| version 1.2, 2000/02/08 04:47:10 |
version 1.12, 2001/03/13 01:10:26 |
|
|
| /* $OpenXM: OpenXM_contrib2/asir2000/include/ca.h,v 1.1.1.1 1999/12/03 07:39:11 noro Exp $ */ |
/* |
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* Copyright (c) 1994-2000 FUJITSU LABORATORIES LIMITED |
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* All rights reserved. |
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* |
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* FUJITSU LABORATORIES LIMITED ("FLL") hereby grants you a limited, |
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* non-exclusive and royalty-free license to use, copy, modify and |
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* redistribute, solely for non-commercial and non-profit purposes, the |
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* computer program, "Risa/Asir" ("SOFTWARE"), subject to the terms and |
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* conditions of this Agreement. For the avoidance of doubt, you acquire |
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* only a limited right to use the SOFTWARE hereunder, and FLL or any |
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* third party developer retains all rights, including but not limited to |
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* copyrights, in and to the SOFTWARE. |
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* |
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* (1) FLL does not grant you a license in any way for commercial |
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* purposes. You may use the SOFTWARE only for non-commercial and |
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* non-profit purposes only, such as academic, research and internal |
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* business use. |
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* (2) The SOFTWARE is protected by the Copyright Law of Japan and |
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* international copyright treaties. If you make copies of the SOFTWARE, |
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* with or without modification, as permitted hereunder, you shall affix |
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* to all such copies of the SOFTWARE the above copyright notice. |
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* (3) An explicit reference to this SOFTWARE and its copyright owner |
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* shall be made on your publication or presentation in any form of the |
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* results obtained by use of the SOFTWARE. |
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* (4) In the event that you modify the SOFTWARE, you shall notify FLL by |
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* e-mail at risa-admin@sec.flab.fujitsu.co.jp of the detailed specification |
