Can anyone explain me how different spacing affects the unary operator?
int i = 1; int j = i+ + +i; // this will print j=2 int k = i++ +i; // this will print k=3 int l = i+++i; // this will print l=3 int m = i++++i; // compile time error
First, let's separate this into three separate cases which can't interact:
int i = 1; System.out.println(i+ + +i); // 2 int j = 1; System.out.println(j++ +j); // 3 int k = 1; System.out.println(k+++k); // 3
Now let's rewrite them using brackets:
int i = 1; System.out.println(i + (+(+i))); int j = 1; System.out.println((j++) + j); int k = 1; System.out.println((k++) + k);
Here we can't be using the prefix or postfix ++ operators, as we don't have a token of
++ anywhere. Instead, we have a binary + operator and two unary + operators.
This one's simple: it's pretty much as it reads, a postfix ++ operator followed by a binary + operator (not the unary + operator that
+j might otherwise imply).
The final line is parsed as
(k++) + k rather than
k + (++k). Both will actually give the same answer in this situation, but we can prove which is which by using two different variables instead:
int k1 = 1; int k2 = 1; System.out.println(k1+++k2); // Prints 2 System.out.println(k1); // Prints 2 System.out.println(k2); // Prints 1
As you can see, it's
k1 that's been incremented rather than
The reason that
k+++k is parsed as tokens of
k is due to section 3.2 of the JLS, which includes:
The longest possible translation is used at each step, even if the result does not ultimately make a correct program while another lexical translation would.
The same "longest possible translation" rule parses
i which isn't a valid expression (because the result of the
++ operation is a value, not a variable).
+ is an operator, and
++ is an operator, but
+ + is not -
+ + is interpreted as two
+s, not one
++. So the space forces your code to be interpreted differently.
+ is both a binary operator which adds two numbers and a unary operator which does not change a number (it exists only for consistency with the unary
If we use
add instead of binary
no-change instead of unary
increment instead of
++ then it might be more clear.
int j=i+ + +i becomes
int j = i add no-change no-change i;.
int k=i++ +i; becomes
int k=i increment add i;.
int k = i+++i; also becomes
int k = i increment add i; but I have not checked this with the language specification.