This question is a slight extension of the one answered here. I am working on re-implementing a version of the histogram approximation found in Section 2.1 of this paper, and I would like to get all my ducks in a row before beginning this process again. Last time, I used boost::multi_index, but performance wasn't the greatest, and I would like to avoid the logarithmic in number of buckets insert/find complexity of a std::set. Because of the number of histograms I'm using (one per feature per class per leaf node of a random tree in a random forest), the computational complexity must be as close to constant as possible.

A standard technique used to implement a histogram involves mapping the input real value to a bin number. To accomplish this, one method is to:

  1. initialize a standard C array of size N, where N = number of bins; and
  2. multiply the input value (real number) by some factor and floor the result to get its index in the C array.

This works well for histograms with uniform bin size, and is quite efficient. However, Section 2.1 of the above-linked paper provides a histogram algorithm without uniform bin sizes.

Another issue is that simply multiplying the input real value by a factor and using the resulting product as an index fails with negative numbers. To resolve this, I considered identifying a '0' bin somewhere in the array. This bin would be centered at 0.0; the bins above/below it could be calculated using the same multiply-and-floor method just explained, with the slight modification that the floored product be added to two or subtracted from two as necessary.

This then raises the question of merges: the algorithm in the paper merges the two closest bins, as measured from center to center. In practice, this creates a 'jagged' histogram approximation, because some bins would have extremely large counts and others would not. Of course, this is due to non-uniform-sized bins, and doesn't result in any loss of precision. A loss of precision does, however, occur if we try to normalize the non-uniform-sized bins to make the uniform. This is because of the assumption that m/2 samples fall to the left and right of the bin center, where m = bin count. We could model each bin as a gaussian, but this will still result in a loss of precision (albeit minimal)

So that's where I'm stuck right now, leading to this major question: What's the best way to implement a histogram accepting streaming data and storing each sample in bins of uniform size?

1 Answer 1


Keep four variables.

int N;  // assume for simplicity that N is even
int count[N];
double lower_bound;
double bin_size;

When a new sample x arrives, compute double i = floor(x - lower_bound) / bin_size. If i >= 0 && i < N, then increment count[i]. If i >= N, then repeatedly double bin_size until x - lower_bound < N * bin_size. On every doubling, adjust the counts (optimize this by exploiting sparsity for multiple doublings).

for (int j = 0; j < N / 2; j++) count[j] = count[2 * j] + count[2 * j + 1];
for (int j = N / 2; j < N; j++) count[j] = 0;

The case i < 0 is trickier, since we need to decrease lower_bound as well as increase bin_size (again, optimize for sparsity or adjust the counts in one step).

while (lower_bound > x) {
    lower_bound -= N * bin_size;
    bin_size += bin_size;
    for (int j = N - 1; j > N / 2 - 1; j--) count[j] = count[2 * j - N] + count[2 * j - N + 1];
    for (int j = 0; j < N / 2; j++) count[j] = 0;

The exceptional cases are expensive but happen only a logarithmic number of times in the range of your data over the initial bin size.

If you implement this in floating-point, be mindful that floating-point numbers are not real numbers and that statements like lower_bound -= N * bin_size may misbehave (in this case, if N * bin_size is much smaller than lower_bound). I recommend that bin_size be a power of the radix (usually two) at all times.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.