Emulate floating point string conversion behaviour of Linux on Windows

I've encountered an annoying problem in outputting a floating point number. When I format 11.545 with a precision of 2 decimal points on Windows it outputs "11.55", as I would expect. However, when I do the same on Linux the output is "11.54"!

I originally encountered the problem in Python, but further investigation showed that the difference is in the underlying C runtime library. (The architecture is x86-x64 in both cases.) Running the following line of C produces the different results on Windows and Linux, same as it does in Python.

``````printf("%.2f", 11.545);
``````

To shed more light on this I printed the number to 20 decimal places (`"%.20f"`):

``````Windows: 11.54500000000000000000
Linux:   11.54499999999999992895
``````

I know that 11.545 cannot be stored precisely as a binary number. So what appears to be happening is that Linux outputs the number it's actually stored with the best possible precision, while Windows outputs the simplest decimal representation of it, ie. tries to guess what the user most likely meant.

My question is: is there any (reasonable) way to emulate the Linux behaviour on Windows?

(While the Windows behaviour is certainly the intuitive one, in my case I actually need to compare the output of a Windows program with that of a Linux program and the Windows one is the only one I can change. By the way, I tried to look at the Windows source of `printf`, but the actual function that does the float->string conversion is `_cfltcvt_l` and its source doesn't appear to be available.)

EDIT: the plot thickens! The theory about this being caused by an imprecise representation might be wrong, because 0.125 does have an exact binary representation and it's still different when output with `'%.2f' % 0.125`:

``````Windows: 0.13
Linux:   0.12
``````

However, `round(0.125, 2)` returns 0.13 on both Windows and Linux.

-
Comparing floats by converting to strings and comparing the strings is a fundamentally nonportable idea. Also, if you're doing math to come to these values, you could normally end up with different results anyway (for example, 32, 64 or 80-bit internal FPU precision; different precision of libm functions), before it even gets to formatting. – Glenn Maynard Feb 10 '10 at 4:36
A double has about 15 decimal digits of precision - at least for MSVC. I'd have assumed that it would be similar for an x86 Linux build, but maybe they have some techniques to provide more (is a `double` on the Linux build 8 bytes? Is `DBL_DIG` in `float.h` something larger than 15?) What is happening on your Windows build is correct, since to the 15 digits of precision, the value does represent 11.545. Welcome to the weird and not always so wonderful world of floating point... – Michael Burr Feb 10 '10 at 7:51

First of all it sounds like Windows has it wrong right in this case (not that this really matters). The C Standard requires that the value output by `%.2f` is rounded to the appropriate number of digits. The best known algorithm for this is dtoa implemented by David M. Gay. You can probably port this to Windows or find a native implementation.

If you haven't already read "How to Print Floating-Point Numbers Accurately" by Steele and White, find a copy and read it. It is definitely an enlightening read. Make sure to find the original from the late 70's. I think that I purchased mine from ACM or IEEE at some point.

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No, both implementations are perfectly valid. ISO 754 permits several rounding modes; Linux uses round-to-even, and Linux uses round-away-from-0. – Glenn Maynard Feb 10 '10 at 4:48
You may be right, Glenn - `round()` doesn't do this, but `printf()` does! `round()` seems to be consistent between Windows and Linux. – EMP Feb 10 '10 at 7:27
The C `round()` function always rounds away from zero so I would expect it to be consistent. – D.Shawley Feb 10 '10 at 13:21
First link is broken. – user11153 Nov 22 '13 at 10:44

I don't think Windows is doing anything especially clever (like trying to reinterpret the float in base 10) here: I'd guess that it's simply computing the first 17 significant digits accurately (which would give '11.545000000000000') and then tacking extra zeros on the end to make up the requested number of places after the point.

As others have said, the different results for 0.125 come from Windows using round-half-up and Linux using round-half-to-even.

Note that for Python 3.1 (and Python 2.7, when it appears), the result of formatting a float will be platform independent (except possibly on unusual platforms).

