Annotation of OpenXM_contrib2/asir2000/engine/nd.c, Revision 1.62
1.62 ! noro 1: /* $OpenXM: OpenXM_contrib2/asir2000/engine/nd.c,v 1.61 2003/09/10 05:14:32 noro Exp $ */
1.2 noro 2:
1.1 noro 3: #include "ca.h"
4: #include "inline.h"
5:
6: #if defined(__GNUC__)
7: #define INLINE inline
8: #elif defined(VISUAL)
9: #define INLINE __inline
10: #else
11: #define INLINE
12: #endif
13:
1.61 noro 14: typedef unsigned int UINT;
15:
1.47 noro 16: #define USE_GEOBUCKET 1
1.28 noro 17:
1.1 noro 18: #define REDTAB_LEN 32003
19:
1.40 noro 20: /* GeoBucket for polynomial addition */
21:
1.1 noro 22: typedef struct oPGeoBucket {
23: int m;
24: struct oND *body[32];
25: } *PGeoBucket;
26:
1.40 noro 27: /* distributed polynomial; linked list rep. */
1.1 noro 28: typedef struct oND {
29: struct oNM *body;
30: int nv;
1.31 noro 31: int len;
1.1 noro 32: int sugar;
33: } *ND;
34:
1.40 noro 35: /* distributed polynomial; array rep. */
1.3 noro 36: typedef struct oNDV {
37: struct oNMV *body;
38: int nv;
1.31 noro 39: int len;
1.3 noro 40: int sugar;
41: } *NDV;
42:
1.40 noro 43: /* monomial; linked list rep. */
1.1 noro 44: typedef struct oNM {
45: struct oNM *next;
1.14 noro 46: union {
47: int m;
48: Q z;
1.61 noro 49: P p;
1.14 noro 50: } c;
1.61 noro 51: UINT dl[1];
1.1 noro 52: } *NM;
53:
1.40 noro 54: /* monomial; array rep. */
1.3 noro 55: typedef struct oNMV {
1.14 noro 56: union {
57: int m;
58: Q z;
1.61 noro 59: P p;
1.14 noro 60: } c;
1.61 noro 61: UINT dl[1];
1.3 noro 62: } *NMV;
63:
1.40 noro 64: /* history of reducer */
1.13 noro 65: typedef struct oRHist {
66: struct oRHist *next;
67: int index;
1.34 noro 68: int sugar;
1.61 noro 69: UINT dl[1];
1.13 noro 70: } *RHist;
71:
1.40 noro 72: /* S-pair list */
1.1 noro 73: typedef struct oND_pairs {
74: struct oND_pairs *next;
75: int i1,i2;
1.34 noro 76: int sugar;
1.61 noro 77: UINT lcm[1];
1.1 noro 78: } *ND_pairs;
79:
1.42 noro 80: /* index and shift count for each exponent */
81: typedef struct oEPOS {
82: int i; /* index */
83: int s; /* shift */
84: } *EPOS;
85:
1.43 noro 86: typedef struct oBlockMask {
87: int n;
88: struct order_pair *order_pair;
1.61 noro 89: UINT **mask;
1.43 noro 90: } *BlockMask;
91:
1.45 noro 92: typedef struct oBaseSet {
93: int len;
94: NDV *ps;
1.61 noro 95: UINT **bound;
1.45 noro 96: } *BaseSet;
97:
1.61 noro 98: int (*ndl_compare_function)(UINT *a1,UINT *a2);
1.32 noro 99:
1.42 noro 100: static double nd_scale=2;
1.61 noro 101: static UINT **nd_bound;
1.42 noro 102: static struct order_spec *nd_ord;
103: static EPOS nd_epos;
1.43 noro 104: static BlockMask nd_blockmask;
1.42 noro 105: static int nd_nvar;
106: static int nd_isrlex;
107: static int nd_epw,nd_bpe,nd_wpd,nd_exporigin;
1.61 noro 108: static UINT nd_mask[32];
109: static UINT nd_mask0,nd_mask1;
1.42 noro 110:
111: static NM _nm_free_list;
112: static ND _nd_free_list;
113: static ND_pairs _ndp_free_list;
1.20 noro 114:
115: static NDV *nd_ps;
1.53 noro 116: static NDV *nd_ps_trace;
1.42 noro 117: static RHist *nd_psh;
118: static int nd_psn,nd_pslen;
1.20 noro 119:
1.42 noro 120: static RHist *nd_red;
1.1 noro 121:
1.42 noro 122: static int nd_found,nd_create,nd_notfirst;
123: static int nm_adv;
124: static int nmv_adv;
125: static int nd_dcomp;
1.1 noro 126:
1.61 noro 127: extern VL CO;
1.55 noro 128: extern int Top,Reverse,dp_nelim,do_weyl;
1.58 noro 129: extern int *current_weyl_weight_vector;
1.1 noro 130:
1.40 noro 131: /* fundamental macros */
1.34 noro 132: #define TD(d) (d[0])
1.1 noro 133: #define HDL(d) ((d)->body->dl)
1.34 noro 134: #define HTD(d) (TD(HDL(d)))
1.14 noro 135: #define HCM(d) ((d)->body->c.m)
1.16 noro 136: #define HCQ(d) ((d)->body->c.z)
1.61 noro 137: #define HCP(d) ((d)->body->c.p)
1.14 noro 138: #define CM(a) ((a)->c.m)
1.16 noro 139: #define CQ(a) ((a)->c.z)
1.61 noro 140: #define CP(a) ((a)->c.p)
1.14 noro 141: #define DL(a) ((a)->dl)
142: #define SG(a) ((a)->sugar)
143: #define LEN(a) ((a)->len)
1.33 noro 144: #define LCM(a) ((a)->lcm)
1.42 noro 145: #define GET_EXP(d,a) (((d)[nd_epos[a].i]>>nd_epos[a].s)&nd_mask0)
1.60 noro 146: #define GET_EXP_MASK(d,a,m) ((((d)[nd_epos[a].i]&(m)[nd_epos[a].i])>>nd_epos[a].s)&nd_mask0)
1.42 noro 147: #define PUT_EXP(r,a,e) ((r)[nd_epos[a].i] |= ((e)<<nd_epos[a].s))
1.45 noro 148: #define XOR_EXP(r,a,e) ((r)[nd_epos[a].i] ^= ((e)<<nd_epos[a].s))
1.1 noro 149:
1.61 noro 150: #define GET_EXP_OLD(d,a) (((d)[oepos[a].i]>>oepos[a].s)&omask0)
151: #define PUT_EXP_OLD(r,a,e) ((r)[oepos[a].i] |= ((e)<<oepos[a].s))
152:
1.40 noro 153: /* macros for term comparison */
1.34 noro 154: #define TD_DL_COMPARE(d1,d2)\
1.41 noro 155: (TD(d1)>TD(d2)?1:(TD(d1)<TD(d2)?-1:ndl_lex_compare(d1,d2)))
1.43 noro 156: #if 0
1.34 noro 157: #define DL_COMPARE(d1,d2)\
1.43 noro 158: (nd_dcomp>0?TD_DL_COMPARE(d1,d2)\
159: :(nd_dcomp==0?ndl_lex_compare(d1,d2)\
160: :(nd_blockmask?ndl_block_compare(d1,d2)\
1.45 noro 161: :(*ndl_compare_function)(d1,d2))))
1.43 noro 162: #else
163: #define DL_COMPARE(d1,d2)\
1.45 noro 164: (nd_dcomp>0?TD_DL_COMPARE(d1,d2):(*ndl_compare_function)(d1,d2))
1.43 noro 165: #endif
1.34 noro 166:
1.40 noro 167: /* allocators */
1.15 noro 168: #define NEWRHist(r) \
1.61 noro 169: ((r)=(RHist)MALLOC(sizeof(struct oRHist)+(nd_wpd-1)*sizeof(UINT)))
1.34 noro 170: #define NEWND_pairs(m) \
171: if(!_ndp_free_list)_NDP_alloc();\
172: (m)=_ndp_free_list; _ndp_free_list = NEXT(_ndp_free_list)
173: #define NEWNM(m)\
174: if(!_nm_free_list)_NM_alloc();\
175: (m)=_nm_free_list; _nm_free_list = NEXT(_nm_free_list)
176: #define MKND(n,m,len,d)\
177: if(!_nd_free_list)_ND_alloc();\
178: (d)=_nd_free_list; _nd_free_list = (ND)BDY(_nd_free_list);\
179: NV(d)=(n); LEN(d)=(len); BDY(d)=(m)
1.40 noro 180: #define NEWNDV(d) ((d)=(NDV)MALLOC(sizeof(struct oNDV)))
181: #define MKNDV(n,m,l,d) NEWNDV(d); NV(d)=(n); BDY(d)=(m); LEN(d) = l;
1.1 noro 182:
1.40 noro 183: /* allocate and link a new object */
1.13 noro 184: #define NEXTRHist(r,c) \
185: if(!(r)){NEWRHist(r);(c)=(r);}else{NEWRHist(NEXT(c));(c)=NEXT(c);}
1.1 noro 186: #define NEXTNM(r,c) \
187: if(!(r)){NEWNM(r);(c)=(r);}else{NEWNM(NEXT(c));(c)=NEXT(c);}
188: #define NEXTNM2(r,c,s) \
189: if(!(r)){(c)=(r)=(s);}else{NEXT(c)=(s);(c)=(s);}
1.40 noro 190: #define NEXTND_pairs(r,c) \
191: if(!(r)){NEWND_pairs(r);(c)=(r);}else{NEWND_pairs(NEXT(c));(c)=NEXT(c);}
1.34 noro 192:
1.40 noro 193: /* deallocators */
1.1 noro 194: #define FREENM(m) NEXT(m)=_nm_free_list; _nm_free_list=(m)
195: #define FREENDP(m) NEXT(m)=_ndp_free_list; _ndp_free_list=(m)
196: #define FREEND(m) BDY(m)=(NM)_nd_free_list; _nd_free_list=(m)
197:
1.40 noro 198: /* macro for increasing pointer to NMV */
199: #define NMV_ADV(m) (m = (NMV)(((char *)m)+nmv_adv))
1.61 noro 200: #define NMV_OADV(m) (m = (NMV)(((char *)m)+oadv))
201: #define NDV_NADV(m) (m = (NMV)(((char *)m)+newadv))
1.56 noro 202: #define NMV_PREV(m) (m = (NMV)(((char *)m)-nmv_adv))
1.61 noro 203: #define NMV_OPREV(m) (m = (NMV)(((char *)m)-oadv))
204:
1.40 noro 205:
206: /* external functions */
207: void GC_gcollect();
208: NODE append_one(NODE,int);
1.1 noro 209:
1.40 noro 210: /* manipulation of coefficients */
1.20 noro 211: void nd_removecont(int mod,ND p);
1.21 noro 212: void nd_removecont2(ND p1,ND p2);
1.40 noro 213: void removecont_array(Q *c,int n);
214:
215: /* GeoBucket functions */
1.25 noro 216: ND normalize_pbucket(int mod,PGeoBucket g);
217: int head_pbucket(int mod,PGeoBucket g);
1.26 noro 218: int head_pbucket_q(PGeoBucket g);
1.31 noro 219: void add_pbucket(int mod,PGeoBucket g,ND d);
1.25 noro 220: void free_pbucket(PGeoBucket b);
1.26 noro 221: void mulq_pbucket(PGeoBucket g,Q c);
1.25 noro 222: PGeoBucket create_pbucket();
1.20 noro 223:
1.40 noro 224: /* manipulation of pairs and bases */
1.39 noro 225: int nd_newps(int mod,ND a,ND aq);
1.40 noro 226: ND_pairs nd_newpairs( NODE g, int t );
1.1 noro 227: ND_pairs nd_minp( ND_pairs d, ND_pairs *prest );
228: NODE update_base(NODE nd,int ndp);
1.40 noro 229: ND_pairs update_pairs( ND_pairs d, NODE /* of index */ g, int t);
230: ND_pairs equivalent_pairs( ND_pairs d1, ND_pairs *prest );
231: ND_pairs crit_B( ND_pairs d, int s );
232: ND_pairs crit_M( ND_pairs d1 );
233: ND_pairs crit_F( ND_pairs d1 );
1.1 noro 234: int crit_2( int dp1, int dp2 );
1.40 noro 235:
236: /* top level functions */
237: void nd_gr(LIST f,LIST v,int m,struct order_spec *ord,LIST *rp);
1.52 noro 238: void nd_gr_trace(LIST f,LIST v,int trace,int homo,struct order_spec *ord,LIST *rp);
1.27 noro 239: NODE nd_gb(int m,int checkonly);
1.23 noro 240: NODE nd_gb_trace(int m);
1.40 noro 241:
242: /* ndl functions */
1.61 noro 243: int ndl_weight(UINT *d);
244: void ndl_weight_mask(UINT *d);
245: void ndl_homogenize(UINT *d,UINT *r,int obpe,EPOS oepos,int weight);
246: void ndl_dehomogenize(UINT *p);
247: void ndl_reconstruct(UINT *d,UINT *r,int obpe,EPOS oepos);
248: INLINE int ndl_reducible(UINT *d1,UINT *d2);
249: INLINE int ndl_lex_compare(UINT *d1,UINT *d2);
250: INLINE int ndl_block_compare(UINT *d1,UINT *d2);
251: INLINE int ndl_equal(UINT *d1,UINT *d2);
252: INLINE void ndl_copy(UINT *d1,UINT *d2);
253: INLINE void ndl_zero(UINT *d);
254: INLINE void ndl_add(UINT *d1,UINT *d2,UINT *d);
255: INLINE void ndl_addto(UINT *d1,UINT *d2);
256: INLINE void ndl_sub(UINT *d1,UINT *d2,UINT *d);
257: INLINE int ndl_hash_value(UINT *d);
1.45 noro 258:
259: /* normal forms */
1.40 noro 260: INLINE int nd_find_reducer(ND g);
261: INLINE int nd_find_reducer_direct(ND g,NDV *ps,int len);
1.53 noro 262: int nd_sp(int mod,int trace,ND_pairs p,ND *nf);
263: int nd_nf(int mod,ND g,NDV *ps,int full,ND *nf);
264: int nd_nf_pbucket(int mod,ND g,NDV *ps,int full,ND *nf);
1.45 noro 265: int nd_nf_direct(int mod,ND g,BaseSet base,int full,ND *rp);
1.40 noro 266:
267: /* finalizers */
1.61 noro 268: NODE ndv_reducebase(NODE x);
269: NODE ndv_reduceall(int m,NODE f);
1.40 noro 270:
271: /* allocators */
272: void nd_free_private_storage();
273: void _NM_alloc();
274: void _ND_alloc();
1.1 noro 275: void nd_free(ND p);
1.40 noro 276: void nd_free_redlist();
277:
278: /* printing */
1.61 noro 279: void ndl_print(UINT *dl);
1.1 noro 280: void nd_print(ND p);
1.16 noro 281: void nd_print_q(ND p);
1.1 noro 282: void ndp_print(ND_pairs d);
1.40 noro 283:
284:
285: /* setup, reconstruct */
286: void nd_init_ord(struct order_spec *spec);
287: ND_pairs nd_reconstruct(int mod,int trace,ND_pairs ndp);
288: void nd_reconstruct_direct(int mod,NDV *ps,int len);
1.61 noro 289: void ndv_setup(int mod,int trace,NODE f);
290: void nd_setup_parameters(int nvar,int max);
1.43 noro 291: BlockMask nd_create_blockmask(struct order_spec *ord);
1.57 noro 292: EPOS nd_create_epos(struct order_spec *ord);
1.48 noro 293: int nd_get_exporigin(struct order_spec *ord);
1.61 noro 294: void ndv_mod(int mod,NDV p);
295: NDV ndv_dup(int mod,NDV p);
1.40 noro 296:
297: /* ND functions */
1.61 noro 298: int ndv_check_candidate(NODE input,int obpe,int oadv,EPOS oepos,NODE cand);
1.40 noro 299: void nd_mul_c(int mod,ND p,int mul);
300: void nd_mul_c_q(ND p,Q mul);
1.61 noro 301: void nd_mul_c_p(VL vl,ND p,P mul);
1.40 noro 302: ND nd_remove_head(ND p);
1.1 noro 303: int nd_length(ND p);
1.61 noro 304: void nd_append_red(UINT *d,int i);
305: UINT *ndv_compute_bound(NDV p);
1.6 noro 306: ND nd_copy(ND p);
1.40 noro 307: ND nd_add(int mod,ND p1,ND p2);
308: ND nd_add_q(ND p1,ND p2);
1.41 noro 309: INLINE int nd_length(ND p);
1.4 noro 310:
1.40 noro 311: /* NDV functions */
1.55 noro 312: ND weyl_ndv_mul_nm(int mod,NM m0,NDV p);
313: void weyl_mul_nm_nmv(int n,int mod,NM m0,NMV m1,NM *tab,int tlen);
1.19 noro 314: void ndv_mul_c(int mod,NDV p,int mul);
1.40 noro 315: void ndv_mul_c_q(NDV p,Q mul);
1.61 noro 316: ND ndv_mul_nm(int mod,NM m0,NDV p);
1.43 noro 317: void ndv_realloc(NDV p,int obpe,int oadv,EPOS oepos);
1.61 noro 318: NDV ndv_dup_realloc(NDV p,int obpe,int oadv,EPOS oepos);
319: void ndv_homogenize(NDV p,int obpe,int oadv,EPOS eops);
1.45 noro 320: void ndv_dehomogenize(NDV p,struct order_spec *spec);
1.40 noro 321: void ndv_removecont(int mod,NDV p);
322: void ndv_print(NDV p);
323: void ndv_print_q(NDV p);
324: void ndv_free(NDV p);
325:
326: /* converters */
1.61 noro 327: ND ptond(VL vl,VL dvl,P p);
328: NDV ptondv(VL vl,VL dvl,P p);
329: P ndvtop(int mod,VL vl,VL dvl,NDV p);
1.16 noro 330: NDV ndtondv(int mod,ND p);
1.23 noro 331: ND ndvtond(int mod,NDV p);
1.1 noro 332:
333: void nd_free_private_storage()
334: {
335: _nd_free_list = 0;
336: _nm_free_list = 0;
1.5 noro 337: _ndp_free_list = 0;
1.13 noro 338: bzero(nd_red,sizeof(REDTAB_LEN*sizeof(RHist)));
1.1 noro 339: GC_gcollect();
340: }
341:
342: void _NM_alloc()
343: {
344: NM p;
345: int i;
346:
1.11 noro 347: for ( i = 0; i < 1024; i++ ) {
1.61 noro 348: p = (NM)GC_malloc(sizeof(struct oNM)+(nd_wpd-1)*sizeof(UINT));
1.1 noro 349: p->next = _nm_free_list; _nm_free_list = p;
350: }
351: }
352:
353: void _ND_alloc()
354: {
355: ND p;
356: int i;
357:
358: for ( i = 0; i < 1024; i++ ) {
359: p = (ND)GC_malloc(sizeof(struct oND));
360: p->body = (NM)_nd_free_list; _nd_free_list = p;
361: }
362: }
363:
364: void _NDP_alloc()
365: {
366: ND_pairs p;
367: int i;
368:
1.11 noro 369: for ( i = 0; i < 1024; i++ ) {
1.1 noro 370: p = (ND_pairs)GC_malloc(sizeof(struct oND_pairs)
1.61 noro 371: +(nd_wpd-1)*sizeof(UINT));
1.1 noro 372: p->next = _ndp_free_list; _ndp_free_list = p;
373: }
374: }
375:
1.30 noro 376: INLINE int nd_length(ND p)
1.1 noro 377: {
378: NM m;
379: int i;
380:
381: if ( !p )
382: return 0;
383: else {
384: for ( i = 0, m = BDY(p); m; m = NEXT(m), i++ );
385: return i;
386: }
387: }
388:
1.61 noro 389: INLINE int ndl_reducible(UINT *d1,UINT *d2)
1.1 noro 390: {
1.61 noro 391: UINT u1,u2;
1.1 noro 392: int i,j;
393:
1.34 noro 394: if ( TD(d1) < TD(d2) ) return 0;
1.1 noro 395: switch ( nd_bpe ) {
1.62 ! noro 396: case 3:
! 397: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
! 398: u1 = d1[i]; u2 = d2[i];
! 399: if ( (u1&0x38000000) < (u2&0x38000000) ) return 0;
! 400: if ( (u1& 0x7000000) < (u2& 0x7000000) ) return 0;
! 401: if ( (u1& 0xe00000) < (u2& 0xe00000) ) return 0;
! 402: if ( (u1& 0x1c0000) < (u2& 0x1c0000) ) return 0;
! 403: if ( (u1& 0x38000) < (u2& 0x38000) ) return 0;
! 404: if ( (u1& 0x7000) < (u2& 0x7000) ) return 0;
! 405: if ( (u1& 0xe00) < (u2& 0xe00) ) return 0;
! 406: if ( (u1& 0x1c0) < (u2& 0x1c0) ) return 0;
! 407: if ( (u1& 0x38) < (u2& 0x38) ) return 0;
! 408: if ( (u1& 0x7) < (u2& 0x7) ) return 0;
! 409: }
! 410: return 1;
! 411: break;
1.1 noro 412: case 4:
1.41 noro 413: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 414: u1 = d1[i]; u2 = d2[i];
415: if ( (u1&0xf0000000) < (u2&0xf0000000) ) return 0;
1.62 ! noro 416: if ( (u1& 0xf000000) < (u2& 0xf000000) ) return 0;
! 417: if ( (u1& 0xf00000) < (u2& 0xf00000) ) return 0;
! 418: if ( (u1& 0xf0000) < (u2& 0xf0000) ) return 0;
! 419: if ( (u1& 0xf000) < (u2& 0xf000) ) return 0;
! 420: if ( (u1& 0xf00) < (u2& 0xf00) ) return 0;
! 421: if ( (u1& 0xf0) < (u2& 0xf0) ) return 0;
! 422: if ( (u1& 0xf) < (u2& 0xf) ) return 0;
1.1 noro 423: }
424: return 1;
425: break;
426: case 6:
1.41 noro 427: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 428: u1 = d1[i]; u2 = d2[i];
429: if ( (u1&0x3f000000) < (u2&0x3f000000) ) return 0;
1.62 ! noro 430: if ( (u1& 0xfc0000) < (u2& 0xfc0000) ) return 0;
! 431: if ( (u1& 0x3f000) < (u2& 0x3f000) ) return 0;
! 432: if ( (u1& 0xfc0) < (u2& 0xfc0) ) return 0;
! 433: if ( (u1& 0x3f) < (u2& 0x3f) ) return 0;
1.1 noro 434: }
435: return 1;
436: break;
437: case 8:
1.41 noro 438: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 439: u1 = d1[i]; u2 = d2[i];
440: if ( (u1&0xff000000) < (u2&0xff000000) ) return 0;
1.62 ! noro 441: if ( (u1& 0xff0000) < (u2& 0xff0000) ) return 0;
! 442: if ( (u1& 0xff00) < (u2& 0xff00) ) return 0;
! 443: if ( (u1& 0xff) < (u2& 0xff) ) return 0;
1.1 noro 444: }
445: return 1;
446: break;
447: case 16:
1.41 noro 448: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 449: u1 = d1[i]; u2 = d2[i];
450: if ( (u1&0xffff0000) < (u2&0xffff0000) ) return 0;
1.62 ! noro 451: if ( (u1& 0xffff) < (u2& 0xffff) ) return 0;
1.1 noro 452: }
453: return 1;
454: break;
455: case 32:
1.41 noro 456: for ( i = nd_exporigin; i < nd_wpd; i++ )
1.1 noro 457: if ( d1[i] < d2[i] ) return 0;
458: return 1;
459: break;
460: default:
1.41 noro 461: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 462: u1 = d1[i]; u2 = d2[i];
463: for ( j = 0; j < nd_epw; j++ )
464: if ( (u1&nd_mask[j]) < (u2&nd_mask[j]) ) return 0;
465: }
466: return 1;
467: }
468: }
469:
1.61 noro 470: /*
471: * If the current order is a block order,
472: * then the last block is length 1 and contains
473: * the homo variable. Otherwise, the original
474: * order is either 0 or 2.
