The previous one-liner solution,

```
n ^ sum(2**i for i in range(0, len(bin(n))-2, 2))
```

is an O(lg n) solution, where n is the input number. The asymptotically-much-faster solution shown below runs in time O(lg(lg n)), that is, in time proportional to the log of the number of bits in the input number. Note, the binary search as shown worked ok in tests, but perhaps can be improved.

*Edit:* The expression `-1<<L`

is a mask with its high bits set and its L low bits clear. For example, python displays 255 as the value of `(-1<<8)&255`

, and 256 as the value of `(-1<<8)&256`

. The program begins by doubling L (leaving more and more low bits clear) until L exceeds the number of bits in the number v; that is, until `(-1<<L)&v`

is zero. At each doubling of L, it can move R up. The program then uses binary search, repeatedly halving the L-R difference, to find L=R+1 such that `v&(-1<<L) == 0`

and `v&(-1<<R) > 0`

, to establish that v is L bits long.
Later, the program doubles the length of an alternating-bits mask k until it is at least L bits long. Then it shifts the mask by one bit if L is odd. (Instead of `if L & 1: k = k<<1`

it could say `k <<= L&1`

. Note, I interpreted “alternate bits” as beginning with the bit just below the MSB. To instead always toggle bits 0,2,4..., remove the `if L & 1: k = k<<1`

line.) Then it picks off the low L bits of k by &'ing with `(1<<L)-1`

, ie, with (2**L)-1. Note, the program's O(lg(lg n)) time bound depends on O(1) logical operations; but as L gets large (beyond a few hundred bits), `1<<L`

etc become O(lg n) operations.

```
def clearaltbits(v):
if not v:
return 0
L, R = 16, 0
# Find an upper bound on # bits
while (-1<<L) & v:
R, L = L, 2*L
# Binary search for top bit #
while not (-1<<L) & v:
m = (L+R)/2
if (-1<<m) & v:
R = m
else:
L = m
if L==R+1: break
print bin(v),'has',len(bin(v))-2,'bits.'
# Make big-enough alternate-bits mask
k, b = 0b0101010101010101, 16
while not (-1<<L) & k:
k = (k<<b)|k
b += b
if L & 1:
k = k<<1
k = k & ((1<<L)-1)
print bin(k^v),'fin'
clearaltbits(3**3)
clearaltbits(5**6)
clearaltbits(7**17)
clearaltbits(13**19)
```

The output from the four function calls is shown below.

```
0b11011 has 5 bits.
0b10001 fin
0b11110100001001 has 14 bits.
0b10100001011100 fin
0b110100111001001110000011001001100110111010000111 has 48 bits.
0b100001101100011011010110011100110011101111010010 fin
0b10011110100000000111000001101101000001011000100011000010010000111010101 has 71 bits.
0b11001011110101010010010100111000010100001101110110010111000101101111111 fin
```