| # Copyright (C) 2020 Arm Limited or its affiliates. All rights reserved. |
| # |
| # SPDX-License-Identifier: Apache-2.0 |
| # |
| # 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 |
| # |
| # 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. |
| # Description: |
| # Early optimisation of the network graph, using the rewrite_graph module to do the traversal of the graph. These are |
| # split into two parts optimise_graph_a and optimise_graph_b. |
| import math |
| |
| import numpy as np |
| |
| from . import fp_math |
| from . import lut |
| from . import rewrite_graph |
| from . import scaling |
| from .data_type import DataType |
| from .debug_database import DebugDatabase |
| from .errors import UnsupportedFeatureError |
| from .ethos_u55_regs.ethos_u55_regs import resampling_mode |
| from .numeric_util import clamp_sigmoid |
| from .numeric_util import full_shape |
| from .numeric_util import round_away_zero |
| from .operation import create_activation_function |
| from .operation import create_avgpool_nop |
| from .operation import NpuBlockType |
| from .operation import Op |
| from .operation import Operation |
| from .softmax import SoftMax |
| from .tensor import check_quantized_tens_scaling_equal |
| from .tensor import create_const_tensor |
| from .tensor import create_reshape_tensor |
| from .tensor import QuantizationParameters |
| from .tensor import Tensor |
| |
| passthrough_nodes = set((Op.Identity,)) |
| |
| memory_only_ops = set((Op.Reshape,)) |
| |
| |
| def remove_passthrough_tensor(tens, arch, nng): |
| if len(tens.ops) == 1 and tens.ops[0].type in passthrough_nodes: |
| assert len(tens.ops[0].inputs) == 1 |
| tens = tens.ops[0].inputs[0] |
| return tens |
| |
| |
| def rewrite_concat(tens, arch, nng): |
| if len(tens.ops) == 1 and tens.ops[0].type.is_concat_op(): |
| concat_op = tens.ops[0] |
| if tens != concat_op.outputs[0]: |
| return tens # don't attempt to rewrite the min/max outputs of QuantizedConcat |
| |
| # Not supported so leave it and run on CPU |
| if not concat_op.run_on_npu: |
| return tens |
| |
| inputs, axis = concat_op.get_concat_inputs_axis() |
| |
| tens.ops = [] |
| offset = 0 |
| for idx, inp in enumerate(inputs): |
| new_op = Operation(Op.ConcatSliceWrite, concat_op.name + str(idx)) |
| new_op.inputs = [inp] |
| new_op.outputs = [tens] |
| new_op.attrs["concat_axis"] = axis |
| new_op.attrs["concat_start"] = offset |
| offset += inp.shape[axis] |
| new_op.attrs["concat_end"] = offset |
| new_op.run_on_npu = True |
| tens.ops.append(new_op) |
| DebugDatabase.add_optimised(concat_op, new_op) |
| assert tens.shape[axis] == offset |
| |
| # If axis corresponds to C-dimension, NHCWB16 can only be used in the output if all the concat_start's are a |
| # multiple of 16. This as, it is only then the address offset for the ofm, for all operations, will be 16 byte |
| # aligned. For other values of axis the address offsets will be 16 byte aligned, as they are all based on c = 0 |
| # and those addresses are always 16 byte aligned due to the NHCWB16 format. |
| if axis == -1 or axis == (len(tens.shape) - 1): |
| for op in tens.ops: |
| if op.attrs["concat_start"] % 16 != 0: |
| tens.avoid_NHCWB16 = True |
| break |
| |
| return tens |
| |
| |
| def rewrite_split(tens, arch, nng): |
| |
| if len(tens.ops) == 1 and tens.ops[0].type.is_split_op(): |
| split_op = tens.ops[0] |
| |
| # Not supported so leave it and run on CPU |
| if not split_op.run_on_npu: |
| return tens |
| |
| inp, outputs, axis, offset_start, offset_end = split_op.get_split_inputs_axis() |
| |
| tens.ops = [] |
| new_op = Operation(Op.SplitSliceRead, split_op.name) |
| new_op.inputs = [inp] |
| |
| # For Split the offset cannot be extracted from the tensor so it has to |
| # be calculated from the index of the output tensor |
| if axis is not None: |
| # Get the start and end of the split |
| offset_start = [0] * len(tens.shape) |
| offset_end = [0] * len(tens.shape) |
| for out in outputs: |
| if out == tens: |
| break |
| offset_start[axis] += out.shape[axis] |
| |
| # If start offset is not a multiple of 16 in the C-dimension, NHCWB16 need to be avoided in the input |
| if (offset_start[-1] % 16) != 0: |
| inp.avoid_NHCWB16 = True |
| |
| offset_end[axis] = offset_start[axis] + tens.shape[axis] |
| |
| new_op.attrs["split_start"] = offset_start |
| new_op.attrs["split_end"] = offset_end |
| new_op.run_on_npu = True |
| new_op.set_output_tensor(tens) |
| DebugDatabase.add_optimised(split_op, new_op) |
| |
| return tens |
| |
| |
| def needed_total_padding(input_size, stride, filter_size): |
| out_size = (input_size + stride - 1) // stride |
| needed_input = (out_size - 1) * stride + filter_size |
| total_padding = max(0, needed_input - input_size) |
| return total_padding |
| |
| |
| def calc_padding_and_skirt(padding_type, kernel_size, stride, input_dims): |
| ypad = needed_total_padding(int(input_dims[1]), int(stride[1]), int(kernel_size[0])) |
| xpad = needed_total_padding(int(input_dims[2]), int(stride[2]), int(kernel_size[1])) |
| if padding_type == b"SAME": |
| left_pad = (xpad + 0) // 2 |
| right_pad = (xpad + 1) // 2 |
| top_pad = (ypad + 0) // 2 |
| bottom_pad = (ypad + 1) // 2 |
| elif padding_type == b"VALID": |
| left_pad = 0 |
| right_pad = 0 |
| top_pad = 0 |