475: */
476:
477: void ndl_homogenize(UINT *d,UINT *r,int obpe,EPOS oepos,int weight)
1.23 noro 478: {
1.61 noro 479: int w,i,e,n,omask0;
480:
481: omask0 = (1<<obpe)-1;
482: n = nd_nvar-1;
483: ndl_zero(r);
484: for ( i = 0; i < n; i++ ) {
485: e = GET_EXP_OLD(d,i);
486: PUT_EXP(r,i,e);
487: }
488: w = TD(d);
489: PUT_EXP(r,nd_nvar-1,weight-w);
490: TD(r) = weight;
491: if ( nd_blockmask ) ndl_weight_mask(r);
492: }
493:
494: void ndl_dehomogenize(UINT *d)
495: {
496: UINT mask;
497: UINT h;
1.31 noro 498: int i,bits;
1.23 noro 499:
1.44 noro 500: if ( nd_blockmask ) {
501: h = GET_EXP(d,nd_nvar-1);
1.45 noro 502: XOR_EXP(d,nd_nvar-1,h);
1.44 noro 503: TD(d) -= h;
504: d[nd_exporigin-1] -= h;
505: } else {
506: if ( nd_isrlex ) {
507: if ( nd_bpe == 32 ) {
508: h = d[nd_exporigin];
509: for ( i = nd_exporigin+1; i < nd_wpd; i++ )
510: d[i-1] = d[i];
511: d[i-1] = 0;
512: TD(d) -= h;
513: } else {
514: bits = nd_epw*nd_bpe;
515: mask = bits==32?0xffffffff:((1<<(nd_epw*nd_bpe))-1);
516: h = (d[nd_exporigin]>>((nd_epw-1)*nd_bpe))&nd_mask0;
517: for ( i = nd_exporigin; i < nd_wpd; i++ )
518: d[i] = ((d[i]<<nd_bpe)&mask)
519: |(i+1<nd_wpd?((d[i+1]>>((nd_epw-1)*nd_bpe))&nd_mask0):0);
520: TD(d) -= h;
521: }
1.45 noro 522: } else {
523: h = GET_EXP(d,nd_nvar-1);
524: XOR_EXP(d,nd_nvar-1,h);
525: TD(d) -= h;
526: }
1.44 noro 527: }
1.23 noro 528: }
529:
1.61 noro 530: void ndl_lcm(UINT *d1,unsigned *d2,UINT *d)
1.1 noro 531: {
1.61 noro 532: UINT t1,t2,u,u1,u2;
1.43 noro 533: int i,j,l;
1.1 noro 534:
535: switch ( nd_bpe ) {
1.62 ! noro 536: case 3:
! 537: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
! 538: u1 = d1[i]; u2 = d2[i];
! 539: t1 = (u1&0x38000000); t2 = (u2&0x38000000); u = t1>t2?t1:t2;
! 540: t1 = (u1& 0x7000000); t2 = (u2& 0x7000000); u |= t1>t2?t1:t2;
! 541: t1 = (u1& 0xe00000); t2 = (u2& 0xe00000); u |= t1>t2?t1:t2;
! 542: t1 = (u1& 0x1c0000); t2 = (u2& 0x1c0000); u |= t1>t2?t1:t2;
! 543: t1 = (u1& 0x38000); t2 = (u2& 0x38000); u |= t1>t2?t1:t2;
! 544: t1 = (u1& 0x7000); t2 = (u2& 0x7000); u |= t1>t2?t1:t2;
! 545: t1 = (u1& 0xe00); t2 = (u2& 0xe00); u |= t1>t2?t1:t2;
! 546: t1 = (u1& 0x1c0); t2 = (u2& 0x1c0); u |= t1>t2?t1:t2;
! 547: t1 = (u1& 0x38); t2 = (u2& 0x38); u |= t1>t2?t1:t2;
! 548: t1 = (u1& 0x7); t2 = (u2& 0x7); u |= t1>t2?t1:t2;
! 549: d[i] = u;
! 550: }
! 551: break;
1.1 noro 552: case 4:
1.41 noro 553: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 554: u1 = d1[i]; u2 = d2[i];
555: t1 = (u1&0xf0000000); t2 = (u2&0xf0000000); u = t1>t2?t1:t2;
1.62 ! noro 556: t1 = (u1& 0xf000000); t2 = (u2& 0xf000000); u |= t1>t2?t1:t2;
! 557: t1 = (u1& 0xf00000); t2 = (u2& 0xf00000); u |= t1>t2?t1:t2;
! 558: t1 = (u1& 0xf0000); t2 = (u2& 0xf0000); u |= t1>t2?t1:t2;
! 559: t1 = (u1& 0xf000); t2 = (u2& 0xf000); u |= t1>t2?t1:t2;
! 560: t1 = (u1& 0xf00); t2 = (u2& 0xf00); u |= t1>t2?t1:t2;
! 561: t1 = (u1& 0xf0); t2 = (u2& 0xf0); u |= t1>t2?t1:t2;
! 562: t1 = (u1& 0xf); t2 = (u2& 0xf); u |= t1>t2?t1:t2;
1.1 noro 563: d[i] = u;
564: }
565: break;
566: case 6:
1.41 noro 567: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 568: u1 = d1[i]; u2 = d2[i];
569: t1 = (u1&0x3f000000); t2 = (u2&0x3f000000); u = t1>t2?t1:t2;
1.62 ! noro 570: t1 = (u1& 0xfc0000); t2 = (u2& 0xfc0000); u |= t1>t2?t1:t2;
! 571: t1 = (u1& 0x3f000); t2 = (u2& 0x3f000); u |= t1>t2?t1:t2;
! 572: t1 = (u1& 0xfc0); t2 = (u2& 0xfc0); u |= t1>t2?t1:t2;
! 573: t1 = (u1& 0x3f); t2 = (u2& 0x3f); u |= t1>t2?t1:t2;
1.1 noro 574: d[i] = u;
575: }
576: break;
577: case 8:
1.41 noro 578: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 579: u1 = d1[i]; u2 = d2[i];
580: t1 = (u1&0xff000000); t2 = (u2&0xff000000); u = t1>t2?t1:t2;
1.62 ! noro 581: t1 = (u1& 0xff0000); t2 = (u2& 0xff0000); u |= t1>t2?t1:t2;
! 582: t1 = (u1& 0xff00); t2 = (u2& 0xff00); u |= t1>t2?t1:t2;
! 583: t1 = (u1& 0xff); t2 = (u2& 0xff); u |= t1>t2?t1:t2;
1.1 noro 584: d[i] = u;
585: }
586: break;
587: case 16:
1.41 noro 588: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 589: u1 = d1[i]; u2 = d2[i];
590: t1 = (u1&0xffff0000); t2 = (u2&0xffff0000); u = t1>t2?t1:t2;
1.62 ! noro 591: t1 = (u1& 0xffff); t2 = (u2& 0xffff); u |= t1>t2?t1:t2;
1.1 noro 592: d[i] = u;
593: }
594: break;
595: case 32:
1.41 noro 596: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 597: u1 = d1[i]; u2 = d2[i];
598: d[i] = u1>u2?u1:u2;
599: }
600: break;
601: default:
1.41 noro 602: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 603: u1 = d1[i]; u2 = d2[i];
604: for ( j = 0, u = 0; j < nd_epw; j++ ) {
605: t1 = (u1&nd_mask[j]); t2 = (u2&nd_mask[j]); u |= t1>t2?t1:t2;
606: }
607: d[i] = u;
608: }
609: break;
610: }
1.39 noro 611: TD(d) = ndl_weight(d);
1.61 noro 612: if ( nd_blockmask ) ndl_weight_mask(d);
1.57 noro 613: }
614:
1.61 noro 615: int ndl_weight(UINT *d)
1.1 noro 616: {
1.61 noro 617: UINT t,u;
1.1 noro 618: int i,j;
619:
1.60 noro 620: if ( current_dl_weight_vector )
621: for ( i = 0, t = 0; i < nd_nvar; i++ ) {
622: u = GET_EXP(d,i);
623: t += MUL_WEIGHT(u,i);
624: }
625: else
626: for ( t = 0, i = nd_exporigin; i < nd_wpd; i++ ) {
627: u = d[i];
628: for ( j = 0; j < nd_epw; j++, u>>=nd_bpe )
629: t += (u&nd_mask0);
630: }
1.1 noro 631: return t;
632: }
633:
1.61 noro 634: void ndl_weight_mask(UINT *d)
1.43 noro 635: {
1.61 noro 636: UINT t,u;
637: UINT *mask;
638: int i,j,k,l;
1.43 noro 639:
1.61 noro 640: l = nd_blockmask->n;
641: for ( k = 0; k < l; k++ ) {
642: mask = nd_blockmask->mask[k];
643: if ( current_dl_weight_vector )
644: for ( i = 0, t = 0; i < nd_nvar; i++ ) {
645: u = GET_EXP_MASK(d,i,mask);
646: t += MUL_WEIGHT(u,i);
647: }
648: else
649: for ( t = 0, i = nd_exporigin; i < nd_wpd; i++ ) {
650: u = d[i]&mask[i];
651: for ( j = 0; j < nd_epw; j++, u>>=nd_bpe )
652: t += (u&nd_mask0);
653: }
654: d[k+1] = t;
655: }
1.43 noro 656: }
657:
1.61 noro 658: int ndl_lex_compare(UINT *d1,UINT *d2)
1.1 noro 659: {
660: int i;
661:
1.41 noro 662: d1 += nd_exporigin;
663: d2 += nd_exporigin;
664: for ( i = nd_exporigin; i < nd_wpd; i++, d1++, d2++ )
1.1 noro 665: if ( *d1 > *d2 )
1.32 noro 666: return nd_isrlex ? -1 : 1;
1.1 noro 667: else if ( *d1 < *d2 )
1.32 noro 668: return nd_isrlex ? 1 : -1;
1.1 noro 669: return 0;
670: }
671:
1.61 noro 672: int ndl_block_compare(UINT *d1,UINT *d2)
1.43 noro 673: {
674: int i,l,j,ord_o,ord_l;
675: struct order_pair *op;
1.61 noro 676: UINT t1,t2,m;
677: UINT *mask;
1.43 noro 678:
679: l = nd_blockmask->n;
680: op = nd_blockmask->order_pair;
681: for ( j = 0; j < l; j++ ) {
682: mask = nd_blockmask->mask[j];
683: ord_o = op[j].order;
684: if ( ord_o < 2 )
1.44 noro 685: if ( (t1=d1[j+1]) > (t2=d2[j+1]) ) return 1;
686: else if ( t1 < t2 ) return -1;
1.43 noro 687: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.44 noro 688: m = mask[i];
689: t1 = d1[i]&m;
690: t2 = d2[i]&m;
1.43 noro 691: if ( t1 > t2 )
692: return !ord_o ? -1 : 1;
693: else if ( t1 < t2 )
694: return !ord_o ? 1 : -1;
695: }
696: }
697: return 0;
698: }
699:
1.58 noro 700: /* TDH -> WW -> TD-> RL */
701:
1.61 noro 702: int ndl_ww_lex_compare(UINT *d1,UINT *d2)
1.58 noro 703: {
704: int i,m,e1,e2;
705:
706: if ( TD(d1) > TD(d2) ) return 1;
707: else if ( TD(d1) < TD(d2) ) return -1;
708: m = nd_nvar>>1;
709: for ( i = 0, e1 = e2 = 0; i < m; i++ ) {
710: e1 += current_weyl_weight_vector[i]*(GET_EXP(d1,m+i)-GET_EXP(d1,i));
711: e2 += current_weyl_weight_vector[i]*(GET_EXP(d2,m+i)-GET_EXP(d2,i));
712: }
713: if ( e1 > e2 ) return 1;
714: else if ( e1 < e2 ) return -1;
715: return ndl_lex_compare(d1,d2);
716: }
717:
1.61 noro 718: INLINE int ndl_equal(UINT *d1,UINT *d2)
1.1 noro 719: {
720: int i;
721:
1.41 noro 722: for ( i = 0; i < nd_wpd; i++ )
1.34 noro 723: if ( *d1++ != *d2++ )
1.1 noro 724: return 0;
725: return 1;
726: }
727:
1.61 noro 728: INLINE void ndl_copy(UINT *d1,UINT *d2)
1.6 noro 729: {
730: int i;
731:
732: switch ( nd_wpd ) {
1.41 noro 733: case 2:
1.34 noro 734: TD(d2) = TD(d1);
735: d2[1] = d1[1];
1.6 noro 736: break;
1.41 noro 737: case 3:
1.34 noro 738: TD(d2) = TD(d1);
1.6 noro 739: d2[1] = d1[1];
1.34 noro 740: d2[2] = d1[2];
1.6 noro 741: break;
742: default:
1.41 noro 743: for ( i = 0; i < nd_wpd; i++ )
1.6 noro 744: d2[i] = d1[i];
745: break;
746: }
747: }
748:
1.61 noro 749: INLINE void ndl_zero(UINT *d)
750: {
751: int i;
752: for ( i = 0; i < nd_wpd; i++ ) d[i] = 0;
753: }
754:
755: INLINE void ndl_add(UINT *d1,UINT *d2,UINT *d)
1.1 noro 756: {
757: int i;
758:
1.43 noro 759: #if 1
1.6 noro 760: switch ( nd_wpd ) {
1.41 noro 761: case 2:
762: TD(d) = TD(d1)+TD(d2);
1.34 noro 763: d[1] = d1[1]+d2[1];
1.6 noro 764: break;
1.41 noro 765: case 3:
766: TD(d) = TD(d1)+TD(d2);
1.6 noro 767: d[1] = d1[1]+d2[1];
1.34 noro 768: d[2] = d1[2]+d2[2];
1.6 noro 769: break;
770: default:
1.43 noro 771: for ( i = 0; i < nd_wpd; i++ ) d[i] = d1[i]+d2[i];
1.6 noro 772: break;
773: }
1.43 noro 774: #else
775: for ( i = 0; i < nd_wpd; i++ ) d[i] = d1[i]+d2[i];
776: #endif
1.6 noro 777: }
778:
1.55 noro 779: /* d1 += d2 */
1.61 noro 780: INLINE void ndl_addto(UINT *d1,UINT *d2)
1.55 noro 781: {
782: int i;
783:
784: #if 1
785: switch ( nd_wpd ) {
786: case 2:
787: TD(d1) += TD(d2);
788: d1[1] += d2[1];
789: break;
790: case 3:
791: TD(d1) += TD(d2);
792: d1[1] += d2[1];
793: d1[2] += d2[2];
794: break;
795: default:
796: for ( i = 0; i < nd_wpd; i++ ) d1[i] += d2[i];
797: break;
798: }
799: #else
800: for ( i = 0; i < nd_wpd; i++ ) d1[i] += d2[i];
801: #endif
802: }
803:
1.61 noro 804: INLINE void ndl_sub(UINT *d1,UINT *d2,UINT *d)
1.6 noro 805: {
806: int i;
807:
1.43 noro 808: for ( i = 0; i < nd_wpd; i++ ) d[i] = d1[i]-d2[i];
1.1 noro 809: }
810:
1.61 noro 811: int ndl_disjoint(UINT *d1,UINT *d2)
1.1 noro 812: {
1.61 noro 813: UINT t1,t2,u,u1,u2;
1.1 noro 814: int i,j;
815:
816: switch ( nd_bpe ) {
1.62 ! noro 817: case 3:
! 818: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
! 819: u1 = d1[i]; u2 = d2[i];
! 820: t1 = u1&0x38000000; t2 = u2&0x38000000; if ( t1&&t2 ) return 0;
! 821: t1 = u1& 0x7000000; t2 = u2& 0x7000000; if ( t1&&t2 ) return 0;
! 822: t1 = u1& 0xe00000; t2 = u2& 0xe00000; if ( t1&&t2 ) return 0;
! 823: t1 = u1& 0x1c0000; t2 = u2& 0x1c0000; if ( t1&&t2 ) return 0;
! 824: t1 = u1& 0x38000; t2 = u2& 0x38000; if ( t1&&t2 ) return 0;
! 825: t1 = u1& 0x7000; t2 = u2& 0x7000; if ( t1&&t2 ) return 0;
! 826: t1 = u1& 0xe00; t2 = u2& 0xe00; if ( t1&&t2 ) return 0;
! 827: t1 = u1& 0x1c0; t2 = u2& 0x1c0; if ( t1&&t2 ) return 0;
! 828: t1 = u1& 0x38; t2 = u2& 0x38; if ( t1&&t2 ) return 0;
! 829: t1 = u1& 0x7; t2 = u2& 0x7; if ( t1&&t2 ) return 0;
! 830: }
! 831: return 1;
! 832: break;
1.1 noro 833: case 4:
1.41 noro 834: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 835: u1 = d1[i]; u2 = d2[i];
836: t1 = u1&0xf0000000; t2 = u2&0xf0000000; if ( t1&&t2 ) return 0;
1.62 ! noro 837: t1 = u1& 0xf000000; t2 = u2& 0xf000000; if ( t1&&t2 ) return 0;
! 838: t1 = u1& 0xf00000; t2 = u2& 0xf00000; if ( t1&&t2 ) return 0;
! 839: t1 = u1& 0xf0000; t2 = u2& 0xf0000; if ( t1&&t2 ) return 0;
! 840: t1 = u1& 0xf000; t2 = u2& 0xf000; if ( t1&&t2 ) return 0;
! 841: t1 = u1& 0xf00; t2 = u2& 0xf00; if ( t1&&t2 ) return 0;
! 842: t1 = u1& 0xf0; t2 = u2& 0xf0; if ( t1&&t2 ) return 0;
! 843: t1 = u1& 0xf; t2 = u2& 0xf; if ( t1&&t2 ) return 0;
1.1 noro 844: }
845: return 1;
846: break;
847: case 6:
1.41 noro 848: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 849: u1 = d1[i]; u2 = d2[i];
850: t1 = u1&0x3f000000; t2 = u2&0x3f000000; if ( t1&&t2 ) return 0;
1.62 ! noro 851: t1 = u1& 0xfc0000; t2 = u2& 0xfc0000; if ( t1&&t2 ) return 0;
! 852: t1 = u1& 0x3f000; t2 = u2& 0x3f000; if ( t1&&t2 ) return 0;
! 853: t1 = u1& 0xfc0; t2 = u2& 0xfc0; if ( t1&&t2 ) return 0;
! 854: t1 = u1& 0x3f; t2 = u2& 0x3f; if ( t1&&t2 ) return 0;
1.1 noro 855: }
856: return 1;
857: break;
858: case 8:
1.41 noro 859: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 860: u1 = d1[i]; u2 = d2[i];
861: t1 = u1&0xff000000; t2 = u2&0xff000000; if ( t1&&t2 ) return 0;
1.62 ! noro 862: t1 = u1& 0xff0000; t2 = u2& 0xff0000; if ( t1&&t2 ) return 0;
! 863: t1 = u1& 0xff00; t2 = u2& 0xff00; if ( t1&&t2 ) return 0;
! 864: t1 = u1& 0xff; t2 = u2& 0xff; if ( t1&&t2 ) return 0;
1.1 noro 865: }
866: return 1;
867: break;
868: case 16:
1.41 noro 869: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 870: u1 = d1[i]; u2 = d2[i];
871: t1 = u1&0xffff0000; t2 = u2&0xffff0000; if ( t1&&t2 ) return 0;
1.62 ! noro 872: t1 = u1& 0xffff; t2 = u2& 0xffff; if ( t1&&t2 ) return 0;
1.1 noro 873: }
874: return 1;
875: break;
876: case 32:
1.41 noro 877: for ( i = nd_exporigin; i < nd_wpd; i++ )
1.1 noro 878: if ( d1[i] && d2[i] ) return 0;
