| # SPDX-FileCopyrightText: Copyright 2020-2023 Arm Limited and/or its affiliates <open-source-office@arm.com> |
| # |
| # 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 a TensorFlow Lite based network graph, using the rewrite_graph module |
| # to do the traversal of the graph. |
| import math |
| import uuid |
| |
| import numpy as np |
| |
| from . import fp_math |
| from . import rewrite_graph |
| from . import scaling |
| from .api import NpuRoundingMode |
| from .data_type import BaseType |
| 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 .graph_optimiser_util import bypass_memory_only_ops |
| from .graph_optimiser_util import calc_explicit_padding |
| from .graph_optimiser_util import convert_depthwise_to_conv |
| from .graph_optimiser_util import convert_to_lut |
| from .graph_optimiser_util import fix_sg_input_output |
| from .graph_optimiser_util import memory_only_ops |
| from .graph_optimiser_util import move_splitsliceread_to_consumer |
| from .graph_optimiser_util import needed_total_padding |
| from .graph_optimiser_util import set_ifm_ofm_op_shapes |
| from .graph_optimiser_util import set_tensor_equivalence |
| from .numeric_util import clamp_sigmoid |
| from .numeric_util import round_away_zero |
| from .operation import create_activation_function |
| from .operation import ExplicitScaling |
| from .operation import NpuBlockType |
| from .operation import Op |
| from .operation import Operation |
| from .operation import Padding |
| from .operation_util import create_add_nop |
| from .operation_util import create_avgpool_nop |
| from .operation_util import get_pad_values_from_input |
| from .scaling import quantise_scale |
| from .shape4d import Shape4D |
| from .softmax import SoftMax |
| from .tensor import check_quantized_tens_scaling_equal |
| from .tensor import create_const_tensor |
| from .tensor import create_equivalence_id |
| from .tensor import QuantizationParameters |
| from .tensor import Tensor |
| from .tensor import TensorPurpose |
| from .tflite_mapping import optype_to_builtintype |
| |
| passthrough_nodes = (Op.Identity,) |
| |
| |
| def create_avg_pool_for_concat(concat_op, name, ifm, ifm_shape: Shape4D, write_offset: Shape4D): |
| """Creates an average pool for the given concat op/input feature map""" |
| ofm = concat_op.ofm |
| avgpool_op = create_avgpool_nop(name) |
| avgpool_op.inputs = [ifm] |
| avgpool_op.outputs = [ofm] |
| |
| avgpool_op.write_offset = write_offset |
| avgpool_op.write_shape = ifm_shape |
| ofm.ops.append(avgpool_op) |
| avgpool_op.ifm_shapes.append(ifm_shape) |
| avgpool_op.ofm_shapes.append(concat_op.ofm_shapes[0]) |
| avgpool_op.memory_function = Op.ConcatSliceWrite |
| DebugDatabase.add_optimised(concat_op, avgpool_op) |
| return avgpool_op |
| |
| |
| 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_ops(op, arch): |
| if not op.run_on_npu or not op.type.is_concat_op(): |
| return |
| |
| axis_4D = 0 |
| ofm = op.ofm |
| ofm.ops = [] |
| offset = 0 |
| |
| unfuse_activation_function(op) |
| |
| if op.type == Op.Pack: |
| # Pack is also referred to as Stack |
| axis = int(op.attrs["axis"]) |
| if axis < 0: # Convert to positive axis |
| axis = len(op.inputs[0].shape) + 1 + axis |
| |
| desired_shape = op.inputs[0].shape[:axis] + [1] + op.inputs[0].shape[axis:] |
| |
| axis_4D = axis + (4 - len(desired_shape)) |
| |
| for idx, inp in enumerate(op.inputs): |
| op.ifm_shapes[idx] = Shape4D(desired_shape) |
| op.type = Op.PackReshaped |
| |
| inputs, axis = op.get_concat_inputs_axis() |
| for idx, inp in enumerate(inputs): |
| if op.type != Op.PackReshaped: |
| op.ifm_shapes[idx] = Shape4D(inp.shape) |
| if axis >= 0: |
| axis_4D = axis + (4 - len(inp.shape)) |
| else: |
| axis_4D = axis |
| write_offset = [0, 0, 0, 0] |
| write_offset[axis_4D] = offset |
| concat_end = offset + op.ifm_shapes[idx][axis_4D] |
| create_avg_pool_for_concat( |
| op, op.name + str(idx) + "_avgpool", inp, op.ifm_shapes[idx], Shape4D.from_list(write_offset) |
| ) |
| offset = concat_end |
| assert ofm.shape[axis] == offset |
| |
| return op |
| |
| |
| def rewrite_split_ops(tens, arch, nng): |
| |
| if len(tens.ops) == 1 and tens.ops[0].type.is_split_op() and tens.ops[0].type != Op.Unpack: |
| 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] |
| ofm_shape_idx = 0 |
| if None in (offset_end, offset_start): |
| read_shape = None |
| else: |
| # the read shape is relative to each start offset |
| read_shape = [oe - os for oe, os in zip(offset_end, offset_start)] |
| |
| # 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] * 4 |
| axis_4D_list = split_op.attrs.get("split_axis_4D", None) # Present for UnpackReshaped and some StridedSlice |
| for idx, out in enumerate(outputs): |
| if axis_4D_list is not None: |
| axis_4D = axis_4D_list[idx] |
| else: |
| split_op.ofm_shapes[idx] = Shape4D(out.shape) |
| if axis >= 0: |
| axis_4D = axis + (4 - len(out.shape)) |
| else: |
| axis_4D = axis |
| |
| if out == tens: |
| ofm_shape_idx = idx |
| read_shape = split_op.ofm_shapes[idx] |
| break |
| |
| offset_start[axis_4D] += split_op.ofm_shapes[idx][axis_4D] |
| |
| new_op.read_offsets[0] = Shape4D.from_list(offset_start, 0) |
| new_op.read_shapes[0] = read_shape |
| new_op.run_on_npu = True |
| new_op.set_output_tensor(tens) |
| new_op.ifm_shapes.append(Shape4D(inp.shape)) |
| new_op.ofm_shapes.append(split_op.ofm_shapes[ofm_shape_idx]) |
| DebugDatabase.add_optimised(split_op, new_op) |
| |
| return tens |
| |
| |
| def remove_SplitSliceRead(op, arch): |
| |
| if op.type == Op.SplitSliceRead: |
| # Check if it is possible to put the SplitSliceRead on the tensor consumer, or if an avgpool need to be inserted |
| if ( |
| len(op.ofm.consumer_list) == 1 |
| and op.ofm.consumer_list[0] is not None |
| and op.ofm.consumer_list[0].run_on_npu |
| and op.ofm.consumer_list[0].type not in memory_only_ops |
| and op.ofm_shapes[0] == Shape4D.from_list(op.ofm.shape) |
| ): |
| # SplitSliceRead can be performed by tensor consumer |
| cons_op = op.ofm.consumer_list[0] |
| move_splitsliceread_to_consumer(op, cons_op) |
| else: |
| avgpool_op = create_avgpool_nop(op.name + "_avgpool") |
| avgpool_op.add_input_tensor(op.ifm) |
| avgpool_op.outputs = [op.ofm] |
| op.ofm.ops.remove(op) |
| op.ofm.ops.append(avgpool_op) |
| avgpool_op.ifm_shapes.append(op.ifm_shapes[0]) |
| avgpool_op.ofm_shapes.append(op.ofm_shapes[0]) |
| avgpool_op.read_offsets[0] = op.read_offsets[0] |
| avgpool_op.read_shapes[0] = op.read_shapes[0] |
| |
| op.ifm.consumer_list.remove(op) |
| DebugDatabase.add_optimised(op, avgpool_op) |
| |
| |
| def calc_padding_and_skirt(padding_type, kernel, input_shape, explicit_padding): |
| k_w, k_h = kernel.dilated_wh() |
| s_x, s_y = kernel.stride |
| ypad = needed_total_padding(int(input_shape.height), int(s_y), int(k_h)) |
| xpad = needed_total_padding(int(input_shape.width), int(s_x), int(k_w)) |
| if padding_type == Padding.SAME: |
| left_pad = (xpad + 0) // 2 |
| right_pad = (xpad + 1) // 2 |
| top_pad = (ypad + 0) // 2 |
| bottom_pad = (ypad + 1) // 2 |
| elif padding_type == Padding.VALID: |
| left_pad = 0 |
| right_pad = 0 |
| top_pad = 0 |
| bottom_pad = 0 |
| elif padding_type == Padding.EXPLICIT: |
| # Padding is specified in a PAD operator which has been bypassed. |
| top, left, bottom, right = explicit_padding |
| top_pad, bottom_pad = calc_explicit_padding(int(input_shape.height), int(s_y), int(k_h), int(top), int(bottom)) |
| left_pad, right_pad = calc_explicit_padding(int(input_shape.width), int(s_x), int(k_w), int(left), int(right)) |
| elif padding_type == Padding.TILE: |
| # The values in the explicit padding only represent the "direction" in which to pad |
