コード例 #1
0
 def array_like_conv_output(self, inputs_shape, filters_shape, border_mode,
                            subsample, dilation, dtype):
     # Return a random array with inferred convolution output shape.
     out_shp = get_conv_output_shape(inputs_shape, filters_shape,
                                     border_mode, subsample, dilation)
     out_shp = assert_conv_shape(out_shp)
     return np.random.random(out_shp).astype(dtype)
コード例 #2
0
 def get_if_valid_conv_output_shape(case_tuple):
     # Filter function to keep only cases that produce valid convolution output shapes.
     out_shp = get_conv_output_shape(case_tuple[0],  # input shape
                                     case_tuple[1],  # filter shape
                                     case_tuple[4],  # border mode
                                     case_tuple[2],  # subsample
                                     case_tuple[3])  # dilation
     try:
         return assert_conv_shape(out_shp)
     except ValueError:
         return False
コード例 #3
0
def local_abstractconv_cudnn_alt(node):
    if not isinstance(node.op, (AbstractConv2d, AbstractConv2d_gradWeights,
                                AbstractConv2d_gradInputs)):
        return

    if version(raises=False) < 6000 and node.op.filter_dilation != (1, 1):
        return None
    if node.op.unshared:
        return None
    if isinstance(node.op.border_mode, tuple) and any(
            isinstance(p, tuple) for p in node.op.border_mode):
        # Asymmetric padding not yet supported
        return None
    inp1 = node.inputs[0]
    inp2 = node.inputs[1]

    if not dnn_available(inp1.type.context_name):
        return

    op = node.op
    border_mode = node.op.border_mode
    subsample = node.op.subsample
    filter_dilation = node.op.filter_dilation
    num_groups = node.op.num_groups
    precision, _ = get_precision(None, [inp1, inp2])

    if node.op.filter_flip:
        conv_mode = "conv"
    else:
        conv_mode = "cross"

    if isinstance(op, AbstractConv2d):
        if border_mode == "half" or subsample != (1, 1) or num_groups != 1:
            return None
        if border_mode == "full":
            direction_hint = "bprop inputs"
        elif border_mode == "valid" and filter_dilation == (1, 1):
            direction_hint = "bprop weights"
        else:
            return None

        rval = dnn_conv(
            inp1,
            inp2,
            border_mode=border_mode,
            subsample=subsample,
            dilation=filter_dilation,
            direction_hint=direction_hint,
            conv_mode=conv_mode,
            num_groups=num_groups,
        )

    elif isinstance(op, AbstractConv2d_gradWeights):
        if (border_mode == "valid" and subsample == (1, 1)
                and filter_dilation == (1, 1) and num_groups == 1):
            img = gpu_contiguous(inp1)
            topgrad = gpu_contiguous(inp2)
            ctx_name = infer_context_name(img, topgrad)
            img = gpu_contiguous(img.dimshuffle(1, 0, 2, 3))
            topgrad = gpu_contiguous(topgrad.dimshuffle(1, 0, 2, 3))
            ishape = [shape_i_op(i)(img) for i in range(img.ndim)]
            tshape = [shape_i_op(i)(topgrad) for i in range(topgrad.ndim)]
            out_shp = get_conv_output_shape(
                ishape,
                tshape,
                border_mode=border_mode,
                subsample=subsample,
                filter_dilation=filter_dilation,
            )

            out_shp = assert_conv_shape(out_shp)
            out = GpuAllocEmpty(dtype=img.dtype,
                                context_name=ctx_name)(*out_shp)
            desc = GpuDnnConvDesc(
                border_mode=border_mode,
                subsample=subsample,
                dilation=filter_dilation,
                conv_mode="cross",
                precision=precision,
            )(out.shape)

            conv = GpuDnnConv(algo=None, num_groups=num_groups)(img, topgrad,
                                                                out, desc)
            if conv_mode == "conv":
                conv = conv[:, :, ::-1, ::-1]

            rval = as_gpuarray_variable(conv.dimshuffle(1, 0, 2, 3), ctx_name)
        else:
            return None

    elif isinstance(op, AbstractConv2d_gradInputs):
        if border_mode == "valid" and subsample == (1, 1) and num_groups == 1:
            kerns = gpu_contiguous(inp1.dimshuffle(1, 0, 2, 3))
            topgrad = gpu_contiguous(inp2)
            ctx_name = infer_context_name(kerns, topgrad)
            conv_mode = "cross" if conv_mode == "conv" else "conv"
            desc = GpuDnnConvDesc(
                border_mode="full",
                subsample=subsample,
                dilation=filter_dilation,
                conv_mode=conv_mode,
                precision=precision,
            )(kerns.shape)

            tshape = [shape_i_op(i)(topgrad) for i in range(topgrad.ndim)]
            kshape = [shape_i_op(i)(kerns) for i in range(kerns.ndim)]
            shape = get_conv_output_shape(
                tshape,
                kshape,
                border_mode="full",
                subsample=subsample,
                filter_dilation=filter_dilation,
            )

            shape = assert_conv_shape(shape)
            out = GpuAllocEmpty(dtype=topgrad.dtype,
                                context_name=ctx_name)(*shape)
            rval = GpuDnnConv(algo=None, num_groups=num_groups)(topgrad, kerns,
                                                                out, desc)
        else:
            return None

    return [rval]
コード例 #4
0
 def array_like_conv_output(self, inputs_shape, filters_shape, border_mode, subsample, dilation, dtype):
     # Return a random array with inferred convolution output shape.
     out_shp = get_conv_output_shape(inputs_shape, filters_shape, border_mode, subsample, dilation)
     out_shp = assert_conv_shape(out_shp)
     return np.random.random(out_shp).astype(dtype)