879: return 1;
880: break;
881: default:
1.41 noro 882: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.1 noro 883: u1 = d1[i]; u2 = d2[i];
884: for ( j = 0; j < nd_epw; j++ ) {
885: if ( (u1&nd_mask0) && (u2&nd_mask0) ) return 0;
886: u1 >>= nd_bpe; u2 >>= nd_bpe;
887: }
888: }
889: return 1;
890: break;
891: }
892: }
893:
1.61 noro 894: int ndl_check_bound2(int index,UINT *d2)
1.1 noro 895: {
1.61 noro 896: UINT u2;
897: UINT *d1;
1.5 noro 898: int i,j,ind,k;
1.1 noro 899:
1.5 noro 900: d1 = nd_bound[index];
901: ind = 0;
902: switch ( nd_bpe ) {
1.62 ! noro 903: case 3:
! 904: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
! 905: u2 = d2[i];
! 906: if ( d1[ind++]+((u2>>27)&0x7) >= 0x8 ) return 1;
! 907: if ( d1[ind++]+((u2>>24)&0x7) >= 0x8 ) return 1;
! 908: if ( d1[ind++]+((u2>>21)&0x7) >= 0x8 ) return 1;
! 909: if ( d1[ind++]+((u2>>18)&0x7) >= 0x8 ) return 1;
! 910: if ( d1[ind++]+((u2>>15)&0x7) >= 0x8 ) return 1;
! 911: if ( d1[ind++]+((u2>>12)&0x7) >= 0x8 ) return 1;
! 912: if ( d1[ind++]+((u2>>9)&0x7) >= 0x8 ) return 1;
! 913: if ( d1[ind++]+((u2>>6)&0x7) >= 0x8 ) return 1;
! 914: if ( d1[ind++]+((u2>>3)&0x7) >= 0x8 ) return 1;
! 915: if ( d1[ind++]+(u2&0x7) >= 0x8 ) return 1;
! 916: }
! 917: return 0;
! 918: break;
1.5 noro 919: case 4:
1.41 noro 920: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.5 noro 921: u2 = d2[i];
922: if ( d1[ind++]+((u2>>28)&0xf) >= 0x10 ) return 1;
923: if ( d1[ind++]+((u2>>24)&0xf) >= 0x10 ) return 1;
924: if ( d1[ind++]+((u2>>20)&0xf) >= 0x10 ) return 1;
925: if ( d1[ind++]+((u2>>16)&0xf) >= 0x10 ) return 1;
926: if ( d1[ind++]+((u2>>12)&0xf) >= 0x10 ) return 1;
927: if ( d1[ind++]+((u2>>8)&0xf) >= 0x10 ) return 1;
928: if ( d1[ind++]+((u2>>4)&0xf) >= 0x10 ) return 1;
929: if ( d1[ind++]+(u2&0xf) >= 0x10 ) return 1;
930: }
931: return 0;
932: break;
933: case 6:
1.41 noro 934: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.5 noro 935: u2 = d2[i];
936: if ( d1[ind++]+((u2>>24)&0x3f) >= 0x40 ) return 1;
937: if ( d1[ind++]+((u2>>18)&0x3f) >= 0x40 ) return 1;
938: if ( d1[ind++]+((u2>>12)&0x3f) >= 0x40 ) return 1;
939: if ( d1[ind++]+((u2>>6)&0x3f) >= 0x40 ) return 1;
940: if ( d1[ind++]+(u2&0x3f) >= 0x40 ) return 1;
941: }
942: return 0;
943: break;
944: case 8:
1.41 noro 945: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.5 noro 946: u2 = d2[i];
947: if ( d1[ind++]+((u2>>24)&0xff) >= 0x100 ) return 1;
948: if ( d1[ind++]+((u2>>16)&0xff) >= 0x100 ) return 1;
949: if ( d1[ind++]+((u2>>8)&0xff) >= 0x100 ) return 1;
950: if ( d1[ind++]+(u2&0xff) >= 0x100 ) return 1;
951: }
952: return 0;
953: break;
954: case 16:
1.41 noro 955: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.5 noro 956: u2 = d2[i];
957: if ( d1[ind++]+((u2>>16)&0xffff) > 0x10000 ) return 1;
958: if ( d1[ind++]+(u2&0xffff) > 0x10000 ) return 1;
959: }
960: return 0;
961: break;
962: case 32:
1.41 noro 963: for ( i = nd_exporigin; i < nd_wpd; i++ )
1.5 noro 964: if ( d1[i]+d2[i]<d1[i] ) return 1;
965: return 0;
966: break;
967: default:
1.41 noro 968: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.5 noro 969: u2 = d2[i];
970: k = (nd_epw-1)*nd_bpe;
971: for ( j = 0; j < nd_epw; j++, k -= nd_bpe )
972: if ( d1[ind++]+((u2>>k)&nd_mask0) > nd_mask0 ) return 1;
973: }
974: return 0;
975: break;
976: }
1.1 noro 977: }
978:
1.61 noro 979: int ndl_check_bound2_direct(UINT *d1,UINT *d2)
1.23 noro 980: {
1.61 noro 981: UINT u2;
1.45 noro 982: int i,j,ind,k;
1.23 noro 983:
1.45 noro 984: ind = 0;
1.23 noro 985: switch ( nd_bpe ) {
1.62 ! noro 986: case 3:
! 987: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
! 988: u2 = d2[i];
! 989: if ( d1[ind++]+((u2>>27)&0x7) >= 0x8 ) return 1;
! 990: if ( d1[ind++]+((u2>>24)&0x7) >= 0x8 ) return 1;
! 991: if ( d1[ind++]+((u2>>21)&0x7) >= 0x8 ) return 1;
! 992: if ( d1[ind++]+((u2>>18)&0x7) >= 0x8 ) return 1;
! 993: if ( d1[ind++]+((u2>>15)&0x7) >= 0x8 ) return 1;
! 994: if ( d1[ind++]+((u2>>12)&0x7) >= 0x8 ) return 1;
! 995: if ( d1[ind++]+((u2>>9)&0x7) >= 0x8 ) return 1;
! 996: if ( d1[ind++]+((u2>>6)&0x7) >= 0x8 ) return 1;
! 997: if ( d1[ind++]+((u2>>3)&0x7) >= 0x8 ) return 1;
! 998: if ( d1[ind++]+(u2&0x7) >= 0x8 ) return 1;
! 999: }
! 1000: return 0;
! 1001: break;
1.23 noro 1002: case 4:
1.41 noro 1003: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.45 noro 1004: u2 = d2[i];
1005: if ( d1[ind++]+((u2>>28)&0xf) >= 0x10 ) return 1;
1006: if ( d1[ind++]+((u2>>24)&0xf) >= 0x10 ) return 1;
1007: if ( d1[ind++]+((u2>>20)&0xf) >= 0x10 ) return 1;
1008: if ( d1[ind++]+((u2>>16)&0xf) >= 0x10 ) return 1;
1009: if ( d1[ind++]+((u2>>12)&0xf) >= 0x10 ) return 1;
1010: if ( d1[ind++]+((u2>>8)&0xf) >= 0x10 ) return 1;
1011: if ( d1[ind++]+((u2>>4)&0xf) >= 0x10 ) return 1;
1012: if ( d1[ind++]+(u2&0xf) >= 0x10 ) return 1;
1.23 noro 1013: }
1014: return 0;
1015: break;
1016: case 6:
1.41 noro 1017: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.45 noro 1018: u2 = d2[i];
1019: if ( d1[ind++]+((u2>>24)&0x3f) >= 0x40 ) return 1;
1020: if ( d1[ind++]+((u2>>18)&0x3f) >= 0x40 ) return 1;
1021: if ( d1[ind++]+((u2>>12)&0x3f) >= 0x40 ) return 1;
1022: if ( d1[ind++]+((u2>>6)&0x3f) >= 0x40 ) return 1;
1023: if ( d1[ind++]+(u2&0x3f) >= 0x40 ) return 1;
1.23 noro 1024: }
1025: return 0;
1026: break;
1027: case 8:
1.41 noro 1028: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.45 noro 1029: u2 = d2[i];
1030: if ( d1[ind++]+((u2>>24)&0xff) >= 0x100 ) return 1;
1031: if ( d1[ind++]+((u2>>16)&0xff) >= 0x100 ) return 1;
1032: if ( d1[ind++]+((u2>>8)&0xff) >= 0x100 ) return 1;
1033: if ( d1[ind++]+(u2&0xff) >= 0x100 ) return 1;
1.23 noro 1034: }
1035: return 0;
1036: break;
1037: case 16:
1.41 noro 1038: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.45 noro 1039: u2 = d2[i];
1040: if ( d1[ind++]+((u2>>16)&0xffff) > 0x10000 ) return 1;
1041: if ( d1[ind++]+(u2&0xffff) > 0x10000 ) return 1;
1.23 noro 1042: }
1043: return 0;
1044: break;
1045: case 32:
1.41 noro 1046: for ( i = nd_exporigin; i < nd_wpd; i++ )
1.23 noro 1047: if ( d1[i]+d2[i]<d1[i] ) return 1;
1048: return 0;
1049: break;
1050: default:
1.41 noro 1051: for ( i = nd_exporigin; i < nd_wpd; i++ ) {
1.45 noro 1052: u2 = d2[i];
1.23 noro 1053: k = (nd_epw-1)*nd_bpe;
1054: for ( j = 0; j < nd_epw; j++, k -= nd_bpe )
1.45 noro 1055: if ( d1[ind++]+((u2>>k)&nd_mask0) > nd_mask0 ) return 1;
1.23 noro 1056: }
1057: return 0;
1058: break;
1059: }
1060: }
1061:
1.61 noro 1062: INLINE int ndl_hash_value(UINT *d)
1.1 noro 1063: {
1064: int i;
1065: int r;
1066:
1.34 noro 1067: r = 0;
1.41 noro 1068: for ( i = 0; i < nd_wpd; i++ )
1.1 noro 1069: r = ((r<<16)+d[i])%REDTAB_LEN;
1070: return r;
1071: }
1072:
1.9 noro 1073: INLINE int nd_find_reducer(ND g)
1.1 noro 1074: {
1.13 noro 1075: RHist r;
1.61 noro 1076: UINT *dg;
1.6 noro 1077: int d,k,i;
1.1 noro 1078:
1.34 noro 1079: dg = HDL(g);
1.39 noro 1080: #if 1
1.34 noro 1081: d = ndl_hash_value(HDL(g));
1.13 noro 1082: for ( r = nd_red[d], k = 0; r; r = NEXT(r), k++ ) {
1.34 noro 1083: if ( ndl_equal(dg,DL(r)) ) {
1.1 noro 1084: if ( k > 0 ) nd_notfirst++;
1085: nd_found++;
1.13 noro 1086: return r->index;
1.1 noro 1087: }
1088: }
1.39 noro 1089: #endif
1.13 noro 1090: if ( Reverse )
1091: for ( i = nd_psn-1; i >= 0; i-- ) {
1092: r = nd_psh[i];
1.34 noro 1093: if ( ndl_reducible(dg,DL(r)) ) {
1.13 noro 1094: nd_create++;
1.34 noro 1095: nd_append_red(dg,i);
1.13 noro 1096: return i;
1097: }
1098: }
1099: else
1100: for ( i = 0; i < nd_psn; i++ ) {
1101: r = nd_psh[i];
1.34 noro 1102: if ( ndl_reducible(dg,DL(r)) ) {
1.13 noro 1103: nd_create++;
1.34 noro 1104: nd_append_red(dg,i);
1.13 noro 1105: return i;
1106: }
1.1 noro 1107: }
1.6 noro 1108: return -1;
1.1 noro 1109: }
1110:
1.23 noro 1111: INLINE int nd_find_reducer_direct(ND g,NDV *ps,int len)
1112: {
1113: NDV r;
1.31 noro 1114: RHist s;
1115: int d,k,i;
1.23 noro 1116:
1117: if ( Reverse )
1118: for ( i = len-1; i >= 0; i-- ) {
1119: r = ps[i];
1.45 noro 1120: if ( ndl_reducible(HDL(g),HDL(r)) )
1.23 noro 1121: return i;
1122: }
1123: else
1124: for ( i = 0; i < len; i++ ) {
1125: r = ps[i];
1.45 noro 1126: if ( ndl_reducible(HDL(g),HDL(r)) )
1.23 noro 1127: return i;
1128: }
1129: return -1;
1130: }
1131:
1.31 noro 1132: ND nd_add(int mod,ND p1,ND p2)
1.1 noro 1133: {
1134: int n,c;
1.34 noro 1135: int t,can,td1,td2;
1.1 noro 1136: ND r;
1137: NM m1,m2,mr0,mr,s;
1138:
1.34 noro 1139: if ( !p1 ) return p2;
1140: else if ( !p2 ) return p1;
1141: else if ( !mod ) return nd_add_q(p1,p2);
1.1 noro 1142: else {
1.30 noro 1143: can = 0;
1.1 noro 1144: for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2), mr0 = 0; m1 && m2; ) {
1.34 noro 1145: c = DL_COMPARE(DL(m1),DL(m2));
1.1 noro 1146: switch ( c ) {
1147: case 0:
1.19 noro 1148: t = ((CM(m1))+(CM(m2))) - mod;
1.34 noro 1149: if ( t < 0 ) t += mod;
1.1 noro 1150: s = m1; m1 = NEXT(m1);
1151: if ( t ) {
1.34 noro 1152: can++; NEXTNM2(mr0,mr,s); CM(mr) = (t);
1.1 noro 1153: } else {
1.34 noro 1154: can += 2; FREENM(s);
1.1 noro 1155: }
1156: s = m2; m2 = NEXT(m2); FREENM(s);
1157: break;
1158: case 1:
1159: s = m1; m1 = NEXT(m1); NEXTNM2(mr0,mr,s);
1160: break;
1161: case -1:
1162: s = m2; m2 = NEXT(m2); NEXTNM2(mr0,mr,s);
1163: break;
1164: }
1165: }
1166: if ( !mr0 )
1.34 noro 1167: if ( m1 ) mr0 = m1;
1168: else if ( m2 ) mr0 = m2;
1169: else return 0;
1170: else if ( m1 ) NEXT(mr) = m1;
1171: else if ( m2 ) NEXT(mr) = m2;
1172: else NEXT(mr) = 0;
1.1 noro 1173: BDY(p1) = mr0;
1.14 noro 1174: SG(p1) = MAX(SG(p1),SG(p2));
1.31 noro 1175: LEN(p1) = LEN(p1)+LEN(p2)-can;
1.1 noro 1176: FREEND(p2);
1177: return p1;
1178: }
1179: }
1180:
1.31 noro 1181: ND nd_add_q(ND p1,ND p2)
1.17 noro 1182: {
1.30 noro 1183: int n,c,can;
1.17 noro 1184: ND r;
1185: NM m1,m2,mr0,mr,s;
1186: Q t;
1187:
1.34 noro 1188: if ( !p1 ) return p2;
1189: else if ( !p2 ) return p1;
1.31 noro 1190: else {
1.30 noro 1191: can = 0;
1.17 noro 1192: for ( n = NV(p1), m1 = BDY(p1), m2 = BDY(p2), mr0 = 0; m1 && m2; ) {
1.34 noro 1193: c = DL_COMPARE(DL(m1),DL(m2));
1.17 noro 1194: switch ( c ) {
1195: case 0:
1196: addq(CQ(m1),CQ(m2),&t);
1197: s = m1; m1 = NEXT(m1);
1198: if ( t ) {
1.34 noro 1199: can++; NEXTNM2(mr0,mr,s); CQ(mr) = (t);
1.17 noro 1200: } else {
1.34 noro 1201: can += 2; FREENM(s);
1.17 noro 1202: }
1203: s = m2; m2 = NEXT(m2); FREENM(s);
1204: break;
1205: case 1:
1206: s = m1; m1 = NEXT(m1); NEXTNM2(mr0,mr,s);
1207: break;
1208: case -1:
1209: s = m2; m2 = NEXT(m2); NEXTNM2(mr0,mr,s);
1210: break;
1211: }
1212: }
1213: if ( !mr0 )
1.34 noro 1214: if ( m1 ) mr0 = m1;
1215: else if ( m2 ) mr0 = m2;
1216: else return 0;
1217: else if ( m1 ) NEXT(mr) = m1;
1218: else if ( m2 ) NEXT(mr) = m2;
1219: else NEXT(mr) = 0;
1.17 noro 1220: BDY(p1) = mr0;
1221: SG(p1) = MAX(SG(p1),SG(p2));
1.31 noro 1222: LEN(p1) = LEN(p1)+LEN(p2)-can;
1.17 noro 1223: FREEND(p2);
1224: return p1;
1225: }
1226: }
1227:
1.1 noro 1228: /* ret=1 : success, ret=0 : overflow */
1.53 noro 1229: int nd_nf(int mod,ND g,NDV *ps,int full,ND *rp)
1.1 noro 1230: {
1.11 noro 1231: ND d;
1.1 noro 1232: NM m,mrd,tail;
1.7 noro 1233: NM mul;
1.10 noro 1234: int n,sugar,psugar,sugar0,stat,index;
1.30 noro 1235: int c,c1,c2,dummy;
1.17 noro 1236: RHist h;
1.11 noro 1237: NDV p,red;
1.16 noro 1238: Q cg,cred,gcd;
1.21 noro 1239: double hmag;
1.1 noro 1240:
1241: if ( !g ) {
1242: *rp = 0;
1243: return 1;
1244: }
1.34 noro 1245: if ( !mod ) hmag = ((double)p_mag((P)HCQ(g)))*nd_scale;
1.21 noro 1246:
1.14 noro 1247: sugar0 = sugar = SG(g);
1.1 noro 1248: n = NV(g);
1.61 noro 1249: mul = (NM)ALLOCA(sizeof(struct oNM)+(nd_wpd-1)*sizeof(UINT));
1.1 noro 1250: for ( d = 0; g; ) {
1.6 noro 1251: index = nd_find_reducer(g);
1252: if ( index >= 0 ) {
1.17 noro 1253: h = nd_psh[index];
1254: ndl_sub(HDL(g),DL(h),DL(mul));
1.14 noro 1255: if ( ndl_check_bound2(index,DL(mul)) ) {
1.6 noro 1256: nd_free(g); nd_free(d);
1257: return 0;
1258: }
1.53 noro 1259: p = ps[index];
1.16 noro 1260: if ( mod ) {
1.19 noro 1261: c1 = invm(HCM(p),mod); c2 = mod-HCM(g);
1262: DMAR(c1,c2,0,mod,c); CM(mul) = c;
1.16 noro 1263: } else {
1.17 noro 1264: igcd_cofactor(HCQ(g),HCQ(p),&gcd,&cg,&cred);
1.16 noro 1265: chsgnq(cg,&CQ(mul));
1.20 noro 1266: nd_mul_c_q(d,cred); nd_mul_c_q(g,cred);
1.16 noro 1267: }
1.55 noro 1268: g = nd_add(mod,g,ndv_mul_nm(mod,mul,p));
1.34 noro 1269: sugar = MAX(sugar,SG(p)+TD(DL(mul)));
1.22 noro 1270: if ( !mod && hmag && g && ((double)(p_mag((P)HCQ(g))) > hmag) ) {
1.21 noro 1271: nd_removecont2(d,g);
1272: hmag = ((double)p_mag((P)HCQ(g)))*nd_scale;
1273: }
1.1 noro 1274: } else if ( !full ) {
1275: *rp = g;
1276: return 1;
1277: } else {
1278: m = BDY(g);
