# why using negative int for mod operation in toString method of Integer class in java src

when I read the source code of java version 1.7.0_09, I found that the realization of toString method of Integer class uses negative int to calculate the mod operation, is there any sense to that? code is as follows:

``````public static String toString(int i, int radix) {

/* Use the faster version */
}

char buf[] = new char[33];
boolean negative = (i < 0);
int charPos = 32;

if (!negative) {
i = -i;                //***** change i to negative
}

buf[charPos--] = digits[-(i % radix)];   //***** change back to positive after
//***** mod operation
}
buf[charPos] = digits[-i];

if (negative) {
buf[--charPos] = '-';
}

return new String(buf, charPos, (33 - charPos));
}
``````
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According to the algorithm, you need a stream of small (`< radix`) nonnegative integers that will fill the character buffer with digits from right to left. The standard, primary-school way to make this work is to put a sign at the beginning of the number, and then print the absolute value of the number.

But imagine if the rule were that `i` is always positive in that loop:

``````if (negative) {
i = -i; // change i to positive
}
``````

If `i` happens to be `Integer.MIN_VALUE`, then `-i` also happens to be `Integer.MIN_VALUE`. Two's complement integer variables can store exactly one more negative integer than they can store positive integers. However, if the invariant is instead that `i` is always the negative absolute value, it will always fit in an `int`.

Why not just use `Math.abs()` or an `if` block? Naturally, integers are converted to strings very frequently in many computer programs, so it is useful to keep `toString` as fast as possible. The trouble is, both `Math.abs()` and `if` statements will likely be compiled to use branch instructions when compiled to machine code. Branches tend to interfere with instruction pipelining; therefore, when paying attention to performance you might choose to remove `if` statements from loops when possible.

NOTE: This kind of optimization is rarely a good idea! The performance gain is miniscule unless your code is called very very frequently (like this code) or you are building a library with lots of users and few readers/modifiers (like this code), and it makes code harder to read, understand, and change. By making this optimization, the Java engineers might speed up your code very slightly--but if you put techniques like this in code you write, your coworker/grader may not be inclined to ask Stack Overflow why your code is so hard to understand. :)

TL;DR: Just an educated guess, but this is a combination of two's complement math and code optimization.

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Thx a lot! I think this is what i want! –  Judking Oct 28 '12 at 9:53