| bottom_pad = 0 |
| else: |
| raise UnsupportedFeatureError("Unknown padding {}".format(str(padding_type))) |
| padding = (top_pad, left_pad, bottom_pad, right_pad) |
| skirt = (top_pad, left_pad, ypad - top_pad, xpad - left_pad) |
| return padding, skirt |
| |
| |
| def calc_upscaled_padding_and_skirt(padding_type, kernel_size, stride, input_dims, upscaling_factor): |
| kernel_height, kernel_width = kernel_size[0], kernel_size[1] |
| if padding_type == b"SAME": |
| ypad = needed_total_padding(int(input_dims[1]) * upscaling_factor, int(stride[1]), int(kernel_height)) |
| xpad = needed_total_padding(int(input_dims[2]) * upscaling_factor, int(stride[2]), int(kernel_width)) |
| |
| right_pad = max(((xpad + 1) // upscaling_factor) - 1, 0) |
| bottom_pad = max(((ypad + 1) // upscaling_factor) - 1, 0) |
| left_pad = max(kernel_width - 1 - right_pad, 0) |
| top_pad = max(kernel_height - 1 - bottom_pad, 0) |
| |
| elif padding_type == b"VALID": |
| right_pad = max(kernel_width - 2, 0) |
| bottom_pad = max(kernel_height - 2, 0) |
| left_pad = kernel_width - 1 |
| top_pad = kernel_height - 1 |
| else: |
| assert 0, "Unknown padding" |
| |
| padding = (top_pad, left_pad, bottom_pad, right_pad) |
| skirt = padding |
| return padding, skirt |
| |
| |
| def fixup_conv2d_backprop(op, arch, nng): |
| if op.type == Op.Conv2DBackpropInput: |
| # flip the inputs |
| op.inputs[0], op.inputs[2] = op.inputs[2], op.inputs[0] |
| op.type = Op.Conv2DBackpropInputSwitchedBias |
| |
| # Update strides |
| op.attrs.update({"stride_w": 1, "stride_h": 1, "strides": (1, 1, 1, 1)}) |
| |
| return op |
| |
| |
| # Convert the op to an elementwise add |
| def convert_resizebilinear_1x1_to_add(op): |
| op.type = Op.Add |
| op.name = op.name + "_add" |
| op.attrs["resizebilinear"] = True |
| # Create an input tensor filled with zeros |
| shape = op.outputs[0].shape |
| tens = Tensor(shape, op.inputs[0].dtype, op.inputs[1].name + "_add") |
| tens.values = np.zeros(shape) |
| tens.quant_values = np.zeros(shape, np.uint8) |
| tens.quantization = QuantizationParameters(0.0, 255.0) |
| tens.quantization.scale_f32 = 1.0 |
| tens.quantization.zero_point = 0 |
| tens.consumer_list = [op] |
| tens_op = op.inputs[1].ops[0] |
| tens_op.set_output_tensor(tens) |
| # Set the add inputs |
| op.inputs[1] = op.inputs[0] |
| op.inputs[0] = tens |
| |
| return op |
| |
| |
| # Convert ResizeBilinear to a number of 2x2 pool ops |
| def convert_resizebilinear_to_2x2_pool(op): |
| count = 0 |
| pre_op = op |
| outputs = op.outputs |
| |
| op.attrs.update({"strides": (1, 1, 1, 1), "ksize": (1, 2, 2, 1)}) |
| if op.attrs["align_corners"]: |
| shape_modifier = 1 |
| op.attrs["padding"] = b"VALID" |
| else: |
| shape_modifier = 0 |
| op.attrs["padding"] = b"SAME" |
| op.inputs[0].resampling_mode = resampling_mode.NEAREST |
| |
| upscaled_shape = np.array(op.inputs[0].shape[1:3]) |
| out_shape = np.array(op.outputs[0].shape[1:3]) |
| if (upscaled_shape == upscaled_shape * 2 - shape_modifier).all(): |
| return op |
| |
| while (upscaled_shape < out_shape).all(): |
| if count == 0: |
| scaled_op = pre_op |
| else: |
| scaled_op = op.clone("_{}".format(count)) |
| scaled_op.inputs[0] = pre_op.outputs[0] |
| |
| upscaled_shape = upscaled_shape * 2 - shape_modifier |
| |
| if (upscaled_shape == out_shape).all(): |
| scaled_op.outputs = outputs |
| scaled_op.outputs[0].ops = [scaled_op] |
| else: |
| shape = outputs[0].shape.copy() |
| shape[1:3] = upscaled_shape[0:2] |
| out_tens = Tensor(shape, DataType.int16, "{}_{}".format(op.outputs[0].name, count)) |
| out_tens.quantization = op.outputs[0].quantization.clone() |
| out_tens.quantization.quant_min = np.iinfo(np.int16).min |
| out_tens.quantization.quant_max = np.iinfo(np.int16).max |
| scaled_op.set_output_tensor(out_tens) |
| pre_op = scaled_op |
| count += 1 |
| |
| # Setup the scale value |
| if scaled_op.inputs[0].dtype.bits == 8 and scaled_op.outputs[0].dtype.bits == 16: |
| scaled_op.attrs["rescale"] = 128 |
| elif scaled_op.inputs[0].dtype.bits == 16 and scaled_op.outputs[0].dtype.bits == 8: |
| scaled_op.attrs["rescale"] = 1 / 128 |
| elif "rescale" in scaled_op.attrs: |
| del scaled_op.attrs["rescale"] |
| |
| return op |
| |
| |
| def fixup_resizebilinear(op, arch, nng): |
| if op.type == Op.ResizeBilinear and op.run_on_npu: |
| if op.inputs[0].shape == op.outputs[0].shape: |
| # Bypass nop resizebilinear |
| op.inputs = op.inputs[:1] |
| op.type = Op.Identity |
| elif op.inputs[0].shape[1] == 1 and op.inputs[0].shape[2] == 1: |
| convert_resizebilinear_1x1_to_add(op) |
| else: |
| convert_resizebilinear_to_2x2_pool(op) |
| |
| return op |
| |
| |
| def convert_nop_split_to_identity(op, arch, nng): |
| if op.type == Op.Split and op.attrs.get("num_splits") == 1: |
| # the list comprehension should return a list with a single tensor |
| # if it shouldn't, remove_passthrough_tensor will fail appropriately |
| op.inputs = [i for i in op.inputs if i.shape == op.outputs[0].shape] |
| op.type = Op.Identity |
| return op |
| |
| |
| def fixup_fully_connected_input(op, arch, nng): |
| if op.type == Op.FullyConnected: |
| inp = op.inputs[0] |
| weights = op.inputs[1] |
| |
| n_in_elems = weights.shape[-2] |
| elms = inp.elements() |
| batch_size = elms // n_in_elems |
| assert batch_size * n_in_elems == elms |
| |