1279: if ( NEXT(m) ) {
1.34 noro 1280: BDY(g) = NEXT(m); NEXT(m) = 0; LEN(g)--;
1.1 noro 1281: } else {
1282: FREEND(g); g = 0;
1283: }
1284: if ( d ) {
1.34 noro 1285: NEXT(tail)=m; tail=m; LEN(d)++;
1.1 noro 1286: } else {
1.34 noro 1287: MKND(n,m,1,d); tail = BDY(d);
1.1 noro 1288: }
1289: }
1290: }
1.34 noro 1291: if ( d ) SG(d) = sugar;
1.1 noro 1292: *rp = d;
1293: return 1;
1294: }
1.28 noro 1295:
1.53 noro 1296: int nd_nf_pbucket(int mod,ND g,NDV *ps,int full,ND *rp)
1.25 noro 1297: {
1298: int hindex,index;
1299: NDV p;
1300: ND u,d,red;
1301: NODE l;
1.31 noro 1302: NM mul,m,mrd,tail;
1.25 noro 1303: int sugar,psugar,n,h_reducible;
1304: PGeoBucket bucket;
1305: int c,c1,c2;
1.26 noro 1306: Q cg,cred,gcd,zzz;
1.25 noro 1307: RHist h;
1.28 noro 1308: double hmag,gmag;
1.25 noro 1309:
1310: if ( !g ) {
1311: *rp = 0;
1312: return 1;
1313: }
1314: sugar = SG(g);
1315: n = NV(g);
1.34 noro 1316: if ( !mod ) hmag = ((double)p_mag((P)HCQ(g)))*nd_scale;
1.25 noro 1317: bucket = create_pbucket();
1.31 noro 1318: add_pbucket(mod,bucket,g);
1.25 noro 1319: d = 0;
1.61 noro 1320: mul = (NM)ALLOCA(sizeof(struct oNM)+(nd_wpd-1)*sizeof(UINT));
1.25 noro 1321: while ( 1 ) {
1.26 noro 1322: hindex = mod?head_pbucket(mod,bucket):head_pbucket_q(bucket);
1.25 noro 1323: if ( hindex < 0 ) {
1.34 noro 1324: if ( d ) SG(d) = sugar;
1.25 noro 1325: *rp = d;
1326: return 1;
1327: }
1328: g = bucket->body[hindex];
1329: index = nd_find_reducer(g);
1330: if ( index >= 0 ) {
1331: h = nd_psh[index];
1332: ndl_sub(HDL(g),DL(h),DL(mul));
1333: if ( ndl_check_bound2(index,DL(mul)) ) {
1.26 noro 1334: nd_free(d);
1.25 noro 1335: free_pbucket(bucket);
1336: *rp = 0;
1337: return 0;
1338: }
1.53 noro 1339: p = ps[index];
1.25 noro 1340: if ( mod ) {
1341: c1 = invm(HCM(p),mod); c2 = mod-HCM(g);
1342: DMAR(c1,c2,0,mod,c); CM(mul) = c;
1343: } else {
1344: igcd_cofactor(HCQ(g),HCQ(p),&gcd,&cg,&cred);
1345: chsgnq(cg,&CQ(mul));
1.26 noro 1346: nd_mul_c_q(d,cred);
1347: mulq_pbucket(bucket,cred);
1348: g = bucket->body[hindex];
1.28 noro 1349: gmag = (double)p_mag((P)HCQ(g));
1.25 noro 1350: }
1.55 noro 1351: red = ndv_mul_nm(mod,mul,p);
1.25 noro 1352: bucket->body[hindex] = nd_remove_head(g);
1353: red = nd_remove_head(red);
1.31 noro 1354: add_pbucket(mod,bucket,red);
1.34 noro 1355: psugar = SG(p)+TD(DL(mul));
1356: sugar = MAX(sugar,psugar);
1.28 noro 1357: if ( !mod && hmag && (gmag > hmag) ) {
1358: g = normalize_pbucket(mod,bucket);
1359: if ( !g ) {
1.34 noro 1360: if ( d ) SG(d) = sugar;
1.28 noro 1361: *rp = d;
1362: return 1;
1363: }
1364: nd_removecont2(d,g);
1365: hmag = ((double)p_mag((P)HCQ(g)))*nd_scale;
1.31 noro 1366: add_pbucket(mod,bucket,g);
1.28 noro 1367: }
1.25 noro 1368: } else if ( !full ) {
1369: g = normalize_pbucket(mod,bucket);
1.34 noro 1370: if ( g ) SG(g) = sugar;
1.25 noro 1371: *rp = g;
1372: return 1;
1373: } else {
1374: m = BDY(g);
1375: if ( NEXT(m) ) {
1.34 noro 1376: BDY(g) = NEXT(m); NEXT(m) = 0; LEN(g)--;
1.25 noro 1377: } else {
1378: FREEND(g); g = 0;
1379: }
1380: bucket->body[hindex] = g;
1381: NEXT(m) = 0;
1382: if ( d ) {
1.34 noro 1383: NEXT(tail)=m; tail=m; LEN(d)++;
1.25 noro 1384: } else {
1.34 noro 1385: MKND(n,m,1,d); tail = BDY(d);
1.25 noro 1386: }
1387: }
1388: }
1389: }
1.27 noro 1390:
1.45 noro 1391: int nd_nf_direct(int mod,ND g,BaseSet base,int full,ND *rp)
1.23 noro 1392: {
1.30 noro 1393: ND d;
1394: NM m,mrd,tail;
1395: NM mul;
1.45 noro 1396: NDV *ps;
1397: int n,sugar,psugar,sugar0,stat,index,len;
1.31 noro 1398: int c,c1,c2;
1.61 noro 1399: UINT **bound;
1.30 noro 1400: RHist h;
1401: NDV p,red;
1402: Q cg,cred,gcd;
1403: double hmag;
1404:
1405: if ( !g ) {
1406: *rp = 0;
1407: return 1;
1408: }
1409: #if 0
1410: if ( !mod )
1411: hmag = ((double)p_mag((P)HCQ(g)))*nd_scale;
1412: #else
1413: /* XXX */
1414: hmag = 0;
1415: #endif
1416:
1.45 noro 1417: ps = base->ps;
1418: bound = base->bound;
1419: len = base->len;
1.30 noro 1420: sugar0 = sugar = SG(g);
1421: n = NV(g);
1.61 noro 1422: mul = (NM)ALLOCA(sizeof(struct oNM)+(nd_wpd-1)*sizeof(UINT));
1.30 noro 1423: for ( d = 0; g; ) {
1424: index = nd_find_reducer_direct(g,ps,len);
1425: if ( index >= 0 ) {
1426: p = ps[index];
1427: ndl_sub(HDL(g),HDL(p),DL(mul));
1.45 noro 1428: if ( ndl_check_bound2_direct(bound[index],DL(mul)) ) {
1.30 noro 1429: nd_free(g); nd_free(d);
1430: return 0;
1431: }
1432: if ( mod ) {
1433: c1 = invm(HCM(p),mod); c2 = mod-HCM(g);
1434: DMAR(c1,c2,0,mod,c); CM(mul) = c;
1435: } else {
1436: igcd_cofactor(HCQ(g),HCQ(p),&gcd,&cg,&cred);
1437: chsgnq(cg,&CQ(mul));
1438: nd_mul_c_q(d,cred); nd_mul_c_q(g,cred);
1439: }
1.55 noro 1440: g = nd_add(mod,g,ndv_mul_nm(mod,mul,p));
1.34 noro 1441: sugar = MAX(sugar,SG(p)+TD(DL(mul)));
1.30 noro 1442: if ( !mod && hmag && g && ((double)(p_mag((P)HCQ(g))) > hmag) ) {
1443: nd_removecont2(d,g);
1444: hmag = ((double)p_mag((P)HCQ(g)))*nd_scale;
1445: }
1446: } else if ( !full ) {
1447: *rp = g;
1448: return 1;
1449: } else {
1450: m = BDY(g);
1451: if ( NEXT(m) ) {
1.34 noro 1452: BDY(g) = NEXT(m); NEXT(m) = 0; LEN(g)--;
1.30 noro 1453: } else {
1454: FREEND(g); g = 0;
1455: }
1456: if ( d ) {
1.34 noro 1457: NEXT(tail)=m; tail=m; LEN(d)++;
1.30 noro 1458: } else {
1.34 noro 1459: MKND(n,m,1,d); tail = BDY(d);
1.30 noro 1460: }
1461: }
1462: }
1.34 noro 1463: if ( d ) SG(d) = sugar;
1.30 noro 1464: *rp = d;
1465: return 1;
1466: }
1467:
1.61 noro 1468: /* input : list of NDV, cand : list of NDV */
1.28 noro 1469:
1.61 noro 1470: int ndv_check_candidate(NODE input,int obpe,int oadv,EPOS oepos,NODE cand)
1.28 noro 1471: {
1472: int n,i,stat;
1473: ND nf,d;
1.61 noro 1474: NDV r;
1.45 noro 1475: NODE t,s;
1476:
1.61 noro 1477: ndv_setup(0,0,cand);
1.31 noro 1478: n = length(cand);
1.28 noro 1479:
1480: /* membercheck : list is a subset of Id(cand) ? */
1481: for ( t = input; t; t = NEXT(t) ) {
1.45 noro 1482: again:
1.61 noro 1483: if ( nd_bpe > obpe )
1484: r = ndv_dup_realloc((NDV)BDY(t),obpe,oadv,oepos);
1485: else
1486: r = (NDV)BDY(t);
1487: d = ndvtond(0,r);
1.53 noro 1488: stat = nd_nf(0,d,nd_ps,0,&nf);
1.45 noro 1489: if ( !stat ) {
1490: nd_reconstruct(0,0,0);
1491: goto again;
1492: } else if ( nf ) return 0;
1493: printf("."); fflush(stdout);
1.28 noro 1494: }
1.45 noro 1495: printf("\n");
1.28 noro 1496: /* gbcheck : cand is a GB of Id(cand) ? */
1.34 noro 1497: if ( !nd_gb(0,1) ) return 0;
1.28 noro 1498: /* XXX */
1.23 noro 1499: return 1;
1500: }
1.1 noro 1501:
1502: ND nd_remove_head(ND p)
1503: {
1504: NM m;
1505:
1506: m = BDY(p);
1507: if ( !NEXT(m) ) {
1.34 noro 1508: FREEND(p); p = 0;
1.31 noro 1509: } else {
1.34 noro 1510: BDY(p) = NEXT(m); LEN(p)--;
1.31 noro 1511: }
1.1 noro 1512: FREENM(m);
1513: return p;
1514: }
1515:
1516: PGeoBucket create_pbucket()
1517: {
1518: PGeoBucket g;
1519:
1520: g = CALLOC(1,sizeof(struct oPGeoBucket));
1521: g->m = -1;
1522: return g;
1523: }
1524:
1.25 noro 1525: void free_pbucket(PGeoBucket b) {
1526: int i;
1527:
1.26 noro 1528: for ( i = 0; i <= b->m; i++ )
1.25 noro 1529: if ( b->body[i] ) {
1530: nd_free(b->body[i]);
1531: b->body[i] = 0;
1532: }
1533: GC_free(b);
1534: }
1535:
1.31 noro 1536: void add_pbucket(int mod,PGeoBucket g,ND d)
1.1 noro 1537: {
1.31 noro 1538: int l,i,k,m;
1.1 noro 1539:
1.31 noro 1540: if ( !d )
1541: return;
1542: l = LEN(d);
1.29 noro 1543: for ( k = 0, m = 1; l > m; k++, m <<= 1 );
1544: /* 2^(k-1) < l <= 2^k (=m) */
1.31 noro 1545: d = nd_add(mod,g->body[k],d);
1546: for ( ; d && LEN(d) > m; k++, m <<= 1 ) {
1.1 noro 1547: g->body[k] = 0;
1.31 noro 1548: d = nd_add(mod,g->body[k+1],d);
1.1 noro 1549: }
1550: g->body[k] = d;
1551: g->m = MAX(g->m,k);
1552: }
1553:
1.26 noro 1554: void mulq_pbucket(PGeoBucket g,Q c)
1555: {
1556: int k;
1557:
1558: for ( k = 0; k <= g->m; k++ )
1559: nd_mul_c_q(g->body[k],c);
1560: }
1561:
1.19 noro 1562: int head_pbucket(int mod,PGeoBucket g)
1.1 noro 1563: {
1564: int j,i,c,k,nv,sum;
1.61 noro 1565: UINT *di,*dj;
1.1 noro 1566: ND gi,gj;
1567:
1568: k = g->m;
1569: while ( 1 ) {
1570: j = -1;
1571: for ( i = 0; i <= k; i++ ) {
1572: if ( !(gi = g->body[i]) )
1573: continue;
1574: if ( j < 0 ) {
1575: j = i;
1576: gj = g->body[j];
1577: dj = HDL(gj);
1.14 noro 1578: sum = HCM(gj);
1.1 noro 1579: } else {
1.34 noro 1580: c = DL_COMPARE(HDL(gi),dj);
1.1 noro 1581: if ( c > 0 ) {
1.34 noro 1582: if ( sum ) HCM(gj) = sum;
1583: else g->body[j] = nd_remove_head(gj);
1.1 noro 1584: j = i;
1585: gj = g->body[j];
1586: dj = HDL(gj);
1.14 noro 1587: sum = HCM(gj);
1.1 noro 1588: } else if ( c == 0 ) {
1.19 noro 1589: sum = sum+HCM(gi)-mod;
1.34 noro 1590: if ( sum < 0 ) sum += mod;
1.1 noro 1591: g->body[i] = nd_remove_head(gi);
1592: }
1593: }
1594: }
1.34 noro 1595: if ( j < 0 ) return -1;
1.1 noro 1596: else if ( sum ) {
1.14 noro 1597: HCM(gj) = sum;
1.26 noro 1598: return j;
1.31 noro 1599: } else
1.26 noro 1600: g->body[j] = nd_remove_head(gj);
1601: }
1602: }
1603:
1604: int head_pbucket_q(PGeoBucket g)
1605: {
1606: int j,i,c,k,nv;
1607: Q sum,t;
1608: ND gi,gj;
1609:
1610: k = g->m;
1611: while ( 1 ) {
1612: j = -1;
1613: for ( i = 0; i <= k; i++ ) {
1.34 noro 1614: if ( !(gi = g->body[i]) ) continue;
1.26 noro 1615: if ( j < 0 ) {
1616: j = i;
1617: gj = g->body[j];
1618: sum = HCQ(gj);
1619: } else {
1620: nv = NV(gi);
1.34 noro 1621: c = DL_COMPARE(HDL(gi),HDL(gj));
1.26 noro 1622: if ( c > 0 ) {
1.34 noro 1623: if ( sum ) HCQ(gj) = sum;
1624: else g->body[j] = nd_remove_head(gj);
1.26 noro 1625: j = i;
1626: gj = g->body[j];
1627: sum = HCQ(gj);
1628: } else if ( c == 0 ) {
1629: addq(sum,HCQ(gi),&t);
1630: sum = t;
1631: g->body[i] = nd_remove_head(gi);
1632: }
1633: }
1634: }
1.34 noro 1635: if ( j < 0 ) return -1;
1.26 noro 1636: else if ( sum ) {
1637: HCQ(gj) = sum;
1.1 noro 1638: return j;
1.31 noro 1639: } else
1.1 noro 1640: g->body[j] = nd_remove_head(gj);
1641: }
1642: }
1643:
1.25 noro 1644: ND normalize_pbucket(int mod,PGeoBucket g)
1.1 noro 1645: {
1.31 noro 1646: int i;
1.1 noro 1647: ND r,t;
1648:
1649: r = 0;
1.28 noro 1650: for ( i = 0; i <= g->m; i++ ) {
1.31 noro 1651: r = nd_add(mod,r,g->body[i]);
1.28 noro 1652: g->body[i] = 0;
1653: }
1654: g->m = -1;
1.1 noro 1655: return r;
1656: }
1657:
1.27 noro 1658: /* return value = 0 => input is not a GB */
1659:
1660: NODE nd_gb(int m,int checkonly)
1.1 noro 1661: {
1662: int i,nh,sugar,stat;
1.23 noro 1663: NODE r,g,t;
1.1 noro 1664: ND_pairs d;
1665: ND_pairs l;
1666: ND h,nf;
1667:
1.23 noro 1668: g = 0; d = 0;
1669: for ( i = 0; i < nd_psn; i++ ) {
1.1 noro 1670: d = update_pairs(d,g,i);
1671: g = update_base(g,i);
1672: }
1673: sugar = 0;
1674: while ( d ) {
1675: again:
1676: l = nd_minp(d,&d);
1.14 noro 1677: if ( SG(l) != sugar ) {
1678: sugar = SG(l);
1.1 noro 1679: fprintf(asir_out,"%d",sugar);
1680: }
1.53 noro 1681: stat = nd_sp(m,0,l,&h);
1.1 noro 1682: if ( !stat ) {
1683: NEXT(l) = d; d = l;
1.20 noro 1684: d = nd_reconstruct(m,0,d);
1.1 noro 1685: goto again;
1686: }
1.41 noro 1687: #if USE_GEOBUCKET
1.53 noro 1688: stat = m?nd_nf_pbucket(m,h,nd_ps,!Top,&nf):nd_nf(m,h,nd_ps,!Top,&nf);
1.41 noro 1689: #else
1.53 noro 1690: stat = nd_nf(m,h,nd_ps,!Top,&nf);
1.41 noro 1691: #endif
1.1 noro 1692: if ( !stat ) {
1693: NEXT(l) = d; d = l;
1.20 noro 1694: d = nd_reconstruct(m,0,d);
1.1 noro 1695: goto again;
1696: } else if ( nf ) {
1.27 noro 1697: if ( checkonly ) return 0;
1.1 noro 1698: printf("+"); fflush(stdout);
1.53 noro 1699: nh = nd_newps(m,nf,0);
1.1 noro 1700: d = update_pairs(d,g,nh);
1701: g = update_base(g,nh);
1702: FREENDP(l);
1703: } else {
1704: printf("."); fflush(stdout);
1705: FREENDP(l);
1706: }
1707: }
1.53 noro 1708: for ( t = g; t; t = NEXT(t) ) BDY(t) = (pointer)nd_ps[(int)BDY(t)];
1.1 noro 1709: return g;
1710: }
1711:
1.23 noro 1712: NODE nd_gb_trace(int m)
1.20 noro 1713: {
1714: int i,nh,sugar,stat;
1.23 noro 1715: NODE r,g,t;
1.20 noro 1716: ND_pairs d;
1717: ND_pairs l;
1718: ND h,nf,nfq;
1719:
1.23 noro 1720: g = 0; d = 0;
1721: for ( i = 0; i < nd_psn; i++ ) {
1.20 noro 1722: d = update_pairs(d,g,i);
1723: g = update_base(g,i);
1724: }
1725: sugar = 0;
1726: while ( d ) {
1727: again:
1728: l = nd_minp(d,&d);
1729: if ( SG(l) != sugar ) {
1730: sugar = SG(l);
1731: fprintf(asir_out,"%d",sugar);
1732: }
1.53 noro 1733: stat = nd_sp(m,0,l,&h);
1.20 noro 1734: if ( !stat ) {
1735: NEXT(l) = d; d = l;
1736: d = nd_reconstruct(m,1,d);
1737: goto again;
1738: }
1.41 noro 1739: #if USE_GEOBUCKET
1.53 noro 1740: stat = nd_nf_pbucket(m,h,nd_ps,!Top,&nf);
1.41 noro 1741: #else
1.53 noro 1742: stat = nd_nf(m,h,nd_ps,!Top,&nf);
1.41 noro 1743: #endif
1.20 noro 1744: if ( !stat ) {
