Exemplo n.º 1
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def test_translate_vmul(x_shape):
    a = np.random.randint(-3, 3, x_shape)
    b = np.random.randint(-3, 3, x_shape)
    np_res = a.dot(b)
    with pm.Node("vmul") as pm_graph:
        pm_a = pm.input(name="a", shape=x_shape)
        pm_b = pm.input(name="b", shape=x_shape)
        pm_o = pm.output(name="o", shape=x_shape)
        pm_s = pm.output(name="out")
        pm.elem_mul(pm_a, pm_b, pm_o)
        pm.reduce_sum(pm_o, pm_s, axes=(0,), keepdims=0)

    pm_res = pm_graph("out", {"a": a, "b": b})
    np.testing.assert_allclose(pm_res, np_res)
Exemplo n.º 2
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def get_max_pool(x,
                 ceil_mode=0,
                 kernel_shape=None,
                 pads=None,
                 auto_pad=None,
                 strides=None,
                 shape=None,
                 name=None,
                 out=None):
    if not out:
        out = pm.output(shape=shape, name=name)
    int_fn = np.ceil if ceil_mode != 0 else np.floor
    if auto_pad:
        h_out = int_fn(x.shape[-2] / strides[0])
        w_out = int_fn(x.shape[-1] / strides[1])
        ph = max(0, (h_out - 1) * strides[0] + kernel_shape[0] - x.shape[-2])
        pw = max(0, (w_out - 1) * strides[1] + kernel_shape[1] - x.shape[-1])
        pads = [0, 0, 0, 0]
        if auto_pad == "SAME_LOWER":
            pads[0] = np.floor(ph // 2)
            pads[1] = ph - pads[0]
            pads[2] = np.floor(pw // 2)
            pads[3] = pw - pads[2]
        elif auto_pad == "SAME_UPPER":
            pads[1] = np.floor(ph // 2)
            pads[0] = ph - pads[1]
            pads[3] = np.floor(pw // 2)
            pads[2] = pw - pads[3]
    pm.max_pool(x, out, kernel_shape[0], kernel_shape[1],
                (int(strides[0]), int(strides[1])),
                (int(pads[0]), int(pads[2])))
    return out
Exemplo n.º 3
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def get_transpose(data, perm=None, shape=None, name=None, out=None, **kwargs):
    if not out:
        out = pm.output(name=name, shape=shape)
    if perm is None:
        perm = tuple(list(reversed([i for i in data.shape])))
    pm.tensor_transpose(data, out, perm=perm)
    return out
Exemplo n.º 4
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def test_conv2d_transpose_shapes(inp_shape, wgt_shape, stride, pad):
    groups = 1
    dilation = 1
    out_pad = 0
    inp = np.random.randint(-15, 15, np.prod(inp_shape)).reshape(inp_shape)
    wgt = np.random.randint(-15, 15, np.prod(wgt_shape)).reshape(wgt_shape)
    torch_res = F.conv_transpose2d(torch.from_numpy(inp), torch.from_numpy(wgt),
                                   stride=stride, padding=pad)
    torch_res = conv2d_transpose(torch.from_numpy(inp), torch.from_numpy(wgt), stride, pad)
    # np.testing.assert_allclose(tres.numpy(), torch_res.numpy())
    info = {
        'data': inp,
        'w': wgt,
    }
    N, C, H, W = inp.shape

    x = pm.input(name="data", shape=inp_shape)
    w = pm.state(name="w", shape=wgt_shape)
    out = pm.output(name="out")

    graph = pm.conv_transpose(x, w, out, stride, pad)
    #
    tres = graph("out", info)

    np.testing.assert_allclose(tres, torch_res.numpy())
Exemplo n.º 5
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    def elem_tanh_grad(self, node):
        grad = self.get_gradient(node)
        out_grad = pm.output(name=f"{node.inputs[0].name}_grad",
                             shape=node.inputs[0].shape)
        pm.elem_tanh_grad(node.inputs[0], grad, out_grad)

        self.update_grad_map(node.inputs[0], out_grad, node)
Exemplo n.º 6
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 def max_pool_grad(self, node):
     grad = self.get_gradient(node)
     mpool_grad = pm.output(name=f"{node.inputs[0].name}_grad",
                            shape=node.inputs[0].shape)
     pm.max_pool_grad(node.inputs[0], grad, mpool_grad, node.kernel_size[0],
                      node.kernel_size[1], node.stride, node.pad)
     self.update_grad_map(node.inputs[0], mpool_grad, node)
Exemplo n.º 7
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def test_translate_conv(x_shape, w_shape, params):
    shape_dict = {"n": x_shape[0], "c": x_shape[1], "ih": x_shape[2], "iw": x_shape[3],
                  "nf": w_shape[0], "kh": w_shape[2], "kw": w_shape[3],
                  "stride": params["stride"], "pad": params["pad"]}

