# Increment a Python floating point value by the smallest possible amount

## How can I increment a floating point value in python by the smallest possible amount?

Background: I'm using floating point values as dictionary keys.

Occasionally, very occasionally (and perhaps never, but not certainly never), there will be collisions. I would like to resolve these by incrementing the floating point value by as small an amount as possible. How can I do this?

In C, I would twiddle the bits of the mantissa to achieve this, but I assume that isn't possible in Python.

• Due to the sheer amount of activity on this question, it seems to be the canonical "duplicate of" question when linking/closing other "next floating point value in Python" questions. However, it suffers from having at least two disjoint aspects: (1) how to increment a floating point value, and (2) how to prevent collisions when using floats as dict keys. A much clearer statement of the title question, and a much more definitive answer can be found here. Dec 3, 2013 at 16:27

Since Python 3.9 there is `math.nextafter` in the stdlib. Read on for alternatives in older Python versions.

Increment a python floating point value by the smallest possible amount

The nextafter(x,y) functions return the next discretely different representable floating-point value following x in the direction of y. The nextafter() functions are guaranteed to work on the platform or to return a sensible value to indicate that the next value is not possible.

The `nextafter()` functions are part of POSIX and ISO C99 standards and is _nextafter() in Visual C. C99 compliant standard math libraries, Visual C, C++, Boost and Java all implement the IEEE recommended nextafter() functions or methods. (I do not honestly know if .NET has nextafter(). Microsoft does not care much about C99 or POSIX.)

None of the bit twiddling functions here fully or correctly deal with the edge cases, such as values going though 0.0, negative 0.0, subnormals, infinities, negative values, over or underflows, etc. Here is a reference implementation of nextafter() in C to give an idea of how to do the correct bit twiddling if that is your direction.

There are two solid work arounds to get `nextafter()` or other excluded POSIX math functions in Python < 3.9:

Use Numpy:

``````>>> import numpy
>>> numpy.nextafter(0,1)
4.9406564584124654e-324
>>> numpy.nextafter(.1, 1)
0.10000000000000002
>>> numpy.nextafter(1e6, -1)
999999.99999999988
>>> numpy.nextafter(-.1, 1)
-0.099999999999999992
``````

Link directly to the system math DLL:

``````import ctypes
import sys
from sys import platform as _platform

if _platform == "linux" or _platform == "linux2":
_funcname = 'nextafter'
elif _platform == "darwin":
_funcname = 'nextafter'
elif _platform == "win32":
_funcname = '_nextafter'
else:
# fill in library and function name for your system math dll
print("Platform", repr(_platform), "is not supported")
sys.exit(0)

_nextafter = getattr(_libm, _funcname)
_nextafter.restype = ctypes.c_double
_nextafter.argtypes = [ctypes.c_double, ctypes.c_double]

def nextafter(x, y):
"Returns the next floating-point number after x in the direction of y."
return _nextafter(x, y)

assert nextafter(0, 1) - nextafter(0, 1) == 0
assert 0.0 + nextafter(0, 1) > 0.0
``````

And if you really really want a pure Python solution:

``````# handles edge cases correctly on MY computer
# not extensively QA'd...
import math
# 'double' means IEEE 754 double precision -- c 'double'
epsilon  = math.ldexp(1.0, -53) # smallest double that 0.5+epsilon != 0.5
maxDouble = float(2**1024 - 2**971)  # From the IEEE 754 standard
minDouble  = math.ldexp(1.0, -1022) # min positive normalized double
smallEpsilon  = math.ldexp(1.0, -1074) # smallest increment for doubles < minFloat
infinity = math.ldexp(1.0, 1023) * 2

def nextafter(x,y):
"""returns the next IEEE double after x in the direction of y if possible"""
if y==x:
return y         #if x==y, no increment

# handle NaN
if x!=x or y!=y:
return x + y

if x >= infinity:
return infinity

if x <= -infinity:
return -infinity

if -minDouble < x < minDouble:
if y > x:
return x + smallEpsilon
else:
return x - smallEpsilon

m, e = math.frexp(x)
if y > x:
m += epsilon
else:
m -= epsilon

return math.ldexp(m,e)
``````

Or, use Mark Dickinson's excellent solution

Obviously the Numpy solution is the easiest.

