Does Python provide a function to get the floating-point value that results from incrementing the least significant bit of an existing floating-point value?
I'm looking for something similar to the std::nextafter
function that was added in C++11.
Does Python provide a function to get the floating-point value that results from incrementing the least significant bit of an existing floating-point value?
I'm looking for something similar to the std::nextafter
function that was added in C++11.
To answer the first part of your question: no, Python doesn't provide this functionality directly. But it's quite easy to write a Python function that does this, assuming IEEE 754 floating-point.
The IEEE 754 binary floating-point formats are rather cleverly designed so that moving from one floating-point number to the 'next' one is as simple as incrementing the bit representation. This works for any number in the range [0, infinity)
, right across exponent boundaries and subnormals. To produce a version of nextUp
that covers the complete floating-point range, you also need to deal with negative numbers, infinities, nans, and one special case involving negative zero. Below is a standards compliant version of IEEE 754's nextUp
function in Python. It covers all the corner cases.
import math
import struct
def next_up(x):
# NaNs and positive infinity map to themselves.
if math.isnan(x) or (math.isinf(x) and x > 0):
return x
# 0.0 and -0.0 both map to the smallest +ve float.
if x == 0.0:
x = 0.0
n = struct.unpack('<q', struct.pack('<d', x))[0]
if n >= 0:
n += 1
else:
n -= 1
return struct.unpack('<d', struct.pack('<q', n))[0]
The implementations of nextDown
and nextAfter
then look like this. (Note that nextAfter
is not a function specified by IEEE 754, so there's a little bit of guesswork as to what should happen with IEEE special values. Here I'm following the IBM Decimal Arithmetic standard that Python's decimal.Decimal
class is based on.)
def next_down(x):
return -next_up(-x)
def next_after(x, y):
# If either argument is a NaN, return that argument.
# This matches the implementation in decimal.Decimal
if math.isnan(x):
return x
if math.isnan(y):
return y
if y == x:
return y
elif y > x:
return next_up(x)
else:
return next_down(x)
UPDATE:
Turns out this is a duplicate question (which comes up in google as result #2 for the search "c++ nextafter python"): Increment a python floating point value by the smallest possible amount
The accepted answer provides some solid solutions.
ORIGINAL ANSWER:
Certainly this isn't the perfect solution but using cython just a few lines will allow you to wrap the existing C++ function and use it in Python. I've compiled the below code and it works on my ubuntu 11.10 box.
First, a .pyx file (I called mine nextafter.pyx) defines your interface to the C++:
cdef extern from "cmath":
float nextafter(float start, float to)
def pynextafter(start, to):
cdef float float_start = float(start)
cdef float float_to = float(to)
result = nextafter(start, to)
return result
Then a setup.py defines how to build the extension:
from distutils.core import setup
from distutils.extension import Extension
from Cython.Distutils import build_ext
ext_modules=[
Extension("nextafter",
["nextafter.pyx"],
libraries=[],
library_dirs=[],
include_dirs=[],
language="c++",
)
]
setup(
name = "nextafter",
cmdclass = {"build_ext": build_ext},
ext_modules = ext_modules
)
Make sure those are in the same directory then build with python setup.py build_ext --inplace
. I hope you can see how you would add the other variations of nextafter to the extension (for doubles, etc...). Once built, you should have a nextafter.so. Fire up python in the same directory (or put nextafter.so on your path somewhere) and you should be able to call from nextafter import pynextafter
.
Enjoy!
float
with double
everywhere in your .pyx
file. (Or use nextafterf
if you really want to use floats, but since Python floats correspond to C++ doubles, the double version would make more sense.)
– Mark Dickinson
May 3 '12 at 19:35
cdef extern...
import to be the double version of nextafter.
– Endophage
May 3 '12 at 23:33
nextafter(1.3, 2.0)
-> 1.2999999523162844
, a result that's less than the original value of 1.3
!
– Mark Dickinson
May 4 '12 at 6:16
Check out http://docs.python.org/library/stdtypes.html#float.hex
Let's try this an implementation that doesn't know much about next after.
First, we need to extract the hex part and the exponent from the hex string:
def extract_parts(hex_val):
if not hex_val.startswith('0x1.'):
return None
relevant_chars = hex_val[4:]
if not len(relevant_chars) > 14 and relevant_chars[13] == 'p':
return None
hex_portion = int(relevant_chars[:13], 16)
if relevant_chars[14] == '+':
p_val = int(relevant_chars[15:])
elif relevant_chars[14] == '-':
p_val = -int(relevant_chars[15:])
else:
return None
return (hex_portion, p_val)
Then we need a way to increment in positive or negative direction (we'll assume the hex string has already been converted to an integer hex_portion
):
def increment_hex(hex_portion, p_val, direction):
if hex_portion == 0 and direction == -1:
new_hex = 'f' * 13
p_val -= 1
elif hex_portion == int('f' * 13, 16) and direction == 1:
new_hex = '0' * 13
p_val += 1
else:
new_hex = hex(hex_portion + direction)[2:].rstrip('L').zfill(13)
if len(new_hex) != 13:
return None
return format_hex(new_hex, p_val)
We need a helper function to reformat an acceptable hex string and exponent, which I used above:
def format_hex(hex_as_str, p_val):
sign = '-' if p_val < 0 else '+'
return '0x1.%sp%s%d' % (hex_as_str, sign, p_val)
Finally, to implement nextafter
:
def nextafter(float_val):
hex_equivalent = float_val.hex()
hex_portion, p_val = extract_parts(hex_equivalent)
direction = 1
new_hex_equiv = increment_hex(hex_portion, p_val, direction)
return float.fromhex(new_hex_equiv)
std::nextafter
is implemented and may be we can come up with something equivalent. – Abhijit May 2 '12 at 20:11