/* Evaluate the expression E modulo MOD and put the result in R. */
void
mpz_eval_mod_expr (mpz_ptr r, expr_t e, mpz_ptr mod)
{
mpz_t lhs, rhs;
switch (e->op)
{
case POW:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_mod_expr (lhs, e->operands.ops.lhs, mod);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_powm (r, lhs, rhs, mod);
mpz_clear (lhs); mpz_clear (rhs);
return;
case PLUS:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_mod_expr (lhs, e->operands.ops.lhs, mod);
mpz_eval_mod_expr (rhs, e->operands.ops.rhs, mod);
mpz_add (r, lhs, rhs);
if (mpz_cmp_si (r, 0L) < 0)
mpz_add (r, r, mod);
else if (mpz_cmp (r, mod) >= 0)
mpz_sub (r, r, mod);
mpz_clear (lhs); mpz_clear (rhs);
return;
case MINUS:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_mod_expr (lhs, e->operands.ops.lhs, mod);
mpz_eval_mod_expr (rhs, e->operands.ops.rhs, mod);
mpz_sub (r, lhs, rhs);
if (mpz_cmp_si (r, 0L) < 0)
mpz_add (r, r, mod);
else if (mpz_cmp (r, mod) >= 0)
mpz_sub (r, r, mod);
mpz_clear (lhs); mpz_clear (rhs);
return;
case MULT:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_mod_expr (lhs, e->operands.ops.lhs, mod);
mpz_eval_mod_expr (rhs, e->operands.ops.rhs, mod);
mpz_mul (r, lhs, rhs);
mpz_mod (r, r, mod);
mpz_clear (lhs); mpz_clear (rhs);
return;
default:
mpz_init (lhs);
mpz_eval_expr (lhs, e);
mpz_mod (r, lhs, mod);
mpz_clear (lhs);
return;
}
}
/* Evaluate the expression E and put the result in R. */
void
mpz_eval_expr (mpz_ptr r, expr_t e)
{
mpz_t lhs, rhs;
switch (e->op)
{
case LIT:
mpz_set (r, e->operands.val);
return;
case PLUS:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_add (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
case MINUS:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_sub (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
case MULT:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_mul (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
case DIV:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_fdiv_q (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
case MOD:
mpz_init (rhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_abs (rhs, rhs);
mpz_eval_mod_expr (r, e->operands.ops.lhs, rhs);
mpz_clear (rhs);
return;
case REM:
/* Check if lhs operand is POW expression and optimize for that case. */
if (e->operands.ops.lhs->op == POW)
{
mpz_t powlhs, powrhs;
mpz_init (powlhs);
mpz_init (powrhs);
mpz_init (rhs);
mpz_eval_expr (powlhs, e->operands.ops.lhs->operands.ops.lhs);
mpz_eval_expr (powrhs, e->operands.ops.lhs->operands.ops.rhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_powm (r, powlhs, powrhs, rhs);
if (mpz_cmp_si (rhs, 0L) < 0)
mpz_neg (r, r);
mpz_clear (powlhs);
mpz_clear (powrhs);
mpz_clear (rhs);
return;
}
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_fdiv_r (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
#if __GNU_MP_VERSION >= 2
case INVMOD:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_invert (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
#endif
case POW:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
if (mpz_cmpabs_ui (lhs, 1) <= 0)
{
/* For 0^rhs and 1^rhs, we just need to verify that
rhs is well-defined. For (-1)^rhs we need to
determine (rhs mod 2). For simplicity, compute
(rhs mod 2) for all three cases. */
expr_t two, et;
two = malloc (sizeof (struct expr));
two -> op = LIT;
mpz_init_set_ui (two->operands.val, 2L);
