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# What is the range of values a float can have in Python?

What are its smallest and biggest values in python?

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See this post.

Relevant parts of the post:

```In [2]: import kinds
In [3]: kinds.default_float_kind.M
kinds.default_float_kind.MAX         kinds.default_float_kind.MIN
kinds.default_float_kind.MAX_10_EXP  kinds.default_float_kind.MIN_10_EXP
kinds.default_float_kind.MAX_EXP     kinds.default_float_kind.MIN_EXP
In [3]: kinds.default_float_kind.MIN
Out[3]: 2.2250738585072014e-308
```
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Note that Numeric has been largely superseded by NumPy. I wonder if a more modern equivalent of the kinds modules exists, though… – EOL Dec 2 '09 at 21:32
``````>>> import sys
>>> sys.float_info
sys.floatinfo(max=1.7976931348623157e+308, max_exp=1024, max_10_exp=308,
min=2.2250738585072014e-308, min_exp=-1021, min_10_exp=-307, dig=15, mant_dig=53,
``````

The smallest is `sys.float_info.min` (2.2250738585072014e-308) and the biggest is `sys.float_info.max` (1.7976931348623157e+308). See documentation for other properties.

Update: you can usually get denormalized minimum as `sys.float_info.min*sys.float_info.epsilon`. But note, that such numbers are represented with a loss of precision.

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As a kind of theoretical complement to the previous answers, I would like to mention that the "magic" value ±308 comes directly from the binary representation of floats. Double precision floats are of the form ±c*2*q with a "small" fractional value c (~1), and q an integer written with 11 binary digits (1 bit for its sign). The fact that 2*(2*10-1) has 308 (decimal) digits explains the appearance of 10*±308 in the extreme float values.

Calculation in Python:

``````>>> print len(repr(2**(2**10-1)).rstrip('L'))
308
``````
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Python uses double-precision floats, which can hold values from about 10 to the -308 to 10 to the 308 power.

http://en.wikipedia.org/wiki/Double%5Fprecision%5Ffloating-point%5Fformat

Try this experiment from the Python prompt:

``````>>> 1e308
1e+308
>>> 1e309
inf
``````

10 to the 309 power is an overflow, but 10 to the 38 is not. QED.

Actually, you can probably get numbers smaller than 1e-308 via denormals, but there is a significant performance hit to this. I found that Python is able to handle `1e-324` but underflows on `1e-325` and returns `0.0` as the value.

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And how's 1e+308 supposed to be bigger (see question) than infinity? ;) – sfussenegger Dec 3 '09 at 11:22

Just playing around; here is an algorithmic method to find the minimum and maximum positive float, hopefully in any python implementation where `float("+inf")` is acceptable:

``````def find_float_limits():
"""Return a tuple of min, max positive numbers
representable by the platform's float"""

# first, make sure a float's a float
if 1.0/10*10 == 10.0:

minimum= maximum= 1.0
infinity= float("+inf")

# first find minimum
last_minimum= 2*minimum
while last_minimum > minimum > 0:
last_minimum= minimum
minimum*= 0.5

# now find maximum
operands= []
while maximum < infinity:
operands.append(maximum)
try:
maximum*= 2
except OverflowError:
break
last_maximum= maximum= 0
while operands and maximum < infinity:
last_maximum= maximum
maximum+= operands.pop()

return last_minimum, last_maximum

if __name__ == "__main__":
print (find_float_limits()) # python 2 and 3 friendly
``````

In my case,

``````\$ python so1835787.py
(4.9406564584124654e-324, 1.7976931348623157e+308)
``````

so denormals are used.

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