I know that most decimals don't have an exact floating point representation (Is floating point math broken?).

But I don't see why 4*0.1 is printed nicely as 0.4, but 3*0.1 isn't, when both values actually have ugly decimal representations:

>>> 3*0.1
>>> 4*0.1
>>> from decimal import Decimal
>>> Decimal(3*0.1)
>>> Decimal(4*0.1)
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    Because some numbers can be represented exactly, and some can't. – Morgan Thrapp Sep 21 '16 at 14:13
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    @MorganThrapp: no it isn't. The OP is asking about the rather arbitrary-looking formatting choice. Neither 0.3 nor 0.4 can be represented exactly in binary floating point. – Bathsheba Sep 21 '16 at 14:13
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    @BartoszKP: Having read the document several times, it doesn't explain why Python is displaying 0.3000000000000000444089209850062616169452667236328125 as 0.30000000000000004 and 0.40000000000000002220446049250313080847263336181640625 as .4 even though they appear to have the same accuracy, and thus doesn't answer the question. – Mooing Duck Sep 21 '16 at 17:36
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    See also stackoverflow.com/questions/28935257/… - I'm somewhat irritated that it got closed as a duplicate but this one hasn't. – Random832 Sep 22 '16 at 1:23
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    Reopened, please do not close this as a duplicate of "is floating point math broken". – Antti Haapala Sep 23 '16 at 21:06

The simple answer is because 3*0.1 != 0.3 due to quantization (roundoff) error (whereas 4*0.1 == 0.4 because multiplying by a power of two is usually an "exact" operation).

You can use the .hex method in Python to view the internal representation of a number (basically, the exact binary floating point value, rather than the base-10 approximation). This can help to explain what's going on under the hood.

>>> (0.1).hex()
>>> (0.3).hex()
>>> (0.1*3).hex()
>>> (0.4).hex()
>>> (0.1*4).hex()

0.1 is 0x1.999999999999a times 2^-4. The "a" at the end means the digit 10 - in other words, 0.1 in binary floating point is very slightly larger than the "exact" value of 0.1 (because the final 0x0.99 is rounded up to 0x0.a). When you multiply this by 4, a power of two, the exponent shifts up (from 2^-4 to 2^-2) but the number is otherwise unchanged, so 4*0.1 == 0.4.

However, when you multiply by 3, the little tiny difference between 0x0.99 and 0x0.a0 (0x0.07) magnifies into a 0x0.15 error, which shows up as a one-digit error in the last position. This causes 0.1*3 to be very slightly larger than the rounded value of 0.3.

Python 3's float repr is designed to be round-trippable, that is, the value shown should be exactly convertible into the original value. Therefore, it cannot display 0.3 and 0.1*3 exactly the same way, or the two different numbers would end up the same after round-tripping. Consequently, Python 3's repr engine chooses to display one with a slight apparent error.

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    This is an amazingly comprehensive answer, thank you. (In particular, thanks for showing .hex(); I didn't know it existed.) – NPE Sep 21 '16 at 14:33
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    @supercat: Python tries to find the shortest string that would round to the desired value, whatever that happens to be. Obviously the evaluated value must be within 0.5ulp (or it would round to something else), but it may require more digits in ambiguous cases. The code is very gnarly, but if you want to take a peek: hg.python.org/cpython/file/03f2c8fc24ea/Python/dtoa.c#l2345 – nneonneo Sep 21 '16 at 16:16
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    @supercat: Always the shortest string that's within 0.5 ulp. (Strictly within if we're looking at a float with odd LSB; i.e., the shortest string that makes it work with round-ties-to-even). Any exceptions to this are a bug, and should be reported. – Mark Dickinson Sep 21 '16 at 19:17
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    @MarkRansom Surely they did use something else than e because that's already a hex digit. Maybe p for power instead of exponent. – Bergi Sep 22 '16 at 4:12
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    @Bergi: The use of p in this context goes back (at least) to C99, and also appears in IEEE 754 and in various other languages (including Java). When float.hex and float.fromhex were implemented (by me :-), Python was merely copying what was by then established practice. I don't know whether the intention was 'p' for "Power", but it seems like a nice way to think about it. – Mark Dickinson Sep 22 '16 at 7:50

repr (and str in Python 3) will put out as many digits as required to make the value unambiguous. In this case the result of the multiplication 3*0.1 isn't the closest value to 0.3 (0x1.3333333333333p-2 in hex), it's actually one LSB higher (0x1.3333333333334p-2) so it needs more digits to distinguish it from 0.3.

On the other hand, the multiplication 4*0.1 does get the closest value to 0.4 (0x1.999999999999ap-2 in hex), so it doesn't need any additional digits.

