# Counting, reversed bit pattern

I am trying to find an algorithm to count from 0 to 2n-1 but their bit pattern reversed. I care about only n LSB of a word. As you may have guessed I failed.

For n=3:

``````000 -> 0
100 -> 4
010 -> 2
110 -> 6
001 -> 1
101 -> 5
011 -> 3
111 -> 7
``````

You get the idea.

Answers in pseudo-code is great. Code fragments in any language are welcome, answers without bit operations are preferred.

Please don't just post a fragment without even a short explanation or a pointer to a source.

Edit: I forgot to add, I already have a naive implementation which just bit-reverses a count variable. In a sense, this method is not really counting.

• i can think of a really kludgey way to do it with strings and a horrible batch of if statements... hopefully someone else has something better, because i'd be embarrassed to post it :) Commented Nov 3, 2008 at 16:42
• is it a requirement that the bits start at "bit n", or could they start in the most significant bit ? Commented Nov 3, 2008 at 16:47
• I don't understand what you mean by "but their bit pattern reversed". Please could you explain the condition on the sequence? Commented Jan 19, 2013 at 16:53

Here's a solution from my answer to a different question that computes the next bit-reversed index without looping. It relies heavily on bit operations, though.

The key idea is that incrementing a number simply flips a sequence of least-significant bits, for example from `nnnn0111` to `nnnn1000`. So in order to compute the next bit-reversed index, you have to flip a sequence of most-significant bits. If your target platform has a CTZ ("count trailing zeros") instruction, this can be done efficiently.

Example in C using GCC's `__builtin_ctz`:

``````void iter_reversed(unsigned bits) {
unsigned n = 1 << bits;

for (unsigned i = 0, j = 0; i < n; i++) {
printf("%x\n", j);

// Compute a mask of LSBs.
unsigned mask = i ^ (i + 1);
// Align the mask to MSB of n.
}
}
``````

Without a CTZ instruction, you can also use integer division:

``````void iter_reversed(unsigned bits) {
unsigned n = 1 << bits;

for (unsigned i = 0, j = 0; i < n; i++) {
printf("%x\n", j);

// Find least significant zero bit.
unsigned bit = ~i & (i + 1);
// Using division to bit-reverse a single bit.
unsigned rev = (n / 2) / bit;
j ^= (n - 1) & ~(rev - 1);
}
}
``````

This is, I think easiest with bit operations, even though you said this wasn't preferred

Assuming 32 bit ints, here's a nifty chunk of code that can reverse all of the bits without doing it in 32 steps:

`````` unsigned int i;
i = (i & 0x55555555) <<  1 | (i & 0xaaaaaaaa) >>  1;
i = (i & 0x33333333) <<  2 | (i & 0xcccccccc) >>  2;
i = (i & 0x0f0f0f0f) <<  4 | (i & 0xf0f0f0f0) >>  4;
i = (i & 0x00ff00ff) <<  8 | (i & 0xff00ff00) >>  8;
i = (i & 0x0000ffff) << 16 | (i & 0xffff0000) >> 16;
i >>= (32 - n);
``````

Essentially this does an interleaved shuffle of all of the bits. Each time around half of the bits in the value are swapped with the other half.

The last line is necessary to realign the bits so that bin "n" is the most significant bit.

Shorter versions of this are possible if "n" is <= 16, or <= 8

• I didn't say this implementation was easiest, just that bit operations in general would be easiest :) This is just the quickest algorithm. ;) Commented Nov 3, 2008 at 17:02
• Note: the code above reverses the bits in a word, in case anyone doesn't recognise it. Commented Nov 3, 2008 at 17:22
• All in all, the naive solution beats the fancy ones again. Commented Nov 3, 2008 at 22:59
• I think it's an exaggeration to call this bit-swap "naive" :-) I reckon I'd back my solution against it for speed and code size on ARM, especially if n is known at compile time, but maybe not so much on x86. Commented Nov 4, 2008 at 11:30
• This might be the fastest algorithm to bit-reverse a single integer, but there are faster ways to iterate bit-reversed indices. See my answer. Commented Aug 6, 2017 at 12:20

At each step, find the leftmost 0 digit of your value. Set it, and clear all digits to the left of it. If you don't find a 0 digit, then you've overflowed: return 0, or stop, or crash, or whatever you want.

This is what happens on a normal binary increment (by which I mean it's the effect, not how it's implemented in hardware), but we're doing it on the left instead of the right.

