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I am trying to convert a double to a string in a native NT application, i.e. an application that only depends on ntdll.dll. Unfortunately, ntdll's version of vsnprintf does not support %f et al., forcing me to implement the conversion on my own.

The aforementioned ntdll.dll exports only a few of the math.h functions (floor, ceil, log, pow, ...). However, I am reasonably sure that I can implement any of the unavailable math.h functions if necessary.

There is an implementation of floating point conversion in GNU's libc, but the code is extremely dense and difficult to comprehent (the GNU indentation style does not help here).

I've already implemented the conversion by normalizing the number (i.e. multiplying/dividing the number by 10 until it's in the interval [1, 10)) and then generating each digit by cutting the integral part off with modf and multiplying the fractional part by 10. This works, but there is a loss of precision (only the first 15 digits are correct). The loss of precision is, of course, inherent to the algorithm.

I'd settle with 17 digits, but an algorithm that would be able to generate an arbitrary number of digits correctly would be preferred.

Could you please suggest an algorithm or point me to a good resource?

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"the GNU indentation style does not help here": use indent ( ), there's a version for Windows ( ) which I haven't tested. –  pmg Sep 16 '09 at 18:16
Thank you, pmg, the indentation is not the only flaw of the code in question, unfortunately. –  avakar Sep 16 '09 at 18:33
I've written an article about the inaccurate conversion method you describe -- in case, one year later, you still care:… –  Rick Regan Nov 12 '10 at 18:24

7 Answers 7

Double-precision numbers do not have more than 15 significant (decimal) figures of precision. There is absolutely no way you can get "an arbitrary number of digits correctly"; doubles are not bignums.

Since you say you're happy with 17 significant figures, use long double; on Windows, I think, that will give you 19 significant figures.

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You can't use doubles to represent rational numbers with precision. Instead, you have to have two integers (possibly longs), to represent the numerator and denominator independently. –  Chris Jester-Young Sep 16 '09 at 18:04
As for roundtripping, you should serialise your double in binary form, not decimal. –  Chris Jester-Young Sep 16 '09 at 18:05
A double doesn't have arbitrary precision. You're losing precision, because a double is incapable of representing it. –  greyfade Sep 16 '09 at 18:14
No, you won't get an infinite number of decimal digits. Why? Because no ratio where the denominator is a power of two ever gives a recurring decimal representation. –  Chris Jester-Young Sep 16 '09 at 18:30
@Avakar: seems you need a question on "why don't I get an infinite number of decimal digits with a floating point representation?" :) –  xtofl Sep 16 '09 at 18:33

I've thought about this a bit more. You lose precision because you normalize by multiplying by some power of 10 (you chose [1,10) rather than [0,1), but that's a minor detail). If you did so with a power of 2, you'd lose no precision, but then you'd get "decimal digits"*2^e; you could implement bcd arithmetic and compute the product yourself, but that doesn't sound like fun.

I'm pretty confident that you could split the double g=m*2^e into two parts: h=floor(g*10^k) and i=modf(g*10^k) for some k, and then separately convert to decimal digits and then stitch them together, but how about a simpler approach: use "long double" (80 bits, but I've heard that Visual C++ may not support it?) with your current approach and stop after 17 digits.

_gcvt should do it (edit - it's not in ntdll.dll, it's in some msvcrt*.dll?)

As for decimal digits of precision, IEEE binary64 has 52 binary digits. 52*log10(2)=15.65... (edit: as you pointed out, to round trip, you need more than 16 digits)

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Thank you wrang-wrang. Unfortunately, I don't have _gcvt available in native. Regarding the 15.65 value, it only means that you can represent a number with 15 digits precisely in double. For round-tripping, however, you need 17 digits. –  avakar Sep 16 '09 at 18:14
I agree that more than log10(2)*d decimal digits are needed to exactly represent a d-bit fraction on [0,1), e.g. 1/16 = (.1111)_2 = .9375, which is 4 decimal digits for 4 binary digits. –  Jonathan Graehl Sep 16 '09 at 19:10
Yes, I suppose having greater precision would give me those 17 digits. Unfortunately, long double is equivalent to double in msvc (at least in msvc9). –  avakar Sep 16 '09 at 19:37
Regarding converting integral and fractional parts separately: remember that doubles can go as high as 1.e308. I'll lose the 17th digit as soon as I perform the first non-power-of-two multiplication. –  avakar Sep 16 '09 at 19:39
up vote 3 down vote accepted

