Apply into NumpyΒΆ

In following parts, we will show some demos about how to use TreeValue in practice.

For example, now we have a group of structed data in python-dict type, we want to do different operations on differnent key-value pairs inplace, get some statistics such as mean value and task some slices.

In normal cases, we need to unroll multiple for-loop and if-else to implement cooresponding operations on each values, and declare additional temporal variables to save result. All the mentioned contents are executed serially, like the next code examples:

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import numpy as np

T, B = 3, 4


def without_treevalue(batch_):
    mean_b_list = []
    even_index_a_list = []
    for i in range(len(batch_)):
        for k, v in batch_[i].items():
            if k == 'a':
                v = v.astype(np.float32)
                even_index_a_list.append(v[::2])
            elif k == 'b':
                v = v.astype(np.float32)
                transformed_v = np.power(v, 2) + 1.0
                mean_b_list.append(transformed_v.mean())
            elif k == 'c':
                for k1, v1 in v.items():
                    if k1 == 'd':
                        v1 = v1.astype(np.float32)
                    else:
                        print('ignore keys: {}'.format(k1))
            else:
                print('ignore keys: {}'.format(k))
    for i in range(len(batch_)):
        for k in batch_[i].keys():
            if k == 'd':
                batch_[i][k]['noise'] = np.random.random(size=(3, 4, 5))

    mean_b = sum(mean_b_list) / len(mean_b_list)
    even_index_a = np.stack(even_index_a_list, axis=0)
    return batch_, mean_b, even_index_a

However, with the help of TreeValue, all the contents mentioned above can be implemented gracefully and efficiently. Users only need to func_treelize the primitive numpy functions and pack data with FastTreeValue, then execute desired operations just like using standard numpy array.

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import numpy as np

from treevalue import FastTreeValue

T, B = 3, 4
power = FastTreeValue.func()(np.power)
stack = FastTreeValue.func(subside=True)(np.stack)
split = FastTreeValue.func(rise=True)(np.split)


def with_treevalue(batch_):
    batch_ = [FastTreeValue(b) for b in batch_]
    batch_ = stack(batch_)
    batch_ = batch_.astype(np.float32)
    batch_.b = power(batch_.b, 2) + 1.0
    batch_.c.noise = np.random.random(size=(B, 3, 4, 5))
    mean_b = batch_.b.mean()
    even_index_a = batch_.a[:, ::2]
    batch_ = split(batch_, indices_or_sections=B, axis=0)
    return batch_, mean_b, even_index_a

And we can run these two demos for comparison:

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import copy

import numpy as np
from with_treevalue import with_treevalue
from without_treevalue import without_treevalue

T, B = 3, 4


def get_data():
    return {
        'a': np.random.random(size=(T, 8)),
        'b': np.random.random(size=(6,)),
        'c': {
            'd': np.random.randint(0, 10, size=(1,))
        }
    }


if __name__ == "__main__":
    batch = [get_data() for _ in range(B)]
    batch0, mean0, even_index_a0 = without_treevalue(copy.deepcopy(batch))
    batch1, mean1, even_index_a1 = with_treevalue(copy.deepcopy(batch))

    assert np.abs(mean0 - mean1) < 1e-6
    print('mean0 & mean1:', mean0, mean1)
    print('\n')

    assert np.abs((even_index_a0 - even_index_a1).max()) < 1e-6
    print('even_index_a0:', even_index_a0)
    print('even_index_a1:', even_index_a1)

    assert len(batch0) == B
    assert len(batch1) == B

The final output should be the text below, and all the assertions can be passed.

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mean0 & mean1: 1.3406870365142822 1.3406872


even_index_a0: [[[0.23041318 0.9591945  0.6814987  0.8218488  0.7415833  0.5647253
   0.05639242 0.10331166]
  [0.19158973 0.21114475 0.6792426  0.28647283 0.88825256 0.03325007
   0.33490345 0.05796575]]

 [[0.18357077 0.9996377  0.39495453 0.4370512  0.8309028  0.42769724
   0.01562462 0.93603295]
  [0.10949744 0.94473386 0.1455865  0.42402208 0.40637073 0.54510194
   0.976213   0.37854636]]

 [[0.98322564 0.22323547 0.17092748 0.6512625  0.11976574 0.8877547
   0.31600872 0.411345  ]
  [0.83575964 0.70989686 0.29825613 0.57674026 0.24539264 0.32152438
   0.547306   0.3206383 ]]

 [[0.2199248  0.97433823 0.57855785 0.20540574 0.7231105  0.5388891
   0.6420753  0.03738151]
  [0.07565436 0.04365401 0.96229583 0.76178455 0.8360824  0.83067536
   0.81521565 0.45383608]]]
even_index_a1: [[[0.23041318 0.9591945  0.6814987  0.8218488  0.7415833  0.5647253
   0.05639242 0.10331166]
  [0.19158973 0.21114475 0.6792426  0.28647283 0.88825256 0.03325007
   0.33490345 0.05796575]]

 [[0.18357077 0.9996377  0.39495453 0.4370512  0.8309028  0.42769724
   0.01562462 0.93603295]
  [0.10949744 0.94473386 0.1455865  0.42402208 0.40637073 0.54510194
   0.976213   0.37854636]]

 [[0.98322564 0.22323547 0.17092748 0.6512625  0.11976574 0.8877547
   0.31600872 0.411345  ]
  [0.83575964 0.70989686 0.29825613 0.57674026 0.24539264 0.32152438
   0.547306   0.3206383 ]]

 [[0.2199248  0.97433823 0.57855785 0.20540574 0.7231105  0.5388891
   0.6420753  0.03738151]
  [0.07565436 0.04365401 0.96229583 0.76178455 0.8360824  0.83067536
   0.81521565 0.45383608]]]

In this case, we can see that the TreeValue can be properly applied into the numpy library. The tree-structured matrix calculation can be easily built with TreeValue like using standard numpy array.

Both the simplicity of logic structure and execution efficiency can be improve a lot.

And Last but not least, the only thing you need to do is to wrap the functions in Numpy library, and then use it painlessly like the primitive numpy.