Python Decimal doesn't support being constructed from float; it expects that you have to convert float to a string first.

This is very inconvenient since standard string formatters for float require that you specify number of decimal places rather than significant places. So if you have a number that could have as many as 15 decimal places you need to format as Decimal("%.15f" % my_float), which will give you garbage at the 15th decimal place if you also have any significant digits before decimal (Decimal("%.15f" % 100000.3) == Decimal('100000.300000000002910')).

Can someone suggest a good way to convert from float to Decimal preserving value as the user has entered, perhaps limiting number of significant digits that can be supported?

  • 5
    Note that in python 2.7 you don't have to cast to a string first, Decimal(0.1) is now valid which prints as Decimal('0.1000000000000000055511151231257827021181583404541015625') Commented Sep 9, 2011 at 15:41

12 Answers 12


Python <2.7

"%.15g" % f

Or in Python 3.0:

format(f, ".15g")

Python 2.7+, 3.2+

Just pass the float to Decimal constructor directly, like this:

from decimal import Decimal
  • 41
    Passing float directly to Decimal constructor introduces a rounding error. It's better to convert a float to a string before passing it to the constructor. E.g. Decimal(0.30000000000000004) results in Decimal('0.3000000000000000444089209850062616169452667236328125'), and Decimal(str(0.30000000000000004)) results in Decimal('0.30000000000000004'). Commented Mar 17, 2020 at 14:00
  • 2
    @AliaksandrAdzinets: it depends on what you want to achieve. To get the value corresponding to the float (0.30000000000000004 .as_integer_ratio() -- the internal representation could be think of as binary numbers written in scientific notation), pass float directly. To get (naive) "what you see is what you get" decimal ratio: 30000000000000004/100000000000000000 , pass string. docs.python.org/3/tutorial/floatingpoint.html
    – jfs
    Commented Mar 19, 2020 at 18:46
  • 8
    @AliaksandrAdzinets: to be clear: it is NOT a rounding error. a float 0.30000000000000004 and a number represented by '0.30000000000000004' are different (because the later can't be represented exactly as a float) i.e., Decimal does NOT introduce the error here, it is the opposite str() changes float's value: it just happens that the error that str() produces might be desirable for a naive view on floats
    – jfs
    Commented Apr 16, 2020 at 15:33
  • 1
    Note that format(0.012345, ".2g") == 0.012 - three dps, whereas format(0.12345, ".2g") == 0.12. The f formatter should be used: format(0.012345, ".2f") == 0.01
    – Chris
    Commented May 27, 2020 at 14:49
  • 1
    @Chris: no. f would be wrong here. Try 1.23e-20
    – jfs
    Commented May 27, 2020 at 18:36

I suggest this

>>> a = 2.111111
>>> a
>>> str(a)
>>> decimal.Decimal(str(a))
  • 4
    This approach gives the most sensible result. Constructing a Decimal directly off the float as in Sebastian's answer can give surprising results in Python 2.7. Well, not surprising at all if you've played with floats before... Commented Feb 28, 2014 at 22:32
  • 2
    One note with this (as raised in comment for answer using repr()) is that str() here will limit to 17 decimal places, e.g. Decimal(str(0.12345678901234567890)) results in Decimal('0.12345678901234568').
    – Gary
    Commented Mar 23, 2019 at 15:26
  • Well, that doesn't work with: 8.9*0.7 --> >>> str(8.9*0.7) '6.2299999999999995' Commented Oct 13, 2022 at 9:38

You said in your question:

Can someone suggest a good way to convert from float to Decimal preserving value as the user has entered

But every time the user enters a value, it is entered as a string, not as a float. You are converting it to a float somewhere. Convert it to a Decimal directly instead and no precision will be lost.