• +1. Thanks for being the first person to actually answer the question. May 29, 2011 at 4:09
• Python has `Decimal.next_plus()` stackoverflow.com/questions/5749188/…
– jfs
Jul 5, 2011 at 17:31
• One edge case not discussed: how to come up with some number bigger than `x` to give to the `nextafter` function. Suppose you just always provide `x + 1` as the `y` argument; that will give you the wrong answer if `x` is very near the maximum possible value. Perhaps it would be more convenient to just consider the sign of the `y` argument to `nextafter`, to indicate whether increment or decrement is desired. Mar 12, 2012 at 21:28
• @wberry What about using +inf or -inf for y ?
– user1220978
Jan 17, 2013 at 21:06
• You might find this useful. `from _testcapi import DBL_MAX, DBL_MIN, FLT_MAX, FLT_MIN` Nov 11, 2014 at 18:58

# Python 3.9 and above

Starting with Python 3.9, released 2020-10-05, you can use the `math.nextafter` function:

`math.nextafter(x, y)`

Return the next floating-point value after x towards y.

If x is equal to y, return y.

Examples:

• `math.nextafter(x, math.inf)` goes up: towards positive infinity.

• `math.nextafter(x, -math.inf)` goes down: towards minus infinity.

• `math.nextafter(x, 0.0)` goes towards zero.

• `math.nextafter(x, math.copysign(math.inf, x))` goes away from zero.

See also `math.ulp()`.

• Even simpler for moving away from zero, one can use `math.nextafter(x, 2*x)`. Jul 27, 2021 at 6:43

First, this "respond to a collision" is a pretty bad idea.

If they collide, the values in the dictionary should have been lists of items with a common key, not individual items.

Your "hash probing" algorithm will have to loop through more than one "tiny increments" to resolve collisions.

And sequential hash probes are known to be inefficient.

Second, use `math.frexp` and `sys.float_info.epsilon` to fiddle with mantissa and exponent separately.

``````>>> m, e = math.frexp(4.0)
>>> (m+sys.float_info.epsilon)*2**e
4.0000000000000018
``````
• +1 for using lists. `defaultdict(list)` can be used so you can just do `mydict[key].append(value)` without worrying if the key already exists. May 19, 2011 at 19:58
• I am aware of all sorts of fancy many-stage hashing techniques, but I'd like to do something quick and simple, which I know will be adequate in this case. May 19, 2011 at 20:05
• And additionally, I know that there are no keys with values greater than the current time, so incrementing is a sensible way to resolve collisions. May 19, 2011 at 20:14
• @Autopulated, there may be keys greater than the current time - if there's already been a collision! May 19, 2011 at 20:23
• @Autopulated you haven't told us the nature of the events you're inserting so I have no idea how likely it is to get more than two events per tick. Also note that some timers don't count as often as their precision would suggest. Three in a row isn't the only way to trip this problem, you could also have two followed by two more in the next tick. May 20, 2011 at 0:59

Forgetting about why we would want to increment a floating point value for a moment, I would have to say I think Autopulated's own answer is probably correct.

But for the problem domain, I share the misgivings of most of the responders to the idea of using floats as dictionary keys. If the objection to using Decimal (as proposed in the main comments) is that it is a "heavyweight" solution, I suggest a do-it-yourself compromise: Figure out what the practical resolution is on the timestamps, pick a number of digits to adequately cover it, then multiply all the timestamps by the necessary amount so that you can use integers as the keys. If you can afford an extra digit or two beyond the timer precision, then you can be even more confident that there will be no or fewer collisions, and that if there are collisions, you can just add 1 (instead of some rigamarole to find the next floating point value).

I recommend against assuming that floats (or timestamps) will be unique if at all possible. Use a counting iterator, database sequence or other service to issue unique identifiers.

• I'm not assuming that they're going to be unique, hence the question! I am assuming collisions are very rare though. May 19, 2011 at 19:42
• @Autopulated: "am assuming collisions are very rare" just as bad as assuming they don't happen. Find a better key. May 19, 2011 at 19:51
• No, collisions are very rare. I know how my timer behaves, and I know when things are added to my dictionary: rare hash collisions are perfectly acceptable. May 19, 2011 at 20:04

Instead of incrementing the value, just use a tuple for the colliding key. If you need to keep them in order, every key should be a tuple, not just the duplicates.