| top_pad, left_pad, bottom_pad, right_pad = explicit_padding |
| else: |
| raise UnsupportedFeatureError(f"Unsupported padding = {padding_type} for padding calculation") |
| 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_shape, upscaling_factor): |
| kernel_height, kernel_width = kernel_size[0], kernel_size[1] |
| if padding_type == Padding.SAME: |
| ypad = needed_total_padding(int(input_shape.height) * upscaling_factor, int(stride[1]), int(kernel_height)) |
| xpad = needed_total_padding(int(input_shape.width) * 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 == Padding.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: |
| raise UnsupportedFeatureError(f"Unsupported padding = {padding_type} for up-scaled padding calculation") |
| 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 |
| op.ifm_resampling_mode = resampling_mode.TRANSPOSE |
| |
| # Update strides |
| op.attrs.update({"stride_w": 1, "stride_h": 1, "strides": (1, 1, 1, 1)}) |
| DebugDatabase.add_optimised(op, op) |
| |
| return op |
| |
| |
| # Convert the op to an elementwise add |
| def convert_resize_1x1_to_add(op): |
| op.type = Op.Add # original_type will stay as Op.ResizeBilinear or Op.ResizeNearestNeighbor |
| op.name = op.name + "_add" |
| # Create an input tensor filled with zeros |
| shape = op.ofm_shapes[0].as_list() |
| tens = Tensor(shape, op.inputs[0].dtype, op.inputs[1].name + "_add") |
| tens.values = np.zeros(shape, tens.dtype.as_numpy_type()) |
| 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 |
| op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, op) |
| |
| return op |
| |
| |
| # Convert ResizeNearestNeightbor with align corners to a depthwise convolution. The IFM will already have been upscaled |
| # apart from the final x2 scaling which will be done as part of this operation. The kernel contains a single coefficient |
| # to select the appropriate nearest neighbor value |
| def convert_resizenn_ac_to_depthwise_conv(op, upscale_factor): |
| ifm = op.ifm |
| ofm = op.ofm |
| output_depth = ofm.shape[-1] |
| dw_op_attrs = { |
| "padding": Padding.VALID, |
| "stride_h": 1, |
| "stride_w": 1, |
| "strides": (1, 1, 1, 1), |
| "depth_multiplier": 1, |
| "channel_multiplier": 1, |
| "dilation_h_factor": 1, |
| "dilation_w_factor": 1, |
| "dilation": (1, 1, 1, 1), |
| } |
| |
| # change resizebilinear to depthwise |
| op.type = Op.DepthwiseConv2DBias |
| op.attrs.update(dw_op_attrs) |
| op.set_input_tensor(ifm, 0) # ifm tensor index |
| op.activation = None |
| |
| # add input resample to resize by x2 |
| op.ifm_resampling_mode = resampling_mode.NEAREST |
| |
| # don't care about the rounding mode as it is nearest neighbor |
| |
| # setup weight tensor |
| weight_quant = QuantizationParameters() |
| weight_quant.scale_f32 = 1.0 # no scaling as only a single non-zero coeff to select the desired value |
| weight_quant.zero_point = 0 |
| weight_quant.quant_dim = 0 |
| ofm_dtype = ofm.dtype |
| if ofm_dtype.type == BaseType.UnsignedInt: |
| weight_quant.quant_min = 0 |
| weight_quant.quant_max = (1 << ofm_dtype.bits) - 1 |
| else: |
| weight_quant.quant_min = -(1 << (ofm_dtype.bits - 1)) |
| weight_quant.quant_max = (1 << (ofm_dtype.bits - 1)) - 1 |
| |
| weight_shape = [upscale_factor, upscale_factor, output_depth, output_depth] # HWIO |
| |
| # the single non-zero coefficient used to select the desired value needs to be placed in the 'centre value', which |
| # is calculated by finding the 'centre position' ('*' in the diagram below) and then choosing the 'value' that is |
| # below-and-right (i.e. next) to it (D). |
| # 0---1---2 |
| # | A | B | |
| # 1---*---+ |
| # | C | D | |
| # 2---+---+ |
| weight_values = [0] * (upscale_factor * upscale_factor) |
| centre_coeff = (upscale_factor // 2) * upscale_factor + (upscale_factor // 2) |
| weight_values[centre_coeff] = 1 |
| |
| # add weight tensor, this will discard the size tensor of the resize op |
| op.set_input_tensor( |
| create_const_tensor( |
| "weights", |
| weight_shape, |
| ofm_dtype, |
| np.array(weight_values).reshape(weight_shape), |
| quantization=weight_quant, |
| ), |
| 1, # inputs tensor weight index |
| ) |
| |
| # setup bias tensor by assign None and then call the fix-up function to create a suitable tensor. |
| # need to append the bias tensor as resize ops only have 2 inputs |
| assert len(op.inputs) == 2 |
| op.inputs.append(None) |
| fixup_bias_tensors(op, None, None, DataType.int32) |
| |
| # finally update the shape incase we've change the tensor shapes or connections |
| op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, op) |
| |
| return op |
| |
| |
| # Convert ResizeBilinear/NearestNeighbor to a number of 1x1 average pools with nearest neighbor x2 upscaling and one |
| # final average pool with a kernel size that depends upon the resize ops upscaling factor (x2, x4 or x8). The maximum |
| # upscale factor is limited to x8 because of the limit 8x8 kernel size limit for average pool with padding. |
| def convert_resize_to_upscale_and_average_pool(op): |
| pre_op = op |
| outputs = op.outputs |
| dtype = op.ifm.dtype |
| |
| op.attrs.update({"strides": (1, 1, 1, 1), "ksize": (1, 1, 1, 1)}) |
| op.attrs["padding"] = Padding.SAME # doesn't really matter as the kernel is 1x1 |
| op.ifm_resampling_mode = resampling_mode.NEAREST |
| |
| upscaled_shape = np.array(op.ifm_shapes[0].get_hw_as_list()) |
| |
| # Get upscale factor that was calculated in the supported operators check |
| upscale_factor = op.attrs["upscale_factor"] |
| |
| # Calculate how many times 2x2 upscaling needs to be performed |
| # Force the result of round to be an integer. This is because the behaviour of rounding numpy.float64 values changed |
| # between different versions of numpy. This consistency ensures that the kernel dimensions are kept integral |
| n = int(np.log2(upscale_factor)) |
| |
| # Perform x2 upscaling n-1 times |
| scaled_op = pre_op |
| for count in range(n - 1): |
| if count > 0: |
| scaled_op = op.clone(f"_{count}") |
| scaled_op.inputs[0] = pre_op.outputs[0] |
| |
| # Nearest neighbor x2 upscaling |
| upscaled_shape = upscaled_shape * 2 |
| shape = op.ofm_shapes[0].as_list() |
| shape[1:3] = upscaled_shape |
| out_tens = Tensor(shape, dtype, f"{op.outputs[0].name}_{count}") |
| out_tens.quantization = op.outputs[0].quantization.clone() |
| scaled_op.set_output_tensor(out_tens) |
| pre_op = scaled_op |
| |
| scaled_op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, scaled_op) |
| |
| # Last x2 upscaling |
| if n > 1: |
| scaled_op = op.clone(f"_{n-1}") |
| scaled_op.inputs[0] = pre_op.outputs[0] |
| |
| if scaled_op.original_type == Op.ResizeBilinear: |
| if scaled_op.attrs["align_corners"]: |
| # no padding |
| scaled_op.attrs["padding"] = Padding.VALID |
| else: |
| # padding to the right and bottom (limits average pool to 8x8 kernel) |
| scaled_op.attrs["padding"] = Padding.EXPLICIT |
| scaled_op.attrs["explicit_padding"] = [0, 0, upscale_factor - 1, upscale_factor - 1] |
| |
| # kernal size dependent on the upscaling factor |
| scaled_op.attrs.update({"ksize": (1, upscale_factor, upscale_factor, 1)}) |
| else: # Op.ResizeNearestNeighbor |
| if scaled_op.attrs["align_corners"]: |
| # use depthwise conv to select the correct value |
| scaled_op = convert_resizenn_ac_to_depthwise_conv(scaled_op, upscale_factor) |
| else: |
| # Keep 1x1 kernel and average pool, this applies both when |
| # half-pixel-centers is True and False. Calculations are the |
| # same in the reference. |
| pass |
| |
| scaled_op.outputs = outputs |
| scaled_op.outputs[0].ops = [scaled_op] |
| scaled_op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, scaled_op) |
| |
| return op |
| |
| |
