Ok, seems like I have a reasonable answer. First let's define `binom(n,k)`

as the number of ways in which we can set `k`

out of `n`

bits. That's the classic Pascal triangle:

```
1 1
1 2 1
1 3 3 1
1 4 6 4 1
1 5 10 10 5 1
1 6 15 20 15 6 1
1 7 21 35 35 21 7 1
1 8 28 56 70 56 28 8 1
...
```

Easily calculated and cached. Note that the sum of each line is `1<<lineNumber`

.

The next thing we'll need is the `partial_sum`

of that triangle:

```
1 2
1 3 4
1 4 7 8
1 5 11 15 16
1 6 16 26 31 32
1 7 22 42 57 63 64
1 8 29 64 99 120 127 128
1 9 37 93 163 219 247 255 256
...
```

Again, this table can be created by summing two values from the previous line, except that the new entry on each line is now `1<<line`

instead of `1`

.

Let's use these tables above to construct `f(x)`

for an 8 bits number (it trivially generalizes to any number of bits). `f(0)`

still has to be 0. Looking up the 8th row in the first triangle, we see that next 8 entries are `f(1)`

to `f(9)`

, all with one bit set. The next 28 entries (7+6+5+4+3+2+1) all have 2 bits set, so that's f(10) to f(37). The next 56 entries, f(38) to f(93) have 3 bits, and there are 70 entries with 4 bits set. From symmetry we can see that they're centered around f(128), in particular they're f(94) to f(163). And obviously, the only number with 8 bits set sorts last, as f(255).

So, with these tables we can quickly determine how many bits must be set in f(i). Just do a binary search in the last row of your table. But that doesn't answer exactly *which* bits are set. For that we need the previous rows.

The reason that each value in the table can be created from the previous line is simple. binom(n,k) == binom(k, n-1) + binom(k-1, n-1). There are two sorts of numbers with k bits set: Those that start with a `0...`

and numbers which start with `1...`

. In the first case, the next `n-1`

bits must contain those `k`

bits, in the second case the next `n-1`

bits must contain only `k-1`

bits. Special cases are of course `0 out of n`

and `n out of n`

.

This same stucture can be used to quickly tell us what `f(16)`

must be. We already had established that it must contain 2 bits set, as it falls in the range `f(10) - f(37)`

. In particular, it's number 6 with 2 bits set (starting as usual with 0). It's useful to define this as an offset in a range as we'll try to shrink the length this range from 28 down to 1.

We now subdivide that range into 21 values which start with a zero and 7 which start a one. Since 6 < 21, we know that the first digit is a zero. Of the remaining 7 bits, still 2 need to be set, so we move up a line in the triangle and see that 15 values start with two zeroes, and 6 start with 01. Since 6 < 15, f(16) starts with 00. Going further up, 7 <= 10 so it starts with `000`

. But 6 == 6, so it doesn't start with `0000`

but `0001`

. At this point we change the start of the range, so the new offset becomes 0 (6-6)

We know need can focus only on the numbers that start with `0001`

and have one extra bit, which are `f(16)...f(19)`

. It should be obvious by know that the range is `f(16)=00010001, f(17)=00010010, f(18)=00010100, f(19)=00011000`

.

So, to calculate each bit, we move one row up in the triangle, compare our "remainder", add a zero or one based on the comparison possibly go left one column. That means the computational complexity of `f(x)`

is `O(bits)`

, or `O(log N)`

, and the storage needed is `O(bits*bits)`

.

`in only a few bits`

? e.g. like the hamming distance? – doctorlove Oct 10 '13 at 13:36which areset in ". In English you can often leave out such a pair of words: "the people who are walking there ..." -> "the people walking there ..." – MSalters Oct 10 '13 at 14:52