    _, input_info, out_info, keys = conv(x_shape, w_shape, params, coarse=True, debug_matrix=False)

    n = pm.parameter(name="n")
    c = pm.parameter(name="ic")
    ih = pm.parameter(name="ih")
    iw = pm.parameter(name="iw")
    nf = pm.parameter(name="nf")
    kh = pm.parameter(name="kh")
    kw = pm.parameter(name="kw")
    x = pm.input(name="data", shape=(n, c, ih, iw))
    w = pm.state(name="w", shape=(nf, c, kh, kw))
    b = pm.state(name="bias", shape=(nf))
    stride = pm.parameter(name="stride")
    pad = pm.parameter(name="pad")
    out = pm.output(name="out")
    graph = pm.conv_bias(x, w, b, out, stride, pad)
    tinput_info = copy.deepcopy(input_info)
    res0 = graph("out", tinput_info)

    np.testing.assert_allclose(res0, out_info["out"])
Exemplo n.º 8
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def get_topk(x,
             k,
             largest=1,
             sorted=1,
             axis=-1,
             shapes=None,
             name=None,
             out=None,
             out_indices=None,
             **kwargs):
    if not out:
        out = pm.output(name=name[0], shape=shapes[0])
    if not out_indices:
        out_indices = pm.output(name=name[1], shape=shapes[1])
    pm.topk(x, k, out, out_indices, largest=largest, sorted=sorted, axis=axis)
    return out, out_indices
Exemplo n.º 9
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    def cross_entropy_grad(self, node):
        grad = self.get_gradient(node)

        inp_grad = pm.output(name=f"{node.inputs[0].name}_grad",
                             shape=node.inputs[0].shape)
        pm.cross_entropy_loss_grad(node.inputs[0], node.inputs[1], grad,
                                   inp_grad)
        self.update_grad_map(node.inputs[0], inp_grad, node)
Exemplo n.º 10
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def test_translate_softmax(x_shape, axis):
    x = np.random.randint(0, 5, x_shape).astype(np.float)
    data = pm.input("x", shape=x.shape)
    out = pm.output("out")
    g = pm.softmax(data, out, axis=1)
    res = g("out", {"x": x})
    np_res = np_softmax(x, axis=1)
    np.testing.assert_allclose(np_res, res)
Exemplo n.º 11
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def test_bnorm():
    shape = (1, 16, 32, 32)
    grad = torch.rand(shape)
    x = torch.rand(shape)
    scale = torch.rand((shape[1], ))
    bias = torch.rand((shape[1], ))
    mean = torch.rand((shape[1], ))
    var = torch.rand((shape[1], ))
    torch_res = batchnorm2d_backward(grad, x, scale, bias)

    grad = grad.numpy()
    x = x.numpy()
    scale = scale.numpy()
    bias = bias.numpy()
    mean = mean.numpy()
    var = var.numpy()
    optimizer = "sgd"
    optimizer_kwargs = {"lr": 0.01}
    pm_x = pm.input(name="x", shape=shape)
    pm_grad = pm.input(name="grad", shape=shape)
    pm_scale = pm.state(name="scale", shape=scale.shape)
    pm_bias = pm.state(name="bias", shape=scale.shape)
    pm_mean = pm.state(name="mean", shape=scale.shape)
    pm_var = pm.state(name="var", shape=scale.shape)
    pm_x_grad = pm.output(name="x_grad", shape=shape)
    pm_scale_grad = pm.output(name="scale_grad", shape=scale.shape)
    pm_b_grad = pm.output(name="bias_grad", shape=bias.shape)

