Grouping by a single dimension works fine for xarray DataArrays:

d = xr.DataArray([1, 2, 3], coords={'a': ['x', 'x', 'y']}, dims=['a'])
d.groupby('a').mean())  # -> DataArray (a: 2) array([1.5, 3. ])`

However, this is only supported for a single dimension, grouping by multiple dimensions does thus not work:

d = DataAssembly([[1, 2, 3], [4, 5, 6]],
                 coords={'a': ('multi_dim', ['a', 'b']), 'c': ('multi_dim', ['c', 'c']), 'b': ['x', 'y', 'z']},
                 dims=['multi_dim', 'b'])
d.groupby(['a', 'b'])  # TypeError: `group` must be an xarray.DataArray or the name of an xarray variable or dimension

I only have an inefficient solution which does the for loops manually:

a, b = np.unique(d['a'].values), np.unique(d['b'].values)
result = xr.DataArray(np.zeros([len(a), len(b)]), coords={'a': a, 'b': b}, dims=['a', 'b'])
for a, b in itertools.product(a, b):
    cells = d.sel(a=a, b=b)
    merge = cells.mean()
    result.loc[{'a': a, 'b': b}] = merge
# result = DataArray (a: 2, b: 2)> array([[2., 3.], [5., 6.]])
#            Coordinates:
#              * a        (a) <U1 'x' 'y'
#              * b        (b) int64 0 1

This is however horribly slow for larger arrays. Is there a more efficient / straight-forward work-around?

2 Answers 2


I built a manual solution. To make it efficient, I discard all of xarray and rebuild indices and values by hand. Any change to use more xarray (e.g. using sel, re-packaging cells into a DataArray; also see https://github.com/pydata/xarray/issues/2452) led to serious losses in speed.

import itertools
from collections import defaultdict

import numpy as np
import xarray as xr
from xarray import DataArray

class DataAssembly(DataArray):
    def multi_dim_groupby(self, groups, apply):
        # align
        groups = sorted(groups, key=lambda group: self.dims.index(self[group].dims[0]))
        # build indices
        groups = {group: np.unique(self[group]) for group in groups}
        group_dims = {self[group].dims: group for group in groups}
        indices = defaultdict(lambda: defaultdict(list))
        result_indices = defaultdict(dict)
        for group in groups:
            for index, value in enumerate(self[group].values):
                if value not in result_indices[group]:  # if captured once, it will be "grouped away"
                    index = max(result_indices[group].values()) + 1 if len(result_indices[group]) > 0 else 0
                    result_indices[group][value] = index

        coords = {coord: (dims, value) for coord, dims, value in walk_coords(self)}

        def simplify(value):
            return value.item() if value.size == 1 else value

        def indexify(dict_indices):
            return [(i,) if isinstance(i, int) else tuple(i) for i in dict_indices.values()]

        # group and apply
        # making this a DataArray right away and then inserting through .loc would slow things down
        result = np.zeros([len(indices) for indices in result_indices.values()])
        result_coords = {coord: (dims, [None] * len(result_indices[group_dims[dims]]))
                         for coord, (dims, value) in coords.items()}
        for values in itertools.product(*groups.values()):
            group_values = dict(zip(groups.keys(), values))
            self_indices = {group: indices[group][value] for group, value in group_values.items()}
            values_indices = indexify(self_indices)
            cells = self.values[values_indices]  # using DataArray would slow things down. thus we pass coords as kwargs
            cells = simplify(cells)
            cell_coords = {coord: (dims, value[self_indices[group_dims[dims]]])
                           for coord, (dims, value) in coords.items()}
            cell_coords = {coord: (dims, simplify(np.unique(value))) for coord, (dims, value) in cell_coords.items()}

            # ignore dims when passing to function
            passed_coords = {coord: value for coord, (dims, value) in cell_coords.items()}
            merge = apply(cells, **passed_coords)
            result_idx = {group: result_indices[group][value] for group, value in group_values.items()}
            result[indexify(result_idx)] = merge
            for coord, (dims, value) in cell_coords.items():
                if isinstance(value, np.ndarray):  # multiple values for coord -> ignore
                    if coord in result_coords:  # delete from result coords if not yet deleted
                        del result_coords[coord]
                assert dims == result_coords[coord][0]
                coord_index = result_idx[group_dims[dims]]
                result_coords[coord][1][coord_index] = value

        # re-package
        result = type(self)(result, coords=result_coords, dims=list(itertools.chain(*group_dims.keys())))
        return result

def walk_coords(assembly):
    walks through coords and all levels, just like the `__repr__` function, yielding `(name, dims, values)`.
    coords = {}

    for name, values in assembly.coords.items():
        # partly borrowed from xarray.core.formatting#summarize_coord
        is_index = name in assembly.dims
        if is_index and values.variable.level_names:
            for level in values.variable.level_names:
                level_values = assembly.coords[level]
                yield level, level_values.dims, level_values.values
            yield name, values.dims, values.values
    return coords

The method multi_dim_groupby performs grouping and apply in one step. The passed apply method can accept group coords via parameters named after the coords (or ignore the coords by putting **_ in the function header).