makeexp (&et, MOD, e->operands.ops.rhs, two);
e->operands.ops.rhs = et;
}
mpz_eval_expr (rhs, e->operands.ops.rhs);
if (mpz_cmp_si (rhs, 0L) == 0)
/* x^0 is 1 */
mpz_set_ui (r, 1L);
else if (mpz_cmp_si (lhs, 0L) == 0)
/* 0^y (where y != 0) is 0 */
mpz_set_ui (r, 0L);
else if (mpz_cmp_ui (lhs, 1L) == 0)
/* 1^y is 1 */
mpz_set_ui (r, 1L);
else if (mpz_cmp_si (lhs, -1L) == 0)
/* (-1)^y just depends on whether y is even or odd */
mpz_set_si (r, (mpz_get_ui (rhs) & 1) ? -1L : 1L);
else if (mpz_cmp_si (rhs, 0L) < 0)
/* x^(-n) is 0 */
mpz_set_ui (r, 0L);
else
{
unsigned long int cnt;
unsigned long int y;
/* error if exponent does not fit into an unsigned long int. */
if (mpz_cmp_ui (rhs, ~(unsigned long int) 0) > 0)
goto pow_err;
y = mpz_get_ui (rhs);
/* x^y == (x/(2^c))^y * 2^(c*y) */
#if __GNU_MP_VERSION >= 2
cnt = mpz_scan1 (lhs, 0);
#else
cnt = 0;
#endif
if (cnt != 0)
{
if (y * cnt / cnt != y)
goto pow_err;
mpz_tdiv_q_2exp (lhs, lhs, cnt);
mpz_pow_ui (r, lhs, y);
mpz_mul_2exp (r, r, y * cnt);
}
else
mpz_pow_ui (r, lhs, y);
}
mpz_clear (lhs); mpz_clear (rhs);
return;
pow_err:
error = "result of `pow' operator too large";
mpz_clear (lhs); mpz_clear (rhs);
longjmp (errjmpbuf, 1);
case GCD:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_gcd (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
#if __GNU_MP_VERSION > 2 || __GNU_MP_VERSION_MINOR >= 1
case LCM:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_lcm (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
#endif
case AND:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_and (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
case IOR:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_ior (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
#if __GNU_MP_VERSION > 2 || __GNU_MP_VERSION_MINOR >= 1
case XOR:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
mpz_xor (r, lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
return;
#endif
case NEG:
mpz_eval_expr (r, e->operands.ops.lhs);
mpz_neg (r, r);
return;
case NOT:
mpz_eval_expr (r, e->operands.ops.lhs);
mpz_com (r, r);
return;
case SQRT:
mpz_init (lhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
if (mpz_sgn (lhs) < 0)
{
error = "cannot take square root of negative numbers";
mpz_clear (lhs);
longjmp (errjmpbuf, 1);
}
mpz_sqrt (r, lhs);
return;
#if __GNU_MP_VERSION > 2 || __GNU_MP_VERSION_MINOR >= 1
case ROOT:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
if (mpz_sgn (rhs) <= 0)
{
error = "cannot take non-positive root orders";
mpz_clear (lhs); mpz_clear (rhs);
longjmp (errjmpbuf, 1);
}
if (mpz_sgn (lhs) < 0 && (mpz_get_ui (rhs) & 1) == 0)
{
error = "cannot take even root orders of negative numbers";
mpz_clear (lhs); mpz_clear (rhs);
longjmp (errjmpbuf, 1);
}
{
unsigned long int nth = mpz_get_ui (rhs);
if (mpz_cmp_ui (rhs, ~(unsigned long int) 0) > 0)
{
/* If we are asked to take an awfully large root order, cheat and
ask for the largest order we can pass to mpz_root. This saves
some error prone special cases. */
nth = ~(unsigned long int) 0;
}
mpz_root (r, lhs, nth);
}
mpz_clear (lhs); mpz_clear (rhs);
return;
#endif
case FAC:
mpz_eval_expr (r, e->operands.ops.lhs);
if (mpz_size (r) > 1)
{
error = "result of `!' operator too large";
longjmp (errjmpbuf, 1);
}
mpz_fac_ui (r, mpz_get_ui (r));
return;
#if __GNU_MP_VERSION >= 2
case POPCNT:
mpz_eval_expr (r, e->operands.ops.lhs);
{ long int cnt;
