# Convert float to string in positional format (without scientific notation and false precision)

I want to print some floating point numbers so that they're always written in decimal form (e.g. `12345000000000000000000.0` or `0.000000000000012345`, not in scientific notation, yet I'd want to the result to have the up to ~15.7 significant figures of a IEEE 754 double, and no more.

What I want is ideally so that the result is the shortest string in positional decimal format that still results in the same value when converted to a `float`.

It is well-known that the `repr` of a `float` is written in scientific notation if the exponent is greater than 15, or less than -4:

``````>>> n = 0.000000054321654321
>>> n
5.4321654321e-08  # scientific notation
``````

If `str` is used, the resulting string again is in scientific notation:

``````>>> str(n)
'5.4321654321e-08'
``````

It has been suggested that I can use `format` with `f` flag and sufficient precision to get rid of the scientific notation:

``````>>> format(0.00000005, '.20f')
'0.00000005000000000000'
``````

It works for that number, though it has some extra trailing zeroes. But then the same format fails for `.1`, which gives decimal digits beyond the actual machine precision of float:

``````>>> format(0.1, '.20f')
'0.10000000000000000555'
``````

And if my number is `4.5678e-20`, using `.20f` would still lose relative precision:

``````>>> format(4.5678e-20, '.20f')
'0.00000000000000000005'
``````

Thus these approaches do not match my requirements.

This leads to the question: what is the easiest and also well-performing way to print arbitrary floating point number in decimal format, having the same digits as in `repr(n)` (or `str(n)` on Python 3), but always using the decimal format, not the scientific notation.

That is, a function or operation that for example converts the float value `0.00000005` to string `'0.00000005'`; `0.1` to `'0.1'`; `420000000000000000.0` to `'420000000000000000.0'` or `420000000000000000` and formats the float value `-4.5678e-5` as `'-0.000045678'`.

After the bounty period: It seems that there are at least 2 viable approaches, as Karin demonstrated that using string manipulation one can achieve significant speed boost compared to my initial algorithm on Python 2.

Thus,

Since I am primarily developing on Python 3, I will accept my own answer, and shall award Karin the bounty.

• And please if you do have a better answer to this question, do share it. Aug 9, 2016 at 10:28
• Project for a rainy day: add a low-level library function to Python (possibly in the `sys` module) that returns the "raw" binary-to-decimal conversion result for a given finite float (i.e., string of digits, decimal exponent, sign). That would give people the freedom to format as they saw fit. Aug 11, 2016 at 7:21
• Short answer: no, there isn't an easier way to do this; at least, not one that I'm aware of, and that also gives decently precise results. (Any solution that involves first pre-processing the number by scaling by powers of 10 is going to risk introducing numerical errors.) Aug 12, 2016 at 7:48
• since you required precision is 15.7 decimal digits ~= 16 decimal digits of precision why your examples request precision 20? Sep 8, 2019 at 19:40
• The 20 isn't precision but scale! Sep 8, 2019 at 19:44

Unfortunately it seems that not even the new-style formatting with `float.__format__` supports this. The default formatting of `float`s is the same as with `repr`; and with `f` flag there are 6 fractional digits by default:

``````>>> format(0.0000000005, 'f')
'0.000000'
``````

However there is a hack to get the desired result - not the fastest one, but relatively simple:

• first the float is converted to a string using `str()` or `repr()`
• then a new `Decimal` instance is created from that string.
• `Decimal.__format__` supports `f` flag which gives the desired result, and, unlike `float`s it prints the actual precision instead of default precision.

Thus we can make a simple utility function `float_to_str`:

``````import decimal

# create a new context for this task
ctx = decimal.Context()

# 20 digits should be enough for everyone :D
ctx.prec = 20

def float_to_str(f):
"""
Convert the given float to a string,
without resorting to scientific notation
"""
d1 = ctx.create_decimal(repr(f))
return format(d1, 'f')
``````

Care must be taken to not use the global decimal context, so a new context is constructed for this function. This is the fastest way; another way would be to use `decimal.local_context` but it would be slower, creating a new thread-local context and a context manager for each conversion.

This function now returns the string with all possible digits from mantissa, rounded to the shortest equivalent representation:

``````>>> float_to_str(0.1)
'0.1'
>>> float_to_str(0.00000005)
'0.00000005'
>>> float_to_str(420000000000000000.0)
'420000000000000000'
>>> float_to_str(0.000000000123123123123123123123)
'0.00000000012312312312312313'
``````

The last result is rounded at the last digit

As @Karin noted, `float_to_str(420000000000000000.0)` does not strictly match the format expected; it returns `420000000000000000` without trailing `.0`.