| def convert_resizebilinear_to_depthwise_convolutions(op, half_pixel_centers=True): |
| def _compute_interpolation_values(index, input_size, output_size): |
| scale = input_size / output_size |
| scaled_value = (index + 0.5 * half_pixel_centers) * scale - 0.5 * half_pixel_centers |
| lower_bound = max(np.floor(scaled_value), 0) |
| |
| return scaled_value, lower_bound |
| |
| def _compute_kernels(input_height, input_width, output_height, output_width): |
| kernels = [] |
| for y in (1, 2): |
| for x in (1, 2): |
| sv_h, lb_h = _compute_interpolation_values(y, input_height, output_height) |
| sv_w, lb_w = _compute_interpolation_values(x, input_width, output_width) |
| |
| # Interpolation values calculated for (x, y) = ([1, 2], [1, 2]) will always generalize to the whole |
| # input for upscale = 2 and input sizes >= 2x2 and be in the correct order for going left-to-right, |
| # top-to-bottom - same as the depthwise convolution strides across each tile |
| kernel = np.zeros((2, 2)) |
| kernel[1, 1] = (1 - (sv_h - lb_h)) * (1 - (sv_w - lb_w)) |
| kernel[0, 1] = (sv_h - lb_h) * (1 - (sv_w - lb_w)) |
| kernel[1, 0] = (1 - (sv_h - lb_h)) * (sv_w - lb_w) |
| kernel[0, 0] = (sv_h - lb_h) * (sv_w - lb_w) |
| kernel *= 16 |
| kernels.append(kernel) |
| |
| return kernels |
| |
| def _build_convolutions(op, kernels): |
| dw_op_attrs = { |
| "padding": Padding.TILE, |
| "stride_h": 1, |
| "stride_w": 1, |
| "strides": (1, 1, 1, 1), |
| "depth_multiplier": 1, |
| "channel_multiplier": 1, |
| "dilation_h_factor": 1, |
| "dilation_w_factor": 1, |
| "dilation": (1, 1, 1, 1), |
| } |
| ifm = op.ifm |
| ofm = op.ofm |
| ofm.ops = [] |
| elem_size = 2 if ofm.dtype == DataType.int16 else 1 |
| |
| n, h, w, c = ifm.shape |
| _, _, ow, _ = ofm.shape |
| |
| intermediate_tens = Tensor(ifm.shape, ifm.dtype, "intermediate_tens") |
| intermediate_tens.quantization = op.outputs[0].quantization.clone() |
| avgpool_op = op |
| avgpool_op.name = "rb_init_avgpool" |
| avgpool_op.type = Op.AvgPool |
| avgpool_op.attrs["padding"] = Padding.VALID |
| avgpool_op.attrs["stride_w"] = 1 |
| avgpool_op.attrs["stride_h"] = 1 |
| avgpool_op.attrs["filter_width"] = 1 |
| avgpool_op.attrs["filter_height"] = 1 |
| avgpool_op.attrs["strides"] = [1, 1, 1, 1] |
| avgpool_op.attrs["ksize"] = [1, 1, 1, 1] |
| |
| avgpool_op.add_input_tensor(ifm) |
| avgpool_op.set_output_tensor(intermediate_tens) |
| avgpool_op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, op) |
| |
| dw_conv = Operation(Op.DepthwiseConv2DBias, "depthwise_conv") |
| dw_conv._original_type = Op.ResizeBilinear |
| dw_conv.write_shape = Shape4D(n, h, w, c) |
| dw_conv.write_offset = Shape4D(0, 0, 0, 0) |
| |
| # Set the output rounding mode. Resize bilinear requires rounding away from zero. Therefore, we need to |
| # adjust the accumulated value by a "small" amount before applying natural rounding. The "small" amount |
| # should be big enough to cause a x.5 to be rounded correctly but small enough not to cause smaller |
| # values to be incorrectly rounded |
| ofm.quantization.next_after = True |
| dw_conv.rounding_mode = NpuRoundingMode.NATURAL |
| |
| # Double height and width stride to write the output of each of the four depthwise convolutions below |
| # interleaved with each other when combined with OFM tile base offsets. |
| dw_conv.ofm_stride_multiplier = [1, 2, 2] # C/H/W |
| |
| # Choose tile padding direction - pad by 1 with edge values in two direction. |
| # For example, TL (top left) will pad top and left in H/W-plane in all channels. |
| directions = [[1, 1, 0, 0], [1, 0, 0, 1], [0, 1, 1, 0], [0, 0, 1, 1]] # TL, TR, BL, BR |
| for i in (0, 1): |
| for j in (0, 1): |
| index = i * 2 + j |
| dw_conv.name = f"depthwise_conv_{index}" |
| dw_op_attrs["explicit_padding"] = directions[index] |
| dw_conv.attrs.update(dw_op_attrs) |
| |
| # This will offset the start of the write by modifying the Tile 0 base address |
| dw_conv.tile_base_offsets_ofm[0] = (i * ow + j) * c * elem_size |
| |
| ofm.ops.append(dw_conv) |
| dw_conv.outputs = [ofm] |
| |
| kernel = kernels[index] |
| shape = [2, 2, 1, c] |
| kernel = np.dstack([kernel] * c) |
| |
| quant = QuantizationParameters() |
| quant.zero_point = 0 |
| quant.scale_f32 = 1.0 / 16 |
| |
| dw_conv.inputs = [] |
| dw_conv.add_input_tensor(intermediate_tens) |
| dw_conv.add_input_tensor( |
| create_const_tensor( |
| "weights", |
| shape, |
| intermediate_tens.dtype, |
| np.array(kernel).reshape(shape), |
| quantization=quant, |
| ), |
| ) |
| |
| # setup bias tensor by assign None and then call the fix-up function to create a suitable tensor. |
| # need to append the bias tensor as resize ops only have 2 inputs |
| assert len(dw_conv.inputs) == 2 |
| dw_conv.inputs.append(None) |
| fixup_bias_tensors(dw_conv, None, None, dtype=DataType.int32) |
| |
| dw_conv.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, dw_conv) |
| |
| dw_conv = dw_conv.clone(f"_{index}") |
| return op |
| |
| _, input_height, input_width, _ = op.ifm.shape |
| _, output_height, output_width, _ = op.ofm.shape |
| |
| kernels = _compute_kernels(input_height, input_width, output_height, output_width) |
| op = _build_convolutions(op, kernels) |
| |
| return op |
| |
| |
| def fixup_resize(op, arch, nng): |
| if op.type.is_resize_op() and op.run_on_npu: |
| if op.ifm_shapes[0] == op.ofm_shapes[0]: |
| # Bypass the resize op which is essentially a NOP |
| op.inputs = op.inputs[:1] |
| op.type = Op.Identity |
| elif op.ifm_shapes[0].height == 1 and op.ifm_shapes[0].width == 1: |
| convert_resize_1x1_to_add(op) |
| elif op.type == Op.ResizeBilinear and op.attrs.get("half_pixel_centers", False): |
| convert_resizebilinear_to_depthwise_convolutions(op) |
| else: |
| convert_resize_to_upscale_and_average_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 rewrite_fully_connected_input(op: Operation, arch, nng): |
| |
| if op.type == Op.FullyConnected: |
| new_shape = op.ifm.get_shape_as_2d(op.weights.shape[-2]) |
| assert new_shape is not None, "Tensor can not be reshaped to 2D" |
| op.ifm_shapes[0] = new_shape |
| |
| if op.ifm_shapes[0].batch > 1 and op.ofm_shapes[0].batch == 1: |
| # If IFM is batching then also make sure OFM is batching |
| h, w = op.ofm_shapes[0].height, op.ofm_shapes[0].width |
| op.ofm_shapes[0] = Shape4D([h * w, 1, 1, op.ofm_shapes[0].depth]) |
| |
| return op |
| |
| |
| def convert_batched_fc_shape(op, arch, nng): |
| if op.type == Op.FullyConnected: |
| # Check if the first dimension indicates batching |
| if op.ifm_shapes[0].batch > 1: |
| batching_split = {4: (2, 2), 8: (2, 4), 16: (4, 4)} |
| n = op.ifm_shapes[0].batch |
| h, w = batching_split.get(n, (1, n)) |
| op.ifm_shapes[0] = Shape4D([1, h, w, op.ifm_shapes[0].depth]) |
| |
| # Reshape Weights to be 4D. IO becomes HWIO |
| weight_tensor = op.inputs[1] |
| weight_tensor.values = np.expand_dims(np.expand_dims(weight_tensor.values, axis=0), axis=0) |
| weight_tensor.set_all_shapes(list(weight_tensor.values.shape)) |
| |
| n = op.ofm_shapes[0].batch |
| h, w = batching_split.get(n, (1, n)) |
| op.ofm_shapes[0] = Shape4D([1, h, w, op.ofm_shapes[0].depth]) |
| return op |
| |
| |
| def unfuse_activation_function(op): |
| 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) |
| act_op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, act_op) |
| |
| |
| def rewrite_stridedslice_output(op, arch, nng): |
| if not op.run_on_npu or op.type != Op.StridedSlice: |
| return op |
| |
| new_axis_mask = op.attrs["new_axis_mask"] |
| shrink_axis_mask = op.attrs["shrink_axis_mask"] |
| |
| if shrink_axis_mask == 0 and new_axis_mask == 0: |
| return op |
| |
| axis_4D = [0] * len(op.outputs) |
| for idx, out_tens in enumerate(op.outputs): |
| output_shape = list(out_tens.shape) |
