int f, const ring R)
c = f*a
matrix mp_Coeffs(ideal I, int var, const ring R)
corresponds to Maple's coeffs: var has to be the number of a variable
void mp_Coef2(poly v, poly mon, matrix *c, matrix *m, const ring R)
corresponds to Macauley's coef: the exponent vector of vars has to contain the variables,...
matrix mp_MultP(matrix a, poly p, const ring R)
multiply a matrix 'a' by a poly 'p', destroy the args
matrix mp_Copy(matrix a, const ring r)
copies matrix a (from ring r to r)
matrix mp_Add(matrix a, matrix b, const ring R)
matrix mp_InitP(int r, int c, poly p, const ring R)
make it a p * unit matrix
poly mp_Trace(matrix a, const ring R)
#define MATELEM(mat, i, j)
1-based access to matrix
lists primeFactorisation(const number n, const int pBound)
Factorises a given bigint number n into its prime factors less than or equal to a given bound,...
This file provides miscellaneous functionality.
lib_types type_of_LIB(const char *newlib, char *libnamebuf)
static number & pGetCoeff(poly p)
return an alias to the leading coefficient of p assumes that p != NULL NOTE: not copy
The main handler for Singular numbers which are suitable for Singular polynomials.
ideal twostd(ideal I)
Compute two-sided GB:
void newstruct_setup(const char *n, newstruct_desc d)
newstruct_desc newstructChildFromString(const char *parent, const char *s)
newstruct_desc newstructFromString(const char *s)
CanonicalForm ndConvSingNFactoryN(number, BOOLEAN, const coeffs)
#define nPower(a, b, res)
#define omFreeSize(addr, size)
#define omRealloc(addr, size)
#define omFreeBin(addr, bin)
#define SI_RESTORE_OPT1(A)
#define SI_RESTORE_OPT2(A)
#define TEST_OPT_DEGBOUND
#define TEST_OPT_RETURN_SB
static int index(p_Length length, p_Ord ord)
void pRestoreDegProcs(ring r, pFDegProc old_FDeg, pLDegProc old_lDeg)
poly p_Homogen(poly p, int varnum, const ring r)
void p_Shift(poly *p, int i, const ring r)
shifts components of the vector p by i
void p_Normalize(poly p, const ring r)
int p_Compare(const poly a, const poly b, const ring R)
poly p_Series(int n, poly p, poly u, intvec *w, const ring R)
poly p_Cleardenom(poly p, const ring r)
long p_DegW(poly p, const short *w, const ring R)
poly p_Vec2Poly(poly v, int k, const ring r)
void pSetDegProcs(ring r, pFDegProc new_FDeg, pLDegProc new_lDeg)
static poly p_Neg(poly p, const ring r)
static long p_MinComp(poly p, ring lmRing, ring tailRing)
static void p_Delete(poly *p, const ring r)
static unsigned pLength(poly a)
static long p_Totaldegree(poly p, const ring r)
void rChangeCurrRing(ring r)
poly p_Divide(poly p, poly q, const ring r)
polynomial division a/b, ignoring the rest via singclap_pdivide resp. idLift destroyes a,...
VAR ring currRing
Widely used global variable which specifies the current polynomial ring for Singular interpreter and ...
poly singclap_gcd(poly f, poly g, const ring r)
polynomial gcd via singclap_gcd_r resp. idSyzygies destroys f and g
Compatiblity layer for legacy polynomial operations (over currRing)
static long pTotaldegree(poly p)
#define pHead(p)
returns newly allocated copy of Lm(p), coef is copied, next=NULL, p might be NULL
#define pIsConstant(p)
like above, except that Comp must be 0
#define pGetComp(p)
Component.