cnt = mpz_popcount (r);
mpz_set_si (r, cnt);
}
return;
case HAMDIST:
{ long int cnt;
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
cnt = mpz_hamdist (lhs, rhs);
mpz_clear (lhs); mpz_clear (rhs);
mpz_set_si (r, cnt);
}
return;
#endif
case LOG2:
mpz_eval_expr (r, e->operands.ops.lhs);
{ unsigned long int cnt;
if (mpz_sgn (r) <= 0)
{
error = "logarithm of non-positive number";
longjmp (errjmpbuf, 1);
}
cnt = mpz_sizeinbase (r, 2);
mpz_set_ui (r, cnt - 1);
}
return;
case LOG:
{ unsigned long int cnt;
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
if (mpz_sgn (lhs) <= 0)
{
error = "logarithm of non-positive number";
mpz_clear (lhs); mpz_clear (rhs);
longjmp (errjmpbuf, 1);
}
if (mpz_cmp_ui (rhs, 256) >= 0)
{
error = "logarithm base too large";
mpz_clear (lhs); mpz_clear (rhs);
longjmp (errjmpbuf, 1);
}
cnt = mpz_sizeinbase (lhs, mpz_get_ui (rhs));
mpz_set_ui (r, cnt - 1);
mpz_clear (lhs); mpz_clear (rhs);
}
return;
case FERMAT:
{
unsigned long int t;
mpz_init (lhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
t = (unsigned long int) 1 << mpz_get_ui (lhs);
if (mpz_cmp_ui (lhs, ~(unsigned long int) 0) > 0 || t == 0)
{
error = "too large Mersenne number index";
mpz_clear (lhs);
longjmp (errjmpbuf, 1);
}
mpz_set_ui (r, 1);
mpz_mul_2exp (r, r, t);
mpz_add_ui (r, r, 1);
mpz_clear (lhs);
}
return;
case MERSENNE:
mpz_init (lhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
if (mpz_cmp_ui (lhs, ~(unsigned long int) 0) > 0)
{
error = "too large Mersenne number index";
mpz_clear (lhs);
longjmp (errjmpbuf, 1);
}
mpz_set_ui (r, 1);
mpz_mul_2exp (r, r, mpz_get_ui (lhs));
mpz_sub_ui (r, r, 1);
mpz_clear (lhs);
return;
case FIBONACCI:
{ mpz_t t;
unsigned long int n, i;
mpz_init (lhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
if (mpz_sgn (lhs) <= 0 || mpz_cmp_si (lhs, 1000000000) > 0)
{
error = "Fibonacci index out of range";
mpz_clear (lhs);
longjmp (errjmpbuf, 1);
}
n = mpz_get_ui (lhs);
mpz_clear (lhs);
#if __GNU_MP_VERSION > 2 || __GNU_MP_VERSION_MINOR >= 1
mpz_fib_ui (r, n);
#else
mpz_init_set_ui (t, 1);
mpz_set_ui (r, 1);
if (n <= 2)
mpz_set_ui (r, 1);
else
{
for (i = 3; i <= n; i++)
{
mpz_add (t, t, r);
mpz_swap (t, r);
}
}
mpz_clear (t);
#endif
}
return;
case RANDOM:
{
unsigned long int n;
mpz_init (lhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
if (mpz_sgn (lhs) <= 0 || mpz_cmp_si (lhs, 1000000000) > 0)
{
error = "random number size out of range";
mpz_clear (lhs);
longjmp (errjmpbuf, 1);
}
n = mpz_get_ui (lhs);
mpz_clear (lhs);
mpz_urandomb (r, rstate, n);
}
return;
case NEXTPRIME:
{
mpz_eval_expr (r, e->operands.ops.lhs);
mpz_nextprime (r, r);
}
return;
case BINOM:
mpz_init (lhs); mpz_init (rhs);
mpz_eval_expr (lhs, e->operands.ops.lhs);
mpz_eval_expr (rhs, e->operands.ops.rhs);
{
unsigned long int k;
if (mpz_cmp_ui (rhs, ~(unsigned long int) 0) > 0)
{
error = "k too large in (n over k) expression";
mpz_clear (lhs); mpz_clear (rhs);
longjmp (errjmpbuf, 1);
}
k = mpz_get_ui (rhs);
mpz_bin_ui (r, lhs, k);
}
mpz_clear (lhs); mpz_clear (rhs);
return;
case TIMING:
{
int t0;
t0 = cputime ();
mpz_eval_expr (r, e->operands.ops.lhs);
printf ("time: %d\n", cputime () - t0);
}
return;
default:
abort ();
}
}
int
main (int argc, char **argv)
{
struct expr *e;
int i;
mpz_t r;
int errcode = 0;
char *str;
int base = 10;
setup_error_handler ();
gmp_randinit (rstate, GMP_RAND_ALG_LC, 128);
{
#if HAVE_GETTIMEOFDAY
struct timeval tv;
