I'd like to find a fast way to update a sum of squared residuals, when I know that only a small fraction of the terms are changing. Let me describe the problem in more detail.

I have N data points from noisy step-function data.

N = 100000
realStepList = [200, 500, 900]

x = np.zeros(N)
for realStep in realStepList:
    x[realStep:] += 1
x+=np.random.randn(len(x))*0.1 #Add noise

I'd like to calculate the sum of squared residuals for this data and an arbitrary list of step locations. Here is how I do this.

a = [0, 250, 550, N] 
def Q(x, a):
    q = np.sum([np.sum((x[ai:af] - i)**2) for i, (ai,af) in enumerate(zip(a[:-1],a[1:]))])
    return q

a is my list of potential steps. It's easier to use a list that always has 0 as the first element and N as the last element.

This is relatively slow, since it is a sum over N squares. However, I realized that if I change a by a relatively small amount, most of these N terms will remain unchanged, which means I don't have to compute them again.

So let's say I have already computed Q(x,a) as above. I now have another list

b = [aa + dd for aa, dd in zip(a, d)]

where d is the difference between the two lists. Rather than calculating Q(x,b) as above (another sum over N elements), I want to find

deltaQ(x, a, d) such that

Q(x, b) = Q(x,a) + deltaQ(x, a, d)

I have written such a function, but it is slow and sloppy. In fact, it is slower than Q!

def deltaQ(x, a, d):
    z = np.zeros(len(x))
    J = np.zeros(len(x))
    s = 0
    for j, [dd, aa] in enumerate(zip(d, a[1:-1])):
            if dd >= 0:
                    z[aa:aa+dd] += 1
                    s += sum(x[aa:aa+dd])
            if dd < 0:
                    z[aa+dd:aa] += -1
                    s += -sum(x[aa+dd:aa])
            J[aa:] += 1
    dq = 2*s - sum((J**2 - (J-z)**2))
    return dq

The idea is to identify all the points in x which will be affected. For example, if the original list was a = [0, 5, 10] and b = [0, 7, 10], then only the terms corresponding to x[5:7] will change in the sum. I keep track of this with the list z. I then calculate the change based on this.

I don't think I'm the first person in the world to have this problem. So my question is:

Is there a fast way to calculate the difference in the sum of squared residuals, since this will often be a sum many fewer elements than recalculating the new sum from scratch?

  • 2
    Minor note, b = [aa + dd for zip(a, d)] is not valid syntax.
    – dROOOze
    Mar 19, 2018 at 16:59
  • Does the shape of a stay the same when making those small changes? In other words, do only the values change or also the number of steps? Also, can you give an example of d?
    – Graipher
    Mar 19, 2018 at 17:24
  • @Graipher Ultimately I'd like to have the shape change, but I'm interested in answers were it does not change, also. In the example I gave, d = [2], since there is only one step, and it changes from 5 -> 7
    – F. Bardamu
    Mar 19, 2018 at 18:22
  • Changed the synthax, @droooze. Thanks for the heads up.
    – F. Bardamu
    Mar 19, 2018 at 18:24
  • Took me a couple of reads to realize that you weren't asking to find the true step locations. If you are, I can help you with that too :) Mar 19, 2018 at 18:35

1 Answer 1


First of all, I was able to run Q with the original code, only modifying N, to get the following timings on a fairly standard issue laptop (nothing too fancy):

N = 1e6: 0.00236s per loop
N = 1e7: 0.0260s per loop
N = 1e8: 0.251 per loop

The process went into swap at N = 1e9, but I would find a timing of 2.5 seconds quite acceptable for that size, assuming you had enough RAM available.

That being said, I was able to get a 10% speedup by changing the inner np.sum to np.ndarray.sum on the result of the call to np.power:

def Q1(x, a):
    return sum(((x[ai:af] - i)**2).sum() for i, (ai, af) in enumerate(zip(a[:-1], a[1:])))

Now here is a version that is three times slower:

def offset(x, a):
    d = np.zeros(x.shape, dtype=np.int)
    d[a[1:-1]] = 1
    # Add out=d to make this run 4 times slower
    return np.cumsum(d)

def Q2(x, a):
    return np.sum((x - offset(x, a))**2)

Why does this help? Well, notice what offset does: it readjusts x to the baseline that you chose. In the long run this does two things. First, you get a much more vectorized solution than the one you are currently proposing. Secondly, it allows you to rewrite your delta function in terms of the different b arrays that you chose instead of having to compute d, which may not even be possible if len(a) != len(b).

The delta is (x - i)2 - (x - i)2. If you expand out all the mess, you get (j - i)(j + i - 2x). j and i being the values of the steps, returned by offset. Not only does this simplify the computation greatly, but j - i is the mask at which you need to compute the deltas:

def deltaQ1(x, a, b):
    i = offset(x, a)
    j = offset(x, b)
    d = j - i
    mask = d.astype(np.bool)
    return (d[mask] * (j[mask] + i[mask] - 2 * x[mask])).sum()

This function runs more than 10 to 15 times faster than your original implementation (but keep in mind that it takes a and b instead of a and d as inputs). Calling Q1(x, b) - Q1(x, a) is still twice as fast though. The new function also creates a bunch of temporary arrays, but these can be easily reduced in quantity.


Here are some sample timings on my computer, in addition to the ones shown above (using the data provided, and a = [0, 250, 550, N], b = [0, 180, 565, N] and therefore d = [0, -70, 15, 0], where relevant:

Raw residuals:

Q:  147µs per loop
Q1: 135µs per loop <-- Use this one!
Q2: 453µs per loop

Delta of residuals:

deltaQ: 8363µs per loop
deltaQ1: 656µs per loop
Q(x, b) - Q(x, a): 297µs per loop
Q1(x, b) - Q1(x, a): 275µs per loop  <-- Best solution?

Final note: I have the distinct impression that your original implementation of the delta function is not correct. It does not agree with the result of Q(x, b) - Q(x, a), but deltaQ1(x, a, b) does.


Please don't optimize prematurely. If you do it right, it is of course possible to write a specialized C function to hold i - j and i + j in memory for you which will work much faster, but I doubt you will get much mileage out of a vectorized pipeline. Part of the reason is that you will end up spending a lot of time figuring out how a complex set of indices intermeshes instead of just adding numbers together.

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