  • Unfortunately it's stored as float in the DB and I can't change the schema
    – Kozyarchuk
    Commented Nov 25, 2008 at 4:10
  • 16
    Then you have already lost “the value as the user has entered” and you can't get it back. All you can do is apply an arbitrary rounding and hope. Python's treatment of Decimal correctly brings this to your attention so you understand the problem now instead of getting a weird bug later.
    – bobince
    Commented Nov 25, 2008 at 12:03
  • 2
    @Kozyarchuk: I know you said that you can't change the schema, but you may want to think about changing it to a decimal type (at some point), because this can become more of a headache in the future. Commented Nov 25, 2008 at 22:24
  • To be fair if you assume the value the user entered has at most 15 decimal digits then we know the value can be safely round-tripped to float, but this answer puts the problem in perspective instead of giving the wrong idea that Decimal's default constructor from float is unreasonable.
    – user202729
    Commented Jun 14 at 9:03

you can convert and than quantize to keep 5 digits after comma via

  • TypeError: conversion from type to Decimal is not supported
    – SuB
    Commented Nov 30, 2023 at 13:48
  • put over there your float Commented Nov 30, 2023 at 17:09

I've come across the the same problem / question today and I'm not completely satisfied with any of the answers given so far. The core of the question seems to be:

Can someone suggest a good way to convert from float to Decimal [...] perhaps limiting number of significant digits that can be supported?

Short answer / solution: Yes.

def ftod(val, prec = 15):
    return Decimal(val).quantize(Decimal(10)**-prec)

Long Answer:

As nosklo pointed out it is not possible to preserve the input of the user after it has been converted to float. It is possible though to round that value with a reasonable precision and convert it into Decimal.

In my case I only need 2 to 4 digits after the separator, but they need to be accurate. Let's consider the classic 0.1 + 0.2 == 0.3 check.

>>> 0.1 + 0.2 == 0.3

Now let's do this with conversion to decimal (complete example):

>>> from decimal import Decimal
>>> def ftod(val, prec = 15):   # float to Decimal
...     return Decimal(val).quantize(Decimal(10)**-prec)
>>> ftod(0.1) + ftod(0.2) == ftod(0.3)

The answer by Ryabchenko Alexander was really helpful for me. It only lacks a way to dynamically set the precision – a feature I want (and maybe also need). The Decimal documentation FAQ gives an example on how to construct the required argument string for quantize():

>>> Decimal(10)**-4

Here's how the numbers look like printed with 18 digits after the separator (coming from C programming I like the fancy python expressions):

>>> for x in [0.1, 0.2, 0.3, ftod(0.1), ftod(0.2), ftod(0.3)]:
...     print("{:8} {:.18f}".format(type(x).__name__+":", x))
float:   0.100000000000000006
float:   0.200000000000000011
float:   0.299999999999999989
Decimal: 0.100000000000000000
Decimal: 0.200000000000000000
Decimal: 0.300000000000000000

And last I want to know for which precision the comparision still works:

>>> for p in [15, 16, 17]:
...     print("Rounding precision: {}. Check  0.1 + 0.2 == 0.3  is {}".format(p,
...         ftod(0.1, p) + ftod(0.2, p) == ftod(0.3, p)))
Rounding precision: 15. Check  0.1 + 0.2 == 0.3  is True
Rounding precision: 16. Check  0.1 + 0.2 == 0.3  is True
Rounding precision: 17. Check  0.1 + 0.2 == 0.3  is False

15 seems to be a good default for maximum precision. That should work on most systems. If you need more info, try:

>>> import sys
>>> sys.float_info
sys.float_info(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, epsilon=2.220446049250313e-16, radix=2, rounds=1)

With float having 53 bits mantissa on my system, I calculated the number of decimal digits:

>>> import math
>>> math.log10(2**53)

Which tells me with 53 bits we get almost 16 digits. So 15 ist fine for the precision value and should always work. 16 is error-prone and 17 definitly causes trouble (as seen above).