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* for such modification or the source code of the modified part of the |
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* SOFTWARE. |
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* |
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* THE SOFTWARE IS PROVIDED AS IS WITHOUT ANY WARRANTY OF ANY KIND. FLL |
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* MAKES ABSOLUTELY NO WARRANTIES, EXPRESSED, IMPLIED OR STATUTORY, AND |
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* EXPRESSLY DISCLAIMS ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS |
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* FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT OF THIRD PARTIES' |
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* RIGHTS. NO FLL DEALER, AGENT, EMPLOYEES IS AUTHORIZED TO MAKE ANY |
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* MODIFICATIONS, EXTENSIONS, OR ADDITIONS TO THIS WARRANTY. |
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* UNDER NO CIRCUMSTANCES AND UNDER NO LEGAL THEORY, TORT, CONTRACT, |
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* OR OTHERWISE, SHALL FLL BE LIABLE TO YOU OR ANY OTHER PERSON FOR ANY |
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* DIRECT, INDIRECT, SPECIAL, INCIDENTAL, PUNITIVE OR CONSEQUENTIAL |
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* DAMAGES OF ANY CHARACTER, INCLUDING, WITHOUT LIMITATION, DAMAGES |
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* ARISING OUT OF OR RELATING TO THE SOFTWARE OR THIS AGREEMENT, DAMAGES |
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* FOR LOSS OF GOODWILL, WORK STOPPAGE, OR LOSS OF DATA, OR FOR ANY |
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* DAMAGES, EVEN IF FLL SHALL HAVE BEEN INFORMED OF THE POSSIBILITY OF |
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* SUCH DAMAGES, OR FOR ANY CLAIM BY ANY OTHER PARTY. EVEN IF A PART |
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* OF THE SOFTWARE HAS BEEN DEVELOPED BY A THIRD PARTY, THE THIRD PARTY |
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* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, |
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* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. |
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* |
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* $OpenXM: OpenXM_contrib2/asir2000/include/ca.h,v 1.11 2000/12/22 10:03:29 saito Exp $ |
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*/ |
| #include <stdio.h> |
#include <stdio.h> |
| |
|
| #if defined(hpux) |
#if defined(hpux) |
|
|
| #include <stdlib.h> |
#include <stdlib.h> |
| #endif |
#endif |
| |
|
| #if defined(__MWERKS__) |
|
| #define THINK_C |
|
| #endif |
|
| |
|
| #if defined(linux) || (defined(sun) && !defined(SYSV)) || defined(news5000) || (defined(mips) && defined(ultrix)) |
#if defined(linux) || (defined(sun) && !defined(SYSV)) || defined(news5000) || (defined(mips) && defined(ultrix)) |
| #include <alloca.h> |