    inp_map = {
        'x': x,
        'grad': grad,
        'scale': scale,
        'bias': bias,
        'mean': mean,
        'var': var,
    }
    graph = pm.batchnorm_grad(pm_x, pm_scale, pm_bias, pm_mean, pm_var,
                              pm_grad, pm_x_grad, pm_scale_grad, pm_b_grad,
                              optimizer, optimizer_kwargs)
    rtol, atol = 1.3e-3, 1e-3
    gout = graph("bias_grad", inp_map)
    np.testing.assert_allclose(gout,
                               torch_res.numpy().reshape(gout.shape),
                               rtol=rtol,
                               atol=atol)
Exemplo n.º 12
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 def populate_output(self, node):
     if node.shape != pm.DEFAULT_SHAPES[0]:
         indices = list(product(*tuple([np.arange(i) for i in node.shape])))
         for i in indices:
             x = pm.output(graph=node,
                           name=f"{node.name}{i}",
                           root_name=node.name,
                           shape=(1, ))
             self.stored_objects[id(x)] = x
Exemplo n.º 13
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def get_elem_if(condition,
                else_branch=None,
                then_branch=None,
                shape=None,
                name=None,
                out=None):
    if not out:
        out = pm.output(name=name, shape=shape)
    pm.elem_nonzero(condition, out)
    return out
Exemplo n.º 14
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 def update_grad_map(self, input_node, gradient_node, parent_node):
     if input_node.name in self.grad_map:
         assert gradient_node.shape == self.grad_map[input_node.name].shape
         grad_name = f"{self.grad_map[input_node.name].name},{gradient_node.name}"
         acc_grad = pm.output(name=grad_name, shape=gradient_node.shape)
         pm.elem_add(self.grad_map[input_node.name], gradient_node,
                     acc_grad)
         self.grad_map[input_node.name] = acc_grad
     else:
         self.grad_map[input_node.name] = gradient_node
Exemplo n.º 15
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def get_concat(*inputs, axis=None, shape=None, name=None, out=None):
    if not out:
        out = pm.output(name=name, shape=shape)
    pm.concat(*(inputs + (out, )), axis=axis)
    # indices = [pm.index(0, s - 1) if s > 1 else 0 for s in shape]
    # for idx, i in enumerate(inputs):
    #     indices[axis] = pm.index(idx*i.shape[axis], (idx+1)*i.shape[axis]-1)
    #     j = pm.index(0, i.shape[axis]-1)
    #     out[tuple(indices)] = i[tuple(indices[:axis] + [j] + indices[axis+1:])]
    return out
Exemplo n.º 16
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def get_loop(v_initial,
             cond=None,
             max_trip_count=None,
             name=None,
             shape=None,
             out=None):
    if not out:
        out = pm.output(name=name, shape=shape)
    pm.loop(v_initial, out, cond=cond, max_trip_count=max_trip_count)
    return out
Exemplo n.º 17
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 def batch_norm_grad(self, node):
     grad = self.get_gradient(node)
     bn_inp_grad = pm.output(name=f"{node.inputs[0].name}_grad",
                             shape=node.inputs[0].shape)
     bn_scale_grad = pm.output(
         name=f"{node.inputs[1].name}_grad_{node.name}",
         shape=node.inputs[1].shape)
     bn_bias_grad = pm.output(
         name=f"{node.inputs[2].name}_grad_{node.name}",
         shape=node.inputs[2].shape)
     inp = node.inputs[0]
     scale = node.inputs[1]
     bias = node.inputs[2]
     mean = node.inputs[3]
     var = node.inputs[4]
     pm.batchnorm_grad(inp, scale, bias, mean, var, grad, bn_inp_grad,
                       bn_scale_grad, bn_bias_grad, self.optimizer_name,
                       self.optimizer_kwargs)
     self.update_grad_map(node.inputs[0], bn_inp_grad, node)
Exemplo n.º 18
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def get_reduce_max(x, shape=None, name=None, out=None, axes=(0, ), **kwargs):
    if not out:
        out = pm.output(name=name, shape=shape)
    if isinstance(axes, Integral):
        axes = (axes, )
    elif isinstance(axes, list):
        axes = tuple(axes)
    else:
        assert isinstance(axes, tuple)
    pm.reduce_max(x, out, axes=axes)
    return out
Exemplo n.º 19
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def get_cross_entropy_loss(scores,
                           labels,
                           ignore_index=-100,
                           reduction="mean",
                           name=None,
                           shape=None,
                           out=None):
    if not out:
        out = pm.output(shape=shape, name=name)
    pm.cross_entropy_loss(scores, labels, out, reduction=reduction)
    return out
Exemplo n.º 20
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    def gemm_grad(self, node):
        grad = self.get_gradient(node)
        gemm_inp_grad = pm.output(name=f"{node.inputs[0].name}_grad",
                                  shape=node.inputs[0].shape)
        gemm_weight_grad = pm.output(name=f"{node.inputs[1].name}_grad",
                                     shape=node.inputs[1].shape)

        if len(node.inputs) > 2:
            gemm_bias_grad = pm.output(name=f"{node.inputs[2].name}_grad",
                                       shape=node.inputs[2].shape)
            pm.gemm_grad(node.inputs[0], node.inputs[1], node.inputs[2], grad,
                         gemm_inp_grad, gemm_weight_grad, gemm_bias_grad,
                         self.optimizer_name, self.optimizer_kwargs)

        else:
            pm.gemm_grad_no_bias(node.inputs[0], node.inputs[1], grad,
                                 gemm_inp_grad, gemm_weight_grad,
                                 self.optimizer_name, self.optimizer_kwargs)

