# Reshaping and reorganizing data¶

These methods allow you to reorganize

## Reordering dimensions¶

To reorder dimensions on a DataArray or across all variables on a Dataset, use transpose() or the .T property:

In [1]: ds = xr.Dataset({'foo': (('x', 'y', 'z'), [[[42]]]), 'bar': (('y', 'z'), [[24]])})

In [2]: ds.transpose('y', 'z', 'x')
Out[2]:
<xarray.Dataset>
Dimensions:  (x: 1, y: 1, z: 1)
Dimensions without coordinates: x, y, z
Data variables:
foo      (y, z, x) int64 42
bar      (y, z) int64 24

In [3]: ds.T
Out[3]:
<xarray.Dataset>
Dimensions:  (x: 1, y: 1, z: 1)
Dimensions without coordinates: x, y, z
Data variables:
foo      (z, y, x) int64 42
bar      (z, y) int64 24


## Converting between datasets and arrays¶

To convert from a Dataset to a DataArray, use to_array():

In [4]: arr = ds.to_array()

In [5]: arr
Out[5]:
<xarray.DataArray (variable: 2, x: 1, y: 1, z: 1)>
array([[[[42]]],

[[[24]]]])
Coordinates:
* variable  (variable) <U3 'foo' 'bar'
Dimensions without coordinates: x, y, z


This method broadcasts all data variables in the dataset against each other, then concatenates them along a new dimension into a new array while preserving coordinates.

To convert back from a DataArray to a Dataset, use to_dataset():

In [6]: arr.to_dataset(dim='variable')
Out[6]:
<xarray.Dataset>
Dimensions:  (x: 1, y: 1, z: 1)
Dimensions without coordinates: x, y, z
Data variables:
foo      (x, y, z) int64 42
bar      (x, y, z) int64 24


The broadcasting behavior of to_array means that the resulting array includes the union of data variable dimensions:

In [7]: ds2 = xr.Dataset({'a': 0, 'b': ('x', [3, 4, 5])})

# the input dataset has 4 elements
In [8]: ds2
Out[8]:
<xarray.Dataset>
Dimensions:  (x: 3)
Dimensions without coordinates: x
Data variables:
a        int64 0
b        (x) int64 3 4 5

# the resulting array has 6 elements
In [9]: ds2.to_array()
Out[9]:
<xarray.DataArray (variable: 2, x: 3)>
array([[0, 0, 0],
[3, 4, 5]])
Coordinates:
* variable  (variable) <U1 'a' 'b'
Dimensions without coordinates: x


Otherwise, the result could not be represented as an orthogonal array.

If you use to_dataset without supplying the dim argument, the DataArray will be converted into a Dataset of one variable:

In [10]: arr.to_dataset(name='combined')
Out[10]:
<xarray.Dataset>
Dimensions:   (variable: 2, x: 1, y: 1, z: 1)
Coordinates:
* variable  (variable) <U3 'foo' 'bar'
Dimensions without coordinates: x, y, z
Data variables:
combined  (variable, x, y, z) int64 42 24


## Stack and unstack¶

As part of xarray’s nascent support for pandas.MultiIndex, we have implemented stack() and unstack() method, for combining or splitting dimensions:

In [11]: array = xr.DataArray(np.random.randn(2, 3),
....:                      coords=[('x', ['a', 'b']), ('y', [0, 1, 2])])
....:

In [12]: stacked = array.stack(z=('x', 'y'))

In [13]: stacked
Out[13]:
<xarray.DataArray (z: 6)>
array([ 0.469112, -0.282863, -1.509059, -1.135632,  1.212112, -0.173215])
Coordinates:
* z        (z) MultiIndex
- x        (z) object 'a' 'a' 'a' 'b' 'b' 'b'
- y        (z) int64 0 1 2 0 1 2

In [14]: stacked.unstack('z')
Out[14]:
<xarray.DataArray (x: 2, y: 3)>
array([[ 0.469112, -0.282863, -1.509059],
[-1.135632,  1.212112, -0.173215]])
Coordinates:
* x        (x) object 'a' 'b'
* y        (y) int64 0 1 2


These methods are modeled on the pandas.DataFrame methods of the same name, although in xarray they always create new dimensions rather than adding to the existing index or columns.

