# Using bitset in place of using hand written bit manipulation code?

Is there any performance loss/gain using bitset in place where hand written?

How to build the following using a bitset at runtime

• make all the bits between 2 and 5 as zero i.e., `11110011`.
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The easiest solution to your second question would be to use another bitset.

``````void makebitszero(bitset<8>& b) {
// Everything but bits 3 and 4 (between 2 and 5).
static const bitset<8> mask = ~bitset<8>(12);
}
``````

It takes a bit of math to come up with an expression for `mask` given two bit positions.

 Ok, here's the math. The trick is that `(1UL << X) -1` is a sequence of `X` ones. E.g. 3 => 00000111. Hence, (1<<5) - (1<<3) = 00011111 - 00000111 -1 + 1 = 00011000 (bits 3 and 4). Thus in code:

``````template<int i, int j, int N>
void makeBitsZero(bitset<N>& b) {
// Everything from bit i up to but not including bit j (i < j)
static const bitset<N> mask = ~bitset<N>(1UL<<j) - (1UL<<i));
}
``````
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The golden rule:

Don't optimise prematurely!

Bitset will in 99% of cases, be fast enough, and has the advantage of being a common concept such that it's both more readable, and less prone to implementation errors. Don't simply assume that your code will obviously need the speed increase; write the code using bitset, profile your application, and see if:

1. It's fast enough as it is; and
2. If it's not fast enough, does it really spend the majority of its time doing bit operations?

Per the 80-20 rule, chances are that you'll get a much greater return on making some other bit of code faster. And hey, if it turns out that you do need to improve the bit-twiddling speed, at least you have some decent baseline figures to use in order to show that you r solution really is faster than the default (which you'd need anyway if you wanted to optimise for performance).

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For a simple example such as the above, a decent hand-coded solution will be faster than using bitset, but the performance differences in either case would be small.

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