1745: NEXT(l) = d; d = l;
1746: d = nd_reconstruct(m,1,d);
1747: goto again;
1748: } else if ( nf ) {
1749: /* overflow does not occur */
1.53 noro 1750: nd_sp(0,1,l,&h);
1751: nd_nf(0,h,nd_ps_trace,!Top,&nfq);
1.20 noro 1752: if ( nfq ) {
1753: printf("+"); fflush(stdout);
1.39 noro 1754: nh = nd_newps(m,nf,nfq);
1.27 noro 1755: /* failure; m|HC(nfq) */
1.38 noro 1756: if ( nh < 0 ) return 0;
1.20 noro 1757: d = update_pairs(d,g,nh);
1758: g = update_base(g,nh);
1759: } else {
1760: printf("*"); fflush(stdout);
1761: }
1762: } else {
1763: printf("."); fflush(stdout);
1764: }
1765: FREENDP(l);
1766: }
1.23 noro 1767: for ( t = g; t; t = NEXT(t) )
1.53 noro 1768: BDY(t) = (pointer)nd_ps_trace[(int)BDY(t)];
1.20 noro 1769: return g;
1770: }
1771:
1.23 noro 1772: int ndv_compare(NDV *p1,NDV *p2)
1773: {
1.34 noro 1774: return DL_COMPARE(HDL(*p1),HDL(*p2));
1.23 noro 1775: }
1776:
1777: int ndv_compare_rev(NDV *p1,NDV *p2)
1778: {
1.34 noro 1779: return -DL_COMPARE(HDL(*p1),HDL(*p2));
1.23 noro 1780: }
1781:
1.61 noro 1782: NODE ndv_reduceall(int m,NODE f)
1.23 noro 1783: {
1784: int i,j,n,stat;
1785: NDV *w,*ps;
1786: ND nf,g;
1787: NODE t,a0,a;
1.45 noro 1788: struct oBaseSet base;
1.61 noro 1789: UINT **bound;
1.23 noro 1790:
1791: for ( n = 0, t = f; t; t = NEXT(t), n++ );
1792: ps = (NDV *)ALLOCA(n*sizeof(NDV));
1.61 noro 1793: bound = (UINT **)ALLOCA(n*sizeof(UINT *));
1.54 noro 1794: for ( i = 0, t = f; i < n; i++, t = NEXT(t) ) ps[i] = (NDV)BDY(t);
1.23 noro 1795: qsort(ps,n,sizeof(NDV),(int (*)(const void *,const void *))ndv_compare);
1.54 noro 1796: for ( i = 0; i < n; i++ ) bound[i] = ndv_compute_bound(ps[i]);
1.45 noro 1797: base.ps = (NDV *)ALLOCA((n-1)*sizeof(NDV));
1.61 noro 1798: base.bound = (UINT **)ALLOCA((n-1)*sizeof(UINT *));
1.45 noro 1799: base.len = n-1;
1.50 noro 1800: i = 0;
1801: while ( i < n ) {
1.45 noro 1802: for ( j = 0; j < i; j++ ) {
1803: base.ps[j] = ps[j]; base.bound[j] = bound[j];
1804: }
1805: for ( j = i+1; j < n; j++ ) {
1806: base.ps[j-1] = ps[j]; base.bound[j-1] = bound[j];
1807: }
1.23 noro 1808: g = ndvtond(m,ps[i]);
1.45 noro 1809: stat = nd_nf_direct(m,g,&base,1,&nf);
1.50 noro 1810: if ( !stat )
1.23 noro 1811: nd_reconstruct_direct(m,ps,n);
1812: else if ( !nf ) {
1813: printf("."); fflush(stdout);
1814: ndv_free(ps[i]);
1.50 noro 1815: for ( j = i+1; j < n; j++ ) {
1816: ps[j-1] = ps[j]; bound[j-1] = bound[j];
1817: }
1.23 noro 1818: n--;
1.50 noro 1819: base.len = n-1;
1.23 noro 1820: } else {
1821: printf("."); fflush(stdout);
1822: ndv_free(ps[i]);
1.24 noro 1823: nd_removecont(m,nf);
1.23 noro 1824: ps[i] = ndtondv(m,nf);
1.45 noro 1825: bound[i] = ndv_compute_bound(ps[i]);
1.23 noro 1826: nd_free(nf);
1.50 noro 1827: i++;
1.23 noro 1828: }
1829: }
1.45 noro 1830: printf("\n");
1.23 noro 1831: for ( a0 = 0, i = 0; i < n; i++ ) {
1832: NEXTNODE(a0,a);
1833: BDY(a) = (pointer)ps[i];
1834: }
1835: NEXT(a) = 0;
1836: return a0;
1837: }
1838:
1.1 noro 1839: ND_pairs update_pairs( ND_pairs d, NODE /* of index */ g, int t)
1840: {
1841: ND_pairs d1,nd,cur,head,prev,remove;
1842:
1843: if ( !g ) return d;
1844: d = crit_B(d,t);
1845: d1 = nd_newpairs(g,t);
1846: d1 = crit_M(d1);
1847: d1 = crit_F(d1);
1.55 noro 1848: if ( do_weyl )
1849: head = d1;
1850: else {
1851: prev = 0; cur = head = d1;
1852: while ( cur ) {
1853: if ( crit_2( cur->i1,cur->i2 ) ) {
1854: remove = cur;
1855: if ( !prev ) head = cur = NEXT(cur);
1856: else cur = NEXT(prev) = NEXT(cur);
1857: FREENDP(remove);
1858: } else {
1859: prev = cur; cur = NEXT(cur);
1860: }
1.1 noro 1861: }
1862: }
1863: if ( !d )
1864: return head;
1865: else {
1866: nd = d;
1.34 noro 1867: while ( NEXT(nd) ) nd = NEXT(nd);
1.1 noro 1868: NEXT(nd) = head;
1869: return d;
1870: }
1871: }
1872:
1873: ND_pairs nd_newpairs( NODE g, int t )
1874: {
1875: NODE h;
1.61 noro 1876: UINT *dl;
1.34 noro 1877: int ts,s;
1.1 noro 1878: ND_pairs r,r0;
1879:
1.20 noro 1880: dl = DL(nd_psh[t]);
1.34 noro 1881: ts = SG(nd_psh[t]) - TD(dl);
1.1 noro 1882: for ( r0 = 0, h = g; h; h = NEXT(h) ) {
1883: NEXTND_pairs(r0,r);
1884: r->i1 = (int)BDY(h);
1885: r->i2 = t;
1.20 noro 1886: ndl_lcm(DL(nd_psh[r->i1]),dl,r->lcm);
1.34 noro 1887: s = SG(nd_psh[r->i1])-TD(DL(nd_psh[r->i1]));
1888: SG(r) = MAX(s,ts) + TD(LCM(r));
1.1 noro 1889: }
1890: NEXT(r) = 0;
1891: return r0;
1892: }
1893:
1894: ND_pairs crit_B( ND_pairs d, int s )
1895: {
1896: ND_pairs cur,head,prev,remove;
1.61 noro 1897: UINT *t,*tl,*lcm;
1.1 noro 1898: int td,tdl;
1899:
1900: if ( !d ) return 0;
1.20 noro 1901: t = DL(nd_psh[s]);
1.1 noro 1902: prev = 0;
1903: head = cur = d;
1.61 noro 1904: lcm = (UINT *)ALLOCA(nd_wpd*sizeof(UINT));
1.1 noro 1905: while ( cur ) {
1906: tl = cur->lcm;
1907: if ( ndl_reducible(tl,t)
1.20 noro 1908: && (ndl_lcm(DL(nd_psh[cur->i1]),t,lcm),!ndl_equal(lcm,tl))
1909: && (ndl_lcm(DL(nd_psh[cur->i2]),t,lcm),!ndl_equal(lcm,tl)) ) {
1.1 noro 1910: remove = cur;
1911: if ( !prev ) {
1912: head = cur = NEXT(cur);
1913: } else {
1914: cur = NEXT(prev) = NEXT(cur);
1915: }
1916: FREENDP(remove);
1917: } else {
1.34 noro 1918: prev = cur; cur = NEXT(cur);
1.1 noro 1919: }
1920: }
1921: return head;
1922: }
1923:
1924: ND_pairs crit_M( ND_pairs d1 )
1925: {
1926: ND_pairs e,d2,d3,dd,p;
1.61 noro 1927: UINT *id,*jd;
1.1 noro 1928:
1929: for ( dd = 0, e = d1; e; e = d3 ) {
1930: if ( !(d2 = NEXT(e)) ) {
1931: NEXT(e) = dd;
1932: return e;
1933: }
1.34 noro 1934: id = LCM(e);
1.1 noro 1935: for ( d3 = 0; d2; d2 = p ) {
1.34 noro 1936: p = NEXT(d2);
1937: jd = LCM(d2);
1938: if ( ndl_equal(jd,id) )
1939: ;
1940: else if ( TD(jd) > TD(id) )
1.1 noro 1941: if ( ndl_reducible(jd,id) ) continue;
1942: else ;
1.34 noro 1943: else if ( ndl_reducible(id,jd) ) goto delit;
1.1 noro 1944: NEXT(d2) = d3;
1945: d3 = d2;
1946: }
1947: NEXT(e) = dd;
1948: dd = e;
1949: continue;
1950: /**/
1951: delit: NEXT(d2) = d3;
1952: d3 = d2;
1953: for ( ; p; p = d2 ) {
1954: d2 = NEXT(p);
1955: NEXT(p) = d3;
1956: d3 = p;
1957: }
1958: FREENDP(e);
1959: }
1960: return dd;
1961: }
1962:
1963: ND_pairs crit_F( ND_pairs d1 )
1964: {
1965: ND_pairs rest, head,remove;
1966: ND_pairs last, p, r, w;
1967: int s;
1968:
1969: for ( head = last = 0, p = d1; NEXT(p); ) {
1970: r = w = equivalent_pairs(p,&rest);
1.14 noro 1971: s = SG(r);
1.1 noro 1972: w = NEXT(w);
1973: while ( w ) {
1974: if ( crit_2(w->i1,w->i2) ) {
1975: r = w;
1976: w = NEXT(w);
1977: while ( w ) {
1978: remove = w;
1979: w = NEXT(w);
1980: FREENDP(remove);
1981: }
1982: break;
1.14 noro 1983: } else if ( SG(w) < s ) {
1.1 noro 1984: FREENDP(r);
1985: r = w;
1.14 noro 1986: s = SG(r);
1.1 noro 1987: w = NEXT(w);
1988: } else {
1989: remove = w;
1990: w = NEXT(w);
1991: FREENDP(remove);
1992: }
1993: }
1994: if ( last ) NEXT(last) = r;
1995: else head = r;
1996: NEXT(last = r) = 0;
1997: p = rest;
1998: if ( !p ) return head;
1999: }
2000: if ( !last ) return p;
2001: NEXT(last) = p;
2002: return head;
2003: }
2004:
2005: int crit_2( int dp1, int dp2 )
2006: {
1.20 noro 2007: return ndl_disjoint(DL(nd_psh[dp1]),DL(nd_psh[dp2]));
1.1 noro 2008: }
2009:
1.40 noro 2010: ND_pairs equivalent_pairs( ND_pairs d1, ND_pairs *prest )
1.1 noro 2011: {
2012: ND_pairs w,p,r,s;
1.61 noro 2013: UINT *d;
1.1 noro 2014:
2015: w = d1;
1.34 noro 2016: d = LCM(w);
1.1 noro 2017: s = NEXT(w);
2018: NEXT(w) = 0;
2019: for ( r = 0; s; s = p ) {
2020: p = NEXT(s);
1.34 noro 2021: if ( ndl_equal(d,LCM(s)) ) {
1.39 noro 2022: NEXT(s) = w; w = s;
1.1 noro 2023: } else {
1.39 noro 2024: NEXT(s) = r; r = s;
1.1 noro 2025: }
2026: }
2027: *prest = r;
2028: return w;
2029: }
2030:
2031: NODE update_base(NODE nd,int ndp)
2032: {
1.61 noro 2033: UINT *dl, *dln;
1.1 noro 2034: NODE last, p, head;
2035:
1.20 noro 2036: dl = DL(nd_psh[ndp]);
1.1 noro 2037: for ( head = last = 0, p = nd; p; ) {
1.20 noro 2038: dln = DL(nd_psh[(int)BDY(p)]);
1.34 noro 2039: if ( ndl_reducible( dln, dl ) ) {
1.1 noro 2040: p = NEXT(p);
2041: if ( last ) NEXT(last) = p;
2042: } else {
2043: if ( !last ) head = p;
2044: p = NEXT(last = p);
2045: }
2046: }
2047: head = append_one(head,ndp);
2048: return head;
2049: }
2050:
2051: ND_pairs nd_minp( ND_pairs d, ND_pairs *prest )
2052: {
2053: ND_pairs m,ml,p,l;
1.61 noro 2054: UINT *lcm;
1.33 noro 2055: int s,td,len,tlen,c,c1;
1.1 noro 2056:
2057: if ( !(p = NEXT(m = d)) ) {
2058: *prest = p;
2059: NEXT(m) = 0;
2060: return m;
2061: }
1.14 noro 2062: s = SG(m);
1.33 noro 2063: for ( ml = 0, l = m; p; p = NEXT(l = p) )
1.34 noro 2064: if ( (SG(p) < s)
2065: || ((SG(p) == s) && (DL_COMPARE(LCM(p),LCM(m)) < 0)) ) {
1.39 noro 2066: ml = l; m = p; s = SG(m);
1.1 noro 2067: }
2068: if ( !ml ) *prest = NEXT(m);
2069: else {
2070: NEXT(ml) = NEXT(m);
2071: *prest = d;
2072: }
2073: NEXT(m) = 0;
2074: return m;
2075: }
2076:
1.39 noro 2077: int nd_newps(int mod,ND a,ND aq)
1.1 noro 2078: {
1.3 noro 2079: int len;
1.13 noro 2080: RHist r;
1.20 noro 2081: NDV b;
1.3 noro 2082:
1.53 noro 2083: if ( aq ) {
2084: /* trace lifting */
2085: if ( !rem(NM(HCQ(aq)),mod) )
2086: return -1;
2087: }
1.1 noro 2088: if ( nd_psn == nd_pslen ) {
2089: nd_pslen *= 2;
1.11 noro 2090: nd_ps = (NDV *)REALLOC((char *)nd_ps,nd_pslen*sizeof(NDV));
1.53 noro 2091: nd_ps_trace = (NDV *)REALLOC((char *)nd_ps_trace,nd_pslen*sizeof(NDV));
1.13 noro 2092: nd_psh = (RHist *)REALLOC((char *)nd_psh,nd_pslen*sizeof(RHist));
1.61 noro 2093: nd_bound = (UINT **)
2094: REALLOC((char *)nd_bound,nd_pslen*sizeof(UINT *));
1.1 noro 2095: }
1.39 noro 2096: NEWRHist(r); nd_psh[nd_psn] = r;
1.53 noro 2097: nd_removecont(mod,a); nd_ps[nd_psn] = ndtondv(mod,a);
1.39 noro 2098: if ( aq ) {
1.53 noro 2099: nd_removecont(0,aq); nd_ps_trace[nd_psn] = ndtondv(0,aq);
2100: nd_bound[nd_psn] = ndv_compute_bound(nd_ps_trace[nd_psn]);
1.39 noro 2101: SG(r) = SG(aq); ndl_copy(HDL(aq),DL(r));
1.53 noro 2102: nd_free(a); nd_free(aq);
2103: } else {
2104: nd_bound[nd_psn] = ndv_compute_bound(nd_ps[nd_psn]);
2105: SG(r) = SG(a); ndl_copy(HDL(a),DL(r));
2106: nd_free(a);
1.39 noro 2107: }
1.1 noro 2108: return nd_psn++;
2109: }
2110:
1.61 noro 2111: void ndv_setup(int mod,int trace,NODE f)
1.1 noro 2112: {
1.5 noro 2113: int i,j,td,len,max;
1.1 noro 2114: NODE s,s0,f0;
1.61 noro 2115: UINT *d;
1.13 noro 2116: RHist r;
1.61 noro 2117: NDV a,am;
1.11 noro 2118:
2119: nd_found = 0; nd_notfirst = 0; nd_create = 0;
1.1 noro 2120:
2121: nd_psn = length(f); nd_pslen = 2*nd_psn;
1.11 noro 2122: nd_ps = (NDV *)MALLOC(nd_pslen*sizeof(NDV));
1.53 noro 2123: nd_ps_trace = (NDV *)MALLOC(nd_pslen*sizeof(NDV));
1.13 noro 2124: nd_psh = (RHist *)MALLOC(nd_pslen*sizeof(RHist));
1.61 noro 2125: nd_bound = (UINT **)MALLOC(nd_pslen*sizeof(UINT *));
1.57 noro 2126:
1.11 noro 2127: if ( !nd_red )
1.13 noro 2128: nd_red = (RHist *)MALLOC(REDTAB_LEN*sizeof(RHist));
2129: bzero(nd_red,REDTAB_LEN*sizeof(RHist));
1.1 noro 2130: nd_free_private_storage();
2131: for ( i = 0; i < nd_psn; i++, f = NEXT(f) ) {
1.39 noro 2132: if ( trace ) {
1.61 noro 2133: a = nd_ps_trace[i] = ndv_dup(0,(NDV)BDY(f));
2134: ndv_removecont(0,a);
2135: am = nd_ps[i] = ndv_dup(mod,a);
2136: ndv_mod(mod,am);
2137: ndv_removecont(mod,am);
2138: } else {
2139: a = nd_ps[i] = ndv_dup(mod,(NDV)BDY(f));
2140: if ( mod ) ndv_mod(mod,a);
2141: ndv_removecont(mod,a);
1.39 noro 2142: }
1.61 noro 2143: NEWRHist(r); SG(r) = HTD(a); ndl_copy(HDL(a),DL(r));
1.57 noro 2144: nd_bound[i] = ndv_compute_bound(a);
1.20 noro 2145: nd_psh[i] = r;
2146: }
2147: }
2148:
1.1 noro 2149: void nd_gr(LIST f,LIST v,int m,struct order_spec *ord,LIST *rp)
2150: {
1.61 noro 2151: VL tv,fv,vv,vc;
1.1 noro 2152: NODE fd,fd0,r,r0,t,x,s,xx;
1.61 noro 2153: int e,max,nvar;
2154: ND b;
1.1 noro 2155:
2156: get_vars((Obj)f,&fv); pltovl(v,&vv);
1.61 noro 2157: nvar = length(vv);
1.32 noro 2158: nd_init_ord(ord);
1.61 noro 2159: for ( t = BDY(f), max = 0; t; t = NEXT(t) )
2160: for ( tv = vv; tv; tv = NEXT(tv) ) {
2161: e = getdeg(tv->v,(P)BDY(t));
2162: max = MAX(e,max);
2163: }
2164: nd_setup_parameters(nvar,max);
1.1 noro 2165: for ( fd0 = 0, t = BDY(f); t; t = NEXT(t) ) {
1.61 noro 2166: b = (pointer)ptondv(CO,vv,(P)BDY(t));
2167: if ( b ) { NEXTNODE(fd0,fd); BDY(fd) = (pointer)b; }
1.1 noro 2168: }
2169: if ( fd0 ) NEXT(fd) = 0;
1.61 noro 2170: ndv_setup(m,0,fd0);
1.27 noro 2171: x = nd_gb(m,0);
1.61 noro 2172: x = ndv_reducebase(x);
2173: x = ndv_reduceall(m,x);
1.23 noro 2174: for ( r0 = 0, t = x; t; t = NEXT(t) ) {
1.1 noro 2175: NEXTNODE(r0,r);
1.61 noro 2176: BDY(r) = ndvtop(m,CO,vv,BDY(t));
1.20 noro 2177: }
2178: if ( r0 ) NEXT(r) = 0;
2179: MKLIST(*rp,r0);
2180: }
2181:
1.52 noro 2182: void nd_gr_trace(LIST f,LIST v,int trace,int homo,struct order_spec *ord,LIST *rp)
