First of all, this is not a floating point newbie question. I know results of floating point arithmetic (not to mention transcendental functions) usually cannot be represented exactly, and that most terminating decimals cannot be represented exactly as binary floating point numbers.

That said, each possible floating point value corresponds exactly to a diadic rational (a rational number p/q where q is a power of 2), which in turn has an exact decimal representation.

My question is: How do you find this exact decimal representation efficiently? sprintf and similar functions are usually only specified up to a number of significant digits to uniquely determine the original floating point value; they don't necessarily print the exact decimal representation. I know one algorithm I've used, but it's very slow, O(e^2) where e is the exponent. Here's an outline:

  1. Convert the mantissa to a decimal integer. You can either do this by pulling apart the bits to read the mantissa directly, or you can write a messy floating point loop that first multiplies the value by a power of two to put it in the range 1<=x<10, then pulls off a digit at a time by casting to int, subtracting, and multiplying by 10.
  2. Apply the exponent by repeatedly multiplying or dividing by 2. This is an operation on the string of decimal digits you generated. Every ~3 multiplications will add an extra digit to the left. Every single dividion will add an extra digit to the right.

Is this really the best possible? I doubt it, but I'm not a floating-point expert and I can't find a way to do the base-10 computations on the floating point representation of the number without running into a possibility of inexact results (multiplying or dividing by anything but a power of 2 is a lossy operation on floating point numbers unless you know you have free bits to work with).

  • In the end, I simply replaced my old base-10 code with base-1e9 and repeated multiplication/division by 2 with mult by 2^29 and div by 2^9 for most of the iterations followed by mult/div by 2 for the tail. The resulting code prints the smallest 80-bit long double in fairly negligible time, so I'm happy enough. – R.. Jul 30 '10 at 23:59
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    Jon Skeet has a DoubleConverter class that can print the exact decimal representations. It's written in C# but you can convert it to C stackoverflow.com/questions/4732680/… – phuclv Jun 21 '14 at 11:02

10 Answers 10


This question has a bureaucratic part and an algorithmic part. A floating point number is stored internally as (2e × m), where e is an exponent (itself in binary) and m is a mantissa. The bureaucratic part of the question is how to access this data, but R. seems more interested in the algorithmic part of the question, namely converting (2e × m) to a fraction (a/b) in decimal form. The answer to the bureaucratic question in several languages is "frexp" (which is an interesting detail that I didn't know before today).

It is true that at first glance, it takes O(e2) work just to write 2e in decimal, and more time still for the mantissa. But, thanks to the magic of the Schonhage-Strassen fast multiplication algorithm, you can do it in Õ(e) time, where the tilde means "up to log factors". If you view Schonhage-Strassen as magic, then it's not that hard to think of what to do. If e is even, you can recursively compute 2e/2, and then square it using fast multiplication. On the other hand if e is odd, you can recursively compute 2e-1 and then double it. You have to be careful to check that there is a version of Schonhage-Strassen in base 10. Although it is not widely documented, it can be done in any base.

Converting a very long mantissa from binary to base 10 is not exactly the same question, but it has a similar answer. You can divide the mantissa into two halves, m = a 2k + b. Then recursively convert a and b to base 10, convert 2^k to base 10, and do another fast multiplication to compute m in base 10.

The abstract result behind all of this is that you can convert integers from one base to another in Õ(N) time.

If the question is about standard 64-bit floating point numbers, then it's too small for the fancy Schonhage-Strassen algorithm. In this range you can instead save work with various tricks. One approach is to store all 2048 values of 2e in a lookup table, and then work in the mantissa with asymmetric multiplication (in between long multiplication and short multiplication). Another trick is to work in base 10000 (or a higher power of 10, depending on architecture) instead of base 10. But, as R. points out in the comments, 128-bit floating point numbers already allow large enough exponents to call into question both lookup tables and standard long multiplication. As a practical matter, long multiplication is the fastest up to a handful of digits, then in a significant medium range one can use Karatsuba multiplication or Toom-Cook multiplication, and then after that a variation of Schonhage-Strassen is best not just in theory but also in practice.