| |
| 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)) |
| output_shape = output_shape[:axis] + [1] + output_shape[axis:] |
| |
| assert len(out_tens.shape) == (len(op.inputs[0].shape) - n) |
| op.attrs["shrink_axis_mask"] = 0 |
| if axis >= 0: |
| axis_4D[idx] = axis + (4 - len(output_shape)) |
| else: |
| axis_4D[idx] = axis |
| op.ofm_shapes[idx] = Shape4D(output_shape) |
| |
| 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)) |
| output_shape = output_shape[:axis] + output_shape[(axis + 1) :] |
| new_axis_mask >>= 1 |
| |
| assert len(out_tens.shape) == (len(op.inputs[0].shape) + n) |
| op.attrs["new_axis_mask"] = 0 |
| if axis >= 0: |
| axis_4D[idx] = axis + (4 - len(output_shape)) |
| else: |
| axis_4D[idx] = axis |
| op.ofm_shapes[idx] = Shape4D(output_shape) |
| |
| op.attrs["split_axis_4D"] = axis_4D |
| return op |
| |
| |
| def rewrite_unpack_output(op, arch, nng): |
| tens = op.outputs[0] |
| if op.run_on_npu and op.type == Op.Unpack: |
| # Unpack is also referred to as Unstack |
| axis = int(op.attrs["axis"]) |
| if axis < 0: # Convert to positive axis |
| axis = len(op.inputs[0].shape) + 1 + axis |
| op.type = Op.UnpackReshaped |
| desired_output_shape = tens.shape[:axis] + [1] + tens.shape[axis:] |
| |
| axis_4D = axis + (4 - len(desired_output_shape)) |
| op.attrs["split_axis_4D"] = [axis_4D] * len(op.outputs) |
| |
| for idx, out_tens in enumerate(op.outputs): |
| op.ofm_shapes[idx] = Shape4D(desired_output_shape) |
| return op |
| |
| |
| def add_padding_fields(op, arch, nng): |
| if op.run_on_npu: |
| if "padding" in op.attrs: |
| input_shape = op.ifm_shapes[0] |
| output_shape = op.ofm_shapes[0] |
| if op.type.is_conv2d_op() or op.type.is_depthwise_conv2d_op(): |
| kernel_size = op.inputs[1].shape[:2] |
| elif op.type.is_pool_op() or op.type.npu_block_type == NpuBlockType.ReduceSum: |
| kernel_size = op.attrs["ksize"][1:3] |
| else: |
| raise UnsupportedFeatureError(f"Unknown operation that uses padding: {optype_to_builtintype(op.type)}") |
| |
| if op.type == Op.Conv2DBackpropInputSwitchedBias: |
| upscaling_factor = output_shape.height // input_shape.height |
| padding, skirt = calc_upscaled_padding_and_skirt( |
| op.attrs["padding"], kernel_size, op.attrs["strides"], input_shape, upscaling_factor |
| ) |
| else: |
| padding, skirt = calc_padding_and_skirt( |
| op.attrs["padding"], |
| op.kernel, |
| input_shape, |
| op.attrs.get("explicit_padding"), |
| ) |
| |
| op.attrs["explicit_padding"] = padding |
| op.attrs["skirt"] = skirt |
| |
| return op |
| |
| |
| def reorder_depthwise_weights(op, arch, nng): |
| if op.type.is_depthwise_conv2d_op(): |
| weight_tensor = op.inputs[1] |
| weight_tensor.values = np.transpose(weight_tensor.values, (0, 1, 3, 2)) |
| weight_tensor.set_all_shapes(list(weight_tensor.values.shape)) |
| weight_tensor.weight_transpose_depthwise = True |
| |
| return op |
| |
| |
| def fixup_strided_conv(op, arch, nng): |
| if op.type != Op.Conv2DBias: |
| return op |
| stride_x, stride_y = op.get_kernel_stride() |
| weight_tensor = op.weights |
| ifm_shape = op.ifm_shapes[0] |
| |
| # Do not optimize if op is not the first in the network and stride is |
| # supported by the hardware |
| if op.op_index != 0 and stride_x < 4: |
| return op |
| op.ifm.needs_linear_format = True |
| |
| if ( |
| (stride_x == 2 or stride_x == 4) |
| and ifm_shape.depth <= 4 |
| and ifm_shape.width % 2 == 0 |
| and weight_tensor is not None |
| and weight_tensor.shape[1] >= 2 |
| ): |
| k_w, _ = op.get_kernel_size() |
| curr_padding_x = needed_total_padding(ifm_shape.width, stride_x, k_w) |
| optimised_padding_x = needed_total_padding(ifm_shape.width // stride_x, 1, (k_w + 1) // stride_x) |
| padding_type = op.attrs.get("padding", None) |
| |
| # If padding is enabled, check if current padding matches optimised padding |
| if not padding_type or (padding_type != Padding.VALID and curr_padding_x != optimised_padding_x): |
| # Horizontal padding would become different after optimisation; this would not work |
| return op |
| # IFM |
| op.ifm_shapes[0] = Shape4D( |
| [ifm_shape.batch, ifm_shape.height, ifm_shape.width // stride_x, ifm_shape.depth * stride_x] |
| ) |
| |
| # Weights |
| weight_shape = weight_tensor.shape |
| if weight_shape[1] % 2 != 0: |
| weight_shape[1] = weight_shape[1] + 1 |
| padded_array = np.zeros(weight_shape) |
| for i in range(weight_shape[0]): |
| padded_array[i] = np.vstack( |
| [ |
| weight_tensor.values[i], |
| np.full((1, weight_shape[2], weight_shape[3]), weight_tensor.quantization.zero_point), |
| ] |
| ) |
| weight_tensor.values = padded_array |
| |
| # Change weight shape based on stride_x |
| weight_shape[1] //= stride_x |
| weight_shape[2] *= stride_x |
| |
| weight_tensor.values = np.reshape(weight_tensor.values, weight_shape) |
| weight_tensor.set_all_shapes(weight_shape) |
| # If multiple copies of the weights are used, we could avoid |
| # them having the same address by changing the value_id |
| weight_tensor.value_id = uuid.uuid4() |
| |
| # Strides |
| stride_x = 1 |
| op.attrs.update({"stride_w": stride_x, "stride_h": stride_y, "strides": (1, stride_y, stride_x, 1)}) |
| |
| 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 = op.ifm_shapes[0].height |
| w = op.ifm_shapes[0].width |
| 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.values = weight_tensor.values.squeeze(axis=(0, 1)) |
| weight_tensor.set_all_shapes(list(weight_tensor.values.shape)) |
| |
| 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) |
| # Add explicit rescaling |
| rescale = ifm.quantization.scale_f32 / ofm.quantization.scale_f32 |
| multiplier, shift = scaling.quantise_scale(rescale) |
| relu_fused_op.explicit_scaling = ExplicitScaling(False, [shift], [multiplier]) |
| # Tidy up and assign the ifm and ofm to the new op |
| ifm.consumer_list.remove(op) |
| |
| relu_fused_op.add_input_tensor(ifm) |
| relu_fused_op.set_output_tensor(ofm) |
| relu_fused_op.set_ifm_ofm_shapes() |
| op = relu_fused_op |
| 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_prelu(op, arch, nng): |
| if op.type == Op.Prelu: |
| ifm, alpha, ofm = op.get_ifm_ifm2_ofm() |
| if None in (ifm, alpha, ofm): |
| return op |
| |
| if alpha.values is not None: |
| # If const alpha check for possible optimisations |
| alpha_zp = alpha.quantization.zero_point |
| alpha_scale = alpha.quantization.scale_f32 |
| # If all alpha values are the same the PReLU can be converted to LeakyRelu |
| alpha_min = (alpha.values.min().astype(int) - alpha_zp) * alpha_scale |
| alpha_max = (alpha.values.max().astype(int) - alpha_zp) * alpha_scale |
| if alpha_min == alpha_max: |
| # or even a Relu |
| if alpha_min == 0: |
| new_op = Op.Relu |
| else: |
| new_op = Op.LeakyRelu |
| op.attrs["alpha"] = alpha_min |
| # setup alpha_scaling for bit exact result |
| ifm_scale = ifm.quantization.scale_f32 |
| ofm_scale = ofm.quantization.scale_f32 |
| alpha_scale, alpha_shift = scaling.elementwise_mul_scale(ifm_scale, alpha_scale, ofm_scale) |
| op.attrs["alpha_scaling"] = (alpha.values.min() - alpha_zp, alpha_scale, alpha_shift) |
| # Change op type |
| op.type = new_op |
| op.name = op.name.replace("Prelu", new_op.name) |
| del op.inputs[1] # Remove alpha tensor |
| return op |
| elif alpha_max < 1: |
| # If alpha_max is less than 1 convert PReLU to Max(alpha * IFM, identity * IFM) |
| # Multiply with alpha tensor |
| mul_alpha = Operation(Op.Mul, op.name + "_mul_alpha") |
| mul_alpha.add_input_tensor(ifm) |
| mul_alpha.add_input_tensor(alpha) |
| fm_alpha = ofm.clone(op.name + "_alpha", set_unique=True) |
| mul_alpha.set_output_tensor(fm_alpha) |
| mul_alpha.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, mul_alpha) |