| desired_shape = [batch_size, n_in_elems] |
| if inp.shape != desired_shape: |
| # mismatch, insert a reshape to fix this. |
| op.set_input_tensor(create_reshape_tensor(inp, desired_shape), 0) |
| |
| return op |
| |
| |
| def convert_batched_fc_to_conv(op, arch, nng): |
| if op.type == Op.FullyConnected: |
| ifm = op.inputs[0] |
| ofm = op.outputs[0] |
| # Check if the FC is 2D and first dimension indicates batching |
| if len(ifm.shape) == len(ofm.shape) == 2 and ifm.shape[0] > 1: |
| n = ifm.shape[0] |
| batching_split = {4: (2, 2), 8: (2, 4), 16: (4, 4)} |
| h, w = batching_split.get(n, (1, n)) |
| |
| # Convert to convolution |
| op.name += "_conv" |
| op.type = Op.Conv2DBias |
| op.attrs = { |
| "dilation": (1, 1, 1, 1), |
| "dilation_h_factor": 1, |
| "dilation_w_factor": 1, |
| "padding": b"SAME", |
| "stride_h": 1, |
| "stride_w": 1, |
| "strides": (1, 1, 1, 1), |
| "is_converted_fc": True, |
| } |
| |
| prev_op = ifm.ops[0] |
| desired_shape = [1, h, w, ifm.shape[-1]] |
| if len(ifm.consumer_list) == 1 and prev_op is not None and prev_op.type == Op.Reshape: |
| # There is a preceding Reshape |
| # Compare input of prev_op and input of op, to see if prev_op can be removed |
| ifm_prev_op = prev_op.inputs[0] |
| if ifm_prev_op.shape == ifm.shape and check_quantized_tens_scaling_equal(ifm_prev_op, ifm): |
| # prev_op can be removed |
| op.set_input_tensor(ifm_prev_op, 0) |
| else: |
| op.inputs[0].set_all_shapes(desired_shape) |
| prev_op.set_input_tensor( |
| create_const_tensor(prev_op.inputs[1].name, [1], DataType.int32, desired_shape), 1 |
| ) |
| prev_op.attrs["new_shape"] = desired_shape |
| else: |
| # Add reshape op to the input if there is no preceding reshape |
| ifm.consumer_list.remove(op) |
| op.set_input_tensor(create_reshape_tensor(ifm, desired_shape), 0) |
| |
| # Reshape Weights to be 4D. IO becomes HWIO |
| weight_tensor = op.inputs[1] |
| weight_tensor.quant_values = np.expand_dims(np.expand_dims(weight_tensor.quant_values, axis=0), axis=0) |
| weight_tensor.set_all_shapes(list(weight_tensor.quant_values.shape)) |
| |
| desired_shape = [1, h, w, ofm.shape[-1]] |
| if ( |
| len(ofm.consumer_list) == 1 |
| and ofm.consumer_list[0] is not None |
| and ofm.consumer_list[0].type == Op.Reshape |
| ): |
| # There is a subsequent Reshape |
| # Compare desired shape and output of consumer op, to see if consumer op can be removed |
| ofm_cons_op = ofm.consumer_list[0].outputs[0] |
| if desired_shape == ofm_cons_op.shape and check_quantized_tens_scaling_equal(ofm, ofm_cons_op): |
| op.outputs[0] = ofm_cons_op |
| op.outputs[0].ops = [op] |
| else: |
| op.outputs[0].set_all_shapes(desired_shape) |
| else: |
| # Add rehape op to the output |
| op.set_output_tensor(create_reshape_tensor(ofm, desired_shape, False)) |
| return op |
| |
| |
| def fixup_pack_input(op, arch, nng): |
| if op.type == Op.Pack: |
| # Pack is also referred to as Stack |
| # Requires the rewrite_concat function to be called on the op afterwards |
| axis = int(op.attrs["axis"]) |
| desired_shape = op.inputs[0].shape[:axis] + [1] + op.inputs[0].shape[axis:] |
| |
| # Construct 1 shape tensor to be used by all inserted reshape ops |
| new_shape_tens = create_const_tensor(op.name + "_reshape_shape", [1], DataType.int32, desired_shape) |
| |
| for idx, inp in enumerate(op.inputs): |
| reshape_out = inp.clone("_reshaped") |
| reshape_out.set_all_shapes(desired_shape) |
| |
| reshape_op = Operation(Op.Reshape, "{}{}_reshape".format(op.name, idx)) |
| reshape_op.attrs["new_shape"] = desired_shape |
| reshape_op.inputs = [inp, new_shape_tens] |
| reshape_op.set_output_tensor(reshape_out) |
| DebugDatabase.add_optimised(op, reshape_op) |
| |
| op.inputs[idx] = reshape_out |
| |
| op.type = Op.PackReshaped |
| |
| return op |
| |
| |
| def unfuse_activation_function(op, arch, nng): |
| if op.type == Op.ConcatTFLite and op.run_on_npu and op.activation is not None: |
| act_op = Operation(op.activation.op_type, op.name + op.activation.op_type.name) |
| op.activation = None |
| out_tens = op.outputs[0] |
| intermediate_tens = out_tens.clone("_act_intermediate") |
| act_op.set_output_tensor(out_tens) |
| act_op.add_input_tensor(intermediate_tens) |
| op.set_output_tensor(intermediate_tens) |
| |
| return op |
| |
| |
| def fixup_stridedslice_output(tens, arch, nng): |
| op = tens.ops[0] |
| if op.run_on_npu and op.type == Op.StridedSlice: |
| reshape_input_shape = tens.shape |
| new_axis_mask = op.attrs["new_axis_mask"] |
| shrink_axis_mask = op.attrs["shrink_axis_mask"] |
| |
| if shrink_axis_mask != 0: |
| n = 0 |
| axis = 0 |
| while shrink_axis_mask: |
| prev_mask = shrink_axis_mask |
| n += 1 |
| shrink_axis_mask &= shrink_axis_mask - 1 |
| axis = int(math.log2(prev_mask - shrink_axis_mask)) |
| reshape_input_shape = reshape_input_shape[:axis] + [1] + reshape_input_shape[axis:] |
| |
| assert len(tens.shape) == (len(op.inputs[0].shape) - n) |
| op.attrs["shrink_axis_mask"] = 0 |
| elif new_axis_mask != 0: |
| n = 0 |
| axis = 0 |
| while new_axis_mask: |
| prev_mask = new_axis_mask |
| n += 1 |
| new_axis_mask &= new_axis_mask - 1 |
| axis = int(math.log2(prev_mask - new_axis_mask)) |
| reshape_input_shape = reshape_input_shape[:axis] + reshape_input_shape[(axis + 1) :] |
| new_axis_mask >>= 1 |
| |
| assert len(tens.shape) == (len(op.inputs[0].shape) + n) |
