/* * Copyright (c) 1994-2000 FUJITSU LABORATORIES LIMITED * All rights reserved. * * FUJITSU LABORATORIES LIMITED ("FLL") hereby grants you a limited, * non-exclusive and royalty-free license to use, copy, modify and * redistribute, solely for non-commercial and non-profit purposes, the * computer program, "Risa/Asir" ("SOFTWARE"), subject to the terms and * conditions of this Agreement. For the avoidance of doubt, you acquire * only a limited right to use the SOFTWARE hereunder, and FLL or any * third party developer retains all rights, including but not limited to * copyrights, in and to the SOFTWARE. * * (1) FLL does not grant you a license in any way for commercial * purposes. You may use the SOFTWARE only for non-commercial and * non-profit purposes only, such as academic, research and internal * business use. * (2) The SOFTWARE is protected by the Copyright Law of Japan and * international copyright treaties. If you make copies of the SOFTWARE, * with or without modification, as permitted hereunder, you shall affix * to all such copies of the SOFTWARE the above copyright notice. * (3) An explicit reference to this SOFTWARE and its copyright owner * shall be made on your publication or presentation in any form of the * results obtained by use of the SOFTWARE. * (4) In the event that you modify the SOFTWARE, you shall notify FLL by * e-mail at risa-admin@sec.flab.fujitsu.co.jp of the detailed specification * for such modification or the source code of the modified part of the * SOFTWARE. * * THE SOFTWARE IS PROVIDED AS IS WITHOUT ANY WARRANTY OF ANY KIND. FLL * MAKES ABSOLUTELY NO WARRANTIES, EXPRESSED, IMPLIED OR STATUTORY, AND * EXPRESSLY DISCLAIMS ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS * FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT OF THIRD PARTIES' * RIGHTS. NO FLL DEALER, AGENT, EMPLOYEES IS AUTHORIZED TO MAKE ANY * MODIFICATIONS, EXTENSIONS, OR ADDITIONS TO THIS WARRANTY. * UNDER NO CIRCUMSTANCES AND UNDER NO LEGAL THEORY, TORT, CONTRACT, * OR OTHERWISE, SHALL FLL BE LIABLE TO YOU OR ANY OTHER PERSON FOR ANY * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, PUNITIVE OR CONSEQUENTIAL * DAMAGES OF ANY CHARACTER, INCLUDING, WITHOUT LIMITATION, DAMAGES * ARISING OUT OF OR RELATING TO THE SOFTWARE OR THIS AGREEMENT, DAMAGES * FOR LOSS OF GOODWILL, WORK STOPPAGE, OR LOSS OF DATA, OR FOR ANY * DAMAGES, EVEN IF FLL SHALL HAVE BEEN INFORMED OF THE POSSIBILITY OF * SUCH DAMAGES, OR FOR ANY CLAIM BY ANY OTHER PARTY. EVEN IF A PART * OF THE SOFTWARE HAS BEEN DEVELOPED BY A THIRD PARTY, THE THIRD PARTY * DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, * PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. * * $OpenXM: OpenXM_contrib2/asir2000/engine/init.c,v 1.24 2006/02/08 02:11:19 noro Exp $ */ #include "ca.h" #include "version.h" #include "prime.h" struct oN oUNIN,oTWON,oTHREEN,oFOURN,oFIVEN,oSIXN,oSEVENN,oEIGHTN; struct oQ oUNIQ,oTWOQ,oTHREEQ,oFOURQ,oFIVEQ,oSIXQ,oSEVENQ,oEIGHTQ; struct oUP2 oONEUP2; N ONEN = &oUNIN; Q ONE = &oUNIQ; Q TWO = &oTWOQ; Q THREE = &oTHREEQ; Q FOUR = &oFOURQ; Q FIVE = &oFIVEQ; Q SIX = &oSIXQ; Q SEVEN = &oSEVENQ; Q EIGHT = &oEIGHTQ; LM THREE_LM,FOUR_LM,EIGHT_LM; struct oR oUNIR; struct oMQ oUNIMQ; struct oLM oUNILM; struct oC oIU; struct oUSINT oVOID; MQ ONEM = &oUNIMQ; LM ONELM = &oUNILM; UP2 ONEUP2 = &oONEUP2; C IU = &oIU; USINT VOIDobj = &oVOID; int bigfloat; int nez = 1; int current_mod = 0; int StrassenSize = 0; int outputstyle = 0; static int *lprime; static int lprime_size; #if defined(PARI) int paristack = 1<<16; #define ADDBF addbf #define SUBBF subbf #define MULBF mulbf #define DIVBF divbf #define PWRBF pwrbf #define CHSGNBF chsgnbf #define CMPBF cmpbf # else #define ADDBF 0 #define SUBBF 0 #define MULBF 0 #define DIVBF 0 #define PWRBF 0 #define CHSGNBF 0 #define CMPBF 0 #endif #if defined(INTERVAL) int zerorewrite = 0; void (*addnumt[])() = { addq, addreal, addalg, ADDBF, 0, additvp, additvd, 0, additvf, addcplx, addmi, addlm, addgf2n, addgfpn, addgfs, addgfsn, adddalg }; void (*subnumt[])() = { subq, subreal, subalg, SUBBF, 0, subitvp, subitvd, 0, subitvf, subcplx, submi, sublm, subgf2n, subgfpn, subgfs, subgfsn, subdalg }; void (*mulnumt[])() = { mulq, mulreal, mulalg, MULBF, 0, mulitvp, mulitvd, 0, mulitvf, mulcplx, mulmi, mullm, mulgf2n, mulgfpn, mulgfs, mulgfsn, muldalg }; void (*divnumt[])() = { divq, divreal, divalg, DIVBF, 0, divitvp, divitvd, 0, divitvf, divcplx, divmi, divlm, divgf2n, divgfpn, divgfs, divgfsn, divdalg }; void (*pwrnumt[])() = { pwrq, pwrreal, pwralg, PWRBF, 0, pwritvp, pwritvd, 0, pwritvf, pwrcplx, pwrmi, pwrlm, pwrgf2n, pwrgfpn, pwrgfs, pwrgfsn, pwrdalg }; void (*chsgnnumt[])() = { chsgnq, chsgnreal, chsgnalg, CHSGNBF, 0, chsgnitvp, chsgnitvd, 0, chsgnitvf, chsgncplx, chsgnmi, chsgnlm, chsgngf2n, chsgngfpn, chsgngfs , chsgngfsn, chsgndalg}; int (*cmpnumt[])() = { cmpq, cmpreal, cmpalg, CMPBF, 0, cmpitvp, cmpitvd, 0, cmpitvf, cmpcplx, cmpmi, cmplm, cmpgf2n, cmpgfpn, cmpgfs, cmpgfsn, cmpdalg }; #else void (*addnumt[])() = { addq, addreal, addalg, ADDBF, addcplx, addmi, addlm, addgf2n, addgfpn, addgfs, addgfsn, adddalg }; void (*subnumt[])() = { subq, subreal, subalg, SUBBF, subcplx, submi, sublm, subgf2n, subgfpn, subgfs, subgfsn, subdalg }; void (*mulnumt[])() = { mulq, mulreal, mulalg, MULBF, mulcplx, mulmi, mullm, mulgf2n, mulgfpn, mulgfs, mulgfsn, muldalg }; void (*divnumt[])() = { divq, divreal, divalg, DIVBF, divcplx, divmi, divlm, divgf2n, divgfpn, divgfs, divgfsn, divdalg }; void (*pwrnumt[])() = { pwrq, pwrreal, pwralg, PWRBF, pwrcplx, pwrmi, pwrlm, pwrgf2n, pwrgfpn, pwrgfs, pwrgfsn, pwrdalg }; void (*chsgnnumt[])() = { chsgnq, chsgnreal, chsgnalg, CHSGNBF, chsgncplx, chsgnmi, chsgnlm, chsgngf2n, chsgngfpn, chsgngfs, chsgngfsn, chsgndalg }; int (*cmpnumt[])() = { cmpq, cmpreal, cmpalg, CMPBF, cmpcplx, cmpmi, cmplm, cmpgf2n, cmpgfpn, cmpgfs, cmpgfsn, cmpdalg }; #endif double get_current_time(); void init_lprime(); void nglob_init() { PL(&oUNIN) = 1; BD(&oUNIN)[0] = 1; PL(&oTWON) = 1; BD(&oTWON)[0] = 2; PL(&oTHREEN) = 1; BD(&oTHREEN)[0] = 3; PL(&oFOURN) = 1; BD(&oFOURN)[0] = 4; PL(&oFIVEN) = 1; BD(&oFIVEN)[0] = 5; PL(&oSIXN) = 1; BD(&oSIXN)[0] = 6; PL(&oSEVENN) = 1; BD(&oSEVENN)[0] = 7; PL(&oEIGHTN) = 1; BD(&oEIGHTN)[0] = 8; oONEUP2.w = 1; oONEUP2.b[0] = 1; OID(&oUNIQ) = O_N; NID(&oUNIQ) = N_Q; SGN(&oUNIQ) = 1; NM(&oUNIQ) = &oUNIN; DN(&oUNIQ) = 0; OID(&oTWOQ) = O_N; NID(&oTWOQ) = N_Q; SGN(&oTWOQ) = 1; NM(&oTWOQ) = &oTWON; DN(&oTWOQ) = 0; OID(&oTHREEQ) = O_N; NID(&oTHREEQ) = N_Q; SGN(&oTHREEQ) = 1; NM(&oTHREEQ) = &oTHREEN; DN(&oTHREEQ) = 0; OID(&oFOURQ) = O_N; NID(&oFOURQ) = N_Q; SGN(&oFOURQ) = 