#include <alloca.h> |
| #endif |
#endif |
| Line 63 typedef void * pointer; |
|
| Line 107 typedef void * pointer; |
|
| #define O_MATHCAP 13 |
#define O_MATHCAP 13 |
| #define O_F 14 |
#define O_F 14 |
| #define O_GFMMAT 15 |
#define O_GFMMAT 15 |
| |
#define O_BYTEARRAY 16 |
| #define O_VOID -1 |
#define O_VOID -1 |
| |
|
| #define N_Q 0 |
#define N_Q 0 |
| Line 74 typedef void * pointer; |
|
| Line 119 typedef void * pointer; |
|
| #define N_LM 6 |
#define N_LM 6 |
| #define N_GF2N 7 |
#define N_GF2N 7 |
| #define N_GFPN 8 |
#define N_GFPN 8 |
| |
#define N_GFS 9 |
| |
|
| #define ORD_REVGRADLEX 0 |
#define ORD_REVGRADLEX 0 |
| #define ORD_GRADLEX 1 |
#define ORD_GRADLEX 1 |
| Line 192 typedef struct oMQ { |
|
| Line 238 typedef struct oMQ { |
|
| int cont; |
int cont; |
| } *MQ; |
} *MQ; |
| |
|
| |
typedef struct oGFS { |
| |
short id; |
| |
char nid; |
| |
char pad; |
| |
int cont; |
| |
} *GFS; |
| |
|
| |
|
| typedef struct oP { |
typedef struct oP { |
| short id; |
short id; |
| short pad; |
short pad; |
| Line 270 typedef struct oMATHCAP { |
|
| Line 324 typedef struct oMATHCAP { |
|
| struct oLIST *body; |
struct oLIST *body; |
| } *MATHCAP; |
} *MATHCAP; |
| |
|
| |
typedef struct oBYTEARRAY { |
| |
short id; |
| |
short pad; |
| |
int len; |
| |
unsigned char *body; |
| |
} *BYTEARRAY; |
| |
|
| typedef struct oObj { |
typedef struct oObj { |
| short id; |
short id; |
| short pad; |
short pad; |
|
|
| #define FF_GFP 1 |
#define FF_GFP 1 |
| #define FF_GF2N 2 |
#define FF_GF2N 2 |
| #define FF_GFPN 3 |
#define FF_GFPN 3 |
| |
#define FF_GFS 4 |
| |
|
| |
/* include interval.h */ |
| |
#include "interval.h" |
| |
|
| #define INDEX 100 |
#define INDEX 100 |
| |
|
| #if USE_FLOAT |
#if USE_FLOAT |
| Line 469 bzero((char *)(q)->b,(w)*sizeof(unsigned int))) |
|
| Line 534 bzero((char *)(q)->b,(w)*sizeof(unsigned int))) |
|
| /* cell allocators */ |
/* cell allocators */ |
| #define NEWQ(q) ((q)=(Q)MALLOC(sizeof(struct oQ)),OID(q)=O_N,NID(q)=N_Q) |
#define NEWQ(q) ((q)=(Q)MALLOC(sizeof(struct oQ)),OID(q)=O_N,NID(q)=N_Q) |
| #define NEWMQ(q) ((q)=(MQ)MALLOC_ATOMIC(sizeof(struct oMQ)),OID(q)=O_N,NID(q)=N_M) |
#define NEWMQ(q) ((q)=(MQ)MALLOC_ATOMIC(sizeof(struct oMQ)),OID(q)=O_N,NID(q)=N_M) |
| |
#define NEWGFS(q) ((q)=(GFS)MALLOC_ATOMIC(sizeof(struct oGFS)),OID(q)=O_N,NID(q)=N_GFS) |
| #define NEWP(p) ((p)=(P)MALLOC(sizeof(struct oP)),OID(p)=O_P) |
#define NEWP(p) ((p)=(P)MALLOC(sizeof(struct oP)),OID(p)=O_P) |
| #define NEWR(r) ((r)=(R)MALLOC(sizeof(struct oR)),OID(r)=O_R,(r)->reduced=0) |
#define NEWR(r) ((r)=(R)MALLOC(sizeof(struct oR)),OID(r)=O_R,(r)->reduced=0) |
| #define NEWLIST(l) ((l)=(LIST)MALLOC(sizeof(struct oLIST)),OID(l)=O_LIST) |
#define NEWLIST(l) ((l)=(LIST)MALLOC(sizeof(struct oLIST)),OID(l)=O_LIST) |
| Line 479 bzero((char *)(q)->b,(w)*sizeof(unsigned int))) |
|
| Line 545 bzero((char *)(q)->b,(w)*sizeof(unsigned int))) |
|
| #define NEWUSINT(u) ((u)=(USINT)MALLOC_ATOMIC(sizeof(struct oUSINT)),OID(u)=O_USINT) |
#define NEWUSINT(u) ((u)=(USINT)MALLOC_ATOMIC(sizeof(struct oUSINT)),OID(u)=O_USINT) |
