The nature of floating-point numbers means that it makes no sense to *check* if a floating-point number is rational, since all floating-point numbers are really fractions of the form *n* / 2^{e}. However, you might well want to know whether there is a *simple* fraction (one with a small denominator rather than a big power of 2) that closely approximates a given floating-point number.

Donald Knuth discusses this latter problem in *The Art of Computer Programming* volume II. See the answer to exercise 4.53-39. The idea is to search for the fraction with the lowest denominator within a range, by expanding the endpoints of the range as continued fractions so long as their coefficients are equal, and then when they differ, take the simplest value between them. Here's a fairly straightforward implementation in Python:

```
from fractions import Fraction
from math import modf
def simplest_fraction_in_interval(x, y):
"""Return the fraction with the lowest denominator in [x,y]."""
if x == y:
# The algorithm will not terminate if x and y are equal.
raise ValueError("Equal arguments.")
elif x < 0 and y < 0:
# Handle negative arguments by solving positive case and negating.
return -simplest_fraction_in_interval(-y, -x)
elif x <= 0 or y <= 0:
# One argument is 0, or arguments are on opposite sides of 0, so
# the simplest fraction in interval is 0 exactly.
return Fraction(0)
else:
# Remainder and Coefficient of continued fractions for x and y.
xr, xc = modf(1/x);
yr, yc = modf(1/y);
if xc < yc:
return Fraction(1, int(xc) + 1)
elif yc < xc:
return Fraction(1, int(yc) + 1)
else:
return 1 / (int(xc) + simplest_fraction_in_interval(xr, yr))
def approximate_fraction(x, e):
"""Return the fraction with the lowest denominator that differs
from x by no more than e."""
return simplest_fraction_in_interval(x - e, x + e)
```

And here are some results:

```
>>> approximate_fraction(6.75, 0.01)
Fraction(27, 4)
>>> approximate_fraction(math.pi, 0.00001)
Fraction(355, 113)
>>> approximate_fraction((1 + math.sqrt(5)) / 2, 0.00001)
Fraction(377, 233)
```