Actually, the big integer package GMP already has Õ(N) time radix conversion, as well as good heuristics for which choice of multiplication algorithm. The only difference between their solution and mine is that instead of doing any big arithmetic in base 10, they compute large powers of 10 in base 2. In this solution, they also need fast division, but that can be obtained from fast multiplication in any of several ways.

  • Thanks for the link and the first answer with any theoretical content! It looks like Toom-Cook might actually be the preferable algorithm for non-astronomical-exponents. – R.. Jul 9 '10 at 19:03
  • Very interesting. Could you explain how using base 10000 speeds things up? – Steven Sudit Jul 9 '10 at 19:04
  • Steven: Using base 10000 speeds things up because it's 4 times faster than base 10 due to them both fitting in a machine word. – Gabe Jul 9 '10 at 19:08
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    @Gabe, are you sure? A "64-bit" float involves ~1076-digit (decimal) arithmetic. An "80-bit" float involves ~16448-digit arithmetic. – R.. Jul 9 '10 at 19:28
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    You're thinking of cases where the exponent is positive. If it's negative, every time you decrement the exponent further you get an extra decimal place on the right (holding a '5') but it takes several exponent decrements to clear a decimal place on the left (e.g. 5->2->1->0). I overestimated but it seems you need roughly binary_exp*2/3 decimal digits, so ~700 digits for IEEE 754. – R.. Jul 9 '10 at 19:54

I see you've accepted an answer already but here are a couple of open source implementations of this conversion you might want to look at:

  1. David Gay's dtoa() function in dtoa.c (http://www.netlib.org/fp/dtoa.c).

  2. The function ___printf_fp() in file /stdio-common/printf_fp.c in glibc (http://ftp.gnu.org/gnu/glibc/glibc-2.11.2.tar.gz, for example).

Both will print as many digits as you ask for in a %f type printf (as I've written about here: http://www.exploringbinary.com/print-precision-of-dyadic-fractions-varies-by-language/ and http://www.exploringbinary.com/print-precision-of-floating-point-integers-varies-too/).

  • Great answer! This is the type of thing I was looking for. I'll check out those sources. – R.. Jul 10 '10 at 18:26
  • Your blog is fantastic. I'd seen a few posts on it earlier, but wasn't aware that the author exists here too :) – devnull Jun 27 '14 at 13:13
  • ISTM that David M. gay's implementation is a de facto (but not official) standard implementation. Several languages like have adopted it to their needs as well. I am actually trying to make the Delphi and C++Builder people at Embarcadero adopt it too. -- Oh wait, you are the guy from Exploring Binary? Good job! Love your site. – Rudy Velthuis Oct 18 '18 at 22:19

There's been a lot of work on printing floating-point numbers. The gold standard is to print out a decimal equivalent of minimal length such that when the decimal equivalent is read back in, you get the same floating-point number that you started with, no matter what the rounding mode is during readback. You can read about the algorithm in the excellent paper by Burger and Dybvig.

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    That's a well-researched problem that's in some ways simpler and in some ways more difficult, but regardless it's a different problem. Thanks for the link though. – R.. Jul 9 '10 at 20:40
  • @R: Oops. I failed to understand the question. Perhaps an example would have helped. – Norman Ramsey Jul 9 '10 at 22:51

Although it's C# and your question is tagged with C, Jon Skeet has code to convert a double to its exact representation as a string: http://www.yoda.arachsys.com/csharp/DoubleConverter.cs

From a quick glance, it does not appear to be too hard to port to C, and even easier to write in C++.

Upon further reflection, it appears that Jon's algorithm is also O(e^2), as it also loops over the exponent. However, that means the algorithm is O(log(n)^2) (where n is the floating-point number), and I'm not sure you can convert from base 2 to base 10 in better than log-squared time.

