ma.
indices
Return an array representing the indices of a grid.
Compute an array where the subarrays contain index values 0, 1, … varying only along the corresponding axis.
The shape of the grid.
Data type of the result.
Return a sparse representation of the grid instead of a dense representation. Default is False.
New in version 1.17.
Returns one array of grid indices, grid.shape = (len(dimensions),) + tuple(dimensions).
grid.shape = (len(dimensions),) + tuple(dimensions)
Returns a tuple of arrays, with grid[i].shape = (1, ..., 1, dimensions[i], 1, ..., 1) with dimensions[i] in the ith place
grid[i].shape = (1, ..., 1, dimensions[i], 1, ..., 1)
See also
mgrid
ogrid
meshgrid
Notes
The output shape in the dense case is obtained by prepending the number of dimensions in front of the tuple of dimensions, i.e. if dimensions is a tuple (r0, ..., rN-1) of length N, the output shape is (N, r0, ..., rN-1).
(r0, ..., rN-1)
N
(N, r0, ..., rN-1)
The subarrays grid[k] contains the N-D array of indices along the k-th axis. Explicitly:
grid[k]
k-th
grid[k, i0, i1, ..., iN-1] = ik
Examples
>>> grid = np.indices((2, 3)) >>> grid.shape (2, 2, 3) >>> grid[0] # row indices array([[0, 0, 0], [1, 1, 1]]) >>> grid[1] # column indices array([[0, 1, 2], [0, 1, 2]])
The indices can be used as an index into an array.
>>> x = np.arange(20).reshape(5, 4) >>> row, col = np.indices((2, 3)) >>> x[row, col] array([[0, 1, 2], [4, 5, 6]])
Note that it would be more straightforward in the above example to extract the required elements directly with x[:2, :3].
x[:2, :3]
If sparse is set to true, the grid will be returned in a sparse representation.
>>> i, j = np.indices((2, 3), sparse=True) >>> i.shape (2, 1) >>> j.shape (1, 3) >>> i # row indices array([[0], [1]]) >>> j # column indices array([[0, 1, 2]])