| if check_quantized_tens_scaling_equal(ifm, ofm): |
| # No scaling 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.scale_f32 = np.float32(1) |
| quantization.zero_point = 0 |
| one = create_const_tensor("one_const", [], ifm.dtype, [1], quantization=quantization) |
| mul_identity.add_input_tensor(one) |
| # Make sure that fm_id is allocated to a different address than fm_alpha |
| fm_id = ofm.clone(op.name + "_id", set_unique=True) |
| mul_identity.set_output_tensor(fm_id) |
| mul_identity.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, mul_identity) |
| |
| # Combine scaled and alpha multiplied values |
| max_op = Operation(Op.Maximum, op.name + "_max") |
| max_op.add_input_tensor(fm_alpha) |
| max_op.add_input_tensor(fm_id) |
| max_op.set_output_tensor(ofm) |
| max_op.set_ifm_ofm_shapes() |
| |
| DebugDatabase.add_optimised(op, max_op) |
| ifm.consumer_list.remove(op) |
| return max_op |
| |
| # Catch all PReLU conversion for the cases that could not be optimised above |
| no_scale_quant = ifm.quantization.clone() |
| no_scale_quant.scale_f32 = None |
| no_scale_quant.zero_point = 0 |
| zero = create_const_tensor("zero_const", [], ifm.dtype, [0], quantization=no_scale_quant) |
| |
| # Select values < 0 |
| min_op = Operation(Op.Minimum, op.name + "_min") |
| min_op.add_input_tensor(ifm) |
| min_op.add_input_tensor(zero) |
| fm_negative = ifm.clone(op.name + "_negative", set_unique=True) |
| min_op.set_output_tensor(fm_negative) |
| min_op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, min_op) |
| |
| # and multiply with alpha tensor |
| mul_alpha = Operation(Op.Mul, op.name + "_mul_alpha") |
| mul_alpha.add_input_tensor(fm_negative) |
| mul_alpha.add_input_tensor(alpha) |
| fm_alpha = ofm.clone(op.name + "_negative_alpha", set_unique=True) |
| mul_alpha.set_output_tensor(fm_alpha) |
| mul_alpha.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, mul_alpha) |
| |
| # Select (and scale) values > 0 |
| relu_op = Operation(Op.Relu, op.name + "_relu") |
| relu_op.add_input_tensor(ifm) |
| fm_scaled = ofm.clone(op.name + "_positive_scaled", set_unique=True) |
| relu_op.set_output_tensor(fm_scaled) |
| relu_op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, relu_op) |
| |
| # Add scaled and alpha multiplied values (without scaling) |
| add_op = Operation(Op.Add, op.name + "_add") |
| add_op.explicit_scaling = ExplicitScaling(False, shift=[0], multiplier=[1]) # No scaling |
| add_op.add_input_tensor(fm_alpha) |
| add_op.add_input_tensor(fm_scaled) |
| add_op.set_output_tensor(ofm) |
| add_op.set_ifm_ofm_shapes() |
| |
| DebugDatabase.add_optimised(op, add_op) |
| ifm.consumer_list.remove(op) |
| op = add_op |
| |
| 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_ifms = [m for m in muls if len(set(op.inputs + m.ops[0].inputs)) == 1] |
| if len(mul_ifms): |
| mul = mul_ifms[0].ops[0] |
| else: |
| # Not using same input |
| return op |
| 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.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] |
| op.set_ifm_ofm_shapes() |
| |
| # Record optimisation in debug database |
| DebugDatabase.add_optimised(op, op) |
| |
| return op |
| |
| |
| def convert_hardswish_to_lut(op, arch, nng): |
| if op.type == Op.HardSwish: |
| ifm, ofm = op.get_ifm_ofm() |
| # 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 |
| ifm_scale_hires = (1 / 128) * ifm_scale |
| relu_multiplier = np.double(3 / 32768) |
| out_scale, out_shift = scaling.quantise_scale(ifm_scale_hires / ofm_scale) |
| relu_scale, relu_shift = scaling.quantise_scale(ifm_scale_hires / relu_multiplier) |
| # Use 16bit scale |
| out_scale_16 = fp_math.downscale_multiplier_int32_to_int16(out_scale) |
| relu_scale_16 = fp_math.downscale_multiplier_int32_to_int16(relu_scale) |
| |
| 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: |
| input_value = x - zp_in |
| input_value_hires = input_value * 128 |
| # Compute the input value on essentially the output scale, not shifted yet |
| input_value_preshift = fp_math.saturating_rounding_mul16(input_value_hires, out_scale_16) |
| # Compute the "relu-ish multiplier". This matches the code in TensorFlow Lite Micro kernel |
| relu_value = np.int16(input_value_hires) |
| if relu_shift < 31: |
| relu_value = fp_math.shift_left16(relu_value, 30 - relu_shift) |
| |
| relu_value = fp_math.saturating_rounding_mul16(relu_value, relu_scale_16) |
| |
| if relu_shift < 31: |
| relu_value = fp_math.shift_left16(relu_value, 1) |
| |
| if relu_shift > 31: |
| relu_value = fp_math.rounding_divide_by_pot(relu_value, relu_shift - 31) |
| |
| # Rescaled the value into a 16bit fixedpoint relu_value in [-1, 1] |
| # Now convert that to a 16bit fixedpoint value in [0, 1] |
| relu_value = (relu_value + (1 << 15)) >> 1 |
| lut_result = fp_math.saturating_mul16(relu_value, input_value_preshift) |
| shift = 31 - out_shift |
| shift = -shift if shift < 0 else 0 |
| # Finally apply the output shift |
| lut_result = fp_math.rounding_divide_by_pot(lut_result, shift) + zp_out |
| lut_result = min(quantized_max, max(quantized_min, lut_result)) |
| values.append(lut_result) |
| return convert_to_lut(op, values, "hardswish") |
| 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 |
| |
| alpha = np.float32(op.attrs["alpha"]) |
| use_mul_max = 0 < alpha < 1 |
| is_converted_prelu = "alpha_scaling" in op.attrs |
| if use_mul_max: |
| mul_ifm = ifm |
| new_op = Op.Maximum |
| else: |
| # Need to use a different approach for alpha < 0 or alpha > 1 |
| no_scale_quant = ifm.quantization.clone() |
| no_scale_quant.scale_f32 = None |
| no_scale_quant.zero_point = 0 |
| zero = create_const_tensor("zero_const", [], ifm.dtype, [0], quantization=no_scale_quant) |
| |
| # Select values < 0 |
| min_op = Operation(Op.Minimum, op.name + "_min") |
| min_op.add_input_tensor(ifm) |
| min_op.add_input_tensor(zero) |
| mul_ifm = ifm.clone(op.name + "_negative", set_unique=True) |
| if alpha < 0 and not is_converted_prelu: |
| # For negative alpha that is not from a converted PReLU we need to use |
| # int32 Mul below to perform the (negative) alpha scaling |
| mul_ifm.dtype = DataType.int32 |
| min_op.set_output_tensor(mul_ifm) |
| min_op.set_ifm_ofm_shapes() |
| new_op = Op.Add |
| op.explicit_scaling = ExplicitScaling(False, shift=[0], multiplier=[1]) # No scaling |
| DebugDatabase.add_optimised(op, min_op) |
| |
| # Add multiplication with alpha |
| mul_alpha = Operation(Op.Mul, op.name + "_mul_alpha") |
| mul_alpha.add_input_tensor(mul_ifm) |
| # Create const tensor containing alpha as scalar |
| quantization = ifm.quantization.clone() |
| quantization.min = 0 |
| quantization.max = alpha * (quantization.quant_max - quantization.quant_min) |
| quantization.zero_point = 0 |
| alpha_dtype = mul_ifm.dtype |
| if is_converted_prelu: |
| # The LeakyRelu was the result from convert_prelu and the scaling is provided |
| scalar, alpha_scale, alpha_shift = op.attrs["alpha_scaling"] |
| mul_alpha.explicit_scaling = ExplicitScaling(False, [alpha_shift], [alpha_scale]) |
| elif alpha == 0 or np.isinf(1 / alpha): |
| # Handling of alpha near or at zero |
| quantization.scale_f32 = np.float32(1) |
| scalar = 0 |
| else: |
| quantization.scale_f32 = alpha |
| if alpha_dtype == DataType.int32: |
| # When the datatype is int32 (alpha negative) we need to do the scaling with the multiplication |
| scalar, _ = scaling.elementwise_mul_scale(ifm.quantization.scale_f32, alpha, ofm.quantization.scale_f32) |
| else: |
| scalar = 1 |
| alpha_tens = create_const_tensor(op.name + "_alpha_scalar", [1], alpha_dtype, [scalar], quantization=quantization) |
| mul_alpha.add_input_tensor(alpha_tens) |
| fm_alpha = ofm.clone(op.name + "_alpha", set_unique=True) |
| mul_alpha.set_output_tensor(fm_alpha) |
