```
#include <cstdint>
// --------------------------------------------------------------------------
// Return number of decimal-digits of a given unsigned-integer
// N is unit8_t/uint16_t/uint32_t/uint64_t
template <class N> inline uint8_t GetUnsignedDecDigits(const N n)
{
static_assert(std::numeric_limits<N>::is_integer && !std::numeric_limits<N>::is_signed,
"GetUnsignedDecDigits: unsigned integer type expected" );
const uint8_t anMaxDigits[]= {3, 5, 8, 10, 13, 15, 17, 20};
const uint8_t nMaxDigits = anMaxDigits[sizeof(N)-1];
uint8_t nDigits= 1;
N nRoof = 10;
while ((n >= nRoof) && (nDigits<nMaxDigits))
{
nDigits++;
nRoof*= 10;
}
return nDigits;
}
// --------------------------------------------------------------------------
// Convert floating-point value to NULL-terminated string represention
TCHAR* DoubleToStr(double f , // [i ]
TCHAR* pczStr , // [i/o] caller should allocate enough space
int nDigitsI, // [i ] digits of integer part including sign / <1: auto
int nDigitsF ) // [i ] digits of fractional part / <0: auto
{
switch (_fpclass(f))
{
case _FPCLASS_SNAN:
case _FPCLASS_QNAN: _tcscpy_s(pczStr, 5, _T("NaN" )); return pczStr;
case _FPCLASS_NINF: _tcscpy_s(pczStr, 5, _T("-INF")); return pczStr;
case _FPCLASS_PINF: _tcscpy_s(pczStr, 5, _T("+INF")); return pczStr;
}
if (nDigitsI> 18) nDigitsI= 18; if (nDigitsI< 1) nDigitsI= -1;
if (nDigitsF> 18) nDigitsF= 18; if (nDigitsF< 0) nDigitsF= -1;
bool bNeg= (f<0);
if (f<0)
f= -f;
int nE= 0; // exponent (displayed if != 0)
if ( ((-1 == nDigitsI) && (f >= 1e18 )) || // large value: switch to scientific representation
((-1 != nDigitsI) && (f >= pow(10., nDigitsI))) )
{
nE= (int)log10(f);
f/= (double)pow(10., nE);
if (-1 != nDigitsF)
nDigitsF= __max(nDigitsF, nDigitsI+nDigitsF-(bNeg?2:1)-4);
nDigitsI= (bNeg?2:1);
}
else if (f>0)
if ((-1 == nDigitsF) && (f <= 1e-10)) // small value: switch to scientific representation
{
nE= (int)log10(f)-1;
f/= (double)pow(10., nE);
if (-1 != nDigitsF)
nDigitsF= __max(nDigitsF, nDigitsI+nDigitsF-(bNeg?2:1)-4);
nDigitsI= (bNeg?2:1);
}
double fI;
double fF= modf(f, &fI); // fI: integer part, fF: fractional part
if (-1 == nDigitsF) // figure out number of meaningfull digits in fF
{
double fG, fGI, fGF;
do
{
nDigitsF++;
fG = fF*pow(10., nDigitsF);
fGF= modf(fG, &fGI);
}
while (fGF > 1e-10);
}
const double afPower10[20]= {1e0 , 1e1 , 1e2 , 1e3 , 1e4 , 1e5 , 1e6 , 1e7 , 1e8 , 1e9 ,
1e10, 1e11, 1e12, 1e13, 1e14, 1e15, 1e16, 1e17, 1e18, 1e19 };
uint64_t uI= (uint64_t)round(fI );
uint64_t uF= (uint64_t)round(fF*afPower10[nDigitsF]);
if (uF)
if (GetUnsignedDecDigits(uF) > nDigitsF) // X.99999 was rounded to X+1
{
uF= 0;
uI++;
if (nE)
{
uI/= 10;
nE++;
}
}
uint8_t nRealDigitsI= GetUnsignedDecDigits(uI);
if (bNeg)
nRealDigitsI++;
int nPads= 0;
if (-1 != nDigitsI)
{
nPads= nDigitsI-nRealDigitsI;
for (int i= nPads-1; i>=0; i--) // leading spaces
pczStr[i]= _T(' ');
}
if (bNeg) // minus sign
{
pczStr[nPads]= _T('-');
nRealDigitsI--;
nPads++;
}
for (int j= nRealDigitsI-1; j>=0; j--) // digits of integer part
{
pczStr[nPads+j]= (uint8_t)(uI%10) + _T('0');
uI /= 10;
}
nPads+= nRealDigitsI;
if (nDigitsF)
{
pczStr[nPads++]= _T('.'); // decimal point
for (int k= nDigitsF-1; k>=0; k--) // digits of fractional part
{
pczStr[nPads+k]= (uint8_t)(uF%10)+ _T('0');
uF /= 10;
}
}
nPads+= nDigitsF;
if (nE)
{
pczStr[nPads++]= _T('e'); // exponent sign
if (nE<0)
{
pczStr[nPads++]= _T('-');
nE= -nE;
}
else
pczStr[nPads++]= _T('+');
for (int l= 2; l>=0; l--) // digits of exponent
{
pczStr[nPads+l]= (uint8_t)(nE%10) + _T('0');
nE /= 10;
}
pczStr[nPads+3]= 0;
}
else
pczStr[nPads]= 0;
return pczStr;
}
```