gettimeofday (&tv, NULL);
gmp_randseed_ui (rstate, tv.tv_sec + tv.tv_usec);
#else
time_t t;
time (&t);
gmp_randseed_ui (rstate, t);
#endif
}
mpz_init (r);
while (argc > 1 && argv[1][0] == '-')
{
char *arg = argv[1];
if (arg[1] >= '0' && arg[1] <= '9')
break;
if (arg[1] == 't')
print_timing = 1;
else if (arg[1] == 'b' && arg[2] >= '0' && arg[2] <= '9')
{
base = atoi (arg + 2);
if (base < 2 || base > 62)
{
fprintf (stderr, "error: invalid output base\n");
exit (-1);
}
}
else if (arg[1] == 'b' && arg[2] == 0)
base = 2;
else if (arg[1] == 'x' && arg[2] == 0)
base = 16;
else if (arg[1] == 'X' && arg[2] == 0)
base = -16;
else if (arg[1] == 'o' && arg[2] == 0)
base = 8;
else if (arg[1] == 'd' && arg[2] == 0)
base = 10;
else if (arg[1] == 'v' && arg[2] == 0)
{
printf ("pexpr linked to gmp %s\n", __gmp_version);
}
else if (strcmp (arg, "-html") == 0)
{
flag_html = 1;
newline = "<br>";
}
else if (strcmp (arg, "-wml") == 0)
{
flag_wml = 1;
newline = "<br/>";
}
else if (strcmp (arg, "-split") == 0)
{
flag_splitup_output = 1;
}
else if (strcmp (arg, "-noprint") == 0)
{
flag_print = 0;
}
else
{
fprintf (stderr, "error: unknown option `%s'\n", arg);
exit (-1);
}
argv++;
argc--;
}
for (i = 1; i < argc; i++)
{
int s;
int jmpval;
/* Set up error handler for parsing expression. */
jmpval = setjmp (errjmpbuf);
if (jmpval != 0)
{
fprintf (stderr, "error: %s%s\n", error, newline);
fprintf (stderr, " %s%s\n", argv[i], newline);
if (! flag_html)
{
/* ??? Dunno how to align expression position with arrow in
HTML ??? */
fprintf (stderr, " ");
for (s = jmpval - (long) argv[i]; --s >= 0; )
putc (' ', stderr);
fprintf (stderr, "^\n");
}
errcode |= 1;
continue;
}
str = expr (argv[i], &e);
if (str[0] != 0)
{
fprintf (stderr,
"error: garbage where end of expression expected%s\n",
newline);
fprintf (stderr, " %s%s\n", argv[i], newline);
if (! flag_html)
{
/* ??? Dunno how to align expression position with arrow in
HTML ??? */
fprintf (stderr, " ");
for (s = str - argv[i]; --s; )
putc (' ', stderr);
fprintf (stderr, "^\n");
}
errcode |= 1;
free_expr (e);
continue;
}
/* Set up error handler for evaluating expression. */
if (setjmp (errjmpbuf))
{
fprintf (stderr, "error: %s%s\n", error, newline);
fprintf (stderr, " %s%s\n", argv[i], newline);
if (! flag_html)
{
/* ??? Dunno how to align expression position with arrow in
HTML ??? */
fprintf (stderr, " ");
for (s = str - argv[i]; --s >= 0; )
putc (' ', stderr);
fprintf (stderr, "^\n");
}
errcode |= 2;
continue;
}
if (print_timing)
{
int t;
TIME (t, mpz_eval_expr (r, e));
printf ("computation took %d ms%s\n", t, newline);
}
else
mpz_eval_expr (r, e);
if (flag_print)
{
size_t out_len;
char *tmp, *s;
out_len = mpz_sizeinbase (r, base >= 0 ? base : -base) + 2;
#ifdef LIMIT_RESOURCE_USAGE
if (out_len > 100000)
{
printf ("result is about %ld digits, not printing it%s\n",
(long) out_len - 3, newline);
exit (-2);
}
#endif
tmp = malloc (out_len);
if (print_timing)
{
int t;
printf ("output conversion ");
TIME (t, mpz_get_str (tmp, base, r));
printf ("took %d ms%s\n", t, newline);
}
else
mpz_get_str (tmp, base, r);
out_len = strlen (tmp);
if (flag_splitup_output)
{
for (s = tmp; out_len > 80; s += 80)
{
fwrite (s, 1, 80, stdout);
printf ("%s\n", newline);
out_len -= 80;
}
fwrite (s, 1, out_len, stdout);
}
else
{
fwrite (tmp, 1, out_len, stdout);
}
free (tmp);
printf ("%s\n", newline);
}
else
{
printf ("result is approximately %ld digits%s\n",