  • Interesting. Looks like he took that BCD approach, or close to it. – Steven Sudit Jul 9 '10 at 18:14
  • That is the same method he mentioned in the question. – Larry Wang Jul 9 '10 at 18:15
  • @Kaestur: Yes, but the code shows how to handle the fringe cases, such as subnormals. It's worth looking at. – Steven Sudit Jul 9 '10 at 18:23
  • If you're considering the theoretical big-O (and bignum stuff), then conversion from base 2 to base 10 probably can't be done in less than log-squared time. But if your numbers fit in machine words, it's log time, which is much better. The question is whether you can do the same thing for floating point numbers using the machine's floating point arithmetic. – R.. Jul 9 '10 at 18:27
  • My implementation used the ugly loop (rather than bit fiddling) to extract the mantissa, so it didn't care if the floating point value was subnormal to begin with. for (e=0; x<1; x*=2, e--); brought it into normal range in a few iterations. – R.. Jul 9 '10 at 18:31

Well being no floating point expert myself, I'd defer to using a well tested open source library.

The GNU MPFR is a good one.

The MPFR library is a C library for multiple-precision floating-point computations with correct rounding. The main goal of MPFR is to provide a library for multiple-precision floating-point computation which is both efficient and has a well-defined semantics.

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    And it does support conversion from double to arbitrary decimal. – Steven Sudit Jul 9 '10 at 18:15

sprintf and similar functions are usually only specified up to a number of significant digits to uniquely determine the original floating point value; they don't necessarily print the exact decimal representation.

You can ask for more significant digits than the default:

printf("%.100g\n", 0.1);

prints 0.1000000000000000055511151231257827021181583404541015625.

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    Your system's printf happens to do the polite (but not specified by any standard) thing and compute as many digits as requested. Most just chop everything off after computing sufficiently many digits to uniquely determine the float. See the links in Rick Regan's answer. – R.. Jul 13 '10 at 6:42
  • this works in gcc(gnu compiler collection) and tcc(tiny c compiler) – barlop Nov 13 '15 at 18:36

If you want more exact results, why not use fixed point math instead? Conversions are quick. Error is known and can be worked around. Not an exact answer to your question, but a different idea for you.

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    Wouldn't be a bad idea if I were using this in a specific application, but the problem domain is specifically solving this (rather painful) floating point to exact decimal conversion. – R.. Jul 9 '10 at 18:03
  • @R.: Then maybe that xrc lib is right for you. – Steven Sudit Jul 9 '10 at 18:16

Off the top of my head, why not break the exponent down into a sum of binary exponents first, then all your operations are loss-less.


10^2 = 2^6 + 2^5 + 2^2

Then sum:

mantissa<<6 + mantissa<<5 + mantissa<<2

I'm thinking that breaking it down would be on the O(n) on the the number of digits, the shifting is O(1), and the summing is O(n) digits...

You would have to have an integer class big enough to store the results, of course...

Let me know - I'm curious about this, it really made me think. :-)

  • The exponent is a binary exponent to begin with. And there's definitely no integer type (without some sort of bigint) capable of storing the result. It can be over 1000 digits with a double, and over 16000 digits with a long double. :-) – R.. Jul 9 '10 at 18:14
  • @r: i guess you could calloc(1000) and then bit-copy things in the right place. but definitely messy. floating point is there for a reason. :-) – eruciform Jul 9 '10 at 18:31
  • this can work only for integer part of number and there are much faster easier and nicer ways for it ... look at my answer for log2(10) which is pretty constant ... so if you want num of dec integer digits than n(base10) = n(base2)/log2(10). the problem is that this question is all about fractional part which cant be decomposed to powers of 2 ... at least i havent a clue how 10^-n = 2^-a+2^-b+2^-c+... the only way is to round it to the closest match within given accuracy – Spektre Aug 23 '13 at 11:03

There are 3 ways

  1. printing numbers in bin or hex

    This is the most precise way. I prefer hex because it is more like base 10 for reading/feel like for example F.8h = 15.5 no precision loss here.

