#include <ctype.h>
#include <stdlib.h>
#include <gm.h>
extern "C"
{
double pow (double, double);
} // Should be #include <math.h>
#include <strings.h>
#include <real.h>
HIDDEN real __tmp_real;
HIDDEN char __string[80];
const real ZERO (0.0);
real::real ()
{
dzero (ptr ());
}
real::real (const real & b)
{
dcpy (ptr (), b.ptr ());
}
real::real (double a)
{
dftodr (ptr (), a, 9); // Round the number (1.0 is NOT 0.999999999)
deltrz (ptr (), ptr ()); // Delete Trailing zeroes
}
char *real::eng2ita (char *s)
{
if (s)
{
char *dot = strchr (s, '.');
if (dot)
*dot = ',';
}
return s;
}
char *real::ita2eng (const char *s)
{
int j = 0;
if (s)
for (int i = 0; s[i]; i++)
{
switch (s[i])
{
case ' ':
case '.':
break;
case ',':
__string[j++] = '.';
break;
default:
__string[j++] = s[i];
break;
}
}
__string[j] = '\0';
return __string;
}
bool real::is_real (const char *s)
{
bool ok = FALSE;
if (s)
{
while (*s == ' ')
s++; // Remove leading spaces before atod
ok = atod (__tmp_real.ptr (), (char *) s) != GM_NULL;
}
return ok;
}
real::real (const char *s)
{
if (s)
while (*s == ' ')
s++; // Remove leading spaces before atod
if (s && *s)
atod (ptr (), (char *) s);
else
dzero (ptr ());
}
real & real::operator = (const real & b)
{
dcpy (ptr (), b.ptr ());
return *this;
}
real & real::operator = (double a)
{
const real n (a);
operator = (n);
return *this;
}
real & real::operator += (const real & b)
{
dadd (ptr (), ptr (), b.ptr ());
return *this;
}
real & real::operator += (double a)
{
__tmp_real = *this;
adddfd (ptr (), __tmp_real.ptr (), a);
return *this;
}
real & real::operator -= (const real & b)
{
__tmp_real = *this;
dsub (ptr (), __tmp_real.ptr (), b.ptr ());
return *this;
}
real & real::operator *= (const real & b)
{
dmul (ptr (), ptr (), b.ptr ());
return *this;
}
real & real::operator /= (const real & b)
{
const DEC *dst = ddiv (ptr (), ptr (), b.ptr ());
#ifdef DBG
if (dst == GM_NULL)
{
errname (__string, gmec ());
error_box ("Division error: %s", __string);
}
#endif
return *this;
}
TObject *real:: dup () const
{
return new real (*this);
}
bool real::is_zero () const
{
return diszero (ptr ());
}
int real::sign () const
{
return dsign (ptr ());
}
real real::operator - () const
{
real n;
dchgs (n.ptr (), ptr ());
return n;
}
long real::integer () const
{
return (long)dtodf(ptr ());
}
// Certified 91%
char *real::string (int len, int dec, char pad) const
{
__tmp_real = *this;
if (dec != UNDEFINED)
__tmp_real.round (dec);
else
deltrz (__tmp_real.ptr (), __tmp_real.ptr ());
dtoa (__string, __tmp_real.ptr ());
int lun = strlen (__string);
if (lun < len)
{
const int delta = len - lun;
for (int i = lun; i >= 0; i--)
__string[i + delta] = __string[i];
for (i = 0; i < delta; i++)
__string[i] = pad;
}
return __string;
}
// Certified 99%
char *real ::stringa (int len, int dec, char pad) const
{
string (len, dec, pad);
if (dec > 0 || dec == UNDEFINED)
eng2ita (__string);
return __string;
}
// Certified 75%
char *real ::literals () const
{
const char *primi20[] =
{"", "uno", "due", "tre", "quattro",
"cinque", "sei", "sette", "otto",
"nove", "dieci", "undici", "dodici",
"tredici", "quattordici", "quindici", "sedici",
"diciassette", "diciotto", "diciannove"};
const char *decine[] =
{"zero", "dieci", "venti", "trenta", "quaranta",
"cinquanta", "sessanta", "settanta", "ottanta",
"novanta", "cento"};
const char *uni[] =
{"uno", "mille", "unmilione", "unmiliardo"};