| #define NEWERR(e) ((e)=(ERR)MALLOC(sizeof(struct oERR)),OID(e)=O_ERR) |
#define NEWERR(e) ((e)=(ERR)MALLOC(sizeof(struct oERR)),OID(e)=O_ERR) |
| #define NEWMATHCAP(e) ((e)=(MATHCAP)MALLOC(sizeof(struct oMATHCAP)),OID(e)=O_MATHCAP) |
#define NEWMATHCAP(e) ((e)=(MATHCAP)MALLOC(sizeof(struct oMATHCAP)),OID(e)=O_MATHCAP) |
| |
#define NEWBYTEARRAY(e) ((e)=(BYTEARRAY)MALLOC(sizeof(struct oBYTEARRAY)),OID(e)=O_BYTEARRAY) |
| |
|
| #define NEWNODE(a) ((a)=(NODE)MALLOC(sizeof(struct oNODE))) |
#define NEWNODE(a) ((a)=(NODE)MALLOC(sizeof(struct oNODE))) |
| #define NEWDC(dc) ((dc)=(DCP)MALLOC(sizeof(struct oDCP))) |
#define NEWDC(dc) ((dc)=(DCP)MALLOC(sizeof(struct oDCP))) |
| Line 498 bzero((char *)(q)->b,(w)*sizeof(unsigned int))) |
|
| Line 565 bzero((char *)(q)->b,(w)*sizeof(unsigned int))) |
|
| #define NEWGFPN(r) ((r)=(GFPN)MALLOC(sizeof(struct oGFPN)),OID(r)=O_N,NID(r)=N_GFPN) |
#define NEWGFPN(r) ((r)=(GFPN)MALLOC(sizeof(struct oGFPN)),OID(r)=O_N,NID(r)=N_GFPN) |
| #define NEWDL(d,n) \ |
#define NEWDL(d,n) \ |
| ((d)=(DL)MALLOC_ATOMIC(TRUESIZE(oDL,(n)-1,int)),bzero((char *)(d),TRUESIZE(oDL,(n)-1,int))) |
((d)=(DL)MALLOC_ATOMIC(TRUESIZE(oDL,(n)-1,int)),bzero((char *)(d),TRUESIZE(oDL,(n)-1,int))) |
| |
#define NEWDL_NOINIT(d,n) \ |
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((d)=(DL)MALLOC_ATOMIC(TRUESIZE(oDL,(n)-1,int))) |
| |
|
| #define MKP(v,dc,p) \ |
#define MKP(v,dc,p) \ |
| (!DEG(dc)?((p)=COEF(dc)):(NEWP(p),VR(p)=(v),DC(p)=(dc),(p))) |
(!DEG(dc)?((p)=COEF(dc)):(NEWP(p),VR(p)=(v),DC(p)=(dc),(p))) |
| Line 526 DEG(DC(p))=ONE,COEF(DC(p))=(P)ONEM,NEXT(DC(p))=0) |
|
| Line 595 DEG(DC(p))=ONE,COEF(DC(p))=(P)ONEM,NEXT(DC(p))=0) |
|
| #define MKUSINT(u,b) (NEWUSINT(u),(u)->body=(unsigned)(b)) |
#define MKUSINT(u,b) (NEWUSINT(u),(u)->body=(unsigned)(b)) |
| #define MKERR(e,b) (NEWERR(e),(e)->body=(Obj)(b)) |
#define MKERR(e,b) (NEWERR(e),(e)->body=(Obj)(b)) |
| #define MKMATHCAP(e,b) (NEWMATHCAP(e),(e)->body=(LIST)(b)) |
#define MKMATHCAP(e,b) (NEWMATHCAP(e),(e)->body=(LIST)(b)) |
| |
#define MKBYTEARRAY(m,l) \ |
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(NEWBYTEARRAY(m),(m)->len=(l),(m)->body=(char *)MALLOC_ATOMIC((l)),bzero((m)->body,(l))) |
| |
|
| #define NEXTDC(r,c) \ |
#define NEXTDC(r,c) \ |
| if(!(r)){NEWDC(r);(c)=(r);}else{NEWDC(NEXT(c));(c)=NEXT(c);} |
if(!(r)){NEWDC(r);(c)=(r);}else{NEWDC(NEXT(c));(c)=NEXT(c);} |
| Line 533 if(!(r)){NEWDC(r);(c)=(r);}else{NEWDC(NEXT(c));(c)=NEX |
|
| Line 604 if(!(r)){NEWDC(r);(c)=(r);}else{NEWDC(NEXT(c));(c)=NEX |
|
| if(!(r)){NEWNODE(r);(c)=(r);}else{NEWNODE(NEXT(c));(c)=NEXT(c);} |
if(!(r)){NEWNODE(r);(c)=(r);}else{NEWNODE(NEXT(c));(c)=NEXT(c);} |
| #define NEXTMP(r,c) \ |
#define NEXTMP(r,c) \ |
| if(!(r)){NEWMP(r);(c)=(r);}else{NEWMP(NEXT(c));(c)=NEXT(c);} |
if(!(r)){NEWMP(r);(c)=(r);}else{NEWMP(NEXT(c));(c)=NEXT(c);} |
| |
#define NEXTMP2(r,c,s) \ |
| |
if(!(r)){(c)=(r)=(s);}else{NEXT(c)=(s);(c)=(s);} |
| |
|
| /* convertors */ |
/* convertors */ |
| #define NTOQ(n,s,q) \ |