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I don't think it's just tacking on extra zeros, because the number is not actually 11.5450000... even to 17 digits. But +1 for the info about Python 3.1 and 2.7 - looking forward to that! – EMP Feb 10 '10 at 22:31
The 'round to 17 significant figures (not 17 places after the point!) and tack on extra zeros' formula seems to work for me, for this particular number. The first 17 digits look like 11.54499..; the 18th is also a 9, so we round up. The guess was motivated by the original 1985 version of IEEE 754: in section 5.6 (Binary <---> Decimal conversions), you'll find the text "the implementor may, at his option, alter all significant digits after the ninth for single and the seventeenth for double to other decimal digits, typically 0." I'm guessing that Microsoft chose to exercise this option. :) – Mark Dickinson Feb 12 '10 at 0:08

``````import decimal

fs = ['11.544','11.545','11.546']

def convert(f,nd):
# we want 'nd' beyond the dec point
nd = f.find('.') + nd
c1 = decimal.getcontext().copy()
c1.rounding = decimal.ROUND_HALF_UP
c1.prec = nd
d1 = c1.create_decimal(f)
c2 = decimal.getcontext().copy()
c2.rounding = decimal.ROUND_HALF_DOWN
c2.prec = nd
d2 = c2.create_decimal(f)
print d1, d2

for f in fs:
convert(f,2)
``````

You can construct a decimal from an int or a string. In your case feed it a string with more digits than you want and truncate by setting context.prec.

Here is a link to a pymotw post w/ a detailed overview of the decimal module:

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Yes, it does produce 11.55 on Linux, but I cannot edit the Linux program, only the Windows one. So I need to get the Windows one to produce 11.54 instead. – EMP Feb 10 '10 at 4:34
Sorry for misreading - I updated the solution with info on the decimal module. Hopefully this will give you the rounding control to duplicate the linux behavior on windows. – Cyrus Feb 10 '10 at 6:16
Good idea, but, same as paxdiablo's answer it doesn't pass the "0.545" test - that rounds down to "0.54" when the Linux program would output "0.55". – EMP Feb 10 '10 at 22:29
The example shows how to round two ways. If you try adding '0.545' to the list - it will print both '.55' and '.54' for this input. For '11.545' you should get '11.55' (ROUND_HALF_UP) & '11.54' (ROUND_HALF_DOWN) For '0.545' you should get '0.55' (ROUND_HALF_UP) & '0.54' (ROUND_HALF_DOWN) Is this not working on Windows? (Sorry I don't have a windows machine readily available.) Or are you looking to create '11.54' & '0.55'. The scheme linux is using should be consistent, maybe one of the other 'decimal.rounding' modes will work to duplicate it on windows? – Cyrus Feb 10 '10 at 23:32
Yes, it does print out what you say, but unfortunately what I'm after is far more complex than that. Linux doesn't just always round down. I tried to explain in the original post what I think it does. – EMP Feb 11 '10 at 4:15

Consider comparing floating point numbers with some tolerance/epsilon instead. This is much more robust than trying to match exactly.

What I mean is, except saying that two floats are equal when:

``````f1 == f2
``````

Say they're equal when:

``````fabs(f1 - f2) < eps
``````

For some small `eps`. More details on this issue can be found here.

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Yes, I would normally do that, but in this case I'm comparing strings, not floats directly. The strings are part of a much larger program output. Besides, if they're rounded to 2 places I cannot realistically use an eps of 0.02 - that would conceal real differences. – EMP Feb 10 '10 at 4:40

You may be able to do subtract a tiny amount from the value to force the rounding down

``````print "%.2f"%(11.545-1e-12)
``````
-

You could try subtracting (or adding for a negative number) a small delta that will have no effect on the rounding for numbers far enough away from the precision.

For example, if you're rounding with `%.2f`, try this version on Windows:

``````printf("%.2f", 11.545 - 0.001);
``````

Floating point numbers are notoriously problematic if you don't know what's happening under the covers. In that case, your best bet is to write (or use) a decimal type library to alleviate the problems.

The example program:

``````#include <stdio.h>
int main (void) {
printf("%.20f\n", 11.545);
printf("%.2f\n", 11.545);
printf("%.2f\n", 11.545 + 0.001);
return 0;
}
``````

outputs this in my Cygwin environment:

``````11.54499999999999992895
11.54
11.55
``````

which is okay for your specific case (it's going the wrong way but should hopefully apply in the other direction as well: you need to test it) but you should check your entire possible input range if you want to be certain this will work for all your cases.

Update:

It works for this specific case, but not as a general solution. For instance if the number I want to format is 0.545 instead of 11.545 then `'%.2f' % (0.545 - 0.001)` returns "0.54", while `'%.2f' % 0.545` on Linux correctly returns "0.55". – EMP Feb 10 '10 at 4:39