| op.attrs["new_axis_mask"] = 0 |
| else: |
| # Equal Rank StridedSlice, no need to insert reshape |
| return tens |
| |
| # Construct 1 shape tensor to be used by all inserted reshape ops |
| new_shape_tens = create_const_tensor(op.name + "_reshape_shape", [1], DataType.int32, tens.shape) |
| |
| for idx, out_tens in enumerate(op.outputs): |
| reshape_in = out_tens.clone("_reshaped") |
| reshape_in.set_all_shapes(reshape_input_shape) |
| reshape_in.ops = [op] |
| |
| reshape_op = Operation(Op.Reshape, "{}{}_reshape".format(op.name, idx)) |
| reshape_op.attrs["new_shape"] = reshape_input_shape |
| reshape_op.inputs = [reshape_in, new_shape_tens] |
| reshape_op.set_output_tensor(out_tens) |
| |
| op.outputs[idx] = reshape_in |
| |
| return tens |
| |
| |
| def fixup_unpack_output(tens, arch, nng): |
| op = tens.ops[0] |
| if op.run_on_npu and op.type == Op.Unpack: |
| # Unpack is also referred to as Unstack |
| # Requires the rewrite_split function to be called on the op afterwards |
| axis = int(op.attrs["axis"]) |
| op.type = Op.UnpackReshaped |
| reshape_input_shape = tens.shape[:axis] + [1] + tens.shape[axis:] |
| |
| # Construct 1 shape tensor to be used by all inserted reshape ops |
| new_shape_tens = create_const_tensor(op.name + "_reshape_shape", [1], DataType.int32, tens.shape) |
| |
| for idx, out_tens in enumerate(op.outputs): |
| reshape_in = out_tens.clone("_reshaped") |
| reshape_in.set_all_shapes(reshape_input_shape) |
| reshape_in.ops = [op] |
| |
| reshape_op = Operation(Op.Reshape, "{}{}_reshape".format(op.name, idx)) |
| reshape_op.attrs["new_shape"] = reshape_input_shape |
| reshape_op.inputs = [reshape_in, new_shape_tens] |
| reshape_op.set_output_tensor(out_tens) |
| DebugDatabase.add_optimised(op, reshape_op) |
| |
| op.outputs[idx] = reshape_in |
| |
| return tens |
| |
| |
| def add_padding_fields(op, arch, nng): |
| if op.run_on_npu: |
| if "padding" in op.attrs: |
| if op.type.is_conv2d_op() or op.type.is_depthwise_conv2d_op(): |
| kernel_size = op.inputs[1].shape[:2] |
| input_shape = op.inputs[0].shape |
| elif op.type.is_pool_op() or op.type.npu_block_type == NpuBlockType.ReduceSum: |
| kernel_size = op.attrs["ksize"][1:3] |
| input_shape = op.inputs[0].shape |
| else: |
| raise UnsupportedFeatureError("Unknown operation that uses padding: {}".format(op.type)) |
| |
| if op.type == Op.Conv2DBackpropInputSwitchedBias: |
| upscaling_factor = op.outputs[0].shape[1] // input_shape[1] |
| padding, skirt = calc_upscaled_padding_and_skirt( |
| op.attrs["padding"], kernel_size, op.attrs["strides"], input_shape, upscaling_factor |
| ) |
| else: |
| dilation_h, dilation_w = op.get_dilation_h_w() |
| dilated_kernel_size = [dilation_h * (kernel_size[0] - 1) + 1, dilation_w * (kernel_size[1] - 1) + 1] |
| padding, skirt = calc_padding_and_skirt( |
| op.attrs["padding"], dilated_kernel_size, op.attrs["strides"], input_shape |
| ) |
| |
| op.attrs["explicit_padding"] = padding |
| op.attrs["skirt"] = skirt |
| |
| return op |
| |
| |
| # Check if the op can be reordered |
| def get_prepend_op(op): |
| inp = op.inputs[0] |
| # The op should be reordered between prev_op and prep_op |
| prev_op = inp.ops[-1] |
| prep_op = None |
| while prev_op.type in memory_only_ops and len(prev_op.outputs) == 1 and len(prev_op.outputs[0].consumers()) == 1: |
| prep_op = prev_op |
| inp = prev_op.inputs[0] |
| prev_op = inp.ops[-1] |
| if prev_op is not None and len(prev_op.outputs) == 1 and len(prev_op.outputs[0].consumers()) == 1: |
| return prep_op |
| |
| return None |
| |
| |
| def convert_depthwise_to_conv(op, arch, nng): |
| # Depthwise is equivalent to a single conv2d if the ifm depth is 1 and |
| # the ofm depth equals the depth multipler. |
| # If those conditions are true, then we can perform a simple |
| # switch of the operator type (and weight order) |
| |
| if op.type == Op.DepthwiseConv2DBias and (op.attrs["depth_multiplier"] != 1): |
| ifm_tensor = op.inputs[0] |
| weight_tensor = op.inputs[1] |
| ofm_tensor = op.outputs[0] |
| if (ifm_tensor.shape[3] == 1) and (ofm_tensor.shape[3] == op.attrs["depth_multiplier"]): |
| # Change op type to Conv2d |
| op.type = Op.Conv2DBias |
| del op.attrs["channel_multiplier"] |
| del op.attrs["depth_multiplier"] |
| |
| weight_tensor.quant_values = np.transpose(weight_tensor.quant_values, (0, 1, 3, 2)) |
| weight_tensor.set_all_shapes(list(weight_tensor.quant_values.shape)) |
| else: |
| raise UnsupportedFeatureError( |
| "Unsupported DepthwiseConv2d with depth_multiplier = {}, ifm channels = {}, ofm channels = {}".format( |
| op.attrs["depth_multiplier"], ifm_tensor.shape[3], ofm_tensor.shape[3] |
| ) |
| ) |
| DebugDatabase.add_optimised(op, op) |
| return op |
| |
| |
| def reorder_depthwise_weights(op, arch, nng): |
| if op.type.is_depthwise_conv2d_op(): |
| weight_tensor = op.inputs[1] |
| weight_tensor.quant_values = np.transpose(weight_tensor.quant_values, (0, 1, 3, 2)) |
| weight_tensor.set_all_shapes(list(weight_tensor.quant_values.shape)) |
| weight_tensor.weight_transpose_depthwise = True |
| |
| return op |
| |
| |
| def convert_conv_to_fc(op, arch, nng): |
| # Conv 1x1 can be equivalent to Fully Connected. |
| # By representing certain convs as fully connected layers, Vela can better determine wether or not to use |