(long) mpz_sizeinbase (r, base >= 0 ? base : -base),
newline);
}
free_expr (e);
}
exit (errcode);
}
main (int argc, char **argv)
{
struct expr *e;
int i;
mpz_t r;
int errcode = 0;
char *str;
int base = 10;
#if !defined(_WIN32) && !defined(__DJGPP__)
setup_error_handler ();
#endif
mpz_init (r);
while (argc > 1 && argv[1][0] == '-')
{
char *arg = argv[1];
if (arg[1] >= '0' && arg[1] <= '9')
break;
if (arg[1] == 't')
print_timing = 1;
else if (arg[1] == 'b' && arg[2] >= '0' && arg[2] <= '9')
{
base = atoi (arg + 2);
if (base < 2 || base > 36)
{
fprintf (stderr, "error: invalid output base\n");
exit (-1);
}
}
else if (arg[1] == 'b' && arg[2] == 0)
base = 2;
else if (arg[1] == 'x' && arg[2] == 0)
base = 16;
else if (arg[1] == 'o' && arg[2] == 0)
base = 8;
else if (arg[1] == 'd' && arg[2] == 0)
base = 10;
else if (strcmp (arg, "-html") == 0)
{
flag_html = 1;
newline = "<BR>";
}
else if (strcmp (arg, "-split") == 0)
{
flag_splitup_output = 1;
}
else if (strcmp (arg, "-noprint") == 0)
{
flag_print = 0;
}
else
{
fprintf (stderr, "error: unknown option `%s'\n", arg);
exit (-1);
}
argv++;
argc--;
}
for (i = 1; i < argc; i++)
{
int s;
int jmpval;
/* Set up error handler for parsing expression. */
jmpval = setjmp (errjmpbuf);
if (jmpval != 0)
{
fprintf (stderr, "error: %s%s\n", error, newline);
fprintf (stderr, " %s%s\n", argv[i], newline);
if (! flag_html)
{
/* ??? Dunno how to align expression position with arrow in
HTML ??? */
fprintf (stderr, " ");
for (s = jmpval - (long) argv[i]; --s >= 0; )
putc (' ', stderr);
fprintf (stderr, "^\n");
}
errcode |= 1;
continue;
}
str = expr (argv[i], &e);
if (str[0] != 0)
{
fprintf (stderr,
"error: garbage where end of expression expected%s\n",
newline);
fprintf (stderr, " %s%s\n", argv[i], newline);
if (! flag_html)
{
/* ??? Dunno how to align expression position with arrow in
HTML ??? */
fprintf (stderr, " ");
for (s = str - argv[i]; --s; )
putc (' ', stderr);
fprintf (stderr, "^\n");
}
errcode |= 1;
free_expr (e);
continue;
}
/* Set up error handler for evaluating expression. */
if (setjmp (errjmpbuf))
{
fprintf (stderr, "error: %s%s\n", error, newline);
fprintf (stderr, " %s%s\n", argv[i], newline);
if (! flag_html)
{
/* ??? Dunno how to align expression position with arrow in
HTML ??? */
fprintf (stderr, " ");
for (s = str - argv[i]; --s >= 0; )
putc (' ', stderr);
fprintf (stderr, "^\n");
}
errcode |= 2;
continue;
}
{
int t0;
if (print_timing)
t0 = cputime ();
mpz_eval_expr (r, e);
if (print_timing)
printf ("computation took %d ms%s\n", cputime () - t0, newline);
}
if (flag_print)
{
size_t out_len;
char *tmp, *s;
int t0;
out_len = mpz_sizeinbase (r, base) + 1;
tmp = malloc (out_len);
if (print_timing)
t0 = cputime ();
if (print_timing)
/* Print first half of message... */
printf ("output conversion ");
mpz_get_str (tmp, -base, r);
if (print_timing)
/* ...print 2nd half of message unless we caught a time limit
and therefore longjmp'ed */
printf ("took %d ms%s\n", cputime () - t0, newline);
out_len = strlen (tmp);
if (flag_splitup_output)
{
for (s = tmp; out_len > 60; s += 60)
{
fwrite (s, 1, 60, stdout);
printf ("%s\n", newline);
out_len -= 60;
}
fwrite (s, 1, out_len, stdout);
}
else
{
fwrite (tmp, 1, out_len, stdout);
}
free (tmp);
printf ("%s\n", newline);
}
else
{
printf ("result is approximately %ld digits%s\n",
(long) mpz_sizeinbase (r, 10), newline);
}
free_expr (e);
}
exit (errcode);
}
