# Strange behaviour with floats and string conversion

I've typed this into python shell:

``````>>> 0.1*0.1
0.010000000000000002
``````

I expected that 0.1*0.1 is not 0.01, because I know that 0.1 in base 10 is periodic in base 2.

``````>>> len(str(0.1*0.1))
4
``````

I expected to get 20 as I've seen 20 characters above. Why do I get 4?

``````>>> str(0.1*0.1)
'0.01'
``````

Ok, this explains why I `len` gives me 4, but why does `str` return `'0.01'`?

``````>>> repr(0.1*0.1)
'0.010000000000000002'
``````

Why does `str` round but `repr` not? (I have read this answer, but I would like to know how they have decided when `str` rounds a float and when it doesn't)

``````>>> str(0.01) == str(0.0100000000001)
False
>>> str(0.01) == str(0.01000000000001)
True
``````

So it seems to be a problem with the accuracy of floats. I thought Python would use IEEE 754 single precicion floats. So I've checked it like this:

``````#include <stdint.h>
#include <stdio.h> // printf

union myUnion {
uint32_t i; // unsigned integer 32-bit type (on every machine)
float f;    // a type you want to play with
};

int main() {
union myUnion testVar;
testVar.f = 0.01000000000001f;
printf("%f\n", testVar.f);

testVar.f = 0.01000000000000002f;
printf("%f\n", testVar.f);

testVar.f = 0.01f*0.01f;
printf("%f\n", testVar.f);
}
``````

I got:

``````0.010000
0.010000
0.000100
``````

Python gives me:

``````>>> 0.01000000000001
0.010000000000009999
>>> 0.01000000000000002
0.010000000000000019
>>> 0.01*0.01
0.0001
``````

Why does Python give me these results?

(I use Python 2.6.5. If you know of differences in the Python versions, I would also be interested in them.)

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not sure why the users deleted their answers, but indeed the behaviour is explained in tutorial – SilentGhost Nov 12 '12 at 14:38
`float('4.1') * 100 == 409.99999999999994` – Hugo Apr 17 '14 at 7:12

The crucial requirement on `repr` is that it should round-trip; that is, `eval(repr(f)) == f` should give `True` in all cases.

In Python 2.x (before 2.7) `repr` works by doing a `printf` with format `%.17g` and discarding trailing zeroes. This is guaranteed correct (for 64-bit floats) by IEEE-754. Since 2.7 and 3.1, Python uses a more intelligent algorithm that can find shorter representations in some cases where `%.17g` gives unnecessary non-zero terminal digits or terminal nines. See What's new in 3.1? and issue 1580.

Even under Python 2.7, `repr(0.1 * 0.1)` gives `"0.010000000000000002"`. This is because `0.1 * 0.1 == 0.01` is `False` under IEEE-754 parsing and arithmetic; that is, the nearest 64-bit floating-point value to `0.1`, when multiplied by itself, yields a 64-bit floating-point value that is not the nearest 64-bit floating-point value to `0.01`:

``````>>> 0.1.hex()
'0x1.999999999999ap-4'
>>> (0.1 * 0.1).hex()
'0x1.47ae147ae147cp-7'
>>> 0.01.hex()
'0x1.47ae147ae147bp-7'
^ 1 ulp difference
``````

The difference between `repr` and `str` (pre-2.7/3.1) is that `str` formats with 12 decimal places as opposed to 17, which is non-round-trippable but produces more readable results in many cases.

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+1. And in Python >= 3.2, the difference between `repr` and `str` for floats is gone entirely. (And about time, too :-) – Mark Dickinson Nov 12 '12 at 18:20

``````ActivePython 2.6.4.10 (ActiveState Software Inc.) based on
Python 2.6.4 (r264:75706, Jan 22 2010, 17:24:21) [MSC v.1500 64 bit (AMD64)] on win32
>>> repr(0.1)
'0.10000000000000001'
>>> repr(0.01)
'0.01'
``````

Now, the docs claim that in Python <2.7

the value of `repr(1.1)` was computed as `format(1.1, '.17g')`

This is a slight simplification.

Note that this is all to do with the string formatting code -- in memory, all Python floats are just stored as C++ doubles, so there is never going to be a difference between them.

Also, it's kind of unpleasant to work with the full-length string for a float even if you know that there's a better one. Indeed, in modern Pythons a new algorithm is used for float formatting, that picks the shortest representation in a smart way.

I spent a while looking this up in the source code, so I'll include the details here in case you're interested. You can skip this section.

In `floatobject.c`, we see

``````static PyObject *
float_repr(PyFloatObject *v)
{
char buf[100];
format_float(buf, sizeof(buf), v, PREC_REPR);

return PyString_FromString(buf);
}
``````

which leads us to look at `format_float`. Omitting the NaN/inf special cases, it is:

``````format_float(char *buf, size_t buflen, PyFloatObject *v, int precision)
{
register char *cp;
char format[32];
int i;

/* Subroutine for float_repr and float_print.
We want float numbers to be recognizable as such,
i.e., they should contain a decimal point or an exponent.
However, %g may print the number as an integer;
in such cases, we append ".0" to the string. */

assert(PyFloat_Check(v));
PyOS_snprintf(format, 32, "%%.%ig", precision);
PyOS_ascii_formatd(buf, buflen, format, v->ob_fval);
cp = buf;
if (*cp == '-')
cp++;
for (; *cp != '\0'; cp++) {
/* Any non-digit means it's not an integer;
this takes care of NAN and INF as well. */
break;
}
if (*cp == '\0') {
*cp++ = '.';
*cp++ = '0';
*cp++ = '\0';
return;
}

<some NaN/inf stuff>
}
``````

We can see that

So this first initialises some variables and checks that `v` is a well-formed float. It then prepares a format string:

``````PyOS_snprintf(format, 32, "%%.%ig", precision);
``````

Now PREC_REPR is defined elsewhere in `floatobject.c` as 17, so this computes to `"%.17g"`. Now we call

``````PyOS_ascii_formatd(buf, buflen, format, v->ob_fval);
``````

With the end of the tunnel in sight, we look up `PyOS_ascii_formatd` and discover that it uses `snprintf` internally.

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I agree that the claim in the What's New doc for Python is a simplification of the old behavior. Perhaps a better description can be found in the enhancement request that lead to the change: "The current float repr() always calculates the 17 first digits of the decimal representation of a float, and displays all of them (discarding trailing zeros)." – Steven Rumbalski Nov 12 '12 at 15:17
Here's the link for 2.6.5 `PyOS_ascii_formatd` and `ensure_minimum_exponent_length`, though I don't know which platforms require the latter to conform with C99. – eryksun Nov 13 '12 at 16:45

In versions prior to Python 2.7 and Python 3.1, Python rounded this value to 17 significant digits, giving `‘0.10000000000000001’`. In current versions, Python displays a value based on the shortest decimal fraction that rounds correctly back to the true binary value, resulting simply in `‘0.1’`.

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