version 1.2, 2000/08/21 08:31:27 |
version 1.20, 2003/05/29 16:45:00 |
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* shall be made on your publication or presentation in any form of the |
* shall be made on your publication or presentation in any form of the |
* results obtained by use of the SOFTWARE. |
* results obtained by use of the SOFTWARE. |
* (4) In the event that you modify the SOFTWARE, you shall notify FLL by |
* (4) In the event that you modify the SOFTWARE, you shall notify FLL by |
* e-mail at risa-admin@flab.fujitsu.co.jp of the detailed specification |
* 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 |
* for such modification or the source code of the modified part of the |
* SOFTWARE. |
* SOFTWARE. |
* |
* |
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* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, |
* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, |
* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. |
* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. |
* |
* |
* $OpenXM: OpenXM_contrib2/asir2000/engine/init.c,v 1.1.1.1 1999/12/03 07:39:08 noro Exp $ |
* $OpenXM: OpenXM_contrib2/asir2000/engine/init.c,v 1.19 2003/02/14 22:29:09 ohara Exp $ |
*/ |
*/ |
#include "ca.h" |
#include "ca.h" |
#include "version.h" |
#include "version.h" |
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#include "prime.h" |
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struct oN oUNIN,oTWON,oTHREEN,oFOURN,oFIVEN,oSIXN,oSEVENN,oEIGHTN; |
struct oN oUNIN,oTWON,oTHREEN,oFOURN,oFIVEN,oSIXN,oSEVENN,oEIGHTN; |
struct oQ oUNIQ,oTWOQ,oTHREEQ,oFOURQ,oFIVEQ,oSIXQ,oSEVENQ,oEIGHTQ; |
struct oQ oUNIQ,oTWOQ,oTHREEQ,oFOURQ,oFIVEQ,oSIXQ,oSEVENQ,oEIGHTQ; |
Line 82 USINT VOIDobj = &oVOID; |
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Line 83 USINT VOIDobj = &oVOID; |
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int bigfloat; |
int bigfloat; |
int nez = 1; |
int nez = 1; |
int current_mod = 0; |
int current_mod = 0; |
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int StrassenSize = 0; |
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int prefixmode = 0; |
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#if PARI |
static int *lprime; |
#if defined(THINK_C) |
int lprime_size; |
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#if defined(PARI) |
int paristack = 1<<16; |
int paristack = 1<<16; |
#else |
#define ADDBF addbf |
int paristack = 1<<20; |
#define SUBBF subbf |
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#define MULBF mulbf |
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#define DIVBF divbf |
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#define PWRBF pwrbf |
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#define CHSGNBF chsgnbf |
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#define CMPBF cmpbf |
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# else |
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#define ADDBF 0 |
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#define SUBBF 0 |
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#define MULBF 0 |
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#define DIVBF 0 |
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#define PWRBF 0 |
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#define CHSGNBF 0 |
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#define CMPBF 0 |
#endif |
#endif |
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void (*addnumt[])() = { addq, addreal, addalg, addbf, addcplx, addmi, addlm, addgf2n, addgfpn }; |
#if defined(INTERVAL) |
void (*subnumt[])() = { subq, subreal, subalg, subbf, subcplx, submi, sublm, subgf2n, subgfpn }; |
int zerorewrite = 0; |
void (*mulnumt[])() = { mulq, mulreal, mulalg, mulbf, mulcplx, mulmi, mullm, mulgf2n, mulgfpn }; |
void (*addnumt[])() = { addq, addreal, addalg, ADDBF, 0, additvp, additvd, 0, additvf, addcplx, addmi, addlm, addgf2n, addgfpn, addgfs, addgfsn }; |
void (*divnumt[])() = { divq, divreal, divalg, divbf, divcplx, divmi, divlm, divgf2n, divgfpn }; |
void (*subnumt[])() = { subq, subreal, subalg, SUBBF, 0, subitvp, subitvd, 0, subitvf, subcplx, submi, sublm, subgf2n, subgfpn, subgfs, subgfsn }; |
void (*pwrnumt[])() = { pwrq, pwrreal, pwralg, pwrbf, pwrcplx, pwrmi, pwrlm, pwrgf2n, pwrgfpn }; |
void (*mulnumt[])() = { mulq, mulreal, mulalg, MULBF, 0, mulitvp, mulitvd, 0, mulitvf, mulcplx, mulmi, mullm, mulgf2n, mulgfpn, mulgfs, mulgfsn }; |
void (*chsgnnumt[])() = { chsgnq, chsgnreal, chsgnalg, chsgnbf, chsgncplx, chsgnmi, chsgnlm, chsgngf2n, chsgngfpn }; |
void (*divnumt[])() = { divq, divreal, divalg, DIVBF, 0, divitvp, divitvd, 0, divitvf, divcplx, divmi, divlm, divgf2n, divgfpn, divgfs, divgfsn }; |
int (*cmpnumt[])() = { cmpq, cmpreal, cmpalg, cmpbf, cmpcplx, cmpmi, cmplm, cmpgf2n, cmpgfpn }; |
void (*pwrnumt[])() = { pwrq, pwrreal, pwralg, PWRBF, 0, pwritvp, pwritvd, 0, pwritvf, pwrcplx, pwrmi, pwrlm, pwrgf2n, pwrgfpn, pwrgfs, pwrgfsn }; |
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void (*chsgnnumt[])() = { chsgnq, chsgnreal, chsgnalg, CHSGNBF, 0, chsgnitvp, chsgnitvd, 0, chsgnitvf, chsgncplx, chsgnmi, chsgnlm, chsgngf2n, chsgngfpn, chsgngfs , chsgngfsn}; |