• Why don't you use `decimal.localcontext`? `with localcontext() as ctx: ctx.prec = 20; d1 = Decimal(str(f))` Aug 9, 2016 at 10:16
• @Bakuriu why would I, it can only be slower Aug 9, 2016 at 10:17
• I see precision loss in the output for 0.000000000123123123123123123123 - the `float_to_str` output cuts off at only 12 digits of precision, not enough to reconstruct the original float. Aug 18, 2016 at 18:17
• @user2357112 good catch. You're using Python 2; in Python 2 `str` only has 12 digits of precision while `repr` uses the Python 3 compatible algorithm. In Python 3, both forms are similar, thus the confusion. I changed my code to use `repr`. Aug 18, 2016 at 18:26
• This helped me a lot! Thanks for the clear explanation Aug 2, 2021 at 17:23

If you are satisfied with the precision in scientific notation, then could we just take a simple string manipulation approach? Maybe it's not terribly clever, but it seems to work (passes all of the use cases you've presented), and I think it's fairly understandable:

``````def float_to_str(f):
float_string = repr(f)
if 'e' in float_string:  # detect scientific notation
digits, exp = float_string.split('e')
digits = digits.replace('.', '').replace('-', '')
exp = int(exp)
zero_padding = '0' * (abs(int(exp)) - 1)  # minus 1 for decimal point in the sci notation
sign = '-' if f < 0 else ''
if exp > 0:
else:
return float_string

n = 0.000000054321654321
assert(float_to_str(n) == '0.000000054321654321')

n = 0.00000005
assert(float_to_str(n) == '0.00000005')

n = 420000000000000000.0
assert(float_to_str(n) == '420000000000000000.0')

n = 4.5678e-5
assert(float_to_str(n) == '0.000045678')

n = 1.1
assert(float_to_str(n) == '1.1')

n = -4.5678e-5
assert(float_to_str(n) == '-0.000045678')
``````

Performance:

I was worried this approach may be too slow, so I ran `timeit` and compared with the OP's solution of decimal contexts. It appears the string manipulation is actually quite a bit faster. Edit: It appears to only be much faster in Python 2. In Python 3, the results were similar, but with the decimal approach slightly faster.

Result:

• Python 2: using `ctx.create_decimal()`: `2.43655490875`

• Python 2: using string manipulation: `0.305557966232`

• Python 3: using `ctx.create_decimal()`: `0.19519368198234588`

• Python 3: using string manipulation: `0.2661344590014778`

Here is the timing code:

``````from timeit import timeit

CODE_TO_TIME = '''
float_to_str(0.000000054321654321)
float_to_str(0.00000005)
float_to_str(420000000000000000.0)
float_to_str(4.5678e-5)
float_to_str(1.1)
float_to_str(-0.000045678)
'''
SETUP_1 = '''
import decimal

# create a new context for this task
ctx = decimal.Context()

# 20 digits should be enough for everyone :D
ctx.prec = 20

def float_to_str(f):
"""
Convert the given float to a string,
without resorting to scientific notation
"""
d1 = ctx.create_decimal(repr(f))
return format(d1, 'f')
'''
SETUP_2 = '''
def float_to_str(f):
float_string = repr(f)
if 'e' in float_string:  # detect scientific notation
digits, exp = float_string.split('e')
digits = digits.replace('.', '').replace('-', '')
exp = int(exp)
zero_padding = '0' * (abs(int(exp)) - 1)  # minus 1 for decimal point in the sci notation
sign = '-' if f < 0 else ''
if exp > 0:
else:
return float_string
'''

print(timeit(CODE_TO_TIME, setup=SETUP_1, number=10000))
print(timeit(CODE_TO_TIME, setup=SETUP_2, number=10000))
``````
• Ahh that seems obvious from the docs now. Great to know! I've updated my timing code and it looks much cleaner now thanks to you :) Aug 17, 2016 at 4:39
• I'm consistently surprised how often the naive "just stringify it" approach works, and sometimes works even better than other cases. Aug 17, 2016 at 14:52
• Frankly, I didn't remember that the returned string was without `.0`, I didn't copy-paste my example output from Python shell, instead writing it here. Good catch :D I fixed my answer. Aug 17, 2016 at 17:26
• `decimal` has received several speed improvements in Python 3.3 (switch to libmpdec, caching, etc.) leading to 10x - 100x performance gains depending on what you are trying to make it do. Aug 17, 2016 at 17:56
• @Antti Thanks! This was a fun use case :) Also updated my code to use `repr` as suggested. Aug 19, 2016 at 1:45

As of NumPy 1.14.0, you can just use `numpy.format_float_positional`. For example, running against the inputs from your question:

``````>>> numpy.format_float_positional(0.000000054321654321)
'0.000000054321654321'
>>> numpy.format_float_positional(0.00000005)
'0.00000005'
>>> numpy.format_float_positional(0.1)
'0.1'
>>> numpy.format_float_positional(4.5678e-20)
'0.000000000000000000045678'
``````

`numpy.format_float_positional` uses the Dragon4 algorithm to produce the shortest decimal representation in positional format that round-trips back to the original float input. There's also `numpy.format_float_scientific` for scientific notation, and both functions offer optional arguments to customize things like rounding and trimming of zeros.

