# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License" # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from x2paddle.decoder.tf_decoder import TFGraph from x2paddle.core.op_mapper import OpMapper from x2paddle.core.util import * import inspect import numpy import sys # compute padding size for SAME mode def get_same_padding(in_size, kernel_size, stride): new_size = int(math.ceil(in_size * 1.0 / stride)) pad_size = (new_size - 1) * stride + kernel_size - in_size pad0 = int(pad_size / 2) pad1 = pad_size - pad0 return [pad0, pad1] def nhwc_dim_to_nchw(node, dim): tf_data_format = list(node.tf_data_format) pd_data_format = list(node.pd_data_format) if isinstance(dim, list): for i in range(len(dim)): char = tf_data_format[dim[i]] dim[i] = pd_data_format.index(char) else: char = tf_data_format[dim] dim = pd_data_format.index(char) return dim if dim < 0: dim += 4 if dim > 0: dim = (dim + 1) % 4 + int((dim + 1) / 4) return dim class TFOpMapper(OpMapper): directly_map_ops = { 'Relu': ['relu'], 'Relu6': ['relu6'], 'Shape': ['shape'], 'Abs': ['abs'], 'Sigmoid': ['sigmoid'], 'Exp': ['exp'], 'Rsqrt': ['rsqrt'], 'swish_f32': ['swish'], 'Tanh': ['tanh'], 'LeakyRelu': ['leaky_relu', { 'alpha': 'alpha' }] } elementwise_ops = { 'Add': 'elementwise_add', 'RealDiv': 'elementwise_div', 'Sub': 'elementwise_sub', 'Maximum': 'elementwise_max', 'Mul': 'elementwise_mul', 'FloorDiv': 'elementwise_floordiv' } def __init__(self, decoder): super(TFOpMapper, self).__init__() self.decoder = decoder self.graph = decoder.tf_graph self.batch_node = None self.weights = dict() self.omit_nodes = list() self.used_custom_layers = dict() not_placeholder = list() for name in self.graph.input_nodes: if self.graph.get_node(name).layer_type != "Placeholder": not_placeholder.append(name) for name in not_placeholder: idx = self.graph.input_nodes.index(name) del self.graph.input_nodes[idx] sys.stderr.write("Total nodes: {}\n".format(len(self.graph.topo_sort))) unsupported_ops = set() for i, node_name in enumerate(self.graph.topo_sort): sys.stderr.write("\rConverting node {} ... ".format(i + 1)) node = self.graph.get_node(node_name) op = node.layer_type if op in self.directly_map_ops: if len(unsupported_ops) > 0: continue self.directly_map(node) elif op in self.elementwise_ops: if len(unsupported_ops) > 0: continue self.elementwise_map(node) elif hasattr(self, op): if len(unsupported_ops) > 0: continue func = getattr(self, op) func(node) else: unsupported_ops.add(op) if len(unsupported_ops) > 0: sys.stderr.write( "=========={} Ops are not supported yet======\n".format( len(unsupported_ops))) for op in unsupported_ops: sys.stderr.write("========== {} ==========\n".format(op)) sys.exit(-1) sys.stderr.write('\nDone!\n') def add_omit_nodes(self, in_node_name, out_node_name): in_node = self.graph.get_node(in_node_name) out_node = self.graph.get_node(out_node_name) index = in_node.outputs.index(out_node_name) del in_node.outputs[index] index = out_node.inputs.index(in_node_name) del out_node.inputs[index] self.omit_nodes.append(in_node.layer_name) def directly_map(self, node): assert node.layer_type in self.directly_map_ops op_info = self.directly_map_ops[node.layer_type] input = self.graph.get_node(node.layer.input[0], copy=True) attr = dict() for param in op_info[1:]: tf_param_name = list(param.keys())[0] pd_param_name = list(param.values())[0] tf_param = node.get_attr(tf_param_name) attr[pd_param_name] = tf_param node.fluid_code.add_layer(op_info[0], inputs=input, output=node, param_attr=attr) def elementwise_map(self, node): assert node.layer_type in self.elementwise_ops op_type = self.elementwise_ops[node.layer_type] x = self.graph.get_node(node.layer.input[0], copy=True) y = self.graph.get_node(node.layer.input[1], copy=True) x_shape = x.out_shapes[0] y_shape = y.out_shapes[0] if len(x_shape) == 0: x_shape = [1] if len(y_shape) == 0: y_shape = [1] # incomplement broadcasting support for paddle x_input = x y_input = y if len(x_shape) < len(y_shape): unrevertable_ops = [ "elementwise_sub", "elementwise_div", "elementwise_floordiv", "elementwise_mod", "elementwise_pow" ] if op_type not in unrevertable_ops: x_input = y y_input = x x_shape = y.out_shapes[0] y_shape = x.out_shapes[0] else: raise Exception("Unexpected situation happend") if len(x_shape) == 4 and len(y_shape) == 1: if x_input.tf_data_format == "NHWC": axis = 1 else: axis = -1 attr = {"axis": axis} inputs = {"x": x_input, "y": y_input} node.fluid_code.add_layer(op_type, inputs=inputs, output=node, param_attr=attr) return is_sub_seq = True for i in range(len(y_shape)): index = -1 * i - 1 if y_shape[index] != x_shape[index]: is_sub_seq = False if not is_sub_seq: if x_shape.count(-1) > 2: x_shape = self.decoder.infer_tensor_shape(x_input) if y_shape.count(-1) > 2: y_shape = self.decoder.infer_tensor_shape(y_input) x_expand_times = [1] * len(x_shape) y_expand_times = [1] * len(y_shape) x_need_expand = False y_need_expand = False for i in range(len(y_shape)): index = -1 * i - 1 if y_shape[index] != x_shape[index]: if y_shape[index] == 1: y_expand_times[index] = x_shape[index] y_need_expand = True elif x_shape[index] == 1: x_expand_times[index] = y_shape[index] x_need_expand = True else: raise Exception("Unexpected situation happend") if x_need_expand: if len(x_expand_times) == 3 and x.tf_data_format == "NHWC": x_expand_times = [x_expand_times[i] for i in [2, 0, 1]] if len(x_expand_times) == 4 and x.tf_data_format == "NHWC": x_expand_times = [x_expand_times[i] for i in [0, 3, 1, 2]] attr = {"expand_times": x_expand_times} node.fluid_code.add_layer("expand", inputs=x_input, output="x_tmp", param_attr=attr) x_input = "x_tmp" if y_need_expand: if len(y_expand_times) == 3 and y.tf_data_format == "NHWC": y_expand_times = [y_expand_times[i] for i in [2, 0, 1]] if len(y_expand_times) == 4 and y.tf_data_format == "NHWC": y_expand_times = [y_expand_times[i] for i in [0, 3, 1, 2]] attr = {"expand_times": y_expand_times} node.fluid_code.add_layer("expand", inputs=y_input, output="y_tmp", param_attr=attr) y_input = "y_tmp" inputs = {"x": x_input, "y": y_input} node.fluid_code.add_layer(op_type, inputs=inputs, output=node, param_attr=None) def Placeholder(self, node): shape = node.out_shapes[0] assert len(shape) != 0, "Unknown shape of input nodes[{}].".format( node.layer_name) if node.tf_data_format == "NHWC" and len(shape) == 4: shape = [shape[i] for i in [0, 3, 1, 2]] elif node.tf_data_format == "NCHW" and len(shape) == 4: self.graph.data_format_propagation(node) dtype = node.dtype attr = { 'dtype': string(dtype), 'shape': shape, 'name': string(node.layer_name), 'append_batch_size': False } if shape[0] < 0: self.batch_node = node node.fluid_code.add_layer("data", inputs=None, output=node, param_attr=attr) def Const(self, node): shape = node.out_shapes[0] dtype = node.dtype value = node.value initializer = "Constant(0.0)" if len(shape) == 0: assert value.size == 1, "Unexpected situation happend" shape = [1] initializer = "Constant({})".format(value) self.weights[node.layer_name] = node.value if node.tf_data_format == "NHWC": if len(shape) == 4: shape = [shape[i] for i in [0, 3, 1, 2]] if len(shape) == 3: shape = [shape[i] for i in [2, 0, 1]] self.weights[node.layer_name] = numpy.transpose( node.value, (2, 0, 1)) elif node.tf_data_format == "NCHW": if len(shape) == 4: self.graph.data_format_propagation(node) attr = { 'dtype': string(dtype), 'shape': shape, 'name': string(node.layer_name), 'default_initializer': initializer } node.fluid_code.add_layer("create_parameter", inputs=None, output=node, param_attr=attr) def Transpose(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) perm = self.graph.get_node(node.layer.input[1], copy=True) assert perm.layer_type == "Const", "Perm of transpose OP should be Const" del self.weights[perm.layer_name.replace('/', '_')] perm.fluid_code.clear() perm = perm.value.tolist() if perm == [0, 3, 1, 2] and input.data_format == "NHWC": input_name = input.layer_name if hasattr(input, "index"): input_name = input_name + "[{}]".format(input.index) node.fluid_code.add_layer("{} = {}").format(node.layer_name, input_name) node.tf_data_format = "NCHW" self.graph.data_format_propagation(node) elif perm == [0, 2, 3, 1] and input.tf_data_format == "NCHW": input_name = input.layer_name if hasattr(input, "index"): input_name = input_name + "[{}]".format(input.index) node.fluid_code.add_layer("{} = {}").format(node.layer_name, input_name) node.tf_data_format = "NHWC" self.graph.data_format_propagation(node) elif len(input.out_shapes[0]) > 4: tf_data_format = list(input.tf_data_format) pd_data_format = list(input.pd_data_format) new_perm = [i for i in range(len(perm))] for i in range(len(perm)): char0 = tf_data_format[i] char1 = tf_data_format[perm[i]] index0 = pd_data_format.index(char0) index1 = pd_data_format.index(char1) new_perm[index0] = index1 