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int (*cmpnumt[])() = { cmpq, cmpreal, cmpalg, CMPBF, 0, cmpitvp, cmpitvd, 0, cmpitvf, cmpcplx, cmpmi, cmplm, cmpgf2n, cmpgfpn, cmpgfs, cmpgfsn }; |
#else |
#else |
void (*addnumt[])() = { addq, addreal, addalg, 0, addcplx, addmi, addlm, addgf2n, addgfpn }; |
void (*addnumt[])() = { addq, addreal, addalg, ADDBF, addcplx, addmi, addlm, addgf2n, addgfpn, addgfs, addgfsn }; |
void (*subnumt[])() = { subq, subreal, subalg, 0, subcplx, submi, sublm, subgf2n, subgfpn }; |
void (*subnumt[])() = { subq, subreal, subalg, SUBBF, subcplx, submi, sublm, subgf2n, subgfpn, subgfs, subgfsn }; |
void (*mulnumt[])() = { mulq, mulreal, mulalg, 0, mulcplx, mulmi, mullm, mulgf2n, mulgfpn }; |
void (*mulnumt[])() = { mulq, mulreal, mulalg, MULBF, mulcplx, mulmi, mullm, mulgf2n, mulgfpn, mulgfs, mulgfsn }; |
void (*divnumt[])() = { divq, divreal, divalg, 0, divcplx, divmi, divlm, divgf2n,divgfpn }; |
void (*divnumt[])() = { divq, divreal, divalg, DIVBF, divcplx, divmi, divlm, divgf2n, divgfpn, divgfs, divgfsn }; |
void (*pwrnumt[])() = { pwrq, pwrreal, pwralg, 0, pwrcplx, pwrmi, pwrlm, pwrgf2n, pwrgfpn }; |
void (*pwrnumt[])() = { pwrq, pwrreal, pwralg, PWRBF, pwrcplx, pwrmi, pwrlm, pwrgf2n, pwrgfpn, pwrgfs, pwrgfsn }; |
void (*chsgnnumt[])() = { chsgnq, chsgnreal, chsgnalg, 0, chsgncplx, chsgnmi, chsgnlm, chsgngf2n, chsgngfpn }; |
void (*chsgnnumt[])() = { chsgnq, chsgnreal, chsgnalg, CHSGNBF, chsgncplx, chsgnmi, chsgnlm, chsgngf2n, chsgngfpn, chsgngfs, chsgngfsn }; |
int (*cmpnumt[])() = { cmpq, cmpreal, cmpalg, 0, cmpcplx, cmpmi, cmplm, cmpgf2n, cmpgfpn }; |
int (*cmpnumt[])() = { cmpq, cmpreal, cmpalg, CMPBF, cmpcplx, cmpmi, cmplm, cmpgf2n, cmpgfpn, cmpgfs, cmpgfsn }; |
#endif |
#endif |
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double get_current_time(); |
double get_current_time(); |
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void init_lprime(); |
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void nglob_init() { |
void nglob_init() { |
PL(&oUNIN) = 1; BD(&oUNIN)[0] = 1; |
PL(&oUNIN) = 1; BD(&oUNIN)[0] = 1; |
Line 158 void nglob_init() { |
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Line 179 void nglob_init() { |
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/* moved to parse/main.c */ |
/* moved to parse/main.c */ |
#if 0 |
#if 0 |
#if PARI |
#if defined(PARI) |
risa_pari_init(); |
risa_pari_init(); |
#endif |
#endif |
srandom((int)get_current_time()); |
srandom((int)get_current_time()); |
#endif |
#endif |
init_up2_tab(); |
init_up2_tab(); |
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init_lprime(); |
} |
} |
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extern double gctime; |
extern double gctime; |
double suspend_start; |
double suspend_start; |
double suspended_time=0; |
double suspended_time=0; |
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void get_eg(p) |
void get_eg(struct oEGT *p) |
struct oEGT *p; |
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{ |
{ |
p->exectime = get_clock() - gctime - suspended_time; p->gctime = gctime; |
p->exectime = get_clock() - gctime - suspended_time; p->gctime = gctime; |
} |
} |
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void init_eg(eg) |
void init_eg(struct oEGT *eg) |
struct oEGT *eg; |
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{ |
{ |
bzero((char *)eg,sizeof(struct oEGT)); |
bzero((char *)eg,sizeof(struct oEGT)); |
} |
} |
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void add_eg(base,start,end) |
void add_eg(struct oEGT *base,struct oEGT *start,struct oEGT *end) |
struct oEGT *base,*start,*end; |
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{ |
{ |
base->exectime += end->exectime - start->exectime; |
base->exectime += end->exectime - start->exectime; |
base->gctime += end->gctime - start->gctime; |
base->gctime += end->gctime - start->gctime; |
} |
} |
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void print_eg(item,eg) |
void print_eg(char *item,struct oEGT *eg) |
char *item; |
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struct oEGT *eg; |
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{ |
{ |
printf("%s=(%.4g,%.4g)",item,eg->exectime,eg->gctime); |
printf("%s=(%.4g,%.4g)",item,eg->exectime,eg->gctime); |
} |
} |
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void print_split_eg(start,end) |
void print_split_eg(struct oEGT *start,struct oEGT *end) |
struct oEGT *start,*end; |
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{ |
{ |
struct oEGT base; |
struct oEGT base; |
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Line 205 struct oEGT *start,*end; |
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Line 222 struct oEGT *start,*end; |
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printf("(%.4g,%.4g)",base.exectime,base.gctime); |
printf("(%.4g,%.4g)",base.exectime,base.gctime); |
} |
} |
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void print_split_e(start,end) |
void print_split_e(struct oEGT *start,struct oEGT *end) |
struct oEGT *start,*end; |
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{ |
{ |
struct oEGT base; |
struct oEGT base; |
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Line 223 void resume_timer() { |
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Line 239 void resume_timer() { |
