A histogram needs a map B(x) that takes a data value x to a bucket B where a count is maintained. If the counts are stored (as is usual) in an array, then B(x) is the index of the count in the array. When the buckets are of equal size, B(x) is particularly simple: B(x) = floor((x - A) / N) where A is the minimum possible value of x and N is the bucket size (this assumes the counts are in an array with 0-based indices).

If the buckets are not of equal size, the B(x) is more complicated. You can always store the bucket boundaries in an array (call it b)

```
b[] = { 0, 10, 25, 50, 100, 250, ... }
```

This encodes the buckets [0..10), [10..25), etc. Now you can use binary search to compute

```
B(x) = index in b of greatest value not greater than or equal to x
```

If there is a precise logarithmic growth of buckets, such as [1, 10), [10, 100), [100, 1000), [1000, 10000), then you can use a logarithm-based map:

```
B(x) = floor( log_10(x) )
```

**Addition**

If the histogram must be accumulated on-line; that is, you don't know anything about the data until they arrive, then your algorithm must be able to reorganize B(x) on the fly.

If you allow B(x) to be any new map, then reorganization means reprocessing all data received so far so they can be re-assigned to the new buckets. This requires O(N) time for N data received each time the histogram is reorganized. Many applications can't handle this expense.

If you allow *only adding new buckets*, then life gets considerably easier. For example, with equal-sized buckets and B(x) = floor((x - A) / N) as discussed above, the problem is that you don't know A in advance. The simplest technique is to set A equal to the first data value and maintain *two* arrays of buckets. The first counts data with values greater than or equal to A using B(x) as given above. The second counts data with values less than A using B'(x) = floor((A - x) / N). Obviously you guess at an initial size and then grow these arrays dynamically as needed to handle the absolute maximum values seen so far.

The same technique works fine for logarithmically sized buckets. Only you'll use something like B(x) = floor(log(x / A) / N) and B'(x) = floor(-log(x / A) / N).

One other kind of reorganization is easy: those restricted to adding *and/or merging* buckets. This requires traversing the old bucket array and adding bucket counts to obtain new merged ones. In the linear case, this equivalent to increasing N by an integer factor: 2*N is merging two buckets into one, etc. The log case is similar.

This kind of reorganization works well if you choose a ridiculously small bucket size and let the buckets grow only enough to keep the histogram array sizes under some chosen threshold. This doesn't cause much performance penalty. Buckets must get at least 2 time bigger for each merge, so growth by a factor of F requires only log_2(F) mergings. For example, if you expect the data to be around 1 and choose an initial linear bucket size of 1/1,000,000, it will still take only 20 twofold merges to make them of unit size.

To make this more concrete, here is pseudocode for the linear bucket case:

```
Let hi = [0] ; Counts for data x >= A
Let lo = [0] ; Counts for data x < A
Let N = < smallest imaginable desired bucket size >
Let N' = N
Let A = x[0] ; Put first received data value in A
hi[0] = 1 ; Count the first data value
for each successive data value x
if x >= A
p = floor((x - A) / N)
; Grow if necessary.
while hi.last_index < p and a has not reached pre-determined max size
grow hi by a factor of 2 and set new elements zero
; Merge if necessary
while hi.last_index < p
; Merge 2 buckets into 1
j = 0
for i = 0 .. lo.last_index / 2
hi[i] = hi[j] + hi[j + 1]
j = j + 2
; Buckets are now half as big
N = 2 * N
p = floor((x - A) / N)
; Second half of hi is now available for higher values
set second half of hi zero
; Count the data value
increment hi[p]
else
p = floor((A - x) / N')
; Grow if necessary.
while lo.last_index < p and a has not reached pre-determined max size
grow lo by a factor of 2 and set new elements zero
; Merge if necessary
while lo.last_index < p
; Merge 2 buckets into 1
j = 0
for i = 0 .. lo.last_index / 2
lo[i] = lo[j] + lo[j + 1]
j = j + 2
; Buckets are now half as big
N' = 2 * N'
p = floor((A - x) / N')
; Second half of lo is now available for smaller values
set second half of lo zero
increment lo[p]
end
```

This lets the buckets in the two arrays grow to different sizes. If this is not what you want, just merge lo and hi together each time either is required to be.

I have used this algorithm with good success to instrument a general purpose factory simulator.