  2. printing in dec but only the relevant digits

    With this I mean only digits which can have 1 in your number represented as close as possible.

    num of integer digits are easy and precise (no precision loss):

    // n10 - base 10 integer digits
    // n2  - base 2 integer digits
    // if fist digit is 0 and n10 > 1 then n10--

    num of fractional digits are more tricky and empirically I found this:

    // n10 - base 10 fract. digits
    // n2  - base 2 fract. digits >= 8
    n10=0; if (n02==8) n10=1;
    else if (n02==9) n10=2;
    else if (n02> 9)
             if (n10>=6) n10=2;
        else if (n10>=1) n10=1;

    if you make a dependency table n02 <-> n10 then you see that constant 0.30102999566398119521373889472449 is still present, but at start from 8 bits because less cannot represent 0.1 with satisfactory precision (0.85 - 1.15). because of negative exponents of base 2 the dependency is not linear, instead it patterns. This code works for small bit count (<=52) but at larger bit counts there can be error because used pattern do not fit log10(2) or 1/log2(10) exactly.

    for larger bit counts I use this:


    but that formula is 32bit aligned !!! and also bigger bit count ads error to it

    P.S. further analysis of binary representation of decadic numbers


    may reveal the exact pattern repetition which would lead to exact number of relevant digits for any bit count.

    for clarity:

    8 bin digits -> 1 dec digits
    9 bin digits -> 2 dec digits
    10 bin digits -> 3 dec digits
    11 bin digits -> 3 dec digits
    12 bin digits -> 3 dec digits
    13 bin digits -> 3 dec digits
    14 bin digits -> 3 dec digits
    15 bin digits -> 4 dec digits
    16 bin digits -> 4 dec digits
    17 bin digits -> 4 dec digits
    18 bin digits -> 4 dec digits
    19 bin digits -> 5 dec digits
    20 bin digits -> 6 dec digits
    21 bin digits -> 6 dec digits
    22 bin digits -> 6 dec digits
    23 bin digits -> 6 dec digits
    24 bin digits -> 6 dec digits
    25 bin digits -> 7 dec digits
    26 bin digits -> 7 dec digits
    27 bin digits -> 7 dec digits
    28 bin digits -> 7 dec digits
    29 bin digits -> 8 dec digits
    30 bin digits -> 9 dec digits
    31 bin digits -> 9 dec digits
    32 bin digits -> 9 dec digits
    33 bin digits -> 9 dec digits
    34 bin digits -> 9 dec digits
    35 bin digits -> 10 dec digits
    36 bin digits -> 10 dec digits
    37 bin digits -> 10 dec digits
    38 bin digits -> 10 dec digits
    39 bin digits -> 11 dec digits
    40 bin digits -> 12 dec digits
    41 bin digits -> 12 dec digits
    42 bin digits -> 12 dec digits
    43 bin digits -> 12 dec digits
    44 bin digits -> 12 dec digits
    45 bin digits -> 13 dec digits
    46 bin digits -> 13 dec digits
    47 bin digits -> 13 dec digits
    48 bin digits -> 13 dec digits
    49 bin digits -> 14 dec digits
    50 bin digits -> 15 dec digits
    51 bin digits -> 15 dec digits
    52 bin digits -> 15 dec digits
    53 bin digits -> 15 dec digits
    54 bin digits -> 15 dec digits
    55 bin digits -> 16 dec digits
    56 bin digits -> 16 dec digits
    57 bin digits -> 16 dec digits
    58 bin digits -> 16 dec digits
    59 bin digits -> 17 dec digits
    60 bin digits -> 18 dec digits
    61 bin digits -> 18 dec digits
    62 bin digits -> 18 dec digits
    63 bin digits -> 18 dec digits
    64 bin digits -> 18 dec digits

    And at last do not forget to round the cut off digits !!! That means if digit after the last relevant digit is >=5 in dec than last relevant digit should be +1 ... and if it is already 9 than you must go to previous digit and so on...

  3. print exact value

    To print exact value of fractional binary number just print fractional n digits where n is the number of fractional bits because the value represented is sum of this values so the number of fractional decimals cannot be bigger than the num of fractional digits of LSB. Stuff above (bullet #2) is relevant for storing decimal number to float (or printing just relevant decimals).

    negative powers of two exact values...