Like DataFrame.unstack, xarray’s unstack always succeeds, even if the multi-index being unstacked does not contain all possible levels. Missing levels are filled in with NaN in the resulting object:

In [15]: stacked2 = stacked[::2]

In [16]: stacked2
Out[16]:
<xarray.DataArray (z: 3)>
array([ 0.469112, -1.509059,  1.212112])
Coordinates:
* z        (z) MultiIndex
- x        (z) object 'a' 'a' 'b'
- y        (z) int64 0 2 1

In [17]: stacked2.unstack('z')
Out[17]:
<xarray.DataArray (x: 2, y: 3)>
array([[ 0.469112,       nan, -1.509059],
[      nan,  1.212112,       nan]])
Coordinates:
* x        (x) object 'a' 'b'
* y        (y) int64 0 1 2


However, xarray’s stack has an important difference from pandas: unlike pandas, it does not automatically drop missing values. Compare:

In [18]: array = xr.DataArray([[np.nan, 1], [2, 3]], dims=['x', 'y'])

In [19]: array.stack(z=('x', 'y'))
Out[19]:
<xarray.DataArray (z: 4)>
array([ nan,   1.,   2.,   3.])
Coordinates:
* z        (z) MultiIndex
- x        (z) int64 0 0 1 1
- y        (z) int64 0 1 0 1

In [20]: array.to_pandas().stack()
Out[20]:
x  y
0  1    1.0
1  0    2.0
1    3.0
dtype: float64


We departed from pandas’s behavior here because predictable shapes for new array dimensions is necessary for Out of core computation with dask.

## Set and reset index¶

Complementary to stack / unstack, xarray’s .set_index, .reset_index and .reorder_levels allow easy manipulation of DataArray or Dataset multi-indexes without modifying the data and its dimensions.

You can create a multi-index from several 1-dimensional variables and/or coordinates using set_index():

In [21]: da = xr.DataArray(np.random.rand(4),
....:                   coords={'band': ('x', ['a', 'a', 'b', 'b']),
....:                           'wavenumber': ('x', np.linspace(200, 400, 4))},
....:                   dims='x')
....:

In [22]: da
Out[22]:
<xarray.DataArray (x: 4)>
array([ 0.123102,  0.543026,  0.373012,  0.447997])
Coordinates:
wavenumber  (x) float64 200.0 266.7 333.3 400.0
band        (x) <U1 'a' 'a' 'b' 'b'
Dimensions without coordinates: x

In [23]: mda = da.set_index(x=['band', 'wavenumber'])

In [24]: mda
Out[24]:
<xarray.DataArray (x: 4)>
array([ 0.123102,  0.543026,  0.373012,  0.447997])
Coordinates:
* x           (x) MultiIndex
- band        (x) object 'a' 'a' 'b' 'b'
- wavenumber  (x) float64 200.0 266.7 333.3 400.0


These coordinates can now be used for indexing, e.g.,

In [25]: mda.sel(band='a')
Out[25]:
<xarray.DataArray (wavenumber: 2)>
array([ 0.123102,  0.543026])
Coordinates:
* wavenumber  (wavenumber) float64 200.0 266.7


Conversely, you can use reset_index() to extract multi-index levels as coordinates (this is mainly useful for serialization):

In [26]: mda.reset_index('x')
Out[26]:
<xarray.DataArray (x: 4)>
array([ 0.123102,  0.543026,  0.373012,  0.447997])
Coordinates:
band        (x) object 'a' 'a' 'b' 'b'
wavenumber  (x) float64 200.0 266.7 333.3 400.0
Dimensions without coordinates: x


reorder_levels() allows changing the order of multi-index levels:

In [27]: mda.reorder_levels(x=['wavenumber', 'band'])
Out[27]:
<xarray.DataArray (x: 4)>
array([ 0.123102,  0.543026,  0.373012,  0.447997])
Coordinates:
* x           (x) MultiIndex
- wavenumber  (x) float64 200.0 266.7 333.3 400.0
- band        (x) object 'a' 'a' 'b' 'b'


As of xarray v0.9 coordinate labels for each dimension are optional. You can also use .set_index / .reset_index to add / remove labels for one or several dimensions:

In [28]: array = xr.DataArray([1, 2, 3], dims='x')

In [29]: array
Out[29]:
<xarray.DataArray (x: 3)>
array([1, 2, 3])
Dimensions without coordinates: x

In [30]: array['c'] = ('x', ['a', 'b', 'c'])

In [31]: array.set_index(x='c')
Out[31]:
<xarray.DataArray (x: 3)>
array([1, 2, 3])
Coordinates:
* x        (x) object 'a' 'b' 'c'

In [32]: array.set_index(x='c', inplace=True)

In [33]: array.reset_index('x', drop=True)
Out[33]:
<xarray.DataArray (x: 3)>
array([1, 2, 3])
Dimensions without coordinates: x


## Shift and roll¶

To adjust coordinate labels, you can use the shift() and roll() methods:

In [34]: array = xr.DataArray([1, 2, 3, 4], dims='x')

In [35]: array.shift(x=2)
Out[35]:
<xarray.DataArray (x: 4)>
array([ nan,  nan,   1.,   2.])
Dimensions without coordinates: x

In [36]: array.roll(x=2)
Out[36]:
<xarray.DataArray (x: 4)>
array([3, 4, 1, 2])
Dimensions without coordinates: x