1.20 noro 2183: {
2184: struct order_spec ord1;
1.61 noro 2185: VL tv,fv,vv,vc;
1.27 noro 2186: NODE fd,fd0,in0,in,r,r0,t,s,cand;
1.61 noro 2187: int m,nocheck,nvar,mindex,e,max;
2188: NDV c;
2189: NMV a;
1.27 noro 2190: P p;
1.61 noro 2191: EPOS oepos;
2192: int obpe,oadv,wmax,i,len,cbpe;
1.20 noro 2193:
2194: get_vars((Obj)f,&fv); pltovl(v,&vv);
1.52 noro 2195: nvar = length(vv);
2196: nocheck = 0;
2197: mindex = 0;
2198:
2199: /* setup modulus */
2200: if ( trace < 0 ) {
2201: trace = -trace;
2202: nocheck = 1;
2203: }
2204: m = trace > 1 ? trace : get_lprime(mindex);
1.61 noro 2205: for ( t = BDY(f), max = 0; t; t = NEXT(t) )
2206: for ( tv = vv; tv; tv = NEXT(tv) ) {
2207: e = getdeg(tv->v,(P)BDY(t));
2208: max = MAX(e,max);
1.23 noro 2209: }
1.61 noro 2210: nd_init_ord(ord);
2211: nd_setup_parameters(nvar,max);
2212: obpe = nd_bpe; oadv = nmv_adv; oepos = nd_epos;
2213: for ( in0 = 0, fd0 = 0, t = BDY(f); t; t = NEXT(t) ) {
2214: c = ptondv(CO,vv,(P)BDY(t));
2215: if ( c ) {
2216: NEXTNODE(in0,in); BDY(in) = (pointer)c;
2217: NEXTNODE(fd0,fd); BDY(fd) = (pointer)ndv_dup(0,c);
1.23 noro 2218: }
1.61 noro 2219: }
2220: if ( in0 ) NEXT(in) = 0;
2221: if ( fd0 ) NEXT(fd) = 0;
2222: if ( homo ) {
2223: for ( t = in0, wmax = 0; t; t = NEXT(t) ) {
2224: c = (NDV)BDY(t); len = LEN(c);
2225: for ( a = BDY(c), i = 0; i < len; i++, NMV_ADV(a) )
2226: wmax = MAX(TD(DL(a)),wmax);
2227: }
2228: homogenize_order(ord,nvar,&ord1);
2229: nd_init_ord(&ord1);
2230: nd_setup_parameters(nvar+1,wmax);
2231: for ( t = fd0; t; t = NEXT(t) )
2232: ndv_homogenize((NDV)BDY(t),obpe,oadv,oepos);
1.27 noro 2233: }
1.52 noro 2234: while ( 1 ) {
1.61 noro 2235: ndv_setup(m,1,fd0);
1.27 noro 2236: cand = nd_gb_trace(m);
1.52 noro 2237: if ( !cand ) {
2238: /* failure */
1.61 noro 2239: if ( trace > 1 ) { *rp = 0; return; }
2240: else m = get_lprime(++mindex);
1.52 noro 2241: continue;
2242: }
1.27 noro 2243: if ( homo ) {
2244: /* dehomogenization */
1.61 noro 2245: for ( t = cand; t; t = NEXT(t) ) ndv_dehomogenize((NDV)BDY(t),ord);
1.45 noro 2246: nd_init_ord(ord);
1.61 noro 2247: nd_setup_parameters(nvar,0);
1.27 noro 2248: }
1.61 noro 2249: cand = ndv_reducebase(cand);
2250: cand = ndv_reduceall(0,cand);
2251: if ( nocheck )
2252: break;
2253: cbpe = nd_bpe;
2254: if ( ndv_check_candidate(in0,obpe,oadv,oepos,cand) )
1.52 noro 2255: /* success */
2256: break;
2257: else if ( trace > 1 ) {
2258: /* failure */
2259: *rp = 0; return;
1.61 noro 2260: } else {
1.52 noro 2261: /* try the next modulus */
2262: m = get_lprime(++mindex);
1.61 noro 2263: /* reset the parameters */
2264: if ( homo ) {
2265: nd_init_ord(&ord1);
2266: nd_setup_parameters(nvar+1,wmax);
2267: } else {
2268: nd_init_ord(ord);
2269: nd_setup_parameters(nvar,max);
2270: }
2271: }
1.52 noro 2272: }
1.27 noro 2273: /* dp->p */
1.61 noro 2274: nd_bpe = cbpe;
2275: nd_setup_parameters(0,0);
2276: for ( r = cand; r; r = NEXT(r) ) BDY(r) = (pointer)ndvtop(0,CO,vv,BDY(r));
1.27 noro 2277: MKLIST(*rp,cand);
1.1 noro 2278: }
2279:
1.61 noro 2280: void dltondl(int n,DL dl,UINT *r)
1.1 noro 2281: {
1.61 noro 2282: UINT *d;
1.57 noro 2283: int i,j,l,s,ord_l;
1.43 noro 2284: struct order_pair *op;
1.1 noro 2285:
2286: d = dl->d;
1.41 noro 2287: for ( i = 0; i < nd_wpd; i++ ) r[i] = 0;
1.43 noro 2288: if ( nd_blockmask ) {
2289: l = nd_blockmask->n;
2290: op = nd_blockmask->order_pair;
2291: for ( j = 0, s = 0; j < l; j++ ) {
2292: ord_l = op[j].length;
1.57 noro 2293: for ( i = 0; i < ord_l; i++, s++ ) PUT_EXP(r,s,d[s]);
1.43 noro 2294: }
2295: TD(r) = ndl_weight(r);
1.61 noro 2296: ndl_weight_mask(r);
1.43 noro 2297: } else {
1.56 noro 2298: for ( i = 0; i < n; i++ ) PUT_EXP(r,i,d[i]);
1.43 noro 2299: TD(r) = ndl_weight(r);
2300: }
1.1 noro 2301: }
2302:
1.61 noro 2303: DL ndltodl(int n,UINT *ndl)
1.1 noro 2304: {
2305: DL dl;
2306: int *d;
1.57 noro 2307: int i,j,l,s,ord_l;
1.43 noro 2308: struct order_pair *op;
1.1 noro 2309:
2310: NEWDL(dl,n);
1.34 noro 2311: dl->td = TD(ndl);
1.1 noro 2312: d = dl->d;
1.43 noro 2313: if ( nd_blockmask ) {
2314: l = nd_blockmask->n;
2315: op = nd_blockmask->order_pair;
2316: for ( j = 0, s = 0; j < l; j++ ) {
2317: ord_l = op[j].length;
1.57 noro 2318: for ( i = 0; i < ord_l; i++, s++ ) d[s] = GET_EXP(ndl,s);
1.43 noro 2319: }
2320: } else {
1.56 noro 2321: for ( i = 0; i < n; i++ ) d[i] = GET_EXP(ndl,i);
1.43 noro 2322: }
1.1 noro 2323: return dl;
2324: }
2325:
1.61 noro 2326: void ndl_print(UINT *dl)
1.1 noro 2327: {
2328: int n;
1.57 noro 2329: int i,j,l,ord_l,s,s0;
1.43 noro 2330: struct order_pair *op;
1.1 noro 2331:
2332: n = nd_nvar;
2333: printf("<<");
1.43 noro 2334: if ( nd_blockmask ) {
2335: l = nd_blockmask->n;
2336: op = nd_blockmask->order_pair;
2337: for ( j = 0, s = s0 = 0; j < l; j++ ) {
2338: ord_l = op[j].length;
1.57 noro 2339: for ( i = 0; i < ord_l; i++, s++ )
2340: printf(s==n-1?"%d":"%d,",GET_EXP(dl,s));
1.43 noro 2341: }
2342: } else {
1.56 noro 2343: for ( i = 0; i < n; i++ ) printf(i==n-1?"%d":"%d,",GET_EXP(dl,i));
1.43 noro 2344: }
1.1 noro 2345: printf(">>");
2346: }
2347:
2348: void nd_print(ND p)
2349: {
2350: NM m;
2351:
2352: if ( !p )
2353: printf("0\n");
2354: else {
2355: for ( m = BDY(p); m; m = NEXT(m) ) {
1.14 noro 2356: printf("+%d*",CM(m));
2357: ndl_print(DL(m));
1.1 noro 2358: }
2359: printf("\n");
2360: }
2361: }
2362:
1.16 noro 2363: void nd_print_q(ND p)
2364: {
2365: NM m;
2366:
2367: if ( !p )
2368: printf("0\n");
2369: else {
2370: for ( m = BDY(p); m; m = NEXT(m) ) {
2371: printf("+");
2372: printexpr(CO,CQ(m));
2373: printf("*");
2374: ndl_print(DL(m));
2375: }
2376: printf("\n");
2377: }
2378: }
2379:
1.1 noro 2380: void ndp_print(ND_pairs d)
2381: {
2382: ND_pairs t;
2383:
1.34 noro 2384: for ( t = d; t; t = NEXT(t) ) printf("%d,%d ",t->i1,t->i2);
1.1 noro 2385: printf("\n");
2386: }
2387:
1.20 noro 2388: void nd_removecont(int mod,ND p)
1.16 noro 2389: {
2390: int i,n;
2391: Q *w;
2392: Q dvr,t;
2393: NM m;
1.21 noro 2394: struct oVECT v;
2395: N q,r;
1.16 noro 2396:
1.34 noro 2397: if ( mod ) nd_mul_c(mod,p,invm(HCM(p),mod));
1.20 noro 2398: else {
2399: for ( m = BDY(p), n = 0; m; m = NEXT(m), n++ );
2400: w = (Q *)ALLOCA(n*sizeof(Q));
1.21 noro 2401: v.len = n;
2402: v.body = (pointer *)w;
1.34 noro 2403: for ( m = BDY(p), i = 0; i < n; m = NEXT(m), i++ ) w[i] = CQ(m);
1.21 noro 2404: removecont_array(w,n);
2405: for ( m = BDY(p), i = 0; i < n; m = NEXT(m), i++ ) CQ(m) = w[i];
1.16 noro 2406: }
2407: }
2408:
1.21 noro 2409: void nd_removecont2(ND p1,ND p2)
2410: {
2411: int i,n1,n2,n;
2412: Q *w;
2413: Q dvr,t;
2414: NM m;
2415: struct oVECT v;
2416: N q,r;
2417:
2418: if ( !p1 ) {
2419: nd_removecont(0,p2); return;
2420: } else if ( !p2 ) {
2421: nd_removecont(0,p1); return;
2422: }
2423: n1 = nd_length(p1);
2424: n2 = nd_length(p2);
2425: n = n1+n2;
2426: w = (Q *)ALLOCA(n*sizeof(Q));
2427: v.len = n;
2428: v.body = (pointer *)w;
1.34 noro 2429: for ( m = BDY(p1), i = 0; i < n1; m = NEXT(m), i++ ) w[i] = CQ(m);
2430: for ( m = BDY(p2); i < n; m = NEXT(m), i++ ) w[i] = CQ(m);
1.21 noro 2431: removecont_array(w,n);
2432: for ( m = BDY(p1), i = 0; i < n1; m = NEXT(m), i++ ) CQ(m) = w[i];
2433: for ( m = BDY(p2); i < n; m = NEXT(m), i++ ) CQ(m) = w[i];
2434: }
2435:
1.20 noro 2436: void ndv_removecont(int mod,NDV p)
1.16 noro 2437: {
2438: int i,len;
2439: Q *w;
2440: Q dvr,t;
2441: NMV m;
2442:
1.20 noro 2443: if ( mod )
2444: ndv_mul_c(mod,p,invm(HCM(p),mod));
2445: else {
2446: len = p->len;
2447: w = (Q *)ALLOCA(len*sizeof(Q));
1.34 noro 2448: for ( m = BDY(p), i = 0; i < len; NMV_ADV(m), i++ ) w[i] = CQ(m);
1.20 noro 2449: sortbynm(w,len);
2450: qltozl(w,len,&dvr);
2451: for ( m = BDY(p), i = 0; i < len; NMV_ADV(m), i++ ) {
2452: divq(CQ(m),dvr,&t); CQ(m) = t;
2453: }
1.16 noro 2454: }
1.21 noro 2455: }
2456:
1.61 noro 2457: void ndv_homogenize(NDV p,int obpe,int oadv,EPOS oepos)
2458: {
2459: int len,i,max;
2460: NMV m,mr0,mr,t;
2461:
2462: len = p->len;
2463: for ( m = BDY(p), i = 0, max = 0; i < len; NMV_OADV(m), i++ )
2464: max = MAX(max,TD(DL(m)));
2465: mr0 = nmv_adv>oadv?(NMV)REALLOC(BDY(p),len*nmv_adv):BDY(p);
2466: m = (NMV)((char *)mr0+(len-1)*oadv);
2467: mr = (NMV)((char *)mr0+(len-1)*nmv_adv);
2468: t = (NMV)ALLOCA(nmv_adv);
2469: for ( i = 0; i < len; i++, NMV_OPREV(m), NMV_PREV(mr) ) {
2470: ndl_homogenize(DL(m),DL(t),obpe,oepos,max);
2471: CQ(mr) = CQ(m);
2472: ndl_copy(DL(t),DL(mr));
2473: }
2474: NV(p)++;
2475: BDY(p) = mr0;
2476: }
2477:
1.45 noro 2478: void ndv_dehomogenize(NDV p,struct order_spec *ord)
1.23 noro 2479: {
1.45 noro 2480: int i,j,adj,len,newnvar,newwpd,newadv,newexporigin;
1.23 noro 2481: Q *w;
2482: Q dvr,t;
2483: NMV m,r;
2484:
2485: len = p->len;
2486: newnvar = nd_nvar-1;
1.48 noro 2487: newexporigin = nd_get_exporigin(ord);
1.45 noro 2488: newwpd = newnvar/nd_epw+(newnvar%nd_epw?1:0)+newexporigin;
1.23 noro 2489: for ( m = BDY(p), i = 0; i < len; NMV_ADV(m), i++ )
1.34 noro 2490: ndl_dehomogenize(DL(m));
1.23 noro 2491: if ( newwpd != nd_wpd ) {
1.61 noro 2492: newadv = sizeof(struct oNMV)+(newwpd-1)*sizeof(UINT);
2493: for ( m = r = BDY(p), i = 0; i < len; NMV_ADV(m), NDV_NADV(r), i++ ) {
1.45 noro 2494: CQ(r) = CQ(m);
2495: for ( j = 0; j < newexporigin; j++ ) DL(r)[j] = DL(m)[j];
2496: adj = nd_exporigin-newexporigin;
2497: for ( ; j < newwpd; j++ ) DL(r)[j] = DL(m)[j+adj];
1.23 noro 2498: }
2499: }
2500: NV(p)--;
2501: }
2502:
1.21 noro 2503: void removecont_array(Q *c,int n)
2504: {
2505: struct oVECT v;
2506: Q d0,d1,a,u,u1,gcd;
2507: int i;
2508: N qn,rn,gn;
2509: Q *q,*r;
2510:
2511: q = (Q *)ALLOCA(n*sizeof(Q));
2512: r = (Q *)ALLOCA(n*sizeof(Q));
2513: v.id = O_VECT; v.len = n; v.body = (pointer *)c;
2514: igcdv_estimate(&v,&d0);
2515: for ( i = 0; i < n; i++ ) {
2516: divn(NM(c[i]),NM(d0),&qn,&rn);
2517: NTOQ(qn,SGN(c[i])*SGN(d0),q[i]);
2518: NTOQ(rn,SGN(c[i]),r[i]);
2519: }
1.34 noro 2520: for ( i = 0; i < n; i++ ) if ( r[i] ) break;
1.21 noro 2521: if ( i < n ) {
2522: v.id = O_VECT; v.len = n; v.body = (pointer *)r;
2523: igcdv(&v,&d1);
2524: gcdn(NM(d0),NM(d1),&gn); NTOQ(gn,1,gcd);
2525: divsn(NM(d0),gn,&qn); NTOQ(qn,1,a);
2526: for ( i = 0; i < n; i++ ) {
2527: mulq(a,q[i],&u);
2528: if ( r[i] ) {
2529: divsn(NM(r[i]),gn,&qn); NTOQ(qn,SGN(r[i]),u1);
2530: addq(u,u1,&q[i]);
2531: } else
2532: q[i] = u;
2533: }
2534: }
1.34 noro 2535: for ( i = 0; i < n; i++ ) c[i] = q[i];
1.16 noro 2536: }
2537:
1.19 noro 2538: void nd_mul_c(int mod,ND p,int mul)
1.1 noro 2539: {
2540: NM m;
2541: int c,c1;
2542:
1.34 noro 2543: if ( !p ) return;
1.1 noro 2544: for ( m = BDY(p); m; m = NEXT(m) ) {
1.14 noro 2545: c1 = CM(m);
1.19 noro 2546: DMAR(c1,mul,0,mod,c);
1.14 noro 2547: CM(m) = c;
1.1 noro 2548: }
2549: }
2550:
1.16 noro 2551: void nd_mul_c_q(ND p,Q mul)
2552: {
2553: NM m;
2554: Q c;
2555:
1.34 noro 2556: if ( !p ) return;
1.16 noro 2557: for ( m = BDY(p); m; m = NEXT(m) ) {
2558: mulq(CQ(m),mul,&c); CQ(m) = c;
2559: }
2560: }
2561:
1.61 noro 2562: void nd_mul_c_p(VL vl,ND p,P mul)
2563: {
2564: NM m;
2565: P c;
2566:
2567: if ( !p ) return;
2568: for ( m = BDY(p); m; m = NEXT(m) ) {
2569: mulp(vl,CP(m),mul,&c); CP(m) = c;
2570: }
2571: }
2572:
1.1 noro 2573: void nd_free(ND p)
2574: {
2575: NM t,s;
2576:
1.34 noro 2577: if ( !p ) return;
1.1 noro 2578: t = BDY(p);
2579: while ( t ) {
2580: s = NEXT(t);
2581: FREENM(t);
2582: t = s;
2583: }
2584: FREEND(p);
2585: }
2586:
1.23 noro 2587: void ndv_free(NDV p)
2588: {
2589: GC_free(BDY(p));
2590: }
2591:
1.61 noro 2592: void nd_append_red(UINT *d,int i)
1.1 noro 2593: {
1.13 noro 2594: RHist m,m0;
1.1 noro 2595: int h;
2596:
1.13 noro 2597: NEWRHist(m);
1.34 noro 2598: h = ndl_hash_value(d);
1.13 noro 2599: m->index = i;
1.14 noro 2600: ndl_copy(d,DL(m));
1.1 noro 2601: NEXT(m) = nd_red[h];
2602: nd_red[h] = m;
2603: }
2604:
1.61 noro 2605: UINT *ndv_compute_bound(NDV p)
1.1 noro 2606: {
1.61 noro 2607: UINT *d1,*d2,*t;
2608: UINT u;
1.57 noro 2609: int i,j,k,l,len,ind;
1.45 noro 2610: NMV m;
1.1 noro 2611:
2612: if ( !p )
2613: return 0;
1.61 noro 2614: d1 = (UINT *)ALLOCA(nd_wpd*sizeof(UINT));
2615: d2 = (UINT *)ALLOCA(nd_wpd*sizeof(UINT));
1.45 noro 2616: len = LEN(p);
2617: m = BDY(p); ndl_copy(DL(m),d1); NMV_ADV(m);
2618: for ( i = 1; i < len; i++, NMV_ADV(m) ) {
1.14 noro 2619: ndl_lcm(DL(m),d1,d2);
1.1 noro 2620: t = d1; d1 = d2; d2 = t;
2621: }
1.12 noro 2622: l = nd_nvar+31;
1.61 noro 2623: t = (UINT *)MALLOC_ATOMIC(l*sizeof(UINT));
1.57 noro 2624: for ( i = nd_exporigin, ind = 0; i < nd_wpd; i++ ) {
2625: u = d1[i];
2626: k = (nd_epw-1)*nd_bpe;
2627: for ( j = 0; j < nd_epw; j++, k -= nd_bpe, ind++ )