#define NTOQ(n,s,q) \ |
| Line 547 SGN(q)=((n)>0?1:-1),NM(q)=NALLOC(1),\ |
|
| Line 620 SGN(q)=((n)>0?1:-1),NM(q)=NALLOC(1),\ |
|
| PL(NM(q))=1,BD(NM(q))[0]=ABS(n),DN(q)=0,(q))) |
PL(NM(q))=1,BD(NM(q))[0]=ABS(n),DN(q)=0,(q))) |
| #define UTOMQ(a,b) \ |
#define UTOMQ(a,b) \ |
| ((a)?(NEWMQ(b),CONT(b)=(unsigned int)(a),(b)):((b)=0)) |
((a)?(NEWMQ(b),CONT(b)=(unsigned int)(a),(b)):((b)=0)) |
| |
#define MKGFS(a,b) \ |
| |
((NEWGFS(b),CONT(b)=(a),(b))) |
| #define STOMQ(a,b) \ |
#define STOMQ(a,b) \ |
| ((a)?(NEWMQ(b),CONT(b)=(a),(b)):((b)=0)) |
((a)?(NEWMQ(b),CONT(b)=(a),(b)):((b)=0)) |
| #define UTON(u,n) \ |
#define UTON(u,n) \ |
| Line 565 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q) |
|
| Line 640 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q) |
|
| #define MKAlg(b,r) \ |
#define MKAlg(b,r) \ |
| (!(b)?((r)=0):NUM(b)?((r)=(Alg)(b)):(NEWAlg(r),BDY(r)=(Obj)(b),(r))) |
(!(b)?((r)=0):NUM(b)?((r)=(Alg)(b)):(NEWAlg(r),BDY(r)=(Obj)(b),(r))) |
| |
|
| #define ToReal(a) (!(a)?(double)0.0:REAL(a)?BDY((Real)a):RATN(a)?RatnToReal((Q)a):0) |
#if PARI |
| |
#define ToReal(a) (!(a)?(double)0.0:REAL(a)?BDY((Real)a):RATN(a)?RatnToReal((Q)a):BIGFLOAT(a)?rtodbl(BDY((BF)a)):0) |
| |
#else |
| |
#define ToReal(a) (!(a)?(double)0.0:REAL(a)?BDY((Real)a):RATN(a)?RatnToReal((Q)a):0.0) |
| |
#endif |
| |
|
| /* predicates */ |
/* predicates */ |
| #define NUM(p) (OID(p)==O_N) |
#define NUM(p) (OID(p)==O_N) |
| Line 573 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q) |
|
| Line 652 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q) |
|
| #define INT(q) (!DN((Q)q)) |
#define INT(q) (!DN((Q)q)) |
| #define RATN(a) (NID(a)==N_Q) |
#define RATN(a) (NID(a)==N_Q) |
| #define REAL(a) (NID(a)==N_R) |
#define REAL(a) (NID(a)==N_R) |
| |
#define BIGFLOAT(a) (NID(a)==N_B) |
| #define SFF(a) (NID(a)==N_M) |
#define SFF(a) (NID(a)==N_M) |
| #define UNIQ(q) ((q)&&NUM(q)&&RATN(q)&&(SGN((Q)q)==1)&&UNIN(NM((Q)q))&&(!DN((Q)q))) |
#define UNIQ(q) ((q)&&NUM(q)&&RATN(q)&&(SGN((Q)q)==1)&&UNIN(NM((Q)q))&&(!DN((Q)q))) |
| #define UNIMQ(q) ((q)&&NUM(q)&&SFF(q)&&(CONT((MQ)q)==1)) |
#define UNIMQ(q) ((q)&&NUM(q)&&SFF(q)&&(CONT((MQ)q)==1)) |
| Line 581 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q) |
|
| Line 661 PL(NM(q))=1,BD(NM(q))[0]=(unsigned int)(n),DN(q)=0,(q) |
|
| #define UNIN(n) ((n)&&(PL(n)==1)&&(BD(n)[0]==1)) |
#define UNIN(n) ((n)&&(PL(n)==1)&&(BD(n)[0]==1)) |
| #define EVENN(n) ((!(n))||(!(BD(n)[0]%2))) |
#define EVENN(n) ((!(n))||(!(BD(n)[0]%2))) |
| |
|
| |
/* special macros for private memory management */ |
| |
|
| |
#define NV(p) ((p)->nv) |
| |
#define C(p) ((p)->c) |
| |
#define ITOS(p) (((unsigned int)(p))&0x7fffffff) |
| |
#define STOI(i) ((P)((unsigned int)(i)|0x80000000)) |
| |
|
| |
struct cdl { |
| |
P c; |
| |
DL d; |
| |
}; |
| |
|
| |
struct cdlm { |
| |
int c; |
| |
DL d; |
| |
}; |
| |
|
| |
extern MP _mp_free_list; |
| |
extern DP _dp_free_list; |
| |
extern DL _dl_free_list; |
| |
extern int current_dl_length; |
| |
|
| |