After a lot of research, I found a paper titled Printing Floating-Point Numbers Quickly and Accurately. It uses exact rational arithmetic to avoid precision loss. It cites a little older paper: How to Print Floating-Point Numbers Accurately, which however seems to require ACM subscription to access.

Since the former paper was reprinted in 2006, I am inclined to believe that it is still current. The exact rational arithmetic (which requires dynamic allocation) seems to be a necessary evil.

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The link is broken for first URL. Use this instead:… –  srm Feb 6 '14 at 20:41
And here is the full C code implementation of this algorithm on SourceForge:… –  srm Feb 6 '14 at 22:42

A complete implementation of the C code for the fastest known (as of today) algorithm:

It even includes a test suite.

This is the C code behind the algorithm described in this PDF: Printing Floating-Point Numbers Quickly and Accurately

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#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))
        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;
            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;

            if (nE)
                uI/= 10;

    uint8_t nRealDigitsI= GetUnsignedDecDigits(uI);
    if (bNeg)

    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('-');

    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;
            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;
        pczStr[nPads]= 0;

    return pczStr;
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These two lines will never execute. They're mutually exclusive with the outer "if" test. Bug? if (-1 != nDigitsF) nDigitsF= max(nDigitsF, nDigitsI+nDigitsF-(bNeg?2:1)-4); –  srm Feb 6 '14 at 19:58
Also, what is "afPower10"? –  srm Feb 6 '14 at 20:39
@srm: thank you, afPower10 was added –  Lior Kogan Feb 7 '14 at 7:25
@srm: Why are these lines mutually exclusive? the outer if is about nDigitsI and the inner if is about nDigitsF. –  Lior Kogan Feb 7 '14 at 7:29
my mistake. I got the I and F messed up while reading the code. I know it would expand the text, but variable names that are almost identical except for a single letter are really hard to follow. I found it easier to follow some of your logic once I text substituted "Integral" for "I" and "Fraction" for "F". That preserves the "both are the same length" quality of the variable names and provides more of a guard against mis-reading an "I" as an "F" or vice versa. I realize that English majors will cringe that I used the adjective form for I and the noun form for F. :-) –  srm Apr 21 '14 at 3:00

Does vsnprintf supports I64?

double x = SOME_VAL; // allowed to be from -1.e18 to 1.e18
bool sign = (SOME_VAL < 0);
if ( sign ) x = -x;
__int64 i = static_cast<__int64>( x );
double xm = x - static_cast<double>( i );
__int64 w = static_cast<__int64>( xm*pow(10.0, DIGITS_VAL) ); // DIGITS_VAL indicates how many digits after the decimal point you want to get

char out[100];
vsnprintf( out, sizeof out, "%s%I64.%I64", (sign?"-":""), i, w );

Another option is to try to find implementation of gcvt.

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That's pretty fast and simple, except it fails when the exponent is large or small, or the number is negative. –  Jonathan Graehl Sep 16 '09 at 18:03
Fixed for negative numbers. –  Kirill V. Lyadvinsky Sep 16 '09 at 18:06
Kirill, thank you. Unfortunately, I need to support numbers up to and above 1.e308 :) –  avakar Sep 16 '09 at 18:28
@avakar, then my answer is not suitable to you :) –  Kirill V. Lyadvinsky Sep 16 '09 at 18:35

Have you looked at the uClibc implementation of printf?

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Thanks for the pointer, caf. I've looked into it and it seems they use similar algorithm as I do, although they extract more than one digit at each step. I'm inclined to believe that they lose precision the same way I do. –  avakar Sep 17 '09 at 11:58

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