| # caching/double buffering for the weights. |
| # (Weights dont need to be reloaded for convs when IFM H and W are 1) |
| if op.type == Op.Conv2DBias: |
| _, h, w, _ = op.inputs[0].shape |
| kh, kw, _, _ = op.inputs[1].shape |
| if h == 1 and w == 1 and kh == 1 and kw == 1: |
| # Overwrite this op as a Fully Connected Op |
| op.name += "_fc" |
| op.type = Op.FullyConnected |
| op.attrs = { |
| "weights_format": 0, |
| } |
| # Reshape Weights to be 2D. HWIO becomes just IO (as H and W are 1, they can just be dropped) |
| weight_tensor = op.inputs[1] |
| weight_tensor.quant_values = weight_tensor.quant_values.squeeze(axis=(0, 1)) |
| weight_tensor.set_all_shapes(list(weight_tensor.quant_values.shape)) |
| # The output from a fully connected is expected to be 2D so we need to add a reshape layer to convert it |
| # back to 4D afterwards as the next layer is expecting that shape |
| orig_ofm_tensor = op.outputs[0] |
| # Reshape this ops output to be 2D: {(N*H*W), C} (We know N H and W are all 1 so this becomes {1, C}) |
| fc_ofm_tensor = orig_ofm_tensor.clone("_fc") |
| fc_ofm_tensor.set_all_shapes([1, fc_ofm_tensor.shape[-1]]) |
| fc_ofm_tensor.ops = [op] |
| # Add a reshape after the new OFM to convert it back to the original 4D shape |
| reshape_name = op.name + "_reshape" |
| new_shape_tens = create_const_tensor(reshape_name + "_shape", [1], DataType.int32, orig_ofm_tensor.shape) |
| reshape_op = Operation(Op.Reshape, reshape_name) |
| reshape_op.attrs["new_shape"] = orig_ofm_tensor.shape |
| reshape_op.inputs = [fc_ofm_tensor, new_shape_tens] |
| reshape_op.set_output_tensor(orig_ofm_tensor) |
| # Replace this ops OFM to point to the 2D tensor |
| op.outputs[0] = fc_ofm_tensor |
| # Record optimisation in debug database |
| DebugDatabase.add_optimised(op, reshape_op) |
| DebugDatabase.add_optimised(op, op) |
| return op |
| |
| |
| def fixup_relus_with_differing_ifm_ofm_scaling(op, arch, nng): |
| if op.run_on_npu and op.type.is_relu_op(): |
| ifm = op.inputs[0] |
| ofm = op.outputs[0] |
| # Relu with differing IFM and OFM scaling cannot be fused with another primary op |
| # and requires its own to be inserted |
| if not check_quantized_tens_scaling_equal(ifm, ofm): |
| # Override this op with its own primary op (avgpool) |
| relu_fused_op = create_avgpool_nop(op.name + "_avgpool") |
| # And fuse the original activation function to it |
| relu_fused_op.activation = create_activation_function(op.type) |
| # Tidy up and assign the ifm and ofm to the new op |
| ifm.consumer_list.remove(op) |
| |
| # if not 4d, reshape ifm/ofm |
| if len(ifm.shape) < 4: |
| ifm_shaped = create_reshape_tensor(ifm, full_shape(4, ifm.shape, 1)) |
| ifm = ifm_shaped |
| if len(ofm.shape) < 4: |
| ofm_shaped = create_reshape_tensor(ofm, full_shape(4, ofm.shape, 1), False) |
| ofm = ofm_shaped |
| |
| relu_fused_op.add_input_tensor(ifm) |
| relu_fused_op.set_output_tensor(ofm) |
| op = relu_fused_op |
| return op |
| |
| |
| # Reorder activation op if it's after the memory only operations |
| def fixup_act_reorder(op, arch, nng): |
| if op.type.is_relu_op() or op.type in set((Op.Sigmoid, Op.Tanh)): |
| prep_op = get_prepend_op(op) |
| if prep_op is not None: |
| act_op = op.clone("_reordered") |
| |
| # There is only one input tensor, overwrite it |
| act_op.set_input_tensor(prep_op.inputs[0], 0) |
| |
| act_op_out = act_op.inputs[0].clone("_acted") |
| act_op_out.quantization = op.outputs[0].quantization.clone() |
| act_op.set_output_tensor(act_op_out) |
| |
| # Update the consumer list |
| act_op_out.consumer_list = op.outputs[0].consumer_list.copy() |
| act_op_out.consumer_list.append(prep_op) |
| |
| prep_op.inputs[0] = act_op_out |
| prep_op.outputs[0].quantization = act_op_out.quantization.clone() |
| |
| # Mark the op so that it will be removed as passthrough later on |
| op.type = Op.Identity |
| |
| # Record optimisation in debug database |
| DebugDatabase.add_optimised(op, act_op) |
| DebugDatabase.add_optimised(op, op) |
| return op |
| |
| |
| def fixup_elementwise_with_scalars(op, arch, nng): |
| if op.type.is_binary_elementwise_op(): |
| ifm_tensor, ifm2_tensor, _, _ = op.get_ifm_ifm2_weights_ofm() |
| if ifm2_tensor.shape != [] and ifm_tensor.shape != []: |
| diff = len(ifm_tensor.shape) - len(ifm2_tensor.shape) |
| if diff > 0: |
| ifm2_tensor.shape = full_shape(len(ifm_tensor.shape), ifm2_tensor.shape, 1) |
| elif diff < 0: |
| ifm_tensor.shape = full_shape(len(ifm2_tensor.shape), ifm_tensor.shape, 1) |
| elif ifm_tensor.shape == [] and ifm_tensor.quant_values is None: |
| # IFM is marked as a scalar, but is a result of an operation; change it to a shape of size 1 |
| ifm_tensor.shape = len(ifm2_tensor.shape) * [1] |
| ifm_tensor.storage_shape = ifm_tensor.shape |
| elif ifm2_tensor.shape == [] and ifm2_tensor.quant_values is None: |
| # IFM2 is marked as a scalar, but is a result of an operation; change it to a shape of size 1 |
| ifm2_tensor.shape = len(ifm_tensor.shape) * [1] |
| ifm2_tensor.storage_shape = ifm2_tensor.shape |
| return op |
| |
| |
| # Set input/output tensor equivalence to the same id for memory operations |
| def set_tensor_equivalence(op, arch, nng): |
| if op.type in memory_only_ops: |
| eid = op.outputs[0].equivalence_id |
| for inp in op.inputs: |
| inp.equivalence_id = eid |