const char *potenze[] =
{"", "mila", "milioni", "miliardi"};
__tmp_real = *this;
__tmp_real.round (0);
TString80 r (__tmp_real.string (0, 0));
const bool negativo = r[0] == '-';
if (negativo)
r.ltrim (1);
TFixed_string risultato (__string, 80);
risultato.cut (0);
TString16 centinaia;
for (int migliaia = 0;; migliaia++)
{
int v = r.len () - 3;
if (v < -2)
break;
if (v < 0)
v = 0;
const int val = atoi (&r[v]);
r.cut (v); // Elimina ultimi 3 caratteri
v = val;
if (v >= 100)
{
const int c = v / 100;
if (c > 1)
centinaia = primi20[c];
else
centinaia.cut (0);
v -= c * 100;
centinaia << "cento";
}
const int d = v / 10;
if (d > 1)
{
centinaia << decine[d];
v -= d * 10;
}
if (v != 1)
{
centinaia << primi20[v] << potenze[migliaia];
}
else if (val > 1)
{
if (d > 1)
centinaia.cut (centinaia.len () - 1);
centinaia << "un" << (migliaia ? potenze[migliaia] : "o");
}
else
centinaia = uni[migliaia];
risultato.insert (centinaia, 0);
}
if (negativo)
risultato.insert ("meno", 0);
return __string;
}
// Certified 75%
char *real ::points (int dec) const
{
const char *str = stringa ();
const int neg = (*str == '-') ? 1 : 0;
TFixed_string n ((char *) str, 24);
int i;
int dot = n.find (',');
if (dot < 0)
dot = n.len ();
if (dec > 0)
{
if (n[dot] == '\0')
n << ',';
const int d = strlen (str + dot + 1); // Decimals already
// there
if (d <= dec)
for (i = d; i < dec; i++)
n << '0';
else
n.cut (dot + dec + 1);
}
for (i = dot - 3; i > neg; i -= 3)
n.insert (".", i);
return __string;
}
HIDDEN int get_picture_decimals (const TString& picture)
{
int decimali = 0;
const int virgola = picture.find (',');
if (virgola >= 0)
{
const int len = picture.len ();
for (int i = virgola + 1; i < len; i++)
if (strchr ("#@~", picture[i]))
decimali++;
}
return decimali;
}
char *real ::string (const char *picture)
const
{
if (*picture == '\0')
return string ();
if (*picture == '.')
return points (atoi (picture + 1));
if (strcmp (picture, "LETTERE") == 0)
return literals ();
TString80 v (string());
TString80 f (picture);
const int voluti = get_picture_decimals (f);
const int virgola = v.find ('.');
int decimali = (virgola >= 0) ? v.len () - virgola - 1 : 0;
for (; voluti > decimali; decimali++)
v << '@';
if (voluti < decimali)
v.cut (virgola + voluti + (voluti > 0));
int j = v.len () - 1;
for (int i = f.len () - 1; i >= 0 && j >= 0; i--)
{
char &z = f[i];
if (strchr ("#@~", z))
{
char c = v[j--];
if (j >= 0 && v[j] == '.')
j--;
if (z == '~')
c = ' ';
else if (c == '@')
c = (z == '@') ? '0' : ' ';
z = c;
}
}
for (; i >= 0; i--)
switch (f[i])
{
case '#':
case '~':
case '.':
f[i] = ' ';
break;
case '@':
f[i] = '0';
break;
default:
break;
}
return strcpy (__string, f);
}
ostream & operator << (ostream & out, const real & a)
{
return out << a.string ();
}
istream & operator >> (istream & in, real & a)
{
in >> __string;
atod (a.ptr (), __string);
return in;
}
int real ::precision ()
{
return dprec (ptr ());
}
real & real ::round (int prec)
{
if (prec < 0)
{
const double p = ::pow (10.0, -prec);
divdfd (ptr (), ptr (), p);
dround (ptr (), ptr (), 0);
muldfd (ptr (), ptr (), p);
}
else
dround (ptr (), ptr (), prec);
return *this;
}
real & real ::ceil (int prec)
{
double p = 1.0;
if (prec != 0)
{
p = ::pow (10.0, -prec);
divdfd (ptr (), ptr (), p);
}
DEC integer;
dint (&integer, ptr ()); // Extract the integer part
if (disgt (ptr (), &integer)) // If positive ...