Whether you do this in bit ops, strings, or whatever, is up to you. If you do it in bitops, then a clz (or call to an equivalent hibit-style function) on `~value` might be the most efficient way: __builtin_clz where available. But that's an implementation detail.

• Well, finding the leftmost 0 of value is equivalent to finding the leftmost 1 of (~value). Or in this case, actually (~value) & (1 << (bits-1)). clz is one way to do this, or find a hibit call in your language. Commented Nov 3, 2008 at 17:43

This solution was originally in binary and converted to conventional math as the requester specified.

It would make more sense as binary, at least the multiply by 2 and divide by 2 should be << 1 and >> 1 for speed, the additions and subtractions probably don't matter one way or the other.

If you pass in mask instead of nBits, and use bitshifting instead of multiplying or dividing, and change the tail recursion to a loop, this will probably be the most performant solution you'll find since every other call it will be nothing but a single add, it would only be as slow as Alnitak's solution once every 4, maybe even 8 calls.

``````int incrementBizarre(int initial, int nBits)
// in the 3 bit example, this should create 100
// This should only return true if the first (least significant) bit is not set
// if initial is 011 and mask is 100
//                3               4, bit is not set
// If it was not, just set it and bail.
return initial+ mask // 011 (3) + 100 (4) = 111 (7)
else
// it was set, are we at the most significant bit yet?
// mask 100 (4) / 2 = 010 (2), 001/2 = 0 indicating overflow
// No, we were't, so unset it (initial-mask) and increment the next bit
else
// Whoops we were at the most significant bit.  Error condition
throw new OverflowedMyBitsException()
``````

Wow, that turned out kinda cool. I didn't figure in the recursion until the last second there.

It feels wrong--like there are some operations that should not work, but they do because of the nature of what you are doing (like it feels like you should get into trouble when you are operating on a bit and some bits to the left are non-zero, but it turns out you can't ever be operating on a bit unless all the bits to the left are zero--which is a very strange condition, but true.

Example of flow to get from 110 to 001 (backwards 3 to backwards 4):

``````mask 100 (4), initial 110 (6); initial < mask=false; initial-mask = 010 (2), now try on the next bit
mask 010 (2), initial 010 (2); initial < mask=false; initial-mask = 000 (0), now inc the next bit
``````
``````void reverse(int nMaxVal, int nBits)
{
int thisVal, bit, out;

// Calculate for each value from 0 to nMaxVal.
for (thisVal=0; thisVal<=nMaxVal; ++thisVal)
{
out = 0;

// Shift each bit from thisVal into out, in reverse order.
for (bit=0; bit<nBits; ++bit)
out = (out<<1) + ((thisVal>>bit) & 1)

}
printf("%d -> %d\n", thisVal, out);
}
``````
• the problem with this answer is that as nBits increases so does the algorithm time (linearly). Commented Nov 3, 2008 at 16:57

Maybe increment from 0 to N (the "usual" way") and do ReverseBitOrder() for each iteration. You can find several implementations here (I like the LUT one the best). Should be really quick.

Here's an answer in Perl. You don't say what comes after the all ones pattern, so I just return zero. I took out the bitwise operations so that it should be easy to translate into another language.

``````sub reverse_increment {
my(\$n, \$bits) = @_;

my \$carry = 2**\$bits;
while(\$carry > 1) {
\$carry /= 2;
if(\$carry > \$n) {
return \$carry + \$n;
} else {
\$n -= \$carry;
}
}
return 0;
}
``````

Here's a solution which doesn't actually try to do any addition, but exploits the on/off pattern of the seqence (most sig bit alternates every time, next most sig bit alternates every other time, etc), adjust n as desired:

``````#define FLIP(x, i) do { (x) ^= (1 << (i)); } while(0)

int main() {
int n   = 3;
int max = (1 << n);
int x   = 0;

for(int i = 1; i <= max; ++i) {
std::cout << x << std::endl;
/* if n == 3, this next part is functionally equivalent to this:
*
* if((i % 1) == 0) FLIP(x, n - 1);
* if((i % 2) == 0) FLIP(x, n - 2);
* if((i % 4) == 0) FLIP(x, n - 3);
*/
for(int j = 0; j < n; ++j) {
if((i % (1 << j)) == 0) FLIP(x, n - (j + 1));
}
}
}
``````
• Random down vote on an answer that works 9 years after the posting? Sure, that makes sense :-P Commented Aug 16, 2017 at 13:32

How about adding 1 to the most significant bit, then carrying to the next (less significant) bit, if necessary. You could speed this up by operating on bytes:

1. Precompute a lookup table for counting in bit-reverse from 0 to 256 (00000000 -> 10000000, 10000000 -> 01000000, ..., 11111111 -> 00000000).
2. Set all bytes in your multi-byte number to zero.
3. Increment the most significant byte using the lookup table. If the byte is 0, increment the next byte using the lookup table. If the byte is 0, increment the next byte...
4. Go to step 3.

