| # Copyright (C) 2021 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: |
| # Common functions and definitions used during the graph optimization. |
| from typing import Tuple |
| |
| from .data_type import DataType |
| from .debug_database import DebugDatabase |
| from .errors import VelaError |
| from .operation import Op |
| from .shape4d import Shape4D |
| from .tensor import check_quantized_tens_scaling_equal |
| |
| |
| memory_only_ops = ( |
| Op.Reshape, |
| Op.Squeeze, |
| ) |
| |
| |
| def _avoid_nhcwb16_for_concat(tens): |
| # 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. |
| return any(op.write_offset.depth % 16 != 0 for op in tens.ops if op.write_offset is not None) |
| |
| |
| def _avoid_nhcwb16_for_split(tens): |
| # If read offset is not a multiple of 16 in the C-dimension, NHCWB16 need to be avoided in the input |
| for cons_op in tens.consumer_list: |
| if cons_op.ifm == tens: |
| read_offset = cons_op.read_offsets[0] |
| elif cons_op.type.is_binary_elementwise_op() and cons_op.ifm2 == tens: |
| read_offset = cons_op.read_offsets[1] |
| else: |
| assert False |
| if read_offset is not None and (read_offset[-1] % 16) != 0: |
| return True |
| return False |
| |
| |
| def _avoid_nhcwb16_for_shapes(tens): |
| # check all producers/consumers to see if any op shape is preventing NHCWB16 |
| for cons_op in tens.consumer_list: |
| if cons_op.ifm == tens: |
| cons_op_shape = cons_op.ifm_shapes[0] |
| elif cons_op.type.is_binary_elementwise_op() and cons_op.ifm2 == tens: |
| cons_op_shape = cons_op.ifm_shapes[1] |
| else: |
| assert False |
| if Shape4D(tens.shape) != cons_op_shape: |
| return True |
| |
| for prod_op in tens.ops: |
| if Shape4D(tens.shape) != prod_op.ofm_shapes[0]: |
| return True |
| |
| return False |
| |
| |
| # Check if non linear format can be used |
| def check_format_restrictions(tens, arch): |
| if len(tens.ops) < 1: |
| return |
| if tens.ops[0].type in (Op.Placeholder, Op.SubgraphInput, Op.Const) or any( |
| cons is None for cons in tens.consumer_list |
| ): |
| return |
| |
| # Check if any of the producers/consumers is run on CPU |
| if not all(cons.run_on_npu for cons in tens.consumer_list): |
| return |
| if not all(prod.run_on_npu for prod in tens.ops): |
| return |
| |
| # "Concat" ofm exception: |
| if _avoid_nhcwb16_for_concat(tens): |
| return |
| |
| # "Split" ifm exception: |
| if _avoid_nhcwb16_for_split(tens): |
| return |
| |
| # Shapes checking: check all producers/consumers are NHCWB16 compatible with tens.shape |
| if _avoid_nhcwb16_for_shapes(tens): |
| return |
| |
| for op in tens.consumer_list: |
| if op.type == Op.ReduceSum and tens.dtype == DataType.int32: |
| return |
| if op.type == Op.Reshape: |
| # Using NHCWB16 format for a no-op reshape is only an option if subsequent |
| # consumers do not also need to perform a reshape or if the OFM is going to |
| # be processed by CPU operations. No-op reshape consumers with empty lists |
| # (those that have no consumers, or null-consumers used as list terminators) |
| # must use normal NHWC output. |
| |
| def incompatible_consumers(oper): |
| if oper and oper.type == Op.Reshape: |
| for consumer in oper.outputs[0].consumer_list: |
| yield from incompatible_consumers(consumer) |
| yield not oper or not oper.run_on_npu |
| |
| if not any(incompatible_consumers(op)): |
| |
| def get_rewrites(oper): |
| if oper and oper.type == Op.Reshape: |
| for consumer in oper.outputs[0].consumer_list: |
| yield from get_rewrites(consumer) |
| yield oper |
| |
| # Detect no-op reshapes by comparing their full input and output tensor shapes. |
| inshape = op.ifm_shapes[0] |
| compatible_shape = [(inshape == oper.ofm_shapes[0]) for oper in get_rewrites(op)] |
| if not (compatible_shape and all(compatible_shape)): |
| return |
| else: |
| return |
| |
| tens.needs_linear_format = False |
| |
| |
| def calc_explicit_padding(input_size, stride, filter_size, pad_before, pad_after) -> Tuple[int, int]: |
| """ |
| Based on explicit padding provided in a PAD operation, returns the corresponding hardware padding |
| that provides equivalent results. |
| """ |
| total_padding = needed_total_padding(input_size, stride, filter_size) |
| |
| # The bottom/right padding might need downward adjustment depending on stride/input size |
| total_minus_before = total_padding - pad_before |
| output_pad_after = pad_after |
| while output_pad_after > 0 and output_pad_after % stride != total_minus_before % stride: |
| output_pad_after -= 1 |
| return pad_before, output_pad_after |
| |
| |
| 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 |
| |
| |
| # 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 set_ifm_ofm_op_shapes(op, arch, nng): |
| if op.run_on_npu and op.type.needs_shapes(): |
| if op.ifm_shapes or op.ofm_shapes: |
| # Shapes already set |
| return op |
| op.set_ifm_ofm_shapes() |
| return op |
| |
| |
| def check_reshapes(op, arch): |
| if op.run_on_npu and op.type == Op.Reshape: |
| ofm = op.ofm |
| |
| if check_quantized_tens_scaling_equal(op.ifm, ofm): |
| # Reshape should have been removed |
| raise VelaError(f"Reshape op {op} expected to have been removed, still remains") |
| |
| |
| def record_optimised(op, arch): |
| if op.type != Op.Const: |
| DebugDatabase.add_optimised(op, op) |