2628: t[ind] = (u>>k)&nd_mask0;
2629: }
2630: for ( ; ind < l; ind++ ) t[ind] = 0;
1.1 noro 2631: return t;
2632: }
2633:
1.48 noro 2634: int nd_get_exporigin(struct order_spec *ord)
2635: {
1.51 noro 2636: switch ( ord->id ) {
1.41 noro 2637: case 0:
1.48 noro 2638: return 1;
1.41 noro 2639: case 1:
2640: /* block order */
1.43 noro 2641: /* d[0]:weight d[1]:w0,...,d[nd_exporigin-1]:w(n-1) */
1.48 noro 2642: return ord->ord.block.length+1;
1.41 noro 2643: case 2:
1.52 noro 2644: error("nd_get_exporigin : matrix order is not supported yet.");
1.41 noro 2645: }
1.48 noro 2646: }
2647:
1.61 noro 2648: void nd_setup_parameters(int nvar,int max) {
1.57 noro 2649: int i,j,n,elen,ord_o,ord_l,l,s;
2650: struct order_pair *op;
1.48 noro 2651:
1.61 noro 2652: /* if max == 0, don't touch nd_bpe */
2653: if ( max > 0 ) {
1.62 ! noro 2654: if ( max < 4 ) nd_bpe = 2;
! 2655: else if ( max < 8 ) nd_bpe = 3;
! 2656: else if ( max < 16 ) nd_bpe = 4;
1.61 noro 2657: else if ( max < 64 ) nd_bpe = 6;
2658: else if ( max < 256 ) nd_bpe = 8;
2659: else if ( max < 65536 ) nd_bpe = 16;
2660: else nd_bpe = 32;
2661: }
2662: /* nvar == 0, don't touch nd_nvar */
2663: if ( nvar > 0 ) nd_nvar = nvar;
2664:
2665: nd_epw = (sizeof(UINT)*8)/nd_bpe;
1.48 noro 2666: elen = nd_nvar/nd_epw+(nd_nvar%nd_epw?1:0);
2667:
2668: nd_exporigin = nd_get_exporigin(nd_ord);
1.43 noro 2669: nd_wpd = nd_exporigin+elen;
1.57 noro 2670:
1.1 noro 2671: if ( nd_bpe < 32 ) {
2672: nd_mask0 = (1<<nd_bpe)-1;
2673: } else {
2674: nd_mask0 = 0xffffffff;
2675: }
2676: bzero(nd_mask,sizeof(nd_mask));
2677: nd_mask1 = 0;
2678: for ( i = 0; i < nd_epw; i++ ) {
2679: nd_mask[nd_epw-i-1] = (nd_mask0<<(i*nd_bpe));
2680: nd_mask1 |= (1<<(nd_bpe-1))<<(i*nd_bpe);
2681: }
1.61 noro 2682: nm_adv = sizeof(struct oNM)+(nd_wpd-1)*sizeof(UINT);
2683: nmv_adv = sizeof(struct oNMV)+(nd_wpd-1)*sizeof(UINT);
1.57 noro 2684: nd_epos = nd_create_epos(nd_ord);
1.43 noro 2685: nd_blockmask = nd_create_blockmask(nd_ord);
1.1 noro 2686: }
2687:
1.20 noro 2688: ND_pairs nd_reconstruct(int mod,int trace,ND_pairs d)
1.1 noro 2689: {
1.37 noro 2690: int i,obpe,oadv,h;
1.13 noro 2691: NM prev_nm_free_list;
2692: RHist mr0,mr;
2693: RHist r;
1.37 noro 2694: RHist *old_red;
1.1 noro 2695: ND_pairs s0,s,t,prev_ndp_free_list;
1.43 noro 2696: EPOS oepos;
1.15 noro 2697:
1.1 noro 2698: obpe = nd_bpe;
1.11 noro 2699: oadv = nmv_adv;
1.43 noro 2700: oepos = nd_epos;
1.62 ! noro 2701: if ( obpe < 3 ) nd_bpe = 3;
! 2702: else if ( obpe < 4 ) nd_bpe = 4;
1.34 noro 2703: else if ( obpe < 6 ) nd_bpe = 6;
2704: else if ( obpe < 8 ) nd_bpe = 8;
2705: else if ( obpe < 16 ) nd_bpe = 16;
2706: else if ( obpe < 32 ) nd_bpe = 32;
2707: else error("nd_reconstruct : exponent too large");
1.5 noro 2708:
1.61 noro 2709: nd_setup_parameters(0,0);
1.1 noro 2710: prev_nm_free_list = _nm_free_list;
2711: prev_ndp_free_list = _ndp_free_list;
2712: _nm_free_list = 0;
2713: _ndp_free_list = 0;
1.53 noro 2714: for ( i = nd_psn-1; i >= 0; i-- ) ndv_realloc(nd_ps[i],obpe,oadv,oepos);
2715: if ( trace )
2716: for ( i = nd_psn-1; i >= 0; i-- )
2717: ndv_realloc(nd_ps_trace[i],obpe,oadv,oepos);
1.1 noro 2718: s0 = 0;
2719: for ( t = d; t; t = NEXT(t) ) {
2720: NEXTND_pairs(s0,s);
2721: s->i1 = t->i1;
2722: s->i2 = t->i2;
1.14 noro 2723: SG(s) = SG(t);
1.61 noro 2724: ndl_reconstruct(LCM(t),LCM(s),obpe,oepos);
1.1 noro 2725: }
1.37 noro 2726:
2727: old_red = (RHist *)ALLOCA(REDTAB_LEN*sizeof(RHist));
1.6 noro 2728: for ( i = 0; i < REDTAB_LEN; i++ ) {
1.37 noro 2729: old_red[i] = nd_red[i];
2730: nd_red[i] = 0;
2731: }
2732: for ( i = 0; i < REDTAB_LEN; i++ )
2733: for ( r = old_red[i]; r; r = NEXT(r) ) {
2734: NEWRHist(mr);
1.13 noro 2735: mr->index = r->index;
1.20 noro 2736: SG(mr) = SG(r);
1.61 noro 2737: ndl_reconstruct(DL(r),DL(mr),obpe,oepos);
1.37 noro 2738: h = ndl_hash_value(DL(mr));
2739: NEXT(mr) = nd_red[h];
2740: nd_red[h] = mr;
1.6 noro 2741: }
1.37 noro 2742: for ( i = 0; i < REDTAB_LEN; i++ ) old_red[i] = 0;
2743: old_red = 0;
1.11 noro 2744: for ( i = 0; i < nd_psn; i++ ) {
1.20 noro 2745: NEWRHist(r); SG(r) = SG(nd_psh[i]);
1.61 noro 2746: ndl_reconstruct(DL(nd_psh[i]),DL(r),obpe,oepos);
1.13 noro 2747: nd_psh[i] = r;
1.11 noro 2748: }
1.1 noro 2749: if ( s0 ) NEXT(s) = 0;
2750: prev_nm_free_list = 0;
2751: prev_ndp_free_list = 0;
2752: GC_gcollect();
2753: return s0;
2754: }
2755:
1.23 noro 2756: void nd_reconstruct_direct(int mod,NDV *ps,int len)
2757: {
1.37 noro 2758: int i,obpe,oadv,h;
1.61 noro 2759: UINT **bound;
1.23 noro 2760: NM prev_nm_free_list;
2761: RHist mr0,mr;
2762: RHist r;
1.37 noro 2763: RHist *old_red;
1.23 noro 2764: ND_pairs s0,s,t,prev_ndp_free_list;
1.43 noro 2765: EPOS oepos;
1.23 noro 2766:
2767: obpe = nd_bpe;
2768: oadv = nmv_adv;
1.43 noro 2769: oepos = nd_epos;
1.62 ! noro 2770: if ( obpe < 3 ) nd_bpe = 3;
! 2771: else if ( obpe < 4 ) nd_bpe = 4;
1.34 noro 2772: else if ( obpe < 6 ) nd_bpe = 6;
2773: else if ( obpe < 8 ) nd_bpe = 8;
2774: else if ( obpe < 16 ) nd_bpe = 16;
2775: else if ( obpe < 32 ) nd_bpe = 32;
2776: else error("nd_reconstruct_direct : exponent too large");
1.23 noro 2777:
1.61 noro 2778: nd_setup_parameters(0,0);
1.23 noro 2779: prev_nm_free_list = _nm_free_list;
2780: prev_ndp_free_list = _ndp_free_list;
1.34 noro 2781: _nm_free_list = 0; _ndp_free_list = 0;
1.43 noro 2782: for ( i = len-1; i >= 0; i-- ) ndv_realloc(ps[i],obpe,oadv,oepos);
1.23 noro 2783: prev_nm_free_list = 0;
2784: prev_ndp_free_list = 0;
2785: GC_gcollect();
2786: }
2787:
1.61 noro 2788: void ndl_reconstruct(UINT *d,UINT *r,int obpe,EPOS oepos)
1.1 noro 2789: {
1.57 noro 2790: int n,i,ei,oepw,omask0,j,s,ord_l,l;
1.43 noro 2791: struct order_pair *op;
1.1 noro 2792:
2793: n = nd_nvar;
1.61 noro 2794: oepw = (sizeof(UINT)*8)/obpe;
1.43 noro 2795: omask0 = (1<<obpe)-1;
1.34 noro 2796: TD(r) = TD(d);
1.41 noro 2797: for ( i = nd_exporigin; i < nd_wpd; i++ ) r[i] = 0;
1.43 noro 2798: if ( nd_blockmask ) {
2799: l = nd_blockmask->n;
2800: op = nd_blockmask->order_pair;
2801: for ( i = 1; i < nd_exporigin; i++ )
2802: r[i] = d[i];
2803: for ( j = 0, s = 0; j < l; j++ ) {
2804: ord_l = op[j].length;
1.57 noro 2805: for ( i = 0; i < ord_l; i++, s++ ) {
2806: ei = GET_EXP_OLD(d,s);
2807: PUT_EXP(r,s,ei);
2808: }
1.1 noro 2809: }
1.43 noro 2810: } else {
1.56 noro 2811: for ( i = 0; i < n; i++ ) {
2812: ei = GET_EXP_OLD(d,i);
2813: PUT_EXP(r,i,ei);
2814: }
1.1 noro 2815: }
2816: }
1.3 noro 2817:
1.6 noro 2818: ND nd_copy(ND p)
2819: {
2820: NM m,mr,mr0;
1.41 noro 2821: int c,n;
1.6 noro 2822: ND r;
2823:
2824: if ( !p )
2825: return 0;
2826: else {
2827: for ( mr0 = 0, m = BDY(p); m; m = NEXT(m) ) {
2828: NEXTNM(mr0,mr);
1.14 noro 2829: CM(mr) = CM(m);
2830: ndl_copy(DL(m),DL(mr));
1.6 noro 2831: }
2832: NEXT(mr) = 0;
1.31 noro 2833: MKND(NV(p),mr0,LEN(p),r);
1.14 noro 2834: SG(r) = SG(p);
1.6 noro 2835: return r;
2836: }
2837: }
2838:
1.53 noro 2839: int nd_sp(int mod,int trace,ND_pairs p,ND *rp)
1.11 noro 2840: {
2841: NM m;
2842: NDV p1,p2;
2843: ND t1,t2;
1.61 noro 2844: UINT *lcm;
1.31 noro 2845: int td;
1.11 noro 2846:
1.53 noro 2847: if ( trace ) {
2848: p1 = nd_ps_trace[p->i1]; p2 = nd_ps_trace[p->i2];
2849: } else {
1.20 noro 2850: p1 = nd_ps[p->i1]; p2 = nd_ps[p->i2];
2851: }
1.34 noro 2852: lcm = LCM(p);
1.11 noro 2853: NEWNM(m);
1.20 noro 2854: CQ(m) = HCQ(p2);
1.34 noro 2855: ndl_sub(lcm,HDL(p1),DL(m));
1.56 noro 2856: if ( ndl_check_bound2(p->i1,DL(m)) )
2857: return 0;
1.55 noro 2858: t1 = ndv_mul_nm(mod,m,p1);
1.34 noro 2859: if ( mod ) CM(m) = mod-HCM(p1);
2860: else chsgnq(HCQ(p1),&CQ(m));
2861: ndl_sub(lcm,HDL(p2),DL(m));
1.14 noro 2862: if ( ndl_check_bound2(p->i2,DL(m)) ) {
1.11 noro 2863: nd_free(t1);
2864: return 0;
2865: }
1.55 noro 2866: t2 = ndv_mul_nm(mod,m,p2);
1.31 noro 2867: *rp = nd_add(mod,t1,t2);
1.11 noro 2868: FREENM(m);
2869: return 1;
2870: }
2871:
1.19 noro 2872: void ndv_mul_c(int mod,NDV p,int mul)
1.11 noro 2873: {
2874: NMV m;
2875: int c,c1,len,i;
2876:
1.34 noro 2877: if ( !p ) return;
1.14 noro 2878: len = LEN(p);
1.11 noro 2879: for ( m = BDY(p), i = 0; i < len; i++, NMV_ADV(m) ) {
1.34 noro 2880: c1 = CM(m); DMAR(c1,mul,0,mod,c); CM(m) = c;
1.11 noro 2881: }
2882: }
2883:
1.16 noro 2884: void ndv_mul_c_q(NDV p,Q mul)
2885: {
2886: NMV m;
2887: Q c;
2888: int len,i;
2889:
1.34 noro 2890: if ( !p ) return;
1.16 noro 2891: len = LEN(p);
2892: for ( m = BDY(p), i = 0; i < len; i++, NMV_ADV(m) ) {
2893: mulq(CQ(m),mul,&c); CQ(m) = c;
2894: }
2895: }
2896:
1.55 noro 2897: ND weyl_ndv_mul_nm(int mod,NM m0,NDV p) {
2898: int n2,i,j,l,n,tlen;
1.61 noro 2899: UINT *d0;
1.55 noro 2900: NM *tab,*psum;
2901: ND s,r;
2902: NM t;
2903: NMV m1;
2904:
2905: if ( !p ) return 0;
2906: n = NV(p); n2 = n>>1;
2907: d0 = DL(m0);
2908: l = LEN(p);
2909: for ( i = 0, tlen = 1; i < n2; i++ ) tlen *= (GET_EXP(d0,n2+i)+1);
2910: tab = (NM *)ALLOCA(tlen*sizeof(NM));
2911: psum = (NM *)ALLOCA(tlen*sizeof(NM));
2912: for ( i = 0; i < tlen; i++ ) psum[i] = 0;
1.56 noro 2913: m1 = (NMV)(((char *)BDY(p))+nmv_adv*(l-1));
2914: for ( i = l-1; i >= 0; i--, NMV_PREV(m1) ) {
1.55 noro 2915: /* m0(NM) * m1(NMV) => tab(NM) */
1.56 noro 2916: weyl_mul_nm_nmv(n,mod,m0,m1,tab,tlen);
1.55 noro 2917: for ( j = 0; j < tlen; j++ ) {
2918: if ( tab[j] ) {
2919: NEXT(tab[j]) = psum[j]; psum[j] = tab[j];
2920: }
2921: }
2922: }
2923: for ( i = tlen-1, r = 0; i >= 0; i-- )
2924: if ( psum[i] ) {
2925: for ( j = 0, t = psum[i]; t; t = NEXT(t), j++ );
2926: MKND(n,psum[i],j,s);
2927: r = nd_add(mod,r,s);
2928: }
1.56 noro 2929: if ( r ) SG(r) = SG(p)+TD(d0);
2930: return r;
1.55 noro 2931: }
2932:
1.56 noro 2933: /* product of monomials */
2934: /* XXX block order is not handled correctly */
2935:
1.55 noro 2936: void weyl_mul_nm_nmv(int n,int mod,NM m0,NMV m1,NM *tab,int tlen)
2937: {
1.56 noro 2938: int i,n2,j,s,curlen,homo,h,a,b,k,l,u,min;
1.61 noro 2939: UINT *d0,*d1,*d,*dt,*ctab;
1.56 noro 2940: Q *ctab_q;
2941: Q q,q1;
1.61 noro 2942: UINT c0,c1,c;
1.55 noro 2943: NM *p;
2944: NM m,t;
2945:
2946: for ( i = 0; i < tlen; i++ ) tab[i] = 0;
2947: if ( !m0 || !m1 ) return;
2948: d0 = DL(m0); d1 = DL(m1); n2 = n>>1;
2949: NEWNM(m); d = DL(m);
1.56 noro 2950: if ( mod ) {
2951: c0 = CM(m0); c1 = CM(m1); DMAR(c0,c1,0,mod,c); CM(m) = c;
2952: } else
2953: mulq(CQ(m0),CQ(m1),&CQ(m));
1.55 noro 2954: for ( i = 0; i < nd_wpd; i++ ) d[i] = 0;
2955: homo = n&1 ? 1 : 0;
2956: if ( homo ) {
2957: /* offset of h-degree */
2958: h = GET_EXP(d0,n-1)+GET_EXP(d1,n-1);
2959: PUT_EXP(DL(m),n-1,h);
2960: TD(DL(m)) = h;
1.61 noro 2961: if ( nd_blockmask ) ndl_weight_mask(DL(m));
1.55 noro 2962: }
2963: tab[0] = m;
2964: NEWNM(m); d = DL(m);
1.57 noro 2965: for ( i = 0, curlen = 1; i < n2; i++ ) {
1.55 noro 2966: a = GET_EXP(d0,i); b = GET_EXP(d1,n2+i);
2967: k = GET_EXP(d0,n2+i); l = GET_EXP(d1,i);
2968: /* xi^a*(Di^k*xi^l)*Di^b */
2969: a += l; b += k;
1.56 noro 2970: s = MUL_WEIGHT(a,i)+MUL_WEIGHT(b,n2+i);
1.55 noro 2971: if ( !k || !l ) {
2972: for ( j = 0; j < curlen; j++ )
1.56 noro 2973: if ( t = tab[j] ) {
2974: dt = DL(t);
2975: PUT_EXP(dt,i,a); PUT_EXP(dt,n2+i,b); TD(dt) += s;
1.61 noro 2976: if ( nd_blockmask ) ndl_weight_mask(dt);
1.55 noro 2977: }
2978: curlen *= k+1;
2979: continue;
2980: }
2981: min = MIN(k,l);
1.56 noro 2982: if ( mod ) {
1.61 noro 2983: ctab = (UINT *)ALLOCA((min+1)*sizeof(UINT));
1.56 noro 2984: mkwcm(k,l,mod,ctab);
2985: } else {
2986: ctab_q = (Q *)ALLOCA((min+1)*sizeof(Q));
2987: mkwc(k,l,ctab_q);
2988: }
1.57 noro 2989: for ( j = min; j >= 0; j-- ) {
1.56 noro 2990: for ( u = 0; u < nd_wpd; u++ ) d[u] = 0;
1.55 noro 2991: PUT_EXP(d,i,a-j); PUT_EXP(d,n2+i,b-j);
1.56 noro 2992: h = MUL_WEIGHT(a-j,i)+MUL_WEIGHT(b-j,n2+i);
1.55 noro 2993: if ( homo ) {
2994: TD(d) = s;
1.56 noro 2995: PUT_EXP(d,n-1,s-h);
1.55 noro 2996: } else TD(d) = h;
1.61 noro 2997: if ( nd_blockmask ) ndl_weight_mask(d);
1.56 noro 2998: if ( mod ) c = ctab[j];
2999: else q = ctab_q[j];
1.57 noro 3000: p = tab+curlen*j;
3001: if ( j == 0 ) {
3002: for ( u = 0; u < curlen; u++, p++ ) {
3003: if ( tab[u] ) {
3004: ndl_addto(DL(tab[u]),d);
3005: if ( mod ) {
3006: c0 = CM(tab[u]); DMAR(c0,c,0,mod,c1); CM(tab[u]) = c1;
3007: } else {
3008: mulq(CQ(tab[u]),q,&q1); CQ(tab[u]) = q1;
3009: }
3010: }
1.56 noro 3011: }
1.57 noro 3012: } else {
3013: for ( u = 0; u < curlen; u++, p++ ) {
3014: if ( tab[u] ) {
3015: NEWNM(t);
3016: ndl_add(DL(tab[u]),d,DL(t));
3017: if ( mod ) {
3018: c0 = CM(tab[u]); DMAR(c0,c,0,mod,c1); CM(t) = c1;
3019: } else
3020: mulq(CQ(tab[u]),q,&CQ(t));
3021: *p = t;
3022: }
1.55 noro 3023: }
3024: }
3025: }
3026: curlen *= k+1;
3027: }
3028: FREENM(m);
3029: }
3030:
3031: ND ndv_mul_nm(int mod,NM m0,NDV p)
1.9 noro 3032: {
3033: NM mr,mr0;
3034: NMV m;
1.61 noro 3035: UINT *d,*dt,*dm;
1.9 noro 3036: int c,n,td,i,c1,c2,len;
1.16 noro 3037: Q q;
1.9 noro 3038: ND r;
3039:
1.34 noro 3040: if ( !p ) return 0;
1.55 noro 3041: else if ( do_weyl )
3042: return weyl_ndv_mul_nm(mod,m0,p);
1.9 noro 3043: else {
3044: n = NV(p); m = BDY(p);
1.34 noro 3045: d = DL(m0);
1.14 noro 3046: len = LEN(p);
1.9 noro 3047: mr0 = 0;
1.34 noro 3048: td = TD(d);
1.16 noro 3049: if ( mod ) {
3050: c = CM(m0);
3051: for ( i = 0; i < len; i++, NMV_ADV(m) ) {
3052: NEXTNM(mr0,mr);
3053: c1 = CM(m);
1.19 noro 3054: DMAR(c1,c,0,mod,c2);
1.16 noro 3055: CM(mr) = c2;
3056: ndl_add(DL(m),d,DL(mr));
3057: }
3058: } else {
3059: q = CQ(m0);
3060: for ( i = 0; i < len; i++, NMV_ADV(m) ) {
3061: NEXTNM(mr0,mr);
3062: mulq(CQ(m),q,&CQ(mr));
3063: ndl_add(DL(m),d,DL(mr));
3064: }
1.4 noro 3065: }
1.9 noro 3066: NEXT(mr) = 0;
1.31 noro 3067: MKND(NV(p),mr0,len,r);
1.34 noro 3068: SG(r) = SG(p) + TD(d);
1.9 noro 3069: return r;
1.4 noro 3070: }
3071: }
3072:
1.43 noro 3073: void ndv_realloc(NDV p,int obpe,int oadv,EPOS oepos)
1.11 noro 3074: {
1.13 noro 3075: NMV m,mr,mr0,t;
3076: int len,i,k;
1.11 noro 3077:
1.61 noro 3078: if ( !p ) return;
3079: m = BDY(p); len = LEN(p);
3080: mr0 = nmv_adv>oadv?(NMV)REALLOC(BDY(p),len*nmv_adv):BDY(p);
3081: m = (NMV)((char *)mr0+(len-1)*oadv);
3082: mr = (NMV)((char *)mr0+(len-1)*nmv_adv);
3083: t = (NMV)ALLOCA(nmv_adv);
3084: for ( i = 0; i < len; i++, NMV_OPREV(m), NMV_PREV(mr) ) {
3085: CQ(t) = CQ(m);
3086: for ( k = 0; k < nd_wpd; k++ ) DL(t)[k] = 0;
3087: ndl_reconstruct(DL(m),DL(t),obpe,oepos);
3088: CQ(mr) = CQ(t);
3089: ndl_copy(DL(t),DL(mr));
3090: }
3091: BDY(p) = mr0;
3092: }
3093:
3094: NDV ndv_dup_realloc(NDV p,int obpe,int oadv,EPOS oepos)
3095: {
3096: NMV m,mr,mr0;
3097: int len,i;
3098: NDV r;
1.11 noro 3099:
1.61 noro 3100: if ( !p ) return 0;
3101: m = BDY(p); len = LEN(p);
3102: mr0 = mr = (NMV)MALLOC(len*nmv_adv);
3103: for ( i = 0; i < len; i++, NMV_OADV(m), NMV_ADV(mr) ) {
3104: ndl_zero(DL(mr));
3105: ndl_reconstruct(DL(m),DL(mr),obpe,oepos);
3106: CQ(mr) = CQ(m);
1.11 noro 3107: }
1.61 noro 3108: MKNDV(NV(p),mr0,len,r);
3109: SG(r) = SG(p);
3110: return r;
1.11 noro 3111: }
3112:
1.61 noro 3113: /* duplicate p */
3114:
3115: NDV ndv_dup(int mod,NDV p)
1.3 noro 3116: {
3117: NDV d;
1.61 noro 3118: NMV t,m,m0;
1.3 noro 3119: int i,len;
3120:
1.34 noro 3121: if ( !p ) return 0;
1.31 noro 3122: len = LEN(p);
1.34 noro 3123: m0 = m = (NMV)(mod?MALLOC_ATOMIC(len*nmv_adv):MALLOC(len*nmv_adv));
1.61 noro 3124: for ( t = BDY(p), i = 0; i < len; i++, NMV_ADV(t), NMV_ADV(m) ) {
1.14 noro 3125: ndl_copy(DL(t),DL(m));
1.16 noro 3126: CQ(m) = CQ(t);
1.3 noro 3127: }
3128: MKNDV(NV(p),m0,len,d);
1.23 noro 3129: SG(d) = SG(p);
3130: return d;
3131: }
3132:
1.61 noro 3133: /* XXX if p->len == 0 then it represents 0 */
3134:
3135: void ndv_mod(int mod,NDV p)
3136: {
3137: NMV t,d;
3138: int r;
3139: int i,len,dlen;
3140:
3141: if ( !p ) return;
3142: len = LEN(p);
3143: dlen = 0;
3144: for ( t = d = BDY(p), i = 0; i < len; i++, NMV_ADV(t) ) {
3145: r = rem(NM(CQ(t)),mod);
3146: if ( r ) {
3147: if ( SGN(CQ(t)) < 0 )
3148: r = mod-r;
3149: CM(d) = r;
3150: ndl_copy(DL(t),DL(d));
3151: NMV_ADV(d);
3152: dlen++;
3153: }
3154: }
3155: LEN(p) = dlen;
3156: }
3157:
3158: NDV ptondv(VL vl,VL dvl,P p)
3159: {
3160: ND nd;
3161:
3162: nd = ptond(vl,dvl,p);
3163: return ndtondv(0,nd);
3164: }
3165:
3166: ND ptond(VL vl,VL dvl,P p)
1.23 noro 3167: {
1.61 noro 3168: int n,i,j,k,e;
3169: VL tvl;
3170: V v;
3171: DCP dc;
3172: DCP *w;
3173: ND r,s,t,u;
3174: P x;
3175: int c;
3176: UINT *d;
1.23 noro 3177: NM m,m0;
1.61 noro 3178:
3179: if ( !p )
3180: return 0;
3181: else if ( NUM(p) ) {
3182: NEWNM(m);
3183: ndl_zero(DL(m));
3184: CQ(m) = (Q)p;
3185: NEXT(m) = 0;
3186: MKND(nd_nvar,m,1,r);
3187: SG(r) = 0;
3188: return r;
3189: } else {
3190: for ( dc = DC(p), k = 0; dc; dc = NEXT(dc), k++ );
3191: w = (DCP *)ALLOCA(k*sizeof(DCP));
3192: for ( dc = DC(p), j = 0; j < k; dc = NEXT(dc), j++ ) w[j] = dc;
3193: for ( i = 0, tvl = dvl, v = VR(p);
3194: vl && tvl->v != v; tvl = NEXT(tvl), i++ );
3195: if ( !tvl ) {
3196: for ( j = k-1, s = 0, MKV(v,x); j >= 0; j-- ) {
3197: t = ptond(vl,dvl,COEF(w[j]));
3198: pwrp(vl,x,DEG(w[j]),&p);
3199: nd_mul_c_p(CO,t,p); s = nd_add(0,s,t);
3200: }
3201: return s;
3202: } else {
3203: NEWNM(m0); d = DL(m0);
3204: for ( j = k-1, s = 0; j >= 0; j-- ) {
3205: ndl_zero(d); e = QTOS(DEG(w[j])); PUT_EXP(d,i,e);
3206: TD(d) = MUL_WEIGHT(e,i);
3207: if ( nd_blockmask) ndl_weight_mask(d);
3208: t = ptond(vl,dvl,COEF(w[j]));
3209: for ( m = BDY(t); m; m = NEXT(m) )
3210: ndl_addto(DL(m),d);
3211: SG(t) += TD(d);
3212: s = nd_add(0,s,t);
3213: }
3214: FREENM(m0);
3215: return s;
3216: }
3217: }
3218: }
3219:
3220: P ndvtop(int mod,VL vl,VL dvl,NDV p)
3221: {
3222: VL tvl;
3223: int len,n,j,i,e;
3224: NMV m;
3225: Q q;
3226: P c;
3227: UINT *d;
3228: P s,r,u,t,w;
1.23 noro 3229:
1.34 noro 3230: if ( !p ) return 0;
1.61 noro 3231: else {
3232: len = LEN(p);
3233: n = NV(p);
3234: m = (NMV)(((char *)BDY(p))+nmv_adv*(len-1));
3235: for ( j = len-1, s = 0; j >= 0; j--, NMV_PREV(m) ) {
3236: if ( mod ) {
3237: STOQ(CM(m),q); c = (P)q;
3238: } else
3239: c = CP(m);
3240: d = DL(m);
3241: for ( i = 0, t = c, tvl = dvl; i < n; tvl = NEXT(tvl), i++ ) {
3242: MKV(tvl->v,r); e = GET_EXP(d,i); STOQ(e,q);
3243: pwrp(vl,r,q,&u); mulp(vl,t,u,&w); t = w;
3244: }
3245: addp(vl,s,t,&u); s = u;
3246: }
3247: return s;
1.23 noro 3248: }
1.3 noro 3249: }
3250:
1.61 noro 3251: NDV ndtondv(int mod,ND p)
1.11 noro 3252: {
3253: NDV d;
1.61 noro 3254: NMV m,m0;
3255: NM t;
3256: int i,len;
1.11 noro 3257:
1.34 noro 3258: if ( !p ) return 0;
1.61 noro 3259: len = LEN(p);
3260: m0 = m = (NMV)(mod?MALLOC_ATOMIC(len*nmv_adv):MALLOC(len*nmv_adv));
3261: for ( t = BDY(p), i = 0; t; t = NEXT(t), i++, NMV_ADV(m) ) {
3262: ndl_copy(DL(t),DL(m));
3263: CQ(m) = CQ(t);
1.11 noro 3264: }
1.61 noro 3265: MKNDV(NV(p),m0,len,d);
1.14 noro 3266: SG(d) = SG(p);
1.11 noro 3267: return d;
3268: }
3269:
1.61 noro 3270: ND ndvtond(int mod,NDV p)
1.11 noro 3271: {
1.61 noro 3272: ND d;
3273: NM m,m0;
1.11 noro 3274: NMV t;
1.61 noro 3275: int i,len;
1.11 noro 3276:
1.34 noro 3277: if ( !p ) return 0;
1.11 noro 3278: m0 = 0;
1.61 noro 3279: len = p->len;
3280: for ( t = BDY(p), i = 0; i < len; NMV_ADV(t), i++ ) {
3281: NEXTNM(m0,m);
3282: ndl_copy(DL(t),DL(m));
3283: CQ(m) = CQ(t);
1.11 noro 3284: }
3285: NEXT(m) = 0;
1.61 noro 3286: MKND(NV(p),m0,len,d);
1.14 noro 3287: SG(d) = SG(p);
1.11 noro 3288: return d;
3289: }
3290:
1.3 noro 3291: void ndv_print(NDV p)
3292: {
3293: NMV m;
3294: int i,len;
3295:
1.34 noro 3296: if ( !p ) printf("0\n");
1.3 noro 3297: else {
1.14 noro 3298: len = LEN(p);
1.3 noro 3299: for ( m = BDY(p), i = 0; i < len; i++, NMV_ADV(m) ) {
1.14 noro 3300: printf("+%d*",CM(m));
1.16 noro 3301: ndl_print(DL(m));
3302: }
3303: printf("\n");
3304: }
3305: }
3306:
3307: void ndv_print_q(NDV p)
3308: {
3309: NMV m;
3310: int i,len;
3311:
1.34 noro 3312: if ( !p ) printf("0\n");
1.16 noro 3313: else {
3314: len = LEN(p);
3315: for ( m = BDY(p), i = 0; i < len; i++, NMV_ADV(m) ) {
3316: printf("+");
3317: printexpr(CO,CQ(m));
3318: printf("*");
1.14 noro 3319: ndl_print(DL(m));
1.3 noro 3320: }
3321: printf("\n");
3322: }
1.25 noro 3323: }
3324:
1.61 noro 3325: NODE ndv_reducebase(NODE x)
1.27 noro 3326: {
3327: int len,i,j;
3328: NDV *w;
3329: NODE t,t0;
3330:
3331: len = length(x);
3332: w = (NDV *)ALLOCA(len*sizeof(NDV));
3333: for ( i = 0, t = x; i < len; i++, t = NEXT(t) ) w[i] = BDY(t);
3334: for ( i = 0; i < len; i++ ) {
3335: for ( j = 0; j < i; j++ ) {
3336: if ( w[i] && w[j] )
3337: if ( ndl_reducible(HDL(w[i]),HDL(w[j])) ) w[i] = 0;
3338: else if ( ndl_reducible(HDL(w[j]),HDL(w[i])) ) w[j] = 0;
3339: }
3340: }
3341: for ( i = len-1, t0 = 0; i >= 0; i-- ) {
3342: if ( w[i] ) { NEXTNODE(t0,t); BDY(t) = (pointer)w[i]; }
3343: }
3344: NEXT(t) = 0; x = t0;
3345: return x;
1.11 noro 3346: }
1.32 noro 3347:
1.43 noro 3348: /* XXX incomplete */
3349:
1.32 noro 3350: void nd_init_ord(struct order_spec *ord)
3351: {
1.43 noro 3352: switch ( ord->id ) {
1.32 noro 3353: case 0:
1.43 noro 3354: switch ( ord->ord.simple ) {
3355: case 0:
3356: nd_dcomp = 1;
3357: nd_isrlex = 1;
3358: break;
3359: case 1:
3360: nd_dcomp = 1;
3361: nd_isrlex = 0;
3362: break;
3363: case 2:
3364: nd_dcomp = 0;
3365: nd_isrlex = 0;
1.45 noro 3366: ndl_compare_function = ndl_lex_compare;
1.58 noro 3367: break;
3368: case 11:
3369: /* XXX */
3370: nd_dcomp = 0;
3371: nd_isrlex = 1;
3372: ndl_compare_function = ndl_ww_lex_compare;
1.43 noro 3373: break;
3374: default:
3375: error("nd_gr : unsupported order");
3376: }
1.32 noro 3377: break;
3378: case 1:
1.43 noro 3379: /* XXX */
3380: nd_dcomp = -1;
1.32 noro 3381: nd_isrlex = 0;
1.45 noro 3382: ndl_compare_function = ndl_block_compare;
1.34 noro 3383: break;
1.43 noro 3384: case 2:
3385: error("nd_init_ord : matrix order is not supported yet.");
1.32 noro 3386: break;
3387: }
1.41 noro 3388: nd_ord = ord;
1.32 noro 3389: }
3390:
1.43 noro 3391: BlockMask nd_create_blockmask(struct order_spec *ord)
3392: {
3393: int n,i,j,s,l;
1.61 noro 3394: UINT *t;
1.43 noro 3395: BlockMask bm;
3396:
3397: if ( !ord->id )
3398: return 0;
3399: n = ord->ord.block.length;
3400: bm = (BlockMask)MALLOC(sizeof(struct oBlockMask));
3401: bm->n = n;
3402: bm->order_pair = ord->ord.block.order_pair;
1.61 noro 3403: bm->mask = (UINT **)MALLOC(n*sizeof(UINT *));
1.43 noro 3404: for ( i = 0, s = 0; i < n; i++ ) {
1.61 noro 3405: bm->mask[i] = t = (UINT *)MALLOC_ATOMIC(nd_wpd*sizeof(UINT));
1.43 noro 3406: for ( j = 0; j < nd_wpd; j++ ) t[j] = 0;
3407: l = bm->order_pair[i].length;
3408: for ( j = 0; j < l; j++, s++ ) PUT_EXP(t,s,nd_mask0);
3409: }
3410: return bm;
1.57 noro 3411: }
3412:
3413: EPOS nd_create_epos(struct order_spec *ord)
3414: {
3415: int i,j,l,s,ord_l,ord_o;
3416: EPOS epos;
3417: struct order_pair *op;
3418:
3419: epos = (EPOS)MALLOC_ATOMIC(nd_nvar*sizeof(struct oEPOS));
3420: switch ( ord->id ) {
3421: case 0:
3422: if ( nd_isrlex ) {
3423: for ( i = 0; i < nd_nvar; i++ ) {
3424: epos[i].i = nd_exporigin + (nd_nvar-1-i)/nd_epw;
3425: epos[i].s = (nd_epw-((nd_nvar-1-i)%nd_epw)-1)*nd_bpe;
3426: }
3427: } else {
3428: for ( i = 0; i < nd_nvar; i++ ) {
3429: epos[i].i = nd_exporigin + i/nd_epw;
3430: epos[i].s = (nd_epw-(i%nd_epw)-1)*nd_bpe;
3431: }
3432: }
3433: break;
3434: case 1:
3435: /* block order */
3436: l = ord->ord.block.length;
3437: op = ord->ord.block.order_pair;
3438: for ( j = 0, s = 0; j < l; j++ ) {
3439: ord_o = op[j].order;
3440: ord_l = op[j].length;
3441: if ( !ord_o )
3442: for ( i = 0; i < ord_l; i++ ) {
3443: epos[s+i].i = nd_exporigin + (s+ord_l-i-1)/nd_epw;
3444: epos[s+i].s = (nd_epw-((s+ord_l-i-1)%nd_epw)-1)*nd_bpe;
3445: }
3446: else
3447: for ( i = 0; i < ord_l; i++ ) {
3448: epos[s+i].i = nd_exporigin + (s+i)/nd_epw;
3449: epos[s+i].s = (nd_epw-((s+i)%nd_epw)-1)*nd_bpe;
3450: }
3451: s += ord_l;
3452: }
3453: break;
3454: case 2:
3455: error("nd_create_epos : matrix order is not supported yet.");
3456: }
3457: return epos;
1.43 noro 3458: }
1.59 noro 3459:
3460: /* external interface */
3461:
3462: void nd_nf_p(P f,LIST g,LIST v,int m,struct order_spec *ord,P *rp)
3463: {
1.61 noro 3464: NODE t,in0,in;
1.59 noro 3465: ND nd,nf;
1.61 noro 3466: NDV ndv;
3467: VL vv,tv;
3468: int stat,nvar,max,e;
1.59 noro 3469:
3470: pltovl(v,&vv);
1.61 noro 3471: nvar = length(vv);
3472:
3473: /* get the degree bound */
3474: for ( t = BDY(g), max = 0; t; t = NEXT(t) )
3475: for ( tv = vv; tv; tv = NEXT(tv) ) {
3476: e = getdeg(tv->v,(P)BDY(t));
3477: max = MAX(e,max);
3478: }
3479: for ( tv = vv; tv; tv = NEXT(tv) ) {
3480: e = getdeg(tv->v,f);
3481: max = MAX(e,max);
3482: }
3483:
1.59 noro 3484: nd_init_ord(ord);
1.61 noro 3485: nd_setup_parameters(nvar,max);
3486:
3487: /* conversion to ndv */
3488: for ( in0 = 0, t = BDY(g); t; t = NEXT(t) ) {
3489: NEXTNODE(in0,in);
3490: BDY(in) = (pointer)ptondv(CO,vv,(P)BDY(t));
3491: }
3492: NEXTNODE(in0,in);
3493: BDY(in) = (pointer)ptondv(CO,vv,f);
3494: NEXT(in) = 0;
3495:
3496: ndv_setup(m,0,in0);
1.59 noro 3497: nd_psn--;
3498: nd_scale=2;
3499: while ( 1 ) {
3500: nd = (pointer)ndvtond(m,nd_ps[nd_psn]);
3501: stat = nd_nf(m,nd,nd_ps,1,&nf);
3502: if ( !stat ) {
3503: nd_psn++;
3504: nd_reconstruct(m,0,0);
3505: nd_psn--;
3506: } else
3507: break;
3508: }
1.61 noro 3509: *rp = ndvtop(m,CO,vv,ndtondv(m,nf));
1.59 noro 3510: }
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