| return op |
| |
| |
| def convert_softmax(op, arch, nng): |
| if op.type == Op.Softmax and op.run_on_npu: |
| softmax = SoftMax(op) |
| op = softmax.get_graph() |
| return op |
| |
| |
| def convert_mul_max_to_abs_or_lrelu(op, arch, nng): |
| r"""Whenever there is a subgraph with this topology: |
| |
| Input X For X = -1 or X > 0 |
| | \ / This subgraph can be replaced with either |
| | Mul an Abs (if X = -1) or a LeakyReLU (if X > 0) |
| | / |
| Max |
| """ |
| |
| if op.type == Op.Maximum: |
| # finds the Mul input(s) to the Max |
| muls = [i for i in op.inputs if i.ops[0].type == Op.Mul] |
| if len(muls) == 1: |
| mul = muls[0].ops[0] |
| elif len(muls) == 2: |
| # In the case both inputs are Muls, find the one with the same input as the Max |
| mul = [m for m in muls if len(set(op.inputs + m.ops[0].inputs)) == 1][0].ops[0] |
| else: |
| # No Mul inputs |
| return op |
| |
| # make sure the Mul doesn't have any other consumers |
| mul_ofm = mul.outputs[0] |
| if len(mul_ofm.consumers()) != 1: |
| return op |
| # make sure the Mul doesn't have a fused activation function |
| if mul.activation: |
| return op |
| ifm, ofm = op.get_ifm_ofm() |
| if ifm is None or ofm is None: |
| return op |
| |
| if ifm.dtype not in (DataType.uint8, DataType.int8) or ifm.dtype != ofm.dtype: |
| return op |
| if not check_quantized_tens_scaling_equal(ifm, ofm) or not check_quantized_tens_scaling_equal(ifm, mul_ofm): |
| # rewrite to LeakyRelu currently only makes sense if the quantization is identical |
| return op |
| |
| # finds the branched input that goes to both the Max and the Mul |
| shared = set(op.inputs) & set(mul.inputs) |
| if len(shared) == 1: |
| shared_in = shared.pop() |
| # find the constant scalar input to the Mul |
| const_tens = (set(mul.inputs) - {shared_in}).pop() |
| # check that it is a scalar |
| if const_tens.shape != []: |
| return op |
| const = const_tens.ops[0] |
| # check that it is a constant |
| if const.type != Op.Const: |
| return op |
| # Remove the Mul from the shared input's consumers |
| shared_in.consumer_list.remove(mul) |
| else: |
| return op |
| |
| val = const.outputs[0].values |
| if val >= 0: |
| new_op = Op.LeakyRelu |
| op.attrs["alpha"] = val |
| # to produce bit exact results, the alpha is not enough; |
| # save additional scaling info in attr "alpha_scale", to be used as input |
| # to the LUT construction |
| alpha_scalar = const_tens.quant_values - const_tens.quantization.zero_point |
| mul_ifm_scale = np.double(ifm.quantization.scale_f32) |
| mul_ifm2_scale = np.double(const_tens.quantization.scale_f32) |
| mul_ofm_scale = np.double(mul_ofm.quantization.scale_f32) |
| alpha_scale, alpha_shift = scaling.elementwise_mul_scale(mul_ifm_scale, mul_ifm2_scale, mul_ofm_scale) |
| op.attrs["alpha_scaling"] = (alpha_scalar, alpha_scale, alpha_shift) |
| elif val == -1: |
| new_op = Op.Abs |
| else: |
| return op |
| |
| op.type = new_op |
| op.name = op.name.replace("Maximum", new_op.name) |
| op.outputs[0].name = op.outputs[0].name.replace("Maximum", new_op.name) |
| op.inputs = [shared_in] |
| |
| # Record optimisation in debug database |
| DebugDatabase.add_optimised(op, op) |
| |
| return op |
| |
| |
| def convert_lrelu_to_mul_max(op, arch): |
| # Converts LeakyRelu to Max(alpha * IFM, identity * IFM) |
| # (the opposite of convert_mul_max_to_abs_or_lrelu) |
| ifm, ofm = op.get_ifm_ofm() |
| if ifm is None or ofm is None: |
| return op |
| |
| # Add multiplication with alpha |
| mul_alpha = Operation(Op.Mul, op.name + "_mul_alpha") |
| mul_alpha.add_input_tensor(ifm) |
| # Create const tensor containing alpha as scalar |
| alpha = op.attrs["alpha"] |
| quantization = ifm.quantization.clone() |
| quantization.min = 0 |
| quantization.max = alpha * (quantization.quant_max - quantization.quant_min) |
| quantization.scale_f32 = alpha |
| quantization.zero_point = 0 |
| alpha_tens = create_const_tensor(op.name + "_alpha_scalar", [], ifm.dtype, [1], np.int8, quantization=quantization) |
| mul_alpha.add_input_tensor(alpha_tens) |
| fm_alpha = ofm.clone(op.name + "_alpha") |
| mul_alpha.set_output_tensor(fm_alpha) |
| DebugDatabase.add_optimised(op, mul_alpha) |
| |
| if check_quantized_tens_scaling_equal(ifm, ofm): |
| # No identity multiplication is needed |
| fm_id = ifm |
| else: |
| # Add multiplication with identity |
| mul_identity = Operation(Op.Mul, op.name + "_mul_identity") |
| mul_identity.add_input_tensor(ifm) |
| # Create const tensor containing identity as scalar |
| quantization = ifm.quantization.clone() |
| quantization.min = 0 |
| quantization.max = quantization.quant_max - quantization.quant_min |
| quantization.scale_f32 = 1 |
| quantization.zero_point = 0 |
| identity_tens = create_const_tensor( |
| op.name + "_id_scalar", [], ifm.dtype, [1], np.uint8, quantization=quantization |
| ) |
| mul_identity.add_input_tensor(identity_tens) |
| fm_id = ofm.clone(op.name + "_id") |
| mul_identity.set_output_tensor(fm_id) |
| DebugDatabase.add_optimised(op, mul_alpha) |
| |
| # Convert LeakyRelu to Max, add the results of the multiplication(s) as inputs |
| op.type = Op.Maximum |
| op.name = op.name.replace("LeakyRelu", "Maximum") |
| op.inputs = [] |
| ifm.consumer_list.remove(op) |
| op.add_input_tensor(fm_alpha) |
| op.add_input_tensor(fm_id) |
| |