1; NM(&oFOURQ) = &oFOURN; DN(&oFOURQ) = 0; OID(&oFIVEQ) = O_N; NID(&oFIVEQ) = N_Q; SGN(&oFIVEQ) = 1; NM(&oFIVEQ) = &oFIVEN; DN(&oFIVEQ) = 0; OID(&oSIXQ) = O_N; NID(&oSIXQ) = N_Q; SGN(&oSIXQ) = 1; NM(&oSIXQ) = &oSIXN; DN(&oSIXQ) = 0; OID(&oSEVENQ) = O_N; NID(&oSEVENQ) = N_Q; SGN(&oSEVENQ) = 1; NM(&oSEVENQ) = &oSEVENN; DN(&oSEVENQ) = 0; OID(&oEIGHTQ) = O_N; NID(&oEIGHTQ) = N_Q; SGN(&oEIGHTQ) = 1; NM(&oEIGHTQ) = &oEIGHTN; DN(&oEIGHTQ) = 0; OID(&oUNIR) = O_R; NM(&oUNIR) = (P)&oUNIQ; DN(&oUNIR) = (P)&oUNIQ; oUNIR.reduced = 1; OID(&oUNIMQ) = O_N; NID(&oUNIMQ) = N_M; CONT(&oUNIMQ) = 1; OID(&oUNILM) = O_N; NID(&oUNILM) = N_LM; BDY(&oUNILM) = ONEN; OID(&oIU) = O_N; NID(&oIU) = N_C; oIU.r = 0; oIU.i = (Num)ONE; MKLM(&oTHREEN,THREE_LM); MKLM(&oFOURN,FOUR_LM); MKLM(&oEIGHTN,EIGHT_LM); OID(&oVOID) = O_VOID; /* moved to parse/main.c */ #if 0 #if defined(PARI) risa_pari_init(); #endif srandom((int)get_current_time()); #endif init_up2_tab(); init_lprime(); } extern double gctime; double suspend_start; double suspended_time=0; void get_eg(struct oEGT *p) { p->exectime = get_clock() - gctime - suspended_time; p->gctime = gctime; } void init_eg(struct oEGT *eg) { bzero((char *)eg,sizeof(struct oEGT)); } void add_eg(struct oEGT *base,struct oEGT *start,struct oEGT *end) { base->exectime += end->exectime - start->exectime; base->gctime += end->gctime - start->gctime; } void print_eg(char *item,struct oEGT *eg) { printf("%s=(%.4g,%.4g)",item,eg->exectime,eg->gctime); } void print_split_eg(struct oEGT *start,struct oEGT *end) { struct oEGT base; init_eg(&base); add_eg(&base,start,end); printf("(%.4g,%.4g)",base.exectime,base.gctime); } void print_split_e(struct oEGT *start,struct oEGT *end) { struct oEGT base; init_eg(&base); add_eg(&base,start,end); printf("(%.4g)",base.exectime); } void suspend_timer() { suspend_start = get_clock(); } void resume_timer() { suspended_time += get_clock()-suspend_start; } extern int lm_lazy, up_lazy; extern int GC_dont_gc; extern int do_weyl; extern int dp_fcoeffs; void reset_engine() { lm_lazy = 0; up_lazy = 0; do_weyl = 0; dp_fcoeffs = 0; GC_dont_gc = 0; } unsigned int get_asir_version() { return ASIR_VERSION; } char *get_asir_distribution() { return ASIR_DISTRIBUTION; } void create_error(ERR *err,unsigned int serial,char *msg,LIST trace) { int len; USINT ui; NODE n,n1; LIST list; char *msg1; STRING errmsg; MKUSINT(ui,serial); len = strlen(msg); msg1 = (char *)MALLOC(len+1); strcpy(msg1,msg); MKSTR(errmsg,msg1); n = mknode(3,ui,errmsg,trace); MKLIST(list,n); MKERR(*err,list); } void init_lprime() { int s,i; s = sizeof(lprime_init); lprime = (int *)GC_malloc_atomic(s); lprime_size = s/sizeof(int); for ( i = 0; i < lprime_size; i++ ) lprime[i] = lprime_init[lprime_size-i-1]; } void create_new_lprimes(int); int get_lprime(index) { if ( index >= lprime_size ) create_new_lprimes(index); return lprime[index]; } void create_new_lprimes(int index) { int count,p,i,j,d; if ( index < lprime_size ) return; count = index-lprime_size+1; if ( count < 256 ) count = 256; lprime = (int *)GC_realloc(lprime,(lprime_size+count)*sizeof(int)); p = lprime[lprime_size-1]+2; for ( i = 0; i < count; p += 2 ) { for ( j = 0; d = sprime[j]; j++ ) { if ( d*d > p ) { lprime[i+lprime_size] = p; i++; break; } if ( !(p%d) ) break; } } lprime_size += count; }