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} |
} |
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extern int lm_lazy, up_lazy; |
extern int lm_lazy, up_lazy; |
extern GC_dont_gc; |
extern int GC_dont_gc; |
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extern int do_weyl; |
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extern int dp_fcoeffs; |
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void reset_engine() { |
void reset_engine() { |
lm_lazy = 0; up_lazy = 0; |
lm_lazy = 0; |
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up_lazy = 0; |
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do_weyl = 0; |
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dp_fcoeffs = 0; |
GC_dont_gc = 0; |
GC_dont_gc = 0; |
} |
} |
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unsigned int get_asir_version() { |
unsigned int get_asir_version() { |
return ASIR_VERSION; |
return ASIR_VERSION; |
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} |
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char *get_asir_distribution() { |
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return ASIR_DISTRIBUTION; |
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} |
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void create_error(ERR *err,unsigned int serial,char *msg) |
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{ |
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int len; |
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USINT ui; |
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NODE n,n1; |
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LIST list; |
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char *msg1; |
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STRING errmsg; |
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MKUSINT(ui,serial); |
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len = strlen(msg); |
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msg1 = (char *)MALLOC(len+1); |
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strcpy(msg1,msg); |
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MKSTR(errmsg,msg1); |
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MKNODE(n1,errmsg,0); MKNODE(n,ui,n1); MKLIST(list,n); |
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MKERR(*err,list); |
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} |
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void init_lprime() |
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{ |
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int s,i; |
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s = sizeof(lprime_init); |
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lprime = (int *)GC_malloc_atomic(s); |
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lprime_size = s/sizeof(int); |
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for ( i = 0; i < lprime_size; i++ ) |
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lprime[i] = lprime_init[lprime_size-i-1]; |
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} |
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void create_new_lprimes(int); |
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int get_lprime(index) |
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{ |
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if ( index >= lprime_size ) |
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create_new_lprimes(index); |
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return lprime[index]; |
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} |
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void create_new_lprimes(int index) |
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{ |
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int count,p,i,j,d; |
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if ( index < lprime_size ) |
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return; |
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count = index-lprime_size+1; |
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if ( count < 256 ) |
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count = 256; |
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lprime = (int *)GC_realloc(lprime,(lprime_size+count)*sizeof(int)); |
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p = lprime[lprime_size-1]+2; |
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for ( i = 0; i < count; p += 2 ) { |
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for ( j = 0; d = sprime[j]; j++ ) { |
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if ( d*d > p ) { |
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lprime[i+lprime_size] = p; |
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i++; |
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break; |
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} |
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if ( !(p%d) ) |
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break; |
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} |
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} |
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lprime_size += count; |
} |
} |