With n as your power of 2 and x the variable you want to step:

``````(defun inv-step (x n)       ; the following is a function declaration
"returns a bit-inverse step of x, bounded by 2^n"    ; documentation
(do ((i (expt 2 (- n 1))  ; loop, init of i
(/ i 2))          ; stepping of i
(s x))               ; init of s as x
((not (integerp i))   ; breaking condition
s)                   ; returned value if all bits are 1 (is 0 then)
(if (< s i)                         ; the loop's body: if s < i
(return-from inv-step (+ s i))  ;     -> add i to s and return the result
(decf s i))))                   ;     else: reduce s by i
``````

I commented it thoroughly as you may not be familiar with this syntax.

edit: here is the tail recursive version. It seems to be a little faster, provided that you have a compiler with tail call optimization.

``````(defun inv-step (x n)
(let ((i (expt 2 (- n 1))))
(cond ((= n 1)
(if (zerop x) 1 0))         ; this is really (logxor x 1)
((< x i)
(+ x i))
(t
(inv-step (- x i) (- n 1))))))
``````

When you reverse `0 to 2^n-1` but their bit pattern reversed, you pretty much cover the entire `0-2^n-1` sequence

``````Sum = 2^n * (2^n+1)/2
``````

`O(1)` operation. No need to do bit reversals

Edit: Of course original poster's question was about to do increment by (reversed) one, which makes things more simple than adding two random values. So nwellnhof's answer contains the algorithm already.

### Summing two bit-reversal values

Here is one solution in php:

``````function RevSum (\$a,\$b) {

// loop until our adder, \$b, is zero
while (\$b) {

// get carry (aka overflow) bit for every bit-location by AND-operation
// 0 + 0 --> 00   no overflow, carry is "0"
// 0 + 1 --> 01   no overflow, carry is "0"
// 1 + 0 --> 01   no overflow, carry is "0"
// 1 + 1 --> 10   overflow! carry is "1"

\$c = \$a & \$b;

// do 1-bit addition for every bit location at once by XOR-operation
// 0 + 0 --> 00   result = 0
// 0 + 1 --> 01   result = 1
// 1 + 0 --> 01   result = 1
// 1 + 1 --> 10   result = 0 (ignored that "1", already taken care above)

\$a ^= \$b;

// now: shift carry bits to the next bit-locations to be added to \$a in
// next iteration.
// PHP_INT_MAX here is used to ensure that the most-significant bit of the
// \$b will be cleared after shifting. see link in the side note below.

\$b = (\$c >> 1) & PHP_INT_MAX;

}

return \$a;
}
``````

Side note: See this question about shifting negative values.

And as for test; start from zero and increment value by 8-bit reversed one (10000000):

``````\$value = 0;
\$add = 0x80;    // 10000000 <-- "one" as bit reversed

for (\$count = 20; \$count--;) {      // loop 20 times
printf("%08b\n", \$value);       // show value as 8-bit binary
}
``````

... will output:

`````` 00000000
10000000
01000000
11000000
00100000
10100000
01100000
11100000
00010000
10010000
01010000
11010000
00110000
10110000
01110000
11110000
00001000
10001000
01001000
11001000
``````

Let assume number 1110101 and our task is to find next one.

1) Find zero on highest position and mark position as index.

11101010 (4th position, so index = 4)

2) Set to zero all bits on position higher than index.

00001010

3) Change founded zero from step 1) to '1'

00011010

That's it. This is by far the fastest algorithm since most of cpu's has instructions to achieve this very efficiently. Here is a C++ implementation which increment 64bit number in reversed patern.

``````#include <intrin.h>
unsigned __int64 reversed_increment(unsigned __int64 number)
{
unsigned long index, result;
_BitScanReverse64(&index, ~number); // returns index of the highest '1' on bit-reverse number (trick to find the highest '0')
result = _bzhi_u64(number, index); // set to '0' all bits at number higher than index position
result |= (unsigned __int64) 1 << index; // changes to '1' bit on index position
return result;
}
``````

Its not hit your requirements to have "no bits" operations, however i fear there is now way how to achieve something similar without them.