## TLDR ;)

The rounding problem of input and output has been **solved definitively by Python 3.1** and the fix is backported also to Python 2.7.0.

**Rounded numbers can be reversibly converted between float and string** back and forth:

`str -> float() -> repr() -> float() ...`

or `Decimal -> float -> str -> Decimal`

```
>>> 0.3
0.3
>>> float(repr(0.3)) == 0.3
True
```

A `Decimal`

type is not necessary for storage anymore.

**Results of arithmetic operations must be rounded again** because rounding errors could accumulate more inaccuracy than that is possible after parsing one number. That is not fixed by the improved `repr()`

algorithm (Python >= 3.1, >= 2.7.0):

```
>>> 0.1 + 0.2
0.30000000000000004
>>> 0.1, 0.2, 0.3
(0.1, 0.2, 0.3)
```

The output string function `str(float(...))`

was rounded to 12 valid digits in Python < 2.7x and < 3.1, to prevent excessive invalid digits similar to unfixed repr() output. That was still insufficientl after subtraction of very similar numbers and it was too much rounded after other operations. Python 2.7 and 3.1 use the same length of str() although the repr() is fixed. Some old versions of Numpy had also excessive invalid digits, even with fixed Python. The current Numpy is fixed. Python versions >= 3.2 have the same results of str() and repr() function and also output of similar functions in Numpy.

## Test

```
import random
from decimal import Decimal
for _ in range(1000000):
x = random.random()
assert x == float(repr(x)) == float(Decimal(repr(x))) # Reversible repr()
assert str(x) == repr(x)
assert len(repr(round(x, 12))) <= 14 # no excessive decimal places.
```

## Documentation

See the Release notes Python 2.7 - Other Language Changes the fourth paragraph:

**Conversions** between floating-point numbers and strings are now **correctly rounded** on most platforms. These conversions occur in many different places: str() on floats and complex numbers; the float and complex constructors; numeric formatting; serializing and de-serializing floats and complex numbers using the `marshal`

, `pickle`

and `json`

modules; parsing of float and imaginary literals in Python code; and Decimal-to-float conversion.

Related to this, the **repr()** of a floating-point number x now returns a result based on the **shortest decimal string that’s guaranteed to round back to x** under correct rounding (with round-half-to-even rounding mode). Previously it gave a string based on rounding x to 17 decimal digits.

The related issue

**More information:** The formatting of `float`

before Python 2.7 was similar to the current `numpy.float64`

. Both types use the same 64 bit IEEE 754 double precision with 52 bit mantissa. A big difference is that `np.float64.__repr__`

is formatted frequently with an excessive decimal number so that no bit can be lost, but no valid IEEE 754 number exists between 13.949999999999999 and 13.950000000000001. The result is not nice and the conversion `repr(float(number_as_string))`

is not reversible with numpy. On the other hand: `float.__repr__`

is formatted so that every digit is important; the sequence is without gaps and the conversion is reversible. Simply: If you perhaps have a numpy.float64 number, convert it to normal float in order to be formatted for humans, not for numeric processors, otherwise nothing more is necessary with Python 2.7+.

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