| DebugDatabase.add_optimised(op, op) |
| return op |
| |
| |
| def convert_to_lut(op, lut_values, lut_name): |
| # Rewrite the operation by Add with scalar 0 + LUT activation |
| ifm = op.inputs[0] |
| if ifm is None: |
| return op |
| assert ifm.dtype.size_in_bytes() == 1 |
| op.type = Op.Add |
| op.name = op.name + "_lut_" + lut_name |
| # Mark as no-op to enable potential fusing optimizations |
| op.attrs["is_nop"] = True |
| # Create an input tensor containing scalar zero |
| quantization = QuantizationParameters(0.0, 255.0) |
| quantization.scale_f32 = ifm.quantization.scale_f32 |
| quantization.zero_point = 0 |
| tens = create_const_tensor(op.inputs[0].name + "_scalar0", [], ifm.dtype, [0], np.uint8, quantization=quantization) |
| op.add_input_tensor(tens) |
| # The LUT must be applied without any preceding rescaling (the LUT itself performs the rescale), |
| # so even if the OFM has a different scale than the IFM, the generated OFM scale instructions |
| # should be the same as the IFM |
| op.forced_output_quantization = ifm.quantization |
| lut_tensor = lut.create_lut_tensor(op.name + "_values", lut_values, DataType.int8) |
| op.set_activation_lut(lut_tensor) |
| return op |
| |
| |
| def convert_to_lut8(op, fn, fn_name): |
| # Converts op to a no-op + int8/uint8 LUT which is generated with the given function. |
| # fn is a function(real) -> real |
| ifm, ofm = op.get_ifm_ofm() |
| if ifm.dtype not in (DataType.uint8, DataType.int8) or ifm.dtype != ofm.dtype: |
| return op |
| # Generate the LUT |
| ifm_scale = np.double(ifm.quantization.scale_f32) |
| ofm_scale = np.double(ofm.quantization.scale_f32) |
| zp_in = ifm.quantization.zero_point |
| zp_out = ofm.quantization.zero_point |
| values = [] |
| ix = range(256) if ifm.dtype == DataType.uint8 else range(-128, 128) |
| quantized_min = min(ix) |
| quantized_max = max(ix) |
| for x in ix: |
| x_real = ifm_scale * (x - zp_in) |
| y_real = fn(x_real) |
| lut_result = round_away_zero(zp_out + y_real / ofm_scale) |
| lut_result = min(quantized_max, max(quantized_min, lut_result)) |
| values.append(lut_result) |
| return convert_to_lut(op, values, fn_name) |
| |
| |
| def convert_lrelu_to_lut(op, arch): |
| ifm, ofm = op.get_ifm_ofm() |
| # Generate the LUT |
| alpha = op.attrs["alpha"] |
| ifm_scale = np.double(ifm.quantization.scale_f32) |
| ofm_scale = np.double(ofm.quantization.scale_f32) |
| zp_in = ifm.quantization.zero_point |
| zp_out = ofm.quantization.zero_point |
| identity_scale, identity_shift = scaling.elementwise_mul_scale(ifm_scale, 1, ofm_scale) |
| alpha_scalar = 1 |
| alpha_scale, alpha_shift = scaling.elementwise_mul_scale(ifm_scale, alpha, ofm_scale) |
| if "alpha_scaling" in op.attrs: |
| # The LeakyRelu was the result from convert_mul_max_to_abs_or_lrelu |
| alpha_scalar, alpha_scale, alpha_shift = op.attrs["alpha_scaling"] |
| values = [] |
| ix = range(256) if ifm.dtype == DataType.uint8 else range(-128, 128) |
| quantized_min = min(ix) |
| quantized_max = max(ix) |
| for x in ix: |
| if x < zp_in: |
| lut_result = zp_out + fp_math.multiply_by_quantized_multiplier( |
| alpha_scalar * (x - zp_in), alpha_scale, alpha_shift |
| ) |
| else: |
| lut_result = zp_out + fp_math.multiply_by_quantized_multiplier(x - zp_in, identity_scale, identity_shift) |
| lut_result = min(quantized_max, max(quantized_min, lut_result)) |
| values.append(lut_result) |
| return convert_to_lut(op, values, "lrelu") |
| |
| |
| def convert_lrelu(op, arch, nng): |
| # Converts LeakyRelu to a LUT based solution if possible, otherwise a mul + max |
| if op.type != Op.LeakyRelu: |
| return op |
| ifm, ofm = op.get_ifm_ofm() |
| if ifm is None or ofm is None: |
| return op |
| if ifm.dtype in (DataType.uint8, DataType.int8) and ifm.dtype == ofm.dtype: |
| # use LUT for int8/uint8 |
| return convert_lrelu_to_lut(op, arch) |
| if check_quantized_tens_scaling_equal(ifm, ofm) and ifm.dtype == ofm.dtype == DataType.int16: |
| # use LeakyRelu unmodified for int16 with equal input/output scaling |
| return op |
| return convert_lrelu_to_mul_max(op, arch) |
| |
| |
| def convert_tanh_sigmoid_to_lut(op, arch, nng): |
| # Converts int8/uint8 Sigmoid and Tanh to a LUT based solution |
| if op.type == Op.Sigmoid: |
| return convert_to_lut8(op, clamp_sigmoid, "sigmoid") |
| elif op.type == Op.Tanh: |
| return convert_to_lut8(op, math.tanh, "tanh") |
| return op |
| |
| |
| def remove_unwanted_reshapes(op, arch, nng): |
| # Try to remove reshapes enclosing ElementWise operator with only one non-constant input |
| if not op.run_on_npu or not op.type.is_elementwise_op(): |
| return op |
| |
| # Check if the ElementWise operator only have one non-constant input |
| non_const_tens = [x for x in op.inputs if x.ops[0].type != Op.Const] |
| if len(non_const_tens) != 1: |
| return op |
| ifm = non_const_tens[0] |
| |
| # Check if operation is enclosed by Reshapes that can be removed |
| ofm = op.outputs[0] |
| prev_op = ifm.ops[0] |
| if ( |
| len(ifm.consumer_list) == 1 |
| and prev_op.type == Op.Reshape |
| and len(ofm.consumer_list) == 1 |
| and ofm.consumer_list[0].type == Op.Reshape |
| ): |
| # Operation is enclosed by reshapes, check if they can be removed |
| prev_op_ifm, prev_op_ofm = prev_op.get_ifm_ofm() |
| cons_op = ofm.consumer_list[0] |
| cons_op_ifm = ofm |