#define _NEWDL_NOINIT(d,n) if ((n)!= current_dl_length){_dl_free_list=0; current_dl_length=(n);} if(!_dl_free_list)_DL_alloc(); (d)=_dl_free_list; _dl_free_list = *((DL *)_dl_free_list) |
| |
#define _NEWDL(d,n) if ((n)!= current_dl_length){_dl_free_list=0; current_dl_length=(n);} if(!_dl_free_list)_DL_alloc(); (d)=_dl_free_list; _dl_free_list = *((DL *)_dl_free_list); bzero((d),(((n)+1)*sizeof(int))) |
| |
#define _NEWMP(m) if(!_mp_free_list)_MP_alloc(); (m)=_mp_free_list; _mp_free_list = NEXT(_mp_free_list) |
| |
#define _MKDP(n,m,d) if(!_dp_free_list)_DP_alloc(); (d)=_dp_free_list; _dp_free_list = (DP)BDY(_dp_free_list); (d)->id = O_DP; (d)->nv=(n); BDY(d)=(m) |
| |
|
| |
#define _NEXTMP(r,c) \ |
| |
if(!(r)){_NEWMP(r);(c)=(r);}else{_NEWMP(NEXT(c));(c)=NEXT(c);} |
| |
|
| |
#define _NEXTMP2(r,c,s) \ |
| |
if(!(r)){(c)=(r)=(s);}else{NEXT(c)=(s);(c)=(s);} |
| |
|
| |
#define _FREEDL(m) *((DL *)m)=_dl_free_list; _dl_free_list=(m) |
| |
#define _FREEMP(m) NEXT(m)=_mp_free_list; _mp_free_list=(m) |
| |
#define _FREEDP(m) BDY(m)=(MP)_dp_free_list; _dp_free_list=(m) |
| |
|
| /* externals */ |
/* externals */ |
| #if 0 |
#if 0 |
| double NatToReal(); |
double NatToReal(); |
|
|
| extern UP2 ONEUP2; |
extern UP2 ONEUP2; |
| |
|
| extern FILE *asir_out; |
extern FILE *asir_out; |
| #if defined(__GNUC__) || defined(THINK_C) |
#if defined(__GNUC__) |
| extern const int sprime[]; |
extern const int sprime[]; |
| extern const int lprime[]; |
extern const int lprime[]; |
| #else |
#else |
| Line 625 extern void (*chsgnnumt[])(); |
|
| Line 741 extern void (*chsgnnumt[])(); |
|
| |
|
| /* prototypes */ |
/* prototypes */ |
| int compui(VL,USINT,USINT); |
int compui(VL,USINT,USINT); |
| |
int compbytearray(VL,BYTEARRAY,BYTEARRAY); |
| |
|
| void powermodup(UP,UP *); |
void powermodup(UP,UP *); |
| void hybrid_powermodup(UP,UP *); |
void hybrid_powermodup(UP,UP *); |
| Line 974 void *GC_realloc(void *,size_t); |
|
| Line 1091 void *GC_realloc(void *,size_t); |
|
| double NatToReal(N,int *); |
double NatToReal(N,int *); |
| double RatnToReal(Q); |
double RatnToReal(Q); |
| double pwrreal0(double,int); |
double pwrreal0(double,int); |
| |
double rtodbl(); /* XXX */ |
| int **almat(int,int); |
int **almat(int,int); |
| pointer **almat_pointer(int,int); |
pointer **almat_pointer(int,int); |
| int berlecnt(register int,UM); |
int berlecnt(register int,UM); |
| Line 1049 void divgfpn(GFPN,GFPN,GFPN *); |
|
| Line 1167 void divgfpn(GFPN,GFPN,GFPN *); |
|
| void chsgngfpn(GFPN,GFPN *); |
void chsgngfpn(GFPN,GFPN *); |
| void pwrgfpn(GFPN,Q, GFPN *); |
void pwrgfpn(GFPN,Q, GFPN *); |
| int cmpgfpn(GFPN,GFPN); |
int cmpgfpn(GFPN,GFPN); |
| |
|
| |
void addgfs(GFS,GFS,GFS *); |
| |
void subgfs(GFS,GFS,GFS *); |
| |
void mulgfs(GFS,GFS,GFS *); |
| |
void divgfs(GFS,GFS,GFS *); |
| |
void chsgngfs(GFS,GFS *); |
| |
void pwrgfs(GFS,Q, GFS *); |
| |
int cmpgfs(GFS,GFS); |
| |
|
| void addalg(Num,Num,Num *); |
void addalg(Num,Num,Num *); |
| void addbf(Num,Num,Num *); |
void addbf(Num,Num,Num *); |
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