It's not particularly pretty and does not cover all possible cases but at least covers the following test cases:

import DataAssembly

class TestMultiDimGroupby:
    def test_unique_values(self):
        d = DataAssembly([[1, 2, 3], [4, 5, 6], [7, 8, 9], [10, 11, 12]],
                         coords={'a': ['a', 'b', 'c', 'd'],
                                 'b': ['x', 'y', 'z']},
                         dims=['a', 'b'])
        g = d.multi_dim_groupby(['a', 'b'], lambda x, **_: x)
        assert g.equals(d)

    def test_nonunique_singledim(self):
        d = DataAssembly([[1, 2, 3], [4, 5, 6], [7, 8, 9], [10, 11, 12]],
                         coords={'a': ['a', 'a', 'b', 'b'],
                                 'b': ['x', 'y', 'z']},
                         dims=['a', 'b'])
        g = d.multi_dim_groupby(['a', 'b'], lambda x, **_: x.mean())
        assert g.equals(DataAssembly([[2.5, 3.5, 4.5], [8.5, 9.5, 10.5]],
                                     coords={'a': ['a', 'b'], 'b': ['x', 'y', 'z']},
                                     dims=['a', 'b']))

    def test_nonunique_adjacentcoord(self):
        d = DataAssembly([[1, 2, 3], [4, 5, 6], [7, 8, 9], [10, 11, 12]],
                         coords={'a': ('adim', ['a', 'a', 'b', 'b']),
                                 'aa': ('adim', ['a', 'b', 'a', 'b']),
                                 'b': ['x', 'y', 'z']},
                         dims=['adim', 'b'])
        g = d.multi_dim_groupby(['a', 'b'], lambda x, **_: x.mean())
        assert g.equals(DataAssembly([[2.5, 3.5, 4.5], [8.5, 9.5, 10.5]],
                                     coords={'adim': ['a', 'b'], 'b': ['x', 'y', 'z']},
                                     dims=['adim', 'b'])), \
            "adjacent coord aa should be discarded due to non-mappability"

    def test_unique_values_swappeddims(self):
        d = DataAssembly([[1, 2, 3], [4, 5, 6], [7, 8, 9], [10, 11, 12]],
                         coords={'a': ['a', 'b', 'c', 'd'],
                                 'b': ['x', 'y', 'z']},
                         dims=['a', 'b'])
        g = d.multi_dim_groupby(['b', 'a'], lambda x, **_: x)
        assert g.equals(d)
  • I'm getting an error: NameError: name 'walk_coords' is not defined
    – skd
    Oct 30, 2019 at 15:30
  • added the walk_coords function
    – mschrimpf
    Oct 30, 2019 at 18:30

I don't know how it would compare speed-wise, nor do I have enough time to put together a full solution for this particular question instance, but I found this question and answer quite helpful when I was searching for ways to iterate over multiple dimensions in xarray and wanted to share the approach I ended up taking. I ultimately used dimension stacking based on this example code by @RyanAbernathy:

import xarray as xr
import numpy as np

# create an example dataset
da = xr.DataArray(np.random.rand(10,30,40), dims=['dtime', 'x', 'y'])

# define a function to compute a linear trend of a timeseries
def linear_trend(x):
    pf = np.polyfit(x.time, x, 1)
    # we need to return a dataarray or else xarray's groupby won't be happy
    return xr.DataArray(pf[0])

# stack lat and lon into a single dimension called allpoints
stacked = da.stack(allpoints=['x','y'])
# apply the function over allpoints to calculate the trend at each point
trend = stacked.groupby('allpoints').apply(linear_trend)
# unstack back to lat lon coordinates
trend_unstacked = trend.unstack('allpoints')

in combination with some groupby wrappers to compute multiple groupbys:

def _calc_allpoints(ds, function):
        Helper function to do a pixel-wise calculation that requires using x and y dimension values
        as inputs. This version does the computation over all available timesteps as well.


        # note: the below code will need to be generalized for other dimensions

        def _time_wrapper(gb):
            gb = gb.groupby('dtime', squeeze=False).apply(function)
            return gb
        # stack x and y into a single dimension called allpoints
        stacked = ds.stack(allpoints=['x','y'])
        # groupby time and apply the function over allpoints to calculate the trend at each point
        newelev = stacked.groupby('allpoints', squeeze=False).apply(_time_wrapper)
        # unstack back to x y coordinates
        ds = newelev.unstack('allpoints')

        return ds

where function is whatever function you are using (e.g. linear_trend)

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.