Metadata-Version: 2.1
Name: python-plyr
Version: 0.5.3
Summary: Mapping tools for nested containers.
Home-page: https://github.com/ivannz/plyr
Author: Ivan Nazarov
Author-email: ivannnnz@gmail.com
License: MIT License
Platform: UNKNOWN
Description-Content-Type: text/markdown
License-File: LICENSE

# Plyr: computing on nested containers 

`plyr` \[/plaɪ'ə/\], derived from `applier`, is a python C-extension, that implements a `map`-like logic, which computes a specified function on the lower-most non-container data of arbitrarily nested *built-in* python containers, i.e. dicts, lists, tuples. It automatically unpacks nested containers in order to call the same function on their underlying non-container objects and then reassembles the structures. See the docstring of `plyr.apply` for details.

`plyr` \[/plaɪ'ə/\] is derived from `applier`, but also happens to coincide with a similarly named library for [`R` statistical computations language](https://www.r-project.org/), which streamlines dataframe and vector/matrix transformations.


## Example

Below we provide hopefully an illustrative example of the cases `plyr` might be useful in.

```python
import plyr

# add the leaf data in a pair of nested objects
plyr.apply(
    lambda u, v: u + v,
    [{'a': [1, 2, 3]}, {'b': 1, 'z': 'abc'}, ],
    [{'a': [4, 6, 8]}, {'b': 4, 'z': 'xyz'}, ],
    # _star=True,  # (default) call fn(d1, d2, **kwargs)
)
# output: [{'a': [5, 8, 11]}, {'b': 5, 'z': 'abcxyz'}]

# join strings in a pair of tuples
plyr.apply(
    ' -->> '.join,
    ('a-b-c', 'u-v-w', 'x-y-z',),
    ('123', '456', '789',),
    _star=False,  # call fn((d1, d2,), **kwargs)
)
# output: ('abc -->> 123', 'uvw -->> 456', 'xyz -->> 789')
```

By default `.apply` performs safety checks to ensure indentical structure if multiple nested objects are given. If the arguments have identical structure by design, then these integrity checks may be turned off by specifying `_safe=False`. Please refer to the docs of `plyr.apply`.


## Other examples

Below we perform something fancy with `numpy`. Specifically we stack experimental results (dicts of arrays), then get the standard deviation between the results

```python
import plyr
import numpy as np


# some computations
def experiment(j):
    return dict(
        a=float(np.random.normal()),
        u=np.random.normal(size=(5, 2)) * 0.1,
        z=np.random.normal(size=(2, 5)) * 10,
    )


# run 10 replications of an experiment
results = [experiment(j) for j in range(10)]

# stack and analyze the results (np.stack needs an iterable argument)
res = plyr.apply(np.stack, *results, axis=0, _star=False)

# get the shapes
shapes = plyr.apply(lambda x: x.shape, res)

# compute the std along the replication axis
plyr.apply(np.std, res, axis=0)
```

You may notice that `.apply` is very _straightforward_: it applies the specified function regardless of the leaf data type.