node.tf_data_format = [tf_data_format[i] for i in perm] node.pd_data_format = [pd_data_format[i] for i in perm] attr = {'perm': new_perm} node.fluid_code.add_layer("transpose", inputs=input, output=node, param_attr=attr) elif len(node.out_shapes[0]) != 4: attr = {'perm': perm} node.fluid_code.add_layer("transpose", inputs=input, output=node, param_attr=attr) else: raise Exception("Unexpected situation happend in Transpose OP") def MaxPool(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) in_shape = input.out_shapes[0] if in_shape.count(-1) > 2: in_shape = self.decoder.infer_tensor(input).shape k_size = node.get_attr("ksize") strides = node.get_attr("strides") data_format = node.get_attr("data_format").decode() pad_mode = node.get_attr("padding").decode() channel_first = data_format == "NCHW" padding = 0 if not channel_first: in_shape = [in_shape[i] for i in [0, 3, 1, 2]] strides = [strides[i] for i in [0, 3, 1, 2]] k_size = [k_size[i] for i in [0, 3, 1, 2]] else: self.graph.data_format_propagation(node) if pad_mode == "SAME": pad_h = get_same_padding(in_shape[2], k_size[2], strides[2]) pad_w = get_same_padding(in_shape[3], k_size[3], strides[3]) pad_h = pad_h[0] + pad_h[1] pad_w = pad_w[0] + pad_w[1] attr = {"paddings": [0, pad_h, 0, pad_w], "pad_value": -10000.0} node.fluid_code.add_layer("pad2d", inputs=input, output=node, param_attr=attr) input = node attr = { "pool_size": k_size[2:4], "pool_type": string("max"), "pool_padding": padding, "pool_stride": strides[2:4] } node.fluid_code.add_layer("pool2d", inputs=input, output=node, param_attr=attr) def Conv2D(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) kernel = self.graph.get_node(node.layer.input[1], copy=True) assert kernel.layer_type == "Const", "Kernel of Conv2D should be Const" self.add_omit_nodes(kernel.layer_name, node.layer_name) in_shape = input.out_shapes[0] if in_shape.count(-1) > 2: in_shape = self.decoder.infer_tensor(input).shape k_size = kernel.out_shapes[0] if k_size.count(-1) > 2: k_size = self.decoder.infer_tensor(kernel).shape strides = node.get_attr("strides") dilations = node.get_attr("dilations") data_format = node.get_attr("data_format").decode() pad_mode = node.get_attr("padding").decode() channel_first = data_format == "NCHW" padding = 0 self.weights[kernel.layer_name.replace('/', '_')] = numpy.transpose( kernel.value, (3, 2, 0, 1)) if not channel_first: in_shape = [in_shape[i] for i in [0, 3, 1, 2]] strides = [strides[i] for i in [0, 3, 1, 2]] dilations = [dilations[i] for i in [0, 3, 1, 2]] else: self.graph.data_format_propagation(node) if pad_mode == "SAME": pad_h = get_same_padding(in_shape[2], k_size[0], strides[2]) pad_w = get_same_padding(in_shape[3], k_size[1], strides[3]) if pad_h[0] == pad_h[1] and pad_w[0] == pad_w[1]: padding = [pad_h[0], pad_w[0]] else: attr = {"paddings": pad_h + pad_w, "pad_value": 0.0} node.fluid_code.add_layer("pad2d", inputs=input, output=node, param_attr=attr) input = node attr = { "bias_attr": False, "param_attr": string(kernel.layer_name), "num_filters": k_size[3], "filter_size": k_size[0:2], "stride": strides[2:4], "dilation": dilations[2:4], "padding": padding } node.fluid_code.add_layer("conv2d", inputs=input, output=node, param_attr=attr) def BiasAdd(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) bias = self.graph.get_node(node.layer.input[1], copy=True) axis = -1 if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: axis = 1 inputs = {"x": input, "y": bias} attr = {"axis": axis} node.fluid_code.add_layer("elementwise_add", inputs=inputs, output=node, param_attr=attr) def FusedBatchNorm(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) gamma = self.graph.get_node(node.layer.input[1], copy=True) beta = self.graph.get_node(node.layer.input[2], copy=True) moving_mean = self.graph.get_node(node.layer.input[3], copy=True) moving_var = self.graph.get_node(node.layer.input[4], copy=True) data_format = node.get_attr("data_format").decode() channel_first = data_format == "NCHW" assert gamma.layer_type == "Const" assert beta.layer_type == "Const" assert moving_mean.layer_type == "Const" assert moving_var.layer_type == "Const" self.add_omit_nodes(gamma.layer_name, node.layer_name) self.add_omit_nodes(beta.layer_name, node.layer_name) self.add_omit_nodes(moving_mean.layer_name, node.layer_name) self.add_omit_nodes(moving_var.layer_name, node.layer_name) if channel_first: self.data_format_propagation(node) attr = { "epsilon": node.get_attr("epsilon"), "param_attr": string(gamma.layer_name), "bias_attr": string(beta.layer_name), "moving_mean_name": string(moving_mean.layer_name), "moving_variance_name": string(moving_var.layer_name), "is_test": True } node.fluid_code.add_layer("batch_norm", inputs=input, output=node, param_attr=attr) def DepthwiseConv2dNative(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) kernel = self.graph.get_node(node.layer.input[1], copy=True) assert kernel.layer_type == "Const", "Kernel of DepthwiseConv2DNative should be Const" self.add_omit_nodes(kernel.layer_name, node.layer_name) in_shape = input.out_shapes[0] if in_shape.count(-1) > 2: in_shape = self.decoder.infer_tensor(input).shape k_size = kernel.out_shapes[0] if k_size.count(-1) > 2: k_size = self.decoder.infer_tensor(kernel).shape strides = node.get_attr("strides") dilations = node.get_attr("dilations") data_format = node.get_attr("data_format").decode() pad_mode = node.get_attr("padding").decode() channel_first = data_format == "NCHW" padding = 0 self.weights[kernel.layer_name.replace('/', '_')] = numpy.transpose( kernel.value, (2, 3, 0, 1)) if not channel_first: in_shape = [in_shape[i] for i in [0, 3, 1, 2]] strides = [strides[i] for i in [0, 3, 1, 2]] dilations = [dilations[i] for i in [0, 3, 1, 2]] else: self.data_format_propagation(node) if pad_mode == "SAME": pad_h = get_same_padding(in_shape[2], k_size[0], strides[2]) pad_w = get_same_padding(in_shape[3], k_size[1], strides[3]) if pad_h[0] == pad_h[1] and pad_w[0] == pad_w[1]: padding = [pad_h[0], pad_w[0]] else: attr = {"paddings": pad_h + pad_w, "pad_value": 0.0} node.fluid_code.add_layer("pad2d", inputs=input, output=node, param_attr=attr) input = node attr = { "bias_attr": False, "param_attr": string(kernel.layer_name), "num_filters": in_shape[1], "filter_size": k_size[0:2], "stride": strides[2:4], "dilation": dilations[2:4], "groups": k_size[3] * in_shape[1], "use_cudnn": False, "padding": padding } node.fluid_code.add_layer("conv2d", inputs=input, output=node, param_attr=attr) def Reshape(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) param = self.graph.get_node(node.layer.input[1], copy=True) if param.layer_type == "Const": attr = {"shape": param.value.tolist()} self.add_omit_nodes(param.layer_name, node.layer_name) else: # Here is a trick method to solove tensor parameter in tensorflow shape = self.decoder.infer_shape_tensor(param, node.out_shapes[0]) if shape.count(-1) <= 1: attr = {"shape": shape} self.add_omit_nodes(param.layer_name, node.layer_name) elif shape.count(-1) == 2 and shape[0] == -1: shape[0] = 0 attr = {"shape": shape} self.add_omit_nodes(param.layer_name, node.layer_name) else: assert len(param.out_shapes[0] ) == 1, "Unexpected situation of shape parameter" attr = {"shape": [-1]} node.fluid_code.add_layer("reshape", inputs=param, output="shape_param", param_attr=attr) attr = {"num_or_sections": param.out_shapes[0][0], "dim": 0} node.fluid_code.add_layer("split", inputs="shape_param", output=node, param_attr=attr) new_param = "[" for i in range(param.out_shapes[0][0]): new_param += (node.layer_name + "[{}]".format(i) + ", ") new_param = new_param.strip(", ") + "]" attr = {"shape": new_param} if len(input.out_shapes[0]) == 4 and node.tf_data_format == "NHWC": if len(attr["shape"]) < 3: perm = {"perm": [0, 2, 3, 1]} node.fluid_code.add_layer("transpose", inputs=input, output=node, param_attr=perm) node.fluid_code.add_layer("reshape", inputs=node, output=node, param_attr=attr) return if len(attr["shape"]) == 4 and node.tf_data_format == "NHWC": input_shape = self.decoder.infer_tensor(input).shape if input_shape[1] == attr["shape"][1]: attr["shape"] = [attr["shape"][i] for i in [0, 3, 1, 2]] else: perm = {"perm": [0, 2, 3, 1]} node.fluid_code.add_layer("transpose", inputs=input, output=node, param_attr=perm) node.fluid_code.add_layer("reshape", inputs=node, output=node, param_attr=attr) perm = {"perm": [0, 3, 1, 2]} node.fluid_code.add_layer("transpose", inputs=node, output=node, param_attr=perm) return node.fluid_code.add_layer("reshape", inputs=input, output=node, param_attr=attr) def AvgPool(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) in_shape = input.out_shapes[0] if in_shape.count(-1) > 2: in_shape = self.decoder.infer_tensor(input).shape k_size = node.get_attr("ksize") strides = node.get_attr("strides") data_format = node.get_attr("data_format").decode() pad_mode = node.get_attr("padding").decode() channel_first = data_format == "NCHW" if not channel_first: in_shape = [in_shape[i] for i in [0, 3, 1, 2]] strides = [strides[i] for i in [0, 3, 1, 2]] k_size = [k_size[i] for i in [0, 3, 1, 2]] else: self.graph.data_format_propagation(node) attr = { "pool_size": k_size[2:4], "pool_type": string("avg"), "pool_stride": strides[2:4] } if pad_mode == "SAME": pad_h = get_same_padding(in_shape[2], k_size[2], strides[2]) pad_w = get_same_padding(in_shape[3], k_size[3], strides[3]) assert pad_h[0] == pad_h[1] and pad_w[0] == pad_w[ 1], "Cannot map AvgPool" attr["pool_padding"] = [pad_h[0], pad_w[0]] node.fluid_code.add_layer("pool2d", inputs=input, output=node, param_attr=attr) def SplitV(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) num_sections = self.graph.get_node(node.layer.input[1], copy=True) dim = self.graph.get_node(node.layer.input[2], copy=True) assert num_sections.layer_type == "Const" assert dim.layer_type == "Const" self.add_omit_nodes(num_sections.layer_name, node.layer_name) self.add_omit_nodes(dim.layer_name, node.layer_name) dim = dim.value if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: dim = nhwc_dim_to_nchw(input, dim) attr = { "num_or_sections": num_sections.value.tolist(), "dim": dim.value } node.fluid_code.add_layer("split", inputs=input, output=node, param_attr=attr) def ConcatV2(self, node): inputs = [ self.graph.get_node(name, copy=True) for name in node.layer.input[:-1] ] axis = self.graph.get_node(node.layer.input[-1], copy=True) assert axis.layer_type == "Const" self.add_omit_nodes(axis.layer_name, node.layer_name) axis = axis.value if inputs[0].tf_data_format == "NHWC" and len( inputs[0].out_shapes[0]) == 4: axis = nhwc_dim_to_nchw(inputs[0], axis) attr = {"axis": axis} node.fluid_code.add_layer("concat", inputs=inputs, output=node, param_attr=attr) def Tile(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) expand_times = self.graph.get_node(node.layer.input[1], copy=True) self.add_omit_nodes(expand_times.layer_name, node.layer_name) if expand_times.layer_type == "Const": expand_times = expand_times.value.tolist() else: expand_times = self.decoder.infer_shape_tensor(expand_times) if input.tf_data_format == "NHWC": if len(input.out_shapes[0]) == 4: expand_times = [expand_times[i] for i in [0, 3, 1, 2]] elif len(input.out_shape[0]) == 3: expand_times = [expand_times[i] for i in [2, 0, 1]] for i in range(len(expand_times)): if expand_times[i] < 0: expand_times[i] = 1 attr = {"expand_times": expand_times} node.fluid_code.add_layer("expand", inputs=input, output=node, param_attr=attr) def Pack(self, node): inputs = [ self.graph.get_node(name, copy=True) for name in node.layer.input ] axis = node.get_attr("axis") if inputs[0].tf_data_format == "NHWC" and len( inputs[0].out_shapes[0]) == 4: tf_data_format = list(inputs[0].tf_data_format) tf_data_format.insert(axis, str(len(tf_data_format))) axis = nhwc_dim_to_nchw(inputs[0], axis) pd_data_format = list(inputs[0].pd_data_format) pd_data_format.insert(axis, str(len(pd_data_format))) node.tf_data_format = "".join(tf_data_format) node.pd_data_format = "".join(pd_data_format) attr = {"axis": axis} node.fluid_code.add_layer("stack", inputs=inputs, output=node, param_attr=attr) def Pad(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) paddings = self.graph.get_node(node.layer.input[1], copy=True) assert paddings.layer_type == "Const", "Padding should be Const" self.add_omit_nodes(paddings.layer_name, node.layer_name) paddings = paddings.value.flatten().tolist() if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: paddings = [paddings[i] for i in [0, 1, 6, 7, 2, 3, 4, 5]] pad_op = "pad" if len(input.out_shapes[0]) == 4: if paddings[0] + paddings[1] + paddings[2] + paddings[3] == 0: paddings = paddings[4:] pad_op = "pad2d" attr = {"paddings": paddings} node.fluid_code.add_layer(pad_op, inputs=input, output=node, param_attr=attr) def Range(self, node): start = self.graph.get_node(node.layer.input[0], copy=True) limit = self.graph.get_node(node.layer.input[1], copy=True) delta = self.graph.get_node(node.layer.input[2], copy=True) if start.layer_type == "Const": start = start.value else: start = self.decoder.infer_tensor(start) if limit.layer_type == "Const": limit = limit.value else: limit = self.decoder.infer_tensor(limit) if delta.layer_type == "Const": delta = delta.value else: delta = self.decoder.infer_tensor(delta) self.add_omit_nodes(start.layer_name, node.layer_name) self.add_omit_nodes(limit.layer_name, node.layer_name) self.add_omit_nodes(delta.layer_name, node.layer_name) inputs = {"start": start, "end": limit, "step": delta} attr = {"dtype": string(node.dtype)} node.fluid_code.add_layer("range", inputs=inputs, output=node, param_attr=None) def Mean(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) reduce_idx = self.graph.get_node(node.layer.input[1], copy=True) assert reduce_idx.layer_type == "Const", "Only support Const parameter[reduce_idx]" dims = reduce_idx.value.tolist() keep_dims = node.get_attr("keep_dims") if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: for i in range(len(dims)): dims[i] = nhwc_dim_to_nchw(input, dims[i]) attr = {"dim": dims, "keep_dim": keep_dims} node.fluid_code.add_layer("reduce_mean", inputs=input, output=node, param_attr=attr) def MatMul(self, node): x = self.graph.get_node(node.layer.input[0], copy=True) y = self.graph.get_node(node.layer.input[1], copy=True) transpose_a = node.get_attr('transpose_a') transpose_b = node.get_attr('transpose_b') inputs = {"x": x, "y": y} # fix paddle shape infer problem # should be removed after paddle 1.6 if x.out_shapes[0][-1] < 0 and y.out_shapes[0][0] > 0: shape = x.out_shapes[0] shape[-1] = y.out_shapes[0][0] attr = {"shape": shape} node.fluid_code.add_layer("reshape", inputs=x, output=x, param_attr=attr) attr = {"transpose_x": transpose_a, "transpose_y": transpose_b} node.fluid_code.add_layer("matmul", inputs=inputs, output=node, param_attr=attr) def ArgMax(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) axis = self.graph.get_node(node.layer.input[1], copy=True) assert axis.layer_type == "Const", "ArgMax only support Const parameter" self.add_omit_nodes(axis.layer_name, node.layer_name) axis = axis.value if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: axis = nhwc_dim_to_nchw(input, axis) attr = {"axis": axis} node.fluid_code.add_layer("argmax", inputs=input, output=node, param_attr=attr) def StridedSlice(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) begin = self.graph.get_node(node.layer.input[1], copy=True) end = self.graph.get_node(node.layer.input[2], copy=True) strides = self.graph.get_node(node.layer.input[3], copy=True) assert begin.layer_type == "Const" assert end.layer_type == "Const" assert strides.layer_type == "Const" self.add_omit_nodes(begin.layer_name, node.layer_name) self.add_omit_nodes(end.layer_name, node.layer_name) self.add_omit_nodes(strides.layer_name, node.layer_name) strides = strides.value.tolist() assert len(set(strides)) == 1 and strides[0] == 1 begin = begin.value.tolist() end = end.value.tolist() if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: begin = [begin[i] for i in [0, 3, 1, 2]] end = [end[i] for i in [0, 3, 1, 2]] for i in range(len(end)): if end[i] == 0: end[i] = 999999 attr = { "axes": [i for i in range(len(strides))], "starts": begin, "ends": end } node.fluid_code.add_layer("slice", inputs=input, output=node, param_attr=attr) def Slice(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) begin = self.graph.get_node(node.layer.input[1], copy=True) size = self.graph.get_node(node.layer.input[2], copy=True) self.add_omit_nodes(begin.layer_name, node.layer_name) self.add_omit_nodes(size.layer_name, node.layer_name) if begin.layer_type == "Const": begin = begin.value.tolist() else: begin = self.decoder.infer_tensor(begin).tolist() if size.layer_type == "const": size = size.value.tolist() else: size = self.decoder.infer_tensor(size).tolist() if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: size = [size[i] for i in [0, 3, 1, 2]] begin = [begin[i] for i in [0, 3, 1, 2]] for i in range(len(size)): if size[i] < 0: size[i] = 99999999 else: size[i] = size[i] + begin[i] attr = { "axes": [i for i in range(len(size))], "starts": begin, "ends": size } node.fluid_code.add_layer("slice", inputs=input, output=node, param_attr=attr) def Conv2DBackpropInput(self, node): out_shape = self.graph.get_node(node.layer.input[0], copy=True) kernel = self.graph.get_node(node.layer.input[1], copy=True) input = self.graph.get_node(node.layer.input[2], copy=True) assert kernel.layer_type == "Const", "Kernel of Conv2DBackpropInput should be Const" self.add_omit_nodes(kernel.layer_name, node.layer_name) self.add_omit_nodes(out_shape.layer_name, node.layer_name) if