Exemple #1
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def test_tree_reduce_futures(n_parts, client):

    a = [client.submit(s, i) for i in range(n_parts)]
    b = tree_reduce(a)
    c = client.compute(b, sync=True)

    assert (sum(range(n_parts)) == c)
Exemple #2
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def test_tree_reduce_delayed(n_parts, client):

    func = delayed(sum)

    a = [delayed(i) for i in range(n_parts)]
    b = tree_reduce(a, func=func)
    c = client.compute(b, sync=True)

    assert (sum(range(n_parts)) == c)
Exemple #3
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def test_tree_reduce_futures(n_parts, cluster):

    client = Client(cluster)
    try:

        a = [client.submit(s, i) for i in range(n_parts)]
        b = tree_reduce(a)
        c = client.compute(b, sync=True)

        assert (sum(range(n_parts)) == c)
    finally:
        client.close()
Exemple #4
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    def score(self, X, y):
        """
        Compute accuracy score

        Parameters
        ----------

        X : Dask.Array
            Features to predict. Note- it is assumed that chunk sizes and
            shape of X are known. This can be done for a fully delayed
            Array by calling X.compute_chunks_sizes()
        y : Dask.Array
            Labels to use for computing accuracy. Note- it is assumed that
            chunk sizes and shape of X are known. This can be done for a fully
            delayed Array by calling X.compute_chunks_sizes()

        Returns
        -------
        score : float the resulting accuracy score
        """

        y_hat = self.predict(X)

        @dask.delayed
        def _count_accurate_predictions(y_hat, y):
            y_hat = rmm_cupy_ary(cp.asarray, y_hat, dtype=y_hat.dtype)
            y = rmm_cupy_ary(cp.asarray, y, dtype=y.dtype)
            return y.shape[0] - cp.count_nonzero(y - y_hat)

        delayed_parts = zip(y_hat.to_delayed(), y.to_delayed())

        accuracy_parts = [
            _count_accurate_predictions(*p) for p in delayed_parts
        ]

        reduced = first(dask.compute(tree_reduce(accuracy_parts)))

        return reduced / X.shape[0]