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My goal is as the following,

Generate successive values, such that each new one was never generated before, until all possible values are generated. At this point, the counter start the same sequence again. The main point here is that, all possible values are generated without repetition (until the period is exhausted). It does not matter if the sequence is simple 0, 1, 2, 3,..., or in other order.

For example, if the range can be represented simply by an unsigned, then

void increment (unsigned &n) {++n;}

is enough. However, the integer range is larger than 64-bits. For example, in one place, I need to generated 256-bits sequence. A simple implementation is like the following, just to illustrate what I am trying to do,

typedef std::array<uint64_t, 4> ctr_type;
static constexpr uint64_t max = ~((uint64_t) 0);
void increment (ctr_type &ctr)
    if (ctr[0] < max) {++ctr[0]; return;}
    if (ctr[1] < max) {++ctr[1]; return;}
    if (ctr[2] < max) {++ctr[2]; return;}
    if (ctr[3] < max) {++ctr[3]; return;}
    ctr[0] = ctr[1] = ctr[2] = ctr[3] = 0;

So if ctr start with all zeros, then first ctr[0] is increased one by one until it reach max, and then ctr[1], and so on. If all 256-bits are set, then we reset it to all zero, and start again.

The problem is that, such implementation is surprisingly slow. My current improved version is sort of equivalent to the following,

void increment (ctr_type &ctr)
    std::size_t k = (!(~ctr[0])) + (!(~ctr[1])) + (!(~ctr[2])) + (!(~ctr[3]))
    if (k < 4)
        memset(ctr.data(), 0, 32);


If the counter is only manipulated with the above increment function, and always start with zero, then ctr[k] == 0 if ctr[k - 1] == 0. And thus the value k will be the index of the first element that is less than the maximum.

I expected the first to be faster, since branch mis-prediction shall happen only once in every 2^64 iterations. The second, though mis-predication only happen every 2^256 iterations, it shall not make a difference. And apart from the branching, it needs four bitwise negation, four boolean negation, and three addition. Which might cost much more than the first.

However, both clang, gcc, or intel icpc generate binaries that the second was much faster.

My main question is that does anyone know if there any faster way to implement such a counter? It does not matter if the counter start by increasing the first integers or if it is implemented as an array of integers at all, as long as the algorithm generate all 2^256 combinations of 256-bits.

What makes things more complicated, I also need non uniform increment. For example, each time the counter is incremented by K where K > 1, but almost always remain a constant. My current implementation is similar to the above.

To provide some more context, one place I am using the counters is using them as input to AES-NI aesenc instructions. So distinct 128-bits integer (loaded into __m128i), after going through 10 (or 12 or 14, depending on the key size) rounds of the instructions, a distinct 128-bits integer is generated. If I generate one __m128i integer at once, then the cost of increment matters little. However, since aesenc has quite a bit latency, I generate integers by blocks. For example, I might have 4 blocks, ctr_type block[4], initialized equivalent to the following,

block[0]; // initialized to zero
block[1] = block[0]; increment(block[1]);
block[2] = block[1]; increment(block[2]);
block[3] = block[2]; increment(block[3]);

And each time I need new output, I increment each block[i] by 4, and generate 4 __m128i output at once. By interleaving instructions, overall I was able to increase the throughput, and reduce the cycles per bytes of output (cpB) from 6 to 0.9 when using 2 64-bits integers as the counter and 8 blocks. However, if instead, use 4 32-bits integers as counter, the throughput, measured as bytes per sec is reduced to half. I know for a fact that on x86-64, 64-bits integers could be faster than 32-bits in some situations. But I did not expect such simple increment operation makes such a big difference. I have carefully benchmarked the application, and the increment is indeed the one slow down the program. Since the loading into __m128i and store the __m128i output into usable 32-bits or 64-bits integers are done through aligned pointers, the only difference between the 32-bits and 64-bits version is how the counter is incremented. I expected that the AES-NI expected, after loading the integers into __m128i, shall dominate the performance. But when using 4 or 8 blocks, it was clearly not the case.

So to summary, my main question is that, if anyone know a way to improve the above counter implementation.

share|improve this question
How quickly do you expect a 64 bit counter to overflow? By my math, it would take ~300 years if you could update it at 2GHz. A 256 bit counter is mind bogglingly huge. –  pat Mar 13 '14 at 7:19
Are you attempting a brute force attack on AES256??? –  pat Mar 13 '14 at 7:22
why did someone downvote this question. –  arunmoezhi Mar 13 '14 at 7:58
Is it really 2^256 combinations you want, or 2^66, which is what you have written? Anyway, during anybodys lifetime, an early exit dominates the performance. –  Aki Suihkonen Mar 13 '14 at 12:00
The speed of light isn't fast enough to let you brute force AES-256. E=MC^2 just isn't enough energy even when you throw in the entire mass-energy of the observable universe. (dark matter included) –  Mysticial Mar 13 '14 at 17:36

3 Answers 3

It's not only slow, but impossible. The total energy of universe is insufficient for 2^256 bit changes. And that would require gray counter.

Next thing before optimization is to fix the original implementation

void increment (ctr_type &ctr)
    if (++ctr[0] != 0) return;
    if (++ctr[1] != 0) return;
    if (++ctr[2] != 0) return;

If each ctr[i] was not allowed to overflow to zero, the period would be just 4*(2^32), as in 0-9, 19,29,39,49,...99, 199,299,... and 1999,2999,3999,..., 9999.

As a reply to the comment -- it takes 2^64 iterations to have the first overflow. Being generous, upto 2^32 iterations could take place in a second, meaning that the program should run 2^32 seconds to have the first carry out. That's about 136 years.


If the original implementation with 2^66 states is really what is wanted, then I'd suggest to change the interface and the functionality to something like:

  (*counter) += 1;
  while (*counter == 0)
     counter++;  // Move to next word
     if (counter > tail_of_array) {
        counter = head_of_array;
        memset(counter,0, 16);

The point being, that the overflow is still very infrequent. Almost always there's just one word to be incremented.

share|improve this answer
Traditionally one uses an add-with-carry instruction to efficiently implement multi-precision add, but this is sadly not available in C or C++ without inline asm. –  Cory Nelson Mar 13 '14 at 6:54

If you're using GCC

unsigned __int128 H, L;
if (L == 0) H++;

On systems where __int128 not available

unsigned long long c[4];
if (c[0] == 0)
    if (c[1] == 0)
        if (c[2] == 0)

Using inline assembly it's much easier to do this using the carry flag. Unfortunately most high level languages don't have a mean to access it. Anyway this is rather waste time since the total number of particles in the universe is only about 1080 and you cannot even count up the 64-bit counter in your life

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@AkiSuihkonen I edited the code –  Lưu Vĩnh Phúc Mar 13 '14 at 10:59

Neither of your counter versions increment correctly. Instead of counting up to UINT256_MAX, you are actually just counting up to UINT64_MAX 4 times and then starting back at 0 again. This is apparent from the fact that you do not bother to clear any of the indices that has reached the max value until all of them have reached the max value. If you are measuring performance based on how often the counter reaches all bits 0, then this is why. Thus your algorithms do not generate all combinations of 256 bits, which is a stated requirement.

share|improve this answer
No, it won't. The first carry out may not happen for hundreds of years. –  Aki Suihkonen Mar 13 '14 at 9:25

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