#define pSetCoeff(p, n)
deletes old coeff before setting the new one
#define pLmInit(p)
like pInit, except that expvector is initialized to that of p, p must be != NULL
#define pIsUnit(p)
return true if the Lm is a constant <>0
#define pLmDelete(p)
assume p != NULL, deletes Lm(p)->coef and Lm(p)
static void pLmFree(poly p)
frees the space of the monomial m, assumes m != NULL coef is not freed, m is not advanced
#define pSeries(n, p, u, w)
#define pGetExp(p, i)
Exponent.
void pNorm(poly p, const ring R=currRing)
#define pInit()
allocates a new monomial and initializes everything to 0
#define pEqualPolys(p1, p2)
#define pLmCmp(p, q)
returns 0|1|-1 if p=q|p>q|p<q w.r.t monomial ordering
#define pCopy(p)
return a copy of the poly
#define pLmFreeAndNext(p)
assumes p != NULL, deletes p, returns pNext(p)
ideal maGetPreimage(ring theImageRing, map theMap, ideal id, const ring dst_r)
const char feNotImplemented[]
void PrintS(const char *s)
void Werror(const char *fmt,...)
int rSum(ring r1, ring r2, ring &sum)
int r_IsRingVar(const char *n, char **names, int N)
ring rMinusVar(const ring r, char *v)
undo rPlusVar
char * rCharStr(const ring r)
TODO: make it a virtual method of coeffs, together with: Decompose & Compose, rParameter & rPar.
BOOLEAN rSamePolyRep(ring r1, ring r2)
returns TRUE, if r1 and r2 represents the monomials in the same way FALSE, otherwise this is an analo...
void rDelete(ring r)
unconditionally deletes fields in r
ring rDefault(const coeffs cf, int N, char **n, int ord_size, rRingOrder_t *ord, int *block0, int *block1, int **wvhdl, unsigned long bitmask)
ring rPlusVar(const ring r, char *v, int left)
K[x],"y" -> K[x,y] resp. K[y,x].
int n_IsParam(const number m, const ring r)
TODO: rewrite somehow...
static BOOLEAN rField_is_Ring(const ring r)
static BOOLEAN rField_is_Zp_a(const ring r)
static BOOLEAN rField_is_Z(const ring r)
static BOOLEAN rField_is_Zp(const ring r)
static BOOLEAN rIsPluralRing(const ring r)
we must always have this test!
long(* pFDegProc)(poly p, ring r)
static char const ** rParameter(const ring r)
(r->cf->parameter)
static BOOLEAN rField_is_Domain(const ring r)
long(* pLDegProc)(poly p, int *length, ring r)
static int rPar(const ring r)
(r->cf->P)
static BOOLEAN rIsLPRing(const ring r)
static BOOLEAN rField_is_Q(const ring r)
static BOOLEAN rField_is_numeric(const ring r)
BOOLEAN rHasMixedOrdering(const ring r)
static BOOLEAN rField_is_GF(const ring r)
static short rVar(const ring r)
#define rVar(r) (r->N)
BOOLEAN rHasLocalOrMixedOrdering(const ring r)
void sBucket_Add_p(sBucket_pt bucket, poly p, int length)
adds poly p to bucket destroys p!
void sBucketCanonicalize(sBucket_pt bucket)
sBucket_pt sBucketCreate(const ring r)
poly sBucketPeek(sBucket_pt b)
void sBucketDestroyAdd(sBucket_pt bucket, poly *p, int *length)
BOOLEAN sdb_set_breakpoint(const char *pp, int given_lineno)
const char * slStatus(si_link l, const char *request)
BOOLEAN slPrepClose(si_link l)
leftv slRead(si_link l, leftv a)
BOOLEAN slDump(si_link l)
BOOLEAN slGetDump(si_link l)
BOOLEAN slClose(si_link l)
BOOLEAN slOpen(si_link l, short flag, leftv h)
int slStatusSsiL(lists L, int timeout)
#define SI_LINK_SET_CLOSE_P(l)
ideal id_Vec2Ideal(poly vec, const ring R)
ideal idInit(int idsize, int rank)
initialise an ideal / module
void id_Delete(ideal *h, ring r)
deletes an ideal/module/matrix
void id_Norm(ideal id, const ring r)
ideal id = (id[i]), result is leadcoeff(id[i]) = 1
void id_Normalize(ideal I, const ring r)
normialize all polys in id
ideal id_Transp(ideal a, const ring rRing)
transpose a module
ideal id_FreeModule(int i, const ring r)
the free module of rank i
ideal id_Homogen(ideal h, int varnum, const ring r)
ideal id_Power(ideal given, int exp, const ring r)
matrix id_Module2Matrix(ideal mod, const ring R)
int idElem(const ideal F)
count non-zero elements
ideal id_Head(ideal h, const ring r)
returns the ideals of initial terms
long id_RankFreeModule(ideal s, ring lmRing, ring tailRing)
return the maximal component number found in any polynomial in s
void id_DelDiv(ideal id, const ring r)
delete id[j], if LT(j) == coeff*mon*LT(i) and vice versa, i.e., delete id[i], if LT(i) == coeff*mon*L...