out_shape.layer_type == "Const": out_shape = out_shape.value.tolist() else: out_shape = self.decoder.infer_shape_tensor(out_shape, node.out_shapes[0]) in_shape = input.out_shapes[0] if in_shape.count(-1) > 2: in_shape = self.decoder.infer_tensor(input).shape k_size = kernel.out_shapes[0] if k_size.count(-1) > 2: k_size = self.decoder.infer_tensor(kernel).shape pad_mode = node.get_attr("padding").decode() strides = node.get_attr("strides") dilations = node.get_attr("dilations") data_format = node.get_attr("data_format").decode() channel_first = data_format == "NCHW" self.weights[kernel.layer_name.replace('/', '_')] = numpy.transpose( kernel.value, (3, 2, 0, 1)) if not channel_first: in_shape = [in_shape[i] for i in [0, 3, 1, 2]] strides = [strides[i] for i in [0, 3, 1, 2]] dilations = [dilations[i] for i in [0, 3, 1, 2]] else: self.data_format_propagation(node) padding = 0 if pad_mode == "SAME": pad_h = get_same_padding(in_shape[2], k_size[0], strides[2]) pad_w = get_same_padding(in_shape[3], k_size[1], strides[3]) if pad_h[0] == pad_h[1] and pad_w[0] == pad_w[1]: padding = [pad_h[0], pad_w[0]] else: attr = {"paddings": pad_h + pad_w, "pad_value": 0.0} node.fluid_code.add_layer("pad2d", inputs=input, output=node, param_attr=attr) input = node attr = { "bias_attr": False, "param_attr": string(kernel.layer_name), "num_filters": k_size[3], "filter_size": k_size[0:2], "stride": strides[2:4], "dilation": dilations[2:4], "padding": padding } node.fluid_code.add_layer("conv2d_transpose", inputs=input, output=node, param_attr=attr) if pad_mode == "SAME": if node.tf_data_format == "NHWC": out_shape = [out_shape[i] for i in [0, 3, 1, 2]] for i in range(4): if out_shape[i] < 0: out_shape[i] = 999999 attr = { "axes": [0, 1, 2, 3], "starts": [0, 0, 0, 0], "ends": out_shape } node.fluid_code.add_layer("slice", inputs=node, output=node, param_attr=attr) def Max(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) reduce_idx = self.graph.get_node(node.layer.input[1], copy=True) assert reduce_idx.layer_type == "Const", "Only support Const parameter[reduce_idx]" keep_dims = node.get_attr("keep_dims") dim = reduce_idx.value.tolist() if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: dim = nhwc_dim_to_nchw(input, dim) attr = {"dim": dim, "keep_dim": keep_dims} node.fluid_code.add_layer("reduce_max", inputs=input, output=node, param_attr=attr) def Sum(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) reduce_idx = self.graph.get_node(node.layer.input[1], copy=True) assert reduce_idx.layer_type == "Const", "Only support Const parameter[reduce_idx]" keep_dims = node.get_attr("keep_dims") dim = reduce_idx.value.tolist() if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: dim = nhwc_dim_to_nchw(input, dim) attr = {"dim": dim, "keep_dim": keep_dims} node.fluid_code.add_layer("reduce_sum", inputs=input, output=node, param_attr=attr) def Cast(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) dtype = node.dtype_map[node.get_attr('DstT')] attr = {"dtype": string(dtype)} node.fluid_code.add_layer("cast", inputs=input, output=node, param_attr=attr) def Split(self, node): dim = self.graph.get_node(node.layer.input[0], copy=True) input = self.graph.get_node(node.layer.input[1], copy=True) self.add_omit_nodes(dim.layer_name, node.layer_name) num_split = node.get_attr('num_split') dim = dim.value if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: dim = nhwc_dim_to_nchw(input, dim) attr = {"num_or_sections": num_split, "dim": dim} node.fluid_code.add_layer("split", inputs=input, output=node, param_attr=attr) def Squeeze(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) squeeze_dims = node.get_attr('squeeze_dims') if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: for i in range(len(squeeze_dims)): squeeze_dims[i] = nhwc_dim_to_nchw(input, squeeze_dims[i]) attr = {"axes": squeeze_dims} node.fluid_code.add_layer("squeeze", inputs=input, output=node, param_attr=attr) def Softmax(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) axis = node.get_attr("axis") if axis is None: axis = -1 + len(input.out_shapes[0]) if input.tf_data_format == "NHWC" and len(input.out_shapes[0]) == 4: axis = nhwc_dim_to_nchw(input, axis) attr = {"axis": axis} node.fluid_code.add_layer("softmax", inputs=input, output=node, param_attr=attr) def ResizeNearestNeighbor(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) resize_shape = self.graph.get_node(node.layer.input[1], copy=True) self.add_omit_nodes(resize_shape.layer_name, node.layer_name) if resize_shape.layer_type == "Const": resize_shape = resize_shape.value.tolist() else: resize_shape = self.decoder.infer_shape_tensor(resize_shape) align_corners = node.get_attr("align_corners") attr = {"align_corners": align_corners, "out_shape": resize_shape} node.fluid_code.add_layer("resize_nearest", inputs=input, output=node, param_attr=attr) def ResizeBilinear(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) resize_shape = self.graph.get_node(node.layer.input[1], copy=True) self.add_omit_nodes(resize_shape.layer_name, node.layer_name) if resize_shape.layer_type == "Const": resize_shape = resize_shape.value.tolist() else: resize_shape = self.decoder.infer_shape_tensor(resize_shape) align_corners = node.get_attr("align_corners") attr = { "align_corners": align_corners, "out_shape": resize_shape, "align_mode": 1 } node.fluid_code.add_layer("resize_bilinear", inputs=input, output=node, param_attr=attr) def ResizeNearestNeighbor(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) resize_shape = self.graph.get_node(node.layer.input[1], copy=True) self.add_omit_nodes(resize_shape.layer_name, node.layer_name) if resize_shape.layer_type == "Const": resize_shape = resize_shape.value.tolist() else: resize_shape = self.decoder.infer_shape_tensor( resize_shape, node.out_shapes[0]) align_corners = node.get_attr("align_corners") attr = {"align_corners": align_corners, "out_shape": resize_shape} node.fluid_code.add_layer("resize_nearest", inputs=input, output=node, param_attr=attr) def ResizeBilinear(self, node): input = self.graph.get_node(node.layer.input[0], copy=True) resize_shape = self.graph.get_node(node.layer.input[1], copy=True) self.add_omit_nodes(resize_shape.layer_name, node.layer_name) if resize_shape.layer_type == "Const": resize_shape = resize_shape.value.tolist() else: resize_shape = self.decoder.infer_shape_tensor( resize_shape, node.out_shapes[0]) align_corners = node.get_attr("align_corners") attr = { "align_corners": align_corners, "out_shape": resize_shape, "align_mode": 1 } node.fluid_code.add_layer("resize_bilinear", inputs=input, output=node, param_attr=attr) def GreaterEqual(self, node): x = self.graph.get_node(node.layer.input[0], copy=True) y = self.graph.get_node(node.layer.input[1], copy=True) inputs = {"x": x, "y": y} node.fluid_code.add_layer("greater_equal", inputs=inputs, output=node, param_attr=None) def RandomUniform(self, node): shape = self.graph.get_node(node.layer.input[0], copy=True) self.add_omit_nodes(shape.layer_name, node.layer_name) if shape.layer_type == "Const": shape = shape.value.tolist() else: shape = self.decoder.infer_shape_tensor(shape) if node.tf_data_format == "NHWC" and len(shape) == 4: shape = [shape[i] for i in [0, 3, 1, 2]] attr = {"shape": shape, "min": 0.0, "max": 0.9999} if shape[0] < 0: input = self.batch_node node.fluid_code.add_layer("uniform_random_batch_size_like", inputs=input, output=node, param_attr=attr) else: node.fluid_code.add_layer("uniform_random", inputs=None, output=node, param_attr=attr) def GreaterEqual(self, node): x = self.graph.get_node(node.layer.input[0], copy=True) y = self.graph.get_node(node.layer.input[1], copy=True) inputs = {"x": x, "y": y} node.fluid_code.add_layer("greater_equal", inputs=inputs, output=node, param_attr=None) def RandomUniform(self, node): shape = self.graph.get_node(node.layer.input[0], copy=True) self.add_omit_nodes(shape.layer_name, node.layer_name) if shape.layer_type == "Const": shape = shape.value.tolist() else: shape = self.decoder.infer_shape_tensor(shape) if len(shape) == 4 and node.tf_data_format == "NHWC": shape = [shape[i] for i in [0, 3, 1, 2]] attr = {"shape": shape, "min": 0.0, "max": 0.9999} if shape[0] < 0: input = self.batch_node node.fluid_code.add_layer("uniform_random_batch_size_like", inputs=input, output=node, param_attr=attr) else: node.fluid_code.add_layer("uniform_random", inputs=None, output=node, param_attr=attr) def SquaredDifference(self, node): x = self.graph.get_node(node.layer.input[0], copy=True) y = self.graph.get_node(node.layer.input[1], copy=True) inputs = {"x": x, "y": y} node.fluid_code.add_layer("elementwise_sub", inputs=inputs, output=node, param_attr=None) inputs = {"x": node, "y": node} node.fluid_code.add_layer("elementwise_mul", inputs=inputs, output=node, param_attr=None)