Anyway ... in my specific case I only need 2 to 4 digits of precision, but as a perfectionist I enjoyed investigating this :-)

Any suggestions / improvements / complaints are welcome.

  • This answer is pretty much equivalent to Decimal("%.15f" % value), replacing %g in the top answer with %f --- but this is not always sensible because after all a double has ≈ 15 decimal digits of relative precision, not absolute accuracy.
    – user202729
    Commented Jun 14 at 8:58
  • This answer solves the problem and it answers the question. What's the point of your comment? Can you please elaborate on it?!
    – ChristophK
    Commented Jun 15 at 10:59

The "official" string representation of a float is given by the repr() built-in:

>>> repr(1.5)
>>> repr(12345.678901234567890123456789)

You can use repr() instead of a formatted string, the result won't contain any unnecessary garbage.

  • repr returns 17 significant places, but there are often errors in 16th and 17th significant place. So the following does not work. from decimal import Decimal start = Decimal('500.123456789016') assert start == Decimal(repr(float(start))), "%s != %s " % (start, Decimal(repr(float(start))))
    – Kozyarchuk
    Commented Nov 25, 2008 at 3:09
  • 4
    @Kozyarchuk: This is not an issue with the number of significant digits. It's a problem with binary representation of decimal numbers. Your example fails for 0.6, too.
    – davidavr
    Commented Nov 25, 2008 at 4:07
  • 1
    repr returns the shortest representation that results in the same IEEE-754 double. Commented Mar 6, 2019 at 3:27
  • I should note that the '500.123456789016' testcase works fine in the modern versions of Python (possibly thanks to bugs.python.org/issue1580 ?), so Decimal(repr(my_float)) seems to be the way to go if you absolutely can't avoid the float in the first place.
    – Nickolay
    Commented Nov 5, 2021 at 5:45

Python does support Decimal creation from a float. You just cast it as a string first. But the precision loss doesn't occur with string conversion. The float you are converting doesn't have that kind of precision in the first place. (Otherwise you wouldn't need Decimal)

I think the confusion here is that we can create float literals in decimal format, but as soon as the interpreter consumes that literal the inner representation becomes a floating point number.


When you say "preserving value as the user has entered", why not just store the user-entered value as a string, and pass that to the Decimal constructor?


The main answer is slightly misleading. The g format ignores any leading zeroes after the decimal point, so format(0.012345, ".2g") returns 0.012 - three decimal places. If you need a hard limit on the number of decimal places, use the f formatter: format(0.012345, ".2f") == 0.01


The "right" way to do this was documented in 1990 by Steele and White's and Clinger's PLDI 1990 papers.

You might also look at this SO discussion about Python Decimal, including my suggestion to try using something like frap to rationalize a float.


You can use JSON to accomplish it

import json
from decimal import Decimal

float_value = 123456.2365
decimal_value = json.loads(json.dumps(float_value), parse_float=Decimal)
  • 1
    This does not seem right. JSON is used as data interchange format and all the code will do is convert float to string and then load that string as Decimal. Downvoted.
    – dotz
    Commented Oct 27, 2021 at 23:50
  • Yet it reminds us that we got the float by parsing JSON in the first place, there's a way to sidestep this whole float->decimal conversion altogether. Thanks!
    – Nickolay
    Commented Nov 5, 2021 at 5:38

Inspired by this answer I found a workaround that allows to shorten the construction of a Decimal from a float bypassing (only apparently) the string step:

import decimal
class DecimalBuilder(float):
    def __or__(self, a):
         return decimal.Decimal(str(a))

>>> d = DecimalBuilder()
>>> x = d|0.1
>>> y = d|0.2
>>> x + y # works as desired
>>> d|0.1 + d|0.2 # does not work as desired, needs parenthesis
TypeError: unsupported operand type(s) for |: 'decimal.Decimal' and 'float'
>>> (d|0.1) + (d|0.2) # works as desired

It's a workaround but it surely allows savings in code typing and it's very readable.

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