• Any `float` is less than any `tuple`. `4.0 < ()` --> `True` May 19, 2011 at 19:54
• @Adam, it appears some people found my mistake and rescinded their votes. I had `<strike>` going through the bad example but it only showed on IE, so my edit left the answer in a very confusing state. Should be fixed now. May 20, 2011 at 0:47
• @kindall, incompatible types are orderable in Python 2, but not Python 3. You'll get a `TypeError` if you use `<` between a float and a tuple. May 25, 2011 at 6:29
• @kindall, in Python 3, floats and tuples aren't directly comparable.`TypeError: unorderable types: float() < tuple()` Dec 18, 2013 at 20:40

A better answer (now I'm just doing this for fun...), motivated by twiddling the bits. Handling the carry and overflows between parts of the number of negative values is somewhat tricky.

``````import struct

def floatToieee754Bits(f):
return struct.unpack('<Q', struct.pack('<d', f))

def ieee754BitsToFloat(i):
return struct.unpack('<d', struct.pack('<Q', i))

def incrementFloat(f):
i = floatToieee754Bits(f)
if f >= 0:
return ieee754BitsToFloat(i+1)
else:
raise Exception('f not >= 0: unsolved problem!')
``````
• I like this one, though I didn't understand it to begin with. (I Read: docs.python.org/library/struct.html and now understand it better.) The only thing i'm not a fan on is the function naming. ;) May 26, 2011 at 23:16
• This is what I came here to post. It is the simplest, most robust, and provably correct answer. Of course if you have a collision at Inf, you'll wrap around...
– Gabe
May 28, 2011 at 17:31
• This is also essentially Mark Dickinson's answer here. Dec 3, 2013 at 16:17

Instead of resolving the collisions by changing the key, how about collecting the collisions? IE:

``````bag = {}
bag[1234.] = 'something'
``````

becomes

``````bag = collections.defaultdict(list)
bag[1234.].append('something')
``````

would that work?

## For colliding key k, add: k / 250

Interesting problem. The amount you need to add obviously depends on the magnitude of the colliding value, so that a normalized add will affect only the least significant bits.

It's not necessary to determine the smallest value that can be added. All you need to do is approximate it. The FPU format provides 52 mantissa bits plus a hidden bit for 53 bits of precision. No physical constant is known to anywhere near this level of precision. No sensor is able measure anything near it. So you don't have a hard problem.

In most cases, for key k, you would be able to add k/253, because of that 52-bit fraction plus the hidden bit.

But it's not necessary to risk triggering library bugs or exploring rounding issues by shooting for the very last bit or anything near it.

### So I would say, for colliding key k, just add k / 250 and call it a day.1

1. Possibly more than once until it doesn't collide any more, at least to foil any diabolical unit test authors.

• Oh, and for zero, you could do something different, because a vastly smaller quantity based on the range (rather than the precision) of double values can be used. Add something like `1 / 2 ** 1020.` May 26, 2011 at 16:21
``````import sys
>>> sys.float_info.epsilon
2.220446049250313e-16
``````
• If you add this number to, say, 4.0, you will get a value that is exactly the same! May 19, 2011 at 19:40
• I think the proper usage would be `x+=x*sys.float_info.epsilon` May 19, 2011 at 19:45
• `sys.float_info.epsilon` is defined at the "smallest difference between 1.0 and the next largest value representable", so isn't safe to use relative to other values. May 19, 2011 at 20:27
• That's right, the smallest difference depends on the exponent. May 19, 2011 at 20:27
• @Mark is correct, it looks robust with big/small floats. Also, for version < 2.6 where there isn't any float_info, you can define `epsilon = 2*pow(2, -53)` May 24, 2011 at 3:02

Instead of modifying your float timestamp, use a tuple for every key as Mark Ransom suggests where the tuple `(x,y)` is composed of `x=your_unmodified_time_stamp` and `y=(extremely unlikely to be a same value twice)`.

So:

1. `x` just is the unmodified timestamp and can be the same value many times;
2. `y` you can use:
1. a random integer number from a large range,
2. serial integer (0,1,2,etc),
3. UUID.

While 2.1 (random int from a large range) there works great for ethernet, I would use 2.2 (serializer) or 2.3 (UUID). Easy, fast, bulletproof. For 2.2 and 2.3 you don't even need collision detection (you might want to still have it for 2.1 as ethernet does.)

The advantage of 2.2 is that you can also tell, and sort, data elements that have the same float time stamp.

Then just extract `x` from the tuple for any sorting type operations and the tuple itself is a collision free key for the hash / dictionary.

