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# Why do I need 17 significant digits (and not 16) to represent a double?

Can someone give me an example of a floating point number (double precision), that needs more than 16 significant decimal digits to represent it?

I have found in this thread that sometimes you need up to 17 digits, but I am not able to find an example of such a number (16 seems enough to me).

Can somebody clarify this?

Thanks a lot!

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``````#include <stdio.h>

int
main(int argc, char *argv[])
{
unsigned long long n = 1ULL << 53;
unsigned long long a = 2*(n-1);
unsigned long long b = 2*(n-2);
printf("%llu\n%llu\n%d\n", a, b, (double)a == (double)b);
return 0;
}
``````

Compile and run to see:

``````18014398509481982
18014398509481980
0
``````

a and b are just 2*(2^53-1) and 2*(2^53-2).

Those are 17-digit base-10 numbers. When rounded to 16 digits, they are the same. Yet a and b clearly only need 53 bits of precision to represent in base-2. So if you take a and b and cast them to double, you get your counter-example.

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I have edited your program a bit. It now prints the two different double precision numbers: 1.8014398509481982e+16 1.8014398509481980e+16 Thanks a lot, this is the right answer! – Ondřej Čertík May 26 '11 at 5:13
I also posted a simple Fortran program below, showing that indeed 17 digits is needed. – Ondřej Čertík May 26 '11 at 5:40
Btw, here is a simple way to proof why we need 17 digits: If the smallest double that can be added to 1 is epsilon ~ 2e-16, then 1+epsilon = 1.0000000000000002, which obviously requires 17 digits to represent. – Ondřej Čertík May 26 '11 at 20:28
%Lu is non-standard. %llu should be used instead. – BSalita May 11 '14 at 8:20
@BSalita: Indeed you are correct (and I have learned something today). Fixed; thanks. – Nemo May 11 '14 at 15:44

I think the guy on that thread is wrong, and 16 base-10 digits are always enough to represent an IEEE double.

My attempt at a proof would go something like this:

Suppose otherwise. Then, necessarily, two distinct double-precision numbers must be represented by the same 16-significant-digit base-10 number.

But two distinct double-precision numbers must differ by at least one part in 2^53, which is greater than one part in 10^16. And no two numbers differing by more than one part in 10^16 could possibly round to the same 16-significant-digit base-10 number.

This is not completely rigorous and could be wrong. :-)

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Nice argument. I am putting this as the right answer, unless somebody actually provides a counter argument (some number that doesn't work). Here is the code in Python (the formatting is not great): `In [1]: 2**(-53) Out[1]: 1.1102230246251565e-16 In [2]: 10**(-16) Out[2]: 9.9999999999999998e-17 ` – Ondřej Čertík May 25 '11 at 5:36
Unfortunately, I now think I am wrong... Suppose we only had three bits of mantissa. By my argument, that should correspond to one base-10 digit. But now consider 2, 4, 6, 8, 10, 12, and 14 (i.e., 2 times 1,2,3,...7). Those are clearly three-bit mantissas, but 10, 12, and 14 are all the same when rounded to one significant digit. I will try to construct a "double" counterexample later today. (Great question, btw) – Nemo May 25 '11 at 13:25
Indeed, your other answer nailed this down. So I put that one as the correct answer. Thanks a lot for this, I really appreciate your effort. So now it is clear, that if I want to print doubles, I do need to use `%.16e` in C, or `(es23.16)` in Fortran. – Ondřej Čertík May 26 '11 at 5:16

The correct answer is the one by Nemo above. Here I am just pasting a simple Fortran program showing an example of the two numbers, that need 17 digits of precision to print, showing, that one does need `(es23.16)` format to print double precision numbers, if one doesn't want to loose any precision:

``````program test
implicit none
integer, parameter :: dp = kind(0.d0)
real(dp) :: a, b
a = 1.8014398509481982e+16_dp
b = 1.8014398509481980e+16_dp
print *, "First we show, that we have two different 'a' and 'b':"
print *, "a == b:", a == b, "a-b:", a-b
print *, "using (es22.15)"
print "(es22.15)", a
print "(es22.15)", b
print *, "using (es23.16)"
print "(es23.16)", a
print "(es23.16)", b
end program
``````

it prints:

``````First we show, that we have two different 'a' and 'b':
a == b: F a-b:   2.0000000000000000
using (es22.15)
1.801439850948198E+16
1.801439850948198E+16
using (es23.16)
1.8014398509481982E+16
1.8014398509481980E+16
``````
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Dig into the single and double precision basics and wean yourself of the notion of this or that (16-17) many DECIMAL digits and start thinking in (53) BINARY digits. The necessary examples may be found here at stackoverflow if you spend some time digging.

And I fail to see how you can award a best answer to anyone giving a DECIMAL answer without qualified BINARY explanations. This stuff is straight-forward but it is not trivial.

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Hi Olof, thanks for your answer. I have searched through the stackoverflow very carefully, but wasn't able to find the answer to my question. Could you please point me to some examples of that? – Ondřej Čertík Aug 3 '11 at 19:07
This post should provide you with some insight into why floating point values (seem to) "behave stangely" (they don't). I'll try to find some more. – Olof Forshell Aug 4 '11 at 7:59
– Olof Forshell Aug 4 '11 at 8:04
@Ondrej Certik: so how did you get along with the binary angle on floating point decimals? – Olof Forshell Aug 21 '11 at 7:56
Thanks a lot for the pointers. In fact, I have read all these posts before asking here, because I couldn't find an example of a number that needs 17 digits. The accepted answer at this question answers this. – Ondřej Čertík Dec 8 '11 at 7:51

The largest continuous range of integers that can be exactly represented by a double (8 byte IEEE) is -2^53 to 2^53 (-9007199254740992. to 9007199254740992.). The numbers -2^53-1 and 2^53+1 cannot be exactly represented by a double.

Therefore, no more than 16 significant decimal digits to the left of the decimal point will exactly represent a double in the continuous range.

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