You can verify this quite easily:

>>> 3*0.1 == 0.3
>>> 4*0.1 == 0.4

I used hex notation above because it's nice and compact and shows the bit difference between the two values. You can do this yourself using e.g. (3*0.1).hex(). If you'd rather see them in all their decimal glory, here you go:

>>> Decimal(3*0.1)
>>> Decimal(0.3)
>>> Decimal(4*0.1)
>>> Decimal(0.4)
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    (+1) Nice answer, thanks. Do you think it might be worth illustrating the "not the closest value" point by including the result of 3*0.1 == 0.3 and 4*0.1 == 0.4? – NPE Sep 21 '16 at 14:29
  • @NPE I should have done that right out of the gate, thanks for the suggestion. – Mark Ransom Sep 21 '16 at 14:34
  • I wonder if it would be worth noting the precise decimal values of the nearest "doubles" to 0.1, 0.3, and 0.4, since a lot of people can't read floating-point hex. – supercat Sep 21 '16 at 15:04
  • @supercat you make a good point. Putting those super large doubles into the text would be distracting, but I thought of a way to add them. – Mark Ransom Sep 21 '16 at 15:36

Here's a simplified conclusion from other answers.

If you check a float on Python's command line or print it, it goes through function repr which creates its string representation.

Starting with version 3.2, Python's str and repr use a complex rounding scheme, which prefers nice-looking decimals if possible, but uses more digits where necessary to guarantee bijective (one-to-one) mapping between floats and their string representations.

This scheme guarantees that value of repr(float(s)) looks nice for simple decimals, even if they can't be represented precisely as floats (eg. when s = "0.1").

At the same time it guarantees that float(repr(x)) == x holds for every float x

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    Your answer is accurate for Python versions >= 3.2, where str and repr are identical for floats. For Python 2.7, repr has the properties you identify, but str is much simpler - it simply computes 12 significant digits and produces an output string based on those. For Python <= 2.6, both repr and str are based on a fixed number of significant digits (17 for repr, 12 for str). (And nobody cares about Python 3.0 or Python 3.1 :-) – Mark Dickinson Sep 21 '16 at 18:27
  • Thanks @MarkDickinson! I included your comment in the answer. – Aivar Sep 21 '16 at 18:37
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    Note that the rounding from shell comes from repr thus the Python 2.7 behaviour would be identical... – Antti Haapala Sep 23 '16 at 21:09

Not really specific to Python's implementation but should apply to any float to decimal string functions.

A floating point number is essentially a binary number, but in scientific notation with a fixed limit of significant figures.

The inverse of any number that has a prime number factor that is not shared with the base will always result in a recurring dot point representation. For example 1/7 has a prime factor, 7, that is not shared with 10, and therefore has a recurring decimal representation, and the same is true for 1/10 with prime factors 2 and 5, the latter not being shared with 2; this means that 0.1 cannot be exactly represented by a finite number of bits after the dot point.

Since 0.1 has no exact representation, a function that converts the approximation to a decimal point string will usually try to approximate certain values so that they don't get unintuitive results like 0.1000000000004121.

Since the floating point is in scientific notation, any multiplication by a power of the base only affects the exponent part of the number. For example 1.231e+2 * 100 = 1.231e+4 for decimal notation, and likewise, 1.00101010e11 * 100 = 1.00101010e101 in binary notation. If I multiply by a non-power of the base, the significant digits will also be affected. For example 1.2e1 * 3 = 3.6e1

Depending on the algorithm used, it may try to guess common decimals based on the significant figures only. Both 0.1 and 0.4 have the same significant figures in binary, because their floats are essentially truncations of (8/5)(2^-4) and (8/5)(2^-6) respectively. If the algorithm identifies the 8/5 sigfig pattern as the decimal 1.6, then it will work on 0.1, 0.2, 0.4, 0.8, etc. It may also have magic sigfig patterns for other combinations, such as the float 3 divided by float 10 and other magic patterns statistically likely to be formed by division by 10.

In the case of 3*0.1, the last few significant figures will likely be different from dividing a float 3 by float 10, causing the algorithm to fail to recognize the magic number for the 0.3 constant depending on its tolerance for precision loss.

Edit: https://docs.python.org/3.1/tutorial/floatingpoint.html

Interestingly, there are many different decimal numbers that share the same nearest approximate binary fraction. For example, the numbers 0.1 and 0.10000000000000001 and 0.1000000000000000055511151231257827021181583404541015625 are all approximated by 3602879701896397 / 2 ** 55. Since all of these decimal values share the same approximation, any one of them could be displayed while still preserving the invariant eval(repr(x)) == x.

There is no tolerance for precision loss, if float x (0.3) is not exactly equal to float y (0.1*3), then repr(x) is not exactly equal to repr(y).

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    This does not really add much to the existing answers. – Antti Haapala Sep 23 '16 at 21:10
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    "Depending on the algorithm used, it may try to guess common decimals based on the significant figures only." <- This seems like pure speculation. Other answers have described what Python actually does. – Mark Dickinson Sep 24 '16 at 9:52

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