        self.update_grad_map(node.inputs[0], gemm_inp_grad, node)
Exemplo n.º 21
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def get_scatter(data,
                indices,
                updates,
                axis=0,
                shape=None,
                name=None,
                out=None):
    if not out:
        out = pm.output(name=name, shape=shape)
    pm.scatter_elements(data, indices, updates, out, axis=axis)
    return out
Exemplo n.º 22
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def get_split(input,
              split=None,
              axis=-1,
              name=None,
              shape=None,
              out=None,
              **kwargs):
    if not out:
        out = pm.output(name=name, shape=shape)
    pm.split(input, out, split=split, axis=axis)
    return out
Exemplo n.º 23
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def test_translate_flatten(x_shape):
    x = np.random.randint(0, 5, x_shape)
    data = pm.input("x", shape=x.shape)
    out = pm.output("out")

    g = pm.batch_flatten(data, out)

    res = g("out", {"x": x})
    print(res)
    print(x.reshape(-1))
    np.testing.assert_allclose(res, x.reshape(-1))
Exemplo n.º 24
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def get_elem_clip(data,
                  min=None,
                  max=None,
                  shape=None,
                  name=None,
                  out=None,
                  **kwargs):
    if not out:
        out = pm.output(name=name, shape=shape)
    pm.elem_clip(data, out, min=min, max=max)
    return out
Exemplo n.º 25
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def get_slice(input,
              starts,
              ends,
              axes=-1,
              steps=1,
              name=None,
              shape=None,
              out=None,
              **kwargs):
    if not out:
        out = pm.output(name=name, shape=shape)
    return out
Exemplo n.º 26
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def get_lrn(x,
            alpha=None,
            beta=None,
            bias=None,
            size=None,
            name=None,
            shape=None,
            out=None):
    if not out:
        out = pm.output(name=name, shape=shape)
    pm.lrn(x, out, alpha=alpha, beta=beta, bias=bias, nsize=size)
    return out
Exemplo n.º 27
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def get_dropout(x,
                ratio=None,
                training_mode=False,
                shape=None,
                name=None,
                out=None):
    if not out:
        out = pm.output(shape=shape, name=name)
    if training_mode:
        pm.dropout(x, out, ratio=ratio)
    else:
        pm.dropout(x, out)
    return out
Exemplo n.º 28
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def test_translate_elem_mul(x_shape):
    a = np.random.randint(-3, 3, x_shape)
    b = np.random.randint(-3, 3, x_shape)
    np_res = a * b
    graph = pm.Node("elem_mul")

    pm_a = pm.input(name="a", shape=x_shape, graph=graph)
    pm_b = pm.input(name="b", shape=x_shape, graph=graph)
    pm_o = pm.output(name="out", shape=x_shape, graph=graph)
    with graph:
        pm.elem_mul(pm_a, pm_b, pm_o)
    pm_res = graph("out", {"a": a, "b": b})
    np.testing.assert_allclose(pm_res, np_res)
Exemplo n.º 29
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def test_translate_reduce_sum(x_shape):
    data = np.random.randint(-3, 3, x_shape)
    np_res = np.sum(data)
    graph = pm.Node("reduce")
    pm_data = pm.input(name="a", shape=x_shape, graph=graph)
    out = pm.output(name="out", graph=graph)
    axis = (0,)
    keepdims = 0

    with graph:
        pm.reduce_sum(pm_data, out, axes=axis, keepdims=keepdims)
    pm_res = graph("out", {"a": data})
    np.testing.assert_allclose(pm_res, np_res)
Exemplo n.º 30
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def get_conv_transpose(x,
                       w,
                       bias=None,
                       dilations=None,
                       group=None,
                       kernel_shape=None,
                       pads=None,
                       auto_pad=None,
                       output_padding=None,
                       strides=None,
                       shape=None,
                       name=None,
                       out=None):
    if not out:
        out = pm.output(shape=shape, name=name)

    if auto_pad:

        h_out = np.ceil(x.shape[-2] / strides[0])
        w_out = np.ceil(x.shape[-1] / strides[1])
        ph = max(0, (h_out - 1) * strides[0] + kernel_shape[0] - x.shape[-2])
        pw = max(0, (w_out - 1) * strides[1] + kernel_shape[1] - x.shape[-1])
        pads = [0, 0, 0, 0]
        if auto_pad == "SAME_LOWER":
            pads[0] = np.floor(ph // 2)
            pads[1] = ph - pads[0]
            pads[2] = np.floor(pw // 2)
            pads[3] = pw - pads[2]
        elif auto_pad == "SAME_UPPER":
            pads[1] = np.floor(ph // 2)
            pads[0] = ph - pads[1]
            pads[3] = np.floor(pw // 2)
            pads[2] = pw - pads[3]

    if bias:
        pm.conv_transpose_bias(x,
                               w,
                               bias,
                               out,
                               int(strides[0]),
                               int(pads[-2]),
                               out_pad=output_padding)
        return out
    else:
        pm.conv_transpose(x,
                          w,
                          out,
                          int(strides[0]),
                          int(pads[-2]),
                          out_pad=output_padding)
        return out