• Hey, that's nice. Not practical if NumPy is not needed otherwise, but if it is this is definitely what one should be using. Mar 23, 2019 at 8:19
• Even better answer. Though my opinion is that this functionality should be included directly as an option in the `.format` method for strings. Decimal representations with a significant figure limit are an extremely common use case in scientific graphs with logarithmic scales. Oct 28, 2019 at 12:21
• numpy.format_float_positional(27052805291130213231.64)=='27052805291130212000.' Aug 24 at 8:36
• @CSQGB: That's normal. Floats don't have enough precision to represent all the digits of 27052805291130213231.64. The value gets rounded to a float with exact numeric value 27052805291130212352, and `'27052805291130212000.'` is the shortest (in terms of minimum significant digits) decimal representation in positional format that produces that same float. Aug 24 at 9:20
• Note that the question specifically wanted to avoid reporting false precision, and asked for "the result to have the up to ~15.7 significant figures of a IEEE 754 double, and no more". Returning `'27052805291130212352.'` would go against what the question asked for (and the float doesn't contain enough information to return `'27052805291130213231.64'`). Aug 24 at 9:26

If you are ready to lose your precision arbitrary by calling `str()` on the float number, then it's the way to go:

``````import decimal

def float_to_string(number, precision=20):
return '{0:.{prec}f}'.format(
decimal.Context(prec=100).create_decimal(str(number)),
prec=precision,
).rstrip('0').rstrip('.') or '0'
``````

It doesn't include global variables and allows you to choose the precision yourself. Decimal precision 100 is chosen as an upper bound for `str(float)` length. The actual supremum is much lower. The `or '0'` part is for the situation with small numbers and zero precision.

Note that it still has its consequences:

``````>> float_to_string(0.10101010101010101010101010101)
'0.10101010101'
``````

Otherwise, if the precision is important, `format` is just fine:

``````import decimal

def float_to_string(number, precision=20):
return '{0:.{prec}f}'.format(
number, prec=precision,
).rstrip('0').rstrip('.') or '0'
``````

It doesn't miss the precision being lost while calling `str(f)`. The `or`

``````>> float_to_string(0.1, precision=10)
'0.1'
>> float_to_string(0.1)
'0.10000000000000000555'
>>float_to_string(0.1, precision=40)
'0.1000000000000000055511151231257827021182'

>>float_to_string(4.5678e-5)
'0.000045678'

>>float_to_string(4.5678e-5, precision=1)
'0'
``````

Anyway, maximum decimal places are limited, since the `float` type itself has its limits and cannot express really long floats:

``````>> float_to_string(0.1, precision=10000)
'0.1000000000000000055511151231257827021181583404541015625'
``````

Also, whole numbers are being formatted as-is.

``````>> float_to_string(100)
'100'
``````
• There is no need to create that Decimal at all, your approach works for `float`s already, but the result of false precision was rejected in the question. These are rounded measurement results, not some arbitrary binary fractions. Aug 15, 2016 at 7:34

I think `rstrip` can get the job done.

``````a=5.4321654321e-08
'{0:.40f}'.format(a).rstrip("0") # float number and delete the zeros on the right
# '0.0000000543216543210000004442039220863003' # there's roundoff error though
``````

Let me know if that works for you.

• Unfortunately as I stated in my question, I do not want any residual fractional part from the fact that these happened to be stored as binary. Aug 18, 2016 at 18:03

Interesting question, to add a little bit more of content to the question, here's a litte test comparing @Antti Haapala and @Harold solutions outputs:

``````import decimal
import math

ctx = decimal.Context()

def f1(number, prec=20):
ctx.prec = prec
return format(ctx.create_decimal(str(number)), 'f')

def f2(number, prec=20):
return '{0:.{prec}f}'.format(
number, prec=prec,
).rstrip('0').rstrip('.')

k = 2*8

for i in range(-2**8,2**8):
if i<0:
value = -k*math.sqrt(math.sqrt(-i))
else:
value = k*math.sqrt(math.sqrt(i))

value_s = '{0:.{prec}E}'.format(value, prec=10)

n = 10

print ' | '.join([str(value), value_s])
for f in [f1, f2]:
test = [f(value, prec=p) for p in range(n)]
print '\t{0}'.format(test)
``````

Neither of them gives "consistent" results for all cases.

• With Anti's you'll see strings like '-000' or '000'
• With Harolds's you'll see strings like ''

I'd prefer consistency even if I'm sacrificing a little bit of speed. Depends which tradeoffs you want to assume for your use-case.

• Why are you adjusting the precision in my approach? I fixed it to 20 to get all of the 15.7 decimal digits of precision of IEEE-754 doubles. Aug 17, 2016 at 16:50

using format(float, ' .f '):

``````old = 0.00000000000000000000123
if str(old).__contains__('e-'):
float_length = str(old)[-2:]
new=format(old,'.'+str(float_length)+'f')
print(old)
print(new)
``````