addid (ptr (), &integer, 1); // add 1
else
dcpy(ptr(), &integer); // If negative
if (prec != 0)
muldfd (ptr (), ptr (), p);
return *this;
}
real & real ::trunc (int prec)
{
dtrunc (ptr (), ptr (), prec);
return *this;
}
real operator + (const real & a, const real & b)
{
dadd (__tmp_real.ptr (), a.ptr (), b.ptr ());
return __tmp_real;
}
real operator + (double a, const real & b)
{
__tmp_real = a;
return __tmp_real += b;
}
real operator + (const real & a, double b)
{
__tmp_real = a;
return __tmp_real += b;
}
real operator - (const real & a, const real & b)
{
dsub (__tmp_real.ptr (), a.ptr (), b.ptr ());
return __tmp_real;
}
real operator - (double a, const real & b)
{
__tmp_real = a;
dsub (__tmp_real.ptr (), __tmp_real.ptr (), b.ptr ());
return __tmp_real;
}
real operator - (const real & a, double b)
{
__tmp_real = b;
return __tmp_real -= a;
}
real operator *(const real & a, const real & b)
{
dmul (__tmp_real.ptr (), a.ptr (), b.ptr ());
return __tmp_real;
}
real operator *(double a, const real & b)
{
muldfd (__tmp_real.ptr (), b.ptr (), a);
return __tmp_real;
}
real operator *(const real & a, double b)
{
muldfd (__tmp_real.ptr (), a.ptr (), b);
return __tmp_real;
}
real operator / (const real & a, const real & b)
{
ddiv (__tmp_real.ptr (), a.ptr (), b.ptr ());
return __tmp_real;
}
real operator / (double a, const real & b)
{
__tmp_real = a;
ddiv (__tmp_real.ptr (), __tmp_real.ptr (), b.ptr ());
return __tmp_real;
}
real operator / (const real & a, double b)
{
__tmp_real = b;
ddiv (__tmp_real.ptr (), a.ptr (), __tmp_real.ptr ());
return __tmp_real;
}
bool operator > (const real & a, const real & b)
{
return disgt (a.ptr (), b.ptr ());
}
bool operator > (double a, const real & b)
{
// dftod(__tmp_real.ptr(), a);
// return disgt(__tmp_real.ptr(), b.ptr());
const double n = dtodf (b.ptr ());
return a > n;
}
bool operator < (const real & a, const real & b)
{
return dislt (a.ptr (), b.ptr ());
}
bool operator < (double a, const real & b)
{
// dftod(__tmp_real.ptr(), a);
// return dislt(__tmp_real.ptr(), b.ptr());
const double n = dtodf (b.ptr ());
return a < n;
}
bool operator >= (const real & a, const real & b)
{
return disge (a.ptr (), b.ptr ());
}
bool operator >= (double a, const real & b)
{
// dftod(__tmp_real.ptr(), a);
// return disge(__tmp_real.ptr(), b.ptr());
const double n = dtodf (b.ptr ());
return a >= n;
}
bool operator <= (const real & a, const real & b)
{
return disle (a.ptr (), b.ptr ());
}
bool operator <= (double a, const real & b)
{
// dftod(__tmp_real.ptr(), a);
// return disle(__tmp_real.ptr(), b.ptr());
const double n = dtodf (b.ptr ());
return a <= n;
}
bool operator == (const real & a, const real & b)
{
return diseq (a.ptr (), b.ptr ());
}
bool operator == (double a, const real & b)
{
const double n = dtodf (b.ptr ());
return a == n;
}
bool operator != (const real & a, const real & b)
{
return !diseq (a.ptr (), b.ptr ());
}
bool operator != (double a, const real & b)
{
const double n = dtodf (b.ptr ());
return a != n;
}
real operator % (const real & a, const long b)
{
dmodl (__tmp_real.ptr (), a.ptr (), b);
return __tmp_real;
}
void swap (real & a, real & b)
{
SwapDecimal (a.ptr (), b.ptr ());
}
real fnc_min (const real & a, const real & b)
{
dmin (__tmp_real.ptr (), a.ptr (), b.ptr ());
return __tmp_real;
}
real fnc_max (const real & a, const real & b)
{
dmax (__tmp_real.ptr (), a.ptr (), b.ptr ());
return __tmp_real;
}
real sqrt (const real & a)
{
dsqrt (__tmp_real.ptr (), a.ptr ());
return __tmp_real;
}
real sqr (const real & a)
{
dmul (__tmp_real.ptr (), a.ptr (), a.ptr ());
return __tmp_real;
}
real exp10 (const real & a)
{
dalog (__tmp_real.ptr (), a.ptr ());
return __tmp_real;
}
real pow (const real & a, const real & b)
{
dpow (__tmp_real.ptr (), a.ptr (), b.ptr ());
return __tmp_real;
}
real exp (const real & a)
{
dexp (__tmp_real.ptr (), a.ptr ());
return __tmp_real;
}
real log10 (const real & a)
{
dlog (__tmp_real.ptr (), a.ptr ());
return __tmp_real;
}
real log (const real & a)
{
dln (__tmp_real.ptr (), a.ptr ());
return __tmp_real;
}
real sin (const real & a)
{
dsin (__tmp_real.ptr (), a.ptr ());
return __tmp_real;
}
real cos (const real & a)
{
dcos (__tmp_real.ptr (), a.ptr ());
return __tmp_real;
}
real tan (const real & a)
{
dtan (__tmp_real.ptr (), a.ptr ());
return __tmp_real;
}
real abs (const real & a)
{
dabs (__tmp_real.ptr (), a.ptr ());
return __tmp_real;
}
///////////////////////////////////////////////////////////
// Distrib
// Oggetto per dividere un real in varie sue percentuali
// in modo che la loro somma dia sempre il real di partenza
// /////////////////////////////////////////////////////////
void TDistrib ::add (real slice)
{
if (slice > real (1.0))
slice /= 100.0;
CHECK (!_ready, "TDistrib: les jeux sont faits");
_slices.add (slice);
}
real TDistrib::get ()
{
_ready = TRUE;
CHECK (_current < _slices.items (), "TDistrib: too many gets");
real r = _tot * ((real &) _slices[_current++]);
r.round (_decs);
if (r > _tot - _prog)
{
r = _tot - _prog; _prog = _tot;
}
else
_prog += r;
return r;
}
void TDistrib::init (const real & r, bool zap)
{
_current = 0; _prog = 0;
_tot = r; _ready = FALSE;
if (zap) _slices.destroy();
}