# scipy csr_matrix: understand indptr

Every once in a while, I get to manipulate a `csr_matrix` but I always forget how the parameters `indices` and `indptr` work together to build a sparse matrix.

I am looking for a clear and intuitive explanation on how the `indptr` interacts with both the `data` and `indices` parameters when defining a sparse matrix using the notation `csr_matrix((data, indices, indptr), [shape=(M, N)])`.

I can see from the scipy documentation that the `data` parameter contains all the non-zero data, and the `indices` parameter contains the columns associated to that data (as such, `indices` is equal to `col` in the example given in the documentation). But how can we explain in clear terms the `indptr` parameter?

• It may help to look at the `lil` equivalent. The successive slices `M.indices[indptr[i]:indptr[i+1]]` as described by @Tanguy correspond to the lists in the `lil` `rows` array. – hpaulj Sep 12 '18 at 16:47

Maybe this explanation can help understand the concept:

• `data` is an array containing all the non zero elements of the sparse matrix.
• `indices` is an array mapping each element in `data` to its column in the sparse matrix.
• `indptr` then maps the elements of `data` and `indices` to the rows of the sparse matrix. This is done with the following reasoning:

1. If the sparse matrix has M rows, `indptr` is an array containing M+1 elements
2. for row i, `[indptr[i]:indptr[i+1]]` returns the indices of elements to take from `data` and `indices` corresponding to row i. So suppose `indptr[i]=k` and `indptr[i+1]=l`, the data corresponding to row i would be `data[k:l]` at columns `indices[k:l]`. This is the tricky part, and I hope the following example helps understanding it.

EDIT : I replaced the numbers in `data` by letters to avoid confusion in the following example. Note: the values in `indptr` are necessarily increasing, because the next cell in `indptr` (the next row) is referring to the next values in `data` and `indices` corresponding to that row.

• Thank you for trying to make it clear, but still not.. can you give an example of M and then do the point 2 from a row, explaining for what values in `indices` and `data` it comes? I tried to follow on an example and I didn't get it. – SarahData Sep 14 '18 at 9:30
• Thank you! This post is helpful! It reminds me of my computational mathematics textbook, it has explained this. But why scipy does offer an official doc for the sparse matrix format in scipy.sparse? – gph Jan 16 at 5:24
• Did you mean "why does scipy does not offer an official doc ..." ? :) – Tanguy Jan 16 at 9:43
• Took me a while to understand this (but much shorter than if I had to research it all my self), but I get it now. The part that tripped me up is the the consecutive values for data. Kept thinking the values represented the columns. If they were random values, I think it would help the reader come to an understanding faster. Great though. Thanks. – spacedustpi Feb 6 at 21:54
• @ivankeller: updating your question to the edited example / picture: "Should not the last element of indptr rather be 10 instead of 11?" --> no because the last element in a range is not selected when subsetting data structures in python (e.g.`data[l]` is not contained in `data[k:l]`). – Tanguy Aug 20 at 14:31

Sure, the elements inside indptr are in ascending order. But how to explain the indptr behavior? In short words, until the element inside indptr is the same or doesn't increase, you can skip row index of the sparse matrix.

The following example illustrates the above interpretation of indptr elements:

Example 1) imagine this matrix:

``````array([[0, 1, 0],
[8, 0, 0],
[0, 0, 0],
[0, 0, 0],
[0, 0, 7]])

mat1 = csr_matrix(([1,8,7], [1,0,2], [0,1,2,2,2,3]), shape=(5,3))
mat1.indptr
# array([0, 1, 2, 2, 2, 3], dtype=int32)
mat1.todense()  # to get the corresponding sparse matrix
``````

Example 2) Array to CSR_matrix (the case when the sparse matrix already exists):

``````arr = np.array([[0, 0, 0],
[8, 0, 0],
[0, 5, 4],
[0, 0, 0],
[0, 0, 7]])

mat2 = csr_matrix(arr))
mat2.indptr
# array([0, 0, 1, 3, 3, 4], dtype=int32)
mat2.indices
# array([0, 1, 2, 2], dtype=int32)
mat.data
# array([8, 5, 4, 7], dtype=int32)
``````