| mul_alpha.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, mul_alpha) |
| |
| if not use_mul_max: |
| relu_op = Operation(Op.Relu, op.name + "_relu") |
| relu_op.add_input_tensor(ifm) |
| fm_id = ofm.clone(op.name + "_positive_scaled", set_unique=True) |
| relu_op.set_output_tensor(fm_id) |
| relu_op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, relu_op) |
| elif 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 = np.float32(1) |
| quantization.zero_point = 0 |
| identity_tens = create_const_tensor(op.name + "_id_scalar", [], ifm.dtype, [1], quantization=quantization) |
| mul_identity.add_input_tensor(identity_tens) |
| # Make sure that fm_id is allocated to a different address than fm_alpha |
| fm_id = ofm.clone(op.name + "_id", set_unique=True) |
| mul_identity.set_output_tensor(fm_id) |
| mul_identity.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, mul_identity) |
| |
| # Convert LeakyRelu to Max, add the results of the multiplication(s) as inputs |
| op.type = new_op |
| op.name = op.name.replace("LeakyRelu", new_op.name) |
| op.inputs = [] |
| ifm.consumer_list.remove(op) |
| op.add_input_tensor(fm_alpha) |
| op.add_input_tensor(fm_id) |
| op.set_ifm_ofm_shapes() |
| |
| DebugDatabase.add_optimised(op, op) |
| 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 |
| alpha = op.attrs["alpha"] |
| if alpha == 0: |
| # When alpha is 0 the opertion can be converted to a ReLU |
| op.type = Op.Relu |
| op.name = op.name.replace("LeakyRelu", op.type.name) |
| 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 and alpha > 0: |
| # use LeakyRelu unmodified for int16 with equal input/output scaling and positive alpha |
| 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_memory_only_ops(op, arch): |
| if op.run_on_npu and op.type in memory_only_ops: |
| bypass_memory_only_ops(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(prev_op, prev_op) |
| return op |
| |
| |
| def _leading_pad_ok(leading_pad, stride, kernel_size): |
| # If kernel size // 2 > stride, then (left, top) padding must be a multiple of stride, |
| # otherwise replacing PAD by hardware padding would iterate the wrong IFM rows/columns |
| max_size = kernel_size // 2 |
| return leading_pad == max_size or max_size <= stride or leading_pad % stride == 0 |
| |
| |
| def replace_pad_by_hw_pad(op: Operation, arch, nng): |
| """ |
| Tries to completely remove a PAD operator by using hardware padding. |
| E.g. a PAD operation that pads 1, followed by a CONV with VALID padding and kernel size 3 |
| is rewritten such that the PAD is removed, and the CONV uses SAME padding. |
| Converts tens1 -> PAD -> tens2 -> CONV to tens1 -> CONV |
| if both operations can be run on the NPU. |
| This is the most efficient way to implement PAD, but cannot be done for all pad sizes. |
| """ |
| if ( |
| (op.type.is_conv2d_op() or op.type.is_depthwise_conv2d_op() or op.type.is_avgpool_op()) |
| and op.type not in (Op.Conv2DBackpropInput, Op.Conv2DBackpropInputSwitchedBias) |
| and op.run_on_npu |
| and op.attrs["padding"] == Padding.VALID |
| ): |
| pad_op = op.ifm.ops[0] |
| if pad_op.type != Op.Pad or not pad_op.run_on_npu: |
| return op |
| if pad_op.ifm.dtype != pad_op.ofm.dtype or not check_quantized_tens_scaling_equal(pad_op.ofm, pad_op.ifm): |
| return op |
| top, left, bottom, right = get_pad_values_from_input(pad_op.inputs[1].values) |
| k = op.kernel |
| k_w, k_h = k.dilated_wh() |
| |
| # Check if the PAD operator can be replaced by hardware padding |
| if left > k_w // 2 or right > k_w // 2 or top > k_h // 2 or bottom > k_h // 2: |
| # Too much padding, it would require hardware padding to actually insert zeros |
| return op |
| if not _leading_pad_ok(top, k.stride.y, k_h) or not _leading_pad_ok(left, k.stride.x, k_w): |
| return op |
| |
| if op.type.is_avgpool_op(): |
| # For average pool, hardware padding can only be used if padding is 0 or kernel size / 2 |
| for pad, k_size in ( |
| (left, k_w), |
| (right, k_w), |
| (top, k_h), |
| (bottom, k_h), |
| ): |
| if pad not in (0, k_size // 2): |
| return op |
| # Average pool is converted to depthwise, because NPU average pool + same padding |
| # has a special implementation that is different from PAD followed by average pool with |
| # valid padding. |
| k_w, k_h = op.kernel.width, op.kernel.height |
| ifm = op.ifm |
| # Remember other inputs |
| other_inputs = op.inputs[1:] |
| # Create a weight tensor, all weights are set to 1/(kernel width * kernel height) |
| quantization = QuantizationParameters(0.0, 255.0) |
| quantization.scale_f32 = 1.0 / (k_w * k_h) |
| quantization.zero_point = 0 |
| shape = [k_h, k_w, 1, op.ofm.shape[-1]] |
| weights = np.full(shape, 1) |
| |
| weight_tens = create_const_tensor( |
| op.name + "_weights", |
| shape, |
| op.ifm.dtype, |
| weights, |
| purpose=TensorPurpose.Weights, |
| quantization=quantization, |
| ) |
| weight_tens.values = weights |
| op.type = Op.DepthwiseConv2DBias |
| op.inputs = [] |
| op.add_input_tensor(ifm) |
| op.add_input_tensor(weight_tens) |
| # Add bias tensor, all biases set to 0 |
| op.inputs.append(None) |
| fixup_bias_tensors(op, arch, nng, DataType.int32) |
| # Add other inputs |
| op.inputs.extend(other_inputs) |
| op.rounding_mode = NpuRoundingMode.NATURAL |
| |
| # Bypass the PAD operator |
| op.set_input_tensor(pad_op.ifm, 0) |
| # Adjust the padding attributes of the convolution operator |
| op.attrs["padding"] = Padding.EXPLICIT |
| op.attrs["explicit_padding"] = (top, left, bottom, right) |
| op.set_ifm_ofm_shapes() |
| DebugDatabase.add_optimised(op, op) |
| |
| return op |
| |
| |
| def convert_pad(op: Operation, arch, nng): |
| """ |
| Rewrites PAD operator to an average pool that copies the IFM to the OFM |
| + up to 4 average pool operators that fill the OFM with zeros at the borders. |
| This is done as fall-back for the PAD operators that remain after replace_pad_by_hw_pad |
| """ |
| if op.type != Op.Pad or not op.run_on_npu: |
| return op |
| top, left, bottom, right = get_pad_values_from_input(op.inputs[1].values) |
| |
| ifm = op.ifm |
| assert ifm is not None |
| ifm_shape = op.ifm_shapes[0] |
| ofm = op.ofm |
| assert ofm is not None |
| ofm.ops = [] |
| ofm_shape = op.ofm_shapes[0] |
| |
| # Average pool op that copies IFM to the right place inside the OFM |
| shp0 = Shape4D(0, 0, 0, 0) |
| shp_top = shp0.with_height(top) |
| avgpool_op = create_avg_pool_for_concat(op, op.name + "_main", ifm, ifm_shape, shp_top.with_width(left)) |
| avgpool_op.activation = op.activation |
| quant = ofm.quantization |
| pad_value = quant.zero_point |
| # Add operations that fill the borders of the OFM |
| if top > 0: |
| shape = Shape4D(1, top, ofm_shape.width, ofm_shape.depth) |
| zero_tens = create_const_tensor( |
| op.name + "_top", shape.as_list(), ofm.dtype, shape.elements() * [pad_value], quantization=quant |
| ) |
| # If top/bottom or left/right are equal, the const tensors can be allocated to the same address |
| zero_tens.equivalence_id = create_equivalence_id(tuple(zero_tens.values)) |
| create_avg_pool_for_concat(op, op.name + "_top", zero_tens, shape, shp0) |
| if bottom > 0: |
| shape = Shape4D(1, bottom, ofm_shape.width, ofm_shape.depth) |
| zero_tens = create_const_tensor( |
| op.name + "_bottom", |
| shape.as_list(), |
| ofm.dtype, |
| shape.elements() * [pad_value], |
| quantization=quant, |
| ) |
| zero_tens.equivalence_id = create_equivalence_id(tuple(zero_tens.values)) |
| create_avg_pool_for_concat( |
| op, op.name + "_bottom", zero_tens, shape, shp0.with_height(ofm_shape.height - bottom) |
| ) |
| if left > 0: |
| shape = Shape4D(1, ifm_shape.height, left, ofm_shape.depth) |
| zero_tens = create_const_tensor( |