void id_DelMultiples(ideal id, const ring r)
ideal id = (id[i]), c any unit if id[i] = c*id[j] then id[j] is deleted for j > i
matrix id_Module2formatedMatrix(ideal mod, int rows, int cols, const ring R)
ideal id_Matrix2Module(matrix mat, const ring R)
converts mat to module, destroys mat
ideal id_ResizeModule(ideal mod, int rows, int cols, const ring R)
ideal id_Delete_Pos(const ideal I, const int p, const ring r)
void id_DelEquals(ideal id, const ring r)
ideal id = (id[i]) if id[i] = id[j] then id[j] is deleted for j > i
ideal id_Jet(const ideal i, int d, const ring R)
void id_DelLmEquals(ideal id, const ring r)
Delete id[j], if Lm(j) == Lm(i) and both LC(j), LC(i) are units and j > i.
ideal id_JetW(const ideal i, int d, intvec *iv, const ring R)
void idSkipZeroes(ideal ide)
gives an ideal/module the minimal possible size
void id_Shift(ideal M, int s, const ring r)
ideal id_ChineseRemainder(ideal *xx, number *q, int rl, const ring r)
ideal id_Subst(ideal id, int n, poly e, const ring r)
void sm_CallBareiss(ideal I, int x, int y, ideal &M, intvec **iv, const ring R)
ideal sm_CallSolv(ideal I, const ring R)
EXTERN_VAR omBin char_ptr_bin
void syMake(leftv v, const char *id, package pa)
INST_VAR sleftv sLastPrinted
BOOLEAN assumeStdFlag(leftv h)
resolvente syResolvente(ideal arg, int maxlength, int *length, intvec ***weights, BOOLEAN minim)
syStrategy syResolution(ideal arg, int maxlength, intvec *w, BOOLEAN minim)
ideal syMinBase(ideal arg)
syStrategy syHilb(ideal arg, int *length)
resolvente sySchreyerResolvente(ideal arg, int maxlength, int *length, BOOLEAN isMonomial=FALSE, BOOLEAN notReplace=FALSE)
syStrategy sySchreyer(ideal arg, int maxlength)
int syDim(syStrategy syzstr)
syStrategy syMinimize(syStrategy syzstr)
syStrategy syKosz(ideal arg, int *length)
int sySize(syStrategy syzstr)
syStrategy syFrank(const ideal arg, const int length, const char *method, const bool use_cache=true, const bool use_tensor_trick=false)
syStrategy syLaScala3(ideal arg, int *length)
ideal t_rep_gb(const ring r, ideal arg_I, int syz_comp, BOOLEAN F4_mode)
number ntDiff(number a, number d, const coeffs cf)
ideal fractalWalkProc(leftv first, leftv second)
ideal walkProc(leftv first, leftv second)
short * iv2array(intvec *iv, const ring R)
BOOLEAN jjStdJanetBasis(leftv res, leftv v, int flag)
flag: 0: JB, 1: SB
#define omPrintBinStats(F)