| cons_op_ofm = cons_op.outputs[0] |
| if len(prev_op_ifm.shape) == len(cons_op_ofm.shape): |
| # Check if quantization is the same in the input and output for the reshape ops |
| if check_quantized_tens_scaling_equal(prev_op_ifm, prev_op_ofm) and check_quantized_tens_scaling_equal( |
| cons_op_ifm, cons_op_ofm |
| ): |
| op.set_input_tensor(prev_op_ifm, 0) |
| op.set_output_tensor(cons_op_ofm) |
| return op |
| |
| |
| def fuse_activation_function_with_prev(op, arch, nng): |
| # if op is a no-op: attempts to move the activation function to the preceding op |
| if not op.attrs.get("is_nop", False) or op.activation is None: |
| return op |
| ifm, ofm = op.get_ifm_ofm() |
| if ifm is None or ofm is None: |
| return op |
| # finds the input(s) to the operation |
| prev_op = ifm.ops[0] |
| # Note: the below checks on prev_op require that a first optimize pass on the full graph has been performed |
| fuse = ( |
| prev_op.run_on_npu |
| and prev_op.type.npu_block_type != NpuBlockType.Default |
| and len(ifm.ops) == 1 |
| and len(prev_op.outputs[0].consumers()) == 1 |
| and prev_op.activation is None |
| ) |
| if op.activation_lut is not None and arch.shram_reserved_unused_banks == 0: |
| # TODO: if SHRAM LUT space is shared with SHRAM ACC (32, 64 MAC), |
| # LUT currently only works correctly for elementwise ops |
| fuse = False |
| if not fuse: |
| return op |
| # Move the fused activation function + corresponding info to prev_op |
| prev_op.activation = op.activation |
| prev_op.forced_output_quantization = op.forced_output_quantization |
| if op.activation_lut is not None: |
| prev_op.set_activation_lut(op.activation_lut) |
| # Bypass op |
| prev_op.set_output_tensor(ofm) |
| DebugDatabase.add_optimised(op, prev_op) |
| return op |
| |
| |
| def add_attrs_to_resizebilinear(op, arch, nng): |
| if op.type == Op.ResizeBilinear and op.run_on_npu: |
| input_tensor = op.inputs[0] |
| upscaled_shape = [input_tensor.shape[1] * 2, input_tensor.shape[2] * 2] |
| out_shape = op.outputs[0].shape[1:3] |
| if not op.attrs["align_corners"] and out_shape == upscaled_shape: |
| # this means the output is supposed to be a x2 upscale, |
| # so we need to do SAME padding |
| op.attrs["padding"] = b"SAME" |
| elif op.attrs["align_corners"] and out_shape == [upscaled_shape[0] - 1, upscaled_shape[1] - 1]: |
| # here we can just run the avg pool without padding and |
| # produce a (M * 2 - 1, N * 2 - 1) sized output |
| op.attrs["padding"] = b"VALID" |
| else: |
| return op |
| input_tensor.resampling_mode = resampling_mode.NEAREST |
| op.attrs.update({"strides": (1, 1, 1, 1), "ksize": (1, 2, 2, 1)}) |
| return op |
| |
| |
| def fixup_bias_tensors(op, arch, nng): |
| if op.type.needs_bias() and op.bias is None: |
| # Op has no bias, add bias tensor filled with zeros |
| nr_biases = op.inputs[1].shape[-1] |
| bias_values = [0] * nr_biases |
| bias_tensor = create_const_tensor(op.name + "_bias", [nr_biases], DataType.int32, bias_values) |
| bias_tensor.quant_values = bias_tensor.values |
| op.set_input_tensor(bias_tensor, -1) |
| |
| return op |
| |
| |
| def supported_operator_check(op, arch, nng): |
| op.run_on_npu = arch.supported_operators.is_operator_supported(op) |
| return op |
| |
| |
| def _record_optimised(op, arch): |
| if op.type != Op.Const: |
| DebugDatabase.add_optimised(op, op) |
| |
| |
| def optimise_graph_a(nng, arch, verbose_graph=False): |
| if verbose_graph: |
| nng.print_graph() |
| |
| op_rewrite_list = [ |
| set_tensor_equivalence, |
| supported_operator_check, |
| # then do any rewrites of supported operators |
| convert_depthwise_to_conv, |
| convert_conv_to_fc, |
| convert_softmax, |
| fixup_fully_connected_input, |
| convert_batched_fc_to_conv, |
| fixup_pack_input, |
| unfuse_activation_function, |
| fixup_conv2d_backprop, |
| fixup_relus_with_differing_ifm_ofm_scaling, |
| fixup_act_reorder, |
| fixup_elementwise_with_scalars, |
| reorder_depthwise_weights, |
| fixup_resizebilinear, |
| fixup_bias_tensors, |
| convert_nop_split_to_identity, |
| convert_mul_max_to_abs_or_lrelu, |
| remove_unwanted_reshapes, |
| convert_lrelu, |
| convert_tanh_sigmoid_to_lut, |
| ] |
| |
| for idx, sg in enumerate(nng.subgraphs): |
| # rewrite graph pass |
| nng.subgraphs[idx] = rewrite_graph.rewrite_graph_pre_order( |
| nng, sg, arch, [], op_rewrite_list, rewrite_unsupported=False, |
| ) |
| |
| for idx, sg in enumerate(nng.subgraphs): |
| # remove passthrough tensors and attempt further optimizations |
| nng.subgraphs[idx] = rewrite_graph.rewrite_graph_pre_order( |
| nng, sg, arch, [remove_passthrough_tensor], [fuse_activation_function_with_prev, add_padding_fields] |
| ) |
| |
| # Post-optimisation operator debug tracing |
| for sg in nng.subgraphs: |
| rewrite_graph.visit_graph_post_order(sg.output_tensors, arch, [], [_record_optimised]) |
| |
| if verbose_graph: |
| nng.print_graph() |
| return nng |
| |
| |
| def optimise_graph_b(nng, arch, verbose_graph=False): |
| if verbose_graph: |
| nng.print_graph() |
| |
| for idx, sg in enumerate(nng.subgraphs): |
| # combined rewrite graph pass |
| nng.subgraphs[idx] = rewrite_graph.rewrite_graph_pre_order( |
| nng, sg, arch, [fixup_unpack_output, fixup_stridedslice_output, rewrite_concat, rewrite_split], [] |
| ) |
| |
| if verbose_graph: |
| nng.print_graph() |
| return nng |