| op.name + "_left", shape.as_list(), ofm.dtype, shape.elements() * [pad_value], quantization=quant |
| ) |
| zero_tens.equivalence_id = create_equivalence_id(tuple(zero_tens.values)) |
| create_avg_pool_for_concat(op, op.name + "_left", zero_tens, shape, shp_top) |
| if right > 0: |
| shape = Shape4D(1, ifm_shape.height, right, ofm_shape.depth) |
| zero_tens = create_const_tensor( |
| op.name + "_right", shape.as_list(), ofm.dtype, shape.elements() * [pad_value], quantization=quant |
| ) |
| zero_tens.equivalence_id = create_equivalence_id(tuple(zero_tens.values)) |
| create_avg_pool_for_concat( |
| op, op.name + "_right", zero_tens, shape, shp_top.with_width(ofm_shape.width - right) |
| ) |
| |
| op.type = Op.ConcatTFLite |
| return avgpool_op |
| |
| |
| def fixup_bias_tensors(op, arch, nng, dtype=None): |
| 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 |
| # The DataType of the bias tensor can be explicitly provided or deduced from the ifm |
| # DataType. Default is int32 bias for 8-bit ifms and int64 for int16 ifms. |
| # For int16 the selected bias DataType will have an impact on the scaling |
| # used when encoding the scales and biases later. The default mode will match the |
| # refence with reduced scaling for int64 bias. |
| # This means that in cases (in the graph optimiser) where DepthwiseConv2DBias |
| # is used to emulate average pool int32 bias should be selected for full precision |
| # int16 scaling. |
| if dtype is None: |
| dtype = DataType.int64 if op.ifm.dtype == DataType.int16 else DataType.int32 |
| bias_tensor = create_const_tensor(op.name + "_bias", [nr_biases], dtype, bias_values) |
| op.set_input_tensor(bias_tensor, op.type.info.indices.biases[0]) |
| |
| return op |
| |
| |
| def fixup_asymmetric_weights(op, arch, nng): |
| if op.run_on_npu and (op.type.is_conv2d_op() or op.type.is_depthwise_conv2d_op()): |
| if op.ifm.dtype == DataType.int8: |
| if not np.all(op.weights.quantization.zero_point == 0): |
| print(f"Warning: {op.type} '{op.name}' has asymmetric weights, zero points have been adjusted.") |
| op.weights.quantization.zero_point *= 0 |
| |
| return op |
| |
| |
| def convert_mean_to_depthwise_conv_or_avgpool(op, arch, nng): |
| if op.type == Op.Mean and op.run_on_npu: |
| inp, axis = op.inputs |
| shape = inp.shape |
| ofm_shape = op.ofm.shape |
| dims = len(shape) |
| dims_ofm = len(ofm_shape) |
| |
| # Height and width axes have different index depending on dimensions |
| if axis.shape == [] or axis.shape[0] == 1: # single axis |
| axis = int(axis.values) if len(axis.shape) == 0 else int(axis.values[0]) |
| if dims in (2, 3): |
| if axis == 0: |
| h, w = shape[axis], 1 |
| else: |
| h, w = 1, shape[axis] |
| else: |
| if axis == 1: |
| h, w = shape[axis], 1 |
| else: |
| h, w = 1, shape[axis] |
| else: # multiple axes |
| axis = sorted(axis.values) |
| h, w = [shape[i] for i in axis] |
| |
| # Set necessary depthwise attributes |
| op.attrs.update( |
| { |
| "padding": Padding.VALID, |
| "stride_h": 1, |
| "stride_w": 1, |
| "strides": (1, 1, 1, 1), |
| "depth_multiplier": 1, |
| "channel_multiplier": 1, |
| "dilation_h_factor": 1, |
| "dilation_w_factor": 1, |
| "dilation": (1, 1, 1, 1), |
| } |
| ) |
| # Change op type |
| op.type = Op.DepthwiseConv2DBias |
| # Set IFM/OFM shapes after changing op type |
| op.set_ifm_ofm_shapes() |
| |
| weight_scale, bias = 1, 0 |
| ofmq, ifmq = op.ofm.quantization, inp.quantization |
| if ifmq.is_scaling_equal(ofmq): |
| # Here we can just use a simple AvgPool with truncating rounding, |
| # as we're emulating simple integer division. |
| op.rounding_mode = NpuRoundingMode.TRUNCATE |
| op.type = Op.AvgPool |
| op.attrs.update({"ksize": (1, h, w, 1), "filter_height": h, "filter_width": w}) |
| else: |
| op.rounding_mode = NpuRoundingMode.NATURAL |
| weight_scale = 1 / (h * w) |
| # Input zero point is adjusted after mean calculation, so we emulate that with a bias |
| bias = -ifmq.zero_point * h * w |
| fiq = ifmq.clone() |
| fiq.zero_point = 0 |
| op.forced_input_quantization = fiq |
| |
| # Change dimensions to 4 |
| def extend_dims(dim, in_shape): |
| if dim < 4: |
| in_shape = [1] + in_shape |
| if dim == 2: |
| in_shape += [1] |
| return in_shape |
| |
| if dims < 4 or dims_ofm < 4: |
| # Fix the ofm dimension when keep_dims is false |
| # e.g. IFM=1xHxWxC axis=2 OFM=1xHxC, the ofm_shape should be 1xHx1xC, not 1x1xHxC |
| if isinstance(axis, int) and dims_ofm + 1 == dims: |
| ofm_shape.insert(axis, 1) |
| elif isinstance(axis, list) and (dims_ofm + len(axis) == dims): |
| for i in axis: |
| ofm_shape.insert(i, 1) |
| shape = extend_dims(dims, shape) |
| dims_ofm = len(ofm_shape) |
| ofm_shape = extend_dims(dims_ofm, ofm_shape) |
| op.set_ifm_ofm_shapes() |
| |
| # If height is greater than max kernel height, reshape from HxW to 1x(HxW) |
| weight_shape = None |
| if (h > 64 and op.type == Op.DepthwiseConv2DBias) or (h > 256 and op.type == Op.AvgPool): |
| # This can only happen and be done for multiple axes, and |
| # h * w <= 256 for DepthwiseConv2DBias |
| # h * w <= 4096 for AvgPool |
| # which is checked in supported ops |
| shape = [shape[0], 1, h * w, shape[3]] |
| op.ifm_shapes[0] = Shape4D(shape) |
| weight_shape = [1, h * w, shape[3], shape[0]] |
| if h > 256 and op.type == Op.AvgPool: |
| op.attrs.update({"ksize": (1, 1, h * w, 1), "filter_height": 1, "filter_width": h * w}) |
| |
| # If the AvgPool version is used, we don't need to do anything else |
| if op.type == Op.AvgPool: |
| DebugDatabase.add_optimised(op, op) |
| return op |
| |
| # Make unit weight tensor quantization |
| weight_quant = ifmq.clone() |
| weight_quant.min = 0 |
| weight_quant.max = 255 |
| weight_quant.scale_f32 = weight_scale |
| weight_quant.zero_point = 0 |
| |
| if weight_shape is None: |
| # Set weight shape to [H,W,C,B] |
| weight_shape = [h, w, shape[3], shape[0]] |
| |
| # Add unit weight tensor |
| op.set_input_tensor( |
| create_const_tensor( |
| "weights", |
| weight_shape, |
| inp.dtype, |
| np.ones(weight_shape), |
| quantization=weight_quant, |
| ), |
| 1, |
| ) |
| op.weights.values = np.reshape(op.inputs[1].values, weight_shape) |
| |
| # Add bias tensor |
| bias_shape = [shape[-1]] |
| op.inputs.append(create_const_tensor("bias", bias_shape, DataType.int32, np.ones(bias_shape) * bias)) |
| DebugDatabase.add_optimised(op, op) |
| |
| return op |
| |
| |
| def optimise_quantize(op: Operation, arch, nng): |
| |
| if op.type == Op.Quantize and op.run_on_npu: |
| |
| ifm, ofm = op.get_ifm_ofm() |
| input_values = ifm.values |
| |
| # Guard clause - input not const or no values to quantize |
| if ifm.ops[0].type != Op.Const or input_values is None: |
| return op |
| |
| # Singular val in numpy array, convert to indexable array |
| if input_values.ndim == 0: |
| input_values = np.array([input_values]) |
| |
| # requantized int8 to int8 or int16 to int16 |
| if ifm.dtype == ofm.dtype == DataType.int8 or ifm.dtype == ofm.dtype == DataType.int16: |
| |
| # scale needs to use double precision to match TFLite reference kernel |
| effective_scale = np.float64(ifm.quantization.scale_f32) / np.float64(ofm.quantization.scale_f32) |
| effective_multiplier, effective_shift = quantise_scale(effective_scale) |
| |
| requantized_vals = [] |
| for val in input_values.flatten(): |
| input_val = val - ifm.quantization.zero_point |
| |
| ofm_val = fp_math.multiply_by_quantized_multiplier(input_val, effective_multiplier, effective_shift) |
| ofm_val += ofm.quantization.zero_point |
| |
| clamped_ofm_value = max(min(ofm_val, ofm.quantization.quant_max), ofm.quantization.quant_min) |
| requantized_vals.append(clamped_ofm_value) |
| |
| ofm.values = np.array(requantized_vals, ofm.dtype.as_numpy_type()) |
