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I have read that everything in python is an object, and as such I started to experiment with different types and invoking __str__ on them — at first I was feeling really excited, but then I got confused.

>>> "hello world".__str__()
'hello world'
>>> [].__str__()
>>> 3.14.__str__()
>>> 3..__str__()
>>> 123.__str__()
  File "<stdin>", line 1
SyntaxError: invalid syntax
  • Why does something.__str__() work for "everything" besides int?
  • Is 123 not an object of type int?
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Look at what the message says: invalid syntax. That is an indication that this has nothing to do with the meaning of the construct, just about how your wrote it down. – Marc van Leeuwen Oct 11 at 12:03
Erm.. what's going on? Why are some answers marked as answered Jun 8 '12 while the question was asked yesterday? – Ruslan Oct 11 at 14:27
@Rusian two different questions, with answers on their own, was merged; that's why the timestamps look a bit weird. – Filip Roséen - refp Oct 11 at 14:41

4 Answers 4

You need parens:


The problem is the lexer thinks "4." is going to be a floating-point number.

Also, this works:

x = 4
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I much prefer the use of brackets here over a space. – Latty Jun 8 '12 at 20:34
The same happens with other languages, like Javascript. – Ismael Miguel Oct 10 at 23:45
@Bergi Did you read the bloody question? – Ismael Miguel Oct 11 at 19:09
up vote 42 down vote accepted

So you think you can  dance  floating-point?

123 is just as much of an object as 3.14, the "problem" lies within the grammar rules of the language; the parser thinks we are about to define a float — not an int with a trailing method call.

We will get the expected behavior if we wrap the number in parenthesis, as in the below.

>>> (123).__str__()

Or if we simply add some whitespace after 123:

>>> 123 .__str__()

The reason it does not work for 123.__str__() is that the dot following the 123 is interpreted as the decimal-point of some partially declared floating-point.

>>> 123.__str__()
  File "", line 1
SyntaxError: invalid syntax

The parser tries to interpret __str__() as a sequence of digits, but obviously fails — and we get a SyntaxError basically saying that the parser stumbled upon something that it did not expect.


When looking at 123.__str__() the python parser could use either 3 characters and interpret these 3 characters as an integer, or it could use 4 characters and interpret these as the start of a floating-point.

^^^ - int
^^^^- start of floating-point

Just as a little child would like as much cake as possible on their plate, the parser is greedy and would like to swallow as much as it can all at once — even if this isn't always the best of ideas —as such the latter ("better") alternative is chosen.

When it later realizes that __str__() can in no way be interpreted as the decimals of a floating-point it is already too late; SyntaxError.


 123 .__str__() # works fine

In the above snippet, 123  (note the space) must be interpreted as an integer since no number can contain spaces. This means that it is semantically equivalent to (123).__str__().


 123..__str__() # works fine

The above also works because a number can contain at most one decimal-point, meaning that it is equivalent to (123.).__str__().

For the language-lawyers

This section contains the lexical definition of the relevant literals.

Lexical analysis - 2.4.5 Floating point literals

floatnumber   ::=  pointfloat | exponentfloat
pointfloat    ::=  [intpart] fraction | intpart "."
exponentfloat ::=  (intpart | pointfloat) exponent
intpart       ::=  digit+
fraction      ::=  "." digit+
exponent      ::=  ("e" | "E") ["+" | "-"] digit+

Lexical analysis - 2.4.4 Integer literals

integer        ::=  decimalinteger | octinteger | hexinteger | bininteger
decimalinteger ::=  nonzerodigit digit* | "0"+
nonzerodigit   ::=  "1"..."9"
digit          ::=  "0"..."9"
octinteger     ::=  "0" ("o" | "O") octdigit+
hexinteger     ::=  "0" ("x" | "X") hexdigit+
bininteger     ::=  "0" ("b" | "B") bindigit+
octdigit       ::=  "0"..."7"
hexdigit       ::=  digit | "a"..."f" | "A"..."F"
bindigit       ::=  "0" | "1"
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Add a space after the 4:

4 .__str__()

Otherwise, the lexer will split this expression into the tokens "4.", "__str__", "(" and ")", i.e. the first token is interpreted as a floating point number. The lexer always tries to build the longest possible token.

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OK, but why on earth the lexer tries to build the longest possible token like this one 4. , Why is 4. a number in python? – Abderrahim ben Oct 11 at 20:31
@Abderrahimben: The lexers of most programming languages work by building the longest possible token. Cases with ambiguous tokenization are generally rare and should be avoided, and trying to automatically resolve the ambiguities would significantly complicate the lexer. 4. is a valid floating-point number it all programming languages I know of, including Python. – Sven Marnach Oct 11 at 21:07
@SvenMarnach One current programming language that is an exception is C#. It makes 4 a valid literal of type int, and 4.0 a valid literal of type double, but 4. two separate tokens. This way, double d = 4.; is disallowed, but the user can simply write double d = 4.0;. This way, string s = 4.ToString(); is allowed. (You did say "all programming languages [you] know of", so you're not wrong if you don't know of C#, but it's probably a useful addition for others.) – hvd Oct 12 at 9:22

actually (to increase unreadability...):


is valid, too. it gives '0x1.0000000000000p+2' -- but then it's a float, of course...

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