Edit

I guess example code will help:

``````#!/usr/bin/env python

import time
import sys
import random

#generator for ints from 0 to maxinteger on system:
serializer=(sn for sn in xrange(0,sys.maxint))

#a list with guranteed collisions:
times=[]
for c in range(0,35):
t=time.clock()
for i in range(0,random.choice(range(0,4))):
times.append(t)

print len(set(times)), "unique items in a list of",len(times)

#dictionary of tuples; no possibilities of collisions:
di={}
for time in times:
sn=serializer.next()
di[(time,sn)]='Element {}'.format(sn)

#for tuples of multiple numbers, Python sorts
# as you expect: first by t then t, until t[n]
for key in sorted(di.keys()):
print "{:>15}:{}".format(key, di[key])
``````

Output:

``````26 unique items in a list of 55
(0.042289, 0):Element 0
(0.042289, 1):Element 1
(0.042289, 2):Element 2
(0.042305, 3):Element 3
(0.042305, 4):Element 4
(0.042317, 5):Element 5
# and so on until Element n...
``````
• The approach seems hacky and complicated/unworkable. How would you retrieve a dict value in O(1) without already knowing the "y value" corresponding per each key? It seems to be just moving the same problem elsewhere.
– wim
Apr 9, 2020 at 22:02

Here it part of it. This is dirty and slow, but maybe that is how you like it. It is missing several corner cases, but maybe this gets someone else close.

The idea is to get the hex string of a floating point number. That gives you a string with the mantissa and exponent bits to twiddle. The twiddling is a pain since you have to do all it manually and keep converting to/from strings. Anyway, you add(subtract) 1 to(from) the last digit for positive(negative) numbers. Make sure you carry through to the exponent if you overflow. Negative numbers are a little more tricky to make you don't waste any bits.

``````def increment(f):
h = f.hex()
# decide if we need to increment up or down
if f > 0:
sign = '+'
inc = 1
else:
sign = '-'
inc = -1
# pull the string apart
h = h.split('0x')[-1]
h,e = h.split('p')
h = ''.join(h.split('.'))
h2 = shift(h, inc)
# increase the exponent if we added a digit
h2 = '%s0x%s.%sp%s' % (sign, h2, h2[1:], e)
return float.fromhex(h2)

def shift(s, num):
if not s:
return ''
right = s[-1]
right = int(right, 16) + num
if right > 15:
num = right // 16
right = right%16
elif right < 0:
right = 0
num = -1
else:
num = 0
right = hex(right)[2:]
return shift(s[:-1], num) + right

a = 1.4e4
print increment(a) - a
a = -1.4e4
print increment(a) - a

a = 1.4
print increment(a) - a
``````

I think you mean "by as small an amount possible to avoid a hash collision", since for example the next-highest-float may already be a key! =)

``````while toInsert.key in myDict: # assumed to be positive
toInsert.key *= 1.000000000001
myDict[toInsert.key] = toInsert
``````

That said you probably don't want to be using timestamps as keys.

• The actual epsilon varies on the value of the exponent though. I'm just going to keep adding until I get to a new value since collisions will be very rare. May 19, 2011 at 19:39
• ah oops, I realized that, just wasn't thinking; I'd actually then recommend multiplying; answer edited May 19, 2011 at 23:53

After Looking at Autopopulated's answer I came up with a slightly different answer:

``````import math, sys

def incrementFloatValue(value):
if value == 0:
return sys.float_info.min
mant, exponent = math.frexp(value)
epsilonAtValue = math.ldexp(1, exponent - sys.float_info.mant_dig)
return math.fsum([value, epsilonAtValue])
``````

Disclaimer: I'm really not as great at maths as I think I am ;) Please verify this is correct before using it. Also I'm not sure about performance

some notes:

• `epsilonAtValue` calculates how many bits are used for the mantissa (the maximum minus what is used for the exponent).
• I'm not sure if the `math.fsum()` is needed but hey it doesn't seem to hurt.
• Seems to work :) I think you need to special-case zero though. May 24, 2011 at 9:16

It turns out that this is actually quite complicated (maybe why seven people have answered without actually providing an answer yet...).

I think this is the right solution, it certainly seems to handle 0 and positive values correctly:

``````import math
import sys

def incrementFloat(f):
if f == 0.0:
return sys.float_info.min
m, e = math.frexp(f)
return math.ldexp(m + sys.float_info.epsilon / 2, e)
``````
• I provided an answer to the problem, just not an answer to the question! Sorry you didn't like it. May 24, 2011 at 3:20
• @Mark I appreciate that people are trying to be helpful (I did upvote most of the answers), but really the problem is the question. My thinking is partly along the lines of "what if someone else searched for how to increment a float by the smallest possible amount in the future" -- if they found a page full of tuples and discussion about hash collisions it wouldn't really much help. May 24, 2011 at 9:12
• If the people providing answers believe that using floats as keys is inherently a bad idea, then they are going to suggest staying away from floats as keys to anyone else who has the same question. May 25, 2011 at 19:58