    2^- 1 = 0.5
    2^- 2 = 0.25
    2^- 3 = 0.125
    2^- 4 = 0.0625
    2^- 5 = 0.03125
    2^- 6 = 0.015625
    2^- 7 = 0.0078125
    2^- 8 = 0.00390625
    2^- 9 = 0.001953125
    2^-10 = 0.0009765625
    2^-11 = 0.00048828125
    2^-12 = 0.000244140625
    2^-13 = 0.0001220703125
    2^-14 = 0.00006103515625
    2^-15 = 0.000030517578125
    2^-16 = 0.0000152587890625
    2^-17 = 0.00000762939453125
    2^-18 = 0.000003814697265625
    2^-19 = 0.0000019073486328125
    2^-20 = 0.00000095367431640625

    now negative powers of 10 printed by exact value style for 64 bit doubles:

    10^+ -1 = 0.1000000000000000055511151231257827021181583404541015625
            = 0.0001100110011001100110011001100110011001100110011001101b
    10^+ -2 = 0.01000000000000000020816681711721685132943093776702880859375
            = 0.00000010100011110101110000101000111101011100001010001111011b
    10^+ -3 = 0.001000000000000000020816681711721685132943093776702880859375
            = 0.000000000100000110001001001101110100101111000110101001111111b
    10^+ -4 = 0.000100000000000000004792173602385929598312941379845142364501953125
            = 0.000000000000011010001101101110001011101011000111000100001100101101b
    10^+ -5 = 0.000010000000000000000818030539140313095458623138256371021270751953125
            = 0.000000000000000010100111110001011010110001000111000110110100011110001b
    10^+ -6 = 0.000000999999999999999954748111825886258685613938723690807819366455078125
            = 0.000000000000000000010000110001101111011110100000101101011110110110001101b
    10^+ -7 = 0.0000000999999999999999954748111825886258685613938723690807819366455078125
            = 0.0000000000000000000000011010110101111111001010011010101111001010111101001b
    10^+ -8 = 0.000000010000000000000000209225608301284726753266340892878361046314239501953125
            = 0.000000000000000000000000001010101111001100011101110001000110000100011000011101b
    10^+ -9 = 0.0000000010000000000000000622815914577798564188970686927859787829220294952392578125
            = 0.0000000000000000000000000000010001001011100000101111101000001001101101011010010101b
    10^+-10 = 0.00000000010000000000000000364321973154977415791655470655996396089904010295867919921875
            = 0.00000000000000000000000000000000011011011111001101111111011001110101111011110110111011b
    10^+-11 = 0.00000000000999999999999999939496969281939810930172340963650867706746794283390045166015625
            = 0.00000000000000000000000000000000000010101111111010111111111100001011110010110010010010101b
    10^+-12 = 0.00000000000099999999999999997988664762925561536725284350612952266601496376097202301025390625
            = 0.00000000000000000000000000000000000000010001100101111001100110000001001011011110101000010001b
    10^+-13 = 0.00000000000010000000000000000303737455634003709136034716842278413651001756079494953155517578125
            = 0.00000000000000000000000000000000000000000001110000100101110000100110100001001001011101101000001b
    10^+-14 = 0.000000000000009999999999999999988193093545598986971343290729163921781719182035885751247406005859375
            = 0.000000000000000000000000000000000000000000000010110100001001001101110000110101000010010101110011011b
    10^+-15 = 0.00000000000000100000000000000007770539987666107923830718560119501514549256171449087560176849365234375
            = 0.00000000000000000000000000000000000000000000000001001000000011101011111001111011100111010101100001011b
    10^+-16 = 0.00000000000000009999999999999999790977867240346035618411149408467364363417573258630000054836273193359375
            = 0.00000000000000000000000000000000000000000000000000000111001101001010110010100101111101100010001001101111b
    10^+-17 = 0.0000000000000000100000000000000007154242405462192450852805618492324772617063644020163337700068950653076171875
            = 0.0000000000000000000000000000000000000000000000000000000010111000011101111010101000110010001101101010010010111b
    10^+-18 = 0.00000000000000000100000000000000007154242405462192450852805618492324772617063644020163337700068950653076171875
            = 0.00000000000000000000000000000000000000000000000000000000000100100111001001011101110100011101001001000011101011b
    10^+-19 = 0.000000000000000000099999999999999997524592683526013185572915905567688179926555402943222361500374972820281982421875
            = 0.000000000000000000000000000000000000000000000000000000000000000111011000001111001001010011111011011011010010101011b
    10^+-20 = 0.00000000000000000000999999999999999945153271454209571651729503702787392447107715776066783064379706047475337982177734375
            = 0.00000000000000000000000000000000000000000000000000000000000000000010111100111001010000100001100100100100100001000100011b

    now negative powers of 10 printed by relevant decimal digits only style (i am more used to this) for 64bit doubles:

    10^+ -1 = 0.1
    10^+ -2 = 0.01
    10^+ -3 = 0.001
    10^+ -4 = 0.0001
    10^+ -5 = 0.00001
    10^+ -6 = 0.000001
    10^+ -7 = 0.0000001
    10^+ -8 = 0.00000001
    10^+ -9 = 0.000000001
    10^+-10 = 0.0000000001
    10^+-11 = 0.00000000001
    10^+-12 = 0.000000000001
    10^+-13 = 0.0000000000001
    10^+-14 = 0.00000000000001
    10^+-15 = 0.000000000000001
    10^+-16 = 0.0000000000000001
    10^+-17 = 0.00000000000000001
    10^+-18 = 0.000000000000000001
    10^+-19 = 0.0000000000000000001
    10^+-20 = 0.00000000000000000001

    hope it helps :)

  • 1
    This answer is is very interesting (so please don't delete it, it might be helpful to somebody who comes along with a slightly different problem) but it doesn't answer this question. This question is about printing the exact value, not printing sufficiently many digits to recover the original value by rounding. – R.. Aug 23 '13 at 12:34
  • binary fractions cannot be converted to decimal fractions without precision loss (in finite digits count) so if you want to print exact value than the point 1. is relevant only (print numbers in hex/bin or any base decomposable by power of 2). i wass thinking you want to print exact decimal value storable in floating point (in given mantisa precision) and not exact floating point value stored in floating point as decimal number. sorry ... still point 1 answers your question (you did not specify decadic system) for example 1.6A09E667F3BCC908B2FB1366h is sqrt(2) in hex – Spektre Aug 23 '13 at 14:26
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    Yes they can. For example, a binary fraction of 0.01 is decimal 0.25, and a binary fraction of 0.001 is decimal 0.125. In general, the number of decimal places to the right of the decimal point is equal to the number of binary places to the right of the binary point. – R.. Aug 23 '13 at 14:53
  • Silly me ... i was thinking it backwards again :) that came for transform base10 -> base2 ... in print it is base2 -> base10 thats easy num of decimal digits is exactly the same as num of fractional digits see my answer ... for edit – Spektre Aug 23 '13 at 15:24
  • btw i forgot to tell: to eliminate precission loss during conversion bin -> dec i create hex string (simple shift+and of mantisa in a loop) and then i convert this hex string to dec string (then reformat and print). my conversion code is here (no use of bignums or FPU) stackoverflow.com/a/18231860/2521214 – Spektre Aug 25 '13 at 10:52

You don't. The closest you can come to that is dumping the bytes.

  • 1
    I've thought about this some more, and I think I'm wrong. Since base 10 goes into base 2, there shouldn't be any binary values that can only be represented in decimal if we allow repeating digits. As a result, you should in principle be able to convert a float/double to a (potentially very long) string of decimal digits. – Steven Sudit Jul 9 '10 at 17:59
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    Of course you can. I have an implementation that does it in O(e^2) time (which hopefully can be improved) and O(e) space (which the decimal representation necessarily requires) as I described. – R.. Jul 9 '10 at 18:01
  • To finish answering, yes, the algorithm you described looks like it would work, but an arbitrary precision library (like the one Byron recommended) would make things easy. For something related but I think different, there's also: keithbriggs.info/xrc.html – Steven Sudit Jul 9 '10 at 18:02
  • I suspect that implementing the multiplications as shifts will speed things up, but that doesn't necessarily improve the big O. – Steven Sudit Jul 9 '10 at 18:04
  • I think what i just wrote is wrong, because I missed out on the fact that the doubling is happening to the decimal value. Perhaps the way to handle this is to keep the output in a format like BCD until you're done. – Steven Sudit Jul 9 '10 at 18:07

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