| ofm.values.shape = input_values.shape |
| |
| # Case: Float input - quantize to int |
| elif ifm.dtype.type == BaseType.Float: |
| |
| quantized_vals = [] |
| for val in input_values: |
| |
| # Derive quantized value |
| quant_val = (val / ofm.quantization.scale_f32) + ofm.quantization.zero_point |
| clamped_quantized_val = np.clip(quant_val, ofm.quantization.quant_min, ofm.quantization.quant_max) |
| quantized_vals.append(clamped_quantized_val) |
| |
| # Pass the statically calculated quant val to output tensor |
| ofm.values = np.array(quantized_vals, ofm.dtype.as_numpy_type()) |
| |
| # Unsupported data type |
| else: |
| return op |
| |
| # Make quantize op const and disconnect from parent node |
| |
| # Remove reference of the current quant op from the parent tensor's consumer list |
| ifm.consumer_list = [consumer for consumer in ifm.consumer_list if consumer.op_index != op.op_index] |
| |
| # Clear any references to parent node |
| op.inputs = [] |
| |
| # Convert this quantize op to const |
| op.type = Op.Const |
| |
| return op |
| |
| |
| def convert_shape_op_to_constant_tensor(op: Operation, arch, nng): |
| """Static optimisation for SHAPE operator output value known at compile time""" |
| |
| # Disconnect SHAPE operator from its parent and transform SHAPE OP into constant |
| |
| if op.type == Op.Shape and op.run_on_npu: |
| |
| ifm, ofm = op.get_ifm_ofm() |
| |
| if len(ifm.shape) != ofm.shape[0]: |
| return op |
| |
| # Remove reference of the current shape op from the parent tensor's consumer list |
| ifm.consumer_list = [consumer for consumer in ifm.consumer_list if consumer.op_index != op.op_index] |
| |
| # Clear any references to parent node |
| op.inputs = [] |
| |
| # Convert this SHAPE op to const |
| op.type = Op.Const |
| |
| # Add size calculation to shape output tensors |
| ofm.values = np.array(ifm.shape) |
| |
| return op |
| |
| |
| def fixup_dilation_gt2(op, arch, nng): |
| assert op.run_on_npu |
| if op.type == Op.Conv2DBias or op.type == Op.DepthwiseConv2DBias: |
| dilation_w, dilation_h = op.get_kernel_dilation() |
| |
| # if dilation in either axis is greater than that supported by the hardware then we must manually dilate the |
| # kernel |
| if dilation_w > 2 or dilation_h > 2: |
| kernel_w, kernel_h = op.get_kernel_size() |
| kernel_ic = op.weights.shape[-2] |
| kernel_oc = op.weights.shape[-1] |
| |
| # if the dilation is a multiple of 2 then the hardware dialtion can be enabled to provide that multiple |
| # of 2. this allows the kernel size to be reduced (via the scaled dilation) by half in that dimension. |
| # odd = 1, even = 2 |
| hw_dilation_h = 1 if (dilation_h & 1) else 2 |
| hw_dilation_w = 1 if (dilation_w & 1) else 2 |
| |
| scale_dilation_h = dilation_h // hw_dilation_h |
| scale_dilation_w = dilation_w // hw_dilation_w |
| |
| # create new empty kernel (HWIO format) |
| new_kernel_h = (kernel_h - 1) * scale_dilation_h + 1 |
| new_kernel_w = (kernel_w - 1) * scale_dilation_w + 1 |
| |
| new_kernel_shape = [new_kernel_h, new_kernel_w, kernel_ic, kernel_oc] |
| new_kernel_values = np.zeros(new_kernel_shape, dtype=op.weights.values.dtype) |
| |
| # copy the original kernel values into the new sparse kernel |
| for h in range(0, kernel_h): |
| for w in range(0, kernel_w): |
| new_h = h * scale_dilation_h |
| new_w = w * scale_dilation_w |
| new_kernel_values[new_h, new_w, :, :] = op.weights.values[h, w, :, :] |
| |
| # update the weight tensor with the new dilated kernel |
| op.weights.shape = new_kernel_shape |
| op.weights.values = new_kernel_values |
| |
| # enable(=2) / disable(=1) hardware dilation |
| op.attrs["dilation"] = (1, hw_dilation_h, hw_dilation_w, 1) # nhwc format |
| op.attrs["dilation_h_factor"] = hw_dilation_h |
| op.attrs["dilation_w_factor"] = hw_dilation_w |
| |
| return op |
| |
| |
| def supported_operator_check(op, arch, nng): |
| op.run_on_npu = arch.tflite_supported_operators.is_operator_supported(op) |
| return op |
| |
| |
| def tflite_optimise_graph(nng, arch): |
| # Compile time static optimisations |
| optimisation_list = [optimise_quantize, convert_shape_op_to_constant_tensor] |
| |
| for idx, sg in enumerate(nng.subgraphs): |
| nng.subgraphs[idx] = rewrite_graph.rewrite_graph_pre_order( |
| nng, |
| sg, |
| arch, |
| [], |
| optimisation_list, |
| rewrite_unsupported=False, |
| ) |
| |
| # Pre-processing step |
| pre_process_list = [ |
| supported_operator_check, |
| set_ifm_ofm_op_shapes, |
| ] |
| |
| for idx, sg in enumerate(nng.subgraphs): |
| nng.subgraphs[idx] = rewrite_graph.rewrite_graph_pre_order( |
| nng, |
| sg, |
| arch, |
| [], |
| pre_process_list, |
| rewrite_unsupported=False, |
| ) |
| |
| # Handle Concat Ops |
| for idx, sg in enumerate(nng.subgraphs): |
| rewrite_graph.visit_graph_post_order(sg.output_tensors, arch, [], [rewrite_concat_ops]) |
| sg.refresh_after_modification() |
| |
| # Handle Split Ops |
| for idx, sg in enumerate(nng.subgraphs): |
| nng.subgraphs[idx] = rewrite_graph.rewrite_graph_pre_order( |
| nng, |
| sg, |
| arch, |
| [], |
| [rewrite_unpack_output, rewrite_stridedslice_output, convert_nop_split_to_identity], |
| rewrite_unsupported=False, |
| ) |
| |
| for idx, sg in enumerate(nng.subgraphs): |
| nng.subgraphs[idx] = rewrite_graph.rewrite_graph_pre_order( |
| nng, |
| sg, |
| arch, |
| [rewrite_split_ops], |
| [], |
| rewrite_unsupported=False, |
| ) |
| |
| # Handle sg input output |
| for idx, sg in enumerate(nng.subgraphs): |
| nng.subgraphs[idx] = rewrite_graph.rewrite_graph_pre_order( |
| nng, |
| sg, |
| arch, |
| [], |
| [fix_sg_input_output], |
| rewrite_unsupported=False, |
| ) |
| |
| # Removal of memory only operators |
| for sg in nng.subgraphs: |
| rewrite_graph.visit_graph_post_order(sg.output_tensors, arch, [], [remove_memory_only_ops]) |
| sg.refresh_after_modification() |
| |
| # Rewrite of operators |
| op_rewrite_list = [ |
| set_tensor_equivalence, |
| convert_mean_to_depthwise_conv_or_avgpool, |
| convert_depthwise_to_conv, |
| convert_conv_to_fc, |
| convert_softmax, |
| convert_prelu, |
| convert_mul_max_to_abs_or_lrelu, |
| convert_lrelu, |
| fixup_strided_conv, |
| convert_hardswish_to_lut, |
| rewrite_fully_connected_input, |
| convert_batched_fc_shape, |
| fixup_conv2d_backprop, |
| fixup_relus_with_differing_ifm_ofm_scaling, |
| reorder_depthwise_weights, |
| fixup_resize, |
| fixup_bias_tensors, |
| fixup_asymmetric_weights, |
| convert_tanh_sigmoid_to_lut, |
| replace_pad_by_hw_pad, |
| fixup_dilation_gt2, |
| ] |
| |
| for idx, sg in enumerate(nng.subgraphs): |
| 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, convert_pad, add_padding_fields], |
| ) |
| |
| # Removal of SplitSliceRead, need to be done after optimisation has been performed, |
| # since ifm/ofm_shapes are of importance to this function |
| for sg in nng.subgraphs: |
| rewrite_graph.visit_graph_post_order(sg.output_tensors, arch, [], [remove_SplitSliceRead]) |
| sg.refresh_after_modification() |
| |
| # Make sure that const optimisations on subgraph outputs are handled correctly |
| for sg in nng.subgraphs: |
| for ofm in sg.output_tensors: |
| if ofm.is_const and ofm.ops[0].type_changed: |
| # Subgraph output cannot be const - insert a memory copy |
| op = ofm.ops[0] |
| ofm_clone = ofm.clone() |
| ofm_clone.values = ofm.values |
| ofm.values = None |
| zero = create_const_tensor("zero", [1], ofm.dtype, [0], quantization=ofm.quantization) |
| memcpy = create_add_nop(f"{ofm.name}_copy") |
| memcpy.add_input_tensor(ofm_clone) |
| memcpy.add_input_tensor(zero) |
| memcpy.set_output_tensor(ofm) |
| memcpy.set_ifm_ofm_shapes() |
| op.set_output_tensor(ofm_clone) |
| DebugDatabase.add_optimised(op, memcpy) |
| |
| return nng |