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.

  • I believe no, but just trying to see how std::nextafter is implemented and may be we can come up with something equivalent. – Abhijit May 2 '12 at 20:11
  • My cython based solution should work on windows (saw you're a windows guy in your profile). You can install cython from pip. Requires gcc/g++. You may have to set the libraries,library_dirs and include_dirs paths in the setup.py, they are the standard file paths you would pass to your compiler to build something that uses cmath. Not sure what those paths would look like on windows or even if they would be needed (probably not), but no reason it shouldn't work. – Endophage May 2 '12 at 20:51
  • No, it doesn't. The easiest way to fake it is to use the struct module to convert to an 8-byte int, add one to the int, and convert back. That works fine for positive numbers, and needs some tweaking for negative numbers. – Mark Dickinson May 2 '12 at 21:06
  • @MarkDickinson, you also need tweaks for NAN, INF, overflow into the exponent, etc. There's a lot of edge cases. – Mark Ransom May 2 '12 at 21:08
  • @MarkRansom Hence use cython to wrap the existing functions... don't bother re-inventing the wheel... – Endophage May 2 '12 at 21:18

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
        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)
        return next_down(x)


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.


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 


    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.


  • Strangely enough I have an answer on that question. – Mark Ransom May 3 '12 at 1:12
  • I think you need to replace 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
  • @MarkDickinson fair enough, that makes sense. Although from the linked C++ docs nextafter appears to be polymorphic in cmath so I'd really just want to change the cdef extern... import to be the double version of nextafter. – Endophage May 3 '12 at 23:33
  • Agreed; that should do it. Without that, you'll be rounding the inputs to C++ floats before doing the computation. E.g., with your current code I get 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:])
        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
        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)
  • 1
    Huh? How's that equivalent to std::nextafter? – phihag May 2 '12 at 20:10
  • 1
    @phihag, it's not equivalent at all but could be the basis for writing your own. – Mark Ransom May 2 '12 at 20:11

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